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// (C) 2001-2015 Altera Corporation. All rights reserved.
// Your use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any output
// files any of the foregoing (including device programming or simulation
// files), and any associated documentation or information are expressly subject
// to the terms and conditions of the Altera Program License Subscription
// Agreement, Altera MegaCore Function License Agreement, or other applicable
// license agreement, including, without limitation, that your use is for the
// sole purpose of programming logic devices manufactured by Altera and sold by
// Altera or its authorized distributors. Please refer to the applicable
// agreement for further details.
// $Id: //acds/rel/15.1/ip/merlin/altera_reset_controller/altera_reset_synchronizer.v#1 $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
// -----------------------------------------------
// Reset Synchronizer
// -----------------------------------------------
`timescale 1 ns / 1 ns
module altera_reset_synchronizer
#(
parameter ASYNC_RESET = 1,
parameter DEPTH = 2
)
(
input reset_in /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=R101" */,
input clk,
output reset_out
);
// -----------------------------------------------
// Synchronizer register chain. We cannot reuse the
// standard synchronizer in this implementation
// because our timing constraints are different.
//
// Instead of cutting the timing path to the d-input
// on the first flop we need to cut the aclr input.
//
// We omit the "preserve" attribute on the final
// output register, so that the synthesis tool can
// duplicate it where needed.
// -----------------------------------------------
(*preserve*) reg [DEPTH-1:0] altera_reset_synchronizer_int_chain;
reg altera_reset_synchronizer_int_chain_out;
generate if (ASYNC_RESET) begin
// -----------------------------------------------
// Assert asynchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk or posedge reset_in) begin
if (reset_in) begin
altera_reset_synchronizer_int_chain <= {DEPTH{1'b1}};
altera_reset_synchronizer_int_chain_out <= 1'b1;
end
else begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= 0;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end else begin
// -----------------------------------------------
// Assert synchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk) begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= reset_in;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end
endgenerate
endmodule
|
// (C) 2001-2015 Altera Corporation. All rights reserved.
// Your use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any output
// files any of the foregoing (including device programming or simulation
// files), and any associated documentation or information are expressly subject
// to the terms and conditions of the Altera Program License Subscription
// Agreement, Altera MegaCore Function License Agreement, or other applicable
// license agreement, including, without limitation, that your use is for the
// sole purpose of programming logic devices manufactured by Altera and sold by
// Altera or its authorized distributors. Please refer to the applicable
// agreement for further details.
// $Id: //acds/rel/15.1/ip/merlin/altera_reset_controller/altera_reset_synchronizer.v#1 $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
// -----------------------------------------------
// Reset Synchronizer
// -----------------------------------------------
`timescale 1 ns / 1 ns
module altera_reset_synchronizer
#(
parameter ASYNC_RESET = 1,
parameter DEPTH = 2
)
(
input reset_in /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=R101" */,
input clk,
output reset_out
);
// -----------------------------------------------
// Synchronizer register chain. We cannot reuse the
// standard synchronizer in this implementation
// because our timing constraints are different.
//
// Instead of cutting the timing path to the d-input
// on the first flop we need to cut the aclr input.
//
// We omit the "preserve" attribute on the final
// output register, so that the synthesis tool can
// duplicate it where needed.
// -----------------------------------------------
(*preserve*) reg [DEPTH-1:0] altera_reset_synchronizer_int_chain;
reg altera_reset_synchronizer_int_chain_out;
generate if (ASYNC_RESET) begin
// -----------------------------------------------
// Assert asynchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk or posedge reset_in) begin
if (reset_in) begin
altera_reset_synchronizer_int_chain <= {DEPTH{1'b1}};
altera_reset_synchronizer_int_chain_out <= 1'b1;
end
else begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= 0;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end else begin
// -----------------------------------------------
// Assert synchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk) begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= reset_in;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end
endgenerate
endmodule
|
// (C) 2001-2015 Altera Corporation. All rights reserved.
// Your use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any output
// files any of the foregoing (including device programming or simulation
// files), and any associated documentation or information are expressly subject
// to the terms and conditions of the Altera Program License Subscription
// Agreement, Altera MegaCore Function License Agreement, or other applicable
// license agreement, including, without limitation, that your use is for the
// sole purpose of programming logic devices manufactured by Altera and sold by
// Altera or its authorized distributors. Please refer to the applicable
// agreement for further details.
// $Id: //acds/rel/15.1/ip/merlin/altera_reset_controller/altera_reset_synchronizer.v#1 $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
// -----------------------------------------------
// Reset Synchronizer
// -----------------------------------------------
`timescale 1 ns / 1 ns
module altera_reset_synchronizer
#(
parameter ASYNC_RESET = 1,
parameter DEPTH = 2
)
(
input reset_in /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=R101" */,
input clk,
output reset_out
);
// -----------------------------------------------
// Synchronizer register chain. We cannot reuse the
// standard synchronizer in this implementation
// because our timing constraints are different.
//
// Instead of cutting the timing path to the d-input
// on the first flop we need to cut the aclr input.
//
// We omit the "preserve" attribute on the final
// output register, so that the synthesis tool can
// duplicate it where needed.
// -----------------------------------------------
(*preserve*) reg [DEPTH-1:0] altera_reset_synchronizer_int_chain;
reg altera_reset_synchronizer_int_chain_out;
generate if (ASYNC_RESET) begin
// -----------------------------------------------
// Assert asynchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk or posedge reset_in) begin
if (reset_in) begin
altera_reset_synchronizer_int_chain <= {DEPTH{1'b1}};
altera_reset_synchronizer_int_chain_out <= 1'b1;
end
else begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= 0;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end else begin
// -----------------------------------------------
// Assert synchronously, deassert synchronously.
// -----------------------------------------------
always @(posedge clk) begin
altera_reset_synchronizer_int_chain[DEPTH-2:0] <= altera_reset_synchronizer_int_chain[DEPTH-1:1];
altera_reset_synchronizer_int_chain[DEPTH-1] <= reset_in;
altera_reset_synchronizer_int_chain_out <= altera_reset_synchronizer_int_chain[0];
end
assign reset_out = altera_reset_synchronizer_int_chain_out;
end
endgenerate
endmodule
|
// (C) 2001-2015 Altera Corporation. All rights reserved.
// Your use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any output
// files any of the foregoing (including device programming or simulation
// files), and any associated documentation or information are expressly subject
// to the terms and conditions of the Altera Program License Subscription
// Agreement, Altera MegaCore Function License Agreement, or other applicable
// license agreement, including, without limitation, that your use is for the
// sole purpose of programming logic devices manufactured by Altera and sold by
// Altera or its authorized distributors. Please refer to the applicable
// agreement for further details.
// $File: //acds/rel/15.1/ip/avalon_st/altera_avalon_st_pipeline_stage/altera_avalon_st_pipeline_base.v $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
//------------------------------------------------------------------------------
`timescale 1ns / 1ns
module altera_avalon_st_pipeline_base (
clk,
reset,
in_ready,
in_valid,
in_data,
out_ready,
out_valid,
out_data
);
parameter SYMBOLS_PER_BEAT = 1;
parameter BITS_PER_SYMBOL = 8;
parameter PIPELINE_READY = 1;
localparam DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL;
input clk;
input reset;
output in_ready;
input in_valid;
input [DATA_WIDTH-1:0] in_data;
input out_ready;
output out_valid;
output [DATA_WIDTH-1:0] out_data;
reg full0;
reg full1;
reg [DATA_WIDTH-1:0] data0;
reg [DATA_WIDTH-1:0] data1;
assign out_valid = full1;
assign out_data = data1;
generate if (PIPELINE_READY == 1)
begin : REGISTERED_READY_PLINE
assign in_ready = !full0;
always @(posedge clk, posedge reset) begin
if (reset) begin
data0 <= {DATA_WIDTH{1'b0}};
data1 <= {DATA_WIDTH{1'b0}};
end else begin
// ----------------------------
// always load the second slot if we can
// ----------------------------
if (~full0)
data0 <= in_data;
// ----------------------------
// first slot is loaded either from the second,
// or with new data
// ----------------------------
if (~full1 || (out_ready && out_valid)) begin
if (full0)
data1 <= data0;
else
data1 <= in_data;
end
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
full0 <= 1'b0;
full1 <= 1'b0;
end else begin
// no data in pipeline
if (~full0 & ~full1) begin
if (in_valid) begin
full1 <= 1'b1;
end
end // ~f1 & ~f0
// one datum in pipeline
if (full1 & ~full0) begin
if (in_valid & ~out_ready) begin
full0 <= 1'b1;
end
// back to empty
if (~in_valid & out_ready) begin
full1 <= 1'b0;
end
end // f1 & ~f0
// two data in pipeline
if (full1 & full0) begin
// go back to one datum state
if (out_ready) begin
full0 <= 1'b0;
end
end // end go back to one datum stage
end
end
end
else
begin : UNREGISTERED_READY_PLINE
// in_ready will be a pass through of the out_ready signal as it is not registered
assign in_ready = (~full1) | out_ready;
always @(posedge clk or posedge reset) begin
if (reset) begin
data1 <= 'b0;
full1 <= 1'b0;
end
else begin
if (in_ready) begin
data1 <= in_data;
full1 <= in_valid;
end
end
end
end
endgenerate
endmodule
|
// (C) 2001-2015 Altera Corporation. All rights reserved.
// Your use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any output
// files any of the foregoing (including device programming or simulation
// files), and any associated documentation or information are expressly subject
// to the terms and conditions of the Altera Program License Subscription
// Agreement, Altera MegaCore Function License Agreement, or other applicable
// license agreement, including, without limitation, that your use is for the
// sole purpose of programming logic devices manufactured by Altera and sold by
// Altera or its authorized distributors. Please refer to the applicable
// agreement for further details.
// $File: //acds/rel/15.1/ip/avalon_st/altera_avalon_st_pipeline_stage/altera_avalon_st_pipeline_base.v $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
//------------------------------------------------------------------------------
`timescale 1ns / 1ns
module altera_avalon_st_pipeline_base (
clk,
reset,
in_ready,
in_valid,
in_data,
out_ready,
out_valid,
out_data
);
parameter SYMBOLS_PER_BEAT = 1;
parameter BITS_PER_SYMBOL = 8;
parameter PIPELINE_READY = 1;
localparam DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL;
input clk;
input reset;
output in_ready;
input in_valid;
input [DATA_WIDTH-1:0] in_data;
input out_ready;
output out_valid;
output [DATA_WIDTH-1:0] out_data;
reg full0;
reg full1;
reg [DATA_WIDTH-1:0] data0;
reg [DATA_WIDTH-1:0] data1;
assign out_valid = full1;
assign out_data = data1;
generate if (PIPELINE_READY == 1)
begin : REGISTERED_READY_PLINE
assign in_ready = !full0;
always @(posedge clk, posedge reset) begin
if (reset) begin
data0 <= {DATA_WIDTH{1'b0}};
data1 <= {DATA_WIDTH{1'b0}};
end else begin
// ----------------------------
// always load the second slot if we can
// ----------------------------
if (~full0)
data0 <= in_data;
// ----------------------------
// first slot is loaded either from the second,
// or with new data
// ----------------------------
if (~full1 || (out_ready && out_valid)) begin
if (full0)
data1 <= data0;
else
data1 <= in_data;
end
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
full0 <= 1'b0;
full1 <= 1'b0;
end else begin
// no data in pipeline
if (~full0 & ~full1) begin
if (in_valid) begin
full1 <= 1'b1;
end
end // ~f1 & ~f0
// one datum in pipeline
if (full1 & ~full0) begin
if (in_valid & ~out_ready) begin
full0 <= 1'b1;
end
// back to empty
if (~in_valid & out_ready) begin
full1 <= 1'b0;
end
end // f1 & ~f0
// two data in pipeline
if (full1 & full0) begin
// go back to one datum state
if (out_ready) begin
full0 <= 1'b0;
end
end // end go back to one datum stage
end
end
end
else
begin : UNREGISTERED_READY_PLINE
// in_ready will be a pass through of the out_ready signal as it is not registered
assign in_ready = (~full1) | out_ready;
always @(posedge clk or posedge reset) begin
if (reset) begin
data1 <= 'b0;
full1 <= 1'b0;
end
else begin
if (in_ready) begin
data1 <= in_data;
full1 <= in_valid;
end
end
end
end
endgenerate
endmodule
|
// (C) 2001-2015 Altera Corporation. All rights reserved.
// Your use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any output
// files any of the foregoing (including device programming or simulation
// files), and any associated documentation or information are expressly subject
// to the terms and conditions of the Altera Program License Subscription
// Agreement, Altera MegaCore Function License Agreement, or other applicable
// license agreement, including, without limitation, that your use is for the
// sole purpose of programming logic devices manufactured by Altera and sold by
// Altera or its authorized distributors. Please refer to the applicable
// agreement for further details.
// $File: //acds/rel/15.1/ip/avalon_st/altera_avalon_st_pipeline_stage/altera_avalon_st_pipeline_base.v $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
//------------------------------------------------------------------------------
`timescale 1ns / 1ns
module altera_avalon_st_pipeline_base (
clk,
reset,
in_ready,
in_valid,
in_data,
out_ready,
out_valid,
out_data
);
parameter SYMBOLS_PER_BEAT = 1;
parameter BITS_PER_SYMBOL = 8;
parameter PIPELINE_READY = 1;
localparam DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL;
input clk;
input reset;
output in_ready;
input in_valid;
input [DATA_WIDTH-1:0] in_data;
input out_ready;
output out_valid;
output [DATA_WIDTH-1:0] out_data;
reg full0;
reg full1;
reg [DATA_WIDTH-1:0] data0;
reg [DATA_WIDTH-1:0] data1;
assign out_valid = full1;
assign out_data = data1;
generate if (PIPELINE_READY == 1)
begin : REGISTERED_READY_PLINE
assign in_ready = !full0;
always @(posedge clk, posedge reset) begin
if (reset) begin
data0 <= {DATA_WIDTH{1'b0}};
data1 <= {DATA_WIDTH{1'b0}};
end else begin
// ----------------------------
// always load the second slot if we can
// ----------------------------
if (~full0)
data0 <= in_data;
// ----------------------------
// first slot is loaded either from the second,
// or with new data
// ----------------------------
if (~full1 || (out_ready && out_valid)) begin
if (full0)
data1 <= data0;
else
data1 <= in_data;
end
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
full0 <= 1'b0;
full1 <= 1'b0;
end else begin
// no data in pipeline
if (~full0 & ~full1) begin
if (in_valid) begin
full1 <= 1'b1;
end
end // ~f1 & ~f0
// one datum in pipeline
if (full1 & ~full0) begin
if (in_valid & ~out_ready) begin
full0 <= 1'b1;
end
// back to empty
if (~in_valid & out_ready) begin
full1 <= 1'b0;
end
end // f1 & ~f0
// two data in pipeline
if (full1 & full0) begin
// go back to one datum state
if (out_ready) begin
full0 <= 1'b0;
end
end // end go back to one datum stage
end
end
end
else
begin : UNREGISTERED_READY_PLINE
// in_ready will be a pass through of the out_ready signal as it is not registered
assign in_ready = (~full1) | out_ready;
always @(posedge clk or posedge reset) begin
if (reset) begin
data1 <= 'b0;
full1 <= 1'b0;
end
else begin
if (in_ready) begin
data1 <= in_data;
full1 <= in_valid;
end
end
end
end
endgenerate
endmodule
|
// (C) 2001-2015 Altera Corporation. All rights reserved.
// Your use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any output
// files any of the foregoing (including device programming or simulation
// files), and any associated documentation or information are expressly subject
// to the terms and conditions of the Altera Program License Subscription
// Agreement, Altera MegaCore Function License Agreement, or other applicable
// license agreement, including, without limitation, that your use is for the
// sole purpose of programming logic devices manufactured by Altera and sold by
// Altera or its authorized distributors. Please refer to the applicable
// agreement for further details.
// $File: //acds/rel/15.1/ip/avalon_st/altera_avalon_st_pipeline_stage/altera_avalon_st_pipeline_base.v $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
//------------------------------------------------------------------------------
`timescale 1ns / 1ns
module altera_avalon_st_pipeline_base (
clk,
reset,
in_ready,
in_valid,
in_data,
out_ready,
out_valid,
out_data
);
parameter SYMBOLS_PER_BEAT = 1;
parameter BITS_PER_SYMBOL = 8;
parameter PIPELINE_READY = 1;
localparam DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL;
input clk;
input reset;
output in_ready;
input in_valid;
input [DATA_WIDTH-1:0] in_data;
input out_ready;
output out_valid;
output [DATA_WIDTH-1:0] out_data;
reg full0;
reg full1;
reg [DATA_WIDTH-1:0] data0;
reg [DATA_WIDTH-1:0] data1;
assign out_valid = full1;
assign out_data = data1;
generate if (PIPELINE_READY == 1)
begin : REGISTERED_READY_PLINE
assign in_ready = !full0;
always @(posedge clk, posedge reset) begin
if (reset) begin
data0 <= {DATA_WIDTH{1'b0}};
data1 <= {DATA_WIDTH{1'b0}};
end else begin
// ----------------------------
// always load the second slot if we can
// ----------------------------
if (~full0)
data0 <= in_data;
// ----------------------------
// first slot is loaded either from the second,
// or with new data
// ----------------------------
if (~full1 || (out_ready && out_valid)) begin
if (full0)
data1 <= data0;
else
data1 <= in_data;
end
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
full0 <= 1'b0;
full1 <= 1'b0;
end else begin
// no data in pipeline
if (~full0 & ~full1) begin
if (in_valid) begin
full1 <= 1'b1;
end
end // ~f1 & ~f0
// one datum in pipeline
if (full1 & ~full0) begin
if (in_valid & ~out_ready) begin
full0 <= 1'b1;
end
// back to empty
if (~in_valid & out_ready) begin
full1 <= 1'b0;
end
end // f1 & ~f0
// two data in pipeline
if (full1 & full0) begin
// go back to one datum state
if (out_ready) begin
full0 <= 1'b0;
end
end // end go back to one datum stage
end
end
end
else
begin : UNREGISTERED_READY_PLINE
// in_ready will be a pass through of the out_ready signal as it is not registered
assign in_ready = (~full1) | out_ready;
always @(posedge clk or posedge reset) begin
if (reset) begin
data1 <= 'b0;
full1 <= 1'b0;
end
else begin
if (in_ready) begin
data1 <= in_data;
full1 <= in_valid;
end
end
end
end
endgenerate
endmodule
|
// (C) 2001-2015 Altera Corporation. All rights reserved.
// Your use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any output
// files any of the foregoing (including device programming or simulation
// files), and any associated documentation or information are expressly subject
// to the terms and conditions of the Altera Program License Subscription
// Agreement, Altera MegaCore Function License Agreement, or other applicable
// license agreement, including, without limitation, that your use is for the
// sole purpose of programming logic devices manufactured by Altera and sold by
// Altera or its authorized distributors. Please refer to the applicable
// agreement for further details.
// $File: //acds/rel/15.1/ip/avalon_st/altera_avalon_st_pipeline_stage/altera_avalon_st_pipeline_base.v $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
//------------------------------------------------------------------------------
`timescale 1ns / 1ns
module altera_avalon_st_pipeline_base (
clk,
reset,
in_ready,
in_valid,
in_data,
out_ready,
out_valid,
out_data
);
parameter SYMBOLS_PER_BEAT = 1;
parameter BITS_PER_SYMBOL = 8;
parameter PIPELINE_READY = 1;
localparam DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL;
input clk;
input reset;
output in_ready;
input in_valid;
input [DATA_WIDTH-1:0] in_data;
input out_ready;
output out_valid;
output [DATA_WIDTH-1:0] out_data;
reg full0;
reg full1;
reg [DATA_WIDTH-1:0] data0;
reg [DATA_WIDTH-1:0] data1;
assign out_valid = full1;
assign out_data = data1;
generate if (PIPELINE_READY == 1)
begin : REGISTERED_READY_PLINE
assign in_ready = !full0;
always @(posedge clk, posedge reset) begin
if (reset) begin
data0 <= {DATA_WIDTH{1'b0}};
data1 <= {DATA_WIDTH{1'b0}};
end else begin
// ----------------------------
// always load the second slot if we can
// ----------------------------
if (~full0)
data0 <= in_data;
// ----------------------------
// first slot is loaded either from the second,
// or with new data
// ----------------------------
if (~full1 || (out_ready && out_valid)) begin
if (full0)
data1 <= data0;
else
data1 <= in_data;
end
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
full0 <= 1'b0;
full1 <= 1'b0;
end else begin
// no data in pipeline
if (~full0 & ~full1) begin
if (in_valid) begin
full1 <= 1'b1;
end
end // ~f1 & ~f0
// one datum in pipeline
if (full1 & ~full0) begin
if (in_valid & ~out_ready) begin
full0 <= 1'b1;
end
// back to empty
if (~in_valid & out_ready) begin
full1 <= 1'b0;
end
end // f1 & ~f0
// two data in pipeline
if (full1 & full0) begin
// go back to one datum state
if (out_ready) begin
full0 <= 1'b0;
end
end // end go back to one datum stage
end
end
end
else
begin : UNREGISTERED_READY_PLINE
// in_ready will be a pass through of the out_ready signal as it is not registered
assign in_ready = (~full1) | out_ready;
always @(posedge clk or posedge reset) begin
if (reset) begin
data1 <= 'b0;
full1 <= 1'b0;
end
else begin
if (in_ready) begin
data1 <= in_data;
full1 <= in_valid;
end
end
end
end
endgenerate
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Address Write Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// aw_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_aw_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_ADDR_WIDTH = 32,
// Width of all ADDR signals on SI and MI side of checker.
// Range: 32.
parameter integer C_AXI_AWUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
output reg cmd_w_valid,
output wire cmd_w_check,
output wire [C_AXI_ID_WIDTH-1:0] cmd_w_id,
input wire cmd_w_ready,
input wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
input wire cmd_b_ready,
// Slave Interface Write Address Port
input wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID,
input wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR,
input wire [4-1:0] S_AXI_AWLEN,
input wire [3-1:0] S_AXI_AWSIZE,
input wire [2-1:0] S_AXI_AWBURST,
input wire [2-1:0] S_AXI_AWLOCK,
input wire [4-1:0] S_AXI_AWCACHE,
input wire [3-1:0] S_AXI_AWPROT,
input wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER,
input wire S_AXI_AWVALID,
output wire S_AXI_AWREADY,
// Master Interface Write Address Port
output wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID,
output wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR,
output wire [4-1:0] M_AXI_AWLEN,
output wire [3-1:0] M_AXI_AWSIZE,
output wire [2-1:0] M_AXI_AWBURST,
output wire [2-1:0] M_AXI_AWLOCK,
output wire [4-1:0] M_AXI_AWCACHE,
output wire [3-1:0] M_AXI_AWPROT,
output wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER,
output wire M_AXI_AWVALID,
input wire M_AXI_AWREADY
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for burst types.
localparam [2-1:0] C_FIX_BURST = 2'b00;
localparam [2-1:0] C_INCR_BURST = 2'b01;
localparam [2-1:0] C_WRAP_BURST = 2'b10;
// Constants for size.
localparam [3-1:0] C_OPTIMIZED_SIZE = 3'b011;
// Constants for length.
localparam [4-1:0] C_OPTIMIZED_LEN = 4'b0011;
// Constants for cacheline address.
localparam [4-1:0] C_NO_ADDR_OFFSET = 5'b0;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Transaction properties.
wire access_is_incr;
wire access_is_wrap;
wire access_is_coherent;
wire access_optimized_size;
wire incr_addr_boundary;
wire incr_is_optimized;
wire wrap_is_optimized;
wire access_is_optimized;
// Command FIFO.
wire cmd_w_push;
reg cmd_full;
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
wire [C_FIFO_DEPTH_LOG-1:0] all_addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
/////////////////////////////////////////////////////////////////////////////
// Transaction Decode:
//
// Detect if transaction is of correct typ, size and length to qualify as
// an optimized transaction that has to be checked for errors.
//
/////////////////////////////////////////////////////////////////////////////
// Transaction burst type.
assign access_is_incr = ( S_AXI_AWBURST == C_INCR_BURST );
assign access_is_wrap = ( S_AXI_AWBURST == C_WRAP_BURST );
// Transaction has to be Coherent.
assign access_is_coherent = ( S_AXI_AWUSER[0] == 1'b1 ) &
( S_AXI_AWCACHE[1] == 1'b1 );
// Transaction cacheline boundary address.
assign incr_addr_boundary = ( S_AXI_AWADDR[4:0] == C_NO_ADDR_OFFSET );
// Transaction length & size.
assign access_optimized_size = ( S_AXI_AWSIZE == C_OPTIMIZED_SIZE ) &
( S_AXI_AWLEN == C_OPTIMIZED_LEN );
// Transaction is optimized.
assign incr_is_optimized = access_is_incr & access_is_coherent & access_optimized_size & incr_addr_boundary;
assign wrap_is_optimized = access_is_wrap & access_is_coherent & access_optimized_size;
assign access_is_optimized = ( incr_is_optimized | wrap_is_optimized );
/////////////////////////////////////////////////////////////////////////////
// Command FIFO:
//
// Since supported write interleaving is only 1, it is safe to use only a
// simple SRL based FIFO as a command queue.
//
/////////////////////////////////////////////////////////////////////////////
// Determine when transaction infromation is pushed to the FIFO.
assign cmd_w_push = S_AXI_AWVALID & M_AXI_AWREADY & ~cmd_full;
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
addr_ptr <= addr_ptr + 1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
addr_ptr <= addr_ptr - 1;
end
end
end
// Total number of buffered commands.
assign all_addr_ptr = addr_ptr + cmd_b_addr + 2;
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_full <= 1'b0;
cmd_w_valid <= 1'b0;
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
cmd_w_valid <= 1'b1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
cmd_w_valid <= ( addr_ptr != 0 );
end
if ( cmd_w_push & ~cmd_b_ready ) begin
// Going to full.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-3 );
end else if ( ~cmd_w_push & cmd_b_ready ) begin
// Pop in middle of queue doesn't affect full status.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-2 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_w_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {access_is_optimized, S_AXI_AWID};
end
end
// Get current transaction info.
assign {cmd_w_check, cmd_w_id} = data_srl[addr_ptr];
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Stall commands if FIFO is full.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign M_AXI_AWVALID = S_AXI_AWVALID & ~cmd_full;
// Return ready with push back.
assign S_AXI_AWREADY = M_AXI_AWREADY & ~cmd_full;
/////////////////////////////////////////////////////////////////////////////
// Address Write propagation:
//
// All information is simply forwarded on from the SI- to MI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWUSER = S_AXI_AWUSER;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Address Write Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// aw_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_aw_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_ADDR_WIDTH = 32,
// Width of all ADDR signals on SI and MI side of checker.
// Range: 32.
parameter integer C_AXI_AWUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
output reg cmd_w_valid,
output wire cmd_w_check,
output wire [C_AXI_ID_WIDTH-1:0] cmd_w_id,
input wire cmd_w_ready,
input wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
input wire cmd_b_ready,
// Slave Interface Write Address Port
input wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID,
input wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR,
input wire [4-1:0] S_AXI_AWLEN,
input wire [3-1:0] S_AXI_AWSIZE,
input wire [2-1:0] S_AXI_AWBURST,
input wire [2-1:0] S_AXI_AWLOCK,
input wire [4-1:0] S_AXI_AWCACHE,
input wire [3-1:0] S_AXI_AWPROT,
input wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER,
input wire S_AXI_AWVALID,
output wire S_AXI_AWREADY,
// Master Interface Write Address Port
output wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID,
output wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR,
output wire [4-1:0] M_AXI_AWLEN,
output wire [3-1:0] M_AXI_AWSIZE,
output wire [2-1:0] M_AXI_AWBURST,
output wire [2-1:0] M_AXI_AWLOCK,
output wire [4-1:0] M_AXI_AWCACHE,
output wire [3-1:0] M_AXI_AWPROT,
output wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER,
output wire M_AXI_AWVALID,
input wire M_AXI_AWREADY
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for burst types.
localparam [2-1:0] C_FIX_BURST = 2'b00;
localparam [2-1:0] C_INCR_BURST = 2'b01;
localparam [2-1:0] C_WRAP_BURST = 2'b10;
// Constants for size.
localparam [3-1:0] C_OPTIMIZED_SIZE = 3'b011;
// Constants for length.
localparam [4-1:0] C_OPTIMIZED_LEN = 4'b0011;
// Constants for cacheline address.
localparam [4-1:0] C_NO_ADDR_OFFSET = 5'b0;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Transaction properties.
wire access_is_incr;
wire access_is_wrap;
wire access_is_coherent;
wire access_optimized_size;
wire incr_addr_boundary;
wire incr_is_optimized;
wire wrap_is_optimized;
wire access_is_optimized;
// Command FIFO.
wire cmd_w_push;
reg cmd_full;
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
wire [C_FIFO_DEPTH_LOG-1:0] all_addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
/////////////////////////////////////////////////////////////////////////////
// Transaction Decode:
//
// Detect if transaction is of correct typ, size and length to qualify as
// an optimized transaction that has to be checked for errors.
//
/////////////////////////////////////////////////////////////////////////////
// Transaction burst type.
assign access_is_incr = ( S_AXI_AWBURST == C_INCR_BURST );
assign access_is_wrap = ( S_AXI_AWBURST == C_WRAP_BURST );
// Transaction has to be Coherent.
assign access_is_coherent = ( S_AXI_AWUSER[0] == 1'b1 ) &
( S_AXI_AWCACHE[1] == 1'b1 );
// Transaction cacheline boundary address.
assign incr_addr_boundary = ( S_AXI_AWADDR[4:0] == C_NO_ADDR_OFFSET );
// Transaction length & size.
assign access_optimized_size = ( S_AXI_AWSIZE == C_OPTIMIZED_SIZE ) &
( S_AXI_AWLEN == C_OPTIMIZED_LEN );
// Transaction is optimized.
assign incr_is_optimized = access_is_incr & access_is_coherent & access_optimized_size & incr_addr_boundary;
assign wrap_is_optimized = access_is_wrap & access_is_coherent & access_optimized_size;
assign access_is_optimized = ( incr_is_optimized | wrap_is_optimized );
/////////////////////////////////////////////////////////////////////////////
// Command FIFO:
//
// Since supported write interleaving is only 1, it is safe to use only a
// simple SRL based FIFO as a command queue.
//
/////////////////////////////////////////////////////////////////////////////
// Determine when transaction infromation is pushed to the FIFO.
assign cmd_w_push = S_AXI_AWVALID & M_AXI_AWREADY & ~cmd_full;
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
addr_ptr <= addr_ptr + 1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
addr_ptr <= addr_ptr - 1;
end
end
end
// Total number of buffered commands.
assign all_addr_ptr = addr_ptr + cmd_b_addr + 2;
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_full <= 1'b0;
cmd_w_valid <= 1'b0;
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
cmd_w_valid <= 1'b1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
cmd_w_valid <= ( addr_ptr != 0 );
end
if ( cmd_w_push & ~cmd_b_ready ) begin
// Going to full.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-3 );
end else if ( ~cmd_w_push & cmd_b_ready ) begin
// Pop in middle of queue doesn't affect full status.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-2 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_w_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {access_is_optimized, S_AXI_AWID};
end
end
// Get current transaction info.
assign {cmd_w_check, cmd_w_id} = data_srl[addr_ptr];
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Stall commands if FIFO is full.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign M_AXI_AWVALID = S_AXI_AWVALID & ~cmd_full;
// Return ready with push back.
assign S_AXI_AWREADY = M_AXI_AWREADY & ~cmd_full;
/////////////////////////////////////////////////////////////////////////////
// Address Write propagation:
//
// All information is simply forwarded on from the SI- to MI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWUSER = S_AXI_AWUSER;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Address Write Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// aw_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_aw_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_ADDR_WIDTH = 32,
// Width of all ADDR signals on SI and MI side of checker.
// Range: 32.
parameter integer C_AXI_AWUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
output reg cmd_w_valid,
output wire cmd_w_check,
output wire [C_AXI_ID_WIDTH-1:0] cmd_w_id,
input wire cmd_w_ready,
input wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
input wire cmd_b_ready,
// Slave Interface Write Address Port
input wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID,
input wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR,
input wire [4-1:0] S_AXI_AWLEN,
input wire [3-1:0] S_AXI_AWSIZE,
input wire [2-1:0] S_AXI_AWBURST,
input wire [2-1:0] S_AXI_AWLOCK,
input wire [4-1:0] S_AXI_AWCACHE,
input wire [3-1:0] S_AXI_AWPROT,
input wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER,
input wire S_AXI_AWVALID,
output wire S_AXI_AWREADY,
// Master Interface Write Address Port
output wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID,
output wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR,
output wire [4-1:0] M_AXI_AWLEN,
output wire [3-1:0] M_AXI_AWSIZE,
output wire [2-1:0] M_AXI_AWBURST,
output wire [2-1:0] M_AXI_AWLOCK,
output wire [4-1:0] M_AXI_AWCACHE,
output wire [3-1:0] M_AXI_AWPROT,
output wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER,
output wire M_AXI_AWVALID,
input wire M_AXI_AWREADY
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for burst types.
localparam [2-1:0] C_FIX_BURST = 2'b00;
localparam [2-1:0] C_INCR_BURST = 2'b01;
localparam [2-1:0] C_WRAP_BURST = 2'b10;
// Constants for size.
localparam [3-1:0] C_OPTIMIZED_SIZE = 3'b011;
// Constants for length.
localparam [4-1:0] C_OPTIMIZED_LEN = 4'b0011;
// Constants for cacheline address.
localparam [4-1:0] C_NO_ADDR_OFFSET = 5'b0;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Transaction properties.
wire access_is_incr;
wire access_is_wrap;
wire access_is_coherent;
wire access_optimized_size;
wire incr_addr_boundary;
wire incr_is_optimized;
wire wrap_is_optimized;
wire access_is_optimized;
// Command FIFO.
wire cmd_w_push;
reg cmd_full;
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
wire [C_FIFO_DEPTH_LOG-1:0] all_addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
/////////////////////////////////////////////////////////////////////////////
// Transaction Decode:
//
// Detect if transaction is of correct typ, size and length to qualify as
// an optimized transaction that has to be checked for errors.
//
/////////////////////////////////////////////////////////////////////////////
// Transaction burst type.
assign access_is_incr = ( S_AXI_AWBURST == C_INCR_BURST );
assign access_is_wrap = ( S_AXI_AWBURST == C_WRAP_BURST );
// Transaction has to be Coherent.
assign access_is_coherent = ( S_AXI_AWUSER[0] == 1'b1 ) &
( S_AXI_AWCACHE[1] == 1'b1 );
// Transaction cacheline boundary address.
assign incr_addr_boundary = ( S_AXI_AWADDR[4:0] == C_NO_ADDR_OFFSET );
// Transaction length & size.
assign access_optimized_size = ( S_AXI_AWSIZE == C_OPTIMIZED_SIZE ) &
( S_AXI_AWLEN == C_OPTIMIZED_LEN );
// Transaction is optimized.
assign incr_is_optimized = access_is_incr & access_is_coherent & access_optimized_size & incr_addr_boundary;
assign wrap_is_optimized = access_is_wrap & access_is_coherent & access_optimized_size;
assign access_is_optimized = ( incr_is_optimized | wrap_is_optimized );
/////////////////////////////////////////////////////////////////////////////
// Command FIFO:
//
// Since supported write interleaving is only 1, it is safe to use only a
// simple SRL based FIFO as a command queue.
//
/////////////////////////////////////////////////////////////////////////////
// Determine when transaction infromation is pushed to the FIFO.
assign cmd_w_push = S_AXI_AWVALID & M_AXI_AWREADY & ~cmd_full;
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
addr_ptr <= addr_ptr + 1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
addr_ptr <= addr_ptr - 1;
end
end
end
// Total number of buffered commands.
assign all_addr_ptr = addr_ptr + cmd_b_addr + 2;
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_full <= 1'b0;
cmd_w_valid <= 1'b0;
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
cmd_w_valid <= 1'b1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
cmd_w_valid <= ( addr_ptr != 0 );
end
if ( cmd_w_push & ~cmd_b_ready ) begin
// Going to full.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-3 );
end else if ( ~cmd_w_push & cmd_b_ready ) begin
// Pop in middle of queue doesn't affect full status.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-2 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_w_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {access_is_optimized, S_AXI_AWID};
end
end
// Get current transaction info.
assign {cmd_w_check, cmd_w_id} = data_srl[addr_ptr];
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Stall commands if FIFO is full.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign M_AXI_AWVALID = S_AXI_AWVALID & ~cmd_full;
// Return ready with push back.
assign S_AXI_AWREADY = M_AXI_AWREADY & ~cmd_full;
/////////////////////////////////////////////////////////////////////////////
// Address Write propagation:
//
// All information is simply forwarded on from the SI- to MI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWUSER = S_AXI_AWUSER;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Address Write Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// aw_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_aw_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_ADDR_WIDTH = 32,
// Width of all ADDR signals on SI and MI side of checker.
// Range: 32.
parameter integer C_AXI_AWUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
output reg cmd_w_valid,
output wire cmd_w_check,
output wire [C_AXI_ID_WIDTH-1:0] cmd_w_id,
input wire cmd_w_ready,
input wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
input wire cmd_b_ready,
// Slave Interface Write Address Port
input wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID,
input wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR,
input wire [4-1:0] S_AXI_AWLEN,
input wire [3-1:0] S_AXI_AWSIZE,
input wire [2-1:0] S_AXI_AWBURST,
input wire [2-1:0] S_AXI_AWLOCK,
input wire [4-1:0] S_AXI_AWCACHE,
input wire [3-1:0] S_AXI_AWPROT,
input wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER,
input wire S_AXI_AWVALID,
output wire S_AXI_AWREADY,
// Master Interface Write Address Port
output wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID,
output wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR,
output wire [4-1:0] M_AXI_AWLEN,
output wire [3-1:0] M_AXI_AWSIZE,
output wire [2-1:0] M_AXI_AWBURST,
output wire [2-1:0] M_AXI_AWLOCK,
output wire [4-1:0] M_AXI_AWCACHE,
output wire [3-1:0] M_AXI_AWPROT,
output wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER,
output wire M_AXI_AWVALID,
input wire M_AXI_AWREADY
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for burst types.
localparam [2-1:0] C_FIX_BURST = 2'b00;
localparam [2-1:0] C_INCR_BURST = 2'b01;
localparam [2-1:0] C_WRAP_BURST = 2'b10;
// Constants for size.
localparam [3-1:0] C_OPTIMIZED_SIZE = 3'b011;
// Constants for length.
localparam [4-1:0] C_OPTIMIZED_LEN = 4'b0011;
// Constants for cacheline address.
localparam [4-1:0] C_NO_ADDR_OFFSET = 5'b0;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Transaction properties.
wire access_is_incr;
wire access_is_wrap;
wire access_is_coherent;
wire access_optimized_size;
wire incr_addr_boundary;
wire incr_is_optimized;
wire wrap_is_optimized;
wire access_is_optimized;
// Command FIFO.
wire cmd_w_push;
reg cmd_full;
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
wire [C_FIFO_DEPTH_LOG-1:0] all_addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
/////////////////////////////////////////////////////////////////////////////
// Transaction Decode:
//
// Detect if transaction is of correct typ, size and length to qualify as
// an optimized transaction that has to be checked for errors.
//
/////////////////////////////////////////////////////////////////////////////
// Transaction burst type.
assign access_is_incr = ( S_AXI_AWBURST == C_INCR_BURST );
assign access_is_wrap = ( S_AXI_AWBURST == C_WRAP_BURST );
// Transaction has to be Coherent.
assign access_is_coherent = ( S_AXI_AWUSER[0] == 1'b1 ) &
( S_AXI_AWCACHE[1] == 1'b1 );
// Transaction cacheline boundary address.
assign incr_addr_boundary = ( S_AXI_AWADDR[4:0] == C_NO_ADDR_OFFSET );
// Transaction length & size.
assign access_optimized_size = ( S_AXI_AWSIZE == C_OPTIMIZED_SIZE ) &
( S_AXI_AWLEN == C_OPTIMIZED_LEN );
// Transaction is optimized.
assign incr_is_optimized = access_is_incr & access_is_coherent & access_optimized_size & incr_addr_boundary;
assign wrap_is_optimized = access_is_wrap & access_is_coherent & access_optimized_size;
assign access_is_optimized = ( incr_is_optimized | wrap_is_optimized );
/////////////////////////////////////////////////////////////////////////////
// Command FIFO:
//
// Since supported write interleaving is only 1, it is safe to use only a
// simple SRL based FIFO as a command queue.
//
/////////////////////////////////////////////////////////////////////////////
// Determine when transaction infromation is pushed to the FIFO.
assign cmd_w_push = S_AXI_AWVALID & M_AXI_AWREADY & ~cmd_full;
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
addr_ptr <= addr_ptr + 1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
addr_ptr <= addr_ptr - 1;
end
end
end
// Total number of buffered commands.
assign all_addr_ptr = addr_ptr + cmd_b_addr + 2;
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_full <= 1'b0;
cmd_w_valid <= 1'b0;
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
cmd_w_valid <= 1'b1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
cmd_w_valid <= ( addr_ptr != 0 );
end
if ( cmd_w_push & ~cmd_b_ready ) begin
// Going to full.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-3 );
end else if ( ~cmd_w_push & cmd_b_ready ) begin
// Pop in middle of queue doesn't affect full status.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-2 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_w_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {access_is_optimized, S_AXI_AWID};
end
end
// Get current transaction info.
assign {cmd_w_check, cmd_w_id} = data_srl[addr_ptr];
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Stall commands if FIFO is full.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign M_AXI_AWVALID = S_AXI_AWVALID & ~cmd_full;
// Return ready with push back.
assign S_AXI_AWREADY = M_AXI_AWREADY & ~cmd_full;
/////////////////////////////////////////////////////////////////////////////
// Address Write propagation:
//
// All information is simply forwarded on from the SI- to MI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWUSER = S_AXI_AWUSER;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Address Write Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// aw_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_aw_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_ADDR_WIDTH = 32,
// Width of all ADDR signals on SI and MI side of checker.
// Range: 32.
parameter integer C_AXI_AWUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
output reg cmd_w_valid,
output wire cmd_w_check,
output wire [C_AXI_ID_WIDTH-1:0] cmd_w_id,
input wire cmd_w_ready,
input wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
input wire cmd_b_ready,
// Slave Interface Write Address Port
input wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID,
input wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR,
input wire [4-1:0] S_AXI_AWLEN,
input wire [3-1:0] S_AXI_AWSIZE,
input wire [2-1:0] S_AXI_AWBURST,
input wire [2-1:0] S_AXI_AWLOCK,
input wire [4-1:0] S_AXI_AWCACHE,
input wire [3-1:0] S_AXI_AWPROT,
input wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER,
input wire S_AXI_AWVALID,
output wire S_AXI_AWREADY,
// Master Interface Write Address Port
output wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID,
output wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR,
output wire [4-1:0] M_AXI_AWLEN,
output wire [3-1:0] M_AXI_AWSIZE,
output wire [2-1:0] M_AXI_AWBURST,
output wire [2-1:0] M_AXI_AWLOCK,
output wire [4-1:0] M_AXI_AWCACHE,
output wire [3-1:0] M_AXI_AWPROT,
output wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER,
output wire M_AXI_AWVALID,
input wire M_AXI_AWREADY
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for burst types.
localparam [2-1:0] C_FIX_BURST = 2'b00;
localparam [2-1:0] C_INCR_BURST = 2'b01;
localparam [2-1:0] C_WRAP_BURST = 2'b10;
// Constants for size.
localparam [3-1:0] C_OPTIMIZED_SIZE = 3'b011;
// Constants for length.
localparam [4-1:0] C_OPTIMIZED_LEN = 4'b0011;
// Constants for cacheline address.
localparam [4-1:0] C_NO_ADDR_OFFSET = 5'b0;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Transaction properties.
wire access_is_incr;
wire access_is_wrap;
wire access_is_coherent;
wire access_optimized_size;
wire incr_addr_boundary;
wire incr_is_optimized;
wire wrap_is_optimized;
wire access_is_optimized;
// Command FIFO.
wire cmd_w_push;
reg cmd_full;
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
wire [C_FIFO_DEPTH_LOG-1:0] all_addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
/////////////////////////////////////////////////////////////////////////////
// Transaction Decode:
//
// Detect if transaction is of correct typ, size and length to qualify as
// an optimized transaction that has to be checked for errors.
//
/////////////////////////////////////////////////////////////////////////////
// Transaction burst type.
assign access_is_incr = ( S_AXI_AWBURST == C_INCR_BURST );
assign access_is_wrap = ( S_AXI_AWBURST == C_WRAP_BURST );
// Transaction has to be Coherent.
assign access_is_coherent = ( S_AXI_AWUSER[0] == 1'b1 ) &
( S_AXI_AWCACHE[1] == 1'b1 );
// Transaction cacheline boundary address.
assign incr_addr_boundary = ( S_AXI_AWADDR[4:0] == C_NO_ADDR_OFFSET );
// Transaction length & size.
assign access_optimized_size = ( S_AXI_AWSIZE == C_OPTIMIZED_SIZE ) &
( S_AXI_AWLEN == C_OPTIMIZED_LEN );
// Transaction is optimized.
assign incr_is_optimized = access_is_incr & access_is_coherent & access_optimized_size & incr_addr_boundary;
assign wrap_is_optimized = access_is_wrap & access_is_coherent & access_optimized_size;
assign access_is_optimized = ( incr_is_optimized | wrap_is_optimized );
/////////////////////////////////////////////////////////////////////////////
// Command FIFO:
//
// Since supported write interleaving is only 1, it is safe to use only a
// simple SRL based FIFO as a command queue.
//
/////////////////////////////////////////////////////////////////////////////
// Determine when transaction infromation is pushed to the FIFO.
assign cmd_w_push = S_AXI_AWVALID & M_AXI_AWREADY & ~cmd_full;
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
addr_ptr <= addr_ptr + 1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
addr_ptr <= addr_ptr - 1;
end
end
end
// Total number of buffered commands.
assign all_addr_ptr = addr_ptr + cmd_b_addr + 2;
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_full <= 1'b0;
cmd_w_valid <= 1'b0;
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
cmd_w_valid <= 1'b1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
cmd_w_valid <= ( addr_ptr != 0 );
end
if ( cmd_w_push & ~cmd_b_ready ) begin
// Going to full.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-3 );
end else if ( ~cmd_w_push & cmd_b_ready ) begin
// Pop in middle of queue doesn't affect full status.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-2 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_w_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {access_is_optimized, S_AXI_AWID};
end
end
// Get current transaction info.
assign {cmd_w_check, cmd_w_id} = data_srl[addr_ptr];
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Stall commands if FIFO is full.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign M_AXI_AWVALID = S_AXI_AWVALID & ~cmd_full;
// Return ready with push back.
assign S_AXI_AWREADY = M_AXI_AWREADY & ~cmd_full;
/////////////////////////////////////////////////////////////////////////////
// Address Write propagation:
//
// All information is simply forwarded on from the SI- to MI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWUSER = S_AXI_AWUSER;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Address Write Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// aw_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_aw_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_ADDR_WIDTH = 32,
// Width of all ADDR signals on SI and MI side of checker.
// Range: 32.
parameter integer C_AXI_AWUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
output reg cmd_w_valid,
output wire cmd_w_check,
output wire [C_AXI_ID_WIDTH-1:0] cmd_w_id,
input wire cmd_w_ready,
input wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
input wire cmd_b_ready,
// Slave Interface Write Address Port
input wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID,
input wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR,
input wire [4-1:0] S_AXI_AWLEN,
input wire [3-1:0] S_AXI_AWSIZE,
input wire [2-1:0] S_AXI_AWBURST,
input wire [2-1:0] S_AXI_AWLOCK,
input wire [4-1:0] S_AXI_AWCACHE,
input wire [3-1:0] S_AXI_AWPROT,
input wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER,
input wire S_AXI_AWVALID,
output wire S_AXI_AWREADY,
// Master Interface Write Address Port
output wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID,
output wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR,
output wire [4-1:0] M_AXI_AWLEN,
output wire [3-1:0] M_AXI_AWSIZE,
output wire [2-1:0] M_AXI_AWBURST,
output wire [2-1:0] M_AXI_AWLOCK,
output wire [4-1:0] M_AXI_AWCACHE,
output wire [3-1:0] M_AXI_AWPROT,
output wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER,
output wire M_AXI_AWVALID,
input wire M_AXI_AWREADY
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for burst types.
localparam [2-1:0] C_FIX_BURST = 2'b00;
localparam [2-1:0] C_INCR_BURST = 2'b01;
localparam [2-1:0] C_WRAP_BURST = 2'b10;
// Constants for size.
localparam [3-1:0] C_OPTIMIZED_SIZE = 3'b011;
// Constants for length.
localparam [4-1:0] C_OPTIMIZED_LEN = 4'b0011;
// Constants for cacheline address.
localparam [4-1:0] C_NO_ADDR_OFFSET = 5'b0;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Transaction properties.
wire access_is_incr;
wire access_is_wrap;
wire access_is_coherent;
wire access_optimized_size;
wire incr_addr_boundary;
wire incr_is_optimized;
wire wrap_is_optimized;
wire access_is_optimized;
// Command FIFO.
wire cmd_w_push;
reg cmd_full;
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
wire [C_FIFO_DEPTH_LOG-1:0] all_addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
/////////////////////////////////////////////////////////////////////////////
// Transaction Decode:
//
// Detect if transaction is of correct typ, size and length to qualify as
// an optimized transaction that has to be checked for errors.
//
/////////////////////////////////////////////////////////////////////////////
// Transaction burst type.
assign access_is_incr = ( S_AXI_AWBURST == C_INCR_BURST );
assign access_is_wrap = ( S_AXI_AWBURST == C_WRAP_BURST );
// Transaction has to be Coherent.
assign access_is_coherent = ( S_AXI_AWUSER[0] == 1'b1 ) &
( S_AXI_AWCACHE[1] == 1'b1 );
// Transaction cacheline boundary address.
assign incr_addr_boundary = ( S_AXI_AWADDR[4:0] == C_NO_ADDR_OFFSET );
// Transaction length & size.
assign access_optimized_size = ( S_AXI_AWSIZE == C_OPTIMIZED_SIZE ) &
( S_AXI_AWLEN == C_OPTIMIZED_LEN );
// Transaction is optimized.
assign incr_is_optimized = access_is_incr & access_is_coherent & access_optimized_size & incr_addr_boundary;
assign wrap_is_optimized = access_is_wrap & access_is_coherent & access_optimized_size;
assign access_is_optimized = ( incr_is_optimized | wrap_is_optimized );
/////////////////////////////////////////////////////////////////////////////
// Command FIFO:
//
// Since supported write interleaving is only 1, it is safe to use only a
// simple SRL based FIFO as a command queue.
//
/////////////////////////////////////////////////////////////////////////////
// Determine when transaction infromation is pushed to the FIFO.
assign cmd_w_push = S_AXI_AWVALID & M_AXI_AWREADY & ~cmd_full;
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
addr_ptr <= addr_ptr + 1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
addr_ptr <= addr_ptr - 1;
end
end
end
// Total number of buffered commands.
assign all_addr_ptr = addr_ptr + cmd_b_addr + 2;
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_full <= 1'b0;
cmd_w_valid <= 1'b0;
end else begin
if ( cmd_w_push & ~cmd_w_ready ) begin
cmd_w_valid <= 1'b1;
end else if ( ~cmd_w_push & cmd_w_ready ) begin
cmd_w_valid <= ( addr_ptr != 0 );
end
if ( cmd_w_push & ~cmd_b_ready ) begin
// Going to full.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-3 );
end else if ( ~cmd_w_push & cmd_b_ready ) begin
// Pop in middle of queue doesn't affect full status.
cmd_full <= ( all_addr_ptr == C_FIFO_DEPTH-2 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_w_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {access_is_optimized, S_AXI_AWID};
end
end
// Get current transaction info.
assign {cmd_w_check, cmd_w_id} = data_srl[addr_ptr];
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Stall commands if FIFO is full.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign M_AXI_AWVALID = S_AXI_AWVALID & ~cmd_full;
// Return ready with push back.
assign S_AXI_AWREADY = M_AXI_AWREADY & ~cmd_full;
/////////////////////////////////////////////////////////////////////////////
// Address Write propagation:
//
// All information is simply forwarded on from the SI- to MI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWUSER = S_AXI_AWUSER;
endmodule
|
`include "../../firmware/include/fpga_regs_common.v"
`include "../../firmware/include/fpga_regs_standard.v"
module adc_interface
(input clock, input reset, input enable,
input wire [6:0] serial_addr, input wire [31:0] serial_data, input serial_strobe,
input wire [11:0] rx_a_a, input wire [11:0] rx_b_a, input wire [11:0] rx_a_b, input wire [11:0] rx_b_b,
output wire [31:0] rssi_0, output wire [31:0] rssi_1, output wire [31:0] rssi_2, output wire [31:0] rssi_3,
output reg [15:0] ddc0_in_i, output reg [15:0] ddc0_in_q,
output reg [15:0] ddc1_in_i, output reg [15:0] ddc1_in_q,
output reg [15:0] ddc2_in_i, output reg [15:0] ddc2_in_q,
output reg [15:0] ddc3_in_i, output reg [15:0] ddc3_in_q,
output wire [3:0] rx_numchan);
// Buffer at input to chip
reg [11:0] adc0,adc1,adc2,adc3;
always @(posedge clock)
begin
adc0 <= #1 rx_a_a;
adc1 <= #1 rx_b_a;
adc2 <= #1 rx_a_b;
adc3 <= #1 rx_b_b;
end
// then scale and subtract dc offset
wire [3:0] dco_en;
wire [15:0] adc0_corr,adc1_corr,adc2_corr,adc3_corr;
setting_reg #(`FR_DC_OFFSET_CL_EN) sr_dco_en(.clock(clock),.reset(reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),
.out(dco_en));
rx_dcoffset #(`FR_ADC_OFFSET_0) rx_dcoffset0(.clock(clock),.enable(dco_en[0]),.reset(reset),.adc_in({adc0[11],adc0,3'b0}),.adc_out(adc0_corr),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
rx_dcoffset #(`FR_ADC_OFFSET_1) rx_dcoffset1(.clock(clock),.enable(dco_en[1]),.reset(reset),.adc_in({adc1[11],adc1,3'b0}),.adc_out(adc1_corr),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
rx_dcoffset #(`FR_ADC_OFFSET_2) rx_dcoffset2(.clock(clock),.enable(dco_en[2]),.reset(reset),.adc_in({adc2[11],adc2,3'b0}),.adc_out(adc2_corr),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
rx_dcoffset #(`FR_ADC_OFFSET_3) rx_dcoffset3(.clock(clock),.enable(dco_en[3]),.reset(reset),.adc_in({adc3[11],adc3,3'b0}),.adc_out(adc3_corr),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
// Level sensing for AGC
rssi rssi_block_0 (.clock(clock),.reset(reset),.enable(enable),.adc(adc0),.rssi(rssi_0[15:0]),.over_count(rssi_0[31:16]));
rssi rssi_block_1 (.clock(clock),.reset(reset),.enable(enable),.adc(adc1),.rssi(rssi_1[15:0]),.over_count(rssi_1[31:16]));
rssi rssi_block_2 (.clock(clock),.reset(reset),.enable(enable),.adc(adc2),.rssi(rssi_2[15:0]),.over_count(rssi_2[31:16]));
rssi rssi_block_3 (.clock(clock),.reset(reset),.enable(enable),.adc(adc3),.rssi(rssi_3[15:0]),.over_count(rssi_3[31:16]));
// And mux to the appropriate outputs
wire [3:0] ddc3mux,ddc2mux,ddc1mux,ddc0mux;
wire rx_realsignals;
setting_reg #(`FR_RX_MUX) sr_rxmux(.clock(clock),.reset(reset),.strobe(serial_strobe),.addr(serial_addr),
.in(serial_data),.out({ddc3mux,ddc2mux,ddc1mux,ddc0mux,rx_realsignals,rx_numchan[3:1]}));
assign rx_numchan[0] = 1'b0;
always @(posedge clock)
begin
ddc0_in_i <= #1 ddc0mux[1] ? (ddc0mux[0] ? adc3_corr : adc2_corr) : (ddc0mux[0] ? adc1_corr : adc0_corr);
ddc0_in_q <= #1 rx_realsignals ? 16'd0 : ddc0mux[3] ? (ddc0mux[2] ? adc3_corr : adc2_corr) : (ddc0mux[2] ? adc1_corr : adc0_corr);
ddc1_in_i <= #1 ddc1mux[1] ? (ddc1mux[0] ? adc3_corr : adc2_corr) : (ddc1mux[0] ? adc1_corr : adc0_corr);
ddc1_in_q <= #1 rx_realsignals ? 16'd0 : ddc1mux[3] ? (ddc1mux[2] ? adc3_corr : adc2_corr) : (ddc1mux[2] ? adc1_corr : adc0_corr);
ddc2_in_i <= #1 ddc2mux[1] ? (ddc2mux[0] ? adc3_corr : adc2_corr) : (ddc2mux[0] ? adc1_corr : adc0_corr);
ddc2_in_q <= #1 rx_realsignals ? 16'd0 : ddc2mux[3] ? (ddc2mux[2] ? adc3_corr : adc2_corr) : (ddc2mux[2] ? adc1_corr : adc0_corr);
ddc3_in_i <= #1 ddc3mux[1] ? (ddc3mux[0] ? adc3_corr : adc2_corr) : (ddc3mux[0] ? adc1_corr : adc0_corr);
ddc3_in_q <= #1 rx_realsignals ? 16'd0 : ddc3mux[3] ? (ddc3mux[2] ? adc3_corr : adc2_corr) : (ddc3mux[2] ? adc1_corr : adc0_corr);
end
endmodule // adc_interface
|
`include "../../firmware/include/fpga_regs_common.v"
`include "../../firmware/include/fpga_regs_standard.v"
module adc_interface
(input clock, input reset, input enable,
input wire [6:0] serial_addr, input wire [31:0] serial_data, input serial_strobe,
input wire [11:0] rx_a_a, input wire [11:0] rx_b_a, input wire [11:0] rx_a_b, input wire [11:0] rx_b_b,
output wire [31:0] rssi_0, output wire [31:0] rssi_1, output wire [31:0] rssi_2, output wire [31:0] rssi_3,
output reg [15:0] ddc0_in_i, output reg [15:0] ddc0_in_q,
output reg [15:0] ddc1_in_i, output reg [15:0] ddc1_in_q,
output reg [15:0] ddc2_in_i, output reg [15:0] ddc2_in_q,
output reg [15:0] ddc3_in_i, output reg [15:0] ddc3_in_q,
output wire [3:0] rx_numchan);
// Buffer at input to chip
reg [11:0] adc0,adc1,adc2,adc3;
always @(posedge clock)
begin
adc0 <= #1 rx_a_a;
adc1 <= #1 rx_b_a;
adc2 <= #1 rx_a_b;
adc3 <= #1 rx_b_b;
end
// then scale and subtract dc offset
wire [3:0] dco_en;
wire [15:0] adc0_corr,adc1_corr,adc2_corr,adc3_corr;
setting_reg #(`FR_DC_OFFSET_CL_EN) sr_dco_en(.clock(clock),.reset(reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),
.out(dco_en));
rx_dcoffset #(`FR_ADC_OFFSET_0) rx_dcoffset0(.clock(clock),.enable(dco_en[0]),.reset(reset),.adc_in({adc0[11],adc0,3'b0}),.adc_out(adc0_corr),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
rx_dcoffset #(`FR_ADC_OFFSET_1) rx_dcoffset1(.clock(clock),.enable(dco_en[1]),.reset(reset),.adc_in({adc1[11],adc1,3'b0}),.adc_out(adc1_corr),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
rx_dcoffset #(`FR_ADC_OFFSET_2) rx_dcoffset2(.clock(clock),.enable(dco_en[2]),.reset(reset),.adc_in({adc2[11],adc2,3'b0}),.adc_out(adc2_corr),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
rx_dcoffset #(`FR_ADC_OFFSET_3) rx_dcoffset3(.clock(clock),.enable(dco_en[3]),.reset(reset),.adc_in({adc3[11],adc3,3'b0}),.adc_out(adc3_corr),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
// Level sensing for AGC
rssi rssi_block_0 (.clock(clock),.reset(reset),.enable(enable),.adc(adc0),.rssi(rssi_0[15:0]),.over_count(rssi_0[31:16]));
rssi rssi_block_1 (.clock(clock),.reset(reset),.enable(enable),.adc(adc1),.rssi(rssi_1[15:0]),.over_count(rssi_1[31:16]));
rssi rssi_block_2 (.clock(clock),.reset(reset),.enable(enable),.adc(adc2),.rssi(rssi_2[15:0]),.over_count(rssi_2[31:16]));
rssi rssi_block_3 (.clock(clock),.reset(reset),.enable(enable),.adc(adc3),.rssi(rssi_3[15:0]),.over_count(rssi_3[31:16]));
// And mux to the appropriate outputs
wire [3:0] ddc3mux,ddc2mux,ddc1mux,ddc0mux;
wire rx_realsignals;
setting_reg #(`FR_RX_MUX) sr_rxmux(.clock(clock),.reset(reset),.strobe(serial_strobe),.addr(serial_addr),
.in(serial_data),.out({ddc3mux,ddc2mux,ddc1mux,ddc0mux,rx_realsignals,rx_numchan[3:1]}));
assign rx_numchan[0] = 1'b0;
always @(posedge clock)
begin
ddc0_in_i <= #1 ddc0mux[1] ? (ddc0mux[0] ? adc3_corr : adc2_corr) : (ddc0mux[0] ? adc1_corr : adc0_corr);
ddc0_in_q <= #1 rx_realsignals ? 16'd0 : ddc0mux[3] ? (ddc0mux[2] ? adc3_corr : adc2_corr) : (ddc0mux[2] ? adc1_corr : adc0_corr);
ddc1_in_i <= #1 ddc1mux[1] ? (ddc1mux[0] ? adc3_corr : adc2_corr) : (ddc1mux[0] ? adc1_corr : adc0_corr);
ddc1_in_q <= #1 rx_realsignals ? 16'd0 : ddc1mux[3] ? (ddc1mux[2] ? adc3_corr : adc2_corr) : (ddc1mux[2] ? adc1_corr : adc0_corr);
ddc2_in_i <= #1 ddc2mux[1] ? (ddc2mux[0] ? adc3_corr : adc2_corr) : (ddc2mux[0] ? adc1_corr : adc0_corr);
ddc2_in_q <= #1 rx_realsignals ? 16'd0 : ddc2mux[3] ? (ddc2mux[2] ? adc3_corr : adc2_corr) : (ddc2mux[2] ? adc1_corr : adc0_corr);
ddc3_in_i <= #1 ddc3mux[1] ? (ddc3mux[0] ? adc3_corr : adc2_corr) : (ddc3mux[0] ? adc1_corr : adc0_corr);
ddc3_in_q <= #1 rx_realsignals ? 16'd0 : ddc3mux[3] ? (ddc3mux[2] ? adc3_corr : adc2_corr) : (ddc3mux[2] ? adc1_corr : adc0_corr);
end
endmodule // adc_interface
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
// http://www.eg.bucknell.edu/~cs320/1995-fall/verilog-manual.html#RTFToC33
// Digital model of a traffic light
// By Dan Hyde August 10, 1995
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red = off; amber = off; green = off;
$display(" Time green amber red");
$monitor("%3d %b %b %b", $time, green, amber, red);
end
// task to wait for 'tics' positive edge clocks
// before turning light off
task light;
output color;
input [31:0] tics;
begin
repeat(tics) // wait to detect tics positive edges on clock
@(posedge clock);
color = off;
end
endtask
// waveform for clock period of 2 time units
always begin: clock_wave
#1 clock = 0;
#1 clock = 1;
end
always begin: main_process
red = on;
light(red, red_tics); // call task to wait
green = on;
light(green, green_tics);
amber = on;
light(amber, amber_tics);
end
endmodule
|
/*
Copyright (c) 2014-2018 Alex Forencich
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
*/
// Language: Verilog-2001
`timescale 1 ns / 1 ps
/*
* Synchronizes switch and button inputs with a slow sampled shift register
*/
module debounce_switch #(
parameter WIDTH=1, // width of the input and output signals
parameter N=3, // length of shift register
parameter RATE=125000 // clock division factor
)(
input wire clk,
input wire rst,
input wire [WIDTH-1:0] in,
output wire [WIDTH-1:0] out
);
reg [23:0] cnt_reg = 24'd0;
reg [N-1:0] debounce_reg[WIDTH-1:0];
reg [WIDTH-1:0] state;
/*
* The synchronized output is the state register
*/
assign out = state;
integer k;
always @(posedge clk or posedge rst) begin
if (rst) begin
cnt_reg <= 0;
state <= 0;
for (k = 0; k < WIDTH; k = k + 1) begin
debounce_reg[k] <= 0;
end
end else begin
if (cnt_reg < RATE) begin
cnt_reg <= cnt_reg + 24'd1;
end else begin
cnt_reg <= 24'd0;
end
if (cnt_reg == 24'd0) begin
for (k = 0; k < WIDTH; k = k + 1) begin
debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]};
end
end
for (k = 0; k < WIDTH; k = k + 1) begin
if (|debounce_reg[k] == 0) begin
state[k] <= 0;
end else if (&debounce_reg[k] == 1) begin
state[k] <= 1;
end else begin
state[k] <= state[k];
end
end
end
end
endmodule
|
/*
Copyright (c) 2014-2018 Alex Forencich
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
*/
// Language: Verilog-2001
`timescale 1 ns / 1 ps
/*
* Synchronizes switch and button inputs with a slow sampled shift register
*/
module debounce_switch #(
parameter WIDTH=1, // width of the input and output signals
parameter N=3, // length of shift register
parameter RATE=125000 // clock division factor
)(
input wire clk,
input wire rst,
input wire [WIDTH-1:0] in,
output wire [WIDTH-1:0] out
);
reg [23:0] cnt_reg = 24'd0;
reg [N-1:0] debounce_reg[WIDTH-1:0];
reg [WIDTH-1:0] state;
/*
* The synchronized output is the state register
*/
assign out = state;
integer k;
always @(posedge clk or posedge rst) begin
if (rst) begin
cnt_reg <= 0;
state <= 0;
for (k = 0; k < WIDTH; k = k + 1) begin
debounce_reg[k] <= 0;
end
end else begin
if (cnt_reg < RATE) begin
cnt_reg <= cnt_reg + 24'd1;
end else begin
cnt_reg <= 24'd0;
end
if (cnt_reg == 24'd0) begin
for (k = 0; k < WIDTH; k = k + 1) begin
debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]};
end
end
for (k = 0; k < WIDTH; k = k + 1) begin
if (|debounce_reg[k] == 0) begin
state[k] <= 0;
end else if (&debounce_reg[k] == 1) begin
state[k] <= 1;
end else begin
state[k] <= state[k];
end
end
end
end
endmodule
|
/*
Copyright (c) 2014-2018 Alex Forencich
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
*/
// Language: Verilog-2001
`timescale 1 ns / 1 ps
/*
* Synchronizes switch and button inputs with a slow sampled shift register
*/
module debounce_switch #(
parameter WIDTH=1, // width of the input and output signals
parameter N=3, // length of shift register
parameter RATE=125000 // clock division factor
)(
input wire clk,
input wire rst,
input wire [WIDTH-1:0] in,
output wire [WIDTH-1:0] out
);
reg [23:0] cnt_reg = 24'd0;
reg [N-1:0] debounce_reg[WIDTH-1:0];
reg [WIDTH-1:0] state;
/*
* The synchronized output is the state register
*/
assign out = state;
integer k;
always @(posedge clk or posedge rst) begin
if (rst) begin
cnt_reg <= 0;
state <= 0;
for (k = 0; k < WIDTH; k = k + 1) begin
debounce_reg[k] <= 0;
end
end else begin
if (cnt_reg < RATE) begin
cnt_reg <= cnt_reg + 24'd1;
end else begin
cnt_reg <= 24'd0;
end
if (cnt_reg == 24'd0) begin
for (k = 0; k < WIDTH; k = k + 1) begin
debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]};
end
end
for (k = 0; k < WIDTH; k = k + 1) begin
if (|debounce_reg[k] == 0) begin
state[k] <= 0;
end else if (&debounce_reg[k] == 1) begin
state[k] <= 1;
end else begin
state[k] <= state[k];
end
end
end
end
endmodule
|
/*
Copyright (c) 2014-2018 Alex Forencich
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
*/
// Language: Verilog-2001
`timescale 1 ns / 1 ps
/*
* Synchronizes switch and button inputs with a slow sampled shift register
*/
module debounce_switch #(
parameter WIDTH=1, // width of the input and output signals
parameter N=3, // length of shift register
parameter RATE=125000 // clock division factor
)(
input wire clk,
input wire rst,
input wire [WIDTH-1:0] in,
output wire [WIDTH-1:0] out
);
reg [23:0] cnt_reg = 24'd0;
reg [N-1:0] debounce_reg[WIDTH-1:0];
reg [WIDTH-1:0] state;
/*
* The synchronized output is the state register
*/
assign out = state;
integer k;
always @(posedge clk or posedge rst) begin
if (rst) begin
cnt_reg <= 0;
state <= 0;
for (k = 0; k < WIDTH; k = k + 1) begin
debounce_reg[k] <= 0;
end
end else begin
if (cnt_reg < RATE) begin
cnt_reg <= cnt_reg + 24'd1;
end else begin
cnt_reg <= 24'd0;
end
if (cnt_reg == 24'd0) begin
for (k = 0; k < WIDTH; k = k + 1) begin
debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]};
end
end
for (k = 0; k < WIDTH; k = k + 1) begin
if (|debounce_reg[k] == 0) begin
state[k] <= 0;
end else if (&debounce_reg[k] == 1) begin
state[k] <= 1;
end else begin
state[k] <= state[k];
end
end
end
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 03/12/2016 06:26:54 PM
// Design Name:
// Module Name: shift_mux_array
// Project Name:
// Target Devices:
// Tool Versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module shift_mux_array
#(parameter SWR=26, parameter LEVEL=5)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
input wire bit_shift_i,
output wire [SWR-1:0] Data_o
);
genvar j;
generate for (j=0; j<=SWR-1 ; j=j+1) begin
localparam sh=(2**LEVEL)+j; //value for second mux input. It changes in exponentation by 2 for each level
case (sh>SWR-1)
1'b1:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (bit_shift_i),
.S (Data_o[j])
);
end
1'b0:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[sh]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 03/12/2016 06:26:54 PM
// Design Name:
// Module Name: shift_mux_array
// Project Name:
// Target Devices:
// Tool Versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module shift_mux_array
#(parameter SWR=26, parameter LEVEL=5)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
input wire bit_shift_i,
output wire [SWR-1:0] Data_o
);
genvar j;
generate for (j=0; j<=SWR-1 ; j=j+1) begin
localparam sh=(2**LEVEL)+j; //value for second mux input. It changes in exponentation by 2 for each level
case (sh>SWR-1)
1'b1:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (bit_shift_i),
.S (Data_o[j])
);
end
1'b0:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[sh]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 03/12/2016 06:26:54 PM
// Design Name:
// Module Name: shift_mux_array
// Project Name:
// Target Devices:
// Tool Versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module shift_mux_array
#(parameter SWR=26, parameter LEVEL=5)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
input wire bit_shift_i,
output wire [SWR-1:0] Data_o
);
genvar j;
generate for (j=0; j<=SWR-1 ; j=j+1) begin
localparam sh=(2**LEVEL)+j; //value for second mux input. It changes in exponentation by 2 for each level
case (sh>SWR-1)
1'b1:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (bit_shift_i),
.S (Data_o[j])
);
end
1'b0:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[sh]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 03/12/2016 06:26:54 PM
// Design Name:
// Module Name: shift_mux_array
// Project Name:
// Target Devices:
// Tool Versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module shift_mux_array
#(parameter SWR=26, parameter LEVEL=5)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
input wire bit_shift_i,
output wire [SWR-1:0] Data_o
);
genvar j;
generate for (j=0; j<=SWR-1 ; j=j+1) begin
localparam sh=(2**LEVEL)+j; //value for second mux input. It changes in exponentation by 2 for each level
case (sh>SWR-1)
1'b1:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (bit_shift_i),
.S (Data_o[j])
);
end
1'b0:begin
Multiplexer_AC #(.W(1)) rotate_mux(
.ctrl(select_i),
.D0 (Data_i[j]),
.D1 (Data_i[sh]),
.S (Data_o[j])
);
end
endcase
end
endgenerate
endmodule
|
// This is a component of pluto_servo, a PWM servo driver and quadrature
// counter for emc2
// Copyright 2006 Jeff Epler <[email protected]>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
module pluto_servo(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, quadA, quadB, quadZ, up, down);
parameter QW=14;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
wire do_tristate;
reg[9:0] real_dout; output [9:0] dout = do_tristate ? 10'bZZZZZZZZZZ : real_dout;
input [7:0] din;
input [3:0] quadA;
input [3:0] quadB;
input [3:0] quadZ;
wire[3:0] real_up; output [3:0] up = do_tristate ? 4'bZZZZ : real_up;
wire[3:0] real_down; output [3:0] down = do_tristate ? 4'bZZZZ : real_down;
reg Zpolarity;
wire [2*QW:0] quad0, quad1, quad2, quad3;
wire do_enable_wdt;
wire pwm_at_top;
wdt w(clk, do_enable_wdt, pwm_at_top, do_tristate);
// PWM stuff
// PWM clock is about 20kHz for clk @ 40MHz, 11-bit cnt
reg [10:0] pwmcnt;
wire [10:0] top = 11'd2046;
assign pwm_at_top = (pwmcnt == top);
reg [15:0] pwm0, pwm1, pwm2, pwm3;
always @(posedge clk) begin
if(pwm_at_top) pwmcnt <= 0;
else pwmcnt <= pwmcnt + 11'd1;
end
wire [10:0] pwmrev = {
pwmcnt[4], pwmcnt[5], pwmcnt[6], pwmcnt[7], pwmcnt[8], pwmcnt[9],
pwmcnt[10], pwmcnt[3:0]};
wire [10:0] pwmcmp0 = pwm0[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp1 = pwm1[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp2 = pwm2[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp3 = pwm3[14] ? pwmrev : pwmcnt;
wire pwmact0 = pwm0[10:0] > pwmcmp0;
wire pwmact1 = pwm1[10:0] > pwmcmp0;
wire pwmact2 = pwm2[10:0] > pwmcmp0;
wire pwmact3 = pwm3[10:0] > pwmcmp0;
assign real_up[0] = pwm0[12] ^ (pwm0[15] ? 1'd0 : pwmact0);
assign real_up[1] = pwm1[12] ^ (pwm1[15] ? 1'd0 : pwmact1);
assign real_up[2] = pwm2[12] ^ (pwm2[15] ? 1'd0 : pwmact2);
assign real_up[3] = pwm3[12] ^ (pwm3[15] ? 1'd0 : pwmact3);
assign real_down[0] = pwm0[13] ^ (~pwm0[15] ? 1'd0 : pwmact0);
assign real_down[1] = pwm1[13] ^ (~pwm1[15] ? 1'd0 : pwmact1);
assign real_down[2] = pwm2[13] ^ (~pwm2[15] ? 1'd0 : pwmact2);
assign real_down[3] = pwm3[13] ^ (~pwm3[15] ? 1'd0 : pwmact3);
// Quadrature stuff
// Quadrature is digitized at 40MHz into 14-bit counters
// Read up to 2^13 pulses / polling period = 8MHz for 1kHz servo period
reg qtest;
wire qr0, qr1, qr2, qr3;
quad q0(clk, qtest ? real_dout[0] : quadA[0], qtest ? real_dout[1] : quadB[0], qtest ? real_dout[2] : quadZ[0]^Zpolarity, qr0, quad0);
quad q1(clk, quadA[1], quadB[1], quadZ[1]^Zpolarity, qr1, quad1);
quad q2(clk, quadA[2], quadB[2], quadZ[2]^Zpolarity, qr2, quad2);
quad q3(clk, quadA[3], quadB[3], quadZ[3]^Zpolarity, qr3, quad3);
// EPP stuff
wire EPP_write = ~nWrite;
wire EPP_read = nWrite;
wire EPP_addr_strobe = ~nAddrStr;
wire EPP_data_strobe = ~nDataStr;
wire EPP_strobe = EPP_data_strobe | EPP_addr_strobe;
wire EPP_wait; assign nWait = ~EPP_wait;
wire [7:0] EPP_datain = pport_data;
wire [7:0] EPP_dataout; assign pport_data = EPP_dataout;
reg [4:0] EPP_strobe_reg;
always @(posedge clk) EPP_strobe_reg <= {EPP_strobe_reg[3:0], EPP_strobe};
wire EPP_strobe_edge1 = (EPP_strobe_reg[2:1]==2'b01);
// reg led;
assign EPP_wait = EPP_strobe_reg[4];
reg[4:0] addr_reg;
reg[7:0] lowbyte;
always @(posedge clk)
if(EPP_strobe_edge1 & EPP_write & EPP_addr_strobe) begin
addr_reg <= EPP_datain[4:0];
end
else if(EPP_strobe_edge1 & !EPP_addr_strobe) addr_reg <= addr_reg + 4'd1;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_write & EPP_data_strobe) begin
if(addr_reg[3:0] == 4'd1) pwm0 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd3) pwm1 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd5) pwm2 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd7) pwm3 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd9) begin
real_dout <= { EPP_datain[1:0], lowbyte };
Zpolarity <= EPP_datain[7];
qtest <= EPP_datain[5];
end
else lowbyte <= EPP_datain;
end
end
reg [31:0] data_buf;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_read && addr_reg[1:0] == 2'd0) begin
if(addr_reg[4:2] == 3'd0) data_buf <= quad0;
else if(addr_reg[4:2] == 3'd1) data_buf <= quad1;
else if(addr_reg[4:2] == 3'd2) data_buf <= quad2;
else if(addr_reg[4:2] == 3'd3) data_buf <= quad3;
else if(addr_reg[4:2] == 3'd4)
data_buf <= {quadA, quadB, quadZ, din};
end
end
// the addr_reg test looks funny because it is auto-incremented in an always
// block so "1" reads the low byte, "2 and "3" read middle bytes, and "0"
// reads the high byte I have a feeling that I'm doing this in the wrong way.
wire [7:0] data_reg = addr_reg[1:0] == 2'd1 ? data_buf[7:0] :
(addr_reg[1:0] == 2'd2 ? data_buf[15:8] :
(addr_reg[1:0] == 2'd3 ? data_buf[23:16] :
data_buf[31:24]));
wire [7:0] EPP_data_mux = data_reg;
assign EPP_dataout = (EPP_read & EPP_wait) ? EPP_data_mux : 8'hZZ;
assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
assign qr0 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd0);
assign qr1 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd1);
assign qr2 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd2);
assign qr3 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd3);
assign led = do_tristate ? 1'BZ : (real_up[0] ^ real_down[0]);
assign nConfig = epp_nReset; // 1'b1;
endmodule
|
// This is a component of pluto_servo, a PWM servo driver and quadrature
// counter for emc2
// Copyright 2006 Jeff Epler <[email protected]>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
module pluto_servo(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, quadA, quadB, quadZ, up, down);
parameter QW=14;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
wire do_tristate;
reg[9:0] real_dout; output [9:0] dout = do_tristate ? 10'bZZZZZZZZZZ : real_dout;
input [7:0] din;
input [3:0] quadA;
input [3:0] quadB;
input [3:0] quadZ;
wire[3:0] real_up; output [3:0] up = do_tristate ? 4'bZZZZ : real_up;
wire[3:0] real_down; output [3:0] down = do_tristate ? 4'bZZZZ : real_down;
reg Zpolarity;
wire [2*QW:0] quad0, quad1, quad2, quad3;
wire do_enable_wdt;
wire pwm_at_top;
wdt w(clk, do_enable_wdt, pwm_at_top, do_tristate);
// PWM stuff
// PWM clock is about 20kHz for clk @ 40MHz, 11-bit cnt
reg [10:0] pwmcnt;
wire [10:0] top = 11'd2046;
assign pwm_at_top = (pwmcnt == top);
reg [15:0] pwm0, pwm1, pwm2, pwm3;
always @(posedge clk) begin
if(pwm_at_top) pwmcnt <= 0;
else pwmcnt <= pwmcnt + 11'd1;
end
wire [10:0] pwmrev = {
pwmcnt[4], pwmcnt[5], pwmcnt[6], pwmcnt[7], pwmcnt[8], pwmcnt[9],
pwmcnt[10], pwmcnt[3:0]};
wire [10:0] pwmcmp0 = pwm0[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp1 = pwm1[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp2 = pwm2[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp3 = pwm3[14] ? pwmrev : pwmcnt;
wire pwmact0 = pwm0[10:0] > pwmcmp0;
wire pwmact1 = pwm1[10:0] > pwmcmp0;
wire pwmact2 = pwm2[10:0] > pwmcmp0;
wire pwmact3 = pwm3[10:0] > pwmcmp0;
assign real_up[0] = pwm0[12] ^ (pwm0[15] ? 1'd0 : pwmact0);
assign real_up[1] = pwm1[12] ^ (pwm1[15] ? 1'd0 : pwmact1);
assign real_up[2] = pwm2[12] ^ (pwm2[15] ? 1'd0 : pwmact2);
assign real_up[3] = pwm3[12] ^ (pwm3[15] ? 1'd0 : pwmact3);
assign real_down[0] = pwm0[13] ^ (~pwm0[15] ? 1'd0 : pwmact0);
assign real_down[1] = pwm1[13] ^ (~pwm1[15] ? 1'd0 : pwmact1);
assign real_down[2] = pwm2[13] ^ (~pwm2[15] ? 1'd0 : pwmact2);
assign real_down[3] = pwm3[13] ^ (~pwm3[15] ? 1'd0 : pwmact3);
// Quadrature stuff
// Quadrature is digitized at 40MHz into 14-bit counters
// Read up to 2^13 pulses / polling period = 8MHz for 1kHz servo period
reg qtest;
wire qr0, qr1, qr2, qr3;
quad q0(clk, qtest ? real_dout[0] : quadA[0], qtest ? real_dout[1] : quadB[0], qtest ? real_dout[2] : quadZ[0]^Zpolarity, qr0, quad0);
quad q1(clk, quadA[1], quadB[1], quadZ[1]^Zpolarity, qr1, quad1);
quad q2(clk, quadA[2], quadB[2], quadZ[2]^Zpolarity, qr2, quad2);
quad q3(clk, quadA[3], quadB[3], quadZ[3]^Zpolarity, qr3, quad3);
// EPP stuff
wire EPP_write = ~nWrite;
wire EPP_read = nWrite;
wire EPP_addr_strobe = ~nAddrStr;
wire EPP_data_strobe = ~nDataStr;
wire EPP_strobe = EPP_data_strobe | EPP_addr_strobe;
wire EPP_wait; assign nWait = ~EPP_wait;
wire [7:0] EPP_datain = pport_data;
wire [7:0] EPP_dataout; assign pport_data = EPP_dataout;
reg [4:0] EPP_strobe_reg;
always @(posedge clk) EPP_strobe_reg <= {EPP_strobe_reg[3:0], EPP_strobe};
wire EPP_strobe_edge1 = (EPP_strobe_reg[2:1]==2'b01);
// reg led;
assign EPP_wait = EPP_strobe_reg[4];
reg[4:0] addr_reg;
reg[7:0] lowbyte;
always @(posedge clk)
if(EPP_strobe_edge1 & EPP_write & EPP_addr_strobe) begin
addr_reg <= EPP_datain[4:0];
end
else if(EPP_strobe_edge1 & !EPP_addr_strobe) addr_reg <= addr_reg + 4'd1;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_write & EPP_data_strobe) begin
if(addr_reg[3:0] == 4'd1) pwm0 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd3) pwm1 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd5) pwm2 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd7) pwm3 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd9) begin
real_dout <= { EPP_datain[1:0], lowbyte };
Zpolarity <= EPP_datain[7];
qtest <= EPP_datain[5];
end
else lowbyte <= EPP_datain;
end
end
reg [31:0] data_buf;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_read && addr_reg[1:0] == 2'd0) begin
if(addr_reg[4:2] == 3'd0) data_buf <= quad0;
else if(addr_reg[4:2] == 3'd1) data_buf <= quad1;
else if(addr_reg[4:2] == 3'd2) data_buf <= quad2;
else if(addr_reg[4:2] == 3'd3) data_buf <= quad3;
else if(addr_reg[4:2] == 3'd4)
data_buf <= {quadA, quadB, quadZ, din};
end
end
// the addr_reg test looks funny because it is auto-incremented in an always
// block so "1" reads the low byte, "2 and "3" read middle bytes, and "0"
// reads the high byte I have a feeling that I'm doing this in the wrong way.
wire [7:0] data_reg = addr_reg[1:0] == 2'd1 ? data_buf[7:0] :
(addr_reg[1:0] == 2'd2 ? data_buf[15:8] :
(addr_reg[1:0] == 2'd3 ? data_buf[23:16] :
data_buf[31:24]));
wire [7:0] EPP_data_mux = data_reg;
assign EPP_dataout = (EPP_read & EPP_wait) ? EPP_data_mux : 8'hZZ;
assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
assign qr0 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd0);
assign qr1 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd1);
assign qr2 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd2);
assign qr3 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd3);
assign led = do_tristate ? 1'BZ : (real_up[0] ^ real_down[0]);
assign nConfig = epp_nReset; // 1'b1;
endmodule
|
// This is a component of pluto_servo, a PWM servo driver and quadrature
// counter for emc2
// Copyright 2006 Jeff Epler <[email protected]>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
module pluto_servo(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, quadA, quadB, quadZ, up, down);
parameter QW=14;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
wire do_tristate;
reg[9:0] real_dout; output [9:0] dout = do_tristate ? 10'bZZZZZZZZZZ : real_dout;
input [7:0] din;
input [3:0] quadA;
input [3:0] quadB;
input [3:0] quadZ;
wire[3:0] real_up; output [3:0] up = do_tristate ? 4'bZZZZ : real_up;
wire[3:0] real_down; output [3:0] down = do_tristate ? 4'bZZZZ : real_down;
reg Zpolarity;
wire [2*QW:0] quad0, quad1, quad2, quad3;
wire do_enable_wdt;
wire pwm_at_top;
wdt w(clk, do_enable_wdt, pwm_at_top, do_tristate);
// PWM stuff
// PWM clock is about 20kHz for clk @ 40MHz, 11-bit cnt
reg [10:0] pwmcnt;
wire [10:0] top = 11'd2046;
assign pwm_at_top = (pwmcnt == top);
reg [15:0] pwm0, pwm1, pwm2, pwm3;
always @(posedge clk) begin
if(pwm_at_top) pwmcnt <= 0;
else pwmcnt <= pwmcnt + 11'd1;
end
wire [10:0] pwmrev = {
pwmcnt[4], pwmcnt[5], pwmcnt[6], pwmcnt[7], pwmcnt[8], pwmcnt[9],
pwmcnt[10], pwmcnt[3:0]};
wire [10:0] pwmcmp0 = pwm0[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp1 = pwm1[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp2 = pwm2[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp3 = pwm3[14] ? pwmrev : pwmcnt;
wire pwmact0 = pwm0[10:0] > pwmcmp0;
wire pwmact1 = pwm1[10:0] > pwmcmp0;
wire pwmact2 = pwm2[10:0] > pwmcmp0;
wire pwmact3 = pwm3[10:0] > pwmcmp0;
assign real_up[0] = pwm0[12] ^ (pwm0[15] ? 1'd0 : pwmact0);
assign real_up[1] = pwm1[12] ^ (pwm1[15] ? 1'd0 : pwmact1);
assign real_up[2] = pwm2[12] ^ (pwm2[15] ? 1'd0 : pwmact2);
assign real_up[3] = pwm3[12] ^ (pwm3[15] ? 1'd0 : pwmact3);
assign real_down[0] = pwm0[13] ^ (~pwm0[15] ? 1'd0 : pwmact0);
assign real_down[1] = pwm1[13] ^ (~pwm1[15] ? 1'd0 : pwmact1);
assign real_down[2] = pwm2[13] ^ (~pwm2[15] ? 1'd0 : pwmact2);
assign real_down[3] = pwm3[13] ^ (~pwm3[15] ? 1'd0 : pwmact3);
// Quadrature stuff
// Quadrature is digitized at 40MHz into 14-bit counters
// Read up to 2^13 pulses / polling period = 8MHz for 1kHz servo period
reg qtest;
wire qr0, qr1, qr2, qr3;
quad q0(clk, qtest ? real_dout[0] : quadA[0], qtest ? real_dout[1] : quadB[0], qtest ? real_dout[2] : quadZ[0]^Zpolarity, qr0, quad0);
quad q1(clk, quadA[1], quadB[1], quadZ[1]^Zpolarity, qr1, quad1);
quad q2(clk, quadA[2], quadB[2], quadZ[2]^Zpolarity, qr2, quad2);
quad q3(clk, quadA[3], quadB[3], quadZ[3]^Zpolarity, qr3, quad3);
// EPP stuff
wire EPP_write = ~nWrite;
wire EPP_read = nWrite;
wire EPP_addr_strobe = ~nAddrStr;
wire EPP_data_strobe = ~nDataStr;
wire EPP_strobe = EPP_data_strobe | EPP_addr_strobe;
wire EPP_wait; assign nWait = ~EPP_wait;
wire [7:0] EPP_datain = pport_data;
wire [7:0] EPP_dataout; assign pport_data = EPP_dataout;
reg [4:0] EPP_strobe_reg;
always @(posedge clk) EPP_strobe_reg <= {EPP_strobe_reg[3:0], EPP_strobe};
wire EPP_strobe_edge1 = (EPP_strobe_reg[2:1]==2'b01);
// reg led;
assign EPP_wait = EPP_strobe_reg[4];
reg[4:0] addr_reg;
reg[7:0] lowbyte;
always @(posedge clk)
if(EPP_strobe_edge1 & EPP_write & EPP_addr_strobe) begin
addr_reg <= EPP_datain[4:0];
end
else if(EPP_strobe_edge1 & !EPP_addr_strobe) addr_reg <= addr_reg + 4'd1;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_write & EPP_data_strobe) begin
if(addr_reg[3:0] == 4'd1) pwm0 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd3) pwm1 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd5) pwm2 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd7) pwm3 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd9) begin
real_dout <= { EPP_datain[1:0], lowbyte };
Zpolarity <= EPP_datain[7];
qtest <= EPP_datain[5];
end
else lowbyte <= EPP_datain;
end
end
reg [31:0] data_buf;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_read && addr_reg[1:0] == 2'd0) begin
if(addr_reg[4:2] == 3'd0) data_buf <= quad0;
else if(addr_reg[4:2] == 3'd1) data_buf <= quad1;
else if(addr_reg[4:2] == 3'd2) data_buf <= quad2;
else if(addr_reg[4:2] == 3'd3) data_buf <= quad3;
else if(addr_reg[4:2] == 3'd4)
data_buf <= {quadA, quadB, quadZ, din};
end
end
// the addr_reg test looks funny because it is auto-incremented in an always
// block so "1" reads the low byte, "2 and "3" read middle bytes, and "0"
// reads the high byte I have a feeling that I'm doing this in the wrong way.
wire [7:0] data_reg = addr_reg[1:0] == 2'd1 ? data_buf[7:0] :
(addr_reg[1:0] == 2'd2 ? data_buf[15:8] :
(addr_reg[1:0] == 2'd3 ? data_buf[23:16] :
data_buf[31:24]));
wire [7:0] EPP_data_mux = data_reg;
assign EPP_dataout = (EPP_read & EPP_wait) ? EPP_data_mux : 8'hZZ;
assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
assign qr0 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd0);
assign qr1 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd1);
assign qr2 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd2);
assign qr3 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd3);
assign led = do_tristate ? 1'BZ : (real_up[0] ^ real_down[0]);
assign nConfig = epp_nReset; // 1'b1;
endmodule
|
// This is a component of pluto_servo, a PWM servo driver and quadrature
// counter for emc2
// Copyright 2006 Jeff Epler <[email protected]>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
module pluto_servo(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, quadA, quadB, quadZ, up, down);
parameter QW=14;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
wire do_tristate;
reg[9:0] real_dout; output [9:0] dout = do_tristate ? 10'bZZZZZZZZZZ : real_dout;
input [7:0] din;
input [3:0] quadA;
input [3:0] quadB;
input [3:0] quadZ;
wire[3:0] real_up; output [3:0] up = do_tristate ? 4'bZZZZ : real_up;
wire[3:0] real_down; output [3:0] down = do_tristate ? 4'bZZZZ : real_down;
reg Zpolarity;
wire [2*QW:0] quad0, quad1, quad2, quad3;
wire do_enable_wdt;
wire pwm_at_top;
wdt w(clk, do_enable_wdt, pwm_at_top, do_tristate);
// PWM stuff
// PWM clock is about 20kHz for clk @ 40MHz, 11-bit cnt
reg [10:0] pwmcnt;
wire [10:0] top = 11'd2046;
assign pwm_at_top = (pwmcnt == top);
reg [15:0] pwm0, pwm1, pwm2, pwm3;
always @(posedge clk) begin
if(pwm_at_top) pwmcnt <= 0;
else pwmcnt <= pwmcnt + 11'd1;
end
wire [10:0] pwmrev = {
pwmcnt[4], pwmcnt[5], pwmcnt[6], pwmcnt[7], pwmcnt[8], pwmcnt[9],
pwmcnt[10], pwmcnt[3:0]};
wire [10:0] pwmcmp0 = pwm0[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp1 = pwm1[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp2 = pwm2[14] ? pwmrev : pwmcnt;
// wire [10:0] pwmcmp3 = pwm3[14] ? pwmrev : pwmcnt;
wire pwmact0 = pwm0[10:0] > pwmcmp0;
wire pwmact1 = pwm1[10:0] > pwmcmp0;
wire pwmact2 = pwm2[10:0] > pwmcmp0;
wire pwmact3 = pwm3[10:0] > pwmcmp0;
assign real_up[0] = pwm0[12] ^ (pwm0[15] ? 1'd0 : pwmact0);
assign real_up[1] = pwm1[12] ^ (pwm1[15] ? 1'd0 : pwmact1);
assign real_up[2] = pwm2[12] ^ (pwm2[15] ? 1'd0 : pwmact2);
assign real_up[3] = pwm3[12] ^ (pwm3[15] ? 1'd0 : pwmact3);
assign real_down[0] = pwm0[13] ^ (~pwm0[15] ? 1'd0 : pwmact0);
assign real_down[1] = pwm1[13] ^ (~pwm1[15] ? 1'd0 : pwmact1);
assign real_down[2] = pwm2[13] ^ (~pwm2[15] ? 1'd0 : pwmact2);
assign real_down[3] = pwm3[13] ^ (~pwm3[15] ? 1'd0 : pwmact3);
// Quadrature stuff
// Quadrature is digitized at 40MHz into 14-bit counters
// Read up to 2^13 pulses / polling period = 8MHz for 1kHz servo period
reg qtest;
wire qr0, qr1, qr2, qr3;
quad q0(clk, qtest ? real_dout[0] : quadA[0], qtest ? real_dout[1] : quadB[0], qtest ? real_dout[2] : quadZ[0]^Zpolarity, qr0, quad0);
quad q1(clk, quadA[1], quadB[1], quadZ[1]^Zpolarity, qr1, quad1);
quad q2(clk, quadA[2], quadB[2], quadZ[2]^Zpolarity, qr2, quad2);
quad q3(clk, quadA[3], quadB[3], quadZ[3]^Zpolarity, qr3, quad3);
// EPP stuff
wire EPP_write = ~nWrite;
wire EPP_read = nWrite;
wire EPP_addr_strobe = ~nAddrStr;
wire EPP_data_strobe = ~nDataStr;
wire EPP_strobe = EPP_data_strobe | EPP_addr_strobe;
wire EPP_wait; assign nWait = ~EPP_wait;
wire [7:0] EPP_datain = pport_data;
wire [7:0] EPP_dataout; assign pport_data = EPP_dataout;
reg [4:0] EPP_strobe_reg;
always @(posedge clk) EPP_strobe_reg <= {EPP_strobe_reg[3:0], EPP_strobe};
wire EPP_strobe_edge1 = (EPP_strobe_reg[2:1]==2'b01);
// reg led;
assign EPP_wait = EPP_strobe_reg[4];
reg[4:0] addr_reg;
reg[7:0] lowbyte;
always @(posedge clk)
if(EPP_strobe_edge1 & EPP_write & EPP_addr_strobe) begin
addr_reg <= EPP_datain[4:0];
end
else if(EPP_strobe_edge1 & !EPP_addr_strobe) addr_reg <= addr_reg + 4'd1;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_write & EPP_data_strobe) begin
if(addr_reg[3:0] == 4'd1) pwm0 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd3) pwm1 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd5) pwm2 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd7) pwm3 <= { EPP_datain, lowbyte };
else if(addr_reg[3:0] == 4'd9) begin
real_dout <= { EPP_datain[1:0], lowbyte };
Zpolarity <= EPP_datain[7];
qtest <= EPP_datain[5];
end
else lowbyte <= EPP_datain;
end
end
reg [31:0] data_buf;
always @(posedge clk) begin
if(EPP_strobe_edge1 & EPP_read && addr_reg[1:0] == 2'd0) begin
if(addr_reg[4:2] == 3'd0) data_buf <= quad0;
else if(addr_reg[4:2] == 3'd1) data_buf <= quad1;
else if(addr_reg[4:2] == 3'd2) data_buf <= quad2;
else if(addr_reg[4:2] == 3'd3) data_buf <= quad3;
else if(addr_reg[4:2] == 3'd4)
data_buf <= {quadA, quadB, quadZ, din};
end
end
// the addr_reg test looks funny because it is auto-incremented in an always
// block so "1" reads the low byte, "2 and "3" read middle bytes, and "0"
// reads the high byte I have a feeling that I'm doing this in the wrong way.
wire [7:0] data_reg = addr_reg[1:0] == 2'd1 ? data_buf[7:0] :
(addr_reg[1:0] == 2'd2 ? data_buf[15:8] :
(addr_reg[1:0] == 2'd3 ? data_buf[23:16] :
data_buf[31:24]));
wire [7:0] EPP_data_mux = data_reg;
assign EPP_dataout = (EPP_read & EPP_wait) ? EPP_data_mux : 8'hZZ;
assign do_enable_wdt = EPP_strobe_edge1 & EPP_write & EPP_data_strobe & (addr_reg[3:0] == 4'd9) & EPP_datain[6];
assign qr0 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd0);
assign qr1 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd1);
assign qr2 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd2);
assign qr3 = EPP_strobe_edge1 & EPP_read & EPP_data_strobe & (addr_reg[4:2] == 3'd3);
assign led = do_tristate ? 1'BZ : (real_up[0] ^ real_down[0]);
assign nConfig = epp_nReset; // 1'b1;
endmodule
|
// This is a component of pluto_step, a hardware step waveform generator
// Copyright 2007 Jeff Epler <[email protected]>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
// install ubuntu package "verilog" from universe
// Compile with: iverilog -DTESTING test_stepgen.v stepgen.v
// run with "./a.out | less" and look at output for problems
module test_stepgen();
reg clk;
reg [4:0] vel;
wire [19:0] pos;
wire step, dir;
stepgen #(16,4,16) s(clk, 1, pos, vel, 1, 0, step, dir, 3);
integer q;
reg ost;
initial begin
vel = 5'h8; // two useful test cases:
// vel=5'h8 (max step speed)
// vel=5'h2 (~1 step per repeat)
q = 0;
repeat(50) begin
repeat(50) begin
#20 clk<=1;
#20 clk<=0;
if(step && !ost) begin
if(dir) q = q+1;
else q = q - 1;
end
ost <= step;
$display("%d %d %x %x %d %d %d %d %d",
step, dir, vel, pos, s.state, s.ones, s.pbit, s.timer, q);
end
vel = 6'h20 - vel;
end
end
endmodule
|
// This is a component of pluto_step, a hardware step waveform generator
// Copyright 2007 Jeff Epler <[email protected]>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
// install ubuntu package "verilog" from universe
// Compile with: iverilog -DTESTING test_stepgen.v stepgen.v
// run with "./a.out | less" and look at output for problems
module test_stepgen();
reg clk;
reg [4:0] vel;
wire [19:0] pos;
wire step, dir;
stepgen #(16,4,16) s(clk, 1, pos, vel, 1, 0, step, dir, 3);
integer q;
reg ost;
initial begin
vel = 5'h8; // two useful test cases:
// vel=5'h8 (max step speed)
// vel=5'h2 (~1 step per repeat)
q = 0;
repeat(50) begin
repeat(50) begin
#20 clk<=1;
#20 clk<=0;
if(step && !ost) begin
if(dir) q = q+1;
else q = q - 1;
end
ost <= step;
$display("%d %d %x %x %d %d %d %d %d",
step, dir, vel, pos, s.state, s.ones, s.pbit, s.timer, q);
end
vel = 6'h20 - vel;
end
end
endmodule
|
// This is a component of pluto_step, a hardware step waveform generator
// Copyright 2007 Jeff Epler <[email protected]>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
// install ubuntu package "verilog" from universe
// Compile with: iverilog -DTESTING test_stepgen.v stepgen.v
// run with "./a.out | less" and look at output for problems
module test_stepgen();
reg clk;
reg [4:0] vel;
wire [19:0] pos;
wire step, dir;
stepgen #(16,4,16) s(clk, 1, pos, vel, 1, 0, step, dir, 3);
integer q;
reg ost;
initial begin
vel = 5'h8; // two useful test cases:
// vel=5'h8 (max step speed)
// vel=5'h2 (~1 step per repeat)
q = 0;
repeat(50) begin
repeat(50) begin
#20 clk<=1;
#20 clk<=0;
if(step && !ost) begin
if(dir) q = q+1;
else q = q - 1;
end
ost <= step;
$display("%d %d %x %x %d %d %d %d %d",
step, dir, vel, pos, s.state, s.ones, s.pbit, s.timer, q);
end
vel = 6'h20 - vel;
end
end
endmodule
|
/*
*******************************************************************************
*
* FIFO Generator - Verilog Behavioral Model
*
*******************************************************************************
*
* (c) Copyright 1995 - 2009 Xilinx, Inc. All rights reserved.
*
* This file contains confidential and proprietary information
* of Xilinx, Inc. and is protected under U.S. and
* international copyright and other intellectual property
* laws.
*
* DISCLAIMER
* This disclaimer is not a license and does not grant any
* rights to the materials distributed herewith. Except as
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* law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
* WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
* AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
* BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
* INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
* (2) Xilinx shall not be liable (whether in contract or tort,
* including negligence, or under any other theory of
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* related to, arising under or in connection with these
* materials, including for any direct, or any indirect,
* special, incidental, or consequential loss or damage
* (including loss of data, profits, goodwill, or any type of
* loss or damage suffered as a result of any action brought
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* reasonably foreseeable or Xilinx had been advised of the
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* CRITICAL APPLICATIONS
* Xilinx products are not designed or intended to be fail-
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*
*******************************************************************************
*******************************************************************************
*
* Filename: fifo_generator_vlog_beh.v
*
* Author : Xilinx
*
*******************************************************************************
* Structure:
*
* fifo_generator_vlog_beh.v
* |
* +-fifo_generator_v13_1_3_bhv_ver_as
* |
* +-fifo_generator_v13_1_3_bhv_ver_ss
* |
* +-fifo_generator_v13_1_3_bhv_ver_preload0
*
*******************************************************************************
* Description:
*
* The Verilog behavioral model for the FIFO Generator.
*
* The behavioral model has three parts:
* - The behavioral model for independent clocks FIFOs (_as)
* - The behavioral model for common clock FIFOs (_ss)
* - The "preload logic" block which implements First-word Fall-through
*
*******************************************************************************
* Description:
* The verilog behavioral model for the FIFO generator core.
*
*******************************************************************************
*/
`timescale 1ps/1ps
`ifndef TCQ
`define TCQ 100
`endif
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "",
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 1,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "4kx4",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_PIPELINE_REG = 0,
parameter C_POWER_SAVING_MODE = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface, 1: AXI4 Stream, 2: AXI4/AXI3
parameter C_AXI_TYPE = 0, // 1: AXI4, 2: AXI4 Lite, 3: AXI3
parameter C_HAS_AXI_WR_CHANNEL = 0,
parameter C_HAS_AXI_RD_CHANNEL = 0,
parameter C_HAS_SLAVE_CE = 0,
parameter C_HAS_MASTER_CE = 0,
parameter C_ADD_NGC_CONSTRAINT = 0,
parameter C_USE_COMMON_UNDERFLOW = 0,
parameter C_USE_COMMON_OVERFLOW = 0,
parameter C_USE_DEFAULT_SETTINGS = 0,
// AXI Full/Lite
parameter C_AXI_ID_WIDTH = 0,
parameter C_AXI_ADDR_WIDTH = 0,
parameter C_AXI_DATA_WIDTH = 0,
parameter C_AXI_LEN_WIDTH = 8,
parameter C_AXI_LOCK_WIDTH = 2,
parameter C_HAS_AXI_ID = 0,
parameter C_HAS_AXI_AWUSER = 0,
parameter C_HAS_AXI_WUSER = 0,
parameter C_HAS_AXI_BUSER = 0,
parameter C_HAS_AXI_ARUSER = 0,
parameter C_HAS_AXI_RUSER = 0,
parameter C_AXI_ARUSER_WIDTH = 0,
parameter C_AXI_AWUSER_WIDTH = 0,
parameter C_AXI_WUSER_WIDTH = 0,
parameter C_AXI_BUSER_WIDTH = 0,
parameter C_AXI_RUSER_WIDTH = 0,
// AXI Streaming
parameter C_HAS_AXIS_TDATA = 0,
parameter C_HAS_AXIS_TID = 0,
parameter C_HAS_AXIS_TDEST = 0,
parameter C_HAS_AXIS_TUSER = 0,
parameter C_HAS_AXIS_TREADY = 0,
parameter C_HAS_AXIS_TLAST = 0,
parameter C_HAS_AXIS_TSTRB = 0,
parameter C_HAS_AXIS_TKEEP = 0,
parameter C_AXIS_TDATA_WIDTH = 1,
parameter C_AXIS_TID_WIDTH = 1,
parameter C_AXIS_TDEST_WIDTH = 1,
parameter C_AXIS_TUSER_WIDTH = 1,
parameter C_AXIS_TSTRB_WIDTH = 1,
parameter C_AXIS_TKEEP_WIDTH = 1,
// AXI Channel Type
// WACH --> Write Address Channel
// WDCH --> Write Data Channel
// WRCH --> Write Response Channel
// RACH --> Read Address Channel
// RDCH --> Read Data Channel
// AXIS --> AXI Streaming
parameter C_WACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logic
parameter C_WDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_WRCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_AXIS_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
// AXI Implementation Type
// 1 = Common Clock Block RAM FIFO
// 2 = Common Clock Distributed RAM FIFO
// 11 = Independent Clock Block RAM FIFO
// 12 = Independent Clock Distributed RAM FIFO
parameter C_IMPLEMENTATION_TYPE_WACH = 0,
parameter C_IMPLEMENTATION_TYPE_WDCH = 0,
parameter C_IMPLEMENTATION_TYPE_WRCH = 0,
parameter C_IMPLEMENTATION_TYPE_RACH = 0,
parameter C_IMPLEMENTATION_TYPE_RDCH = 0,
parameter C_IMPLEMENTATION_TYPE_AXIS = 0,
// AXI FIFO Type
// 0 = Data FIFO
// 1 = Packet FIFO
// 2 = Low Latency Sync FIFO
// 3 = Low Latency Async FIFO
parameter C_APPLICATION_TYPE_WACH = 0,
parameter C_APPLICATION_TYPE_WDCH = 0,
parameter C_APPLICATION_TYPE_WRCH = 0,
parameter C_APPLICATION_TYPE_RACH = 0,
parameter C_APPLICATION_TYPE_RDCH = 0,
parameter C_APPLICATION_TYPE_AXIS = 0,
// AXI Built-in FIFO Primitive Type
// 512x36, 1kx18, 2kx9, 4kx4, etc
parameter C_PRIM_FIFO_TYPE_WACH = "512x36",
parameter C_PRIM_FIFO_TYPE_WDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_WRCH = "512x36",
parameter C_PRIM_FIFO_TYPE_RACH = "512x36",
parameter C_PRIM_FIFO_TYPE_RDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_AXIS = "512x36",
// Enable ECC
// 0 = ECC disabled
// 1 = ECC enabled
parameter C_USE_ECC_WACH = 0,
parameter C_USE_ECC_WDCH = 0,
parameter C_USE_ECC_WRCH = 0,
parameter C_USE_ECC_RACH = 0,
parameter C_USE_ECC_RDCH = 0,
parameter C_USE_ECC_AXIS = 0,
// ECC Error Injection Type
// 0 = No Error Injection
// 1 = Single Bit Error Injection
// 2 = Double Bit Error Injection
// 3 = Single Bit and Double Bit Error Injection
parameter C_ERROR_INJECTION_TYPE_WACH = 0,
parameter C_ERROR_INJECTION_TYPE_WDCH = 0,
parameter C_ERROR_INJECTION_TYPE_WRCH = 0,
parameter C_ERROR_INJECTION_TYPE_RACH = 0,
parameter C_ERROR_INJECTION_TYPE_RDCH = 0,
parameter C_ERROR_INJECTION_TYPE_AXIS = 0,
// Input Data Width
// Accumulation of all AXI input signal's width
parameter C_DIN_WIDTH_WACH = 1,
parameter C_DIN_WIDTH_WDCH = 1,
parameter C_DIN_WIDTH_WRCH = 1,
parameter C_DIN_WIDTH_RACH = 1,
parameter C_DIN_WIDTH_RDCH = 1,
parameter C_DIN_WIDTH_AXIS = 1,
parameter C_WR_DEPTH_WACH = 16,
parameter C_WR_DEPTH_WDCH = 16,
parameter C_WR_DEPTH_WRCH = 16,
parameter C_WR_DEPTH_RACH = 16,
parameter C_WR_DEPTH_RDCH = 16,
parameter C_WR_DEPTH_AXIS = 16,
parameter C_WR_PNTR_WIDTH_WACH = 4,
parameter C_WR_PNTR_WIDTH_WDCH = 4,
parameter C_WR_PNTR_WIDTH_WRCH = 4,
parameter C_WR_PNTR_WIDTH_RACH = 4,
parameter C_WR_PNTR_WIDTH_RDCH = 4,
parameter C_WR_PNTR_WIDTH_AXIS = 4,
parameter C_HAS_DATA_COUNTS_WACH = 0,
parameter C_HAS_DATA_COUNTS_WDCH = 0,
parameter C_HAS_DATA_COUNTS_WRCH = 0,
parameter C_HAS_DATA_COUNTS_RACH = 0,
parameter C_HAS_DATA_COUNTS_RDCH = 0,
parameter C_HAS_DATA_COUNTS_AXIS = 0,
parameter C_HAS_PROG_FLAGS_WACH = 0,
parameter C_HAS_PROG_FLAGS_WDCH = 0,
parameter C_HAS_PROG_FLAGS_WRCH = 0,
parameter C_HAS_PROG_FLAGS_RACH = 0,
parameter C_HAS_PROG_FLAGS_RDCH = 0,
parameter C_HAS_PROG_FLAGS_AXIS = 0,
parameter C_PROG_FULL_TYPE_WACH = 0,
parameter C_PROG_FULL_TYPE_WDCH = 0,
parameter C_PROG_FULL_TYPE_WRCH = 0,
parameter C_PROG_FULL_TYPE_RACH = 0,
parameter C_PROG_FULL_TYPE_RDCH = 0,
parameter C_PROG_FULL_TYPE_AXIS = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_PROG_EMPTY_TYPE_WACH = 0,
parameter C_PROG_EMPTY_TYPE_WDCH = 0,
parameter C_PROG_EMPTY_TYPE_WRCH = 0,
parameter C_PROG_EMPTY_TYPE_RACH = 0,
parameter C_PROG_EMPTY_TYPE_RDCH = 0,
parameter C_PROG_EMPTY_TYPE_AXIS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_REG_SLICE_MODE_WACH = 0,
parameter C_REG_SLICE_MODE_WDCH = 0,
parameter C_REG_SLICE_MODE_WRCH = 0,
parameter C_REG_SLICE_MODE_RACH = 0,
parameter C_REG_SLICE_MODE_RDCH = 0,
parameter C_REG_SLICE_MODE_AXIS = 0
)
(
//------------------------------------------------------------------------------
// Input and Output Declarations
//------------------------------------------------------------------------------
// Conventional FIFO Interface Signals
input backup,
input backup_marker,
input clk,
input rst,
input srst,
input wr_clk,
input wr_rst,
input rd_clk,
input rd_rst,
input [C_DIN_WIDTH-1:0] din,
input wr_en,
input rd_en,
// Optional inputs
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate,
input int_clk,
input injectdbiterr,
input injectsbiterr,
input sleep,
output [C_DOUT_WIDTH-1:0] dout,
output full,
output almost_full,
output wr_ack,
output overflow,
output empty,
output almost_empty,
output valid,
output underflow,
output [C_DATA_COUNT_WIDTH-1:0] data_count,
output [C_RD_DATA_COUNT_WIDTH-1:0] rd_data_count,
output [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count,
output prog_full,
output prog_empty,
output sbiterr,
output dbiterr,
output wr_rst_busy,
output rd_rst_busy,
// AXI Global Signal
input m_aclk,
input s_aclk,
input s_aresetn,
input s_aclk_en,
input m_aclk_en,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_awlen,
input [3-1:0] s_axi_awsize,
input [2-1:0] s_axi_awburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_awlock,
input [4-1:0] s_axi_awcache,
input [3-1:0] s_axi_awprot,
input [4-1:0] s_axi_awqos,
input [4-1:0] s_axi_awregion,
input [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser,
input s_axi_awvalid,
output s_axi_awready,
input [C_AXI_ID_WIDTH-1:0] s_axi_wid,
input [C_AXI_DATA_WIDTH-1:0] s_axi_wdata,
input [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb,
input s_axi_wlast,
input [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [2-1:0] s_axi_bresp,
output [C_AXI_BUSER_WIDTH-1:0] s_axi_buser,
output s_axi_bvalid,
input s_axi_bready,
// AXI Full/Lite Master Write Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_awlen,
output [3-1:0] m_axi_awsize,
output [2-1:0] m_axi_awburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_awlock,
output [4-1:0] m_axi_awcache,
output [3-1:0] m_axi_awprot,
output [4-1:0] m_axi_awqos,
output [4-1:0] m_axi_awregion,
output [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
output m_axi_awvalid,
input m_axi_awready,
output [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output m_axi_wlast,
output [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
output m_axi_wvalid,
input m_axi_wready,
input [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input [2-1:0] m_axi_bresp,
input [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
input m_axi_bvalid,
output m_axi_bready,
// AXI Full/Lite Slave Read Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_arlen,
input [3-1:0] s_axi_arsize,
input [2-1:0] s_axi_arburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_arlock,
input [4-1:0] s_axi_arcache,
input [3-1:0] s_axi_arprot,
input [4-1:0] s_axi_arqos,
input [4-1:0] s_axi_arregion,
input [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_AXI_DATA_WIDTH-1:0] s_axi_rdata,
output [2-1:0] s_axi_rresp,
output s_axi_rlast,
output [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser,
output s_axi_rvalid,
input s_axi_rready,
// AXI Full/Lite Master Read Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_arlen,
output [3-1:0] m_axi_arsize,
output [2-1:0] m_axi_arburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_arlock,
output [4-1:0] m_axi_arcache,
output [3-1:0] m_axi_arprot,
output [4-1:0] m_axi_arqos,
output [4-1:0] m_axi_arregion,
output [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
output m_axi_arvalid,
input m_axi_arready,
input [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input [2-1:0] m_axi_rresp,
input m_axi_rlast,
input [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
input m_axi_rvalid,
output m_axi_rready,
// AXI Streaming Slave Signals (Write side)
input s_axis_tvalid,
output s_axis_tready,
input [C_AXIS_TDATA_WIDTH-1:0] s_axis_tdata,
input [C_AXIS_TSTRB_WIDTH-1:0] s_axis_tstrb,
input [C_AXIS_TKEEP_WIDTH-1:0] s_axis_tkeep,
input s_axis_tlast,
input [C_AXIS_TID_WIDTH-1:0] s_axis_tid,
input [C_AXIS_TDEST_WIDTH-1:0] s_axis_tdest,
input [C_AXIS_TUSER_WIDTH-1:0] s_axis_tuser,
// AXI Streaming Master Signals (Read side)
output m_axis_tvalid,
input m_axis_tready,
output [C_AXIS_TDATA_WIDTH-1:0] m_axis_tdata,
output [C_AXIS_TSTRB_WIDTH-1:0] m_axis_tstrb,
output [C_AXIS_TKEEP_WIDTH-1:0] m_axis_tkeep,
output m_axis_tlast,
output [C_AXIS_TID_WIDTH-1:0] m_axis_tid,
output [C_AXIS_TDEST_WIDTH-1:0] m_axis_tdest,
output [C_AXIS_TUSER_WIDTH-1:0] m_axis_tuser,
// AXI Full/Lite Write Address Channel signals
input axi_aw_injectsbiterr,
input axi_aw_injectdbiterr,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_wr_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_rd_data_count,
output axi_aw_sbiterr,
output axi_aw_dbiterr,
output axi_aw_overflow,
output axi_aw_underflow,
output axi_aw_prog_full,
output axi_aw_prog_empty,
// AXI Full/Lite Write Data Channel signals
input axi_w_injectsbiterr,
input axi_w_injectdbiterr,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_wr_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_rd_data_count,
output axi_w_sbiterr,
output axi_w_dbiterr,
output axi_w_overflow,
output axi_w_underflow,
output axi_w_prog_full,
output axi_w_prog_empty,
// AXI Full/Lite Write Response Channel signals
input axi_b_injectsbiterr,
input axi_b_injectdbiterr,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_wr_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_rd_data_count,
output axi_b_sbiterr,
output axi_b_dbiterr,
output axi_b_overflow,
output axi_b_underflow,
output axi_b_prog_full,
output axi_b_prog_empty,
// AXI Full/Lite Read Address Channel signals
input axi_ar_injectsbiterr,
input axi_ar_injectdbiterr,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_wr_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_rd_data_count,
output axi_ar_sbiterr,
output axi_ar_dbiterr,
output axi_ar_overflow,
output axi_ar_underflow,
output axi_ar_prog_full,
output axi_ar_prog_empty,
// AXI Full/Lite Read Data Channel Signals
input axi_r_injectsbiterr,
input axi_r_injectdbiterr,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_wr_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_rd_data_count,
output axi_r_sbiterr,
output axi_r_dbiterr,
output axi_r_overflow,
output axi_r_underflow,
output axi_r_prog_full,
output axi_r_prog_empty,
// AXI Streaming FIFO Related Signals
input axis_injectsbiterr,
input axis_injectdbiterr,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_full_thresh,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_wr_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_rd_data_count,
output axis_sbiterr,
output axis_dbiterr,
output axis_overflow,
output axis_underflow,
output axis_prog_full,
output axis_prog_empty
);
wire BACKUP;
wire BACKUP_MARKER;
wire CLK;
wire RST;
wire SRST;
wire WR_CLK;
wire WR_RST;
wire RD_CLK;
wire RD_RST;
wire [C_DIN_WIDTH-1:0] DIN;
wire WR_EN;
wire RD_EN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire INT_CLK;
wire INJECTDBITERR;
wire INJECTSBITERR;
wire SLEEP;
wire [C_DOUT_WIDTH-1:0] DOUT;
wire FULL;
wire ALMOST_FULL;
wire WR_ACK;
wire OVERFLOW;
wire EMPTY;
wire ALMOST_EMPTY;
wire VALID;
wire UNDERFLOW;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT;
wire PROG_FULL;
wire PROG_EMPTY;
wire SBITERR;
wire DBITERR;
wire WR_RST_BUSY;
wire RD_RST_BUSY;
wire M_ACLK;
wire S_ACLK;
wire S_ARESETN;
wire S_ACLK_EN;
wire M_ACLK_EN;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_AWLEN;
wire [3-1:0] S_AXI_AWSIZE;
wire [2-1:0] S_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_AWLOCK;
wire [4-1:0] S_AXI_AWCACHE;
wire [3-1:0] S_AXI_AWPROT;
wire [4-1:0] S_AXI_AWQOS;
wire [4-1:0] S_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER;
wire S_AXI_AWVALID;
wire S_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB;
wire S_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER;
wire S_AXI_WVALID;
wire S_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [2-1:0] S_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER;
wire S_AXI_BVALID;
wire S_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_AWLEN;
wire [3-1:0] M_AXI_AWSIZE;
wire [2-1:0] M_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_AWLOCK;
wire [4-1:0] M_AXI_AWCACHE;
wire [3-1:0] M_AXI_AWPROT;
wire [4-1:0] M_AXI_AWQOS;
wire [4-1:0] M_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER;
wire M_AXI_AWVALID;
wire M_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB;
wire M_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER;
wire M_AXI_WVALID;
wire M_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID;
wire [2-1:0] M_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER;
wire M_AXI_BVALID;
wire M_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_ARLEN;
wire [3-1:0] S_AXI_ARSIZE;
wire [2-1:0] S_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_ARLOCK;
wire [4-1:0] S_AXI_ARCACHE;
wire [3-1:0] S_AXI_ARPROT;
wire [4-1:0] S_AXI_ARQOS;
wire [4-1:0] S_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER;
wire S_AXI_ARVALID;
wire S_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA;
wire [2-1:0] S_AXI_RRESP;
wire S_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER;
wire S_AXI_RVALID;
wire S_AXI_RREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_ARLEN;
wire [3-1:0] M_AXI_ARSIZE;
wire [2-1:0] M_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_ARLOCK;
wire [4-1:0] M_AXI_ARCACHE;
wire [3-1:0] M_AXI_ARPROT;
wire [4-1:0] M_AXI_ARQOS;
wire [4-1:0] M_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER;
wire M_AXI_ARVALID;
wire M_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA;
wire [2-1:0] M_AXI_RRESP;
wire M_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER;
wire M_AXI_RVALID;
wire M_AXI_RREADY;
wire S_AXIS_TVALID;
wire S_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] S_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] S_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] S_AXIS_TKEEP;
wire S_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] S_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] S_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] S_AXIS_TUSER;
wire M_AXIS_TVALID;
wire M_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] M_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] M_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] M_AXIS_TKEEP;
wire M_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] M_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] M_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] M_AXIS_TUSER;
wire AXI_AW_INJECTSBITERR;
wire AXI_AW_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_RD_DATA_COUNT;
wire AXI_AW_SBITERR;
wire AXI_AW_DBITERR;
wire AXI_AW_OVERFLOW;
wire AXI_AW_UNDERFLOW;
wire AXI_AW_PROG_FULL;
wire AXI_AW_PROG_EMPTY;
wire AXI_W_INJECTSBITERR;
wire AXI_W_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_RD_DATA_COUNT;
wire AXI_W_SBITERR;
wire AXI_W_DBITERR;
wire AXI_W_OVERFLOW;
wire AXI_W_UNDERFLOW;
wire AXI_W_PROG_FULL;
wire AXI_W_PROG_EMPTY;
wire AXI_B_INJECTSBITERR;
wire AXI_B_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_RD_DATA_COUNT;
wire AXI_B_SBITERR;
wire AXI_B_DBITERR;
wire AXI_B_OVERFLOW;
wire AXI_B_UNDERFLOW;
wire AXI_B_PROG_FULL;
wire AXI_B_PROG_EMPTY;
wire AXI_AR_INJECTSBITERR;
wire AXI_AR_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_RD_DATA_COUNT;
wire AXI_AR_SBITERR;
wire AXI_AR_DBITERR;
wire AXI_AR_OVERFLOW;
wire AXI_AR_UNDERFLOW;
wire AXI_AR_PROG_FULL;
wire AXI_AR_PROG_EMPTY;
wire AXI_R_INJECTSBITERR;
wire AXI_R_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_RD_DATA_COUNT;
wire AXI_R_SBITERR;
wire AXI_R_DBITERR;
wire AXI_R_OVERFLOW;
wire AXI_R_UNDERFLOW;
wire AXI_R_PROG_FULL;
wire AXI_R_PROG_EMPTY;
wire AXIS_INJECTSBITERR;
wire AXIS_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_RD_DATA_COUNT;
wire AXIS_SBITERR;
wire AXIS_DBITERR;
wire AXIS_OVERFLOW;
wire AXIS_UNDERFLOW;
wire AXIS_PROG_FULL;
wire AXIS_PROG_EMPTY;
wire [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count_in;
wire wr_rst_int;
wire rd_rst_int;
wire wr_rst_busy_o;
wire wr_rst_busy_ntve;
wire wr_rst_busy_axis;
wire wr_rst_busy_wach;
wire wr_rst_busy_wdch;
wire wr_rst_busy_wrch;
wire wr_rst_busy_rach;
wire wr_rst_busy_rdch;
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// Conventional FIFO Interface Signals
assign BACKUP = backup;
assign BACKUP_MARKER = backup_marker;
assign CLK = clk;
assign RST = rst;
assign SRST = srst;
assign WR_CLK = wr_clk;
assign WR_RST = wr_rst;
assign RD_CLK = rd_clk;
assign RD_RST = rd_rst;
assign WR_EN = wr_en;
assign RD_EN = rd_en;
assign INT_CLK = int_clk;
assign INJECTDBITERR = injectdbiterr;
assign INJECTSBITERR = injectsbiterr;
assign SLEEP = sleep;
assign full = FULL;
assign almost_full = ALMOST_FULL;
assign wr_ack = WR_ACK;
assign overflow = OVERFLOW;
assign empty = EMPTY;
assign almost_empty = ALMOST_EMPTY;
assign valid = VALID;
assign underflow = UNDERFLOW;
assign prog_full = PROG_FULL;
assign prog_empty = PROG_EMPTY;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
// assign wr_rst_busy = WR_RST_BUSY | wr_rst_busy_o;
assign wr_rst_busy = wr_rst_busy_o;
assign rd_rst_busy = RD_RST_BUSY;
assign M_ACLK = m_aclk;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_ACLK_EN = s_aclk_en;
assign M_ACLK_EN = m_aclk_en;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign m_axi_awvalid = M_AXI_AWVALID;
assign M_AXI_AWREADY = m_axi_awready;
assign m_axi_wlast = M_AXI_WLAST;
assign m_axi_wvalid = M_AXI_WVALID;
assign M_AXI_WREADY = m_axi_wready;
assign M_AXI_BVALID = m_axi_bvalid;
assign m_axi_bready = M_AXI_BREADY;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign m_axi_arvalid = M_AXI_ARVALID;
assign M_AXI_ARREADY = m_axi_arready;
assign M_AXI_RLAST = m_axi_rlast;
assign M_AXI_RVALID = m_axi_rvalid;
assign m_axi_rready = M_AXI_RREADY;
assign S_AXIS_TVALID = s_axis_tvalid;
assign s_axis_tready = S_AXIS_TREADY;
assign S_AXIS_TLAST = s_axis_tlast;
assign m_axis_tvalid = M_AXIS_TVALID;
assign M_AXIS_TREADY = m_axis_tready;
assign m_axis_tlast = M_AXIS_TLAST;
assign AXI_AW_INJECTSBITERR = axi_aw_injectsbiterr;
assign AXI_AW_INJECTDBITERR = axi_aw_injectdbiterr;
assign axi_aw_sbiterr = AXI_AW_SBITERR;
assign axi_aw_dbiterr = AXI_AW_DBITERR;
assign axi_aw_overflow = AXI_AW_OVERFLOW;
assign axi_aw_underflow = AXI_AW_UNDERFLOW;
assign axi_aw_prog_full = AXI_AW_PROG_FULL;
assign axi_aw_prog_empty = AXI_AW_PROG_EMPTY;
assign AXI_W_INJECTSBITERR = axi_w_injectsbiterr;
assign AXI_W_INJECTDBITERR = axi_w_injectdbiterr;
assign axi_w_sbiterr = AXI_W_SBITERR;
assign axi_w_dbiterr = AXI_W_DBITERR;
assign axi_w_overflow = AXI_W_OVERFLOW;
assign axi_w_underflow = AXI_W_UNDERFLOW;
assign axi_w_prog_full = AXI_W_PROG_FULL;
assign axi_w_prog_empty = AXI_W_PROG_EMPTY;
assign AXI_B_INJECTSBITERR = axi_b_injectsbiterr;
assign AXI_B_INJECTDBITERR = axi_b_injectdbiterr;
assign axi_b_sbiterr = AXI_B_SBITERR;
assign axi_b_dbiterr = AXI_B_DBITERR;
assign axi_b_overflow = AXI_B_OVERFLOW;
assign axi_b_underflow = AXI_B_UNDERFLOW;
assign axi_b_prog_full = AXI_B_PROG_FULL;
assign axi_b_prog_empty = AXI_B_PROG_EMPTY;
assign AXI_AR_INJECTSBITERR = axi_ar_injectsbiterr;
assign AXI_AR_INJECTDBITERR = axi_ar_injectdbiterr;
assign axi_ar_sbiterr = AXI_AR_SBITERR;
assign axi_ar_dbiterr = AXI_AR_DBITERR;
assign axi_ar_overflow = AXI_AR_OVERFLOW;
assign axi_ar_underflow = AXI_AR_UNDERFLOW;
assign axi_ar_prog_full = AXI_AR_PROG_FULL;
assign axi_ar_prog_empty = AXI_AR_PROG_EMPTY;
assign AXI_R_INJECTSBITERR = axi_r_injectsbiterr;
assign AXI_R_INJECTDBITERR = axi_r_injectdbiterr;
assign axi_r_sbiterr = AXI_R_SBITERR;
assign axi_r_dbiterr = AXI_R_DBITERR;
assign axi_r_overflow = AXI_R_OVERFLOW;
assign axi_r_underflow = AXI_R_UNDERFLOW;
assign axi_r_prog_full = AXI_R_PROG_FULL;
assign axi_r_prog_empty = AXI_R_PROG_EMPTY;
assign AXIS_INJECTSBITERR = axis_injectsbiterr;
assign AXIS_INJECTDBITERR = axis_injectdbiterr;
assign axis_sbiterr = AXIS_SBITERR;
assign axis_dbiterr = AXIS_DBITERR;
assign axis_overflow = AXIS_OVERFLOW;
assign axis_underflow = AXIS_UNDERFLOW;
assign axis_prog_full = AXIS_PROG_FULL;
assign axis_prog_empty = AXIS_PROG_EMPTY;
assign DIN = din;
assign PROG_EMPTY_THRESH = prog_empty_thresh;
assign PROG_EMPTY_THRESH_ASSERT = prog_empty_thresh_assert;
assign PROG_EMPTY_THRESH_NEGATE = prog_empty_thresh_negate;
assign PROG_FULL_THRESH = prog_full_thresh;
assign PROG_FULL_THRESH_ASSERT = prog_full_thresh_assert;
assign PROG_FULL_THRESH_NEGATE = prog_full_thresh_negate;
assign dout = DOUT;
assign data_count = DATA_COUNT;
assign rd_data_count = RD_DATA_COUNT;
assign wr_data_count = WR_DATA_COUNT;
assign S_AXI_AWID = s_axi_awid;
assign S_AXI_AWADDR = s_axi_awaddr;
assign S_AXI_AWLEN = s_axi_awlen;
assign S_AXI_AWSIZE = s_axi_awsize;
assign S_AXI_AWBURST = s_axi_awburst;
assign S_AXI_AWLOCK = s_axi_awlock;
assign S_AXI_AWCACHE = s_axi_awcache;
assign S_AXI_AWPROT = s_axi_awprot;
assign S_AXI_AWQOS = s_axi_awqos;
assign S_AXI_AWREGION = s_axi_awregion;
assign S_AXI_AWUSER = s_axi_awuser;
assign S_AXI_WID = s_axi_wid;
assign S_AXI_WDATA = s_axi_wdata;
assign S_AXI_WSTRB = s_axi_wstrb;
assign S_AXI_WUSER = s_axi_wuser;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_buser = S_AXI_BUSER;
assign m_axi_awid = M_AXI_AWID;
assign m_axi_awaddr = M_AXI_AWADDR;
assign m_axi_awlen = M_AXI_AWLEN;
assign m_axi_awsize = M_AXI_AWSIZE;
assign m_axi_awburst = M_AXI_AWBURST;
assign m_axi_awlock = M_AXI_AWLOCK;
assign m_axi_awcache = M_AXI_AWCACHE;
assign m_axi_awprot = M_AXI_AWPROT;
assign m_axi_awqos = M_AXI_AWQOS;
assign m_axi_awregion = M_AXI_AWREGION;
assign m_axi_awuser = M_AXI_AWUSER;
assign m_axi_wid = M_AXI_WID;
assign m_axi_wdata = M_AXI_WDATA;
assign m_axi_wstrb = M_AXI_WSTRB;
assign m_axi_wuser = M_AXI_WUSER;
assign M_AXI_BID = m_axi_bid;
assign M_AXI_BRESP = m_axi_bresp;
assign M_AXI_BUSER = m_axi_buser;
assign S_AXI_ARID = s_axi_arid;
assign S_AXI_ARADDR = s_axi_araddr;
assign S_AXI_ARLEN = s_axi_arlen;
assign S_AXI_ARSIZE = s_axi_arsize;
assign S_AXI_ARBURST = s_axi_arburst;
assign S_AXI_ARLOCK = s_axi_arlock;
assign S_AXI_ARCACHE = s_axi_arcache;
assign S_AXI_ARPROT = s_axi_arprot;
assign S_AXI_ARQOS = s_axi_arqos;
assign S_AXI_ARREGION = s_axi_arregion;
assign S_AXI_ARUSER = s_axi_aruser;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_ruser = S_AXI_RUSER;
assign m_axi_arid = M_AXI_ARID;
assign m_axi_araddr = M_AXI_ARADDR;
assign m_axi_arlen = M_AXI_ARLEN;
assign m_axi_arsize = M_AXI_ARSIZE;
assign m_axi_arburst = M_AXI_ARBURST;
assign m_axi_arlock = M_AXI_ARLOCK;
assign m_axi_arcache = M_AXI_ARCACHE;
assign m_axi_arprot = M_AXI_ARPROT;
assign m_axi_arqos = M_AXI_ARQOS;
assign m_axi_arregion = M_AXI_ARREGION;
assign m_axi_aruser = M_AXI_ARUSER;
assign M_AXI_RID = m_axi_rid;
assign M_AXI_RDATA = m_axi_rdata;
assign M_AXI_RRESP = m_axi_rresp;
assign M_AXI_RUSER = m_axi_ruser;
assign S_AXIS_TDATA = s_axis_tdata;
assign S_AXIS_TSTRB = s_axis_tstrb;
assign S_AXIS_TKEEP = s_axis_tkeep;
assign S_AXIS_TID = s_axis_tid;
assign S_AXIS_TDEST = s_axis_tdest;
assign S_AXIS_TUSER = s_axis_tuser;
assign m_axis_tdata = M_AXIS_TDATA;
assign m_axis_tstrb = M_AXIS_TSTRB;
assign m_axis_tkeep = M_AXIS_TKEEP;
assign m_axis_tid = M_AXIS_TID;
assign m_axis_tdest = M_AXIS_TDEST;
assign m_axis_tuser = M_AXIS_TUSER;
assign AXI_AW_PROG_FULL_THRESH = axi_aw_prog_full_thresh;
assign AXI_AW_PROG_EMPTY_THRESH = axi_aw_prog_empty_thresh;
assign axi_aw_data_count = AXI_AW_DATA_COUNT;
assign axi_aw_wr_data_count = AXI_AW_WR_DATA_COUNT;
assign axi_aw_rd_data_count = AXI_AW_RD_DATA_COUNT;
assign AXI_W_PROG_FULL_THRESH = axi_w_prog_full_thresh;
assign AXI_W_PROG_EMPTY_THRESH = axi_w_prog_empty_thresh;
assign axi_w_data_count = AXI_W_DATA_COUNT;
assign axi_w_wr_data_count = AXI_W_WR_DATA_COUNT;
assign axi_w_rd_data_count = AXI_W_RD_DATA_COUNT;
assign AXI_B_PROG_FULL_THRESH = axi_b_prog_full_thresh;
assign AXI_B_PROG_EMPTY_THRESH = axi_b_prog_empty_thresh;
assign axi_b_data_count = AXI_B_DATA_COUNT;
assign axi_b_wr_data_count = AXI_B_WR_DATA_COUNT;
assign axi_b_rd_data_count = AXI_B_RD_DATA_COUNT;
assign AXI_AR_PROG_FULL_THRESH = axi_ar_prog_full_thresh;
assign AXI_AR_PROG_EMPTY_THRESH = axi_ar_prog_empty_thresh;
assign axi_ar_data_count = AXI_AR_DATA_COUNT;
assign axi_ar_wr_data_count = AXI_AR_WR_DATA_COUNT;
assign axi_ar_rd_data_count = AXI_AR_RD_DATA_COUNT;
assign AXI_R_PROG_FULL_THRESH = axi_r_prog_full_thresh;
assign AXI_R_PROG_EMPTY_THRESH = axi_r_prog_empty_thresh;
assign axi_r_data_count = AXI_R_DATA_COUNT;
assign axi_r_wr_data_count = AXI_R_WR_DATA_COUNT;
assign axi_r_rd_data_count = AXI_R_RD_DATA_COUNT;
assign AXIS_PROG_FULL_THRESH = axis_prog_full_thresh;
assign AXIS_PROG_EMPTY_THRESH = axis_prog_empty_thresh;
assign axis_data_count = AXIS_DATA_COUNT;
assign axis_wr_data_count = AXIS_WR_DATA_COUNT;
assign axis_rd_data_count = AXIS_RD_DATA_COUNT;
generate if (C_INTERFACE_TYPE == 0) begin : conv_fifo
fifo_generator_v13_1_3_CONV_VER
#(
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_USE_DOUT_RST == 1 ? C_DOUT_RST_VAL : 0),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_FAMILY (C_FAMILY),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RD_RST (C_HAS_RD_RST),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_HAS_WR_RST (C_HAS_WR_RST),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_FREQ (C_RD_FREQ),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE)
)
fifo_generator_v13_1_3_conv_dut
(
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.CLK (CLK),
.RST (RST),
.SRST (SRST),
.WR_CLK (WR_CLK),
.WR_RST (WR_RST),
.RD_CLK (RD_CLK),
.RD_RST (RD_RST),
.DIN (DIN),
.WR_EN (WR_EN),
.RD_EN (RD_EN),
.PROG_EMPTY_THRESH (PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT (PROG_EMPTY_THRESH_ASSERT),
.PROG_EMPTY_THRESH_NEGATE (PROG_EMPTY_THRESH_NEGATE),
.PROG_FULL_THRESH (PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT (PROG_FULL_THRESH_ASSERT),
.PROG_FULL_THRESH_NEGATE (PROG_FULL_THRESH_NEGATE),
.INT_CLK (INT_CLK),
.INJECTDBITERR (INJECTDBITERR),
.INJECTSBITERR (INJECTSBITERR),
.DOUT (DOUT),
.FULL (FULL),
.ALMOST_FULL (ALMOST_FULL),
.WR_ACK (WR_ACK),
.OVERFLOW (OVERFLOW),
.EMPTY (EMPTY),
.ALMOST_EMPTY (ALMOST_EMPTY),
.VALID (VALID),
.UNDERFLOW (UNDERFLOW),
.DATA_COUNT (DATA_COUNT),
.RD_DATA_COUNT (RD_DATA_COUNT),
.WR_DATA_COUNT (wr_data_count_in),
.PROG_FULL (PROG_FULL),
.PROG_EMPTY (PROG_EMPTY),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.wr_rst_busy_o (wr_rst_busy_o),
.wr_rst_busy (wr_rst_busy_i),
.rd_rst_busy (rd_rst_busy),
.wr_rst_i_out (wr_rst_int),
.rd_rst_i_out (rd_rst_int)
);
end endgenerate
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_AXI_SIZE_WIDTH = 3;
localparam C_AXI_BURST_WIDTH = 2;
localparam C_AXI_CACHE_WIDTH = 4;
localparam C_AXI_PROT_WIDTH = 3;
localparam C_AXI_QOS_WIDTH = 4;
localparam C_AXI_REGION_WIDTH = 4;
localparam C_AXI_BRESP_WIDTH = 2;
localparam C_AXI_RRESP_WIDTH = 2;
localparam IS_AXI_STREAMING = C_INTERFACE_TYPE == 1 ? 1 : 0;
localparam TDATA_OFFSET = C_HAS_AXIS_TDATA == 1 ? C_DIN_WIDTH_AXIS-C_AXIS_TDATA_WIDTH : C_DIN_WIDTH_AXIS;
localparam TSTRB_OFFSET = C_HAS_AXIS_TSTRB == 1 ? TDATA_OFFSET-C_AXIS_TSTRB_WIDTH : TDATA_OFFSET;
localparam TKEEP_OFFSET = C_HAS_AXIS_TKEEP == 1 ? TSTRB_OFFSET-C_AXIS_TKEEP_WIDTH : TSTRB_OFFSET;
localparam TID_OFFSET = C_HAS_AXIS_TID == 1 ? TKEEP_OFFSET-C_AXIS_TID_WIDTH : TKEEP_OFFSET;
localparam TDEST_OFFSET = C_HAS_AXIS_TDEST == 1 ? TID_OFFSET-C_AXIS_TDEST_WIDTH : TID_OFFSET;
localparam TUSER_OFFSET = C_HAS_AXIS_TUSER == 1 ? TDEST_OFFSET-C_AXIS_TUSER_WIDTH : TDEST_OFFSET;
localparam LOG_DEPTH_AXIS = find_log2(C_WR_DEPTH_AXIS);
localparam LOG_WR_DEPTH = find_log2(C_WR_DEPTH);
function [LOG_DEPTH_AXIS-1:0] bin2gray;
input [LOG_DEPTH_AXIS-1:0] x;
begin
bin2gray = x ^ (x>>1);
end
endfunction
function [LOG_DEPTH_AXIS-1:0] gray2bin;
input [LOG_DEPTH_AXIS-1:0] x;
integer i;
begin
gray2bin[LOG_DEPTH_AXIS-1] = x[LOG_DEPTH_AXIS-1];
for(i=LOG_DEPTH_AXIS-2; i>=0; i=i-1) begin
gray2bin[i] = gray2bin[i+1] ^ x[i];
end
end
endfunction
wire [(LOG_WR_DEPTH)-1 : 0] w_cnt_gc_asreg_last;
wire [LOG_WR_DEPTH-1 : 0] w_q [0:C_SYNCHRONIZER_STAGE] ;
wire [LOG_WR_DEPTH-1 : 0] w_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_rd = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_gc = 0;
reg [LOG_WR_DEPTH-1 : 0] r_cnt = 0;
wire [LOG_WR_DEPTH : 0] adj_w_cnt_rd_pad;
wire [LOG_WR_DEPTH : 0] r_inv_pad;
wire [LOG_WR_DEPTH-1 : 0] d_cnt;
reg [LOG_WR_DEPTH : 0] d_cnt_pad = 0;
reg adj_w_cnt_rd_pad_0 = 0;
reg r_inv_pad_0 = 0;
genvar l;
generate for (l = 1; ((l <= C_SYNCHRONIZER_STAGE) && (C_HAS_DATA_COUNTS_AXIS == 3 && C_INTERFACE_TYPE == 0) ); l = l + 1) begin : g_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_WR_DEPTH)
)
rd_stg_inst
(
.RST (rd_rst_int),
.CLK (RD_CLK),
.DIN (w_q[l-1]),
.DOUT (w_q[l])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS == 3) begin : fifo_ic_adapter
assign wr_eop_ad = WR_EN & !(FULL);
assign rd_eop_ad = RD_EN & !(EMPTY);
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt <= 1'b0;
else if (wr_eop_ad)
w_cnt <= w_cnt + 1;
end
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt_gc <= 1'b0;
else
w_cnt_gc <= bin2gray(w_cnt);
end
assign w_q[0] = w_cnt_gc;
assign w_cnt_gc_asreg_last = w_q[C_SYNCHRONIZER_STAGE];
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
w_cnt_rd <= 1'b0;
else
w_cnt_rd <= gray2bin(w_cnt_gc_asreg_last);
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
r_cnt <= 1'b0;
else if (rd_eop_ad)
r_cnt <= r_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_w_cnt_rd_pad[LOG_WR_DEPTH : 1] = w_cnt_rd;
assign r_inv_pad[LOG_WR_DEPTH : 1] = ~r_cnt;
assign adj_w_cnt_rd_pad[0] = adj_w_cnt_rd_pad_0;
assign r_inv_pad[0] = r_inv_pad_0;
always @ ( rd_eop_ad )
begin
if (!rd_eop_ad) begin
adj_w_cnt_rd_pad_0 <= 1'b1;
r_inv_pad_0 <= 1'b1;
end else begin
adj_w_cnt_rd_pad_0 <= 1'b0;
r_inv_pad_0 <= 1'b0;
end
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
d_cnt_pad <= 1'b0;
else
d_cnt_pad <= adj_w_cnt_rd_pad + r_inv_pad ;
end
assign d_cnt = d_cnt_pad [LOG_WR_DEPTH : 1] ;
assign WR_DATA_COUNT = d_cnt;
end endgenerate // fifo_ic_adapter
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS != 3) begin : fifo_icn_adapter
assign WR_DATA_COUNT = wr_data_count_in;
end endgenerate // fifo_icn_adapter
wire inverted_reset = ~S_ARESETN;
wire axi_rs_rst;
wire [C_DIN_WIDTH_AXIS-1:0] axis_din ;
wire [C_DIN_WIDTH_AXIS-1:0] axis_dout ;
wire axis_full ;
wire axis_almost_full ;
wire axis_empty ;
wire axis_s_axis_tready;
wire axis_m_axis_tvalid;
wire axis_wr_en ;
wire axis_rd_en ;
wire axis_we ;
wire axis_re ;
wire [C_WR_PNTR_WIDTH_AXIS:0] axis_dc;
reg axis_pkt_read = 1'b0;
wire axis_rd_rst;
wire axis_wr_rst;
generate if (C_INTERFACE_TYPE > 0 && (C_AXIS_TYPE == 1 || C_WACH_TYPE == 1 ||
C_WDCH_TYPE == 1 || C_WRCH_TYPE == 1 || C_RACH_TYPE == 1 || C_RDCH_TYPE == 1)) begin : gaxi_rs_rst
reg rst_d1 = 0 ;
reg rst_d2 = 0 ;
reg [3:0] axi_rst = 4'h0 ;
always @ (posedge inverted_reset or posedge S_ACLK) begin
if (inverted_reset) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
axi_rst <= 4'hf;
end else begin
rst_d1 <= #`TCQ 1'b0;
rst_d2 <= #`TCQ rst_d1;
axi_rst <= #`TCQ {axi_rst[2:0],1'b0};
end
end
assign axi_rs_rst = axi_rst[3];//rst_d2;
end endgenerate // gaxi_rs_rst
generate if (IS_AXI_STREAMING == 1 && C_AXIS_TYPE == 0) begin : axi_streaming
// Write protection when almost full or prog_full is high
assign axis_we = (C_PROG_FULL_TYPE_AXIS != 0) ? axis_s_axis_tready & S_AXIS_TVALID :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_s_axis_tready & S_AXIS_TVALID : S_AXIS_TVALID;
// Read protection when almost empty or prog_empty is high
assign axis_re = (C_PROG_EMPTY_TYPE_AXIS != 0) ? axis_m_axis_tvalid & M_AXIS_TREADY :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_m_axis_tvalid & M_AXIS_TREADY : M_AXIS_TREADY;
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? axis_we & S_ACLK_EN : axis_we;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? axis_re & M_ACLK_EN : axis_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_AXIS == 2 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_AXIS == 11 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_AXIS),
.C_WR_DEPTH (C_WR_DEPTH_AXIS),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_DOUT_WIDTH (C_DIN_WIDTH_AXIS),
.C_RD_DEPTH (C_WR_DEPTH_AXIS),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_AXIS),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_AXIS),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_AXIS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS),
.C_USE_ECC (C_USE_ECC_AXIS),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_AXIS),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (C_APPLICATION_TYPE_AXIS == 1 ? 1: 0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_FIFO_TYPE (C_APPLICATION_TYPE_AXIS == 1 ? 0: C_APPLICATION_TYPE_AXIS),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_axis_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (axis_wr_en),
.RD_EN (axis_rd_en),
.PROG_FULL_THRESH (AXIS_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH (AXIS_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.INJECTDBITERR (AXIS_INJECTDBITERR),
.INJECTSBITERR (AXIS_INJECTSBITERR),
.DIN (axis_din),
.DOUT (axis_dout),
.FULL (axis_full),
.EMPTY (axis_empty),
.ALMOST_FULL (axis_almost_full),
.PROG_FULL (AXIS_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXIS_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (AXIS_OVERFLOW),
.VALID (),
.UNDERFLOW (AXIS_UNDERFLOW),
.DATA_COUNT (axis_dc),
.RD_DATA_COUNT (AXIS_RD_DATA_COUNT),
.WR_DATA_COUNT (AXIS_WR_DATA_COUNT),
.SBITERR (AXIS_SBITERR),
.DBITERR (AXIS_DBITERR),
.wr_rst_busy (wr_rst_busy_axis),
.rd_rst_busy (rd_rst_busy_axis),
.wr_rst_i_out (axis_wr_rst),
.rd_rst_i_out (axis_rd_rst),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign axis_s_axis_tready = (IS_8SERIES == 0) ? ~axis_full : (C_IMPLEMENTATION_TYPE_AXIS == 5 || C_IMPLEMENTATION_TYPE_AXIS == 13) ? ~(axis_full | wr_rst_busy_axis) : ~axis_full;
assign axis_m_axis_tvalid = (C_APPLICATION_TYPE_AXIS != 1) ? ~axis_empty : ~axis_empty & axis_pkt_read;
assign S_AXIS_TREADY = axis_s_axis_tready;
assign M_AXIS_TVALID = axis_m_axis_tvalid;
end endgenerate // axi_streaming
wire axis_wr_eop;
reg axis_wr_eop_d1 = 1'b0;
wire axis_rd_eop;
integer axis_pkt_cnt;
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 1) begin : gaxis_pkt_fifo_cc
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (axis_pkt_cnt == 1) && ~axis_wr_eop_d1)
axis_pkt_read <= 1'b0;
else if ((axis_pkt_cnt > 0) || (axis_almost_full && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_wr_eop_d1 <= 1'b0;
else
axis_wr_eop_d1 <= axis_wr_eop;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_cnt <= 0;
else if (axis_wr_eop_d1 && ~axis_rd_eop)
axis_pkt_cnt <= axis_pkt_cnt + 1;
else if (axis_rd_eop && ~axis_wr_eop_d1)
axis_pkt_cnt <= axis_pkt_cnt - 1;
end
end endgenerate // gaxis_pkt_fifo_cc
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_gc = 0;
wire [(LOG_DEPTH_AXIS)-1 : 0] axis_wpkt_cnt_gc_asreg_last;
wire axis_rd_has_rst;
wire [0:C_SYNCHRONIZER_STAGE] axis_af_q ;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q [0:C_SYNCHRONIZER_STAGE] ;
wire [1:C_SYNCHRONIZER_STAGE] axis_af_q_temp = 0;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_rd = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_rpkt_cnt = 0;
wire [LOG_DEPTH_AXIS : 0] adj_axis_wpkt_cnt_rd_pad;
wire [LOG_DEPTH_AXIS : 0] rpkt_inv_pad;
wire [LOG_DEPTH_AXIS-1 : 0] diff_pkt_cnt;
reg [LOG_DEPTH_AXIS : 0] diff_pkt_cnt_pad = 0;
reg adj_axis_wpkt_cnt_rd_pad_0 = 0;
reg rpkt_inv_pad_0 = 0;
wire axis_af_rd ;
generate if (C_HAS_RST == 1) begin : rst_blk_has
assign axis_rd_has_rst = axis_rd_rst;
end endgenerate //rst_blk_has
generate if (C_HAS_RST == 0) begin :rst_blk_no
assign axis_rd_has_rst = 1'b0;
end endgenerate //rst_blk_no
genvar i;
generate for (i = 1; ((i <= C_SYNCHRONIZER_STAGE) && (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) ); i = i + 1) begin : gpkt_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_DEPTH_AXIS)
)
rd_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (wpkt_q[i-1]),
.DOUT (wpkt_q[i])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (1)
)
wr_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (axis_af_q[i-1]),
.DOUT (axis_af_q[i])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) begin : gaxis_pkt_fifo_ic
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (diff_pkt_cnt == 1))
axis_pkt_read <= 1'b0;
else if ((diff_pkt_cnt > 0) || (axis_af_rd && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt <= 1'b0;
else if (axis_wr_eop)
axis_wpkt_cnt <= axis_wpkt_cnt + 1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt_gc <= 1'b0;
else
axis_wpkt_cnt_gc <= bin2gray(axis_wpkt_cnt);
end
assign wpkt_q[0] = axis_wpkt_cnt_gc;
assign axis_wpkt_cnt_gc_asreg_last = wpkt_q[C_SYNCHRONIZER_STAGE];
assign axis_af_q[0] = axis_almost_full;
//assign axis_af_q[1:C_SYNCHRONIZER_STAGE] = axis_af_q_temp[1:C_SYNCHRONIZER_STAGE];
assign axis_af_rd = axis_af_q[C_SYNCHRONIZER_STAGE];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_wpkt_cnt_rd <= 1'b0;
else
axis_wpkt_cnt_rd <= gray2bin(axis_wpkt_cnt_gc_asreg_last);
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_rpkt_cnt <= 1'b0;
else if (axis_rd_eop)
axis_rpkt_cnt <= axis_rpkt_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_axis_wpkt_cnt_rd_pad[LOG_DEPTH_AXIS : 1] = axis_wpkt_cnt_rd;
assign rpkt_inv_pad[LOG_DEPTH_AXIS : 1] = ~axis_rpkt_cnt;
assign adj_axis_wpkt_cnt_rd_pad[0] = adj_axis_wpkt_cnt_rd_pad_0;
assign rpkt_inv_pad[0] = rpkt_inv_pad_0;
always @ ( axis_rd_eop )
begin
if (!axis_rd_eop) begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b1;
rpkt_inv_pad_0 <= 1'b1;
end else begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b0;
rpkt_inv_pad_0 <= 1'b0;
end
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
diff_pkt_cnt_pad <= 1'b0;
else
diff_pkt_cnt_pad <= adj_axis_wpkt_cnt_rd_pad + rpkt_inv_pad ;
end
assign diff_pkt_cnt = diff_pkt_cnt_pad [LOG_DEPTH_AXIS : 1] ;
end endgenerate // gaxis_pkt_fifo_ic
// Generate the accurate data count for axi stream packet fifo configuration
reg [C_WR_PNTR_WIDTH_AXIS:0] axis_dc_pkt_fifo = 0;
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 1 && C_APPLICATION_TYPE_AXIS == 1) begin : gdc_pkt
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_dc_pkt_fifo <= 0;
else if (axis_wr_en && (~axis_rd_en))
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo + 1;
else if (~axis_wr_en && axis_rd_en)
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo - 1;
end
assign AXIS_DATA_COUNT = axis_dc_pkt_fifo;
end endgenerate // gdc_pkt
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 0 && C_APPLICATION_TYPE_AXIS == 1) begin : gndc_pkt
assign AXIS_DATA_COUNT = 0;
end endgenerate // gndc_pkt
generate if (IS_AXI_STREAMING == 1 && C_APPLICATION_TYPE_AXIS != 1) begin : gdc
assign AXIS_DATA_COUNT = axis_dc;
end endgenerate // gdc
// Register Slice for Write Address Channel
generate if (C_AXIS_TYPE == 1) begin : gaxis_reg_slice
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? S_AXIS_TVALID & S_ACLK_EN : S_AXIS_TVALID;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? M_AXIS_TREADY & M_ACLK_EN : M_AXIS_TREADY;
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_AXIS),
.C_REG_CONFIG (C_REG_SLICE_MODE_AXIS)
)
axis_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (axis_din),
.S_VALID (axis_wr_en),
.S_READY (S_AXIS_TREADY),
// Master side
.M_PAYLOAD_DATA (axis_dout),
.M_VALID (M_AXIS_TVALID),
.M_READY (axis_rd_en)
);
end endgenerate // gaxis_reg_slice
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDATA == 1) begin : tdata
assign axis_din[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET] = S_AXIS_TDATA;
assign M_AXIS_TDATA = axis_dout[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TSTRB == 1) begin : tstrb
assign axis_din[TDATA_OFFSET-1:TSTRB_OFFSET] = S_AXIS_TSTRB;
assign M_AXIS_TSTRB = axis_dout[TDATA_OFFSET-1:TSTRB_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TKEEP == 1) begin : tkeep
assign axis_din[TSTRB_OFFSET-1:TKEEP_OFFSET] = S_AXIS_TKEEP;
assign M_AXIS_TKEEP = axis_dout[TSTRB_OFFSET-1:TKEEP_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TID == 1) begin : tid
assign axis_din[TKEEP_OFFSET-1:TID_OFFSET] = S_AXIS_TID;
assign M_AXIS_TID = axis_dout[TKEEP_OFFSET-1:TID_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDEST == 1) begin : tdest
assign axis_din[TID_OFFSET-1:TDEST_OFFSET] = S_AXIS_TDEST;
assign M_AXIS_TDEST = axis_dout[TID_OFFSET-1:TDEST_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TUSER == 1) begin : tuser
assign axis_din[TDEST_OFFSET-1:TUSER_OFFSET] = S_AXIS_TUSER;
assign M_AXIS_TUSER = axis_dout[TDEST_OFFSET-1:TUSER_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TLAST == 1) begin : tlast
assign axis_din[0] = S_AXIS_TLAST;
assign M_AXIS_TLAST = axis_dout[0];
end endgenerate
//###########################################################################
// AXI FULL Write Channel (axi_write_channel)
//###########################################################################
localparam IS_AXI_FULL = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE != 2)) ? 1 : 0;
localparam IS_AXI_LITE = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE == 2)) ? 1 : 0;
localparam IS_AXI_FULL_WACH = ((IS_AXI_FULL == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WDCH = ((IS_AXI_FULL == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WRCH = ((IS_AXI_FULL == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RACH = ((IS_AXI_FULL == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RDCH = ((IS_AXI_FULL == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WACH = ((IS_AXI_LITE == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WDCH = ((IS_AXI_LITE == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WRCH = ((IS_AXI_LITE == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RACH = ((IS_AXI_LITE == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RDCH = ((IS_AXI_LITE == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_WR_ADDR_CH = ((IS_AXI_FULL_WACH == 1) || (IS_AXI_LITE_WACH == 1)) ? 1 : 0;
localparam IS_WR_DATA_CH = ((IS_AXI_FULL_WDCH == 1) || (IS_AXI_LITE_WDCH == 1)) ? 1 : 0;
localparam IS_WR_RESP_CH = ((IS_AXI_FULL_WRCH == 1) || (IS_AXI_LITE_WRCH == 1)) ? 1 : 0;
localparam IS_RD_ADDR_CH = ((IS_AXI_FULL_RACH == 1) || (IS_AXI_LITE_RACH == 1)) ? 1 : 0;
localparam IS_RD_DATA_CH = ((IS_AXI_FULL_RDCH == 1) || (IS_AXI_LITE_RDCH == 1)) ? 1 : 0;
localparam AWID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WACH;
localparam AWADDR_OFFSET = AWID_OFFSET - C_AXI_ADDR_WIDTH;
localparam AWLEN_OFFSET = C_AXI_TYPE != 2 ? AWADDR_OFFSET - C_AXI_LEN_WIDTH : AWADDR_OFFSET;
localparam AWSIZE_OFFSET = C_AXI_TYPE != 2 ? AWLEN_OFFSET - C_AXI_SIZE_WIDTH : AWLEN_OFFSET;
localparam AWBURST_OFFSET = C_AXI_TYPE != 2 ? AWSIZE_OFFSET - C_AXI_BURST_WIDTH : AWSIZE_OFFSET;
localparam AWLOCK_OFFSET = C_AXI_TYPE != 2 ? AWBURST_OFFSET - C_AXI_LOCK_WIDTH : AWBURST_OFFSET;
localparam AWCACHE_OFFSET = C_AXI_TYPE != 2 ? AWLOCK_OFFSET - C_AXI_CACHE_WIDTH : AWLOCK_OFFSET;
localparam AWPROT_OFFSET = AWCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam AWQOS_OFFSET = AWPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam AWREGION_OFFSET = C_AXI_TYPE == 1 ? AWQOS_OFFSET - C_AXI_REGION_WIDTH : AWQOS_OFFSET;
localparam AWUSER_OFFSET = C_HAS_AXI_AWUSER == 1 ? AWREGION_OFFSET-C_AXI_AWUSER_WIDTH : AWREGION_OFFSET;
localparam WID_OFFSET = (C_AXI_TYPE == 3 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WDCH;
localparam WDATA_OFFSET = WID_OFFSET - C_AXI_DATA_WIDTH;
localparam WSTRB_OFFSET = WDATA_OFFSET - C_AXI_DATA_WIDTH/8;
localparam WUSER_OFFSET = C_HAS_AXI_WUSER == 1 ? WSTRB_OFFSET-C_AXI_WUSER_WIDTH : WSTRB_OFFSET;
localparam BID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WRCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WRCH;
localparam BRESP_OFFSET = BID_OFFSET - C_AXI_BRESP_WIDTH;
localparam BUSER_OFFSET = C_HAS_AXI_BUSER == 1 ? BRESP_OFFSET-C_AXI_BUSER_WIDTH : BRESP_OFFSET;
wire [C_DIN_WIDTH_WACH-1:0] wach_din ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout_pkt ;
wire wach_full ;
wire wach_almost_full ;
wire wach_prog_full ;
wire wach_empty ;
wire wach_almost_empty ;
wire wach_prog_empty ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_din ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_dout ;
wire wdch_full ;
wire wdch_almost_full ;
wire wdch_prog_full ;
wire wdch_empty ;
wire wdch_almost_empty ;
wire wdch_prog_empty ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_din ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_dout ;
wire wrch_full ;
wire wrch_almost_full ;
wire wrch_prog_full ;
wire wrch_empty ;
wire wrch_almost_empty ;
wire wrch_prog_empty ;
wire axi_aw_underflow_i;
wire axi_w_underflow_i ;
wire axi_b_underflow_i ;
wire axi_aw_overflow_i ;
wire axi_w_overflow_i ;
wire axi_b_overflow_i ;
wire axi_wr_underflow_i;
wire axi_wr_overflow_i ;
wire wach_s_axi_awready;
wire wach_m_axi_awvalid;
wire wach_wr_en ;
wire wach_rd_en ;
wire wdch_s_axi_wready ;
wire wdch_m_axi_wvalid ;
wire wdch_wr_en ;
wire wdch_rd_en ;
wire wrch_s_axi_bvalid ;
wire wrch_m_axi_bready ;
wire wrch_wr_en ;
wire wrch_rd_en ;
wire txn_count_up ;
wire txn_count_down ;
wire awvalid_en ;
wire awvalid_pkt ;
wire awready_pkt ;
integer wr_pkt_count ;
wire wach_we ;
wire wach_re ;
wire wdch_we ;
wire wdch_re ;
wire wrch_we ;
wire wrch_re ;
generate if (IS_WR_ADDR_CH == 1) begin : axi_write_address_channel
// Write protection when almost full or prog_full is high
assign wach_we = (C_PROG_FULL_TYPE_WACH != 0) ? wach_s_axi_awready & S_AXI_AWVALID : S_AXI_AWVALID;
// Read protection when almost empty or prog_empty is high
assign wach_re = (C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH == 1) ?
wach_m_axi_awvalid & awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY && wach_m_axi_awvalid :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH == 1) ?
awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY : 1'b0;
assign wach_wr_en = (C_HAS_SLAVE_CE == 1) ? wach_we & S_ACLK_EN : wach_we;
assign wach_rd_en = (C_HAS_MASTER_CE == 1) ? wach_re & M_ACLK_EN : wach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WACH == 2 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WACH == 11 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_DEPTH (C_WR_DEPTH_WACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WACH),
.C_RD_DEPTH (C_WR_DEPTH_WACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH),
.C_USE_ECC (C_USE_ECC_WACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_WACH == 1)?0:C_APPLICATION_TYPE_WACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 : 0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wach_wr_en),
.RD_EN (wach_rd_en),
.PROG_FULL_THRESH (AXI_AW_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AW_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.INJECTDBITERR (AXI_AW_INJECTDBITERR),
.INJECTSBITERR (AXI_AW_INJECTSBITERR),
.DIN (wach_din),
.DOUT (wach_dout_pkt),
.FULL (wach_full),
.EMPTY (wach_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_AW_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_AW_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_aw_overflow_i),
.VALID (),
.UNDERFLOW (axi_aw_underflow_i),
.DATA_COUNT (AXI_AW_DATA_COUNT),
.RD_DATA_COUNT (AXI_AW_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AW_WR_DATA_COUNT),
.SBITERR (AXI_AW_SBITERR),
.DBITERR (AXI_AW_DBITERR),
.wr_rst_busy (wr_rst_busy_wach),
.rd_rst_busy (rd_rst_busy_wach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wach_s_axi_awready = (IS_8SERIES == 0) ? ~wach_full : (C_IMPLEMENTATION_TYPE_WACH == 5 || C_IMPLEMENTATION_TYPE_WACH == 13) ? ~(wach_full | wr_rst_busy_wach) : ~wach_full;
assign wach_m_axi_awvalid = ~wach_empty;
assign S_AXI_AWREADY = wach_s_axi_awready;
assign AXI_AW_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_aw_underflow_i : 0;
assign AXI_AW_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_aw_overflow_i : 0;
end endgenerate // axi_write_address_channel
// Register Slice for Write Address Channel
generate if (C_WACH_TYPE == 1) begin : gwach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WACH)
)
wach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wach_din),
.S_VALID (S_AXI_AWVALID),
.S_READY (S_AXI_AWREADY),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
end endgenerate // gwach_reg_slice
generate if (C_APPLICATION_TYPE_WACH == 1 && C_HAS_AXI_WR_CHANNEL == 1) begin : axi_mm_pkt_fifo_wr
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (1)
)
wach_pkt_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (wach_dout_pkt),
.S_VALID (awvalid_pkt),
.S_READY (awready_pkt),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
assign awvalid_pkt = wach_m_axi_awvalid && awvalid_en;
assign txn_count_up = wdch_s_axi_wready && wdch_wr_en && wdch_din[0];
assign txn_count_down = wach_m_axi_awvalid && awready_pkt && awvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset == 1) begin
wr_pkt_count <= 0;
end else begin
if(txn_count_up == 1 && txn_count_down == 0) begin
wr_pkt_count <= wr_pkt_count + 1;
end else if(txn_count_up == 0 && txn_count_down == 1) begin
wr_pkt_count <= wr_pkt_count - 1;
end
end
end //Always end
assign awvalid_en = (wr_pkt_count > 0)?1:0;
end endgenerate
generate if (C_APPLICATION_TYPE_WACH != 1) begin : axi_mm_fifo_wr
assign awvalid_en = 1;
assign wach_dout = wach_dout_pkt;
assign M_AXI_AWVALID = wach_m_axi_awvalid;
end
endgenerate
generate if (IS_WR_DATA_CH == 1) begin : axi_write_data_channel
// Write protection when almost full or prog_full is high
assign wdch_we = (C_PROG_FULL_TYPE_WDCH != 0) ? wdch_s_axi_wready & S_AXI_WVALID : S_AXI_WVALID;
// Read protection when almost empty or prog_empty is high
assign wdch_re = (C_PROG_EMPTY_TYPE_WDCH != 0) ? wdch_m_axi_wvalid & M_AXI_WREADY : M_AXI_WREADY;
assign wdch_wr_en = (C_HAS_SLAVE_CE == 1) ? wdch_we & S_ACLK_EN : wdch_we;
assign wdch_rd_en = (C_HAS_MASTER_CE == 1) ? wdch_re & M_ACLK_EN : wdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WDCH == 2 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WDCH == 11 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WDCH),
.C_WR_DEPTH (C_WR_DEPTH_WDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WDCH),
.C_RD_DEPTH (C_WR_DEPTH_WDCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH),
.C_USE_ECC (C_USE_ECC_WDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wdch_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wdch_wr_en),
.RD_EN (wdch_rd_en),
.PROG_FULL_THRESH (AXI_W_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_W_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.INJECTDBITERR (AXI_W_INJECTDBITERR),
.INJECTSBITERR (AXI_W_INJECTSBITERR),
.DIN (wdch_din),
.DOUT (wdch_dout),
.FULL (wdch_full),
.EMPTY (wdch_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_W_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_W_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_w_overflow_i),
.VALID (),
.UNDERFLOW (axi_w_underflow_i),
.DATA_COUNT (AXI_W_DATA_COUNT),
.RD_DATA_COUNT (AXI_W_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_W_WR_DATA_COUNT),
.SBITERR (AXI_W_SBITERR),
.DBITERR (AXI_W_DBITERR),
.wr_rst_busy (wr_rst_busy_wdch),
.rd_rst_busy (rd_rst_busy_wdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wdch_s_axi_wready = (IS_8SERIES == 0) ? ~wdch_full : (C_IMPLEMENTATION_TYPE_WDCH == 5 || C_IMPLEMENTATION_TYPE_WDCH == 13) ? ~(wdch_full | wr_rst_busy_wdch) : ~wdch_full;
assign wdch_m_axi_wvalid = ~wdch_empty;
assign S_AXI_WREADY = wdch_s_axi_wready;
assign M_AXI_WVALID = wdch_m_axi_wvalid;
assign AXI_W_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_w_underflow_i : 0;
assign AXI_W_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_w_overflow_i : 0;
end endgenerate // axi_write_data_channel
// Register Slice for Write Data Channel
generate if (C_WDCH_TYPE == 1) begin : gwdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WDCH)
)
wdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wdch_din),
.S_VALID (S_AXI_WVALID),
.S_READY (S_AXI_WREADY),
// Master side
.M_PAYLOAD_DATA (wdch_dout),
.M_VALID (M_AXI_WVALID),
.M_READY (M_AXI_WREADY)
);
end endgenerate // gwdch_reg_slice
generate if (IS_WR_RESP_CH == 1) begin : axi_write_resp_channel
// Write protection when almost full or prog_full is high
assign wrch_we = (C_PROG_FULL_TYPE_WRCH != 0) ? wrch_m_axi_bready & M_AXI_BVALID : M_AXI_BVALID;
// Read protection when almost empty or prog_empty is high
assign wrch_re = (C_PROG_EMPTY_TYPE_WRCH != 0) ? wrch_s_axi_bvalid & S_AXI_BREADY : S_AXI_BREADY;
assign wrch_wr_en = (C_HAS_MASTER_CE == 1) ? wrch_we & M_ACLK_EN : wrch_we;
assign wrch_rd_en = (C_HAS_SLAVE_CE == 1) ? wrch_re & S_ACLK_EN : wrch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WRCH == 2 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WRCH == 11 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WRCH),
.C_WR_DEPTH (C_WR_DEPTH_WRCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WRCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_DEPTH (C_WR_DEPTH_WRCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WRCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WRCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WRCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH),
.C_USE_ECC (C_USE_ECC_WRCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WRCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WRCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wrch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wrch_wr_en),
.RD_EN (wrch_rd_en),
.PROG_FULL_THRESH (AXI_B_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_B_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.INJECTDBITERR (AXI_B_INJECTDBITERR),
.INJECTSBITERR (AXI_B_INJECTSBITERR),
.DIN (wrch_din),
.DOUT (wrch_dout),
.FULL (wrch_full),
.EMPTY (wrch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_B_PROG_FULL),
.PROG_EMPTY (AXI_B_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_b_overflow_i),
.VALID (),
.UNDERFLOW (axi_b_underflow_i),
.DATA_COUNT (AXI_B_DATA_COUNT),
.RD_DATA_COUNT (AXI_B_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_B_WR_DATA_COUNT),
.SBITERR (AXI_B_SBITERR),
.DBITERR (AXI_B_DBITERR),
.wr_rst_busy (wr_rst_busy_wrch),
.rd_rst_busy (rd_rst_busy_wrch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wrch_s_axi_bvalid = ~wrch_empty;
assign wrch_m_axi_bready = (IS_8SERIES == 0) ? ~wrch_full : (C_IMPLEMENTATION_TYPE_WRCH == 5 || C_IMPLEMENTATION_TYPE_WRCH == 13) ? ~(wrch_full | wr_rst_busy_wrch) : ~wrch_full;
assign S_AXI_BVALID = wrch_s_axi_bvalid;
assign M_AXI_BREADY = wrch_m_axi_bready;
assign AXI_B_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_b_underflow_i : 0;
assign AXI_B_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_b_overflow_i : 0;
end endgenerate // axi_write_resp_channel
// Register Slice for Write Response Channel
generate if (C_WRCH_TYPE == 1) begin : gwrch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WRCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WRCH)
)
wrch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wrch_din),
.S_VALID (M_AXI_BVALID),
.S_READY (M_AXI_BREADY),
// Master side
.M_PAYLOAD_DATA (wrch_dout),
.M_VALID (S_AXI_BVALID),
.M_READY (S_AXI_BREADY)
);
end endgenerate // gwrch_reg_slice
assign axi_wr_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_aw_underflow_i || axi_w_underflow_i || axi_b_underflow_i) : 0;
assign axi_wr_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_aw_overflow_i || axi_w_overflow_i || axi_b_overflow_i) : 0;
generate if (IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output
assign M_AXI_AWADDR = wach_dout[AWID_OFFSET-1:AWADDR_OFFSET];
assign M_AXI_AWLEN = wach_dout[AWADDR_OFFSET-1:AWLEN_OFFSET];
assign M_AXI_AWSIZE = wach_dout[AWLEN_OFFSET-1:AWSIZE_OFFSET];
assign M_AXI_AWBURST = wach_dout[AWSIZE_OFFSET-1:AWBURST_OFFSET];
assign M_AXI_AWLOCK = wach_dout[AWBURST_OFFSET-1:AWLOCK_OFFSET];
assign M_AXI_AWCACHE = wach_dout[AWLOCK_OFFSET-1:AWCACHE_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWCACHE_OFFSET-1:AWPROT_OFFSET];
assign M_AXI_AWQOS = wach_dout[AWPROT_OFFSET-1:AWQOS_OFFSET];
assign wach_din[AWID_OFFSET-1:AWADDR_OFFSET] = S_AXI_AWADDR;
assign wach_din[AWADDR_OFFSET-1:AWLEN_OFFSET] = S_AXI_AWLEN;
assign wach_din[AWLEN_OFFSET-1:AWSIZE_OFFSET] = S_AXI_AWSIZE;
assign wach_din[AWSIZE_OFFSET-1:AWBURST_OFFSET] = S_AXI_AWBURST;
assign wach_din[AWBURST_OFFSET-1:AWLOCK_OFFSET] = S_AXI_AWLOCK;
assign wach_din[AWLOCK_OFFSET-1:AWCACHE_OFFSET] = S_AXI_AWCACHE;
assign wach_din[AWCACHE_OFFSET-1:AWPROT_OFFSET] = S_AXI_AWPROT;
assign wach_din[AWPROT_OFFSET-1:AWQOS_OFFSET] = S_AXI_AWQOS;
end endgenerate // axi_wach_output
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_awregion
assign M_AXI_AWREGION = wach_dout[AWQOS_OFFSET-1:AWREGION_OFFSET];
end endgenerate // axi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_awregion
assign M_AXI_AWREGION = 0;
end endgenerate // naxi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : axi_awuser
assign M_AXI_AWUSER = wach_dout[AWREGION_OFFSET-1:AWUSER_OFFSET];
end endgenerate // axi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 0) begin : naxi_awuser
assign M_AXI_AWUSER = 0;
end endgenerate // naxi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_awid
assign M_AXI_AWID = wach_dout[C_DIN_WIDTH_WACH-1:AWID_OFFSET];
end endgenerate //axi_awid
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_awid
assign M_AXI_AWID = 0;
end endgenerate //naxi_awid
generate if (IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output
assign M_AXI_WDATA = wdch_dout[WID_OFFSET-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
assign M_AXI_WLAST = wdch_dout[0];
assign wdch_din[WID_OFFSET-1:WDATA_OFFSET] = S_AXI_WDATA;
assign wdch_din[WDATA_OFFSET-1:WSTRB_OFFSET] = S_AXI_WSTRB;
assign wdch_din[0] = S_AXI_WLAST;
end endgenerate // axi_wdch_output
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin
assign M_AXI_WID = wdch_dout[C_DIN_WIDTH_WDCH-1:WID_OFFSET];
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && (C_HAS_AXI_ID == 0 || C_AXI_TYPE != 3)) begin
assign M_AXI_WID = 0;
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1 ) begin
assign M_AXI_WUSER = wdch_dout[WSTRB_OFFSET-1:WUSER_OFFSET];
end endgenerate
generate if (C_HAS_AXI_WUSER == 0) begin
assign M_AXI_WUSER = 0;
end endgenerate
generate if (IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output
assign S_AXI_BRESP = wrch_dout[BID_OFFSET-1:BRESP_OFFSET];
assign wrch_din[BID_OFFSET-1:BRESP_OFFSET] = M_AXI_BRESP;
end endgenerate // axi_wrch_output
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : axi_buser
assign S_AXI_BUSER = wrch_dout[BRESP_OFFSET-1:BUSER_OFFSET];
end endgenerate // axi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 0) begin : naxi_buser
assign S_AXI_BUSER = 0;
end endgenerate // naxi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_bid
assign S_AXI_BID = wrch_dout[C_DIN_WIDTH_WRCH-1:BID_OFFSET];
end endgenerate // axi_bid
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_bid
assign S_AXI_BID = 0 ;
end endgenerate // naxi_bid
generate if (IS_AXI_LITE_WACH == 1 || (IS_AXI_LITE == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output1
assign wach_din = {S_AXI_AWADDR, S_AXI_AWPROT};
assign M_AXI_AWADDR = wach_dout[C_DIN_WIDTH_WACH-1:AWADDR_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWADDR_OFFSET-1:AWPROT_OFFSET];
end endgenerate // axi_wach_output1
generate if (IS_AXI_LITE_WDCH == 1 || (IS_AXI_LITE == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output1
assign wdch_din = {S_AXI_WDATA, S_AXI_WSTRB};
assign M_AXI_WDATA = wdch_dout[C_DIN_WIDTH_WDCH-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
end endgenerate // axi_wdch_output1
generate if (IS_AXI_LITE_WRCH == 1 || (IS_AXI_LITE == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output1
assign wrch_din = M_AXI_BRESP;
assign S_AXI_BRESP = wrch_dout[C_DIN_WIDTH_WRCH-1:BRESP_OFFSET];
end endgenerate // axi_wrch_output1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : gwach_din1
assign wach_din[AWREGION_OFFSET-1:AWUSER_OFFSET] = S_AXI_AWUSER;
end endgenerate // gwach_din1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwach_din2
assign wach_din[C_DIN_WIDTH_WACH-1:AWID_OFFSET] = S_AXI_AWID;
end endgenerate // gwach_din2
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : gwach_din3
assign wach_din[AWQOS_OFFSET-1:AWREGION_OFFSET] = S_AXI_AWREGION;
end endgenerate // gwach_din3
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1) begin : gwdch_din1
assign wdch_din[WSTRB_OFFSET-1:WUSER_OFFSET] = S_AXI_WUSER;
end endgenerate // gwdch_din1
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin : gwdch_din2
assign wdch_din[C_DIN_WIDTH_WDCH-1:WID_OFFSET] = S_AXI_WID;
end endgenerate // gwdch_din2
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : gwrch_din1
assign wrch_din[BRESP_OFFSET-1:BUSER_OFFSET] = M_AXI_BUSER;
end endgenerate // gwrch_din1
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwrch_din2
assign wrch_din[C_DIN_WIDTH_WRCH-1:BID_OFFSET] = M_AXI_BID;
end endgenerate // gwrch_din2
//end of axi_write_channel
//###########################################################################
// AXI FULL Read Channel (axi_read_channel)
//###########################################################################
wire [C_DIN_WIDTH_RACH-1:0] rach_din ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout_pkt ;
wire rach_full ;
wire rach_almost_full ;
wire rach_prog_full ;
wire rach_empty ;
wire rach_almost_empty ;
wire rach_prog_empty ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_din ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_dout ;
wire rdch_full ;
wire rdch_almost_full ;
wire rdch_prog_full ;
wire rdch_empty ;
wire rdch_almost_empty ;
wire rdch_prog_empty ;
wire axi_ar_underflow_i ;
wire axi_r_underflow_i ;
wire axi_ar_overflow_i ;
wire axi_r_overflow_i ;
wire axi_rd_underflow_i ;
wire axi_rd_overflow_i ;
wire rach_s_axi_arready ;
wire rach_m_axi_arvalid ;
wire rach_wr_en ;
wire rach_rd_en ;
wire rdch_m_axi_rready ;
wire rdch_s_axi_rvalid ;
wire rdch_wr_en ;
wire rdch_rd_en ;
wire arvalid_pkt ;
wire arready_pkt ;
wire arvalid_en ;
wire rdch_rd_ok ;
wire accept_next_pkt ;
integer rdch_free_space ;
integer rdch_commited_space ;
wire rach_we ;
wire rach_re ;
wire rdch_we ;
wire rdch_re ;
localparam ARID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RACH;
localparam ARADDR_OFFSET = ARID_OFFSET - C_AXI_ADDR_WIDTH;
localparam ARLEN_OFFSET = C_AXI_TYPE != 2 ? ARADDR_OFFSET - C_AXI_LEN_WIDTH : ARADDR_OFFSET;
localparam ARSIZE_OFFSET = C_AXI_TYPE != 2 ? ARLEN_OFFSET - C_AXI_SIZE_WIDTH : ARLEN_OFFSET;
localparam ARBURST_OFFSET = C_AXI_TYPE != 2 ? ARSIZE_OFFSET - C_AXI_BURST_WIDTH : ARSIZE_OFFSET;
localparam ARLOCK_OFFSET = C_AXI_TYPE != 2 ? ARBURST_OFFSET - C_AXI_LOCK_WIDTH : ARBURST_OFFSET;
localparam ARCACHE_OFFSET = C_AXI_TYPE != 2 ? ARLOCK_OFFSET - C_AXI_CACHE_WIDTH : ARLOCK_OFFSET;
localparam ARPROT_OFFSET = ARCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam ARQOS_OFFSET = ARPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam ARREGION_OFFSET = C_AXI_TYPE == 1 ? ARQOS_OFFSET - C_AXI_REGION_WIDTH : ARQOS_OFFSET;
localparam ARUSER_OFFSET = C_HAS_AXI_ARUSER == 1 ? ARREGION_OFFSET-C_AXI_ARUSER_WIDTH : ARREGION_OFFSET;
localparam RID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RDCH;
localparam RDATA_OFFSET = RID_OFFSET - C_AXI_DATA_WIDTH;
localparam RRESP_OFFSET = RDATA_OFFSET - C_AXI_RRESP_WIDTH;
localparam RUSER_OFFSET = C_HAS_AXI_RUSER == 1 ? RRESP_OFFSET-C_AXI_RUSER_WIDTH : RRESP_OFFSET;
generate if (IS_RD_ADDR_CH == 1) begin : axi_read_addr_channel
// Write protection when almost full or prog_full is high
assign rach_we = (C_PROG_FULL_TYPE_RACH != 0) ? rach_s_axi_arready & S_AXI_ARVALID : S_AXI_ARVALID;
// Read protection when almost empty or prog_empty is high
// assign rach_rd_en = (C_PROG_EMPTY_TYPE_RACH != 5) ? rach_m_axi_arvalid & M_AXI_ARREADY : M_AXI_ARREADY && arvalid_en;
assign rach_re = (C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH == 1) ?
rach_m_axi_arvalid & arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY && rach_m_axi_arvalid :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH == 1) ?
arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY : 1'b0;
assign rach_wr_en = (C_HAS_SLAVE_CE == 1) ? rach_we & S_ACLK_EN : rach_we;
assign rach_rd_en = (C_HAS_MASTER_CE == 1) ? rach_re & M_ACLK_EN : rach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RACH == 2 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RACH == 11 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RACH),
.C_WR_DEPTH (C_WR_DEPTH_RACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_DOUT_WIDTH (C_DIN_WIDTH_RACH),
.C_RD_DEPTH (C_WR_DEPTH_RACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH),
.C_USE_ECC (C_USE_ECC_RACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_RACH == 1)?0:C_APPLICATION_TYPE_RACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rach_wr_en),
.RD_EN (rach_rd_en),
.PROG_FULL_THRESH (AXI_AR_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AR_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.INJECTDBITERR (AXI_AR_INJECTDBITERR),
.INJECTSBITERR (AXI_AR_INJECTSBITERR),
.DIN (rach_din),
.DOUT (rach_dout_pkt),
.FULL (rach_full),
.EMPTY (rach_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_AR_PROG_FULL),
.PROG_EMPTY (AXI_AR_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_ar_overflow_i),
.VALID (),
.UNDERFLOW (axi_ar_underflow_i),
.DATA_COUNT (AXI_AR_DATA_COUNT),
.RD_DATA_COUNT (AXI_AR_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AR_WR_DATA_COUNT),
.SBITERR (AXI_AR_SBITERR),
.DBITERR (AXI_AR_DBITERR),
.wr_rst_busy (wr_rst_busy_rach),
.rd_rst_busy (rd_rst_busy_rach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rach_s_axi_arready = (IS_8SERIES == 0) ? ~rach_full : (C_IMPLEMENTATION_TYPE_RACH == 5 || C_IMPLEMENTATION_TYPE_RACH == 13) ? ~(rach_full | wr_rst_busy_rach) : ~rach_full;
assign rach_m_axi_arvalid = ~rach_empty;
assign S_AXI_ARREADY = rach_s_axi_arready;
assign AXI_AR_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_ar_underflow_i : 0;
assign AXI_AR_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_ar_overflow_i : 0;
end endgenerate // axi_read_addr_channel
// Register Slice for Read Address Channel
generate if (C_RACH_TYPE == 1) begin : grach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RACH)
)
rach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rach_din),
.S_VALID (S_AXI_ARVALID),
.S_READY (S_AXI_ARREADY),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice
// Register Slice for Read Address Channel for MM Packet FIFO
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH == 1) begin : grach_reg_slice_mm_pkt_fifo
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (1)
)
reg_slice_mm_pkt_fifo_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (rach_dout_pkt),
.S_VALID (arvalid_pkt),
.S_READY (arready_pkt),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice_mm_pkt_fifo
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH != 1) begin : grach_m_axi_arvalid
assign M_AXI_ARVALID = rach_m_axi_arvalid;
assign rach_dout = rach_dout_pkt;
end endgenerate // grach_m_axi_arvalid
generate if (C_APPLICATION_TYPE_RACH == 1 && C_HAS_AXI_RD_CHANNEL == 1) begin : axi_mm_pkt_fifo_rd
assign rdch_rd_ok = rdch_s_axi_rvalid && rdch_rd_en;
assign arvalid_pkt = rach_m_axi_arvalid && arvalid_en;
assign accept_next_pkt = rach_m_axi_arvalid && arready_pkt && arvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset) begin
rdch_commited_space <= 0;
end else begin
if(rdch_rd_ok && !accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space-1;
end else if(!rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1);
end else if(rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]);
end
end
end //Always end
always@(*) begin
rdch_free_space <= (C_WR_DEPTH_RDCH-(rdch_commited_space+rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1));
end
assign arvalid_en = (rdch_free_space >= 0)?1:0;
end
endgenerate
generate if (C_APPLICATION_TYPE_RACH != 1) begin : axi_mm_fifo_rd
assign arvalid_en = 1;
end
endgenerate
generate if (IS_RD_DATA_CH == 1) begin : axi_read_data_channel
// Write protection when almost full or prog_full is high
assign rdch_we = (C_PROG_FULL_TYPE_RDCH != 0) ? rdch_m_axi_rready & M_AXI_RVALID : M_AXI_RVALID;
// Read protection when almost empty or prog_empty is high
assign rdch_re = (C_PROG_EMPTY_TYPE_RDCH != 0) ? rdch_s_axi_rvalid & S_AXI_RREADY : S_AXI_RREADY;
assign rdch_wr_en = (C_HAS_MASTER_CE == 1) ? rdch_we & M_ACLK_EN : rdch_we;
assign rdch_rd_en = (C_HAS_SLAVE_CE == 1) ? rdch_re & S_ACLK_EN : rdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RDCH == 2 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RDCH == 11 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RDCH),
.C_WR_DEPTH (C_WR_DEPTH_RDCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_RDCH),
.C_RD_DEPTH (C_WR_DEPTH_RDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH),
.C_USE_ECC (C_USE_ECC_RDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_RDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rdch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rdch_wr_en),
.RD_EN (rdch_rd_en),
.PROG_FULL_THRESH (AXI_R_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_R_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.INJECTDBITERR (AXI_R_INJECTDBITERR),
.INJECTSBITERR (AXI_R_INJECTSBITERR),
.DIN (rdch_din),
.DOUT (rdch_dout),
.FULL (rdch_full),
.EMPTY (rdch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_R_PROG_FULL),
.PROG_EMPTY (AXI_R_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_r_overflow_i),
.VALID (),
.UNDERFLOW (axi_r_underflow_i),
.DATA_COUNT (AXI_R_DATA_COUNT),
.RD_DATA_COUNT (AXI_R_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_R_WR_DATA_COUNT),
.SBITERR (AXI_R_SBITERR),
.DBITERR (AXI_R_DBITERR),
.wr_rst_busy (wr_rst_busy_rdch),
.rd_rst_busy (rd_rst_busy_rdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rdch_s_axi_rvalid = ~rdch_empty;
assign rdch_m_axi_rready = (IS_8SERIES == 0) ? ~rdch_full : (C_IMPLEMENTATION_TYPE_RDCH == 5 || C_IMPLEMENTATION_TYPE_RDCH == 13) ? ~(rdch_full | wr_rst_busy_rdch) : ~rdch_full;
assign S_AXI_RVALID = rdch_s_axi_rvalid;
assign M_AXI_RREADY = rdch_m_axi_rready;
assign AXI_R_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_r_underflow_i : 0;
assign AXI_R_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_r_overflow_i : 0;
end endgenerate //axi_read_data_channel
// Register Slice for read Data Channel
generate if (C_RDCH_TYPE == 1) begin : grdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RDCH)
)
rdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rdch_din),
.S_VALID (M_AXI_RVALID),
.S_READY (M_AXI_RREADY),
// Master side
.M_PAYLOAD_DATA (rdch_dout),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY)
);
end endgenerate // grdch_reg_slice
assign axi_rd_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_ar_underflow_i || axi_r_underflow_i) : 0;
assign axi_rd_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_ar_overflow_i || axi_r_overflow_i) : 0;
generate if (IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) begin : axi_full_rach_output
assign M_AXI_ARADDR = rach_dout[ARID_OFFSET-1:ARADDR_OFFSET];
assign M_AXI_ARLEN = rach_dout[ARADDR_OFFSET-1:ARLEN_OFFSET];
assign M_AXI_ARSIZE = rach_dout[ARLEN_OFFSET-1:ARSIZE_OFFSET];
assign M_AXI_ARBURST = rach_dout[ARSIZE_OFFSET-1:ARBURST_OFFSET];
assign M_AXI_ARLOCK = rach_dout[ARBURST_OFFSET-1:ARLOCK_OFFSET];
assign M_AXI_ARCACHE = rach_dout[ARLOCK_OFFSET-1:ARCACHE_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARCACHE_OFFSET-1:ARPROT_OFFSET];
assign M_AXI_ARQOS = rach_dout[ARPROT_OFFSET-1:ARQOS_OFFSET];
assign rach_din[ARID_OFFSET-1:ARADDR_OFFSET] = S_AXI_ARADDR;
assign rach_din[ARADDR_OFFSET-1:ARLEN_OFFSET] = S_AXI_ARLEN;
assign rach_din[ARLEN_OFFSET-1:ARSIZE_OFFSET] = S_AXI_ARSIZE;
assign rach_din[ARSIZE_OFFSET-1:ARBURST_OFFSET] = S_AXI_ARBURST;
assign rach_din[ARBURST_OFFSET-1:ARLOCK_OFFSET] = S_AXI_ARLOCK;
assign rach_din[ARLOCK_OFFSET-1:ARCACHE_OFFSET] = S_AXI_ARCACHE;
assign rach_din[ARCACHE_OFFSET-1:ARPROT_OFFSET] = S_AXI_ARPROT;
assign rach_din[ARPROT_OFFSET-1:ARQOS_OFFSET] = S_AXI_ARQOS;
end endgenerate // axi_full_rach_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_arregion
assign M_AXI_ARREGION = rach_dout[ARQOS_OFFSET-1:ARREGION_OFFSET];
end endgenerate // axi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_arregion
assign M_AXI_ARREGION = 0;
end endgenerate // naxi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : axi_aruser
assign M_AXI_ARUSER = rach_dout[ARREGION_OFFSET-1:ARUSER_OFFSET];
end endgenerate // axi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 0) begin : naxi_aruser
assign M_AXI_ARUSER = 0;
end endgenerate // naxi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_arid
assign M_AXI_ARID = rach_dout[C_DIN_WIDTH_RACH-1:ARID_OFFSET];
end endgenerate // axi_arid
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_arid
assign M_AXI_ARID = 0;
end endgenerate // naxi_arid
generate if (IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) begin : axi_full_rdch_output
assign S_AXI_RDATA = rdch_dout[RID_OFFSET-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
assign S_AXI_RLAST = rdch_dout[0];
assign rdch_din[RID_OFFSET-1:RDATA_OFFSET] = M_AXI_RDATA;
assign rdch_din[RDATA_OFFSET-1:RRESP_OFFSET] = M_AXI_RRESP;
assign rdch_din[0] = M_AXI_RLAST;
end endgenerate // axi_full_rdch_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : axi_full_ruser_output
assign S_AXI_RUSER = rdch_dout[RRESP_OFFSET-1:RUSER_OFFSET];
end endgenerate // axi_full_ruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 0) begin : axi_full_nruser_output
assign S_AXI_RUSER = 0;
end endgenerate // axi_full_nruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_rid
assign S_AXI_RID = rdch_dout[C_DIN_WIDTH_RDCH-1:RID_OFFSET];
end endgenerate // axi_rid
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_rid
assign S_AXI_RID = 0;
end endgenerate // naxi_rid
generate if (IS_AXI_LITE_RACH == 1 || (IS_AXI_LITE == 1 && C_RACH_TYPE == 1)) begin : axi_lite_rach_output1
assign rach_din = {S_AXI_ARADDR, S_AXI_ARPROT};
assign M_AXI_ARADDR = rach_dout[C_DIN_WIDTH_RACH-1:ARADDR_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARADDR_OFFSET-1:ARPROT_OFFSET];
end endgenerate // axi_lite_rach_output
generate if (IS_AXI_LITE_RDCH == 1 || (IS_AXI_LITE == 1 && C_RDCH_TYPE == 1)) begin : axi_lite_rdch_output1
assign rdch_din = {M_AXI_RDATA, M_AXI_RRESP};
assign S_AXI_RDATA = rdch_dout[C_DIN_WIDTH_RDCH-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
end endgenerate // axi_lite_rdch_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : grach_din1
assign rach_din[ARREGION_OFFSET-1:ARUSER_OFFSET] = S_AXI_ARUSER;
end endgenerate // grach_din1
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grach_din2
assign rach_din[C_DIN_WIDTH_RACH-1:ARID_OFFSET] = S_AXI_ARID;
end endgenerate // grach_din2
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin
assign rach_din[ARQOS_OFFSET-1:ARREGION_OFFSET] = S_AXI_ARREGION;
end endgenerate
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : grdch_din1
assign rdch_din[RRESP_OFFSET-1:RUSER_OFFSET] = M_AXI_RUSER;
end endgenerate // grdch_din1
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grdch_din2
assign rdch_din[C_DIN_WIDTH_RDCH-1:RID_OFFSET] = M_AXI_RID;
end endgenerate // grdch_din2
//end of axi_read_channel
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_UNDERFLOW == 1) begin : gaxi_comm_uf
assign UNDERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_underflow_i || axi_rd_underflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_underflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_underflow_i : 0;
end endgenerate // gaxi_comm_uf
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_OVERFLOW == 1) begin : gaxi_comm_of
assign OVERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_overflow_i || axi_rd_overflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_overflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_overflow_i : 0;
end endgenerate // gaxi_comm_of
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic or Wiring Logic
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Write Address Channel
generate if (C_WACH_TYPE == 2) begin : gwach_pass_through
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWQOS = S_AXI_AWQOS;
assign M_AXI_AWREGION = S_AXI_AWREGION;
assign M_AXI_AWUSER = S_AXI_AWUSER;
assign S_AXI_AWREADY = M_AXI_AWREADY;
assign M_AXI_AWVALID = S_AXI_AWVALID;
end endgenerate // gwach_pass_through;
// Wiring logic for Write Data Channel
generate if (C_WDCH_TYPE == 2) begin : gwdch_pass_through
assign M_AXI_WID = S_AXI_WID;
assign M_AXI_WDATA = S_AXI_WDATA;
assign M_AXI_WSTRB = S_AXI_WSTRB;
assign M_AXI_WLAST = S_AXI_WLAST;
assign M_AXI_WUSER = S_AXI_WUSER;
assign S_AXI_WREADY = M_AXI_WREADY;
assign M_AXI_WVALID = S_AXI_WVALID;
end endgenerate // gwdch_pass_through;
// Wiring logic for Write Response Channel
generate if (C_WRCH_TYPE == 2) begin : gwrch_pass_through
assign S_AXI_BID = M_AXI_BID;
assign S_AXI_BRESP = M_AXI_BRESP;
assign S_AXI_BUSER = M_AXI_BUSER;
assign M_AXI_BREADY = S_AXI_BREADY;
assign S_AXI_BVALID = M_AXI_BVALID;
end endgenerate // gwrch_pass_through;
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Read Address Channel
generate if (C_RACH_TYPE == 2) begin : grach_pass_through
assign M_AXI_ARID = S_AXI_ARID;
assign M_AXI_ARADDR = S_AXI_ARADDR;
assign M_AXI_ARLEN = S_AXI_ARLEN;
assign M_AXI_ARSIZE = S_AXI_ARSIZE;
assign M_AXI_ARBURST = S_AXI_ARBURST;
assign M_AXI_ARLOCK = S_AXI_ARLOCK;
assign M_AXI_ARCACHE = S_AXI_ARCACHE;
assign M_AXI_ARPROT = S_AXI_ARPROT;
assign M_AXI_ARQOS = S_AXI_ARQOS;
assign M_AXI_ARREGION = S_AXI_ARREGION;
assign M_AXI_ARUSER = S_AXI_ARUSER;
assign S_AXI_ARREADY = M_AXI_ARREADY;
assign M_AXI_ARVALID = S_AXI_ARVALID;
end endgenerate // grach_pass_through;
// Wiring logic for Read Data Channel
generate if (C_RDCH_TYPE == 2) begin : grdch_pass_through
assign S_AXI_RID = M_AXI_RID;
assign S_AXI_RLAST = M_AXI_RLAST;
assign S_AXI_RUSER = M_AXI_RUSER;
assign S_AXI_RDATA = M_AXI_RDATA;
assign S_AXI_RRESP = M_AXI_RRESP;
assign S_AXI_RVALID = M_AXI_RVALID;
assign M_AXI_RREADY = S_AXI_RREADY;
end endgenerate // grdch_pass_through;
// Wiring logic for AXI Streaming
generate if (C_AXIS_TYPE == 2) begin : gaxis_pass_through
assign M_AXIS_TDATA = S_AXIS_TDATA;
assign M_AXIS_TSTRB = S_AXIS_TSTRB;
assign M_AXIS_TKEEP = S_AXIS_TKEEP;
assign M_AXIS_TID = S_AXIS_TID;
assign M_AXIS_TDEST = S_AXIS_TDEST;
assign M_AXIS_TUSER = S_AXIS_TUSER;
assign M_AXIS_TLAST = S_AXIS_TLAST;
assign S_AXIS_TREADY = M_AXIS_TREADY;
assign M_AXIS_TVALID = S_AXIS_TVALID;
end endgenerate // gaxis_pass_through;
endmodule //fifo_generator_v13_1_3
/*******************************************************************************
* Declaration of top-level module for Conventional FIFO
******************************************************************************/
module fifo_generator_v13_1_3_CONV_VER
#(
parameter C_COMMON_CLOCK = 0,
parameter C_INTERFACE_TYPE = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "virtex7", //Not allowed in Verilog model
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
parameter C_AXI_TYPE = 0
)
(
input BACKUP,
input BACKUP_MARKER,
input CLK,
input RST,
input SRST,
input WR_CLK,
input WR_RST,
input RD_CLK,
input RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input WR_EN,
input RD_EN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input INT_CLK,
input INJECTDBITERR,
input INJECTSBITERR,
output [C_DOUT_WIDTH-1:0] DOUT,
output FULL,
output ALMOST_FULL,
output WR_ACK,
output OVERFLOW,
output EMPTY,
output ALMOST_EMPTY,
output VALID,
output UNDERFLOW,
output [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_FULL,
output PROG_EMPTY,
output SBITERR,
output DBITERR,
output wr_rst_busy_o,
output wr_rst_busy,
output rd_rst_busy,
output wr_rst_i_out,
output rd_rst_i_out
);
/*
******************************************************************************
* Definition of Parameters
******************************************************************************
* C_COMMON_CLOCK : Common Clock (1), Independent Clocks (0)
* C_COUNT_TYPE : *not used
* C_DATA_COUNT_WIDTH : Width of DATA_COUNT bus
* C_DEFAULT_VALUE : *not used
* C_DIN_WIDTH : Width of DIN bus
* C_DOUT_RST_VAL : Reset value of DOUT
* C_DOUT_WIDTH : Width of DOUT bus
* C_ENABLE_RLOCS : *not used
* C_FAMILY : not used in bhv model
* C_FULL_FLAGS_RST_VAL : Full flags rst val (0 or 1)
* C_HAS_ALMOST_EMPTY : 1=Core has ALMOST_EMPTY flag
* C_HAS_ALMOST_FULL : 1=Core has ALMOST_FULL flag
* C_HAS_BACKUP : *not used
* C_HAS_DATA_COUNT : 1=Core has DATA_COUNT bus
* C_HAS_INT_CLK : not used in bhv model
* C_HAS_MEMINIT_FILE : *not used
* C_HAS_OVERFLOW : 1=Core has OVERFLOW flag
* C_HAS_RD_DATA_COUNT : 1=Core has RD_DATA_COUNT bus
* C_HAS_RD_RST : *not used
* C_HAS_RST : 1=Core has Async Rst
* C_HAS_SRST : 1=Core has Sync Rst
* C_HAS_UNDERFLOW : 1=Core has UNDERFLOW flag
* C_HAS_VALID : 1=Core has VALID flag
* C_HAS_WR_ACK : 1=Core has WR_ACK flag
* C_HAS_WR_DATA_COUNT : 1=Core has WR_DATA_COUNT bus
* C_HAS_WR_RST : *not used
* C_IMPLEMENTATION_TYPE : 0=Common-Clock Bram/Dram
* 1=Common-Clock ShiftRam
* 2=Indep. Clocks Bram/Dram
* 3=Virtex-4 Built-in
* 4=Virtex-5 Built-in
* C_INIT_WR_PNTR_VAL : *not used
* C_MEMORY_TYPE : 1=Block RAM
* 2=Distributed RAM
* 3=Shift RAM
* 4=Built-in FIFO
* C_MIF_FILE_NAME : *not used
* C_OPTIMIZATION_MODE : *not used
* C_OVERFLOW_LOW : 1=OVERFLOW active low
* C_PRELOAD_LATENCY : Latency of read: 0, 1, 2
* C_PRELOAD_REGS : 1=Use output registers
* C_PRIM_FIFO_TYPE : not used in bhv model
* C_PROG_EMPTY_THRESH_ASSERT_VAL: PROG_EMPTY assert threshold
* C_PROG_EMPTY_THRESH_NEGATE_VAL: PROG_EMPTY negate threshold
* C_PROG_EMPTY_TYPE : 0=No programmable empty
* 1=Single prog empty thresh constant
* 2=Multiple prog empty thresh constants
* 3=Single prog empty thresh input
* 4=Multiple prog empty thresh inputs
* C_PROG_FULL_THRESH_ASSERT_VAL : PROG_FULL assert threshold
* C_PROG_FULL_THRESH_NEGATE_VAL : PROG_FULL negate threshold
* C_PROG_FULL_TYPE : 0=No prog full
* 1=Single prog full thresh constant
* 2=Multiple prog full thresh constants
* 3=Single prog full thresh input
* 4=Multiple prog full thresh inputs
* C_RD_DATA_COUNT_WIDTH : Width of RD_DATA_COUNT bus
* C_RD_DEPTH : Depth of read interface (2^N)
* C_RD_FREQ : not used in bhv model
* C_RD_PNTR_WIDTH : always log2(C_RD_DEPTH)
* C_UNDERFLOW_LOW : 1=UNDERFLOW active low
* C_USE_DOUT_RST : 1=Resets DOUT on RST
* C_USE_ECC : Used for error injection purpose
* C_USE_EMBEDDED_REG : 1=Use BRAM embedded output register
* C_USE_FIFO16_FLAGS : not used in bhv model
* C_USE_FWFT_DATA_COUNT : 1=Use extra logic for FWFT data count
* C_VALID_LOW : 1=VALID active low
* C_WR_ACK_LOW : 1=WR_ACK active low
* C_WR_DATA_COUNT_WIDTH : Width of WR_DATA_COUNT bus
* C_WR_DEPTH : Depth of write interface (2^N)
* C_WR_FREQ : not used in bhv model
* C_WR_PNTR_WIDTH : always log2(C_WR_DEPTH)
* C_WR_RESPONSE_LATENCY : *not used
* C_MSGON_VAL : *not used by bhv model
* C_ENABLE_RST_SYNC : 0 = Use WR_RST & RD_RST
* 1 = Use RST
* C_ERROR_INJECTION_TYPE : 0 = No error injection
* 1 = Single bit error injection only
* 2 = Double bit error injection only
* 3 = Single and double bit error injection
******************************************************************************
* Definition of Ports
******************************************************************************
* BACKUP : Not used
* BACKUP_MARKER: Not used
* CLK : Clock
* DIN : Input data bus
* PROG_EMPTY_THRESH : Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_ASSERT: Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_NEGATE: Threshold for Programmable Empty Flag
* PROG_FULL_THRESH : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_ASSERT : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_NEGATE : Threshold for Programmable Full Flag
* RD_CLK : Read Domain Clock
* RD_EN : Read enable
* RD_RST : Read Reset
* RST : Asynchronous Reset
* SRST : Synchronous Reset
* WR_CLK : Write Domain Clock
* WR_EN : Write enable
* WR_RST : Write Reset
* INT_CLK : Internal Clock
* INJECTSBITERR: Inject Signle bit error
* INJECTDBITERR: Inject Double bit error
* ALMOST_EMPTY : One word remaining in FIFO
* ALMOST_FULL : One empty space remaining in FIFO
* DATA_COUNT : Number of data words in fifo( synchronous to CLK)
* DOUT : Output data bus
* EMPTY : Empty flag
* FULL : Full flag
* OVERFLOW : Last write rejected
* PROG_EMPTY : Programmable Empty Flag
* PROG_FULL : Programmable Full Flag
* RD_DATA_COUNT: Number of data words in fifo (synchronous to RD_CLK)
* UNDERFLOW : Last read rejected
* VALID : Last read acknowledged, DOUT bus VALID
* WR_ACK : Last write acknowledged
* WR_DATA_COUNT: Number of data words in fifo (synchronous to WR_CLK)
* SBITERR : Single Bit ECC Error Detected
* DBITERR : Double Bit ECC Error Detected
******************************************************************************
*/
//----------------------------------------------------------------------------
//- Internal Signals for delayed input signals
//- All the input signals except Clock are delayed by 100 ps and then given to
//- the models.
//----------------------------------------------------------------------------
reg rst_delayed ;
reg empty_fb ;
reg srst_delayed ;
reg wr_rst_delayed ;
reg rd_rst_delayed ;
reg wr_en_delayed ;
reg rd_en_delayed ;
reg [C_DIN_WIDTH-1:0] din_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate_delayed ;
reg injectdbiterr_delayed ;
reg injectsbiterr_delayed ;
wire empty_p0_out;
always @* rst_delayed <= #`TCQ RST ;
always @* empty_fb <= #`TCQ empty_p0_out ;
always @* srst_delayed <= #`TCQ SRST ;
always @* wr_rst_delayed <= #`TCQ WR_RST ;
always @* rd_rst_delayed <= #`TCQ RD_RST ;
always @* din_delayed <= #`TCQ DIN ;
always @* wr_en_delayed <= #`TCQ WR_EN ;
always @* rd_en_delayed <= #`TCQ RD_EN ;
always @* prog_empty_thresh_delayed <= #`TCQ PROG_EMPTY_THRESH ;
always @* prog_empty_thresh_assert_delayed <= #`TCQ PROG_EMPTY_THRESH_ASSERT ;
always @* prog_empty_thresh_negate_delayed <= #`TCQ PROG_EMPTY_THRESH_NEGATE ;
always @* prog_full_thresh_delayed <= #`TCQ PROG_FULL_THRESH ;
always @* prog_full_thresh_assert_delayed <= #`TCQ PROG_FULL_THRESH_ASSERT ;
always @* prog_full_thresh_negate_delayed <= #`TCQ PROG_FULL_THRESH_NEGATE ;
always @* injectdbiterr_delayed <= #`TCQ INJECTDBITERR ;
always @* injectsbiterr_delayed <= #`TCQ INJECTSBITERR ;
/*****************************************************************************
* Derived parameters
****************************************************************************/
//There are 2 Verilog behavioral models
// 0 = Common-Clock FIFO/ShiftRam FIFO
// 1 = Independent Clocks FIFO
// 2 = Low Latency Synchronous FIFO
// 3 = Low Latency Asynchronous FIFO
localparam C_VERILOG_IMPL = (C_FIFO_TYPE == 3) ? 2 :
(C_IMPLEMENTATION_TYPE == 2) ? 1 : 0;
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//Internal reset signals
reg rd_rst_asreg = 0;
wire rd_rst_asreg_d1;
wire rd_rst_asreg_d2;
reg rd_rst_asreg_d3 = 0;
reg rd_rst_reg = 0;
wire rd_rst_comb;
reg wr_rst_d0 = 0;
reg wr_rst_d1 = 0;
reg wr_rst_d2 = 0;
reg rd_rst_d0 = 0;
reg rd_rst_d1 = 0;
reg rd_rst_d2 = 0;
reg rd_rst_d3 = 0;
reg wrrst_done = 0;
reg rdrst_done = 0;
reg wr_rst_asreg = 0;
wire wr_rst_asreg_d1;
wire wr_rst_asreg_d2;
reg wr_rst_asreg_d3 = 0;
reg rd_rst_wr_d0 = 0;
reg rd_rst_wr_d1 = 0;
reg rd_rst_wr_d2 = 0;
reg wr_rst_reg = 0;
reg rst_active_i = 1'b1;
reg rst_delayed_d1 = 1'b1;
reg rst_delayed_d2 = 1'b1;
wire wr_rst_comb;
wire wr_rst_i;
wire rd_rst_i;
wire rst_i;
//Internal reset signals
reg rst_asreg = 0;
reg srst_asreg = 0;
wire rst_asreg_d1;
wire rst_asreg_d2;
reg srst_asreg_d1 = 0;
reg srst_asreg_d2 = 0;
reg rst_reg = 0;
reg srst_reg = 0;
wire rst_comb;
wire srst_comb;
reg rst_full_gen_i = 0;
reg rst_full_ff_i = 0;
reg [2:0] sckt_ff0_bsy_o_i = {3{1'b0}};
wire RD_CLK_P0_IN;
wire RST_P0_IN;
wire RD_EN_FIFO_IN;
wire RD_EN_P0_IN;
wire ALMOST_EMPTY_FIFO_OUT;
wire ALMOST_FULL_FIFO_OUT;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT_FIFO_OUT;
wire [C_DOUT_WIDTH-1:0] DOUT_FIFO_OUT;
wire EMPTY_FIFO_OUT;
wire fifo_empty_fb;
wire FULL_FIFO_OUT;
wire OVERFLOW_FIFO_OUT;
wire PROG_EMPTY_FIFO_OUT;
wire PROG_FULL_FIFO_OUT;
wire VALID_FIFO_OUT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT_FIFO_OUT;
wire UNDERFLOW_FIFO_OUT;
wire WR_ACK_FIFO_OUT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT_FIFO_OUT;
//***************************************************************************
// Internal Signals
// The core uses either the internal_ wires or the preload0_ wires depending
// on whether the core uses Preload0 or not.
// When using preload0, the internal signals connect the internal core to
// the preload logic, and the external core's interfaces are tied to the
// preload0 signals from the preload logic.
//***************************************************************************
wire [C_DOUT_WIDTH-1:0] DATA_P0_OUT;
wire VALID_P0_OUT;
wire EMPTY_P0_OUT;
wire ALMOSTEMPTY_P0_OUT;
reg EMPTY_P0_OUT_Q;
reg ALMOSTEMPTY_P0_OUT_Q;
wire UNDERFLOW_P0_OUT;
wire RDEN_P0_OUT;
wire [C_DOUT_WIDTH-1:0] DATA_P0_IN;
wire EMPTY_P0_IN;
reg [31:0] DATA_COUNT_FWFT;
reg SS_FWFT_WR ;
reg SS_FWFT_RD ;
wire sbiterr_fifo_out;
wire dbiterr_fifo_out;
wire inject_sbit_err;
wire inject_dbit_err;
wire safety_ckt_wr_rst;
wire safety_ckt_rd_rst;
reg sckt_wr_rst_i_q = 1'b0;
wire w_fab_read_data_valid_i;
wire w_read_data_valid_i;
wire w_ram_valid_i;
// Assign 0 if not selected to avoid 'X' propogation to S/DBITERR.
assign inject_sbit_err = ((C_ERROR_INJECTION_TYPE == 1) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectsbiterr_delayed : 0;
assign inject_dbit_err = ((C_ERROR_INJECTION_TYPE == 2) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectdbiterr_delayed : 0;
assign wr_rst_i_out = wr_rst_i;
assign rd_rst_i_out = rd_rst_i;
assign wr_rst_busy_o = wr_rst_busy | rst_full_gen_i | sckt_ff0_bsy_o_i[2];
generate if (C_FULL_FLAGS_RST_VAL == 0 && C_EN_SAFETY_CKT == 1) begin : gsckt_bsy_o
wire clk_i = C_COMMON_CLOCK ? CLK : WR_CLK;
always @ (posedge clk_i)
sckt_ff0_bsy_o_i <= {sckt_ff0_bsy_o_i[1:0],wr_rst_busy};
end endgenerate
// Choose the behavioral model to instantiate based on the C_VERILOG_IMPL
// parameter (1=Independent Clocks, 0=Common Clock)
localparam FULL_FLAGS_RST_VAL = (C_HAS_SRST == 1) ? 0 : C_FULL_FLAGS_RST_VAL;
generate
case (C_VERILOG_IMPL)
0 : begin : block1
//Common Clock Behavioral Model
fifo_generator_v13_1_3_bhv_ver_ss
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL ((C_AXI_TYPE == 0 && C_FIFO_TYPE == 1) ? 1 : C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ss
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.CLK (CLK),
.RST (rst_i),
.SRST (srst_delayed),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.USER_EMPTY_FB (empty_fb),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.DATA_COUNT (DATA_COUNT_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
1 : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.fab_read_data_valid_i (w_fab_read_data_valid_i),
.read_data_valid_i (w_read_data_valid_i),
.ram_valid_i (w_ram_valid_i),
.DBITERR (dbiterr_fifo_out)
);
end
2 : begin : ll_afifo_inst
fifo_generator_v13_1_3_beh_ver_ll_afifo
#(
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ll_afifo
(
.DIN (din_delayed),
.RD_CLK (RD_CLK),
.RD_EN (rd_en_delayed),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.WR_CLK (WR_CLK),
.WR_EN (wr_en_delayed),
.DOUT (DOUT),
.EMPTY (EMPTY),
.FULL (FULL)
);
end
default : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
endcase
endgenerate
//**************************************************************************
// Connect Internal Signals
// (Signals labeled internal_*)
// In the normal case, these signals tie directly to the FIFO's inputs and
// outputs.
// In the case of Preload Latency 0 or 1, there are intermediate
// signals between the internal FIFO and the preload logic.
//**************************************************************************
//***********************************************
// If First-Word Fall-Through, instantiate
// the preload0 (FWFT) module
//***********************************************
wire rd_en_to_fwft_fifo;
wire sbiterr_fwft;
wire dbiterr_fwft;
wire [C_DOUT_WIDTH-1:0] dout_fwft;
wire empty_fwft;
wire rd_en_fifo_in;
wire stage2_reg_en_i;
wire [1:0] valid_stages_i;
wire rst_fwft;
//wire empty_p0_out;
reg [C_SYNCHRONIZER_STAGE-1:0] pkt_empty_sync = 'b1;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
localparam IS_PKT_FIFO = (C_FIFO_TYPE == 1) ? 1 : 0;
localparam IS_AXIS_PKT_FIFO = (C_FIFO_TYPE == 1 && C_AXI_TYPE == 0) ? 1 : 0;
assign rst_fwft = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 1'b0;
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 3) begin : block2
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
fgpl0
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (RST_P0_IN),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (RD_EN_P0_IN),
.FIFOEMPTY (EMPTY_P0_IN),
.FIFODATA (DATA_P0_IN),
.FIFOSBITERR (sbiterr_fifo_out),
.FIFODBITERR (dbiterr_fifo_out),
// Output
.USERDATA (dout_fwft),
.USERVALID (VALID_P0_OUT),
.USEREMPTY (empty_fwft),
.USERALMOSTEMPTY (ALMOSTEMPTY_P0_OUT),
.USERUNDERFLOW (UNDERFLOW_P0_OUT),
.RAMVALID (),
.FIFORDEN (rd_en_fifo_in),
.USERSBITERR (sbiterr_fwft),
.USERDBITERR (dbiterr_fwft),
.STAGE2_REG_EN (stage2_reg_en_i),
.fab_read_data_valid_i_o (w_fab_read_data_valid_i),
.read_data_valid_i_o (w_read_data_valid_i),
.ram_valid_i_o (w_ram_valid_i),
.VALID_STAGES (valid_stages_i)
);
//***********************************************
// Connect inputs to preload (FWFT) module
//***********************************************
//Connect the RD_CLK of the Preload (FWFT) module to CLK if we
// have a common-clock FIFO, or RD_CLK if we have an
// independent clock FIFO
assign RD_CLK_P0_IN = ((C_VERILOG_IMPL == 0) ? CLK : RD_CLK);
assign RST_P0_IN = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 0;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
assign EMPTY_P0_IN = C_EN_SAFETY_CKT ? fifo_empty_fb : EMPTY_FIFO_OUT;
assign DATA_P0_IN = DOUT_FIFO_OUT;
//***********************************************
// Connect outputs from preload (FWFT) module
//***********************************************
assign VALID = VALID_P0_OUT ;
assign ALMOST_EMPTY = ALMOSTEMPTY_P0_OUT;
assign UNDERFLOW = UNDERFLOW_P0_OUT ;
assign RD_EN_FIFO_IN = rd_en_fifo_in;
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
assign DATA_COUNT = (C_USE_FWFT_DATA_COUNT == 0)? DATA_COUNT_FIFO_OUT:
(C_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) ? DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:0] :
DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH+1];
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
EMPTY_P0_OUT_Q <= 1;
ALMOSTEMPTY_P0_OUT_Q <= 1;
end else begin
EMPTY_P0_OUT_Q <= #`TCQ empty_p0_out;
// EMPTY_P0_OUT_Q <= #`TCQ EMPTY_FIFO_OUT;
ALMOSTEMPTY_P0_OUT_Q <= #`TCQ ALMOSTEMPTY_P0_OUT;
end
end //always
//***********************************************
// logic for common-clock data count when FWFT is selected
//***********************************************
initial begin
SS_FWFT_RD = 1'b0;
DATA_COUNT_FWFT = 0 ;
SS_FWFT_WR = 1'b0 ;
end //initial
//***********************************************
// common-clock data count is implemented as an
// up-down counter. SS_FWFT_WR and SS_FWFT_RD
// are the up/down enables for the counter.
//***********************************************
always @ (RD_EN or VALID_P0_OUT or WR_EN or FULL_FIFO_OUT or empty_p0_out) begin
if (C_VALID_LOW == 1) begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && ~VALID_P0_OUT) : (~empty_p0_out && RD_EN && ~VALID_P0_OUT) ;
end else begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && VALID_P0_OUT) : (~empty_p0_out && RD_EN && VALID_P0_OUT) ;
end
SS_FWFT_WR = (WR_EN && (~FULL_FIFO_OUT)) ;
end
//***********************************************
// common-clock data count is implemented as an
// up-down counter for FWFT. This always block
// calculates the counter.
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
DATA_COUNT_FWFT <= 0;
end else begin
//if (srst_delayed && (C_HAS_SRST == 1) ) begin
if ((srst_delayed | wr_rst_busy | rd_rst_busy) && (C_HAS_SRST == 1) ) begin
DATA_COUNT_FWFT <= #`TCQ 0;
end else begin
case ( {SS_FWFT_WR, SS_FWFT_RD})
2'b00: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
2'b01: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT - 1 ;
2'b10: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT + 1 ;
2'b11: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
endcase
end //if SRST
end //IF RST
end //always
end endgenerate // : block2
// AXI Streaming Packet FIFO
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_plus1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_reg = 0;
reg partial_packet = 0;
reg stage1_eop_d1 = 0;
reg rd_en_fifo_in_d1 = 0;
reg eop_at_stage2 = 0;
reg ram_pkt_empty = 0;
reg ram_pkt_empty_d1 = 0;
wire [C_DOUT_WIDTH-1:0] dout_p0_out;
wire packet_empty_wr;
wire wr_rst_fwft_pkt_fifo;
wire dummy_wr_eop;
wire ram_wr_en_pkt_fifo;
wire wr_eop;
wire ram_rd_en_compare;
wire stage1_eop;
wire pkt_ready_to_read;
wire rd_en_2_stage2;
// Generate Dummy WR_EOP for partial packet (Only for AXI Streaming)
// When Packet EMPTY is high, and FIFO is full, then generate the dummy WR_EOP
// When dummy WR_EOP is high, mask the actual EOP to avoid double increment of
// write packet count
generate if (IS_FWFT == 1 && IS_AXIS_PKT_FIFO == 1) begin // gdummy_wr_eop
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
partial_packet <= 1'b0;
else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy)
partial_packet <= #`TCQ 1'b0;
else if (ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]))
partial_packet <= #`TCQ 1'b1;
else if (partial_packet && din_delayed[0] && ram_wr_en_pkt_fifo)
partial_packet <= #`TCQ 1'b0;
end
end
end endgenerate // gdummy_wr_eop
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1) begin // gpkt_fifo_fwft
assign wr_rst_fwft_pkt_fifo = (C_COMMON_CLOCK == 0) ? wr_rst_i : (C_HAS_RST == 1) ? rst_i:1'b0;
assign dummy_wr_eop = ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]) && (~partial_packet);
assign packet_empty_wr = (C_COMMON_CLOCK == 1) ? empty_p0_out : pkt_empty_sync[C_SYNCHRONIZER_STAGE-1];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
stage1_eop_d1 <= 1'b0;
rd_en_fifo_in_d1 <= 1'b0;
end else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
stage1_eop_d1 <= #`TCQ 1'b0;
rd_en_fifo_in_d1 <= #`TCQ 1'b0;
end else begin
stage1_eop_d1 <= #`TCQ stage1_eop;
rd_en_fifo_in_d1 <= #`TCQ rd_en_fifo_in;
end
end
end
assign stage1_eop = (rd_en_fifo_in_d1) ? DOUT_FIFO_OUT[0] : stage1_eop_d1;
assign ram_wr_en_pkt_fifo = wr_en_delayed && (~FULL_FIFO_OUT);
assign wr_eop = ram_wr_en_pkt_fifo && ((din_delayed[0] && (~partial_packet)) || dummy_wr_eop);
assign ram_rd_en_compare = stage2_reg_en_i && stage1_eop;
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (2) // Enable low latency fwft logic
)
pkt_fifo_fwft
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (rst_fwft),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (rd_en_delayed),
.FIFOEMPTY (pkt_ready_to_read),
.FIFODATA (dout_fwft),
.FIFOSBITERR (sbiterr_fwft),
.FIFODBITERR (dbiterr_fwft),
// Output
.USERDATA (dout_p0_out),
.USERVALID (),
.USEREMPTY (empty_p0_out),
.USERALMOSTEMPTY (),
.USERUNDERFLOW (),
.RAMVALID (),
.FIFORDEN (rd_en_2_stage2),
.USERSBITERR (SBITERR),
.USERDBITERR (DBITERR),
.STAGE2_REG_EN (),
.VALID_STAGES ()
);
assign pkt_ready_to_read = ~(!(ram_pkt_empty || empty_fwft) && ((valid_stages_i[0] && valid_stages_i[1]) || eop_at_stage2));
assign rd_en_to_fwft_fifo = ~empty_fwft && rd_en_2_stage2;
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
eop_at_stage2 <= 1'b0;
else if (stage2_reg_en_i)
eop_at_stage2 <= #`TCQ stage1_eop;
end
//---------------------------------------------------------------------------
// Write and Read Packet Count
//---------------------------------------------------------------------------
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count <= 0;
else if (srst_delayed | wr_rst_busy | rd_rst_busy)
wr_pkt_count <= #`TCQ 0;
else if (wr_eop)
wr_pkt_count <= #`TCQ wr_pkt_count + 1;
end
end endgenerate // gpkt_fifo_fwft
assign DOUT = (C_FIFO_TYPE != 1) ? dout_fwft : dout_p0_out;
assign EMPTY = (C_FIFO_TYPE != 1) ? empty_fwft : empty_p0_out;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 1) begin // grss_pkt_cnt
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
rd_pkt_count <= 0;
rd_pkt_count_plus1 <= 1;
end else if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
rd_pkt_count <= #`TCQ 0;
rd_pkt_count_plus1 <= #`TCQ 1;
end else if (stage2_reg_en_i && stage1_eop) begin
rd_pkt_count <= #`TCQ rd_pkt_count + 1;
rd_pkt_count_plus1 <= #`TCQ rd_pkt_count_plus1 + 1;
end
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (SRST | wr_rst_busy | rd_rst_busy) begin
ram_pkt_empty <= #`TCQ 1'b1;
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count) && wr_eop) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count_plus1 == wr_pkt_count) && ~wr_eop && ~ALMOST_FULL_FIFO_OUT && ram_rd_en_compare) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
end endgenerate //grss_pkt_cnt
localparam SYNC_STAGE_WIDTH = (C_SYNCHRONIZER_STAGE+1)*C_WR_PNTR_WIDTH;
reg [SYNC_STAGE_WIDTH-1:0] wr_pkt_count_q = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_b2g = 0;
wire [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_rd;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 0) begin // gras_pkt_cnt
// Delay the write packet count in write clock domain to accomodate the binary to gray conversion delay
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count_b2g <= 0;
else
wr_pkt_count_b2g <= #`TCQ wr_pkt_count;
end
// Synchronize the delayed write packet count in read domain, and also compensate the gray to binay conversion delay
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
wr_pkt_count_q <= 0;
else
wr_pkt_count_q <= #`TCQ {wr_pkt_count_q[SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH-1:0],wr_pkt_count_b2g};
end
always @* begin
if (stage1_eop)
rd_pkt_count <= rd_pkt_count_reg + 1;
else
rd_pkt_count <= rd_pkt_count_reg;
end
assign wr_pkt_count_rd = wr_pkt_count_q[SYNC_STAGE_WIDTH-1:SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
rd_pkt_count_reg <= 0;
else if (rd_en_fifo_in)
rd_pkt_count_reg <= #`TCQ rd_pkt_count;
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (rd_pkt_count != wr_pkt_count_rd) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count_rd) && stage2_reg_en_i) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
// Synchronize the empty in write domain
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
pkt_empty_sync <= 'b1;
else
pkt_empty_sync <= #`TCQ {pkt_empty_sync[C_SYNCHRONIZER_STAGE-2:0], empty_p0_out};
end
end endgenerate //gras_pkt_cnt
generate if (IS_FWFT == 0 || C_FIFO_TYPE == 3) begin : STD_FIFO
//***********************************************
// If NOT First-Word Fall-Through, wire the outputs
// of the internal _ss or _as FIFO directly to the
// output, and do not instantiate the preload0
// module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VALID = VALID_FIFO_OUT;
assign EMPTY = EMPTY_FIFO_OUT;
assign ALMOST_EMPTY = ALMOST_EMPTY_FIFO_OUT;
assign EMPTY_P0_IN = 0;
assign UNDERFLOW = UNDERFLOW_FIFO_OUT;
assign DATA_COUNT = DATA_COUNT_FIFO_OUT;
assign SBITERR = sbiterr_fifo_out;
assign DBITERR = dbiterr_fifo_out;
end endgenerate // STD_FIFO
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 1) begin : NO_PKT_FIFO
assign empty_p0_out = empty_fwft;
assign SBITERR = sbiterr_fwft;
assign DBITERR = dbiterr_fwft;
assign DOUT = dout_fwft;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
end endgenerate // NO_PKT_FIFO
//***********************************************
// Connect user flags to internal signals
//***********************************************
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//RD_DATA_COUNT is 0 when EMPTY and 1 when ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block3
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : RD_DATA_COUNT_FIFO_OUT);
end //block_ic
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block30
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : RD_DATA_COUNT_FIFO_OUT);
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block30_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : (RD_DATA_COUNT_FIFO_OUT));
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30_both
endgenerate
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block3_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : (RD_DATA_COUNT_FIFO_OUT));
end //block_ic_both
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3_both
endgenerate
//If we are not using extra logic for the FWFT data count,
//then connect RD_DATA_COUNT to the RD_DATA_COUNT from the
//internal FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==0 ) begin : block31
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Always connect WR_DATA_COUNT to the WR_DATA_COUNT from the internal
//FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==1) begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
else begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Connect other flags to the internal FIFO instance
assign FULL = FULL_FIFO_OUT;
assign ALMOST_FULL = ALMOST_FULL_FIFO_OUT;
assign WR_ACK = WR_ACK_FIFO_OUT;
assign OVERFLOW = OVERFLOW_FIFO_OUT;
assign PROG_FULL = PROG_FULL_FIFO_OUT;
assign PROG_EMPTY = PROG_EMPTY_FIFO_OUT;
/**************************************************************************
* find_log2
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// if an asynchronous FIFO has been selected, display a message that the FIFO
// will not be cycle-accurate in simulation
initial begin
if (C_IMPLEMENTATION_TYPE == 2) begin
$display("WARNING: Behavioral models for independent clock FIFO configurations do not model synchronization delays. The behavioral models are functionally correct, and will represent the behavior of the configured FIFO. See the FIFO Generator User Guide for more information.");
end else if (C_MEMORY_TYPE == 4) begin
$display("FAILURE : Behavioral models do not support built-in FIFO configurations. Please use post-synthesis or post-implement simulation in Vivado.");
$finish;
end
if (C_WR_PNTR_WIDTH != find_log2(C_WR_DEPTH)) begin
$display("FAILURE : C_WR_PNTR_WIDTH is not log2 of C_WR_DEPTH.");
$finish;
end
if (C_RD_PNTR_WIDTH != find_log2(C_RD_DEPTH)) begin
$display("FAILURE : C_RD_PNTR_WIDTH is not log2 of C_RD_DEPTH.");
$finish;
end
if (C_USE_ECC == 1) begin
if (C_DIN_WIDTH != C_DOUT_WIDTH) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be equal for ECC configuration.");
$finish;
end
if (C_DIN_WIDTH == 1 && C_ERROR_INJECTION_TYPE > 1) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be > 1 for double bit error injection.");
$finish;
end
end
end //initial
/**************************************************************************
* Internal reset logic
**************************************************************************/
assign wr_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? wr_rst_reg : 0;
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? rd_rst_reg : 0;
assign rst_i = C_HAS_RST ? rst_reg : 0;
wire rst_2_sync;
wire rst_2_sync_safety = (C_ENABLE_RST_SYNC == 1) ? rst_delayed : RD_RST;
wire clk_2_sync = (C_COMMON_CLOCK == 1) ? CLK : WR_CLK;
wire clk_2_sync_safety = (C_COMMON_CLOCK == 1) ? CLK : RD_CLK;
localparam RST_SYNC_STAGES = (C_EN_SAFETY_CKT == 0) ? C_SYNCHRONIZER_STAGE :
(C_COMMON_CLOCK == 1) ? 3 : C_SYNCHRONIZER_STAGE+2;
reg [RST_SYNC_STAGES-1:0] wrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] arst_sync_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_wr = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_ext = {RST_SYNC_STAGES{1'b0}};
reg [1:0] wrst_cc = {2{1'b0}};
reg [1:0] rrst_cc = {2{1'b0}};
generate
if (C_EN_SAFETY_CKT == 1 && C_INTERFACE_TYPE == 0) begin : grst_safety_ckt
reg[1:0] rst_d1_safety =1;
reg[1:0] rst_d2_safety =1;
reg[1:0] rst_d3_safety =1;
reg[1:0] rst_d4_safety =1;
reg[1:0] rst_d5_safety =1;
reg[1:0] rst_d6_safety =1;
reg[1:0] rst_d7_safety =1;
always@(posedge rst_2_sync_safety or posedge clk_2_sync_safety) begin : prst
if (rst_2_sync_safety == 1'b1) begin
rst_d1_safety <= 1'b1;
rst_d2_safety <= 1'b1;
rst_d3_safety <= 1'b1;
rst_d4_safety <= 1'b1;
rst_d5_safety <= 1'b1;
rst_d6_safety <= 1'b1;
rst_d7_safety <= 1'b1;
end
else begin
rst_d1_safety <= #`TCQ 1'b0;
rst_d2_safety <= #`TCQ rst_d1_safety;
rst_d3_safety <= #`TCQ rst_d2_safety;
rst_d4_safety <= #`TCQ rst_d3_safety;
rst_d5_safety <= #`TCQ rst_d4_safety;
rst_d6_safety <= #`TCQ rst_d5_safety;
rst_d7_safety <= #`TCQ rst_d6_safety;
end //if
end //prst
always@(posedge rst_d7_safety or posedge WR_EN) begin : assert_safety
if(rst_d7_safety == 1 && WR_EN == 1) begin
$display("WARNING:A write attempt has been made within the 7 clock cycles of reset de-assertion. This can lead to data discrepancy when safety circuit is enabled.");
end //if
end //always
end // grst_safety_ckt
endgenerate
// if (C_EN_SAFET_CKT == 1)
// assertion:the reset shud be atleast 3 cycles wide.
generate
reg safety_ckt_wr_rst_i = 1'b0;
if (C_ENABLE_RST_SYNC == 0) begin : gnrst_sync
always @* begin
wr_rst_reg <= wr_rst_delayed;
rd_rst_reg <= rd_rst_delayed;
rst_reg <= 1'b0;
srst_reg <= 1'b0;
end
assign rst_2_sync = wr_rst_delayed;
assign wr_rst_busy = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
// end : gnrst_sync
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 0) begin : g7s_ic_rst
reg fifo_wrst_done = 1'b0;
reg fifo_rrst_done = 1'b0;
reg sckt_wrst_i = 1'b0;
reg sckt_wrst_i_q = 1'b0;
reg rd_rst_active = 1'b0;
reg rd_rst_middle = 1'b0;
reg sckt_rd_rst_d1 = 1'b0;
reg [1:0] rst_delayed_ic_w = 2'h0;
wire rst_delayed_ic_w_i;
reg [1:0] rst_delayed_ic_r = 2'h0;
wire rst_delayed_ic_r_i;
wire arst_sync_rst;
wire fifo_rst_done;
wire fifo_rst_active;
assign wr_rst_comb = !wr_rst_asreg_d2 && wr_rst_asreg;
assign rd_rst_comb = C_EN_SAFETY_CKT ? (!rd_rst_asreg_d2 && rd_rst_asreg) || rd_rst_active : !rd_rst_asreg_d2 && rd_rst_asreg;
assign rst_2_sync = rst_delayed_ic_w_i;
assign arst_sync_rst = arst_sync_q[RST_SYNC_STAGES-1];
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | fifo_rst_active : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? safety_ckt_rd_rst : 1'b0;
assign fifo_rst_done = fifo_wrst_done & fifo_rrst_done;
assign fifo_rst_active = sckt_wrst_i | wrst_ext[RST_SYNC_STAGES-1] | rrst_wr[RST_SYNC_STAGES-1];
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_w <= 2'b11;
else
rst_delayed_ic_w <= #`TCQ {rst_delayed_ic_w[0],1'b0};
end
assign rst_delayed_ic_w_i = rst_delayed_ic_w[1];
always @(posedge RD_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_r <= 2'b11;
else
rst_delayed_ic_r <= #`TCQ {rst_delayed_ic_r[0],1'b0};
end
assign rst_delayed_ic_r_i = rst_delayed_ic_r[1];
always @(posedge WR_CLK) begin
sckt_wrst_i_q <= #`TCQ sckt_wrst_i;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ sckt_wrst_i | wr_rst_busy | sckt_wr_rst_i_q;
if (arst_sync_rst && ~fifo_rst_active)
sckt_wrst_i <= #`TCQ 1'b1;
else if (sckt_wrst_i && fifo_rst_done)
sckt_wrst_i <= #`TCQ 1'b0;
else
sckt_wrst_i <= #`TCQ sckt_wrst_i;
if (rrst_wr[RST_SYNC_STAGES-2] & ~rrst_wr[RST_SYNC_STAGES-1])
fifo_rrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_rrst_done <= #`TCQ 1'b0;
else
fifo_rrst_done <= #`TCQ fifo_rrst_done;
if (wrst_ext[RST_SYNC_STAGES-2] & ~wrst_ext[RST_SYNC_STAGES-1])
fifo_wrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_wrst_done <= #`TCQ 1'b0;
else
fifo_wrst_done <= #`TCQ fifo_wrst_done;
end
always @(posedge WR_CLK or posedge rst_delayed_ic_w_i) begin
if (rst_delayed_ic_w_i == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],wr_rst_asreg};
wrst_ext <= #`TCQ {wrst_ext[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_wr <= #`TCQ {rrst_wr[RST_SYNC_STAGES-2:0],safety_ckt_rd_rst};
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_ic_w_i};
end
assign wr_rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign wr_rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge WR_CLK or posedge wr_rst_comb) begin
if (wr_rst_comb == 1'b1) begin
wr_rst_reg <= 1'b1;
end else begin
wr_rst_reg <= #`TCQ 1'b0;
end
end
always @(posedge RD_CLK or posedge rst_delayed_ic_r_i) begin
if (rst_delayed_ic_r_i == 1'b1) begin
rd_rst_asreg <= 1'b1;
end else begin
if (rd_rst_asreg_d1 == 1'b1) begin
rd_rst_asreg <= #`TCQ 1'b0;
end else begin
rd_rst_asreg <= #`TCQ rd_rst_asreg;
end
end
end
always @(posedge RD_CLK) begin
rrst_reg <= #`TCQ {rrst_reg[RST_SYNC_STAGES-2:0],rd_rst_asreg};
rrst_q <= #`TCQ {rrst_q[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_cc <= #`TCQ {rrst_cc[0],rd_rst_asreg_d2};
sckt_rd_rst_d1 <= #`TCQ safety_ckt_rd_rst;
if (!rd_rst_middle && rrst_reg[1] && !rrst_reg[2]) begin
rd_rst_active <= #`TCQ 1'b1;
rd_rst_middle <= #`TCQ 1'b1;
end else if (safety_ckt_rd_rst)
rd_rst_active <= #`TCQ 1'b0;
else if (sckt_rd_rst_d1 && !safety_ckt_rd_rst)
rd_rst_middle <= #`TCQ 1'b0;
end
assign rd_rst_asreg_d1 = rrst_reg[RST_SYNC_STAGES-2];
assign rd_rst_asreg_d2 = C_EN_SAFETY_CKT ? rrst_reg[RST_SYNC_STAGES-1] : rrst_reg[1];
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rrst_q[2] : 1'b0;
always @(posedge RD_CLK or posedge rd_rst_comb) begin
if (rd_rst_comb == 1'b1) begin
rd_rst_reg <= 1'b1;
end else begin
rd_rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_ic_rst
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 1) begin : g7s_cc_rst
reg [1:0] rst_delayed_cc = 2'h0;
wire rst_delayed_cc_i;
assign rst_comb = !rst_asreg_d2 && rst_asreg;
assign rst_2_sync = rst_delayed_cc_i;
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | wrst_cc[1] : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? arst_sync_q[1] | arst_sync_q[RST_SYNC_STAGES-1] | wrst_cc[1] : 1'b0;
always @(posedge CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1)
rst_delayed_cc <= 2'b11;
else
rst_delayed_cc <= #`TCQ {rst_delayed_cc,1'b0};
end
assign rst_delayed_cc_i = rst_delayed_cc[1];
always @(posedge CLK or posedge rst_delayed_cc_i) begin
if (rst_delayed_cc_i == 1'b1) begin
rst_asreg <= 1'b1;
end else begin
if (rst_asreg_d1 == 1'b1) begin
rst_asreg <= #`TCQ 1'b0;
end else begin
rst_asreg <= #`TCQ rst_asreg;
end
end
end
always @(posedge CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],rst_asreg};
wrst_cc <= #`TCQ {wrst_cc[0],arst_sync_q[RST_SYNC_STAGES-1]};
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ wrst_cc[1] | wr_rst_busy | sckt_wr_rst_i_q;
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_cc_i};
end
assign rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge CLK or posedge rst_comb) begin
if (rst_comb == 1'b1) begin
rst_reg <= 1'b1;
end else begin
rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_cc_rst
end else if (IS_8SERIES == 1 && C_HAS_SRST == 1 && C_COMMON_CLOCK == 1) begin : g8s_cc_rst
assign wr_rst_busy = (C_MEMORY_TYPE != 4) ? rst_reg : rst_active_i;
assign rd_rst_busy = rst_reg;
assign rst_2_sync = srst_delayed;
always @* rst_full_ff_i <= rst_reg;
always @* rst_full_gen_i <= C_FULL_FLAGS_RST_VAL == 1 ? rst_active_i : 0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
always @(posedge CLK) begin
rst_delayed_d1 <= #`TCQ srst_delayed;
rst_delayed_d2 <= #`TCQ rst_delayed_d1;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
if (rst_reg || rst_delayed_d2) begin
rst_active_i <= #`TCQ 1'b1;
end else begin
rst_active_i <= #`TCQ rst_reg;
end
end
always @(posedge CLK) begin
if (~rst_reg && srst_delayed) begin
rst_reg <= #`TCQ 1'b1;
end else if (rst_reg) begin
rst_reg <= #`TCQ 1'b0;
end else begin
rst_reg <= #`TCQ rst_reg;
end
end
// end : g8s_cc_rst
end else begin
assign wr_rst_busy = 1'b0;
assign rd_rst_busy = 1'b0;
assign safety_ckt_wr_rst = 1'b0;
assign safety_ckt_rd_rst = 1'b0;
end
endgenerate
generate
if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 1) begin : grstd1
// RST_FULL_GEN replaces the reset falling edge detection used to de-assert
// FULL, ALMOST_FULL & PROG_FULL flags if C_FULL_FLAGS_RST_VAL = 1.
// RST_FULL_FF goes to the reset pin of the final flop of FULL, ALMOST_FULL &
// PROG_FULL
reg rst_d1 = 1'b0;
reg rst_d2 = 1'b0;
reg rst_d3 = 1'b0;
reg rst_d4 = 1'b0;
reg rst_d5 = 1'b0;
always @ (posedge rst_2_sync or posedge clk_2_sync) begin
if (rst_2_sync) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
rst_d3 <= 1'b1;
rst_d4 <= 1'b1;
end else begin
if (srst_delayed) begin
rst_d1 <= #`TCQ 1'b1;
rst_d2 <= #`TCQ 1'b1;
rst_d3 <= #`TCQ 1'b1;
rst_d4 <= #`TCQ 1'b1;
end else begin
rst_d1 <= #`TCQ wr_rst_busy;
rst_d2 <= #`TCQ rst_d1;
rst_d3 <= #`TCQ rst_d2 | safety_ckt_wr_rst;
rst_d4 <= #`TCQ rst_d3;
end
end
end
always @* rst_full_ff_i <= (C_HAS_SRST == 0) ? rst_d2 : 1'b0 ;
always @* rst_full_gen_i <= rst_d3;
end else if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 0) begin : gnrst_full
always @* rst_full_ff_i <= (C_COMMON_CLOCK == 0) ? wr_rst_i : rst_i;
end
endgenerate // grstd1
endmodule //fifo_generator_v13_1_3_conv_ver
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0;
else
DOUT <= #`TCQ DIN;
end
endmodule // fifo_generator_v13_1_3_sync_stage
/*******************************************************************************
* Declaration of Independent-Clocks FIFO Module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_as
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input SAFETY_CKT_WR_RST,
input SAFETY_CKT_RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_CLK,
input RD_EN,
input RD_EN_USER,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input USER_EMPTY_FB,
input fab_read_data_valid_i,
input read_data_valid_i,
input ram_valid_i,
output reg ALMOST_EMPTY = 1'b1,
output reg ALMOST_FULL = C_FULL_FLAGS_RST_VAL,
output [C_DOUT_WIDTH-1:0] DOUT,
output reg EMPTY = 1'b1,
output reg EMPTY_FB = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL,
output OVERFLOW,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output UNDERFLOW,
output WR_ACK,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC_1 && SYMMETRIC_PORT && ERR_INJECTION;
// Array that holds the error injection type (single/double bit error) on
// a specific write operation, which is returned on read to corrupt the
// output data.
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
//The amount of data stored in the FIFO at any time is given
// by num_wr_bits (in the WR_CLK domain) and num_rd_bits (in the RD_CLK
// domain.
//num_wr_bits is calculated by considering the total words in the FIFO,
// and the state of the read pointer (which may not have yet crossed clock
// domains.)
//num_rd_bits is calculated by considering the total words in the FIFO,
// and the state of the write pointer (which may not have yet crossed clock
// domains.)
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
wire wr_rst_i = WR_RST;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire rd_rst_i = RD_RST;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
// Delayed ram_rd_en is needed only for STD Embedded register option
generate
if (C_PRELOAD_LATENCY == 2) begin : grd_d
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
end
endgenerate
generate
if (C_PRELOAD_LATENCY == 2 && C_USE_EMBEDDED_REG == 3) begin : grd_d1
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
endgenerate
// Write pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : rdg // Read depth greater than write depth
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1:0] = 0;
end else begin : rdl // Read depth lesser than or equal to write depth
assign adj_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
endgenerate
// Generate Empty and Almost Empty
// ram_rd_en used to determine EMPTY should depend on the EMPTY.
assign ram_rd_en = RD_EN & !EMPTY;
assign empty_int = ((adj_wr_pntr_rd == rd_pntr) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+1'h1))));
assign almost_empty_int = ((adj_wr_pntr_rd == (rd_pntr+1'h1)) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+2'h2))));
// Register Empty and Almost Empty
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin
EMPTY <= 1'b1;
ALMOST_EMPTY <= 1'b1;
rd_data_count_int <= {C_RD_PNTR_WIDTH{1'b0}};
end else begin
rd_data_count_int <= #`TCQ {(adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:0] - rd_pntr[C_RD_PNTR_WIDTH-1:0]), 1'b0};
if (empty_int)
EMPTY <= #`TCQ 1'b1;
else
EMPTY <= #`TCQ 1'b0;
if (!EMPTY) begin
if (almost_empty_int)
ALMOST_EMPTY <= #`TCQ 1'b1;
else
ALMOST_EMPTY <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (SAFETY_CKT_RD_RST && C_EN_SAFETY_CKT)
EMPTY_FB <= #`TCQ 1'b1;
else if (empty_int)
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ 1'b0;
end // rd_rst_i
end // always
// Read pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wdg // Write depth greater than read depth
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1:0] = 0;
end else begin : wdl // Write depth lesser than or equal to read depth
assign adj_rd_pntr_wr = rd_pntr_wr[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end
endgenerate
// Generate FULL and ALMOST_FULL
// ram_wr_en used to determine FULL should depend on the FULL.
assign ram_wr_en = WR_EN & !FULL;
assign full_int = ((adj_rd_pntr_wr == (wr_pntr+1'h1)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+2'h2))));
assign almost_full_int = ((adj_rd_pntr_wr == (wr_pntr+2'h2)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+3'h3))));
// Register FULL and ALMOST_FULL Empty
always @ (posedge WR_CLK or posedge RST_FULL_FF)
begin
if (RST_FULL_FF) begin
FULL <= C_FULL_FLAGS_RST_VAL;
ALMOST_FULL <= C_FULL_FLAGS_RST_VAL;
end else begin
if (full_int) begin
FULL <= #`TCQ 1'b1;
end else begin
FULL <= #`TCQ 1'b0;
end
if (RST_FULL_GEN) begin
ALMOST_FULL <= #`TCQ 1'b0;
end else if (!FULL) begin
if (almost_full_int)
ALMOST_FULL <= #`TCQ 1'b1;
else
ALMOST_FULL <= #`TCQ 1'b0;
end
end // wr_rst_i
end // always
always @ (posedge WR_CLK or posedge wr_rst_i)
begin
if (wr_rst_i) begin
wr_data_count_int <= {C_WR_DATA_COUNT_WIDTH{1'b0}};
end else begin
wr_data_count_int <= #`TCQ {(wr_pntr[C_WR_PNTR_WIDTH-1:0] - adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:0]), 1'b0};
end // wr_rst_i
end // always
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
stage1_valid <= 0;
stage2_valid <= 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//Pointers passed into opposite clock domain
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_EMPTY.
wire [31:0] num_read_words_pe =
num_rd_bits/(C_DOUT_WIDTH/C_DEPTH_RATIO_WR);
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_FULL.
wire [31:0] num_write_words_pf =
num_wr_bits/(C_DIN_WIDTH/C_DEPTH_RATIO_RD);
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/***************************************************************************
* Internal registers and wires
**************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire valid_i;
wire valid_out1;
wire valid_out2;
wire valid_out;
wire underflow_i;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
reg valid_d1 = 0;
reg valid_d2 = 0;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/****************************************************************************
* Function Declarations
***************************************************************************/
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
/***********************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_d2 = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_CLK;
wire RD_EN;
wire RST;
wire WR_CLK;
wire WR_EN;
*/
//***************************************************************************
// Dout may change behavior based on latency
//***************************************************************************
assign ideal_dout_out[C_DOUT_WIDTH-1:0] = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) )?
ideal_dout_d1: ideal_dout;
assign DOUT[C_DOUT_WIDTH-1:0] = ideal_dout_out;
//***************************************************************************
// Assign SBITERR and DBITERR based on latency
//***************************************************************************
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY == 2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) ) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY==2 && (C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
//***************************************************************************
// Safety-ckt logic with embedded reg/fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
// if (C_HAS_VALID == 1) begin
// assign valid_out = valid_d1;
// end
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK)
begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else begin
if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end
end
endgenerate
//***************************************************************************
// Safety-ckt logic with embedded reg + fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK) begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else begin
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end
endgenerate
//***************************************************************************
// Overflow may be active-low
//***************************************************************************
generate
if (C_HAS_OVERFLOW==1) begin : blockOF1
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end
endgenerate
assign PROG_EMPTY = ideal_prog_empty;
assign PROG_FULL = ideal_prog_full;
//***************************************************************************
// Valid may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_VALID==1) begin : blockVL1
assign valid_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out1 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG < 3)?
valid_d1: valid_i;
assign valid_out2 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG == 3)?
valid_d2: valid_i;
assign valid_out = (C_USE_EMBEDDED_REG == 3) ? valid_out2 : valid_out1;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end
endgenerate
//***************************************************************************
// Underflow may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_UNDERFLOW==1) begin : blockUF1
assign underflow_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & EMPTY) : ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end
endgenerate
//***************************************************************************
// Write acknowledge may be active low
//***************************************************************************
generate
if (C_HAS_WR_ACK==1) begin : blockWK1
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : wdc_fwft_ext
reg [C_PNTR_WIDTH-1:0] adjusted_wr_pntr = 0;
reg [C_PNTR_WIDTH-1:0] adjusted_rd_pntr = 0;
wire [C_PNTR_WIDTH-1:0] diff_wr_rd_tmp;
wire [C_PNTR_WIDTH:0] diff_wr_rd;
reg [C_PNTR_WIDTH:0] wr_data_count_i = 0;
always @* begin
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = 0;
adjusted_rd_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
end else if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin
adjusted_rd_pntr = rd_pntr_wr;
adjusted_wr_pntr = 0;
adjusted_wr_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
end else begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = rd_pntr_wr;
end
end // always @*
assign diff_wr_rd_tmp = adjusted_wr_pntr - adjusted_rd_pntr;
assign diff_wr_rd = {1'b0,diff_wr_rd_tmp};
always @ (posedge wr_rst_i or posedge WR_CLK)
begin
if (wr_rst_i)
wr_data_count_i <= 0;
else
wr_data_count_i <= #`TCQ diff_wr_rd + EXTRA_WORDS_DC;
end // always @ (posedge WR_CLK or posedge WR_CLK)
always @* begin
if (C_WR_PNTR_WIDTH >= C_RD_PNTR_WIDTH)
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:0];
else
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end // always @*
end // wdc_fwft_ext
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
reg [C_RD_PNTR_WIDTH:0] rdc_fwft_ext_as = 0;
generate if (C_USE_EMBEDDED_REG < 3) begin: rdc_fwft_ext_both
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= 0;
end else begin
if (!stage2_valid)
rdc_fwft_ext_as <= #`TCQ 0;
else if (!stage1_valid && stage2_valid)
rdc_fwft_ext_as <= #`TCQ 1;
else
rdc_fwft_ext_as <= #`TCQ diff_rd_wr + 2'h2;
end
end // always @ (posedge WR_CLK or posedge WR_CLK)
end // rdc_fwft_ext
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3) begin
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr_1;
// assign diff_rd_wr_1 = diff_rd_wr +2'h2;
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= #`TCQ 0;
end else begin
//if (fab_read_data_valid_i == 1'b0 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b0;
//else if (fab_read_data_valid_i == 1'b1 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b1;
//else
rdc_fwft_ext_as <= diff_rd_wr + 2'h2 ;
end
end
end
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = C_USE_FWFT_DATA_COUNT ?
rdc_fwft_ext_as[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH] :
rd_data_count_int[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = (C_USE_FWFT_DATA_COUNT == 1) ?
wdc_fwft_ext_as[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] :
wr_data_count_int[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate
if (C_HAS_VALID==1) begin : blockVL2
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_d2 <= 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
valid_d2 <= #`TCQ valid_d1;
end
// if (C_USE_EMBEDDED_REG == 3 && (C_EN_SAFETY_CKT == 0 || C_EN_SAFETY_CKT == 1 ) begin
// valid_d2 <= #`TCQ valid_d1;
// end
end
end
endgenerate
//Capture delayed version of dout
/**************************************************************************
*embedded/fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG < 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0)
err_type_d1 <= #`TCQ 0;
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
endgenerate
/**************************************************************************
*embedded + fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG == 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate
if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge WR_CLK) begin
ideal_overflow <= #`TCQ WR_EN & FULL;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge WR_CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (FULL | wr_rst_i);
ideal_overflow <= #`TCQ WR_EN & (FULL );
end
end
endgenerate
generate
if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ EMPTY & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ (EMPTY) & RD_EN;
//ideal_underflow <= #`TCQ (rd_rst_i | EMPTY) & RD_EN;
end
end
endgenerate
/**************************************************************************
* Write/Read Pointer Synchronization
**************************************************************************/
localparam NO_OF_SYNC_STAGE_INC_G2B = C_SYNCHRONIZER_STAGE + 1;
wire [C_WR_PNTR_WIDTH-1:0] wr_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
genvar gss;
generate for (gss = 1; gss <= NO_OF_SYNC_STAGE_INC_G2B; gss = gss + 1) begin : Sync_stage_inst
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_WR_PNTR_WIDTH)
)
rd_stg_inst
(
.RST (rd_rst_i),
.CLK (RD_CLK),
.DIN (wr_pntr_sync_stgs[gss-1]),
.DOUT (wr_pntr_sync_stgs[gss])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_RD_PNTR_WIDTH)
)
wr_stg_inst
(
.RST (wr_rst_i),
.CLK (WR_CLK),
.DIN (rd_pntr_sync_stgs[gss-1]),
.DOUT (rd_pntr_sync_stgs[gss])
);
end endgenerate // Sync_stage_inst
assign wr_pntr_sync_stgs[0] = wr_pntr_rd1;
assign rd_pntr_sync_stgs[0] = rd_pntr_wr1;
always@* begin
wr_pntr_rd <= wr_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
rd_pntr_wr <= rd_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
end
/**************************************************************************
* Write Domain Logic
**************************************************************************/
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_wp
if (wr_rst_i == 1'b1 && C_EN_SAFETY_CKT == 0)
wr_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_WR_RST == 1'b1)
wr_pntr <= #`TCQ 0;
end
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (wr_rst_i == 1'b1) begin
num_wr_bits <= 0;
next_num_wr_bits = 0;
wr_ptr <= C_WR_DEPTH - 1;
rd_ptr_wrclk <= C_RD_DEPTH - 1;
ideal_wr_ack <= 0;
ideal_wr_count <= 0;
tmp_wr_listsize = 0;
rd_ptr_wrclk_next <= 0;
wr_pntr_rd1 <= 0;
end else begin //wr_rst_i==0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
//If this is a write, handle the write by adding the value
// to the linked list, and updating all outputs appropriately
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD
>= C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full, but reporting full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//With DEPTH-1 words in the FIFO, it is almost_full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is completely empty, but it is
// reporting FULL for some reason (like reset)
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <=
C_FIFO_WR_DEPTH-2) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//FIFO is really not close to full, so change flag status.
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end //(tmp_wr_listsize == 0)
end else begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD >=
C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//This write is CAUSING the FIFO to go full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is 2 from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Still 2 from full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is not close to being full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //wr_rst_i==0
end // gen_fifo_w
/***************************************************************************
* Programmable FULL flags
***************************************************************************/
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_assert_val;
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_negate_val;
generate if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin : FWFT
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_DC;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_DC;
end else begin // STD
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL;
end endgenerate
always @(posedge WR_CLK or posedge wr_rst_i) begin
if (wr_rst_i == 1'b1) begin
diff_pntr <= 0;
end else begin
if (ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr + 2'h1);
else if (!ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr);
end
end
always @(posedge WR_CLK or posedge RST_FULL_FF) begin : gen_pf
if (RST_FULL_FF == 1'b1) begin
ideal_prog_full <= C_FULL_FLAGS_RST_VAL;
end else begin
if (RST_FULL_GEN)
ideal_prog_full <= #`TCQ 0;
//Single Programmable Full Constant Threshold
else if (C_PROG_FULL_TYPE == 1) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Constant Thresholds
end else if (C_PROG_FULL_TYPE == 2) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < pf_thr_negate_val)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Single Programmable Full Threshold Input
end else if (C_PROG_FULL_TYPE == 3) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Threshold Inputs
end else if (C_PROG_FULL_TYPE == 4) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH_ASSERT - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < (PROG_FULL_THRESH_NEGATE - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH_ASSERT)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < PROG_FULL_THRESH_NEGATE)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
end // C_PROG_FULL_TYPE
end //wr_rst_i==0
end //
/**************************************************************************
* Read Domain Logic
**************************************************************************/
/*********************************************************
* Programmable EMPTY flags
*********************************************************/
//Determine the Assert and Negate thresholds for Programmable Empty
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_assert_val;
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_negate_val;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_rd = 0;
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_pe
if (rd_rst_i) begin
diff_pntr_rd <= 0;
ideal_prog_empty <= 1'b1;
end else begin
if (ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr) - 1'h1;
else if (!ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr);
else
diff_pntr_rd <= #`TCQ diff_pntr_rd;
if (C_PROG_EMPTY_TYPE == 1) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 2) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 3) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 4) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end //C_PROG_EMPTY_TYPE
end
end // gen_pe
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH - 2'h2 : PROG_EMPTY_THRESH;
end endgenerate // single_pe_thr_input
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_ASSERT - 2'h2 : PROG_EMPTY_THRESH_ASSERT;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_NEGATE - 2'h2 : PROG_EMPTY_THRESH_NEGATE;
end endgenerate // multiple_pe_thr_input
generate if (C_PROG_EMPTY_TYPE < 3) begin : single_multiple_pe_thr_const
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2'h2 : C_PROG_EMPTY_THRESH_ASSERT_VAL;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2'h2 : C_PROG_EMPTY_THRESH_NEGATE_VAL;
end endgenerate // single_multiple_pe_thr_const
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_rp
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
rd_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_RD_RST == 1'b1)
rd_pntr <= #`TCQ 0;
end
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_r_as
/****** Reset fifo (case 1)***************************************/
if (rd_rst_i) begin
num_rd_bits <= 0;
next_num_rd_bits = 0;
rd_ptr <= C_RD_DEPTH -1;
rd_pntr_wr1 <= 0;
wr_ptr_rdclk <= C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_MEMORY_TYPE == 2 && C_USE_DOUT_RST == 1)
ideal_dout <= dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= 1'b0;
ideal_rd_count <= 0;
end else begin //rd_rst_i==0
rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
/*****************************************************************/
// Read Operation - Read Latency 1
/*****************************************************************/
if (C_PRELOAD_LATENCY==1 || C_PRELOAD_LATENCY==2) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
//If the FIFO is one from empty, but it is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is two from empty, and is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH))
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end // else: if(ideal_empty == 1'b1)
else //if (ideal_empty == 1'b0)
begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == C_FIFO_RD_DEPTH)
//If the FIFO is not close to being empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
//If the FIFO is two from empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is one from empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR == 1))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is completely empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end //(RD_EN == 1'b1)
else //if (RD_EN == 1'b0)
begin
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
/*****************************************************************/
// Read Operation - Read Latency 0
/*****************************************************************/
end else if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty, but it is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty, and is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH)) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end else begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to being empty
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH)) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is completely empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end else begin//(RD_EN == 1'b0)
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
end //if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0)
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //rd_rst_i==0
end //always gen_fifo_r_as
endmodule // fifo_generator_v13_1_3_bhv_ver_as
/*******************************************************************************
* Declaration of Low Latency Asynchronous FIFO
******************************************************************************/
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_USE_DOUT_RST = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_FIFO_TYPE = 0
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input [C_DIN_WIDTH-1:0] DIN,
input RD_CLK,
input RD_EN,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
output reg [C_DOUT_WIDTH-1:0] DOUT = 0,
output reg EMPTY = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL
);
//-----------------------------------------------------------------------------
// Low Latency Asynchronous FIFO
//-----------------------------------------------------------------------------
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
integer i;
initial begin
for (i = 0; i < C_WR_DEPTH; i = i + 1)
memory[i] = 0;
end
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_ll_afifo = 0;
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo_q = 0;
reg ll_afifo_full = 1'b0;
reg ll_afifo_empty = 1'b1;
wire write_allow;
wire read_allow;
assign write_allow = WR_EN & ~ll_afifo_full;
assign read_allow = RD_EN & ~ll_afifo_empty;
//-----------------------------------------------------------------------------
// Write Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
wr_pntr_ll_afifo <= 0;
else if (write_allow)
wr_pntr_ll_afifo <= #`TCQ wr_pntr_ll_afifo + 1;
end
//-----------------------------------------------------------------------------
// Read Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
rd_pntr_ll_afifo_q <= 0;
else
rd_pntr_ll_afifo_q <= #`TCQ rd_pntr_ll_afifo;
end
assign rd_pntr_ll_afifo = read_allow ? rd_pntr_ll_afifo_q + 1 : rd_pntr_ll_afifo_q;
//-----------------------------------------------------------------------------
// Fill the Memory
//-----------------------------------------------------------------------------
always @(posedge WR_CLK) begin
if (write_allow)
memory[wr_pntr_ll_afifo] <= #`TCQ DIN;
end
//-----------------------------------------------------------------------------
// Generate DOUT
//-----------------------------------------------------------------------------
always @(posedge RD_CLK) begin
DOUT <= #`TCQ memory[rd_pntr_ll_afifo];
end
//-----------------------------------------------------------------------------
// Generate EMPTY
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
ll_afifo_empty <= 1'b1;
else
ll_afifo_empty <= ((wr_pntr_ll_afifo == rd_pntr_ll_afifo_q) |
(read_allow & (wr_pntr_ll_afifo == (rd_pntr_ll_afifo_q + 2'h1))));
end
//-----------------------------------------------------------------------------
// Generate FULL
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
ll_afifo_full <= 1'b1;
else
ll_afifo_full <= ((rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h1)) |
(write_allow & (rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h2))));
end
always @* begin
FULL <= ll_afifo_full;
EMPTY <= ll_afifo_empty;
end
endmodule // fifo_generator_v13_1_3_beh_ver_ll_afifo
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* Declare user parameters and their defaults
*************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
/**************************************************************************
* Declare Input and Output Ports
*************************************************************************/
(
//Inputs
input SAFETY_CKT_WR_RST,
input CLK,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_EN,
input RD_EN_USER,
input USER_EMPTY_FB,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input SRST,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input WR_RST_BUSY,
input RD_RST_BUSY,
//Outputs
output ALMOST_EMPTY,
output ALMOST_FULL,
output reg [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT = 0,
output [C_DOUT_WIDTH-1:0] DOUT,
output EMPTY,
output reg EMPTY_FB = 1'b1,
output FULL,
output OVERFLOW,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output UNDERFLOW,
output WR_ACK,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
wire [C_RD_PNTR_WIDTH:0] rd_data_count_i_ss;
wire [C_WR_PNTR_WIDTH:0] wr_data_count_i_ss;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
//localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
//localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
localparam C_GRTR_PNTR_WIDTH = (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH ;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
wire [C_WR_PNTR_WIDTH:0] EXTRA_WORDS_PF = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//wire [C_RD_PNTR_WIDTH:0] EXTRA_WORDS_PE = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam EXTRA_WORDS_PF_PARAM = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//localparam EXTRA_WORDS_PE_PARAM = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
//The reset value assignments for FULL, ALMOST_FULL, and PROG_FULL are not
//changed for v3.2(IP2_Im). When the core has Sync Reset, C_HAS_SRST=1 and C_HAS_RST=0.
// Therefore, during SRST, all the FULL flags reset to 0.
localparam C_HAS_FAST_FIFO = 0;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH;
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC && SYMMETRIC_PORT && ERR_INJECTION;
localparam C_DATA_WIDTH = (ENABLE_ERR_INJECTION == 1) ? (C_DIN_WIDTH+2) : C_DIN_WIDTH;
localparam IS_ASYMMETRY = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 0 : 1;
localparam LESSER_WIDTH = (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
localparam [C_RD_PNTR_WIDTH-1 : 0] DIFF_MAX_RD = {C_RD_PNTR_WIDTH{1'b1}};
localparam [C_WR_PNTR_WIDTH-1 : 0] DIFF_MAX_WR = {C_WR_PNTR_WIDTH{1'b1}};
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
/**************************************************************************
* Internal Registers and wires
*************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire underflow_i;
wire valid_i;
wire valid_out;
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_reg = 1'b0;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
wire srst_rrst_busy;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire fwft_enabled;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg full_i = C_FULL_FLAGS_RST_VAL;
reg full_i_temp = 0;
reg empty_i = 1;
reg almost_full_i = 0;
reg almost_empty_i = 1;
reg prog_full_i = 0;
reg prog_empty_i = 1;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] diff_count = 0;
reg write_allow_q = 0;
reg read_allow_q = 0;
reg valid_d1 = 0;
reg valid_both = 0;
reg valid_d2 = 0;
wire rst_i;
wire srst_i;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
/****************************************************************************
* Function Declarations
***************************************************************************/
/****************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***************************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 ) begin
case (def_data[7:0])
8'b00000000 : begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default : begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1) begin
if ((index*4)+j < C_DOUT_WIDTH) begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
//reg valid_d1 = 0;
//user specified value for reseting the size of the fifo
//reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_dout_both = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_both = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_EN;
wire RST;
wire WR_EN;
*/
// Assign ALMOST_EPMTY
generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae
assign ALMOST_EMPTY = almost_empty_i;
end else begin : gnae
assign ALMOST_EMPTY = 0;
end endgenerate // gae
// Assign ALMOST_FULL
generate if (C_HAS_ALMOST_FULL==1) begin : gaf
assign ALMOST_FULL = almost_full_i;
end else begin : gnaf
assign ALMOST_FULL = 0;
end endgenerate // gaf
// Dout may change behavior based on latency
localparam C_FWFT_ENABLED = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign fwft_enabled = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign ideal_dout_out= ((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1))?
ideal_dout_d1: ideal_dout;
assign DOUT = ideal_dout_out;
// Assign SBITERR and DBITERR based on latency
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
assign EMPTY = empty_i;
assign FULL = full_i;
//saftey_ckt with one register
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && (C_USE_EMBEDDED_REG == 1 || C_USE_EMBEDDED_REG == 2 )) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK)
begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK)
begin
if( rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end
else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
valid_d1 <= #`TCQ valid_i;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end //if
endgenerate
//safety ckt with both registers
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK) begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end //if
endgenerate
//Overflow may be active-low
generate if (C_HAS_OVERFLOW==1) begin : gof
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end else begin : gnof
assign OVERFLOW = 0;
end endgenerate // gof
assign PROG_EMPTY = prog_empty_i;
assign PROG_FULL = prog_full_i;
//Valid may change behavior based on latency or active-low
generate if (C_HAS_VALID==1) begin : gvalid
assign valid_i = (C_PRELOAD_LATENCY == 0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out = (C_PRELOAD_LATENCY == 2 && C_MEMORY_TYPE < 2) ?
valid_d1 : valid_i;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end else begin : gnvalid
assign VALID = 0;
end endgenerate // gvalid
//Trim data count differently depending on set widths
generate if (C_HAS_DATA_COUNT == 1) begin : gdc
always @* begin
diff_count <= wr_pntr - rd_pntr;
if (C_DATA_COUNT_WIDTH > C_RD_PNTR_WIDTH) begin
DATA_COUNT[C_RD_PNTR_WIDTH-1:0] <= diff_count;
DATA_COUNT[C_DATA_COUNT_WIDTH-1] <= 1'b0 ;
end else begin
DATA_COUNT <= diff_count[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH];
end
end
// end else begin : gndc
// always @* DATA_COUNT <= 0;
end endgenerate // gdc
//Underflow may change behavior based on latency or active-low
generate if (C_HAS_UNDERFLOW==1) begin : guf
assign underflow_i = ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end else begin : gnuf
assign UNDERFLOW = 0;
end endgenerate // guf
//Write acknowledge may be active low
generate if (C_HAS_WR_ACK==1) begin : gwr_ack
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end else begin : gnwr_ack
assign WR_ACK = 0;
end endgenerate // gwr_ack
/*****************************************************************************
* Internal reset logic
****************************************************************************/
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_WR_RST : C_HAS_SRST ? (SRST | WR_RST_BUSY) : 0;
assign rst_i = C_HAS_RST ? RST : 0;
assign srst_wrst_busy = srst_i;
assign srst_rrst_busy = srst_i;
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG <3)) begin : blockVL20
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG == 3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_both <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
valid_both <= #`TCQ 1'b0;
end else begin
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge CLK or posedge rst_i) begin
if (rst_i) begin
stage1_valid <= #`TCQ 0;
stage2_valid <= #`TCQ 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT ==1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = rd_data_count_i_ss[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = wr_data_count_i_ss[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] ;
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//reg ram_rd_en_d1 = 1'b0;
//Capture delayed version of dout
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG<3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
ram_rd_en_d1 <= #`TCQ 1'b0;
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
end // always
end
endgenerate
//no safety ckt with both registers
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG==3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
fab_rd_en_d1 <= #`TCQ (ram_rd_en_d1);
if (ram_rd_en_d1 ) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end // always
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge CLK) begin
ideal_overflow <= #`TCQ WR_EN & full_i;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (rst_i | full_i);
ideal_overflow <= #`TCQ WR_EN & (WR_RST_BUSY | full_i);
end
end endgenerate // blockOF20
generate if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge CLK) begin
ideal_underflow <= #`TCQ empty_i & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge CLK) begin
//ideal_underflow <= #`TCQ (rst_i | empty_i) & RD_EN;
ideal_underflow <= #`TCQ (RD_RST_BUSY | empty_i) & RD_EN;
end
end endgenerate // blockUF20
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/*************************************************************************
* Write and Read Logic
************************************************************************/
wire write_allow;
wire read_allow;
wire read_allow_dc;
wire write_only;
wire read_only;
//wire write_only_q;
reg write_only_q;
//wire read_only_q;
reg read_only_q;
reg full_reg;
reg rst_full_ff_reg1;
reg rst_full_ff_reg2;
wire ram_full_comb;
wire carry;
assign write_allow = WR_EN & ~full_i;
assign read_allow = RD_EN & ~empty_i;
assign read_allow_dc = RD_EN_USER & ~USER_EMPTY_FB;
//assign write_only = write_allow & ~read_allow;
//assign write_only_q = write_allow_q;
//assign read_only = read_allow & ~write_allow;
//assign read_only_q = read_allow_q ;
wire [C_WR_PNTR_WIDTH-1:0] diff_pntr;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_reg1 = 0;
reg [C_RD_PNTR_WIDTH:0] diff_pntr_pe_asym = 0;
wire [C_RD_PNTR_WIDTH:0] adj_wr_pntr_rd_asym ;
wire [C_RD_PNTR_WIDTH:0] rd_pntr_asym;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_pe_reg2 = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_max;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_max;
assign diff_pntr_pe_max = DIFF_MAX_RD;
assign diff_pntr_max = DIFF_MAX_WR;
generate if (IS_ASYMMETRY == 0) begin : diff_pntr_sym
assign write_only = write_allow & ~read_allow;
assign read_only = read_allow & ~write_allow;
end endgenerate
generate if ( IS_ASYMMETRY == 1 && C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : wr_grt_rd
assign read_only = read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]) & ~write_allow;
assign write_only = write_allow & ~(read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (IS_ASYMMETRY ==1 && C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : rd_grt_wr
assign read_only = read_allow & ~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
assign write_only = write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]) & ~read_allow;
end endgenerate
//-----------------------------------------------------------------------------
// Write and Read pointer generation
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
wr_pntr <= 0;
rd_pntr <= 0;
end else begin
if (srst_i) begin
wr_pntr <= #`TCQ 0;
rd_pntr <= #`TCQ 0;
end else begin
if (write_allow) wr_pntr <= #`TCQ wr_pntr + 1;
if (read_allow) rd_pntr <= #`TCQ rd_pntr + 1;
end
end
end
generate if (C_FIFO_TYPE == 2) begin : gll_dm_dout
always @(posedge CLK) begin
if (write_allow) begin
if (ENABLE_ERR_INJECTION == 1)
memory[wr_pntr] <= #`TCQ {INJECTDBITERR,INJECTSBITERR,DIN};
else
memory[wr_pntr] <= #`TCQ DIN;
end
end
reg [C_DATA_WIDTH-1:0] dout_tmp_q;
reg [C_DATA_WIDTH-1:0] dout_tmp = 0;
reg [C_DATA_WIDTH-1:0] dout_tmp1 = 0;
always @(posedge CLK) begin
dout_tmp_q <= #`TCQ ideal_dout;
end
always @* begin
if (read_allow)
ideal_dout <= memory[rd_pntr];
else
ideal_dout <= dout_tmp_q;
end
end endgenerate // gll_dm_dout
/**************************************************************************
* Write Domain Logic
**************************************************************************/
assign ram_rd_en = RD_EN & !EMPTY;
//reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
generate if (C_FIFO_TYPE != 2) begin : gnll_din
always @(posedge CLK or posedge rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (rst_i == 1'b1) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin //rst_i==0
if (srst_wrst_busy) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin//srst_i=0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end else begin
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
//end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //srst_i==0
end //wr_rst_i==0
end // gen_fifo_w
end endgenerate
generate if (C_FIFO_TYPE < 2 && C_MEMORY_TYPE < 2) begin : gnll_dm_dout
always @(posedge CLK) begin
if (rst_i || srst_rrst_busy) begin
if (C_USE_DOUT_RST == 1) begin
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end
end
end endgenerate
generate if (C_FIFO_TYPE != 2) begin : gnll_dout
always @(posedge CLK or posedge rst_i) begin : gen_fifo_r
/****** Reset fifo (case 1)***************************************/
if (rst_i) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end else begin //rd_rst_i==0
if (srst_rrst_busy) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets synchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end //srst_i
else begin
//rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
if (RD_EN == 1'b1) begin
if (EMPTY == 1'b1) begin
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end
else
begin
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
end
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //s_rst_i==0
end //rd_rst_i==0
end //always
end endgenerate
//-----------------------------------------------------------------------------
// Generate diff_pntr for PROG_FULL generation
// Generate diff_pntr_pe for PROG_EMPTY generation
//-----------------------------------------------------------------------------
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 0) begin : reg_write_allow
always @(posedge CLK ) begin
if (rst_i) begin
write_only_q <= 1'b0;
read_only_q <= 1'b0;
diff_pntr_reg1 <= 0;
diff_pntr_pe_reg1 <= 0;
diff_pntr_reg2 <= 0;
diff_pntr_pe_reg2 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_rrst_busy) begin
read_only_q <= #`TCQ 1'b0;
diff_pntr_pe_reg1 <= #`TCQ 0;
diff_pntr_pe_reg2 <= #`TCQ 0;
end
if (srst_wrst_busy) begin
write_only_q <= #`TCQ 1'b0;
diff_pntr_reg1 <= #`TCQ 0;
diff_pntr_reg2 <= #`TCQ 0;
end
end else begin
write_only_q <= #`TCQ write_only;
read_only_q <= #`TCQ read_only;
diff_pntr_reg2 <= #`TCQ diff_pntr_reg1;
diff_pntr_pe_reg2 <= #`TCQ diff_pntr_pe_reg1;
// Add 1 to the difference pointer value when only write happens.
if (write_only)
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr + 1;
else
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
// Add 1 to the difference pointer value when write or both write & read or no write & read happen.
if (read_only)
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr - 1;
else
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr;
end
end
end
assign diff_pntr_pe = diff_pntr_pe_reg1;
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 1) begin : reg_write_allow_asym
assign adj_wr_pntr_rd_asym[C_RD_PNTR_WIDTH:0] = {adj_wr_pntr_rd,1'b1};
assign rd_pntr_asym[C_RD_PNTR_WIDTH:0] = {~rd_pntr,1'b1};
always @(posedge CLK ) begin
if (rst_i) begin
diff_pntr_pe_asym <= 0;
diff_pntr_reg1 <= 0;
full_reg <= 0;
rst_full_ff_reg1 <= 1;
rst_full_ff_reg2 <= 1;
diff_pntr_pe_reg1 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_wrst_busy)
diff_pntr_reg1 <= #`TCQ 0;
if (srst_rrst_busy)
full_reg <= #`TCQ 0;
rst_full_ff_reg1 <= #`TCQ 1;
rst_full_ff_reg2 <= #`TCQ 1;
diff_pntr_pe_asym <= #`TCQ 0;
diff_pntr_pe_reg1 <= #`TCQ 0;
end else begin
diff_pntr_pe_asym <= #`TCQ adj_wr_pntr_rd_asym + rd_pntr_asym;
full_reg <= #`TCQ full_i;
rst_full_ff_reg1 <= #`TCQ RST_FULL_FF;
rst_full_ff_reg2 <= #`TCQ rst_full_ff_reg1;
if (~full_i) begin
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
end
end
end
end
assign carry = (~(|(diff_pntr_pe_asym [C_RD_PNTR_WIDTH : 1])));
assign diff_pntr_pe = (full_reg && ~rst_full_ff_reg2 && carry ) ? diff_pntr_pe_max : diff_pntr_pe_asym[C_RD_PNTR_WIDTH:1];
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow_asym
//-----------------------------------------------------------------------------
// Generate FULL flag
//-----------------------------------------------------------------------------
wire comp0;
wire comp1;
wire going_full;
wire leaving_full;
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gpad
assign adj_rd_pntr_wr [C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_WR_PNTR_WIDTH <= C_RD_PNTR_WIDTH) begin : gtrim
assign adj_rd_pntr_wr = rd_pntr[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
assign comp1 = (adj_rd_pntr_wr == (wr_pntr + 1'b1));
assign comp0 = (adj_rd_pntr_wr == wr_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gf_wp_eq_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full = (comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gf_asym
assign going_full = (comp1 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_full = (comp0 & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gf_wp_gt_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full =(comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_full_comb = going_full | (~leaving_full & full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
full_i <= #`TCQ ram_full_comb;
end
//-----------------------------------------------------------------------------
// Generate EMPTY flag
//-----------------------------------------------------------------------------
wire ecomp0;
wire ecomp1;
wire going_empty;
wire leaving_empty;
wire ram_empty_comb;
generate if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : pad
assign adj_wr_pntr_rd [C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_RD_PNTR_WIDTH <= C_WR_PNTR_WIDTH) begin : trim
assign adj_wr_pntr_rd = wr_pntr[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
assign ecomp1 = (adj_wr_pntr_rd == (rd_pntr + 1'b1));
assign ecomp0 = (adj_wr_pntr_rd == rd_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : ge_wp_eq_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty = (ecomp0 & write_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : ge_wp_gt_rp
assign going_empty = (ecomp1 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_empty = (ecomp0 & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : ge_wp_lt_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty =(ecomp0 & write_allow);
end endgenerate
assign ram_empty_comb = going_empty | (~leaving_empty & empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
empty_i <= 1'b1;
else if (srst_rrst_busy)
empty_i <= #`TCQ 1'b1;
else
empty_i <= #`TCQ ram_empty_comb;
end
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (srst_rrst_busy || (SAFETY_CKT_WR_RST && C_EN_SAFETY_CKT))
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ ram_empty_comb;
end
end // always
//-----------------------------------------------------------------------------
// Generate Read and write data counts for asymmetic common clock
//-----------------------------------------------------------------------------
reg [C_GRTR_PNTR_WIDTH :0] count_dc = 0;
wire [C_GRTR_PNTR_WIDTH :0] ratio;
wire decr_by_one;
wire incr_by_ratio;
wire incr_by_one;
wire decr_by_ratio;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : rd_depth_gt_wr
assign ratio = C_DEPTH_RATIO_RD;
assign decr_by_one = (IS_FWFT == 1)? read_allow_dc : read_allow;
assign incr_by_ratio = write_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (decr_by_one) begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc - 1;
else
count_dc <= #`TCQ count_dc - 1 + ratio ;
end
else begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc + ratio ;
end
end
end
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc;
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wr_depth_gt_rd
assign ratio = C_DEPTH_RATIO_WR;
assign incr_by_one = write_allow;
assign decr_by_ratio = (IS_FWFT == 1)? read_allow_dc : read_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (incr_by_one) begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc + 1;
else
count_dc <= #`TCQ count_dc + 1 - ratio ;
end
else begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc - ratio ;
end
end
end
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc;
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
//-----------------------------------------------------------------------------
// Generate WR_ACK flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_wr_ack <= 1'b0;
else if (srst_wrst_busy)
ideal_wr_ack <= #`TCQ 1'b0;
else if (WR_EN & ~full_i)
ideal_wr_ack <= #`TCQ 1'b1;
else
ideal_wr_ack <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate VALID flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_valid <= 1'b0;
else if (srst_rrst_busy)
ideal_valid <= #`TCQ 1'b0;
else if (RD_EN & ~empty_i)
ideal_valid <= #`TCQ 1'b1;
else
ideal_valid <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate ALMOST_FULL flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_FULL == 1 || C_PROG_FULL_TYPE > 2 || C_PROG_EMPTY_TYPE > 2) begin : gaf_ss
wire fcomp2;
wire going_afull;
wire leaving_afull;
wire ram_afull_comb;
assign fcomp2 = (adj_rd_pntr_wr == (wr_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gaf_wp_eq_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull = (comp1 & read_allow & ~write_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gaf_asym
assign going_afull = (fcomp2 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_afull = (comp1 & (~write_allow) & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gaf_wp_gt_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull =((comp0 | comp1 | fcomp2) & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_afull_comb = going_afull | (~leaving_afull & almost_full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
almost_full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
almost_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
almost_full_i <= #`TCQ ram_afull_comb;
end
// end endgenerate // gaf_ss
//-----------------------------------------------------------------------------
// Generate ALMOST_EMPTY flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae_ss
wire ecomp2;
wire going_aempty;
wire leaving_aempty;
wire ram_aempty_comb;
assign ecomp2 = (adj_wr_pntr_rd == (rd_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gae_wp_eq_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty = (ecomp1 & write_allow & ~read_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gae_wp_gt_rp
assign going_aempty = (ecomp2 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_aempty = (ecomp1 & ~read_allow & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gae_wp_lt_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty =((ecomp2 | ecomp1 |ecomp0) & write_allow);
end endgenerate
assign ram_aempty_comb = going_aempty | (~leaving_aempty & almost_empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
almost_empty_i <= 1'b1;
else if (srst_rrst_busy)
almost_empty_i <= #`TCQ 1'b1;
else
almost_empty_i <= #`TCQ ram_aempty_comb;
end
// end endgenerate // gae_ss
//-----------------------------------------------------------------------------
// Generate PROG_FULL
//-----------------------------------------------------------------------------
localparam C_PF_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_PF_PARAM : // FWFT
C_PROG_FULL_THRESH_ASSERT_VAL; // STD
localparam C_PF_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_PF_PARAM: // FWFT
C_PROG_FULL_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold constant
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] temp = C_PF_ASSERT_VAL;
generate if (C_PROG_FULL_TYPE == 1) begin : single_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_ASSERT_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr>= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr) < C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b0;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate // single_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_FULL_TYPE == 2) begin : multiple_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_NEGATE_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr >= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < C_PF_NEGATE_VAL)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf3_assert_val = (C_PRELOAD_LATENCY == 0) ?
PROG_FULL_THRESH - EXTRA_WORDS_PF: // FWFT
PROG_FULL_THRESH; // STD
generate if (C_PROG_FULL_TYPE == 3) begin : single_pf_input
always @(posedge CLK or posedge RST_FULL_FF) begin//0
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin //1
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin//2
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin//3
if (diff_pntr > pf3_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == pf3_assert_val) begin//4
if (read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b1;
end else//4
prog_full_i <= #`TCQ 1'b0;
end else//3
prog_full_i <= #`TCQ prog_full_i;
end //2
else begin//5
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin//6
if (diff_pntr >= pf3_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf3_assert_val) begin//7
prog_full_i <= #`TCQ 1'b0;
end//7
end//6
else
prog_full_i <= #`TCQ prog_full_i;
end//5
end//1
end//0
end endgenerate //single_pf_input
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_ASSERT -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_ASSERT; // STD
wire [C_WR_PNTR_WIDTH-1:0] pf_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_NEGATE -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_NEGATE; // STD
generate if (C_PROG_FULL_TYPE == 4) begin : multiple_pf_inputs
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin
if (diff_pntr >= pf_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr == pf_negate_val && read_only_q) ||
diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin
if (diff_pntr >= pf_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_inputs
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY
//-----------------------------------------------------------------------------
localparam C_PE_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_ASSERT_VAL; // STD
localparam C_PE_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold constant
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 1) begin : single_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_ASSERT_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b0;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 2) begin : multiple_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_NEGATE_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_NEGATE_VAL)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate //multiple_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe3_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH -2) : // FWFT
PROG_EMPTY_THRESH; // STD
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_input
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe < pe3_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == pe3_assert_val) begin
if (write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ 1'b1;
end else
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe3_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe3_assert_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_input
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe4_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_ASSERT - 2) : // FWFT
PROG_EMPTY_THRESH_ASSERT; // STD
wire [C_RD_PNTR_WIDTH-1:0] pe4_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_NEGATE - 2) : // FWFT
PROG_EMPTY_THRESH_NEGATE; // STD
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_inputs
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe <= pe4_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (((diff_pntr_pe == pe4_negate_val) && write_only_q) ||
(diff_pntr_pe > pe4_negate_val)) begin
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe4_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe4_negate_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // multiple_pe_inputs
endmodule // fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* First-Word Fall-Through module (preload 0)
**************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USERVALID_LOW = 0,
parameter C_USERUNDERFLOW_LOW = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
(
//Inputs
input SAFETY_CKT_RD_RST,
input RD_CLK,
input RD_RST,
input SRST,
input WR_RST_BUSY,
input RD_RST_BUSY,
input RD_EN,
input FIFOEMPTY,
input [C_DOUT_WIDTH-1:0] FIFODATA,
input FIFOSBITERR,
input FIFODBITERR,
//Outputs
output reg [C_DOUT_WIDTH-1:0] USERDATA,
output USERVALID,
output USERUNDERFLOW,
output USEREMPTY,
output USERALMOSTEMPTY,
output RAMVALID,
output FIFORDEN,
output reg USERSBITERR,
output reg USERDBITERR,
output reg STAGE2_REG_EN,
output fab_read_data_valid_i_o,
output read_data_valid_i_o,
output ram_valid_i_o,
output [1:0] VALID_STAGES
);
//Internal signals
wire preloadstage1;
wire preloadstage2;
reg ram_valid_i;
reg fab_valid;
reg read_data_valid_i;
reg fab_read_data_valid_i;
reg fab_read_data_valid_i_1;
reg ram_valid_i_d;
reg read_data_valid_i_d;
reg fab_read_data_valid_i_d;
wire ram_regout_en;
reg ram_regout_en_d1;
reg ram_regout_en_d2;
wire fab_regout_en;
wire ram_rd_en;
reg empty_i = 1'b1;
reg empty_sckt = 1'b1;
reg sckt_rrst_q = 1'b0;
reg sckt_rrst_done = 1'b0;
reg empty_q = 1'b1;
reg rd_en_q = 1'b0;
reg almost_empty_i = 1'b1;
reg almost_empty_q = 1'b1;
wire rd_rst_i;
wire srst_i;
reg [C_DOUT_WIDTH-1:0] userdata_both;
wire uservalid_both;
wire uservalid_one;
reg user_sbiterr_both = 1'b0;
reg user_dbiterr_both = 1'b0;
assign ram_valid_i_o = ram_valid_i;
assign read_data_valid_i_o = read_data_valid_i;
assign fab_read_data_valid_i_o = fab_read_data_valid_i;
/*************************************************************************
* FUNCTIONS
*************************************************************************/
/*************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
//*************************************************************************
// Set power-on states for regs
//*************************************************************************
initial begin
ram_valid_i = 1'b0;
fab_valid = 1'b0;
read_data_valid_i = 1'b0;
fab_read_data_valid_i = 1'b0;
fab_read_data_valid_i_1 = 1'b0;
USERDATA = hexstr_conv(C_DOUT_RST_VAL);
userdata_both = hexstr_conv(C_DOUT_RST_VAL);
USERSBITERR = 1'b0;
USERDBITERR = 1'b0;
user_sbiterr_both = 1'b0;
user_dbiterr_both = 1'b0;
end //initial
//***************************************************************************
// connect up optional reset
//***************************************************************************
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? RD_RST : 0;
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_RD_RST : C_HAS_SRST ? SRST : 0;
reg sckt_rd_rst_fwft = 1'b0;
reg fwft_rst_done_i = 1'b0;
wire fwft_rst_done;
assign fwft_rst_done = C_EN_SAFETY_CKT ? fwft_rst_done_i : 1'b1;
always @ (posedge RD_CLK) begin
sckt_rd_rst_fwft <= #`TCQ SAFETY_CKT_RD_RST;
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i)
fwft_rst_done_i <= 1'b0;
else if (sckt_rd_rst_fwft & ~SAFETY_CKT_RD_RST)
fwft_rst_done_i <= #`TCQ 1'b1;
end
localparam INVALID = 0;
localparam STAGE1_VALID = 2;
localparam STAGE2_VALID = 1;
localparam BOTH_STAGES_VALID = 3;
reg [1:0] curr_fwft_state = INVALID;
reg [1:0] next_fwft_state = INVALID;
generate if (C_USE_EMBEDDED_REG < 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = preloadstage2;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = (RD_EN & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
reg curr_state = 0;
reg next_state = 0;
reg leaving_empty_fwft = 0;
reg going_empty_fwft = 0;
reg empty_i_q = 0;
reg ram_rd_en_fwft = 0;
generate if (C_FIFO_TYPE == 2) begin : gll_fifo
always @* begin // FSM fo FWFT
case (curr_state)
1'b0: begin
if (~FIFOEMPTY)
next_state <= 1'b1;
else
next_state <= 1'b0;
end
1'b1: begin
if (FIFOEMPTY && RD_EN)
next_state <= 1'b0;
else
next_state <= 1'b1;
end
default: next_state <= 1'b0;
endcase
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_i <= 1'b1;
empty_i_q <= 1'b1;
ram_valid_i <= 1'b0;
end else if (srst_i) begin
empty_i <= #`TCQ 1'b1;
empty_i_q <= #`TCQ 1'b1;
ram_valid_i <= #`TCQ 1'b0;
end else begin
empty_i <= #`TCQ going_empty_fwft | (~leaving_empty_fwft & empty_i);
empty_i_q <= #`TCQ FIFOEMPTY;
ram_valid_i <= #`TCQ next_state;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
curr_state <= 1'b0;
end else if (srst_i) begin
curr_state <= #`TCQ 1'b0;
end else begin
curr_state <= #`TCQ next_state;
end
end //always
wire fe_of_empty;
assign fe_of_empty = empty_i_q & ~FIFOEMPTY;
always @* begin // Finding leaving empty
case (curr_state)
1'b0: leaving_empty_fwft <= fe_of_empty;
1'b1: leaving_empty_fwft <= 1'b1;
default: leaving_empty_fwft <= 1'b0;
endcase
end
always @* begin // Finding going empty
case (curr_state)
1'b1: going_empty_fwft <= FIFOEMPTY & RD_EN;
default: going_empty_fwft <= 1'b0;
endcase
end
always @* begin // Generating FWFT rd_en
case (curr_state)
1'b0: ram_rd_en_fwft <= ~FIFOEMPTY;
1'b1: ram_rd_en_fwft <= ~FIFOEMPTY & RD_EN;
default: ram_rd_en_fwft <= 1'b0;
endcase
end
assign ram_regout_en = ram_rd_en_fwft;
//assign ram_regout_en_d1 = ram_rd_en_fwft;
//assign ram_regout_en_d2 = ram_rd_en_fwft;
assign ram_rd_en = ram_rd_en_fwft;
end endgenerate // gll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false.
// Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2) begin : gnll_fifo_ram_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (ram_rd_en == 1'b1) begin
ram_valid_i <= #`TCQ 1'b1;
end else begin
if (ram_regout_en == 1'b1)
ram_valid_i <= #`TCQ 1'b0;
else
ram_valid_i <= #`TCQ ram_valid_i;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_ram_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ ram_valid_i | (read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG < 3) begin : gnll_fifo_empty
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~ram_valid_i & ~read_data_valid_i) | (~ram_valid_i & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
generate if ( C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((ram_regout_en) | (~FIFOEMPTY & read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ FIFOEMPTY;
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
// BRAM resets synchronously
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG < 3) begin
always @ ( posedge rd_rst_i)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
//safety ckt with one register
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
//@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay
if (rd_rst_i == 1) begin
ram_regout_en_d1 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d1 <= #`TCQ 1'b0;
else
ram_regout_en_d1 <= #`TCQ ram_regout_en;
end
end //always
// assign fab_regout_en = ((ram_regout_en_d1 & ~(ram_regout_en_d2) & empty_i) | (RD_EN & !empty_i));
assign fab_regout_en = ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b0 )? 1'b1: ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1) ? RD_EN : 1'b0;
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay1
if (rd_rst_i == 1) begin
ram_regout_en_d2 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d2 <= #`TCQ 1'b0;
else
ram_regout_en_d2 <= #`TCQ ram_regout_en_d1;
end
end //always
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
always @ (posedge RD_CLK) begin
ram_valid_i_d <= #`TCQ ram_valid_i;
read_data_valid_i_d <= #`TCQ read_data_valid_i;
fab_read_data_valid_i_d <= #`TCQ fab_read_data_valid_i;
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = (ram_valid_i == 1'b1 && (read_data_valid_i == 1'b0 || fab_read_data_valid_i == 1'b0)) ? 1'b1 : (read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1 && ram_valid_i == 1'b1) ? RD_EN : 1'b0;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = ((RD_EN | ~ fab_read_data_valid_i) & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false // Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3) begin : gnll_fifo_fab_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (ram_regout_en == 1'b1) begin
fab_valid <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
fab_valid <= #`TCQ 1'b0;
else
fab_valid <= #`TCQ fab_valid;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_fab_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG == 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else begin
if (ram_regout_en == 1'b1) begin
read_data_valid_i <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ read_data_valid_i;
end
end
end //always
end
endgenerate
//generate if(C_USE_EMBEDDED_REG == 3) begin
// always @ (posedge RD_CLK or posedge rd_rst_i) begin
// if (rd_rst_i)
// read_data_valid_i <= #`TCQ 1'b0;
// else if (srst_i)
// read_data_valid_i <= #`TCQ 1'b0;
//
// if (ram_regout_en == 1'b1) begin
// fab_read_data_valid_i <= #`TCQ 1'b0;
// end else begin
// if (fab_regout_en == 1'b1)
// fab_read_data_valid_i <= #`TCQ 1'b1;
// else
// fab_read_data_valid_i <= #`TCQ fab_read_data_valid_i;
// end
// end //always
//end
//endgenerate
generate if(C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin :fabout_dvalid
if (rd_rst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else
fab_read_data_valid_i <= #`TCQ fab_valid | (fab_read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
always @ (posedge RD_CLK ) begin : proc_del1
begin
fab_read_data_valid_i_1 <= #`TCQ fab_read_data_valid_i;
end
end //always
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3 ) begin : gnll_fifo_empty_both
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~fab_valid & ~fab_read_data_valid_i) | (~fab_valid & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty_both
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
reg FIFOEMPTY_1;
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @(posedge RD_CLK) begin
FIFOEMPTY_1 <= #`TCQ FIFOEMPTY;
end
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((fab_regout_en) | (ram_valid_i & fab_read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ (~ram_valid_i);
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_sckt <= #`TCQ 1'b1;
sckt_rrst_q <= #`TCQ 1'b0;
sckt_rrst_done <= #`TCQ 1'b0;
end else begin
sckt_rrst_q <= #`TCQ SAFETY_CKT_RD_RST;
if (sckt_rrst_q && ~SAFETY_CKT_RD_RST) begin
sckt_rrst_done <= #`TCQ 1'b1;
end else if (sckt_rrst_done) begin
// rising clock edge
empty_sckt <= #`TCQ 1'b0;
end
end
end //always
// assign USEREMPTY = C_EN_SAFETY_CKT ? (sckt_rrst_done ? empty_i : empty_sckt) : empty_i;
assign USEREMPTY = empty_i;
assign USERALMOSTEMPTY = almost_empty_i;
assign FIFORDEN = ram_rd_en;
assign RAMVALID = (C_USE_EMBEDDED_REG == 3)? fab_valid : ram_valid_i;
assign uservalid_both = (C_USERVALID_LOW && C_USE_EMBEDDED_REG == 3) ? ~fab_read_data_valid_i : ((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG == 3) ? fab_read_data_valid_i : 1'b0);
assign uservalid_one = (C_USERVALID_LOW && C_USE_EMBEDDED_REG < 3) ? ~read_data_valid_i :((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG < 3) ? read_data_valid_i : 1'b0);
assign USERVALID = (C_USE_EMBEDDED_REG == 3) ? uservalid_both : uservalid_one;
assign USERUNDERFLOW = C_USERUNDERFLOW_LOW ? ~(empty_q & rd_en_q) : empty_q & rd_en_q;
//no safety ckt with both reg
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin
if (fwft_rst_done) begin
if (ram_regout_en) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end
end //always
end //if
endgenerate
//safety_ckt with both registers
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK) begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end //always
end //if
endgenerate
endmodule //fifo_generator_v13_1_3_bhv_ver_preload0
//-----------------------------------------------------------------------------
//
// Register Slice
// Register one AXI channel on forward and/or reverse signal path
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// reg_slice
//
//--------------------------------------------------------------------------
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
input wire S_VALID,
output wire S_READY,
// Master side
output wire [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA,
output wire M_VALID,
input wire M_READY
);
generate
////////////////////////////////////////////////////////////////////
//
// Both FWD and REV mode
//
////////////////////////////////////////////////////////////////////
if (C_REG_CONFIG == 32'h00000000)
begin
reg [1:0] state;
localparam [1:0]
ZERO = 2'b10,
ONE = 2'b11,
TWO = 2'b01;
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg [C_DATA_WIDTH-1:0] storage_data2 = 0;
reg load_s1;
wire load_s2;
wire load_s1_from_s2;
reg s_ready_i; //local signal of output
wire m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with either slave side data or from storage2
always @(posedge ACLK)
begin
if (load_s1)
if (load_s1_from_s2)
storage_data1 <= storage_data2;
else
storage_data1 <= S_PAYLOAD_DATA;
end
// Load storage2 with slave side data
always @(posedge ACLK)
begin
if (load_s2)
storage_data2 <= S_PAYLOAD_DATA;
end
assign M_PAYLOAD_DATA = storage_data1;
// Always load s2 on a valid transaction even if it's unnecessary
assign load_s2 = S_VALID & s_ready_i;
// Loading s1
always @ *
begin
if ( ((state == ZERO) && (S_VALID == 1)) || // Load when empty on slave transaction
// Load when ONE if we both have read and write at the same time
((state == ONE) && (S_VALID == 1) && (M_READY == 1)) ||
// Load when TWO and we have a transaction on Master side
((state == TWO) && (M_READY == 1)))
load_s1 = 1'b1;
else
load_s1 = 1'b0;
end // always @ *
assign load_s1_from_s2 = (state == TWO);
// State Machine for handling output signals
always @(posedge ACLK) begin
if (ARESET) begin
s_ready_i <= 1'b0;
state <= ZERO;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else begin
case (state)
// No transaction stored locally
ZERO: if (S_VALID) state <= ONE; // Got one so move to ONE
// One transaction stored locally
ONE: begin
if (M_READY & ~S_VALID) state <= ZERO; // Read out one so move to ZERO
if (~M_READY & S_VALID) begin
state <= TWO; // Got another one so move to TWO
s_ready_i <= 1'b0;
end
end
// TWO transaction stored locally
TWO: if (M_READY) begin
state <= ONE; // Read out one so move to ONE
s_ready_i <= 1'b1;
end
endcase // case (state)
end
end // always @ (posedge ACLK)
assign m_valid_i = state[0];
end // if (C_REG_CONFIG == 1)
////////////////////////////////////////////////////////////////////
//
// 1-stage pipeline register with bubble cycle, both FWD and REV pipelining
// Operates same as 1-deep FIFO
//
////////////////////////////////////////////////////////////////////
else if (C_REG_CONFIG == 32'h00000001)
begin
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg s_ready_i; //local signal of output
reg m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with slave side data
always @(posedge ACLK)
begin
if (ARESET) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b0;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else if (m_valid_i & M_READY) begin
s_ready_i <= 1'b1;
m_valid_i <= 1'b0;
end else if (S_VALID & s_ready_i) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b1;
end
if (~m_valid_i) begin
storage_data1 <= S_PAYLOAD_DATA;
end
end
assign M_PAYLOAD_DATA = storage_data1;
end // if (C_REG_CONFIG == 7)
else begin : default_case
// Passthrough
assign M_PAYLOAD_DATA = S_PAYLOAD_DATA;
assign M_VALID = S_VALID;
assign S_READY = M_READY;
end
endgenerate
endmodule // reg_slice
|
/*
*******************************************************************************
*
* FIFO Generator - Verilog Behavioral Model
*
*******************************************************************************
*
* (c) Copyright 1995 - 2009 Xilinx, Inc. All rights reserved.
*
* This file contains confidential and proprietary information
* of Xilinx, Inc. and is protected under U.S. and
* international copyright and other intellectual property
* laws.
*
* DISCLAIMER
* This disclaimer is not a license and does not grant any
* rights to the materials distributed herewith. Except as
* otherwise provided in a valid license issued to you by
* Xilinx, and to the maximum extent permitted by applicable
* law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
* WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
* AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
* BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
* INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
* (2) Xilinx shall not be liable (whether in contract or tort,
* including negligence, or under any other theory of
* liability) for any loss or damage of any kind or nature
* related to, arising under or in connection with these
* materials, including for any direct, or any indirect,
* special, incidental, or consequential loss or damage
* (including loss of data, profits, goodwill, or any type of
* loss or damage suffered as a result of any action brought
* by a third party) even if such damage or loss was
* reasonably foreseeable or Xilinx had been advised of the
* possibility of the same.
*
* CRITICAL APPLICATIONS
* Xilinx products are not designed or intended to be fail-
* safe, or for use in any application requiring fail-safe
* performance, such as life-support or safety devices or
* systems, Class III medical devices, nuclear facilities,
* applications related to the deployment of airbags, or any
* other applications that could lead to death, personal
* injury, or severe property or environmental damage
* (individually and collectively, "Critical
* Applications"). Customer assumes the sole risk and
* liability of any use of Xilinx products in Critical
* Applications, subject only to applicable laws and
* regulations governing limitations on product liability.
*
* THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
* PART OF THIS FILE AT ALL TIMES.
*
*******************************************************************************
*******************************************************************************
*
* Filename: fifo_generator_vlog_beh.v
*
* Author : Xilinx
*
*******************************************************************************
* Structure:
*
* fifo_generator_vlog_beh.v
* |
* +-fifo_generator_v13_1_3_bhv_ver_as
* |
* +-fifo_generator_v13_1_3_bhv_ver_ss
* |
* +-fifo_generator_v13_1_3_bhv_ver_preload0
*
*******************************************************************************
* Description:
*
* The Verilog behavioral model for the FIFO Generator.
*
* The behavioral model has three parts:
* - The behavioral model for independent clocks FIFOs (_as)
* - The behavioral model for common clock FIFOs (_ss)
* - The "preload logic" block which implements First-word Fall-through
*
*******************************************************************************
* Description:
* The verilog behavioral model for the FIFO generator core.
*
*******************************************************************************
*/
`timescale 1ps/1ps
`ifndef TCQ
`define TCQ 100
`endif
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "",
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 1,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "4kx4",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_PIPELINE_REG = 0,
parameter C_POWER_SAVING_MODE = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface, 1: AXI4 Stream, 2: AXI4/AXI3
parameter C_AXI_TYPE = 0, // 1: AXI4, 2: AXI4 Lite, 3: AXI3
parameter C_HAS_AXI_WR_CHANNEL = 0,
parameter C_HAS_AXI_RD_CHANNEL = 0,
parameter C_HAS_SLAVE_CE = 0,
parameter C_HAS_MASTER_CE = 0,
parameter C_ADD_NGC_CONSTRAINT = 0,
parameter C_USE_COMMON_UNDERFLOW = 0,
parameter C_USE_COMMON_OVERFLOW = 0,
parameter C_USE_DEFAULT_SETTINGS = 0,
// AXI Full/Lite
parameter C_AXI_ID_WIDTH = 0,
parameter C_AXI_ADDR_WIDTH = 0,
parameter C_AXI_DATA_WIDTH = 0,
parameter C_AXI_LEN_WIDTH = 8,
parameter C_AXI_LOCK_WIDTH = 2,
parameter C_HAS_AXI_ID = 0,
parameter C_HAS_AXI_AWUSER = 0,
parameter C_HAS_AXI_WUSER = 0,
parameter C_HAS_AXI_BUSER = 0,
parameter C_HAS_AXI_ARUSER = 0,
parameter C_HAS_AXI_RUSER = 0,
parameter C_AXI_ARUSER_WIDTH = 0,
parameter C_AXI_AWUSER_WIDTH = 0,
parameter C_AXI_WUSER_WIDTH = 0,
parameter C_AXI_BUSER_WIDTH = 0,
parameter C_AXI_RUSER_WIDTH = 0,
// AXI Streaming
parameter C_HAS_AXIS_TDATA = 0,
parameter C_HAS_AXIS_TID = 0,
parameter C_HAS_AXIS_TDEST = 0,
parameter C_HAS_AXIS_TUSER = 0,
parameter C_HAS_AXIS_TREADY = 0,
parameter C_HAS_AXIS_TLAST = 0,
parameter C_HAS_AXIS_TSTRB = 0,
parameter C_HAS_AXIS_TKEEP = 0,
parameter C_AXIS_TDATA_WIDTH = 1,
parameter C_AXIS_TID_WIDTH = 1,
parameter C_AXIS_TDEST_WIDTH = 1,
parameter C_AXIS_TUSER_WIDTH = 1,
parameter C_AXIS_TSTRB_WIDTH = 1,
parameter C_AXIS_TKEEP_WIDTH = 1,
// AXI Channel Type
// WACH --> Write Address Channel
// WDCH --> Write Data Channel
// WRCH --> Write Response Channel
// RACH --> Read Address Channel
// RDCH --> Read Data Channel
// AXIS --> AXI Streaming
parameter C_WACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logic
parameter C_WDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_WRCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_AXIS_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
// AXI Implementation Type
// 1 = Common Clock Block RAM FIFO
// 2 = Common Clock Distributed RAM FIFO
// 11 = Independent Clock Block RAM FIFO
// 12 = Independent Clock Distributed RAM FIFO
parameter C_IMPLEMENTATION_TYPE_WACH = 0,
parameter C_IMPLEMENTATION_TYPE_WDCH = 0,
parameter C_IMPLEMENTATION_TYPE_WRCH = 0,
parameter C_IMPLEMENTATION_TYPE_RACH = 0,
parameter C_IMPLEMENTATION_TYPE_RDCH = 0,
parameter C_IMPLEMENTATION_TYPE_AXIS = 0,
// AXI FIFO Type
// 0 = Data FIFO
// 1 = Packet FIFO
// 2 = Low Latency Sync FIFO
// 3 = Low Latency Async FIFO
parameter C_APPLICATION_TYPE_WACH = 0,
parameter C_APPLICATION_TYPE_WDCH = 0,
parameter C_APPLICATION_TYPE_WRCH = 0,
parameter C_APPLICATION_TYPE_RACH = 0,
parameter C_APPLICATION_TYPE_RDCH = 0,
parameter C_APPLICATION_TYPE_AXIS = 0,
// AXI Built-in FIFO Primitive Type
// 512x36, 1kx18, 2kx9, 4kx4, etc
parameter C_PRIM_FIFO_TYPE_WACH = "512x36",
parameter C_PRIM_FIFO_TYPE_WDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_WRCH = "512x36",
parameter C_PRIM_FIFO_TYPE_RACH = "512x36",
parameter C_PRIM_FIFO_TYPE_RDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_AXIS = "512x36",
// Enable ECC
// 0 = ECC disabled
// 1 = ECC enabled
parameter C_USE_ECC_WACH = 0,
parameter C_USE_ECC_WDCH = 0,
parameter C_USE_ECC_WRCH = 0,
parameter C_USE_ECC_RACH = 0,
parameter C_USE_ECC_RDCH = 0,
parameter C_USE_ECC_AXIS = 0,
// ECC Error Injection Type
// 0 = No Error Injection
// 1 = Single Bit Error Injection
// 2 = Double Bit Error Injection
// 3 = Single Bit and Double Bit Error Injection
parameter C_ERROR_INJECTION_TYPE_WACH = 0,
parameter C_ERROR_INJECTION_TYPE_WDCH = 0,
parameter C_ERROR_INJECTION_TYPE_WRCH = 0,
parameter C_ERROR_INJECTION_TYPE_RACH = 0,
parameter C_ERROR_INJECTION_TYPE_RDCH = 0,
parameter C_ERROR_INJECTION_TYPE_AXIS = 0,
// Input Data Width
// Accumulation of all AXI input signal's width
parameter C_DIN_WIDTH_WACH = 1,
parameter C_DIN_WIDTH_WDCH = 1,
parameter C_DIN_WIDTH_WRCH = 1,
parameter C_DIN_WIDTH_RACH = 1,
parameter C_DIN_WIDTH_RDCH = 1,
parameter C_DIN_WIDTH_AXIS = 1,
parameter C_WR_DEPTH_WACH = 16,
parameter C_WR_DEPTH_WDCH = 16,
parameter C_WR_DEPTH_WRCH = 16,
parameter C_WR_DEPTH_RACH = 16,
parameter C_WR_DEPTH_RDCH = 16,
parameter C_WR_DEPTH_AXIS = 16,
parameter C_WR_PNTR_WIDTH_WACH = 4,
parameter C_WR_PNTR_WIDTH_WDCH = 4,
parameter C_WR_PNTR_WIDTH_WRCH = 4,
parameter C_WR_PNTR_WIDTH_RACH = 4,
parameter C_WR_PNTR_WIDTH_RDCH = 4,
parameter C_WR_PNTR_WIDTH_AXIS = 4,
parameter C_HAS_DATA_COUNTS_WACH = 0,
parameter C_HAS_DATA_COUNTS_WDCH = 0,
parameter C_HAS_DATA_COUNTS_WRCH = 0,
parameter C_HAS_DATA_COUNTS_RACH = 0,
parameter C_HAS_DATA_COUNTS_RDCH = 0,
parameter C_HAS_DATA_COUNTS_AXIS = 0,
parameter C_HAS_PROG_FLAGS_WACH = 0,
parameter C_HAS_PROG_FLAGS_WDCH = 0,
parameter C_HAS_PROG_FLAGS_WRCH = 0,
parameter C_HAS_PROG_FLAGS_RACH = 0,
parameter C_HAS_PROG_FLAGS_RDCH = 0,
parameter C_HAS_PROG_FLAGS_AXIS = 0,
parameter C_PROG_FULL_TYPE_WACH = 0,
parameter C_PROG_FULL_TYPE_WDCH = 0,
parameter C_PROG_FULL_TYPE_WRCH = 0,
parameter C_PROG_FULL_TYPE_RACH = 0,
parameter C_PROG_FULL_TYPE_RDCH = 0,
parameter C_PROG_FULL_TYPE_AXIS = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_PROG_EMPTY_TYPE_WACH = 0,
parameter C_PROG_EMPTY_TYPE_WDCH = 0,
parameter C_PROG_EMPTY_TYPE_WRCH = 0,
parameter C_PROG_EMPTY_TYPE_RACH = 0,
parameter C_PROG_EMPTY_TYPE_RDCH = 0,
parameter C_PROG_EMPTY_TYPE_AXIS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_REG_SLICE_MODE_WACH = 0,
parameter C_REG_SLICE_MODE_WDCH = 0,
parameter C_REG_SLICE_MODE_WRCH = 0,
parameter C_REG_SLICE_MODE_RACH = 0,
parameter C_REG_SLICE_MODE_RDCH = 0,
parameter C_REG_SLICE_MODE_AXIS = 0
)
(
//------------------------------------------------------------------------------
// Input and Output Declarations
//------------------------------------------------------------------------------
// Conventional FIFO Interface Signals
input backup,
input backup_marker,
input clk,
input rst,
input srst,
input wr_clk,
input wr_rst,
input rd_clk,
input rd_rst,
input [C_DIN_WIDTH-1:0] din,
input wr_en,
input rd_en,
// Optional inputs
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate,
input int_clk,
input injectdbiterr,
input injectsbiterr,
input sleep,
output [C_DOUT_WIDTH-1:0] dout,
output full,
output almost_full,
output wr_ack,
output overflow,
output empty,
output almost_empty,
output valid,
output underflow,
output [C_DATA_COUNT_WIDTH-1:0] data_count,
output [C_RD_DATA_COUNT_WIDTH-1:0] rd_data_count,
output [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count,
output prog_full,
output prog_empty,
output sbiterr,
output dbiterr,
output wr_rst_busy,
output rd_rst_busy,
// AXI Global Signal
input m_aclk,
input s_aclk,
input s_aresetn,
input s_aclk_en,
input m_aclk_en,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_awlen,
input [3-1:0] s_axi_awsize,
input [2-1:0] s_axi_awburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_awlock,
input [4-1:0] s_axi_awcache,
input [3-1:0] s_axi_awprot,
input [4-1:0] s_axi_awqos,
input [4-1:0] s_axi_awregion,
input [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser,
input s_axi_awvalid,
output s_axi_awready,
input [C_AXI_ID_WIDTH-1:0] s_axi_wid,
input [C_AXI_DATA_WIDTH-1:0] s_axi_wdata,
input [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb,
input s_axi_wlast,
input [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [2-1:0] s_axi_bresp,
output [C_AXI_BUSER_WIDTH-1:0] s_axi_buser,
output s_axi_bvalid,
input s_axi_bready,
// AXI Full/Lite Master Write Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_awlen,
output [3-1:0] m_axi_awsize,
output [2-1:0] m_axi_awburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_awlock,
output [4-1:0] m_axi_awcache,
output [3-1:0] m_axi_awprot,
output [4-1:0] m_axi_awqos,
output [4-1:0] m_axi_awregion,
output [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
output m_axi_awvalid,
input m_axi_awready,
output [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output m_axi_wlast,
output [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
output m_axi_wvalid,
input m_axi_wready,
input [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input [2-1:0] m_axi_bresp,
input [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
input m_axi_bvalid,
output m_axi_bready,
// AXI Full/Lite Slave Read Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_arlen,
input [3-1:0] s_axi_arsize,
input [2-1:0] s_axi_arburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_arlock,
input [4-1:0] s_axi_arcache,
input [3-1:0] s_axi_arprot,
input [4-1:0] s_axi_arqos,
input [4-1:0] s_axi_arregion,
input [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_AXI_DATA_WIDTH-1:0] s_axi_rdata,
output [2-1:0] s_axi_rresp,
output s_axi_rlast,
output [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser,
output s_axi_rvalid,
input s_axi_rready,
// AXI Full/Lite Master Read Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_arlen,
output [3-1:0] m_axi_arsize,
output [2-1:0] m_axi_arburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_arlock,
output [4-1:0] m_axi_arcache,
output [3-1:0] m_axi_arprot,
output [4-1:0] m_axi_arqos,
output [4-1:0] m_axi_arregion,
output [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
output m_axi_arvalid,
input m_axi_arready,
input [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input [2-1:0] m_axi_rresp,
input m_axi_rlast,
input [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
input m_axi_rvalid,
output m_axi_rready,
// AXI Streaming Slave Signals (Write side)
input s_axis_tvalid,
output s_axis_tready,
input [C_AXIS_TDATA_WIDTH-1:0] s_axis_tdata,
input [C_AXIS_TSTRB_WIDTH-1:0] s_axis_tstrb,
input [C_AXIS_TKEEP_WIDTH-1:0] s_axis_tkeep,
input s_axis_tlast,
input [C_AXIS_TID_WIDTH-1:0] s_axis_tid,
input [C_AXIS_TDEST_WIDTH-1:0] s_axis_tdest,
input [C_AXIS_TUSER_WIDTH-1:0] s_axis_tuser,
// AXI Streaming Master Signals (Read side)
output m_axis_tvalid,
input m_axis_tready,
output [C_AXIS_TDATA_WIDTH-1:0] m_axis_tdata,
output [C_AXIS_TSTRB_WIDTH-1:0] m_axis_tstrb,
output [C_AXIS_TKEEP_WIDTH-1:0] m_axis_tkeep,
output m_axis_tlast,
output [C_AXIS_TID_WIDTH-1:0] m_axis_tid,
output [C_AXIS_TDEST_WIDTH-1:0] m_axis_tdest,
output [C_AXIS_TUSER_WIDTH-1:0] m_axis_tuser,
// AXI Full/Lite Write Address Channel signals
input axi_aw_injectsbiterr,
input axi_aw_injectdbiterr,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_wr_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_rd_data_count,
output axi_aw_sbiterr,
output axi_aw_dbiterr,
output axi_aw_overflow,
output axi_aw_underflow,
output axi_aw_prog_full,
output axi_aw_prog_empty,
// AXI Full/Lite Write Data Channel signals
input axi_w_injectsbiterr,
input axi_w_injectdbiterr,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_wr_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_rd_data_count,
output axi_w_sbiterr,
output axi_w_dbiterr,
output axi_w_overflow,
output axi_w_underflow,
output axi_w_prog_full,
output axi_w_prog_empty,
// AXI Full/Lite Write Response Channel signals
input axi_b_injectsbiterr,
input axi_b_injectdbiterr,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_wr_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_rd_data_count,
output axi_b_sbiterr,
output axi_b_dbiterr,
output axi_b_overflow,
output axi_b_underflow,
output axi_b_prog_full,
output axi_b_prog_empty,
// AXI Full/Lite Read Address Channel signals
input axi_ar_injectsbiterr,
input axi_ar_injectdbiterr,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_wr_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_rd_data_count,
output axi_ar_sbiterr,
output axi_ar_dbiterr,
output axi_ar_overflow,
output axi_ar_underflow,
output axi_ar_prog_full,
output axi_ar_prog_empty,
// AXI Full/Lite Read Data Channel Signals
input axi_r_injectsbiterr,
input axi_r_injectdbiterr,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_wr_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_rd_data_count,
output axi_r_sbiterr,
output axi_r_dbiterr,
output axi_r_overflow,
output axi_r_underflow,
output axi_r_prog_full,
output axi_r_prog_empty,
// AXI Streaming FIFO Related Signals
input axis_injectsbiterr,
input axis_injectdbiterr,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_full_thresh,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_wr_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_rd_data_count,
output axis_sbiterr,
output axis_dbiterr,
output axis_overflow,
output axis_underflow,
output axis_prog_full,
output axis_prog_empty
);
wire BACKUP;
wire BACKUP_MARKER;
wire CLK;
wire RST;
wire SRST;
wire WR_CLK;
wire WR_RST;
wire RD_CLK;
wire RD_RST;
wire [C_DIN_WIDTH-1:0] DIN;
wire WR_EN;
wire RD_EN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire INT_CLK;
wire INJECTDBITERR;
wire INJECTSBITERR;
wire SLEEP;
wire [C_DOUT_WIDTH-1:0] DOUT;
wire FULL;
wire ALMOST_FULL;
wire WR_ACK;
wire OVERFLOW;
wire EMPTY;
wire ALMOST_EMPTY;
wire VALID;
wire UNDERFLOW;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT;
wire PROG_FULL;
wire PROG_EMPTY;
wire SBITERR;
wire DBITERR;
wire WR_RST_BUSY;
wire RD_RST_BUSY;
wire M_ACLK;
wire S_ACLK;
wire S_ARESETN;
wire S_ACLK_EN;
wire M_ACLK_EN;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_AWLEN;
wire [3-1:0] S_AXI_AWSIZE;
wire [2-1:0] S_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_AWLOCK;
wire [4-1:0] S_AXI_AWCACHE;
wire [3-1:0] S_AXI_AWPROT;
wire [4-1:0] S_AXI_AWQOS;
wire [4-1:0] S_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER;
wire S_AXI_AWVALID;
wire S_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB;
wire S_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER;
wire S_AXI_WVALID;
wire S_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [2-1:0] S_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER;
wire S_AXI_BVALID;
wire S_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_AWLEN;
wire [3-1:0] M_AXI_AWSIZE;
wire [2-1:0] M_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_AWLOCK;
wire [4-1:0] M_AXI_AWCACHE;
wire [3-1:0] M_AXI_AWPROT;
wire [4-1:0] M_AXI_AWQOS;
wire [4-1:0] M_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER;
wire M_AXI_AWVALID;
wire M_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB;
wire M_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER;
wire M_AXI_WVALID;
wire M_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID;
wire [2-1:0] M_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER;
wire M_AXI_BVALID;
wire M_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_ARLEN;
wire [3-1:0] S_AXI_ARSIZE;
wire [2-1:0] S_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_ARLOCK;
wire [4-1:0] S_AXI_ARCACHE;
wire [3-1:0] S_AXI_ARPROT;
wire [4-1:0] S_AXI_ARQOS;
wire [4-1:0] S_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER;
wire S_AXI_ARVALID;
wire S_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA;
wire [2-1:0] S_AXI_RRESP;
wire S_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER;
wire S_AXI_RVALID;
wire S_AXI_RREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_ARLEN;
wire [3-1:0] M_AXI_ARSIZE;
wire [2-1:0] M_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_ARLOCK;
wire [4-1:0] M_AXI_ARCACHE;
wire [3-1:0] M_AXI_ARPROT;
wire [4-1:0] M_AXI_ARQOS;
wire [4-1:0] M_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER;
wire M_AXI_ARVALID;
wire M_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA;
wire [2-1:0] M_AXI_RRESP;
wire M_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER;
wire M_AXI_RVALID;
wire M_AXI_RREADY;
wire S_AXIS_TVALID;
wire S_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] S_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] S_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] S_AXIS_TKEEP;
wire S_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] S_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] S_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] S_AXIS_TUSER;
wire M_AXIS_TVALID;
wire M_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] M_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] M_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] M_AXIS_TKEEP;
wire M_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] M_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] M_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] M_AXIS_TUSER;
wire AXI_AW_INJECTSBITERR;
wire AXI_AW_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_RD_DATA_COUNT;
wire AXI_AW_SBITERR;
wire AXI_AW_DBITERR;
wire AXI_AW_OVERFLOW;
wire AXI_AW_UNDERFLOW;
wire AXI_AW_PROG_FULL;
wire AXI_AW_PROG_EMPTY;
wire AXI_W_INJECTSBITERR;
wire AXI_W_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_RD_DATA_COUNT;
wire AXI_W_SBITERR;
wire AXI_W_DBITERR;
wire AXI_W_OVERFLOW;
wire AXI_W_UNDERFLOW;
wire AXI_W_PROG_FULL;
wire AXI_W_PROG_EMPTY;
wire AXI_B_INJECTSBITERR;
wire AXI_B_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_RD_DATA_COUNT;
wire AXI_B_SBITERR;
wire AXI_B_DBITERR;
wire AXI_B_OVERFLOW;
wire AXI_B_UNDERFLOW;
wire AXI_B_PROG_FULL;
wire AXI_B_PROG_EMPTY;
wire AXI_AR_INJECTSBITERR;
wire AXI_AR_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_RD_DATA_COUNT;
wire AXI_AR_SBITERR;
wire AXI_AR_DBITERR;
wire AXI_AR_OVERFLOW;
wire AXI_AR_UNDERFLOW;
wire AXI_AR_PROG_FULL;
wire AXI_AR_PROG_EMPTY;
wire AXI_R_INJECTSBITERR;
wire AXI_R_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_RD_DATA_COUNT;
wire AXI_R_SBITERR;
wire AXI_R_DBITERR;
wire AXI_R_OVERFLOW;
wire AXI_R_UNDERFLOW;
wire AXI_R_PROG_FULL;
wire AXI_R_PROG_EMPTY;
wire AXIS_INJECTSBITERR;
wire AXIS_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_RD_DATA_COUNT;
wire AXIS_SBITERR;
wire AXIS_DBITERR;
wire AXIS_OVERFLOW;
wire AXIS_UNDERFLOW;
wire AXIS_PROG_FULL;
wire AXIS_PROG_EMPTY;
wire [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count_in;
wire wr_rst_int;
wire rd_rst_int;
wire wr_rst_busy_o;
wire wr_rst_busy_ntve;
wire wr_rst_busy_axis;
wire wr_rst_busy_wach;
wire wr_rst_busy_wdch;
wire wr_rst_busy_wrch;
wire wr_rst_busy_rach;
wire wr_rst_busy_rdch;
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// Conventional FIFO Interface Signals
assign BACKUP = backup;
assign BACKUP_MARKER = backup_marker;
assign CLK = clk;
assign RST = rst;
assign SRST = srst;
assign WR_CLK = wr_clk;
assign WR_RST = wr_rst;
assign RD_CLK = rd_clk;
assign RD_RST = rd_rst;
assign WR_EN = wr_en;
assign RD_EN = rd_en;
assign INT_CLK = int_clk;
assign INJECTDBITERR = injectdbiterr;
assign INJECTSBITERR = injectsbiterr;
assign SLEEP = sleep;
assign full = FULL;
assign almost_full = ALMOST_FULL;
assign wr_ack = WR_ACK;
assign overflow = OVERFLOW;
assign empty = EMPTY;
assign almost_empty = ALMOST_EMPTY;
assign valid = VALID;
assign underflow = UNDERFLOW;
assign prog_full = PROG_FULL;
assign prog_empty = PROG_EMPTY;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
// assign wr_rst_busy = WR_RST_BUSY | wr_rst_busy_o;
assign wr_rst_busy = wr_rst_busy_o;
assign rd_rst_busy = RD_RST_BUSY;
assign M_ACLK = m_aclk;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_ACLK_EN = s_aclk_en;
assign M_ACLK_EN = m_aclk_en;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign m_axi_awvalid = M_AXI_AWVALID;
assign M_AXI_AWREADY = m_axi_awready;
assign m_axi_wlast = M_AXI_WLAST;
assign m_axi_wvalid = M_AXI_WVALID;
assign M_AXI_WREADY = m_axi_wready;
assign M_AXI_BVALID = m_axi_bvalid;
assign m_axi_bready = M_AXI_BREADY;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign m_axi_arvalid = M_AXI_ARVALID;
assign M_AXI_ARREADY = m_axi_arready;
assign M_AXI_RLAST = m_axi_rlast;
assign M_AXI_RVALID = m_axi_rvalid;
assign m_axi_rready = M_AXI_RREADY;
assign S_AXIS_TVALID = s_axis_tvalid;
assign s_axis_tready = S_AXIS_TREADY;
assign S_AXIS_TLAST = s_axis_tlast;
assign m_axis_tvalid = M_AXIS_TVALID;
assign M_AXIS_TREADY = m_axis_tready;
assign m_axis_tlast = M_AXIS_TLAST;
assign AXI_AW_INJECTSBITERR = axi_aw_injectsbiterr;
assign AXI_AW_INJECTDBITERR = axi_aw_injectdbiterr;
assign axi_aw_sbiterr = AXI_AW_SBITERR;
assign axi_aw_dbiterr = AXI_AW_DBITERR;
assign axi_aw_overflow = AXI_AW_OVERFLOW;
assign axi_aw_underflow = AXI_AW_UNDERFLOW;
assign axi_aw_prog_full = AXI_AW_PROG_FULL;
assign axi_aw_prog_empty = AXI_AW_PROG_EMPTY;
assign AXI_W_INJECTSBITERR = axi_w_injectsbiterr;
assign AXI_W_INJECTDBITERR = axi_w_injectdbiterr;
assign axi_w_sbiterr = AXI_W_SBITERR;
assign axi_w_dbiterr = AXI_W_DBITERR;
assign axi_w_overflow = AXI_W_OVERFLOW;
assign axi_w_underflow = AXI_W_UNDERFLOW;
assign axi_w_prog_full = AXI_W_PROG_FULL;
assign axi_w_prog_empty = AXI_W_PROG_EMPTY;
assign AXI_B_INJECTSBITERR = axi_b_injectsbiterr;
assign AXI_B_INJECTDBITERR = axi_b_injectdbiterr;
assign axi_b_sbiterr = AXI_B_SBITERR;
assign axi_b_dbiterr = AXI_B_DBITERR;
assign axi_b_overflow = AXI_B_OVERFLOW;
assign axi_b_underflow = AXI_B_UNDERFLOW;
assign axi_b_prog_full = AXI_B_PROG_FULL;
assign axi_b_prog_empty = AXI_B_PROG_EMPTY;
assign AXI_AR_INJECTSBITERR = axi_ar_injectsbiterr;
assign AXI_AR_INJECTDBITERR = axi_ar_injectdbiterr;
assign axi_ar_sbiterr = AXI_AR_SBITERR;
assign axi_ar_dbiterr = AXI_AR_DBITERR;
assign axi_ar_overflow = AXI_AR_OVERFLOW;
assign axi_ar_underflow = AXI_AR_UNDERFLOW;
assign axi_ar_prog_full = AXI_AR_PROG_FULL;
assign axi_ar_prog_empty = AXI_AR_PROG_EMPTY;
assign AXI_R_INJECTSBITERR = axi_r_injectsbiterr;
assign AXI_R_INJECTDBITERR = axi_r_injectdbiterr;
assign axi_r_sbiterr = AXI_R_SBITERR;
assign axi_r_dbiterr = AXI_R_DBITERR;
assign axi_r_overflow = AXI_R_OVERFLOW;
assign axi_r_underflow = AXI_R_UNDERFLOW;
assign axi_r_prog_full = AXI_R_PROG_FULL;
assign axi_r_prog_empty = AXI_R_PROG_EMPTY;
assign AXIS_INJECTSBITERR = axis_injectsbiterr;
assign AXIS_INJECTDBITERR = axis_injectdbiterr;
assign axis_sbiterr = AXIS_SBITERR;
assign axis_dbiterr = AXIS_DBITERR;
assign axis_overflow = AXIS_OVERFLOW;
assign axis_underflow = AXIS_UNDERFLOW;
assign axis_prog_full = AXIS_PROG_FULL;
assign axis_prog_empty = AXIS_PROG_EMPTY;
assign DIN = din;
assign PROG_EMPTY_THRESH = prog_empty_thresh;
assign PROG_EMPTY_THRESH_ASSERT = prog_empty_thresh_assert;
assign PROG_EMPTY_THRESH_NEGATE = prog_empty_thresh_negate;
assign PROG_FULL_THRESH = prog_full_thresh;
assign PROG_FULL_THRESH_ASSERT = prog_full_thresh_assert;
assign PROG_FULL_THRESH_NEGATE = prog_full_thresh_negate;
assign dout = DOUT;
assign data_count = DATA_COUNT;
assign rd_data_count = RD_DATA_COUNT;
assign wr_data_count = WR_DATA_COUNT;
assign S_AXI_AWID = s_axi_awid;
assign S_AXI_AWADDR = s_axi_awaddr;
assign S_AXI_AWLEN = s_axi_awlen;
assign S_AXI_AWSIZE = s_axi_awsize;
assign S_AXI_AWBURST = s_axi_awburst;
assign S_AXI_AWLOCK = s_axi_awlock;
assign S_AXI_AWCACHE = s_axi_awcache;
assign S_AXI_AWPROT = s_axi_awprot;
assign S_AXI_AWQOS = s_axi_awqos;
assign S_AXI_AWREGION = s_axi_awregion;
assign S_AXI_AWUSER = s_axi_awuser;
assign S_AXI_WID = s_axi_wid;
assign S_AXI_WDATA = s_axi_wdata;
assign S_AXI_WSTRB = s_axi_wstrb;
assign S_AXI_WUSER = s_axi_wuser;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_buser = S_AXI_BUSER;
assign m_axi_awid = M_AXI_AWID;
assign m_axi_awaddr = M_AXI_AWADDR;
assign m_axi_awlen = M_AXI_AWLEN;
assign m_axi_awsize = M_AXI_AWSIZE;
assign m_axi_awburst = M_AXI_AWBURST;
assign m_axi_awlock = M_AXI_AWLOCK;
assign m_axi_awcache = M_AXI_AWCACHE;
assign m_axi_awprot = M_AXI_AWPROT;
assign m_axi_awqos = M_AXI_AWQOS;
assign m_axi_awregion = M_AXI_AWREGION;
assign m_axi_awuser = M_AXI_AWUSER;
assign m_axi_wid = M_AXI_WID;
assign m_axi_wdata = M_AXI_WDATA;
assign m_axi_wstrb = M_AXI_WSTRB;
assign m_axi_wuser = M_AXI_WUSER;
assign M_AXI_BID = m_axi_bid;
assign M_AXI_BRESP = m_axi_bresp;
assign M_AXI_BUSER = m_axi_buser;
assign S_AXI_ARID = s_axi_arid;
assign S_AXI_ARADDR = s_axi_araddr;
assign S_AXI_ARLEN = s_axi_arlen;
assign S_AXI_ARSIZE = s_axi_arsize;
assign S_AXI_ARBURST = s_axi_arburst;
assign S_AXI_ARLOCK = s_axi_arlock;
assign S_AXI_ARCACHE = s_axi_arcache;
assign S_AXI_ARPROT = s_axi_arprot;
assign S_AXI_ARQOS = s_axi_arqos;
assign S_AXI_ARREGION = s_axi_arregion;
assign S_AXI_ARUSER = s_axi_aruser;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_ruser = S_AXI_RUSER;
assign m_axi_arid = M_AXI_ARID;
assign m_axi_araddr = M_AXI_ARADDR;
assign m_axi_arlen = M_AXI_ARLEN;
assign m_axi_arsize = M_AXI_ARSIZE;
assign m_axi_arburst = M_AXI_ARBURST;
assign m_axi_arlock = M_AXI_ARLOCK;
assign m_axi_arcache = M_AXI_ARCACHE;
assign m_axi_arprot = M_AXI_ARPROT;
assign m_axi_arqos = M_AXI_ARQOS;
assign m_axi_arregion = M_AXI_ARREGION;
assign m_axi_aruser = M_AXI_ARUSER;
assign M_AXI_RID = m_axi_rid;
assign M_AXI_RDATA = m_axi_rdata;
assign M_AXI_RRESP = m_axi_rresp;
assign M_AXI_RUSER = m_axi_ruser;
assign S_AXIS_TDATA = s_axis_tdata;
assign S_AXIS_TSTRB = s_axis_tstrb;
assign S_AXIS_TKEEP = s_axis_tkeep;
assign S_AXIS_TID = s_axis_tid;
assign S_AXIS_TDEST = s_axis_tdest;
assign S_AXIS_TUSER = s_axis_tuser;
assign m_axis_tdata = M_AXIS_TDATA;
assign m_axis_tstrb = M_AXIS_TSTRB;
assign m_axis_tkeep = M_AXIS_TKEEP;
assign m_axis_tid = M_AXIS_TID;
assign m_axis_tdest = M_AXIS_TDEST;
assign m_axis_tuser = M_AXIS_TUSER;
assign AXI_AW_PROG_FULL_THRESH = axi_aw_prog_full_thresh;
assign AXI_AW_PROG_EMPTY_THRESH = axi_aw_prog_empty_thresh;
assign axi_aw_data_count = AXI_AW_DATA_COUNT;
assign axi_aw_wr_data_count = AXI_AW_WR_DATA_COUNT;
assign axi_aw_rd_data_count = AXI_AW_RD_DATA_COUNT;
assign AXI_W_PROG_FULL_THRESH = axi_w_prog_full_thresh;
assign AXI_W_PROG_EMPTY_THRESH = axi_w_prog_empty_thresh;
assign axi_w_data_count = AXI_W_DATA_COUNT;
assign axi_w_wr_data_count = AXI_W_WR_DATA_COUNT;
assign axi_w_rd_data_count = AXI_W_RD_DATA_COUNT;
assign AXI_B_PROG_FULL_THRESH = axi_b_prog_full_thresh;
assign AXI_B_PROG_EMPTY_THRESH = axi_b_prog_empty_thresh;
assign axi_b_data_count = AXI_B_DATA_COUNT;
assign axi_b_wr_data_count = AXI_B_WR_DATA_COUNT;
assign axi_b_rd_data_count = AXI_B_RD_DATA_COUNT;
assign AXI_AR_PROG_FULL_THRESH = axi_ar_prog_full_thresh;
assign AXI_AR_PROG_EMPTY_THRESH = axi_ar_prog_empty_thresh;
assign axi_ar_data_count = AXI_AR_DATA_COUNT;
assign axi_ar_wr_data_count = AXI_AR_WR_DATA_COUNT;
assign axi_ar_rd_data_count = AXI_AR_RD_DATA_COUNT;
assign AXI_R_PROG_FULL_THRESH = axi_r_prog_full_thresh;
assign AXI_R_PROG_EMPTY_THRESH = axi_r_prog_empty_thresh;
assign axi_r_data_count = AXI_R_DATA_COUNT;
assign axi_r_wr_data_count = AXI_R_WR_DATA_COUNT;
assign axi_r_rd_data_count = AXI_R_RD_DATA_COUNT;
assign AXIS_PROG_FULL_THRESH = axis_prog_full_thresh;
assign AXIS_PROG_EMPTY_THRESH = axis_prog_empty_thresh;
assign axis_data_count = AXIS_DATA_COUNT;
assign axis_wr_data_count = AXIS_WR_DATA_COUNT;
assign axis_rd_data_count = AXIS_RD_DATA_COUNT;
generate if (C_INTERFACE_TYPE == 0) begin : conv_fifo
fifo_generator_v13_1_3_CONV_VER
#(
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_USE_DOUT_RST == 1 ? C_DOUT_RST_VAL : 0),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_FAMILY (C_FAMILY),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RD_RST (C_HAS_RD_RST),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_HAS_WR_RST (C_HAS_WR_RST),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_FREQ (C_RD_FREQ),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE)
)
fifo_generator_v13_1_3_conv_dut
(
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.CLK (CLK),
.RST (RST),
.SRST (SRST),
.WR_CLK (WR_CLK),
.WR_RST (WR_RST),
.RD_CLK (RD_CLK),
.RD_RST (RD_RST),
.DIN (DIN),
.WR_EN (WR_EN),
.RD_EN (RD_EN),
.PROG_EMPTY_THRESH (PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT (PROG_EMPTY_THRESH_ASSERT),
.PROG_EMPTY_THRESH_NEGATE (PROG_EMPTY_THRESH_NEGATE),
.PROG_FULL_THRESH (PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT (PROG_FULL_THRESH_ASSERT),
.PROG_FULL_THRESH_NEGATE (PROG_FULL_THRESH_NEGATE),
.INT_CLK (INT_CLK),
.INJECTDBITERR (INJECTDBITERR),
.INJECTSBITERR (INJECTSBITERR),
.DOUT (DOUT),
.FULL (FULL),
.ALMOST_FULL (ALMOST_FULL),
.WR_ACK (WR_ACK),
.OVERFLOW (OVERFLOW),
.EMPTY (EMPTY),
.ALMOST_EMPTY (ALMOST_EMPTY),
.VALID (VALID),
.UNDERFLOW (UNDERFLOW),
.DATA_COUNT (DATA_COUNT),
.RD_DATA_COUNT (RD_DATA_COUNT),
.WR_DATA_COUNT (wr_data_count_in),
.PROG_FULL (PROG_FULL),
.PROG_EMPTY (PROG_EMPTY),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.wr_rst_busy_o (wr_rst_busy_o),
.wr_rst_busy (wr_rst_busy_i),
.rd_rst_busy (rd_rst_busy),
.wr_rst_i_out (wr_rst_int),
.rd_rst_i_out (rd_rst_int)
);
end endgenerate
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_AXI_SIZE_WIDTH = 3;
localparam C_AXI_BURST_WIDTH = 2;
localparam C_AXI_CACHE_WIDTH = 4;
localparam C_AXI_PROT_WIDTH = 3;
localparam C_AXI_QOS_WIDTH = 4;
localparam C_AXI_REGION_WIDTH = 4;
localparam C_AXI_BRESP_WIDTH = 2;
localparam C_AXI_RRESP_WIDTH = 2;
localparam IS_AXI_STREAMING = C_INTERFACE_TYPE == 1 ? 1 : 0;
localparam TDATA_OFFSET = C_HAS_AXIS_TDATA == 1 ? C_DIN_WIDTH_AXIS-C_AXIS_TDATA_WIDTH : C_DIN_WIDTH_AXIS;
localparam TSTRB_OFFSET = C_HAS_AXIS_TSTRB == 1 ? TDATA_OFFSET-C_AXIS_TSTRB_WIDTH : TDATA_OFFSET;
localparam TKEEP_OFFSET = C_HAS_AXIS_TKEEP == 1 ? TSTRB_OFFSET-C_AXIS_TKEEP_WIDTH : TSTRB_OFFSET;
localparam TID_OFFSET = C_HAS_AXIS_TID == 1 ? TKEEP_OFFSET-C_AXIS_TID_WIDTH : TKEEP_OFFSET;
localparam TDEST_OFFSET = C_HAS_AXIS_TDEST == 1 ? TID_OFFSET-C_AXIS_TDEST_WIDTH : TID_OFFSET;
localparam TUSER_OFFSET = C_HAS_AXIS_TUSER == 1 ? TDEST_OFFSET-C_AXIS_TUSER_WIDTH : TDEST_OFFSET;
localparam LOG_DEPTH_AXIS = find_log2(C_WR_DEPTH_AXIS);
localparam LOG_WR_DEPTH = find_log2(C_WR_DEPTH);
function [LOG_DEPTH_AXIS-1:0] bin2gray;
input [LOG_DEPTH_AXIS-1:0] x;
begin
bin2gray = x ^ (x>>1);
end
endfunction
function [LOG_DEPTH_AXIS-1:0] gray2bin;
input [LOG_DEPTH_AXIS-1:0] x;
integer i;
begin
gray2bin[LOG_DEPTH_AXIS-1] = x[LOG_DEPTH_AXIS-1];
for(i=LOG_DEPTH_AXIS-2; i>=0; i=i-1) begin
gray2bin[i] = gray2bin[i+1] ^ x[i];
end
end
endfunction
wire [(LOG_WR_DEPTH)-1 : 0] w_cnt_gc_asreg_last;
wire [LOG_WR_DEPTH-1 : 0] w_q [0:C_SYNCHRONIZER_STAGE] ;
wire [LOG_WR_DEPTH-1 : 0] w_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_rd = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_gc = 0;
reg [LOG_WR_DEPTH-1 : 0] r_cnt = 0;
wire [LOG_WR_DEPTH : 0] adj_w_cnt_rd_pad;
wire [LOG_WR_DEPTH : 0] r_inv_pad;
wire [LOG_WR_DEPTH-1 : 0] d_cnt;
reg [LOG_WR_DEPTH : 0] d_cnt_pad = 0;
reg adj_w_cnt_rd_pad_0 = 0;
reg r_inv_pad_0 = 0;
genvar l;
generate for (l = 1; ((l <= C_SYNCHRONIZER_STAGE) && (C_HAS_DATA_COUNTS_AXIS == 3 && C_INTERFACE_TYPE == 0) ); l = l + 1) begin : g_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_WR_DEPTH)
)
rd_stg_inst
(
.RST (rd_rst_int),
.CLK (RD_CLK),
.DIN (w_q[l-1]),
.DOUT (w_q[l])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS == 3) begin : fifo_ic_adapter
assign wr_eop_ad = WR_EN & !(FULL);
assign rd_eop_ad = RD_EN & !(EMPTY);
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt <= 1'b0;
else if (wr_eop_ad)
w_cnt <= w_cnt + 1;
end
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt_gc <= 1'b0;
else
w_cnt_gc <= bin2gray(w_cnt);
end
assign w_q[0] = w_cnt_gc;
assign w_cnt_gc_asreg_last = w_q[C_SYNCHRONIZER_STAGE];
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
w_cnt_rd <= 1'b0;
else
w_cnt_rd <= gray2bin(w_cnt_gc_asreg_last);
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
r_cnt <= 1'b0;
else if (rd_eop_ad)
r_cnt <= r_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_w_cnt_rd_pad[LOG_WR_DEPTH : 1] = w_cnt_rd;
assign r_inv_pad[LOG_WR_DEPTH : 1] = ~r_cnt;
assign adj_w_cnt_rd_pad[0] = adj_w_cnt_rd_pad_0;
assign r_inv_pad[0] = r_inv_pad_0;
always @ ( rd_eop_ad )
begin
if (!rd_eop_ad) begin
adj_w_cnt_rd_pad_0 <= 1'b1;
r_inv_pad_0 <= 1'b1;
end else begin
adj_w_cnt_rd_pad_0 <= 1'b0;
r_inv_pad_0 <= 1'b0;
end
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
d_cnt_pad <= 1'b0;
else
d_cnt_pad <= adj_w_cnt_rd_pad + r_inv_pad ;
end
assign d_cnt = d_cnt_pad [LOG_WR_DEPTH : 1] ;
assign WR_DATA_COUNT = d_cnt;
end endgenerate // fifo_ic_adapter
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS != 3) begin : fifo_icn_adapter
assign WR_DATA_COUNT = wr_data_count_in;
end endgenerate // fifo_icn_adapter
wire inverted_reset = ~S_ARESETN;
wire axi_rs_rst;
wire [C_DIN_WIDTH_AXIS-1:0] axis_din ;
wire [C_DIN_WIDTH_AXIS-1:0] axis_dout ;
wire axis_full ;
wire axis_almost_full ;
wire axis_empty ;
wire axis_s_axis_tready;
wire axis_m_axis_tvalid;
wire axis_wr_en ;
wire axis_rd_en ;
wire axis_we ;
wire axis_re ;
wire [C_WR_PNTR_WIDTH_AXIS:0] axis_dc;
reg axis_pkt_read = 1'b0;
wire axis_rd_rst;
wire axis_wr_rst;
generate if (C_INTERFACE_TYPE > 0 && (C_AXIS_TYPE == 1 || C_WACH_TYPE == 1 ||
C_WDCH_TYPE == 1 || C_WRCH_TYPE == 1 || C_RACH_TYPE == 1 || C_RDCH_TYPE == 1)) begin : gaxi_rs_rst
reg rst_d1 = 0 ;
reg rst_d2 = 0 ;
reg [3:0] axi_rst = 4'h0 ;
always @ (posedge inverted_reset or posedge S_ACLK) begin
if (inverted_reset) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
axi_rst <= 4'hf;
end else begin
rst_d1 <= #`TCQ 1'b0;
rst_d2 <= #`TCQ rst_d1;
axi_rst <= #`TCQ {axi_rst[2:0],1'b0};
end
end
assign axi_rs_rst = axi_rst[3];//rst_d2;
end endgenerate // gaxi_rs_rst
generate if (IS_AXI_STREAMING == 1 && C_AXIS_TYPE == 0) begin : axi_streaming
// Write protection when almost full or prog_full is high
assign axis_we = (C_PROG_FULL_TYPE_AXIS != 0) ? axis_s_axis_tready & S_AXIS_TVALID :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_s_axis_tready & S_AXIS_TVALID : S_AXIS_TVALID;
// Read protection when almost empty or prog_empty is high
assign axis_re = (C_PROG_EMPTY_TYPE_AXIS != 0) ? axis_m_axis_tvalid & M_AXIS_TREADY :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_m_axis_tvalid & M_AXIS_TREADY : M_AXIS_TREADY;
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? axis_we & S_ACLK_EN : axis_we;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? axis_re & M_ACLK_EN : axis_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_AXIS == 2 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_AXIS == 11 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_AXIS),
.C_WR_DEPTH (C_WR_DEPTH_AXIS),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_DOUT_WIDTH (C_DIN_WIDTH_AXIS),
.C_RD_DEPTH (C_WR_DEPTH_AXIS),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_AXIS),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_AXIS),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_AXIS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS),
.C_USE_ECC (C_USE_ECC_AXIS),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_AXIS),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (C_APPLICATION_TYPE_AXIS == 1 ? 1: 0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_FIFO_TYPE (C_APPLICATION_TYPE_AXIS == 1 ? 0: C_APPLICATION_TYPE_AXIS),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_axis_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (axis_wr_en),
.RD_EN (axis_rd_en),
.PROG_FULL_THRESH (AXIS_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH (AXIS_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.INJECTDBITERR (AXIS_INJECTDBITERR),
.INJECTSBITERR (AXIS_INJECTSBITERR),
.DIN (axis_din),
.DOUT (axis_dout),
.FULL (axis_full),
.EMPTY (axis_empty),
.ALMOST_FULL (axis_almost_full),
.PROG_FULL (AXIS_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXIS_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (AXIS_OVERFLOW),
.VALID (),
.UNDERFLOW (AXIS_UNDERFLOW),
.DATA_COUNT (axis_dc),
.RD_DATA_COUNT (AXIS_RD_DATA_COUNT),
.WR_DATA_COUNT (AXIS_WR_DATA_COUNT),
.SBITERR (AXIS_SBITERR),
.DBITERR (AXIS_DBITERR),
.wr_rst_busy (wr_rst_busy_axis),
.rd_rst_busy (rd_rst_busy_axis),
.wr_rst_i_out (axis_wr_rst),
.rd_rst_i_out (axis_rd_rst),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign axis_s_axis_tready = (IS_8SERIES == 0) ? ~axis_full : (C_IMPLEMENTATION_TYPE_AXIS == 5 || C_IMPLEMENTATION_TYPE_AXIS == 13) ? ~(axis_full | wr_rst_busy_axis) : ~axis_full;
assign axis_m_axis_tvalid = (C_APPLICATION_TYPE_AXIS != 1) ? ~axis_empty : ~axis_empty & axis_pkt_read;
assign S_AXIS_TREADY = axis_s_axis_tready;
assign M_AXIS_TVALID = axis_m_axis_tvalid;
end endgenerate // axi_streaming
wire axis_wr_eop;
reg axis_wr_eop_d1 = 1'b0;
wire axis_rd_eop;
integer axis_pkt_cnt;
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 1) begin : gaxis_pkt_fifo_cc
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (axis_pkt_cnt == 1) && ~axis_wr_eop_d1)
axis_pkt_read <= 1'b0;
else if ((axis_pkt_cnt > 0) || (axis_almost_full && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_wr_eop_d1 <= 1'b0;
else
axis_wr_eop_d1 <= axis_wr_eop;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_cnt <= 0;
else if (axis_wr_eop_d1 && ~axis_rd_eop)
axis_pkt_cnt <= axis_pkt_cnt + 1;
else if (axis_rd_eop && ~axis_wr_eop_d1)
axis_pkt_cnt <= axis_pkt_cnt - 1;
end
end endgenerate // gaxis_pkt_fifo_cc
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_gc = 0;
wire [(LOG_DEPTH_AXIS)-1 : 0] axis_wpkt_cnt_gc_asreg_last;
wire axis_rd_has_rst;
wire [0:C_SYNCHRONIZER_STAGE] axis_af_q ;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q [0:C_SYNCHRONIZER_STAGE] ;
wire [1:C_SYNCHRONIZER_STAGE] axis_af_q_temp = 0;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_rd = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_rpkt_cnt = 0;
wire [LOG_DEPTH_AXIS : 0] adj_axis_wpkt_cnt_rd_pad;
wire [LOG_DEPTH_AXIS : 0] rpkt_inv_pad;
wire [LOG_DEPTH_AXIS-1 : 0] diff_pkt_cnt;
reg [LOG_DEPTH_AXIS : 0] diff_pkt_cnt_pad = 0;
reg adj_axis_wpkt_cnt_rd_pad_0 = 0;
reg rpkt_inv_pad_0 = 0;
wire axis_af_rd ;
generate if (C_HAS_RST == 1) begin : rst_blk_has
assign axis_rd_has_rst = axis_rd_rst;
end endgenerate //rst_blk_has
generate if (C_HAS_RST == 0) begin :rst_blk_no
assign axis_rd_has_rst = 1'b0;
end endgenerate //rst_blk_no
genvar i;
generate for (i = 1; ((i <= C_SYNCHRONIZER_STAGE) && (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) ); i = i + 1) begin : gpkt_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_DEPTH_AXIS)
)
rd_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (wpkt_q[i-1]),
.DOUT (wpkt_q[i])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (1)
)
wr_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (axis_af_q[i-1]),
.DOUT (axis_af_q[i])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) begin : gaxis_pkt_fifo_ic
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (diff_pkt_cnt == 1))
axis_pkt_read <= 1'b0;
else if ((diff_pkt_cnt > 0) || (axis_af_rd && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt <= 1'b0;
else if (axis_wr_eop)
axis_wpkt_cnt <= axis_wpkt_cnt + 1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt_gc <= 1'b0;
else
axis_wpkt_cnt_gc <= bin2gray(axis_wpkt_cnt);
end
assign wpkt_q[0] = axis_wpkt_cnt_gc;
assign axis_wpkt_cnt_gc_asreg_last = wpkt_q[C_SYNCHRONIZER_STAGE];
assign axis_af_q[0] = axis_almost_full;
//assign axis_af_q[1:C_SYNCHRONIZER_STAGE] = axis_af_q_temp[1:C_SYNCHRONIZER_STAGE];
assign axis_af_rd = axis_af_q[C_SYNCHRONIZER_STAGE];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_wpkt_cnt_rd <= 1'b0;
else
axis_wpkt_cnt_rd <= gray2bin(axis_wpkt_cnt_gc_asreg_last);
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_rpkt_cnt <= 1'b0;
else if (axis_rd_eop)
axis_rpkt_cnt <= axis_rpkt_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_axis_wpkt_cnt_rd_pad[LOG_DEPTH_AXIS : 1] = axis_wpkt_cnt_rd;
assign rpkt_inv_pad[LOG_DEPTH_AXIS : 1] = ~axis_rpkt_cnt;
assign adj_axis_wpkt_cnt_rd_pad[0] = adj_axis_wpkt_cnt_rd_pad_0;
assign rpkt_inv_pad[0] = rpkt_inv_pad_0;
always @ ( axis_rd_eop )
begin
if (!axis_rd_eop) begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b1;
rpkt_inv_pad_0 <= 1'b1;
end else begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b0;
rpkt_inv_pad_0 <= 1'b0;
end
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
diff_pkt_cnt_pad <= 1'b0;
else
diff_pkt_cnt_pad <= adj_axis_wpkt_cnt_rd_pad + rpkt_inv_pad ;
end
assign diff_pkt_cnt = diff_pkt_cnt_pad [LOG_DEPTH_AXIS : 1] ;
end endgenerate // gaxis_pkt_fifo_ic
// Generate the accurate data count for axi stream packet fifo configuration
reg [C_WR_PNTR_WIDTH_AXIS:0] axis_dc_pkt_fifo = 0;
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 1 && C_APPLICATION_TYPE_AXIS == 1) begin : gdc_pkt
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_dc_pkt_fifo <= 0;
else if (axis_wr_en && (~axis_rd_en))
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo + 1;
else if (~axis_wr_en && axis_rd_en)
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo - 1;
end
assign AXIS_DATA_COUNT = axis_dc_pkt_fifo;
end endgenerate // gdc_pkt
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 0 && C_APPLICATION_TYPE_AXIS == 1) begin : gndc_pkt
assign AXIS_DATA_COUNT = 0;
end endgenerate // gndc_pkt
generate if (IS_AXI_STREAMING == 1 && C_APPLICATION_TYPE_AXIS != 1) begin : gdc
assign AXIS_DATA_COUNT = axis_dc;
end endgenerate // gdc
// Register Slice for Write Address Channel
generate if (C_AXIS_TYPE == 1) begin : gaxis_reg_slice
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? S_AXIS_TVALID & S_ACLK_EN : S_AXIS_TVALID;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? M_AXIS_TREADY & M_ACLK_EN : M_AXIS_TREADY;
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_AXIS),
.C_REG_CONFIG (C_REG_SLICE_MODE_AXIS)
)
axis_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (axis_din),
.S_VALID (axis_wr_en),
.S_READY (S_AXIS_TREADY),
// Master side
.M_PAYLOAD_DATA (axis_dout),
.M_VALID (M_AXIS_TVALID),
.M_READY (axis_rd_en)
);
end endgenerate // gaxis_reg_slice
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDATA == 1) begin : tdata
assign axis_din[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET] = S_AXIS_TDATA;
assign M_AXIS_TDATA = axis_dout[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TSTRB == 1) begin : tstrb
assign axis_din[TDATA_OFFSET-1:TSTRB_OFFSET] = S_AXIS_TSTRB;
assign M_AXIS_TSTRB = axis_dout[TDATA_OFFSET-1:TSTRB_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TKEEP == 1) begin : tkeep
assign axis_din[TSTRB_OFFSET-1:TKEEP_OFFSET] = S_AXIS_TKEEP;
assign M_AXIS_TKEEP = axis_dout[TSTRB_OFFSET-1:TKEEP_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TID == 1) begin : tid
assign axis_din[TKEEP_OFFSET-1:TID_OFFSET] = S_AXIS_TID;
assign M_AXIS_TID = axis_dout[TKEEP_OFFSET-1:TID_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDEST == 1) begin : tdest
assign axis_din[TID_OFFSET-1:TDEST_OFFSET] = S_AXIS_TDEST;
assign M_AXIS_TDEST = axis_dout[TID_OFFSET-1:TDEST_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TUSER == 1) begin : tuser
assign axis_din[TDEST_OFFSET-1:TUSER_OFFSET] = S_AXIS_TUSER;
assign M_AXIS_TUSER = axis_dout[TDEST_OFFSET-1:TUSER_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TLAST == 1) begin : tlast
assign axis_din[0] = S_AXIS_TLAST;
assign M_AXIS_TLAST = axis_dout[0];
end endgenerate
//###########################################################################
// AXI FULL Write Channel (axi_write_channel)
//###########################################################################
localparam IS_AXI_FULL = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE != 2)) ? 1 : 0;
localparam IS_AXI_LITE = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE == 2)) ? 1 : 0;
localparam IS_AXI_FULL_WACH = ((IS_AXI_FULL == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WDCH = ((IS_AXI_FULL == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WRCH = ((IS_AXI_FULL == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RACH = ((IS_AXI_FULL == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RDCH = ((IS_AXI_FULL == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WACH = ((IS_AXI_LITE == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WDCH = ((IS_AXI_LITE == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WRCH = ((IS_AXI_LITE == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RACH = ((IS_AXI_LITE == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RDCH = ((IS_AXI_LITE == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_WR_ADDR_CH = ((IS_AXI_FULL_WACH == 1) || (IS_AXI_LITE_WACH == 1)) ? 1 : 0;
localparam IS_WR_DATA_CH = ((IS_AXI_FULL_WDCH == 1) || (IS_AXI_LITE_WDCH == 1)) ? 1 : 0;
localparam IS_WR_RESP_CH = ((IS_AXI_FULL_WRCH == 1) || (IS_AXI_LITE_WRCH == 1)) ? 1 : 0;
localparam IS_RD_ADDR_CH = ((IS_AXI_FULL_RACH == 1) || (IS_AXI_LITE_RACH == 1)) ? 1 : 0;
localparam IS_RD_DATA_CH = ((IS_AXI_FULL_RDCH == 1) || (IS_AXI_LITE_RDCH == 1)) ? 1 : 0;
localparam AWID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WACH;
localparam AWADDR_OFFSET = AWID_OFFSET - C_AXI_ADDR_WIDTH;
localparam AWLEN_OFFSET = C_AXI_TYPE != 2 ? AWADDR_OFFSET - C_AXI_LEN_WIDTH : AWADDR_OFFSET;
localparam AWSIZE_OFFSET = C_AXI_TYPE != 2 ? AWLEN_OFFSET - C_AXI_SIZE_WIDTH : AWLEN_OFFSET;
localparam AWBURST_OFFSET = C_AXI_TYPE != 2 ? AWSIZE_OFFSET - C_AXI_BURST_WIDTH : AWSIZE_OFFSET;
localparam AWLOCK_OFFSET = C_AXI_TYPE != 2 ? AWBURST_OFFSET - C_AXI_LOCK_WIDTH : AWBURST_OFFSET;
localparam AWCACHE_OFFSET = C_AXI_TYPE != 2 ? AWLOCK_OFFSET - C_AXI_CACHE_WIDTH : AWLOCK_OFFSET;
localparam AWPROT_OFFSET = AWCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam AWQOS_OFFSET = AWPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam AWREGION_OFFSET = C_AXI_TYPE == 1 ? AWQOS_OFFSET - C_AXI_REGION_WIDTH : AWQOS_OFFSET;
localparam AWUSER_OFFSET = C_HAS_AXI_AWUSER == 1 ? AWREGION_OFFSET-C_AXI_AWUSER_WIDTH : AWREGION_OFFSET;
localparam WID_OFFSET = (C_AXI_TYPE == 3 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WDCH;
localparam WDATA_OFFSET = WID_OFFSET - C_AXI_DATA_WIDTH;
localparam WSTRB_OFFSET = WDATA_OFFSET - C_AXI_DATA_WIDTH/8;
localparam WUSER_OFFSET = C_HAS_AXI_WUSER == 1 ? WSTRB_OFFSET-C_AXI_WUSER_WIDTH : WSTRB_OFFSET;
localparam BID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WRCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WRCH;
localparam BRESP_OFFSET = BID_OFFSET - C_AXI_BRESP_WIDTH;
localparam BUSER_OFFSET = C_HAS_AXI_BUSER == 1 ? BRESP_OFFSET-C_AXI_BUSER_WIDTH : BRESP_OFFSET;
wire [C_DIN_WIDTH_WACH-1:0] wach_din ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout_pkt ;
wire wach_full ;
wire wach_almost_full ;
wire wach_prog_full ;
wire wach_empty ;
wire wach_almost_empty ;
wire wach_prog_empty ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_din ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_dout ;
wire wdch_full ;
wire wdch_almost_full ;
wire wdch_prog_full ;
wire wdch_empty ;
wire wdch_almost_empty ;
wire wdch_prog_empty ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_din ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_dout ;
wire wrch_full ;
wire wrch_almost_full ;
wire wrch_prog_full ;
wire wrch_empty ;
wire wrch_almost_empty ;
wire wrch_prog_empty ;
wire axi_aw_underflow_i;
wire axi_w_underflow_i ;
wire axi_b_underflow_i ;
wire axi_aw_overflow_i ;
wire axi_w_overflow_i ;
wire axi_b_overflow_i ;
wire axi_wr_underflow_i;
wire axi_wr_overflow_i ;
wire wach_s_axi_awready;
wire wach_m_axi_awvalid;
wire wach_wr_en ;
wire wach_rd_en ;
wire wdch_s_axi_wready ;
wire wdch_m_axi_wvalid ;
wire wdch_wr_en ;
wire wdch_rd_en ;
wire wrch_s_axi_bvalid ;
wire wrch_m_axi_bready ;
wire wrch_wr_en ;
wire wrch_rd_en ;
wire txn_count_up ;
wire txn_count_down ;
wire awvalid_en ;
wire awvalid_pkt ;
wire awready_pkt ;
integer wr_pkt_count ;
wire wach_we ;
wire wach_re ;
wire wdch_we ;
wire wdch_re ;
wire wrch_we ;
wire wrch_re ;
generate if (IS_WR_ADDR_CH == 1) begin : axi_write_address_channel
// Write protection when almost full or prog_full is high
assign wach_we = (C_PROG_FULL_TYPE_WACH != 0) ? wach_s_axi_awready & S_AXI_AWVALID : S_AXI_AWVALID;
// Read protection when almost empty or prog_empty is high
assign wach_re = (C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH == 1) ?
wach_m_axi_awvalid & awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY && wach_m_axi_awvalid :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH == 1) ?
awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY : 1'b0;
assign wach_wr_en = (C_HAS_SLAVE_CE == 1) ? wach_we & S_ACLK_EN : wach_we;
assign wach_rd_en = (C_HAS_MASTER_CE == 1) ? wach_re & M_ACLK_EN : wach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WACH == 2 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WACH == 11 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_DEPTH (C_WR_DEPTH_WACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WACH),
.C_RD_DEPTH (C_WR_DEPTH_WACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH),
.C_USE_ECC (C_USE_ECC_WACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_WACH == 1)?0:C_APPLICATION_TYPE_WACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 : 0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wach_wr_en),
.RD_EN (wach_rd_en),
.PROG_FULL_THRESH (AXI_AW_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AW_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.INJECTDBITERR (AXI_AW_INJECTDBITERR),
.INJECTSBITERR (AXI_AW_INJECTSBITERR),
.DIN (wach_din),
.DOUT (wach_dout_pkt),
.FULL (wach_full),
.EMPTY (wach_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_AW_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_AW_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_aw_overflow_i),
.VALID (),
.UNDERFLOW (axi_aw_underflow_i),
.DATA_COUNT (AXI_AW_DATA_COUNT),
.RD_DATA_COUNT (AXI_AW_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AW_WR_DATA_COUNT),
.SBITERR (AXI_AW_SBITERR),
.DBITERR (AXI_AW_DBITERR),
.wr_rst_busy (wr_rst_busy_wach),
.rd_rst_busy (rd_rst_busy_wach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wach_s_axi_awready = (IS_8SERIES == 0) ? ~wach_full : (C_IMPLEMENTATION_TYPE_WACH == 5 || C_IMPLEMENTATION_TYPE_WACH == 13) ? ~(wach_full | wr_rst_busy_wach) : ~wach_full;
assign wach_m_axi_awvalid = ~wach_empty;
assign S_AXI_AWREADY = wach_s_axi_awready;
assign AXI_AW_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_aw_underflow_i : 0;
assign AXI_AW_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_aw_overflow_i : 0;
end endgenerate // axi_write_address_channel
// Register Slice for Write Address Channel
generate if (C_WACH_TYPE == 1) begin : gwach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WACH)
)
wach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wach_din),
.S_VALID (S_AXI_AWVALID),
.S_READY (S_AXI_AWREADY),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
end endgenerate // gwach_reg_slice
generate if (C_APPLICATION_TYPE_WACH == 1 && C_HAS_AXI_WR_CHANNEL == 1) begin : axi_mm_pkt_fifo_wr
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (1)
)
wach_pkt_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (wach_dout_pkt),
.S_VALID (awvalid_pkt),
.S_READY (awready_pkt),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
assign awvalid_pkt = wach_m_axi_awvalid && awvalid_en;
assign txn_count_up = wdch_s_axi_wready && wdch_wr_en && wdch_din[0];
assign txn_count_down = wach_m_axi_awvalid && awready_pkt && awvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset == 1) begin
wr_pkt_count <= 0;
end else begin
if(txn_count_up == 1 && txn_count_down == 0) begin
wr_pkt_count <= wr_pkt_count + 1;
end else if(txn_count_up == 0 && txn_count_down == 1) begin
wr_pkt_count <= wr_pkt_count - 1;
end
end
end //Always end
assign awvalid_en = (wr_pkt_count > 0)?1:0;
end endgenerate
generate if (C_APPLICATION_TYPE_WACH != 1) begin : axi_mm_fifo_wr
assign awvalid_en = 1;
assign wach_dout = wach_dout_pkt;
assign M_AXI_AWVALID = wach_m_axi_awvalid;
end
endgenerate
generate if (IS_WR_DATA_CH == 1) begin : axi_write_data_channel
// Write protection when almost full or prog_full is high
assign wdch_we = (C_PROG_FULL_TYPE_WDCH != 0) ? wdch_s_axi_wready & S_AXI_WVALID : S_AXI_WVALID;
// Read protection when almost empty or prog_empty is high
assign wdch_re = (C_PROG_EMPTY_TYPE_WDCH != 0) ? wdch_m_axi_wvalid & M_AXI_WREADY : M_AXI_WREADY;
assign wdch_wr_en = (C_HAS_SLAVE_CE == 1) ? wdch_we & S_ACLK_EN : wdch_we;
assign wdch_rd_en = (C_HAS_MASTER_CE == 1) ? wdch_re & M_ACLK_EN : wdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WDCH == 2 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WDCH == 11 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WDCH),
.C_WR_DEPTH (C_WR_DEPTH_WDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WDCH),
.C_RD_DEPTH (C_WR_DEPTH_WDCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH),
.C_USE_ECC (C_USE_ECC_WDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wdch_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wdch_wr_en),
.RD_EN (wdch_rd_en),
.PROG_FULL_THRESH (AXI_W_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_W_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.INJECTDBITERR (AXI_W_INJECTDBITERR),
.INJECTSBITERR (AXI_W_INJECTSBITERR),
.DIN (wdch_din),
.DOUT (wdch_dout),
.FULL (wdch_full),
.EMPTY (wdch_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_W_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_W_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_w_overflow_i),
.VALID (),
.UNDERFLOW (axi_w_underflow_i),
.DATA_COUNT (AXI_W_DATA_COUNT),
.RD_DATA_COUNT (AXI_W_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_W_WR_DATA_COUNT),
.SBITERR (AXI_W_SBITERR),
.DBITERR (AXI_W_DBITERR),
.wr_rst_busy (wr_rst_busy_wdch),
.rd_rst_busy (rd_rst_busy_wdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wdch_s_axi_wready = (IS_8SERIES == 0) ? ~wdch_full : (C_IMPLEMENTATION_TYPE_WDCH == 5 || C_IMPLEMENTATION_TYPE_WDCH == 13) ? ~(wdch_full | wr_rst_busy_wdch) : ~wdch_full;
assign wdch_m_axi_wvalid = ~wdch_empty;
assign S_AXI_WREADY = wdch_s_axi_wready;
assign M_AXI_WVALID = wdch_m_axi_wvalid;
assign AXI_W_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_w_underflow_i : 0;
assign AXI_W_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_w_overflow_i : 0;
end endgenerate // axi_write_data_channel
// Register Slice for Write Data Channel
generate if (C_WDCH_TYPE == 1) begin : gwdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WDCH)
)
wdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wdch_din),
.S_VALID (S_AXI_WVALID),
.S_READY (S_AXI_WREADY),
// Master side
.M_PAYLOAD_DATA (wdch_dout),
.M_VALID (M_AXI_WVALID),
.M_READY (M_AXI_WREADY)
);
end endgenerate // gwdch_reg_slice
generate if (IS_WR_RESP_CH == 1) begin : axi_write_resp_channel
// Write protection when almost full or prog_full is high
assign wrch_we = (C_PROG_FULL_TYPE_WRCH != 0) ? wrch_m_axi_bready & M_AXI_BVALID : M_AXI_BVALID;
// Read protection when almost empty or prog_empty is high
assign wrch_re = (C_PROG_EMPTY_TYPE_WRCH != 0) ? wrch_s_axi_bvalid & S_AXI_BREADY : S_AXI_BREADY;
assign wrch_wr_en = (C_HAS_MASTER_CE == 1) ? wrch_we & M_ACLK_EN : wrch_we;
assign wrch_rd_en = (C_HAS_SLAVE_CE == 1) ? wrch_re & S_ACLK_EN : wrch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WRCH == 2 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WRCH == 11 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WRCH),
.C_WR_DEPTH (C_WR_DEPTH_WRCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WRCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_DEPTH (C_WR_DEPTH_WRCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WRCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WRCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WRCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH),
.C_USE_ECC (C_USE_ECC_WRCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WRCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WRCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wrch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wrch_wr_en),
.RD_EN (wrch_rd_en),
.PROG_FULL_THRESH (AXI_B_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_B_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.INJECTDBITERR (AXI_B_INJECTDBITERR),
.INJECTSBITERR (AXI_B_INJECTSBITERR),
.DIN (wrch_din),
.DOUT (wrch_dout),
.FULL (wrch_full),
.EMPTY (wrch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_B_PROG_FULL),
.PROG_EMPTY (AXI_B_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_b_overflow_i),
.VALID (),
.UNDERFLOW (axi_b_underflow_i),
.DATA_COUNT (AXI_B_DATA_COUNT),
.RD_DATA_COUNT (AXI_B_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_B_WR_DATA_COUNT),
.SBITERR (AXI_B_SBITERR),
.DBITERR (AXI_B_DBITERR),
.wr_rst_busy (wr_rst_busy_wrch),
.rd_rst_busy (rd_rst_busy_wrch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wrch_s_axi_bvalid = ~wrch_empty;
assign wrch_m_axi_bready = (IS_8SERIES == 0) ? ~wrch_full : (C_IMPLEMENTATION_TYPE_WRCH == 5 || C_IMPLEMENTATION_TYPE_WRCH == 13) ? ~(wrch_full | wr_rst_busy_wrch) : ~wrch_full;
assign S_AXI_BVALID = wrch_s_axi_bvalid;
assign M_AXI_BREADY = wrch_m_axi_bready;
assign AXI_B_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_b_underflow_i : 0;
assign AXI_B_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_b_overflow_i : 0;
end endgenerate // axi_write_resp_channel
// Register Slice for Write Response Channel
generate if (C_WRCH_TYPE == 1) begin : gwrch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WRCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WRCH)
)
wrch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wrch_din),
.S_VALID (M_AXI_BVALID),
.S_READY (M_AXI_BREADY),
// Master side
.M_PAYLOAD_DATA (wrch_dout),
.M_VALID (S_AXI_BVALID),
.M_READY (S_AXI_BREADY)
);
end endgenerate // gwrch_reg_slice
assign axi_wr_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_aw_underflow_i || axi_w_underflow_i || axi_b_underflow_i) : 0;
assign axi_wr_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_aw_overflow_i || axi_w_overflow_i || axi_b_overflow_i) : 0;
generate if (IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output
assign M_AXI_AWADDR = wach_dout[AWID_OFFSET-1:AWADDR_OFFSET];
assign M_AXI_AWLEN = wach_dout[AWADDR_OFFSET-1:AWLEN_OFFSET];
assign M_AXI_AWSIZE = wach_dout[AWLEN_OFFSET-1:AWSIZE_OFFSET];
assign M_AXI_AWBURST = wach_dout[AWSIZE_OFFSET-1:AWBURST_OFFSET];
assign M_AXI_AWLOCK = wach_dout[AWBURST_OFFSET-1:AWLOCK_OFFSET];
assign M_AXI_AWCACHE = wach_dout[AWLOCK_OFFSET-1:AWCACHE_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWCACHE_OFFSET-1:AWPROT_OFFSET];
assign M_AXI_AWQOS = wach_dout[AWPROT_OFFSET-1:AWQOS_OFFSET];
assign wach_din[AWID_OFFSET-1:AWADDR_OFFSET] = S_AXI_AWADDR;
assign wach_din[AWADDR_OFFSET-1:AWLEN_OFFSET] = S_AXI_AWLEN;
assign wach_din[AWLEN_OFFSET-1:AWSIZE_OFFSET] = S_AXI_AWSIZE;
assign wach_din[AWSIZE_OFFSET-1:AWBURST_OFFSET] = S_AXI_AWBURST;
assign wach_din[AWBURST_OFFSET-1:AWLOCK_OFFSET] = S_AXI_AWLOCK;
assign wach_din[AWLOCK_OFFSET-1:AWCACHE_OFFSET] = S_AXI_AWCACHE;
assign wach_din[AWCACHE_OFFSET-1:AWPROT_OFFSET] = S_AXI_AWPROT;
assign wach_din[AWPROT_OFFSET-1:AWQOS_OFFSET] = S_AXI_AWQOS;
end endgenerate // axi_wach_output
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_awregion
assign M_AXI_AWREGION = wach_dout[AWQOS_OFFSET-1:AWREGION_OFFSET];
end endgenerate // axi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_awregion
assign M_AXI_AWREGION = 0;
end endgenerate // naxi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : axi_awuser
assign M_AXI_AWUSER = wach_dout[AWREGION_OFFSET-1:AWUSER_OFFSET];
end endgenerate // axi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 0) begin : naxi_awuser
assign M_AXI_AWUSER = 0;
end endgenerate // naxi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_awid
assign M_AXI_AWID = wach_dout[C_DIN_WIDTH_WACH-1:AWID_OFFSET];
end endgenerate //axi_awid
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_awid
assign M_AXI_AWID = 0;
end endgenerate //naxi_awid
generate if (IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output
assign M_AXI_WDATA = wdch_dout[WID_OFFSET-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
assign M_AXI_WLAST = wdch_dout[0];
assign wdch_din[WID_OFFSET-1:WDATA_OFFSET] = S_AXI_WDATA;
assign wdch_din[WDATA_OFFSET-1:WSTRB_OFFSET] = S_AXI_WSTRB;
assign wdch_din[0] = S_AXI_WLAST;
end endgenerate // axi_wdch_output
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin
assign M_AXI_WID = wdch_dout[C_DIN_WIDTH_WDCH-1:WID_OFFSET];
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && (C_HAS_AXI_ID == 0 || C_AXI_TYPE != 3)) begin
assign M_AXI_WID = 0;
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1 ) begin
assign M_AXI_WUSER = wdch_dout[WSTRB_OFFSET-1:WUSER_OFFSET];
end endgenerate
generate if (C_HAS_AXI_WUSER == 0) begin
assign M_AXI_WUSER = 0;
end endgenerate
generate if (IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output
assign S_AXI_BRESP = wrch_dout[BID_OFFSET-1:BRESP_OFFSET];
assign wrch_din[BID_OFFSET-1:BRESP_OFFSET] = M_AXI_BRESP;
end endgenerate // axi_wrch_output
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : axi_buser
assign S_AXI_BUSER = wrch_dout[BRESP_OFFSET-1:BUSER_OFFSET];
end endgenerate // axi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 0) begin : naxi_buser
assign S_AXI_BUSER = 0;
end endgenerate // naxi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_bid
assign S_AXI_BID = wrch_dout[C_DIN_WIDTH_WRCH-1:BID_OFFSET];
end endgenerate // axi_bid
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_bid
assign S_AXI_BID = 0 ;
end endgenerate // naxi_bid
generate if (IS_AXI_LITE_WACH == 1 || (IS_AXI_LITE == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output1
assign wach_din = {S_AXI_AWADDR, S_AXI_AWPROT};
assign M_AXI_AWADDR = wach_dout[C_DIN_WIDTH_WACH-1:AWADDR_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWADDR_OFFSET-1:AWPROT_OFFSET];
end endgenerate // axi_wach_output1
generate if (IS_AXI_LITE_WDCH == 1 || (IS_AXI_LITE == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output1
assign wdch_din = {S_AXI_WDATA, S_AXI_WSTRB};
assign M_AXI_WDATA = wdch_dout[C_DIN_WIDTH_WDCH-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
end endgenerate // axi_wdch_output1
generate if (IS_AXI_LITE_WRCH == 1 || (IS_AXI_LITE == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output1
assign wrch_din = M_AXI_BRESP;
assign S_AXI_BRESP = wrch_dout[C_DIN_WIDTH_WRCH-1:BRESP_OFFSET];
end endgenerate // axi_wrch_output1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : gwach_din1
assign wach_din[AWREGION_OFFSET-1:AWUSER_OFFSET] = S_AXI_AWUSER;
end endgenerate // gwach_din1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwach_din2
assign wach_din[C_DIN_WIDTH_WACH-1:AWID_OFFSET] = S_AXI_AWID;
end endgenerate // gwach_din2
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : gwach_din3
assign wach_din[AWQOS_OFFSET-1:AWREGION_OFFSET] = S_AXI_AWREGION;
end endgenerate // gwach_din3
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1) begin : gwdch_din1
assign wdch_din[WSTRB_OFFSET-1:WUSER_OFFSET] = S_AXI_WUSER;
end endgenerate // gwdch_din1
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin : gwdch_din2
assign wdch_din[C_DIN_WIDTH_WDCH-1:WID_OFFSET] = S_AXI_WID;
end endgenerate // gwdch_din2
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : gwrch_din1
assign wrch_din[BRESP_OFFSET-1:BUSER_OFFSET] = M_AXI_BUSER;
end endgenerate // gwrch_din1
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwrch_din2
assign wrch_din[C_DIN_WIDTH_WRCH-1:BID_OFFSET] = M_AXI_BID;
end endgenerate // gwrch_din2
//end of axi_write_channel
//###########################################################################
// AXI FULL Read Channel (axi_read_channel)
//###########################################################################
wire [C_DIN_WIDTH_RACH-1:0] rach_din ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout_pkt ;
wire rach_full ;
wire rach_almost_full ;
wire rach_prog_full ;
wire rach_empty ;
wire rach_almost_empty ;
wire rach_prog_empty ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_din ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_dout ;
wire rdch_full ;
wire rdch_almost_full ;
wire rdch_prog_full ;
wire rdch_empty ;
wire rdch_almost_empty ;
wire rdch_prog_empty ;
wire axi_ar_underflow_i ;
wire axi_r_underflow_i ;
wire axi_ar_overflow_i ;
wire axi_r_overflow_i ;
wire axi_rd_underflow_i ;
wire axi_rd_overflow_i ;
wire rach_s_axi_arready ;
wire rach_m_axi_arvalid ;
wire rach_wr_en ;
wire rach_rd_en ;
wire rdch_m_axi_rready ;
wire rdch_s_axi_rvalid ;
wire rdch_wr_en ;
wire rdch_rd_en ;
wire arvalid_pkt ;
wire arready_pkt ;
wire arvalid_en ;
wire rdch_rd_ok ;
wire accept_next_pkt ;
integer rdch_free_space ;
integer rdch_commited_space ;
wire rach_we ;
wire rach_re ;
wire rdch_we ;
wire rdch_re ;
localparam ARID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RACH;
localparam ARADDR_OFFSET = ARID_OFFSET - C_AXI_ADDR_WIDTH;
localparam ARLEN_OFFSET = C_AXI_TYPE != 2 ? ARADDR_OFFSET - C_AXI_LEN_WIDTH : ARADDR_OFFSET;
localparam ARSIZE_OFFSET = C_AXI_TYPE != 2 ? ARLEN_OFFSET - C_AXI_SIZE_WIDTH : ARLEN_OFFSET;
localparam ARBURST_OFFSET = C_AXI_TYPE != 2 ? ARSIZE_OFFSET - C_AXI_BURST_WIDTH : ARSIZE_OFFSET;
localparam ARLOCK_OFFSET = C_AXI_TYPE != 2 ? ARBURST_OFFSET - C_AXI_LOCK_WIDTH : ARBURST_OFFSET;
localparam ARCACHE_OFFSET = C_AXI_TYPE != 2 ? ARLOCK_OFFSET - C_AXI_CACHE_WIDTH : ARLOCK_OFFSET;
localparam ARPROT_OFFSET = ARCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam ARQOS_OFFSET = ARPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam ARREGION_OFFSET = C_AXI_TYPE == 1 ? ARQOS_OFFSET - C_AXI_REGION_WIDTH : ARQOS_OFFSET;
localparam ARUSER_OFFSET = C_HAS_AXI_ARUSER == 1 ? ARREGION_OFFSET-C_AXI_ARUSER_WIDTH : ARREGION_OFFSET;
localparam RID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RDCH;
localparam RDATA_OFFSET = RID_OFFSET - C_AXI_DATA_WIDTH;
localparam RRESP_OFFSET = RDATA_OFFSET - C_AXI_RRESP_WIDTH;
localparam RUSER_OFFSET = C_HAS_AXI_RUSER == 1 ? RRESP_OFFSET-C_AXI_RUSER_WIDTH : RRESP_OFFSET;
generate if (IS_RD_ADDR_CH == 1) begin : axi_read_addr_channel
// Write protection when almost full or prog_full is high
assign rach_we = (C_PROG_FULL_TYPE_RACH != 0) ? rach_s_axi_arready & S_AXI_ARVALID : S_AXI_ARVALID;
// Read protection when almost empty or prog_empty is high
// assign rach_rd_en = (C_PROG_EMPTY_TYPE_RACH != 5) ? rach_m_axi_arvalid & M_AXI_ARREADY : M_AXI_ARREADY && arvalid_en;
assign rach_re = (C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH == 1) ?
rach_m_axi_arvalid & arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY && rach_m_axi_arvalid :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH == 1) ?
arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY : 1'b0;
assign rach_wr_en = (C_HAS_SLAVE_CE == 1) ? rach_we & S_ACLK_EN : rach_we;
assign rach_rd_en = (C_HAS_MASTER_CE == 1) ? rach_re & M_ACLK_EN : rach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RACH == 2 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RACH == 11 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RACH),
.C_WR_DEPTH (C_WR_DEPTH_RACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_DOUT_WIDTH (C_DIN_WIDTH_RACH),
.C_RD_DEPTH (C_WR_DEPTH_RACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH),
.C_USE_ECC (C_USE_ECC_RACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_RACH == 1)?0:C_APPLICATION_TYPE_RACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rach_wr_en),
.RD_EN (rach_rd_en),
.PROG_FULL_THRESH (AXI_AR_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AR_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.INJECTDBITERR (AXI_AR_INJECTDBITERR),
.INJECTSBITERR (AXI_AR_INJECTSBITERR),
.DIN (rach_din),
.DOUT (rach_dout_pkt),
.FULL (rach_full),
.EMPTY (rach_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_AR_PROG_FULL),
.PROG_EMPTY (AXI_AR_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_ar_overflow_i),
.VALID (),
.UNDERFLOW (axi_ar_underflow_i),
.DATA_COUNT (AXI_AR_DATA_COUNT),
.RD_DATA_COUNT (AXI_AR_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AR_WR_DATA_COUNT),
.SBITERR (AXI_AR_SBITERR),
.DBITERR (AXI_AR_DBITERR),
.wr_rst_busy (wr_rst_busy_rach),
.rd_rst_busy (rd_rst_busy_rach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rach_s_axi_arready = (IS_8SERIES == 0) ? ~rach_full : (C_IMPLEMENTATION_TYPE_RACH == 5 || C_IMPLEMENTATION_TYPE_RACH == 13) ? ~(rach_full | wr_rst_busy_rach) : ~rach_full;
assign rach_m_axi_arvalid = ~rach_empty;
assign S_AXI_ARREADY = rach_s_axi_arready;
assign AXI_AR_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_ar_underflow_i : 0;
assign AXI_AR_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_ar_overflow_i : 0;
end endgenerate // axi_read_addr_channel
// Register Slice for Read Address Channel
generate if (C_RACH_TYPE == 1) begin : grach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RACH)
)
rach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rach_din),
.S_VALID (S_AXI_ARVALID),
.S_READY (S_AXI_ARREADY),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice
// Register Slice for Read Address Channel for MM Packet FIFO
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH == 1) begin : grach_reg_slice_mm_pkt_fifo
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (1)
)
reg_slice_mm_pkt_fifo_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (rach_dout_pkt),
.S_VALID (arvalid_pkt),
.S_READY (arready_pkt),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice_mm_pkt_fifo
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH != 1) begin : grach_m_axi_arvalid
assign M_AXI_ARVALID = rach_m_axi_arvalid;
assign rach_dout = rach_dout_pkt;
end endgenerate // grach_m_axi_arvalid
generate if (C_APPLICATION_TYPE_RACH == 1 && C_HAS_AXI_RD_CHANNEL == 1) begin : axi_mm_pkt_fifo_rd
assign rdch_rd_ok = rdch_s_axi_rvalid && rdch_rd_en;
assign arvalid_pkt = rach_m_axi_arvalid && arvalid_en;
assign accept_next_pkt = rach_m_axi_arvalid && arready_pkt && arvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset) begin
rdch_commited_space <= 0;
end else begin
if(rdch_rd_ok && !accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space-1;
end else if(!rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1);
end else if(rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]);
end
end
end //Always end
always@(*) begin
rdch_free_space <= (C_WR_DEPTH_RDCH-(rdch_commited_space+rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1));
end
assign arvalid_en = (rdch_free_space >= 0)?1:0;
end
endgenerate
generate if (C_APPLICATION_TYPE_RACH != 1) begin : axi_mm_fifo_rd
assign arvalid_en = 1;
end
endgenerate
generate if (IS_RD_DATA_CH == 1) begin : axi_read_data_channel
// Write protection when almost full or prog_full is high
assign rdch_we = (C_PROG_FULL_TYPE_RDCH != 0) ? rdch_m_axi_rready & M_AXI_RVALID : M_AXI_RVALID;
// Read protection when almost empty or prog_empty is high
assign rdch_re = (C_PROG_EMPTY_TYPE_RDCH != 0) ? rdch_s_axi_rvalid & S_AXI_RREADY : S_AXI_RREADY;
assign rdch_wr_en = (C_HAS_MASTER_CE == 1) ? rdch_we & M_ACLK_EN : rdch_we;
assign rdch_rd_en = (C_HAS_SLAVE_CE == 1) ? rdch_re & S_ACLK_EN : rdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RDCH == 2 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RDCH == 11 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RDCH),
.C_WR_DEPTH (C_WR_DEPTH_RDCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_RDCH),
.C_RD_DEPTH (C_WR_DEPTH_RDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH),
.C_USE_ECC (C_USE_ECC_RDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_RDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rdch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rdch_wr_en),
.RD_EN (rdch_rd_en),
.PROG_FULL_THRESH (AXI_R_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_R_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.INJECTDBITERR (AXI_R_INJECTDBITERR),
.INJECTSBITERR (AXI_R_INJECTSBITERR),
.DIN (rdch_din),
.DOUT (rdch_dout),
.FULL (rdch_full),
.EMPTY (rdch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_R_PROG_FULL),
.PROG_EMPTY (AXI_R_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_r_overflow_i),
.VALID (),
.UNDERFLOW (axi_r_underflow_i),
.DATA_COUNT (AXI_R_DATA_COUNT),
.RD_DATA_COUNT (AXI_R_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_R_WR_DATA_COUNT),
.SBITERR (AXI_R_SBITERR),
.DBITERR (AXI_R_DBITERR),
.wr_rst_busy (wr_rst_busy_rdch),
.rd_rst_busy (rd_rst_busy_rdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rdch_s_axi_rvalid = ~rdch_empty;
assign rdch_m_axi_rready = (IS_8SERIES == 0) ? ~rdch_full : (C_IMPLEMENTATION_TYPE_RDCH == 5 || C_IMPLEMENTATION_TYPE_RDCH == 13) ? ~(rdch_full | wr_rst_busy_rdch) : ~rdch_full;
assign S_AXI_RVALID = rdch_s_axi_rvalid;
assign M_AXI_RREADY = rdch_m_axi_rready;
assign AXI_R_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_r_underflow_i : 0;
assign AXI_R_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_r_overflow_i : 0;
end endgenerate //axi_read_data_channel
// Register Slice for read Data Channel
generate if (C_RDCH_TYPE == 1) begin : grdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RDCH)
)
rdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rdch_din),
.S_VALID (M_AXI_RVALID),
.S_READY (M_AXI_RREADY),
// Master side
.M_PAYLOAD_DATA (rdch_dout),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY)
);
end endgenerate // grdch_reg_slice
assign axi_rd_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_ar_underflow_i || axi_r_underflow_i) : 0;
assign axi_rd_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_ar_overflow_i || axi_r_overflow_i) : 0;
generate if (IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) begin : axi_full_rach_output
assign M_AXI_ARADDR = rach_dout[ARID_OFFSET-1:ARADDR_OFFSET];
assign M_AXI_ARLEN = rach_dout[ARADDR_OFFSET-1:ARLEN_OFFSET];
assign M_AXI_ARSIZE = rach_dout[ARLEN_OFFSET-1:ARSIZE_OFFSET];
assign M_AXI_ARBURST = rach_dout[ARSIZE_OFFSET-1:ARBURST_OFFSET];
assign M_AXI_ARLOCK = rach_dout[ARBURST_OFFSET-1:ARLOCK_OFFSET];
assign M_AXI_ARCACHE = rach_dout[ARLOCK_OFFSET-1:ARCACHE_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARCACHE_OFFSET-1:ARPROT_OFFSET];
assign M_AXI_ARQOS = rach_dout[ARPROT_OFFSET-1:ARQOS_OFFSET];
assign rach_din[ARID_OFFSET-1:ARADDR_OFFSET] = S_AXI_ARADDR;
assign rach_din[ARADDR_OFFSET-1:ARLEN_OFFSET] = S_AXI_ARLEN;
assign rach_din[ARLEN_OFFSET-1:ARSIZE_OFFSET] = S_AXI_ARSIZE;
assign rach_din[ARSIZE_OFFSET-1:ARBURST_OFFSET] = S_AXI_ARBURST;
assign rach_din[ARBURST_OFFSET-1:ARLOCK_OFFSET] = S_AXI_ARLOCK;
assign rach_din[ARLOCK_OFFSET-1:ARCACHE_OFFSET] = S_AXI_ARCACHE;
assign rach_din[ARCACHE_OFFSET-1:ARPROT_OFFSET] = S_AXI_ARPROT;
assign rach_din[ARPROT_OFFSET-1:ARQOS_OFFSET] = S_AXI_ARQOS;
end endgenerate // axi_full_rach_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_arregion
assign M_AXI_ARREGION = rach_dout[ARQOS_OFFSET-1:ARREGION_OFFSET];
end endgenerate // axi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_arregion
assign M_AXI_ARREGION = 0;
end endgenerate // naxi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : axi_aruser
assign M_AXI_ARUSER = rach_dout[ARREGION_OFFSET-1:ARUSER_OFFSET];
end endgenerate // axi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 0) begin : naxi_aruser
assign M_AXI_ARUSER = 0;
end endgenerate // naxi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_arid
assign M_AXI_ARID = rach_dout[C_DIN_WIDTH_RACH-1:ARID_OFFSET];
end endgenerate // axi_arid
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_arid
assign M_AXI_ARID = 0;
end endgenerate // naxi_arid
generate if (IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) begin : axi_full_rdch_output
assign S_AXI_RDATA = rdch_dout[RID_OFFSET-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
assign S_AXI_RLAST = rdch_dout[0];
assign rdch_din[RID_OFFSET-1:RDATA_OFFSET] = M_AXI_RDATA;
assign rdch_din[RDATA_OFFSET-1:RRESP_OFFSET] = M_AXI_RRESP;
assign rdch_din[0] = M_AXI_RLAST;
end endgenerate // axi_full_rdch_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : axi_full_ruser_output
assign S_AXI_RUSER = rdch_dout[RRESP_OFFSET-1:RUSER_OFFSET];
end endgenerate // axi_full_ruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 0) begin : axi_full_nruser_output
assign S_AXI_RUSER = 0;
end endgenerate // axi_full_nruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_rid
assign S_AXI_RID = rdch_dout[C_DIN_WIDTH_RDCH-1:RID_OFFSET];
end endgenerate // axi_rid
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_rid
assign S_AXI_RID = 0;
end endgenerate // naxi_rid
generate if (IS_AXI_LITE_RACH == 1 || (IS_AXI_LITE == 1 && C_RACH_TYPE == 1)) begin : axi_lite_rach_output1
assign rach_din = {S_AXI_ARADDR, S_AXI_ARPROT};
assign M_AXI_ARADDR = rach_dout[C_DIN_WIDTH_RACH-1:ARADDR_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARADDR_OFFSET-1:ARPROT_OFFSET];
end endgenerate // axi_lite_rach_output
generate if (IS_AXI_LITE_RDCH == 1 || (IS_AXI_LITE == 1 && C_RDCH_TYPE == 1)) begin : axi_lite_rdch_output1
assign rdch_din = {M_AXI_RDATA, M_AXI_RRESP};
assign S_AXI_RDATA = rdch_dout[C_DIN_WIDTH_RDCH-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
end endgenerate // axi_lite_rdch_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : grach_din1
assign rach_din[ARREGION_OFFSET-1:ARUSER_OFFSET] = S_AXI_ARUSER;
end endgenerate // grach_din1
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grach_din2
assign rach_din[C_DIN_WIDTH_RACH-1:ARID_OFFSET] = S_AXI_ARID;
end endgenerate // grach_din2
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin
assign rach_din[ARQOS_OFFSET-1:ARREGION_OFFSET] = S_AXI_ARREGION;
end endgenerate
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : grdch_din1
assign rdch_din[RRESP_OFFSET-1:RUSER_OFFSET] = M_AXI_RUSER;
end endgenerate // grdch_din1
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grdch_din2
assign rdch_din[C_DIN_WIDTH_RDCH-1:RID_OFFSET] = M_AXI_RID;
end endgenerate // grdch_din2
//end of axi_read_channel
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_UNDERFLOW == 1) begin : gaxi_comm_uf
assign UNDERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_underflow_i || axi_rd_underflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_underflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_underflow_i : 0;
end endgenerate // gaxi_comm_uf
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_OVERFLOW == 1) begin : gaxi_comm_of
assign OVERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_overflow_i || axi_rd_overflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_overflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_overflow_i : 0;
end endgenerate // gaxi_comm_of
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic or Wiring Logic
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Write Address Channel
generate if (C_WACH_TYPE == 2) begin : gwach_pass_through
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWQOS = S_AXI_AWQOS;
assign M_AXI_AWREGION = S_AXI_AWREGION;
assign M_AXI_AWUSER = S_AXI_AWUSER;
assign S_AXI_AWREADY = M_AXI_AWREADY;
assign M_AXI_AWVALID = S_AXI_AWVALID;
end endgenerate // gwach_pass_through;
// Wiring logic for Write Data Channel
generate if (C_WDCH_TYPE == 2) begin : gwdch_pass_through
assign M_AXI_WID = S_AXI_WID;
assign M_AXI_WDATA = S_AXI_WDATA;
assign M_AXI_WSTRB = S_AXI_WSTRB;
assign M_AXI_WLAST = S_AXI_WLAST;
assign M_AXI_WUSER = S_AXI_WUSER;
assign S_AXI_WREADY = M_AXI_WREADY;
assign M_AXI_WVALID = S_AXI_WVALID;
end endgenerate // gwdch_pass_through;
// Wiring logic for Write Response Channel
generate if (C_WRCH_TYPE == 2) begin : gwrch_pass_through
assign S_AXI_BID = M_AXI_BID;
assign S_AXI_BRESP = M_AXI_BRESP;
assign S_AXI_BUSER = M_AXI_BUSER;
assign M_AXI_BREADY = S_AXI_BREADY;
assign S_AXI_BVALID = M_AXI_BVALID;
end endgenerate // gwrch_pass_through;
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Read Address Channel
generate if (C_RACH_TYPE == 2) begin : grach_pass_through
assign M_AXI_ARID = S_AXI_ARID;
assign M_AXI_ARADDR = S_AXI_ARADDR;
assign M_AXI_ARLEN = S_AXI_ARLEN;
assign M_AXI_ARSIZE = S_AXI_ARSIZE;
assign M_AXI_ARBURST = S_AXI_ARBURST;
assign M_AXI_ARLOCK = S_AXI_ARLOCK;
assign M_AXI_ARCACHE = S_AXI_ARCACHE;
assign M_AXI_ARPROT = S_AXI_ARPROT;
assign M_AXI_ARQOS = S_AXI_ARQOS;
assign M_AXI_ARREGION = S_AXI_ARREGION;
assign M_AXI_ARUSER = S_AXI_ARUSER;
assign S_AXI_ARREADY = M_AXI_ARREADY;
assign M_AXI_ARVALID = S_AXI_ARVALID;
end endgenerate // grach_pass_through;
// Wiring logic for Read Data Channel
generate if (C_RDCH_TYPE == 2) begin : grdch_pass_through
assign S_AXI_RID = M_AXI_RID;
assign S_AXI_RLAST = M_AXI_RLAST;
assign S_AXI_RUSER = M_AXI_RUSER;
assign S_AXI_RDATA = M_AXI_RDATA;
assign S_AXI_RRESP = M_AXI_RRESP;
assign S_AXI_RVALID = M_AXI_RVALID;
assign M_AXI_RREADY = S_AXI_RREADY;
end endgenerate // grdch_pass_through;
// Wiring logic for AXI Streaming
generate if (C_AXIS_TYPE == 2) begin : gaxis_pass_through
assign M_AXIS_TDATA = S_AXIS_TDATA;
assign M_AXIS_TSTRB = S_AXIS_TSTRB;
assign M_AXIS_TKEEP = S_AXIS_TKEEP;
assign M_AXIS_TID = S_AXIS_TID;
assign M_AXIS_TDEST = S_AXIS_TDEST;
assign M_AXIS_TUSER = S_AXIS_TUSER;
assign M_AXIS_TLAST = S_AXIS_TLAST;
assign S_AXIS_TREADY = M_AXIS_TREADY;
assign M_AXIS_TVALID = S_AXIS_TVALID;
end endgenerate // gaxis_pass_through;
endmodule //fifo_generator_v13_1_3
/*******************************************************************************
* Declaration of top-level module for Conventional FIFO
******************************************************************************/
module fifo_generator_v13_1_3_CONV_VER
#(
parameter C_COMMON_CLOCK = 0,
parameter C_INTERFACE_TYPE = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "virtex7", //Not allowed in Verilog model
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
parameter C_AXI_TYPE = 0
)
(
input BACKUP,
input BACKUP_MARKER,
input CLK,
input RST,
input SRST,
input WR_CLK,
input WR_RST,
input RD_CLK,
input RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input WR_EN,
input RD_EN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input INT_CLK,
input INJECTDBITERR,
input INJECTSBITERR,
output [C_DOUT_WIDTH-1:0] DOUT,
output FULL,
output ALMOST_FULL,
output WR_ACK,
output OVERFLOW,
output EMPTY,
output ALMOST_EMPTY,
output VALID,
output UNDERFLOW,
output [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_FULL,
output PROG_EMPTY,
output SBITERR,
output DBITERR,
output wr_rst_busy_o,
output wr_rst_busy,
output rd_rst_busy,
output wr_rst_i_out,
output rd_rst_i_out
);
/*
******************************************************************************
* Definition of Parameters
******************************************************************************
* C_COMMON_CLOCK : Common Clock (1), Independent Clocks (0)
* C_COUNT_TYPE : *not used
* C_DATA_COUNT_WIDTH : Width of DATA_COUNT bus
* C_DEFAULT_VALUE : *not used
* C_DIN_WIDTH : Width of DIN bus
* C_DOUT_RST_VAL : Reset value of DOUT
* C_DOUT_WIDTH : Width of DOUT bus
* C_ENABLE_RLOCS : *not used
* C_FAMILY : not used in bhv model
* C_FULL_FLAGS_RST_VAL : Full flags rst val (0 or 1)
* C_HAS_ALMOST_EMPTY : 1=Core has ALMOST_EMPTY flag
* C_HAS_ALMOST_FULL : 1=Core has ALMOST_FULL flag
* C_HAS_BACKUP : *not used
* C_HAS_DATA_COUNT : 1=Core has DATA_COUNT bus
* C_HAS_INT_CLK : not used in bhv model
* C_HAS_MEMINIT_FILE : *not used
* C_HAS_OVERFLOW : 1=Core has OVERFLOW flag
* C_HAS_RD_DATA_COUNT : 1=Core has RD_DATA_COUNT bus
* C_HAS_RD_RST : *not used
* C_HAS_RST : 1=Core has Async Rst
* C_HAS_SRST : 1=Core has Sync Rst
* C_HAS_UNDERFLOW : 1=Core has UNDERFLOW flag
* C_HAS_VALID : 1=Core has VALID flag
* C_HAS_WR_ACK : 1=Core has WR_ACK flag
* C_HAS_WR_DATA_COUNT : 1=Core has WR_DATA_COUNT bus
* C_HAS_WR_RST : *not used
* C_IMPLEMENTATION_TYPE : 0=Common-Clock Bram/Dram
* 1=Common-Clock ShiftRam
* 2=Indep. Clocks Bram/Dram
* 3=Virtex-4 Built-in
* 4=Virtex-5 Built-in
* C_INIT_WR_PNTR_VAL : *not used
* C_MEMORY_TYPE : 1=Block RAM
* 2=Distributed RAM
* 3=Shift RAM
* 4=Built-in FIFO
* C_MIF_FILE_NAME : *not used
* C_OPTIMIZATION_MODE : *not used
* C_OVERFLOW_LOW : 1=OVERFLOW active low
* C_PRELOAD_LATENCY : Latency of read: 0, 1, 2
* C_PRELOAD_REGS : 1=Use output registers
* C_PRIM_FIFO_TYPE : not used in bhv model
* C_PROG_EMPTY_THRESH_ASSERT_VAL: PROG_EMPTY assert threshold
* C_PROG_EMPTY_THRESH_NEGATE_VAL: PROG_EMPTY negate threshold
* C_PROG_EMPTY_TYPE : 0=No programmable empty
* 1=Single prog empty thresh constant
* 2=Multiple prog empty thresh constants
* 3=Single prog empty thresh input
* 4=Multiple prog empty thresh inputs
* C_PROG_FULL_THRESH_ASSERT_VAL : PROG_FULL assert threshold
* C_PROG_FULL_THRESH_NEGATE_VAL : PROG_FULL negate threshold
* C_PROG_FULL_TYPE : 0=No prog full
* 1=Single prog full thresh constant
* 2=Multiple prog full thresh constants
* 3=Single prog full thresh input
* 4=Multiple prog full thresh inputs
* C_RD_DATA_COUNT_WIDTH : Width of RD_DATA_COUNT bus
* C_RD_DEPTH : Depth of read interface (2^N)
* C_RD_FREQ : not used in bhv model
* C_RD_PNTR_WIDTH : always log2(C_RD_DEPTH)
* C_UNDERFLOW_LOW : 1=UNDERFLOW active low
* C_USE_DOUT_RST : 1=Resets DOUT on RST
* C_USE_ECC : Used for error injection purpose
* C_USE_EMBEDDED_REG : 1=Use BRAM embedded output register
* C_USE_FIFO16_FLAGS : not used in bhv model
* C_USE_FWFT_DATA_COUNT : 1=Use extra logic for FWFT data count
* C_VALID_LOW : 1=VALID active low
* C_WR_ACK_LOW : 1=WR_ACK active low
* C_WR_DATA_COUNT_WIDTH : Width of WR_DATA_COUNT bus
* C_WR_DEPTH : Depth of write interface (2^N)
* C_WR_FREQ : not used in bhv model
* C_WR_PNTR_WIDTH : always log2(C_WR_DEPTH)
* C_WR_RESPONSE_LATENCY : *not used
* C_MSGON_VAL : *not used by bhv model
* C_ENABLE_RST_SYNC : 0 = Use WR_RST & RD_RST
* 1 = Use RST
* C_ERROR_INJECTION_TYPE : 0 = No error injection
* 1 = Single bit error injection only
* 2 = Double bit error injection only
* 3 = Single and double bit error injection
******************************************************************************
* Definition of Ports
******************************************************************************
* BACKUP : Not used
* BACKUP_MARKER: Not used
* CLK : Clock
* DIN : Input data bus
* PROG_EMPTY_THRESH : Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_ASSERT: Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_NEGATE: Threshold for Programmable Empty Flag
* PROG_FULL_THRESH : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_ASSERT : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_NEGATE : Threshold for Programmable Full Flag
* RD_CLK : Read Domain Clock
* RD_EN : Read enable
* RD_RST : Read Reset
* RST : Asynchronous Reset
* SRST : Synchronous Reset
* WR_CLK : Write Domain Clock
* WR_EN : Write enable
* WR_RST : Write Reset
* INT_CLK : Internal Clock
* INJECTSBITERR: Inject Signle bit error
* INJECTDBITERR: Inject Double bit error
* ALMOST_EMPTY : One word remaining in FIFO
* ALMOST_FULL : One empty space remaining in FIFO
* DATA_COUNT : Number of data words in fifo( synchronous to CLK)
* DOUT : Output data bus
* EMPTY : Empty flag
* FULL : Full flag
* OVERFLOW : Last write rejected
* PROG_EMPTY : Programmable Empty Flag
* PROG_FULL : Programmable Full Flag
* RD_DATA_COUNT: Number of data words in fifo (synchronous to RD_CLK)
* UNDERFLOW : Last read rejected
* VALID : Last read acknowledged, DOUT bus VALID
* WR_ACK : Last write acknowledged
* WR_DATA_COUNT: Number of data words in fifo (synchronous to WR_CLK)
* SBITERR : Single Bit ECC Error Detected
* DBITERR : Double Bit ECC Error Detected
******************************************************************************
*/
//----------------------------------------------------------------------------
//- Internal Signals for delayed input signals
//- All the input signals except Clock are delayed by 100 ps and then given to
//- the models.
//----------------------------------------------------------------------------
reg rst_delayed ;
reg empty_fb ;
reg srst_delayed ;
reg wr_rst_delayed ;
reg rd_rst_delayed ;
reg wr_en_delayed ;
reg rd_en_delayed ;
reg [C_DIN_WIDTH-1:0] din_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate_delayed ;
reg injectdbiterr_delayed ;
reg injectsbiterr_delayed ;
wire empty_p0_out;
always @* rst_delayed <= #`TCQ RST ;
always @* empty_fb <= #`TCQ empty_p0_out ;
always @* srst_delayed <= #`TCQ SRST ;
always @* wr_rst_delayed <= #`TCQ WR_RST ;
always @* rd_rst_delayed <= #`TCQ RD_RST ;
always @* din_delayed <= #`TCQ DIN ;
always @* wr_en_delayed <= #`TCQ WR_EN ;
always @* rd_en_delayed <= #`TCQ RD_EN ;
always @* prog_empty_thresh_delayed <= #`TCQ PROG_EMPTY_THRESH ;
always @* prog_empty_thresh_assert_delayed <= #`TCQ PROG_EMPTY_THRESH_ASSERT ;
always @* prog_empty_thresh_negate_delayed <= #`TCQ PROG_EMPTY_THRESH_NEGATE ;
always @* prog_full_thresh_delayed <= #`TCQ PROG_FULL_THRESH ;
always @* prog_full_thresh_assert_delayed <= #`TCQ PROG_FULL_THRESH_ASSERT ;
always @* prog_full_thresh_negate_delayed <= #`TCQ PROG_FULL_THRESH_NEGATE ;
always @* injectdbiterr_delayed <= #`TCQ INJECTDBITERR ;
always @* injectsbiterr_delayed <= #`TCQ INJECTSBITERR ;
/*****************************************************************************
* Derived parameters
****************************************************************************/
//There are 2 Verilog behavioral models
// 0 = Common-Clock FIFO/ShiftRam FIFO
// 1 = Independent Clocks FIFO
// 2 = Low Latency Synchronous FIFO
// 3 = Low Latency Asynchronous FIFO
localparam C_VERILOG_IMPL = (C_FIFO_TYPE == 3) ? 2 :
(C_IMPLEMENTATION_TYPE == 2) ? 1 : 0;
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//Internal reset signals
reg rd_rst_asreg = 0;
wire rd_rst_asreg_d1;
wire rd_rst_asreg_d2;
reg rd_rst_asreg_d3 = 0;
reg rd_rst_reg = 0;
wire rd_rst_comb;
reg wr_rst_d0 = 0;
reg wr_rst_d1 = 0;
reg wr_rst_d2 = 0;
reg rd_rst_d0 = 0;
reg rd_rst_d1 = 0;
reg rd_rst_d2 = 0;
reg rd_rst_d3 = 0;
reg wrrst_done = 0;
reg rdrst_done = 0;
reg wr_rst_asreg = 0;
wire wr_rst_asreg_d1;
wire wr_rst_asreg_d2;
reg wr_rst_asreg_d3 = 0;
reg rd_rst_wr_d0 = 0;
reg rd_rst_wr_d1 = 0;
reg rd_rst_wr_d2 = 0;
reg wr_rst_reg = 0;
reg rst_active_i = 1'b1;
reg rst_delayed_d1 = 1'b1;
reg rst_delayed_d2 = 1'b1;
wire wr_rst_comb;
wire wr_rst_i;
wire rd_rst_i;
wire rst_i;
//Internal reset signals
reg rst_asreg = 0;
reg srst_asreg = 0;
wire rst_asreg_d1;
wire rst_asreg_d2;
reg srst_asreg_d1 = 0;
reg srst_asreg_d2 = 0;
reg rst_reg = 0;
reg srst_reg = 0;
wire rst_comb;
wire srst_comb;
reg rst_full_gen_i = 0;
reg rst_full_ff_i = 0;
reg [2:0] sckt_ff0_bsy_o_i = {3{1'b0}};
wire RD_CLK_P0_IN;
wire RST_P0_IN;
wire RD_EN_FIFO_IN;
wire RD_EN_P0_IN;
wire ALMOST_EMPTY_FIFO_OUT;
wire ALMOST_FULL_FIFO_OUT;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT_FIFO_OUT;
wire [C_DOUT_WIDTH-1:0] DOUT_FIFO_OUT;
wire EMPTY_FIFO_OUT;
wire fifo_empty_fb;
wire FULL_FIFO_OUT;
wire OVERFLOW_FIFO_OUT;
wire PROG_EMPTY_FIFO_OUT;
wire PROG_FULL_FIFO_OUT;
wire VALID_FIFO_OUT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT_FIFO_OUT;
wire UNDERFLOW_FIFO_OUT;
wire WR_ACK_FIFO_OUT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT_FIFO_OUT;
//***************************************************************************
// Internal Signals
// The core uses either the internal_ wires or the preload0_ wires depending
// on whether the core uses Preload0 or not.
// When using preload0, the internal signals connect the internal core to
// the preload logic, and the external core's interfaces are tied to the
// preload0 signals from the preload logic.
//***************************************************************************
wire [C_DOUT_WIDTH-1:0] DATA_P0_OUT;
wire VALID_P0_OUT;
wire EMPTY_P0_OUT;
wire ALMOSTEMPTY_P0_OUT;
reg EMPTY_P0_OUT_Q;
reg ALMOSTEMPTY_P0_OUT_Q;
wire UNDERFLOW_P0_OUT;
wire RDEN_P0_OUT;
wire [C_DOUT_WIDTH-1:0] DATA_P0_IN;
wire EMPTY_P0_IN;
reg [31:0] DATA_COUNT_FWFT;
reg SS_FWFT_WR ;
reg SS_FWFT_RD ;
wire sbiterr_fifo_out;
wire dbiterr_fifo_out;
wire inject_sbit_err;
wire inject_dbit_err;
wire safety_ckt_wr_rst;
wire safety_ckt_rd_rst;
reg sckt_wr_rst_i_q = 1'b0;
wire w_fab_read_data_valid_i;
wire w_read_data_valid_i;
wire w_ram_valid_i;
// Assign 0 if not selected to avoid 'X' propogation to S/DBITERR.
assign inject_sbit_err = ((C_ERROR_INJECTION_TYPE == 1) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectsbiterr_delayed : 0;
assign inject_dbit_err = ((C_ERROR_INJECTION_TYPE == 2) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectdbiterr_delayed : 0;
assign wr_rst_i_out = wr_rst_i;
assign rd_rst_i_out = rd_rst_i;
assign wr_rst_busy_o = wr_rst_busy | rst_full_gen_i | sckt_ff0_bsy_o_i[2];
generate if (C_FULL_FLAGS_RST_VAL == 0 && C_EN_SAFETY_CKT == 1) begin : gsckt_bsy_o
wire clk_i = C_COMMON_CLOCK ? CLK : WR_CLK;
always @ (posedge clk_i)
sckt_ff0_bsy_o_i <= {sckt_ff0_bsy_o_i[1:0],wr_rst_busy};
end endgenerate
// Choose the behavioral model to instantiate based on the C_VERILOG_IMPL
// parameter (1=Independent Clocks, 0=Common Clock)
localparam FULL_FLAGS_RST_VAL = (C_HAS_SRST == 1) ? 0 : C_FULL_FLAGS_RST_VAL;
generate
case (C_VERILOG_IMPL)
0 : begin : block1
//Common Clock Behavioral Model
fifo_generator_v13_1_3_bhv_ver_ss
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL ((C_AXI_TYPE == 0 && C_FIFO_TYPE == 1) ? 1 : C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ss
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.CLK (CLK),
.RST (rst_i),
.SRST (srst_delayed),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.USER_EMPTY_FB (empty_fb),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.DATA_COUNT (DATA_COUNT_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
1 : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.fab_read_data_valid_i (w_fab_read_data_valid_i),
.read_data_valid_i (w_read_data_valid_i),
.ram_valid_i (w_ram_valid_i),
.DBITERR (dbiterr_fifo_out)
);
end
2 : begin : ll_afifo_inst
fifo_generator_v13_1_3_beh_ver_ll_afifo
#(
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ll_afifo
(
.DIN (din_delayed),
.RD_CLK (RD_CLK),
.RD_EN (rd_en_delayed),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.WR_CLK (WR_CLK),
.WR_EN (wr_en_delayed),
.DOUT (DOUT),
.EMPTY (EMPTY),
.FULL (FULL)
);
end
default : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
endcase
endgenerate
//**************************************************************************
// Connect Internal Signals
// (Signals labeled internal_*)
// In the normal case, these signals tie directly to the FIFO's inputs and
// outputs.
// In the case of Preload Latency 0 or 1, there are intermediate
// signals between the internal FIFO and the preload logic.
//**************************************************************************
//***********************************************
// If First-Word Fall-Through, instantiate
// the preload0 (FWFT) module
//***********************************************
wire rd_en_to_fwft_fifo;
wire sbiterr_fwft;
wire dbiterr_fwft;
wire [C_DOUT_WIDTH-1:0] dout_fwft;
wire empty_fwft;
wire rd_en_fifo_in;
wire stage2_reg_en_i;
wire [1:0] valid_stages_i;
wire rst_fwft;
//wire empty_p0_out;
reg [C_SYNCHRONIZER_STAGE-1:0] pkt_empty_sync = 'b1;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
localparam IS_PKT_FIFO = (C_FIFO_TYPE == 1) ? 1 : 0;
localparam IS_AXIS_PKT_FIFO = (C_FIFO_TYPE == 1 && C_AXI_TYPE == 0) ? 1 : 0;
assign rst_fwft = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 1'b0;
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 3) begin : block2
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
fgpl0
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (RST_P0_IN),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (RD_EN_P0_IN),
.FIFOEMPTY (EMPTY_P0_IN),
.FIFODATA (DATA_P0_IN),
.FIFOSBITERR (sbiterr_fifo_out),
.FIFODBITERR (dbiterr_fifo_out),
// Output
.USERDATA (dout_fwft),
.USERVALID (VALID_P0_OUT),
.USEREMPTY (empty_fwft),
.USERALMOSTEMPTY (ALMOSTEMPTY_P0_OUT),
.USERUNDERFLOW (UNDERFLOW_P0_OUT),
.RAMVALID (),
.FIFORDEN (rd_en_fifo_in),
.USERSBITERR (sbiterr_fwft),
.USERDBITERR (dbiterr_fwft),
.STAGE2_REG_EN (stage2_reg_en_i),
.fab_read_data_valid_i_o (w_fab_read_data_valid_i),
.read_data_valid_i_o (w_read_data_valid_i),
.ram_valid_i_o (w_ram_valid_i),
.VALID_STAGES (valid_stages_i)
);
//***********************************************
// Connect inputs to preload (FWFT) module
//***********************************************
//Connect the RD_CLK of the Preload (FWFT) module to CLK if we
// have a common-clock FIFO, or RD_CLK if we have an
// independent clock FIFO
assign RD_CLK_P0_IN = ((C_VERILOG_IMPL == 0) ? CLK : RD_CLK);
assign RST_P0_IN = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 0;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
assign EMPTY_P0_IN = C_EN_SAFETY_CKT ? fifo_empty_fb : EMPTY_FIFO_OUT;
assign DATA_P0_IN = DOUT_FIFO_OUT;
//***********************************************
// Connect outputs from preload (FWFT) module
//***********************************************
assign VALID = VALID_P0_OUT ;
assign ALMOST_EMPTY = ALMOSTEMPTY_P0_OUT;
assign UNDERFLOW = UNDERFLOW_P0_OUT ;
assign RD_EN_FIFO_IN = rd_en_fifo_in;
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
assign DATA_COUNT = (C_USE_FWFT_DATA_COUNT == 0)? DATA_COUNT_FIFO_OUT:
(C_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) ? DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:0] :
DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH+1];
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
EMPTY_P0_OUT_Q <= 1;
ALMOSTEMPTY_P0_OUT_Q <= 1;
end else begin
EMPTY_P0_OUT_Q <= #`TCQ empty_p0_out;
// EMPTY_P0_OUT_Q <= #`TCQ EMPTY_FIFO_OUT;
ALMOSTEMPTY_P0_OUT_Q <= #`TCQ ALMOSTEMPTY_P0_OUT;
end
end //always
//***********************************************
// logic for common-clock data count when FWFT is selected
//***********************************************
initial begin
SS_FWFT_RD = 1'b0;
DATA_COUNT_FWFT = 0 ;
SS_FWFT_WR = 1'b0 ;
end //initial
//***********************************************
// common-clock data count is implemented as an
// up-down counter. SS_FWFT_WR and SS_FWFT_RD
// are the up/down enables for the counter.
//***********************************************
always @ (RD_EN or VALID_P0_OUT or WR_EN or FULL_FIFO_OUT or empty_p0_out) begin
if (C_VALID_LOW == 1) begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && ~VALID_P0_OUT) : (~empty_p0_out && RD_EN && ~VALID_P0_OUT) ;
end else begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && VALID_P0_OUT) : (~empty_p0_out && RD_EN && VALID_P0_OUT) ;
end
SS_FWFT_WR = (WR_EN && (~FULL_FIFO_OUT)) ;
end
//***********************************************
// common-clock data count is implemented as an
// up-down counter for FWFT. This always block
// calculates the counter.
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
DATA_COUNT_FWFT <= 0;
end else begin
//if (srst_delayed && (C_HAS_SRST == 1) ) begin
if ((srst_delayed | wr_rst_busy | rd_rst_busy) && (C_HAS_SRST == 1) ) begin
DATA_COUNT_FWFT <= #`TCQ 0;
end else begin
case ( {SS_FWFT_WR, SS_FWFT_RD})
2'b00: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
2'b01: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT - 1 ;
2'b10: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT + 1 ;
2'b11: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
endcase
end //if SRST
end //IF RST
end //always
end endgenerate // : block2
// AXI Streaming Packet FIFO
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_plus1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_reg = 0;
reg partial_packet = 0;
reg stage1_eop_d1 = 0;
reg rd_en_fifo_in_d1 = 0;
reg eop_at_stage2 = 0;
reg ram_pkt_empty = 0;
reg ram_pkt_empty_d1 = 0;
wire [C_DOUT_WIDTH-1:0] dout_p0_out;
wire packet_empty_wr;
wire wr_rst_fwft_pkt_fifo;
wire dummy_wr_eop;
wire ram_wr_en_pkt_fifo;
wire wr_eop;
wire ram_rd_en_compare;
wire stage1_eop;
wire pkt_ready_to_read;
wire rd_en_2_stage2;
// Generate Dummy WR_EOP for partial packet (Only for AXI Streaming)
// When Packet EMPTY is high, and FIFO is full, then generate the dummy WR_EOP
// When dummy WR_EOP is high, mask the actual EOP to avoid double increment of
// write packet count
generate if (IS_FWFT == 1 && IS_AXIS_PKT_FIFO == 1) begin // gdummy_wr_eop
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
partial_packet <= 1'b0;
else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy)
partial_packet <= #`TCQ 1'b0;
else if (ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]))
partial_packet <= #`TCQ 1'b1;
else if (partial_packet && din_delayed[0] && ram_wr_en_pkt_fifo)
partial_packet <= #`TCQ 1'b0;
end
end
end endgenerate // gdummy_wr_eop
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1) begin // gpkt_fifo_fwft
assign wr_rst_fwft_pkt_fifo = (C_COMMON_CLOCK == 0) ? wr_rst_i : (C_HAS_RST == 1) ? rst_i:1'b0;
assign dummy_wr_eop = ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]) && (~partial_packet);
assign packet_empty_wr = (C_COMMON_CLOCK == 1) ? empty_p0_out : pkt_empty_sync[C_SYNCHRONIZER_STAGE-1];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
stage1_eop_d1 <= 1'b0;
rd_en_fifo_in_d1 <= 1'b0;
end else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
stage1_eop_d1 <= #`TCQ 1'b0;
rd_en_fifo_in_d1 <= #`TCQ 1'b0;
end else begin
stage1_eop_d1 <= #`TCQ stage1_eop;
rd_en_fifo_in_d1 <= #`TCQ rd_en_fifo_in;
end
end
end
assign stage1_eop = (rd_en_fifo_in_d1) ? DOUT_FIFO_OUT[0] : stage1_eop_d1;
assign ram_wr_en_pkt_fifo = wr_en_delayed && (~FULL_FIFO_OUT);
assign wr_eop = ram_wr_en_pkt_fifo && ((din_delayed[0] && (~partial_packet)) || dummy_wr_eop);
assign ram_rd_en_compare = stage2_reg_en_i && stage1_eop;
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (2) // Enable low latency fwft logic
)
pkt_fifo_fwft
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (rst_fwft),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (rd_en_delayed),
.FIFOEMPTY (pkt_ready_to_read),
.FIFODATA (dout_fwft),
.FIFOSBITERR (sbiterr_fwft),
.FIFODBITERR (dbiterr_fwft),
// Output
.USERDATA (dout_p0_out),
.USERVALID (),
.USEREMPTY (empty_p0_out),
.USERALMOSTEMPTY (),
.USERUNDERFLOW (),
.RAMVALID (),
.FIFORDEN (rd_en_2_stage2),
.USERSBITERR (SBITERR),
.USERDBITERR (DBITERR),
.STAGE2_REG_EN (),
.VALID_STAGES ()
);
assign pkt_ready_to_read = ~(!(ram_pkt_empty || empty_fwft) && ((valid_stages_i[0] && valid_stages_i[1]) || eop_at_stage2));
assign rd_en_to_fwft_fifo = ~empty_fwft && rd_en_2_stage2;
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
eop_at_stage2 <= 1'b0;
else if (stage2_reg_en_i)
eop_at_stage2 <= #`TCQ stage1_eop;
end
//---------------------------------------------------------------------------
// Write and Read Packet Count
//---------------------------------------------------------------------------
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count <= 0;
else if (srst_delayed | wr_rst_busy | rd_rst_busy)
wr_pkt_count <= #`TCQ 0;
else if (wr_eop)
wr_pkt_count <= #`TCQ wr_pkt_count + 1;
end
end endgenerate // gpkt_fifo_fwft
assign DOUT = (C_FIFO_TYPE != 1) ? dout_fwft : dout_p0_out;
assign EMPTY = (C_FIFO_TYPE != 1) ? empty_fwft : empty_p0_out;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 1) begin // grss_pkt_cnt
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
rd_pkt_count <= 0;
rd_pkt_count_plus1 <= 1;
end else if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
rd_pkt_count <= #`TCQ 0;
rd_pkt_count_plus1 <= #`TCQ 1;
end else if (stage2_reg_en_i && stage1_eop) begin
rd_pkt_count <= #`TCQ rd_pkt_count + 1;
rd_pkt_count_plus1 <= #`TCQ rd_pkt_count_plus1 + 1;
end
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (SRST | wr_rst_busy | rd_rst_busy) begin
ram_pkt_empty <= #`TCQ 1'b1;
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count) && wr_eop) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count_plus1 == wr_pkt_count) && ~wr_eop && ~ALMOST_FULL_FIFO_OUT && ram_rd_en_compare) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
end endgenerate //grss_pkt_cnt
localparam SYNC_STAGE_WIDTH = (C_SYNCHRONIZER_STAGE+1)*C_WR_PNTR_WIDTH;
reg [SYNC_STAGE_WIDTH-1:0] wr_pkt_count_q = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_b2g = 0;
wire [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_rd;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 0) begin // gras_pkt_cnt
// Delay the write packet count in write clock domain to accomodate the binary to gray conversion delay
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count_b2g <= 0;
else
wr_pkt_count_b2g <= #`TCQ wr_pkt_count;
end
// Synchronize the delayed write packet count in read domain, and also compensate the gray to binay conversion delay
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
wr_pkt_count_q <= 0;
else
wr_pkt_count_q <= #`TCQ {wr_pkt_count_q[SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH-1:0],wr_pkt_count_b2g};
end
always @* begin
if (stage1_eop)
rd_pkt_count <= rd_pkt_count_reg + 1;
else
rd_pkt_count <= rd_pkt_count_reg;
end
assign wr_pkt_count_rd = wr_pkt_count_q[SYNC_STAGE_WIDTH-1:SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
rd_pkt_count_reg <= 0;
else if (rd_en_fifo_in)
rd_pkt_count_reg <= #`TCQ rd_pkt_count;
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (rd_pkt_count != wr_pkt_count_rd) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count_rd) && stage2_reg_en_i) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
// Synchronize the empty in write domain
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
pkt_empty_sync <= 'b1;
else
pkt_empty_sync <= #`TCQ {pkt_empty_sync[C_SYNCHRONIZER_STAGE-2:0], empty_p0_out};
end
end endgenerate //gras_pkt_cnt
generate if (IS_FWFT == 0 || C_FIFO_TYPE == 3) begin : STD_FIFO
//***********************************************
// If NOT First-Word Fall-Through, wire the outputs
// of the internal _ss or _as FIFO directly to the
// output, and do not instantiate the preload0
// module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VALID = VALID_FIFO_OUT;
assign EMPTY = EMPTY_FIFO_OUT;
assign ALMOST_EMPTY = ALMOST_EMPTY_FIFO_OUT;
assign EMPTY_P0_IN = 0;
assign UNDERFLOW = UNDERFLOW_FIFO_OUT;
assign DATA_COUNT = DATA_COUNT_FIFO_OUT;
assign SBITERR = sbiterr_fifo_out;
assign DBITERR = dbiterr_fifo_out;
end endgenerate // STD_FIFO
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 1) begin : NO_PKT_FIFO
assign empty_p0_out = empty_fwft;
assign SBITERR = sbiterr_fwft;
assign DBITERR = dbiterr_fwft;
assign DOUT = dout_fwft;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
end endgenerate // NO_PKT_FIFO
//***********************************************
// Connect user flags to internal signals
//***********************************************
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//RD_DATA_COUNT is 0 when EMPTY and 1 when ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block3
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : RD_DATA_COUNT_FIFO_OUT);
end //block_ic
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block30
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : RD_DATA_COUNT_FIFO_OUT);
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block30_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : (RD_DATA_COUNT_FIFO_OUT));
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30_both
endgenerate
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block3_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : (RD_DATA_COUNT_FIFO_OUT));
end //block_ic_both
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3_both
endgenerate
//If we are not using extra logic for the FWFT data count,
//then connect RD_DATA_COUNT to the RD_DATA_COUNT from the
//internal FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==0 ) begin : block31
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Always connect WR_DATA_COUNT to the WR_DATA_COUNT from the internal
//FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==1) begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
else begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Connect other flags to the internal FIFO instance
assign FULL = FULL_FIFO_OUT;
assign ALMOST_FULL = ALMOST_FULL_FIFO_OUT;
assign WR_ACK = WR_ACK_FIFO_OUT;
assign OVERFLOW = OVERFLOW_FIFO_OUT;
assign PROG_FULL = PROG_FULL_FIFO_OUT;
assign PROG_EMPTY = PROG_EMPTY_FIFO_OUT;
/**************************************************************************
* find_log2
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// if an asynchronous FIFO has been selected, display a message that the FIFO
// will not be cycle-accurate in simulation
initial begin
if (C_IMPLEMENTATION_TYPE == 2) begin
$display("WARNING: Behavioral models for independent clock FIFO configurations do not model synchronization delays. The behavioral models are functionally correct, and will represent the behavior of the configured FIFO. See the FIFO Generator User Guide for more information.");
end else if (C_MEMORY_TYPE == 4) begin
$display("FAILURE : Behavioral models do not support built-in FIFO configurations. Please use post-synthesis or post-implement simulation in Vivado.");
$finish;
end
if (C_WR_PNTR_WIDTH != find_log2(C_WR_DEPTH)) begin
$display("FAILURE : C_WR_PNTR_WIDTH is not log2 of C_WR_DEPTH.");
$finish;
end
if (C_RD_PNTR_WIDTH != find_log2(C_RD_DEPTH)) begin
$display("FAILURE : C_RD_PNTR_WIDTH is not log2 of C_RD_DEPTH.");
$finish;
end
if (C_USE_ECC == 1) begin
if (C_DIN_WIDTH != C_DOUT_WIDTH) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be equal for ECC configuration.");
$finish;
end
if (C_DIN_WIDTH == 1 && C_ERROR_INJECTION_TYPE > 1) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be > 1 for double bit error injection.");
$finish;
end
end
end //initial
/**************************************************************************
* Internal reset logic
**************************************************************************/
assign wr_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? wr_rst_reg : 0;
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? rd_rst_reg : 0;
assign rst_i = C_HAS_RST ? rst_reg : 0;
wire rst_2_sync;
wire rst_2_sync_safety = (C_ENABLE_RST_SYNC == 1) ? rst_delayed : RD_RST;
wire clk_2_sync = (C_COMMON_CLOCK == 1) ? CLK : WR_CLK;
wire clk_2_sync_safety = (C_COMMON_CLOCK == 1) ? CLK : RD_CLK;
localparam RST_SYNC_STAGES = (C_EN_SAFETY_CKT == 0) ? C_SYNCHRONIZER_STAGE :
(C_COMMON_CLOCK == 1) ? 3 : C_SYNCHRONIZER_STAGE+2;
reg [RST_SYNC_STAGES-1:0] wrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] arst_sync_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_wr = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_ext = {RST_SYNC_STAGES{1'b0}};
reg [1:0] wrst_cc = {2{1'b0}};
reg [1:0] rrst_cc = {2{1'b0}};
generate
if (C_EN_SAFETY_CKT == 1 && C_INTERFACE_TYPE == 0) begin : grst_safety_ckt
reg[1:0] rst_d1_safety =1;
reg[1:0] rst_d2_safety =1;
reg[1:0] rst_d3_safety =1;
reg[1:0] rst_d4_safety =1;
reg[1:0] rst_d5_safety =1;
reg[1:0] rst_d6_safety =1;
reg[1:0] rst_d7_safety =1;
always@(posedge rst_2_sync_safety or posedge clk_2_sync_safety) begin : prst
if (rst_2_sync_safety == 1'b1) begin
rst_d1_safety <= 1'b1;
rst_d2_safety <= 1'b1;
rst_d3_safety <= 1'b1;
rst_d4_safety <= 1'b1;
rst_d5_safety <= 1'b1;
rst_d6_safety <= 1'b1;
rst_d7_safety <= 1'b1;
end
else begin
rst_d1_safety <= #`TCQ 1'b0;
rst_d2_safety <= #`TCQ rst_d1_safety;
rst_d3_safety <= #`TCQ rst_d2_safety;
rst_d4_safety <= #`TCQ rst_d3_safety;
rst_d5_safety <= #`TCQ rst_d4_safety;
rst_d6_safety <= #`TCQ rst_d5_safety;
rst_d7_safety <= #`TCQ rst_d6_safety;
end //if
end //prst
always@(posedge rst_d7_safety or posedge WR_EN) begin : assert_safety
if(rst_d7_safety == 1 && WR_EN == 1) begin
$display("WARNING:A write attempt has been made within the 7 clock cycles of reset de-assertion. This can lead to data discrepancy when safety circuit is enabled.");
end //if
end //always
end // grst_safety_ckt
endgenerate
// if (C_EN_SAFET_CKT == 1)
// assertion:the reset shud be atleast 3 cycles wide.
generate
reg safety_ckt_wr_rst_i = 1'b0;
if (C_ENABLE_RST_SYNC == 0) begin : gnrst_sync
always @* begin
wr_rst_reg <= wr_rst_delayed;
rd_rst_reg <= rd_rst_delayed;
rst_reg <= 1'b0;
srst_reg <= 1'b0;
end
assign rst_2_sync = wr_rst_delayed;
assign wr_rst_busy = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
// end : gnrst_sync
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 0) begin : g7s_ic_rst
reg fifo_wrst_done = 1'b0;
reg fifo_rrst_done = 1'b0;
reg sckt_wrst_i = 1'b0;
reg sckt_wrst_i_q = 1'b0;
reg rd_rst_active = 1'b0;
reg rd_rst_middle = 1'b0;
reg sckt_rd_rst_d1 = 1'b0;
reg [1:0] rst_delayed_ic_w = 2'h0;
wire rst_delayed_ic_w_i;
reg [1:0] rst_delayed_ic_r = 2'h0;
wire rst_delayed_ic_r_i;
wire arst_sync_rst;
wire fifo_rst_done;
wire fifo_rst_active;
assign wr_rst_comb = !wr_rst_asreg_d2 && wr_rst_asreg;
assign rd_rst_comb = C_EN_SAFETY_CKT ? (!rd_rst_asreg_d2 && rd_rst_asreg) || rd_rst_active : !rd_rst_asreg_d2 && rd_rst_asreg;
assign rst_2_sync = rst_delayed_ic_w_i;
assign arst_sync_rst = arst_sync_q[RST_SYNC_STAGES-1];
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | fifo_rst_active : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? safety_ckt_rd_rst : 1'b0;
assign fifo_rst_done = fifo_wrst_done & fifo_rrst_done;
assign fifo_rst_active = sckt_wrst_i | wrst_ext[RST_SYNC_STAGES-1] | rrst_wr[RST_SYNC_STAGES-1];
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_w <= 2'b11;
else
rst_delayed_ic_w <= #`TCQ {rst_delayed_ic_w[0],1'b0};
end
assign rst_delayed_ic_w_i = rst_delayed_ic_w[1];
always @(posedge RD_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_r <= 2'b11;
else
rst_delayed_ic_r <= #`TCQ {rst_delayed_ic_r[0],1'b0};
end
assign rst_delayed_ic_r_i = rst_delayed_ic_r[1];
always @(posedge WR_CLK) begin
sckt_wrst_i_q <= #`TCQ sckt_wrst_i;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ sckt_wrst_i | wr_rst_busy | sckt_wr_rst_i_q;
if (arst_sync_rst && ~fifo_rst_active)
sckt_wrst_i <= #`TCQ 1'b1;
else if (sckt_wrst_i && fifo_rst_done)
sckt_wrst_i <= #`TCQ 1'b0;
else
sckt_wrst_i <= #`TCQ sckt_wrst_i;
if (rrst_wr[RST_SYNC_STAGES-2] & ~rrst_wr[RST_SYNC_STAGES-1])
fifo_rrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_rrst_done <= #`TCQ 1'b0;
else
fifo_rrst_done <= #`TCQ fifo_rrst_done;
if (wrst_ext[RST_SYNC_STAGES-2] & ~wrst_ext[RST_SYNC_STAGES-1])
fifo_wrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_wrst_done <= #`TCQ 1'b0;
else
fifo_wrst_done <= #`TCQ fifo_wrst_done;
end
always @(posedge WR_CLK or posedge rst_delayed_ic_w_i) begin
if (rst_delayed_ic_w_i == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],wr_rst_asreg};
wrst_ext <= #`TCQ {wrst_ext[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_wr <= #`TCQ {rrst_wr[RST_SYNC_STAGES-2:0],safety_ckt_rd_rst};
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_ic_w_i};
end
assign wr_rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign wr_rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge WR_CLK or posedge wr_rst_comb) begin
if (wr_rst_comb == 1'b1) begin
wr_rst_reg <= 1'b1;
end else begin
wr_rst_reg <= #`TCQ 1'b0;
end
end
always @(posedge RD_CLK or posedge rst_delayed_ic_r_i) begin
if (rst_delayed_ic_r_i == 1'b1) begin
rd_rst_asreg <= 1'b1;
end else begin
if (rd_rst_asreg_d1 == 1'b1) begin
rd_rst_asreg <= #`TCQ 1'b0;
end else begin
rd_rst_asreg <= #`TCQ rd_rst_asreg;
end
end
end
always @(posedge RD_CLK) begin
rrst_reg <= #`TCQ {rrst_reg[RST_SYNC_STAGES-2:0],rd_rst_asreg};
rrst_q <= #`TCQ {rrst_q[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_cc <= #`TCQ {rrst_cc[0],rd_rst_asreg_d2};
sckt_rd_rst_d1 <= #`TCQ safety_ckt_rd_rst;
if (!rd_rst_middle && rrst_reg[1] && !rrst_reg[2]) begin
rd_rst_active <= #`TCQ 1'b1;
rd_rst_middle <= #`TCQ 1'b1;
end else if (safety_ckt_rd_rst)
rd_rst_active <= #`TCQ 1'b0;
else if (sckt_rd_rst_d1 && !safety_ckt_rd_rst)
rd_rst_middle <= #`TCQ 1'b0;
end
assign rd_rst_asreg_d1 = rrst_reg[RST_SYNC_STAGES-2];
assign rd_rst_asreg_d2 = C_EN_SAFETY_CKT ? rrst_reg[RST_SYNC_STAGES-1] : rrst_reg[1];
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rrst_q[2] : 1'b0;
always @(posedge RD_CLK or posedge rd_rst_comb) begin
if (rd_rst_comb == 1'b1) begin
rd_rst_reg <= 1'b1;
end else begin
rd_rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_ic_rst
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 1) begin : g7s_cc_rst
reg [1:0] rst_delayed_cc = 2'h0;
wire rst_delayed_cc_i;
assign rst_comb = !rst_asreg_d2 && rst_asreg;
assign rst_2_sync = rst_delayed_cc_i;
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | wrst_cc[1] : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? arst_sync_q[1] | arst_sync_q[RST_SYNC_STAGES-1] | wrst_cc[1] : 1'b0;
always @(posedge CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1)
rst_delayed_cc <= 2'b11;
else
rst_delayed_cc <= #`TCQ {rst_delayed_cc,1'b0};
end
assign rst_delayed_cc_i = rst_delayed_cc[1];
always @(posedge CLK or posedge rst_delayed_cc_i) begin
if (rst_delayed_cc_i == 1'b1) begin
rst_asreg <= 1'b1;
end else begin
if (rst_asreg_d1 == 1'b1) begin
rst_asreg <= #`TCQ 1'b0;
end else begin
rst_asreg <= #`TCQ rst_asreg;
end
end
end
always @(posedge CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],rst_asreg};
wrst_cc <= #`TCQ {wrst_cc[0],arst_sync_q[RST_SYNC_STAGES-1]};
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ wrst_cc[1] | wr_rst_busy | sckt_wr_rst_i_q;
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_cc_i};
end
assign rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge CLK or posedge rst_comb) begin
if (rst_comb == 1'b1) begin
rst_reg <= 1'b1;
end else begin
rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_cc_rst
end else if (IS_8SERIES == 1 && C_HAS_SRST == 1 && C_COMMON_CLOCK == 1) begin : g8s_cc_rst
assign wr_rst_busy = (C_MEMORY_TYPE != 4) ? rst_reg : rst_active_i;
assign rd_rst_busy = rst_reg;
assign rst_2_sync = srst_delayed;
always @* rst_full_ff_i <= rst_reg;
always @* rst_full_gen_i <= C_FULL_FLAGS_RST_VAL == 1 ? rst_active_i : 0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
always @(posedge CLK) begin
rst_delayed_d1 <= #`TCQ srst_delayed;
rst_delayed_d2 <= #`TCQ rst_delayed_d1;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
if (rst_reg || rst_delayed_d2) begin
rst_active_i <= #`TCQ 1'b1;
end else begin
rst_active_i <= #`TCQ rst_reg;
end
end
always @(posedge CLK) begin
if (~rst_reg && srst_delayed) begin
rst_reg <= #`TCQ 1'b1;
end else if (rst_reg) begin
rst_reg <= #`TCQ 1'b0;
end else begin
rst_reg <= #`TCQ rst_reg;
end
end
// end : g8s_cc_rst
end else begin
assign wr_rst_busy = 1'b0;
assign rd_rst_busy = 1'b0;
assign safety_ckt_wr_rst = 1'b0;
assign safety_ckt_rd_rst = 1'b0;
end
endgenerate
generate
if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 1) begin : grstd1
// RST_FULL_GEN replaces the reset falling edge detection used to de-assert
// FULL, ALMOST_FULL & PROG_FULL flags if C_FULL_FLAGS_RST_VAL = 1.
// RST_FULL_FF goes to the reset pin of the final flop of FULL, ALMOST_FULL &
// PROG_FULL
reg rst_d1 = 1'b0;
reg rst_d2 = 1'b0;
reg rst_d3 = 1'b0;
reg rst_d4 = 1'b0;
reg rst_d5 = 1'b0;
always @ (posedge rst_2_sync or posedge clk_2_sync) begin
if (rst_2_sync) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
rst_d3 <= 1'b1;
rst_d4 <= 1'b1;
end else begin
if (srst_delayed) begin
rst_d1 <= #`TCQ 1'b1;
rst_d2 <= #`TCQ 1'b1;
rst_d3 <= #`TCQ 1'b1;
rst_d4 <= #`TCQ 1'b1;
end else begin
rst_d1 <= #`TCQ wr_rst_busy;
rst_d2 <= #`TCQ rst_d1;
rst_d3 <= #`TCQ rst_d2 | safety_ckt_wr_rst;
rst_d4 <= #`TCQ rst_d3;
end
end
end
always @* rst_full_ff_i <= (C_HAS_SRST == 0) ? rst_d2 : 1'b0 ;
always @* rst_full_gen_i <= rst_d3;
end else if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 0) begin : gnrst_full
always @* rst_full_ff_i <= (C_COMMON_CLOCK == 0) ? wr_rst_i : rst_i;
end
endgenerate // grstd1
endmodule //fifo_generator_v13_1_3_conv_ver
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0;
else
DOUT <= #`TCQ DIN;
end
endmodule // fifo_generator_v13_1_3_sync_stage
/*******************************************************************************
* Declaration of Independent-Clocks FIFO Module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_as
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input SAFETY_CKT_WR_RST,
input SAFETY_CKT_RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_CLK,
input RD_EN,
input RD_EN_USER,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input USER_EMPTY_FB,
input fab_read_data_valid_i,
input read_data_valid_i,
input ram_valid_i,
output reg ALMOST_EMPTY = 1'b1,
output reg ALMOST_FULL = C_FULL_FLAGS_RST_VAL,
output [C_DOUT_WIDTH-1:0] DOUT,
output reg EMPTY = 1'b1,
output reg EMPTY_FB = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL,
output OVERFLOW,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output UNDERFLOW,
output WR_ACK,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC_1 && SYMMETRIC_PORT && ERR_INJECTION;
// Array that holds the error injection type (single/double bit error) on
// a specific write operation, which is returned on read to corrupt the
// output data.
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
//The amount of data stored in the FIFO at any time is given
// by num_wr_bits (in the WR_CLK domain) and num_rd_bits (in the RD_CLK
// domain.
//num_wr_bits is calculated by considering the total words in the FIFO,
// and the state of the read pointer (which may not have yet crossed clock
// domains.)
//num_rd_bits is calculated by considering the total words in the FIFO,
// and the state of the write pointer (which may not have yet crossed clock
// domains.)
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
wire wr_rst_i = WR_RST;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire rd_rst_i = RD_RST;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
// Delayed ram_rd_en is needed only for STD Embedded register option
generate
if (C_PRELOAD_LATENCY == 2) begin : grd_d
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
end
endgenerate
generate
if (C_PRELOAD_LATENCY == 2 && C_USE_EMBEDDED_REG == 3) begin : grd_d1
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
endgenerate
// Write pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : rdg // Read depth greater than write depth
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1:0] = 0;
end else begin : rdl // Read depth lesser than or equal to write depth
assign adj_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
endgenerate
// Generate Empty and Almost Empty
// ram_rd_en used to determine EMPTY should depend on the EMPTY.
assign ram_rd_en = RD_EN & !EMPTY;
assign empty_int = ((adj_wr_pntr_rd == rd_pntr) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+1'h1))));
assign almost_empty_int = ((adj_wr_pntr_rd == (rd_pntr+1'h1)) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+2'h2))));
// Register Empty and Almost Empty
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin
EMPTY <= 1'b1;
ALMOST_EMPTY <= 1'b1;
rd_data_count_int <= {C_RD_PNTR_WIDTH{1'b0}};
end else begin
rd_data_count_int <= #`TCQ {(adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:0] - rd_pntr[C_RD_PNTR_WIDTH-1:0]), 1'b0};
if (empty_int)
EMPTY <= #`TCQ 1'b1;
else
EMPTY <= #`TCQ 1'b0;
if (!EMPTY) begin
if (almost_empty_int)
ALMOST_EMPTY <= #`TCQ 1'b1;
else
ALMOST_EMPTY <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (SAFETY_CKT_RD_RST && C_EN_SAFETY_CKT)
EMPTY_FB <= #`TCQ 1'b1;
else if (empty_int)
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ 1'b0;
end // rd_rst_i
end // always
// Read pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wdg // Write depth greater than read depth
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1:0] = 0;
end else begin : wdl // Write depth lesser than or equal to read depth
assign adj_rd_pntr_wr = rd_pntr_wr[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end
endgenerate
// Generate FULL and ALMOST_FULL
// ram_wr_en used to determine FULL should depend on the FULL.
assign ram_wr_en = WR_EN & !FULL;
assign full_int = ((adj_rd_pntr_wr == (wr_pntr+1'h1)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+2'h2))));
assign almost_full_int = ((adj_rd_pntr_wr == (wr_pntr+2'h2)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+3'h3))));
// Register FULL and ALMOST_FULL Empty
always @ (posedge WR_CLK or posedge RST_FULL_FF)
begin
if (RST_FULL_FF) begin
FULL <= C_FULL_FLAGS_RST_VAL;
ALMOST_FULL <= C_FULL_FLAGS_RST_VAL;
end else begin
if (full_int) begin
FULL <= #`TCQ 1'b1;
end else begin
FULL <= #`TCQ 1'b0;
end
if (RST_FULL_GEN) begin
ALMOST_FULL <= #`TCQ 1'b0;
end else if (!FULL) begin
if (almost_full_int)
ALMOST_FULL <= #`TCQ 1'b1;
else
ALMOST_FULL <= #`TCQ 1'b0;
end
end // wr_rst_i
end // always
always @ (posedge WR_CLK or posedge wr_rst_i)
begin
if (wr_rst_i) begin
wr_data_count_int <= {C_WR_DATA_COUNT_WIDTH{1'b0}};
end else begin
wr_data_count_int <= #`TCQ {(wr_pntr[C_WR_PNTR_WIDTH-1:0] - adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:0]), 1'b0};
end // wr_rst_i
end // always
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
stage1_valid <= 0;
stage2_valid <= 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//Pointers passed into opposite clock domain
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_EMPTY.
wire [31:0] num_read_words_pe =
num_rd_bits/(C_DOUT_WIDTH/C_DEPTH_RATIO_WR);
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_FULL.
wire [31:0] num_write_words_pf =
num_wr_bits/(C_DIN_WIDTH/C_DEPTH_RATIO_RD);
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/***************************************************************************
* Internal registers and wires
**************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire valid_i;
wire valid_out1;
wire valid_out2;
wire valid_out;
wire underflow_i;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
reg valid_d1 = 0;
reg valid_d2 = 0;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/****************************************************************************
* Function Declarations
***************************************************************************/
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
/***********************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_d2 = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_CLK;
wire RD_EN;
wire RST;
wire WR_CLK;
wire WR_EN;
*/
//***************************************************************************
// Dout may change behavior based on latency
//***************************************************************************
assign ideal_dout_out[C_DOUT_WIDTH-1:0] = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) )?
ideal_dout_d1: ideal_dout;
assign DOUT[C_DOUT_WIDTH-1:0] = ideal_dout_out;
//***************************************************************************
// Assign SBITERR and DBITERR based on latency
//***************************************************************************
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY == 2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) ) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY==2 && (C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
//***************************************************************************
// Safety-ckt logic with embedded reg/fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
// if (C_HAS_VALID == 1) begin
// assign valid_out = valid_d1;
// end
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK)
begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else begin
if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end
end
endgenerate
//***************************************************************************
// Safety-ckt logic with embedded reg + fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK) begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else begin
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end
endgenerate
//***************************************************************************
// Overflow may be active-low
//***************************************************************************
generate
if (C_HAS_OVERFLOW==1) begin : blockOF1
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end
endgenerate
assign PROG_EMPTY = ideal_prog_empty;
assign PROG_FULL = ideal_prog_full;
//***************************************************************************
// Valid may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_VALID==1) begin : blockVL1
assign valid_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out1 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG < 3)?
valid_d1: valid_i;
assign valid_out2 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG == 3)?
valid_d2: valid_i;
assign valid_out = (C_USE_EMBEDDED_REG == 3) ? valid_out2 : valid_out1;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end
endgenerate
//***************************************************************************
// Underflow may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_UNDERFLOW==1) begin : blockUF1
assign underflow_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & EMPTY) : ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end
endgenerate
//***************************************************************************
// Write acknowledge may be active low
//***************************************************************************
generate
if (C_HAS_WR_ACK==1) begin : blockWK1
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : wdc_fwft_ext
reg [C_PNTR_WIDTH-1:0] adjusted_wr_pntr = 0;
reg [C_PNTR_WIDTH-1:0] adjusted_rd_pntr = 0;
wire [C_PNTR_WIDTH-1:0] diff_wr_rd_tmp;
wire [C_PNTR_WIDTH:0] diff_wr_rd;
reg [C_PNTR_WIDTH:0] wr_data_count_i = 0;
always @* begin
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = 0;
adjusted_rd_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
end else if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin
adjusted_rd_pntr = rd_pntr_wr;
adjusted_wr_pntr = 0;
adjusted_wr_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
end else begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = rd_pntr_wr;
end
end // always @*
assign diff_wr_rd_tmp = adjusted_wr_pntr - adjusted_rd_pntr;
assign diff_wr_rd = {1'b0,diff_wr_rd_tmp};
always @ (posedge wr_rst_i or posedge WR_CLK)
begin
if (wr_rst_i)
wr_data_count_i <= 0;
else
wr_data_count_i <= #`TCQ diff_wr_rd + EXTRA_WORDS_DC;
end // always @ (posedge WR_CLK or posedge WR_CLK)
always @* begin
if (C_WR_PNTR_WIDTH >= C_RD_PNTR_WIDTH)
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:0];
else
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end // always @*
end // wdc_fwft_ext
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
reg [C_RD_PNTR_WIDTH:0] rdc_fwft_ext_as = 0;
generate if (C_USE_EMBEDDED_REG < 3) begin: rdc_fwft_ext_both
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= 0;
end else begin
if (!stage2_valid)
rdc_fwft_ext_as <= #`TCQ 0;
else if (!stage1_valid && stage2_valid)
rdc_fwft_ext_as <= #`TCQ 1;
else
rdc_fwft_ext_as <= #`TCQ diff_rd_wr + 2'h2;
end
end // always @ (posedge WR_CLK or posedge WR_CLK)
end // rdc_fwft_ext
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3) begin
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr_1;
// assign diff_rd_wr_1 = diff_rd_wr +2'h2;
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= #`TCQ 0;
end else begin
//if (fab_read_data_valid_i == 1'b0 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b0;
//else if (fab_read_data_valid_i == 1'b1 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b1;
//else
rdc_fwft_ext_as <= diff_rd_wr + 2'h2 ;
end
end
end
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = C_USE_FWFT_DATA_COUNT ?
rdc_fwft_ext_as[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH] :
rd_data_count_int[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = (C_USE_FWFT_DATA_COUNT == 1) ?
wdc_fwft_ext_as[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] :
wr_data_count_int[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate
if (C_HAS_VALID==1) begin : blockVL2
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_d2 <= 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
valid_d2 <= #`TCQ valid_d1;
end
// if (C_USE_EMBEDDED_REG == 3 && (C_EN_SAFETY_CKT == 0 || C_EN_SAFETY_CKT == 1 ) begin
// valid_d2 <= #`TCQ valid_d1;
// end
end
end
endgenerate
//Capture delayed version of dout
/**************************************************************************
*embedded/fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG < 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0)
err_type_d1 <= #`TCQ 0;
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
endgenerate
/**************************************************************************
*embedded + fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG == 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate
if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge WR_CLK) begin
ideal_overflow <= #`TCQ WR_EN & FULL;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge WR_CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (FULL | wr_rst_i);
ideal_overflow <= #`TCQ WR_EN & (FULL );
end
end
endgenerate
generate
if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ EMPTY & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ (EMPTY) & RD_EN;
//ideal_underflow <= #`TCQ (rd_rst_i | EMPTY) & RD_EN;
end
end
endgenerate
/**************************************************************************
* Write/Read Pointer Synchronization
**************************************************************************/
localparam NO_OF_SYNC_STAGE_INC_G2B = C_SYNCHRONIZER_STAGE + 1;
wire [C_WR_PNTR_WIDTH-1:0] wr_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
genvar gss;
generate for (gss = 1; gss <= NO_OF_SYNC_STAGE_INC_G2B; gss = gss + 1) begin : Sync_stage_inst
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_WR_PNTR_WIDTH)
)
rd_stg_inst
(
.RST (rd_rst_i),
.CLK (RD_CLK),
.DIN (wr_pntr_sync_stgs[gss-1]),
.DOUT (wr_pntr_sync_stgs[gss])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_RD_PNTR_WIDTH)
)
wr_stg_inst
(
.RST (wr_rst_i),
.CLK (WR_CLK),
.DIN (rd_pntr_sync_stgs[gss-1]),
.DOUT (rd_pntr_sync_stgs[gss])
);
end endgenerate // Sync_stage_inst
assign wr_pntr_sync_stgs[0] = wr_pntr_rd1;
assign rd_pntr_sync_stgs[0] = rd_pntr_wr1;
always@* begin
wr_pntr_rd <= wr_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
rd_pntr_wr <= rd_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
end
/**************************************************************************
* Write Domain Logic
**************************************************************************/
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_wp
if (wr_rst_i == 1'b1 && C_EN_SAFETY_CKT == 0)
wr_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_WR_RST == 1'b1)
wr_pntr <= #`TCQ 0;
end
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (wr_rst_i == 1'b1) begin
num_wr_bits <= 0;
next_num_wr_bits = 0;
wr_ptr <= C_WR_DEPTH - 1;
rd_ptr_wrclk <= C_RD_DEPTH - 1;
ideal_wr_ack <= 0;
ideal_wr_count <= 0;
tmp_wr_listsize = 0;
rd_ptr_wrclk_next <= 0;
wr_pntr_rd1 <= 0;
end else begin //wr_rst_i==0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
//If this is a write, handle the write by adding the value
// to the linked list, and updating all outputs appropriately
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD
>= C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full, but reporting full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//With DEPTH-1 words in the FIFO, it is almost_full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is completely empty, but it is
// reporting FULL for some reason (like reset)
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <=
C_FIFO_WR_DEPTH-2) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//FIFO is really not close to full, so change flag status.
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end //(tmp_wr_listsize == 0)
end else begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD >=
C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//This write is CAUSING the FIFO to go full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is 2 from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Still 2 from full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is not close to being full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //wr_rst_i==0
end // gen_fifo_w
/***************************************************************************
* Programmable FULL flags
***************************************************************************/
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_assert_val;
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_negate_val;
generate if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin : FWFT
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_DC;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_DC;
end else begin // STD
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL;
end endgenerate
always @(posedge WR_CLK or posedge wr_rst_i) begin
if (wr_rst_i == 1'b1) begin
diff_pntr <= 0;
end else begin
if (ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr + 2'h1);
else if (!ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr);
end
end
always @(posedge WR_CLK or posedge RST_FULL_FF) begin : gen_pf
if (RST_FULL_FF == 1'b1) begin
ideal_prog_full <= C_FULL_FLAGS_RST_VAL;
end else begin
if (RST_FULL_GEN)
ideal_prog_full <= #`TCQ 0;
//Single Programmable Full Constant Threshold
else if (C_PROG_FULL_TYPE == 1) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Constant Thresholds
end else if (C_PROG_FULL_TYPE == 2) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < pf_thr_negate_val)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Single Programmable Full Threshold Input
end else if (C_PROG_FULL_TYPE == 3) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Threshold Inputs
end else if (C_PROG_FULL_TYPE == 4) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH_ASSERT - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < (PROG_FULL_THRESH_NEGATE - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH_ASSERT)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < PROG_FULL_THRESH_NEGATE)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
end // C_PROG_FULL_TYPE
end //wr_rst_i==0
end //
/**************************************************************************
* Read Domain Logic
**************************************************************************/
/*********************************************************
* Programmable EMPTY flags
*********************************************************/
//Determine the Assert and Negate thresholds for Programmable Empty
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_assert_val;
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_negate_val;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_rd = 0;
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_pe
if (rd_rst_i) begin
diff_pntr_rd <= 0;
ideal_prog_empty <= 1'b1;
end else begin
if (ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr) - 1'h1;
else if (!ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr);
else
diff_pntr_rd <= #`TCQ diff_pntr_rd;
if (C_PROG_EMPTY_TYPE == 1) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 2) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 3) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 4) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end //C_PROG_EMPTY_TYPE
end
end // gen_pe
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH - 2'h2 : PROG_EMPTY_THRESH;
end endgenerate // single_pe_thr_input
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_ASSERT - 2'h2 : PROG_EMPTY_THRESH_ASSERT;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_NEGATE - 2'h2 : PROG_EMPTY_THRESH_NEGATE;
end endgenerate // multiple_pe_thr_input
generate if (C_PROG_EMPTY_TYPE < 3) begin : single_multiple_pe_thr_const
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2'h2 : C_PROG_EMPTY_THRESH_ASSERT_VAL;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2'h2 : C_PROG_EMPTY_THRESH_NEGATE_VAL;
end endgenerate // single_multiple_pe_thr_const
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_rp
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
rd_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_RD_RST == 1'b1)
rd_pntr <= #`TCQ 0;
end
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_r_as
/****** Reset fifo (case 1)***************************************/
if (rd_rst_i) begin
num_rd_bits <= 0;
next_num_rd_bits = 0;
rd_ptr <= C_RD_DEPTH -1;
rd_pntr_wr1 <= 0;
wr_ptr_rdclk <= C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_MEMORY_TYPE == 2 && C_USE_DOUT_RST == 1)
ideal_dout <= dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= 1'b0;
ideal_rd_count <= 0;
end else begin //rd_rst_i==0
rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
/*****************************************************************/
// Read Operation - Read Latency 1
/*****************************************************************/
if (C_PRELOAD_LATENCY==1 || C_PRELOAD_LATENCY==2) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
//If the FIFO is one from empty, but it is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is two from empty, and is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH))
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end // else: if(ideal_empty == 1'b1)
else //if (ideal_empty == 1'b0)
begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == C_FIFO_RD_DEPTH)
//If the FIFO is not close to being empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
//If the FIFO is two from empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is one from empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR == 1))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is completely empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end //(RD_EN == 1'b1)
else //if (RD_EN == 1'b0)
begin
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
/*****************************************************************/
// Read Operation - Read Latency 0
/*****************************************************************/
end else if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty, but it is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty, and is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH)) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end else begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to being empty
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH)) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is completely empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end else begin//(RD_EN == 1'b0)
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
end //if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0)
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //rd_rst_i==0
end //always gen_fifo_r_as
endmodule // fifo_generator_v13_1_3_bhv_ver_as
/*******************************************************************************
* Declaration of Low Latency Asynchronous FIFO
******************************************************************************/
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_USE_DOUT_RST = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_FIFO_TYPE = 0
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input [C_DIN_WIDTH-1:0] DIN,
input RD_CLK,
input RD_EN,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
output reg [C_DOUT_WIDTH-1:0] DOUT = 0,
output reg EMPTY = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL
);
//-----------------------------------------------------------------------------
// Low Latency Asynchronous FIFO
//-----------------------------------------------------------------------------
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
integer i;
initial begin
for (i = 0; i < C_WR_DEPTH; i = i + 1)
memory[i] = 0;
end
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_ll_afifo = 0;
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo_q = 0;
reg ll_afifo_full = 1'b0;
reg ll_afifo_empty = 1'b1;
wire write_allow;
wire read_allow;
assign write_allow = WR_EN & ~ll_afifo_full;
assign read_allow = RD_EN & ~ll_afifo_empty;
//-----------------------------------------------------------------------------
// Write Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
wr_pntr_ll_afifo <= 0;
else if (write_allow)
wr_pntr_ll_afifo <= #`TCQ wr_pntr_ll_afifo + 1;
end
//-----------------------------------------------------------------------------
// Read Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
rd_pntr_ll_afifo_q <= 0;
else
rd_pntr_ll_afifo_q <= #`TCQ rd_pntr_ll_afifo;
end
assign rd_pntr_ll_afifo = read_allow ? rd_pntr_ll_afifo_q + 1 : rd_pntr_ll_afifo_q;
//-----------------------------------------------------------------------------
// Fill the Memory
//-----------------------------------------------------------------------------
always @(posedge WR_CLK) begin
if (write_allow)
memory[wr_pntr_ll_afifo] <= #`TCQ DIN;
end
//-----------------------------------------------------------------------------
// Generate DOUT
//-----------------------------------------------------------------------------
always @(posedge RD_CLK) begin
DOUT <= #`TCQ memory[rd_pntr_ll_afifo];
end
//-----------------------------------------------------------------------------
// Generate EMPTY
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
ll_afifo_empty <= 1'b1;
else
ll_afifo_empty <= ((wr_pntr_ll_afifo == rd_pntr_ll_afifo_q) |
(read_allow & (wr_pntr_ll_afifo == (rd_pntr_ll_afifo_q + 2'h1))));
end
//-----------------------------------------------------------------------------
// Generate FULL
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
ll_afifo_full <= 1'b1;
else
ll_afifo_full <= ((rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h1)) |
(write_allow & (rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h2))));
end
always @* begin
FULL <= ll_afifo_full;
EMPTY <= ll_afifo_empty;
end
endmodule // fifo_generator_v13_1_3_beh_ver_ll_afifo
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* Declare user parameters and their defaults
*************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
/**************************************************************************
* Declare Input and Output Ports
*************************************************************************/
(
//Inputs
input SAFETY_CKT_WR_RST,
input CLK,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_EN,
input RD_EN_USER,
input USER_EMPTY_FB,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input SRST,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input WR_RST_BUSY,
input RD_RST_BUSY,
//Outputs
output ALMOST_EMPTY,
output ALMOST_FULL,
output reg [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT = 0,
output [C_DOUT_WIDTH-1:0] DOUT,
output EMPTY,
output reg EMPTY_FB = 1'b1,
output FULL,
output OVERFLOW,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output UNDERFLOW,
output WR_ACK,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
wire [C_RD_PNTR_WIDTH:0] rd_data_count_i_ss;
wire [C_WR_PNTR_WIDTH:0] wr_data_count_i_ss;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
//localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
//localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
localparam C_GRTR_PNTR_WIDTH = (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH ;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
wire [C_WR_PNTR_WIDTH:0] EXTRA_WORDS_PF = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//wire [C_RD_PNTR_WIDTH:0] EXTRA_WORDS_PE = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam EXTRA_WORDS_PF_PARAM = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//localparam EXTRA_WORDS_PE_PARAM = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
//The reset value assignments for FULL, ALMOST_FULL, and PROG_FULL are not
//changed for v3.2(IP2_Im). When the core has Sync Reset, C_HAS_SRST=1 and C_HAS_RST=0.
// Therefore, during SRST, all the FULL flags reset to 0.
localparam C_HAS_FAST_FIFO = 0;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH;
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC && SYMMETRIC_PORT && ERR_INJECTION;
localparam C_DATA_WIDTH = (ENABLE_ERR_INJECTION == 1) ? (C_DIN_WIDTH+2) : C_DIN_WIDTH;
localparam IS_ASYMMETRY = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 0 : 1;
localparam LESSER_WIDTH = (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
localparam [C_RD_PNTR_WIDTH-1 : 0] DIFF_MAX_RD = {C_RD_PNTR_WIDTH{1'b1}};
localparam [C_WR_PNTR_WIDTH-1 : 0] DIFF_MAX_WR = {C_WR_PNTR_WIDTH{1'b1}};
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
/**************************************************************************
* Internal Registers and wires
*************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire underflow_i;
wire valid_i;
wire valid_out;
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_reg = 1'b0;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
wire srst_rrst_busy;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire fwft_enabled;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg full_i = C_FULL_FLAGS_RST_VAL;
reg full_i_temp = 0;
reg empty_i = 1;
reg almost_full_i = 0;
reg almost_empty_i = 1;
reg prog_full_i = 0;
reg prog_empty_i = 1;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] diff_count = 0;
reg write_allow_q = 0;
reg read_allow_q = 0;
reg valid_d1 = 0;
reg valid_both = 0;
reg valid_d2 = 0;
wire rst_i;
wire srst_i;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
/****************************************************************************
* Function Declarations
***************************************************************************/
/****************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***************************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 ) begin
case (def_data[7:0])
8'b00000000 : begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default : begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1) begin
if ((index*4)+j < C_DOUT_WIDTH) begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
//reg valid_d1 = 0;
//user specified value for reseting the size of the fifo
//reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_dout_both = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_both = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_EN;
wire RST;
wire WR_EN;
*/
// Assign ALMOST_EPMTY
generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae
assign ALMOST_EMPTY = almost_empty_i;
end else begin : gnae
assign ALMOST_EMPTY = 0;
end endgenerate // gae
// Assign ALMOST_FULL
generate if (C_HAS_ALMOST_FULL==1) begin : gaf
assign ALMOST_FULL = almost_full_i;
end else begin : gnaf
assign ALMOST_FULL = 0;
end endgenerate // gaf
// Dout may change behavior based on latency
localparam C_FWFT_ENABLED = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign fwft_enabled = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign ideal_dout_out= ((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1))?
ideal_dout_d1: ideal_dout;
assign DOUT = ideal_dout_out;
// Assign SBITERR and DBITERR based on latency
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
assign EMPTY = empty_i;
assign FULL = full_i;
//saftey_ckt with one register
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && (C_USE_EMBEDDED_REG == 1 || C_USE_EMBEDDED_REG == 2 )) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK)
begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK)
begin
if( rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end
else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
valid_d1 <= #`TCQ valid_i;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end //if
endgenerate
//safety ckt with both registers
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK) begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end //if
endgenerate
//Overflow may be active-low
generate if (C_HAS_OVERFLOW==1) begin : gof
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end else begin : gnof
assign OVERFLOW = 0;
end endgenerate // gof
assign PROG_EMPTY = prog_empty_i;
assign PROG_FULL = prog_full_i;
//Valid may change behavior based on latency or active-low
generate if (C_HAS_VALID==1) begin : gvalid
assign valid_i = (C_PRELOAD_LATENCY == 0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out = (C_PRELOAD_LATENCY == 2 && C_MEMORY_TYPE < 2) ?
valid_d1 : valid_i;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end else begin : gnvalid
assign VALID = 0;
end endgenerate // gvalid
//Trim data count differently depending on set widths
generate if (C_HAS_DATA_COUNT == 1) begin : gdc
always @* begin
diff_count <= wr_pntr - rd_pntr;
if (C_DATA_COUNT_WIDTH > C_RD_PNTR_WIDTH) begin
DATA_COUNT[C_RD_PNTR_WIDTH-1:0] <= diff_count;
DATA_COUNT[C_DATA_COUNT_WIDTH-1] <= 1'b0 ;
end else begin
DATA_COUNT <= diff_count[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH];
end
end
// end else begin : gndc
// always @* DATA_COUNT <= 0;
end endgenerate // gdc
//Underflow may change behavior based on latency or active-low
generate if (C_HAS_UNDERFLOW==1) begin : guf
assign underflow_i = ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end else begin : gnuf
assign UNDERFLOW = 0;
end endgenerate // guf
//Write acknowledge may be active low
generate if (C_HAS_WR_ACK==1) begin : gwr_ack
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end else begin : gnwr_ack
assign WR_ACK = 0;
end endgenerate // gwr_ack
/*****************************************************************************
* Internal reset logic
****************************************************************************/
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_WR_RST : C_HAS_SRST ? (SRST | WR_RST_BUSY) : 0;
assign rst_i = C_HAS_RST ? RST : 0;
assign srst_wrst_busy = srst_i;
assign srst_rrst_busy = srst_i;
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG <3)) begin : blockVL20
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG == 3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_both <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
valid_both <= #`TCQ 1'b0;
end else begin
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge CLK or posedge rst_i) begin
if (rst_i) begin
stage1_valid <= #`TCQ 0;
stage2_valid <= #`TCQ 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT ==1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = rd_data_count_i_ss[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = wr_data_count_i_ss[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] ;
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//reg ram_rd_en_d1 = 1'b0;
//Capture delayed version of dout
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG<3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
ram_rd_en_d1 <= #`TCQ 1'b0;
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
end // always
end
endgenerate
//no safety ckt with both registers
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG==3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
fab_rd_en_d1 <= #`TCQ (ram_rd_en_d1);
if (ram_rd_en_d1 ) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end // always
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge CLK) begin
ideal_overflow <= #`TCQ WR_EN & full_i;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (rst_i | full_i);
ideal_overflow <= #`TCQ WR_EN & (WR_RST_BUSY | full_i);
end
end endgenerate // blockOF20
generate if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge CLK) begin
ideal_underflow <= #`TCQ empty_i & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge CLK) begin
//ideal_underflow <= #`TCQ (rst_i | empty_i) & RD_EN;
ideal_underflow <= #`TCQ (RD_RST_BUSY | empty_i) & RD_EN;
end
end endgenerate // blockUF20
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/*************************************************************************
* Write and Read Logic
************************************************************************/
wire write_allow;
wire read_allow;
wire read_allow_dc;
wire write_only;
wire read_only;
//wire write_only_q;
reg write_only_q;
//wire read_only_q;
reg read_only_q;
reg full_reg;
reg rst_full_ff_reg1;
reg rst_full_ff_reg2;
wire ram_full_comb;
wire carry;
assign write_allow = WR_EN & ~full_i;
assign read_allow = RD_EN & ~empty_i;
assign read_allow_dc = RD_EN_USER & ~USER_EMPTY_FB;
//assign write_only = write_allow & ~read_allow;
//assign write_only_q = write_allow_q;
//assign read_only = read_allow & ~write_allow;
//assign read_only_q = read_allow_q ;
wire [C_WR_PNTR_WIDTH-1:0] diff_pntr;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_reg1 = 0;
reg [C_RD_PNTR_WIDTH:0] diff_pntr_pe_asym = 0;
wire [C_RD_PNTR_WIDTH:0] adj_wr_pntr_rd_asym ;
wire [C_RD_PNTR_WIDTH:0] rd_pntr_asym;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_pe_reg2 = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_max;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_max;
assign diff_pntr_pe_max = DIFF_MAX_RD;
assign diff_pntr_max = DIFF_MAX_WR;
generate if (IS_ASYMMETRY == 0) begin : diff_pntr_sym
assign write_only = write_allow & ~read_allow;
assign read_only = read_allow & ~write_allow;
end endgenerate
generate if ( IS_ASYMMETRY == 1 && C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : wr_grt_rd
assign read_only = read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]) & ~write_allow;
assign write_only = write_allow & ~(read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (IS_ASYMMETRY ==1 && C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : rd_grt_wr
assign read_only = read_allow & ~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
assign write_only = write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]) & ~read_allow;
end endgenerate
//-----------------------------------------------------------------------------
// Write and Read pointer generation
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
wr_pntr <= 0;
rd_pntr <= 0;
end else begin
if (srst_i) begin
wr_pntr <= #`TCQ 0;
rd_pntr <= #`TCQ 0;
end else begin
if (write_allow) wr_pntr <= #`TCQ wr_pntr + 1;
if (read_allow) rd_pntr <= #`TCQ rd_pntr + 1;
end
end
end
generate if (C_FIFO_TYPE == 2) begin : gll_dm_dout
always @(posedge CLK) begin
if (write_allow) begin
if (ENABLE_ERR_INJECTION == 1)
memory[wr_pntr] <= #`TCQ {INJECTDBITERR,INJECTSBITERR,DIN};
else
memory[wr_pntr] <= #`TCQ DIN;
end
end
reg [C_DATA_WIDTH-1:0] dout_tmp_q;
reg [C_DATA_WIDTH-1:0] dout_tmp = 0;
reg [C_DATA_WIDTH-1:0] dout_tmp1 = 0;
always @(posedge CLK) begin
dout_tmp_q <= #`TCQ ideal_dout;
end
always @* begin
if (read_allow)
ideal_dout <= memory[rd_pntr];
else
ideal_dout <= dout_tmp_q;
end
end endgenerate // gll_dm_dout
/**************************************************************************
* Write Domain Logic
**************************************************************************/
assign ram_rd_en = RD_EN & !EMPTY;
//reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
generate if (C_FIFO_TYPE != 2) begin : gnll_din
always @(posedge CLK or posedge rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (rst_i == 1'b1) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin //rst_i==0
if (srst_wrst_busy) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin//srst_i=0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end else begin
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
//end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //srst_i==0
end //wr_rst_i==0
end // gen_fifo_w
end endgenerate
generate if (C_FIFO_TYPE < 2 && C_MEMORY_TYPE < 2) begin : gnll_dm_dout
always @(posedge CLK) begin
if (rst_i || srst_rrst_busy) begin
if (C_USE_DOUT_RST == 1) begin
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end
end
end endgenerate
generate if (C_FIFO_TYPE != 2) begin : gnll_dout
always @(posedge CLK or posedge rst_i) begin : gen_fifo_r
/****** Reset fifo (case 1)***************************************/
if (rst_i) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end else begin //rd_rst_i==0
if (srst_rrst_busy) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets synchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end //srst_i
else begin
//rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
if (RD_EN == 1'b1) begin
if (EMPTY == 1'b1) begin
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end
else
begin
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
end
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //s_rst_i==0
end //rd_rst_i==0
end //always
end endgenerate
//-----------------------------------------------------------------------------
// Generate diff_pntr for PROG_FULL generation
// Generate diff_pntr_pe for PROG_EMPTY generation
//-----------------------------------------------------------------------------
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 0) begin : reg_write_allow
always @(posedge CLK ) begin
if (rst_i) begin
write_only_q <= 1'b0;
read_only_q <= 1'b0;
diff_pntr_reg1 <= 0;
diff_pntr_pe_reg1 <= 0;
diff_pntr_reg2 <= 0;
diff_pntr_pe_reg2 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_rrst_busy) begin
read_only_q <= #`TCQ 1'b0;
diff_pntr_pe_reg1 <= #`TCQ 0;
diff_pntr_pe_reg2 <= #`TCQ 0;
end
if (srst_wrst_busy) begin
write_only_q <= #`TCQ 1'b0;
diff_pntr_reg1 <= #`TCQ 0;
diff_pntr_reg2 <= #`TCQ 0;
end
end else begin
write_only_q <= #`TCQ write_only;
read_only_q <= #`TCQ read_only;
diff_pntr_reg2 <= #`TCQ diff_pntr_reg1;
diff_pntr_pe_reg2 <= #`TCQ diff_pntr_pe_reg1;
// Add 1 to the difference pointer value when only write happens.
if (write_only)
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr + 1;
else
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
// Add 1 to the difference pointer value when write or both write & read or no write & read happen.
if (read_only)
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr - 1;
else
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr;
end
end
end
assign diff_pntr_pe = diff_pntr_pe_reg1;
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 1) begin : reg_write_allow_asym
assign adj_wr_pntr_rd_asym[C_RD_PNTR_WIDTH:0] = {adj_wr_pntr_rd,1'b1};
assign rd_pntr_asym[C_RD_PNTR_WIDTH:0] = {~rd_pntr,1'b1};
always @(posedge CLK ) begin
if (rst_i) begin
diff_pntr_pe_asym <= 0;
diff_pntr_reg1 <= 0;
full_reg <= 0;
rst_full_ff_reg1 <= 1;
rst_full_ff_reg2 <= 1;
diff_pntr_pe_reg1 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_wrst_busy)
diff_pntr_reg1 <= #`TCQ 0;
if (srst_rrst_busy)
full_reg <= #`TCQ 0;
rst_full_ff_reg1 <= #`TCQ 1;
rst_full_ff_reg2 <= #`TCQ 1;
diff_pntr_pe_asym <= #`TCQ 0;
diff_pntr_pe_reg1 <= #`TCQ 0;
end else begin
diff_pntr_pe_asym <= #`TCQ adj_wr_pntr_rd_asym + rd_pntr_asym;
full_reg <= #`TCQ full_i;
rst_full_ff_reg1 <= #`TCQ RST_FULL_FF;
rst_full_ff_reg2 <= #`TCQ rst_full_ff_reg1;
if (~full_i) begin
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
end
end
end
end
assign carry = (~(|(diff_pntr_pe_asym [C_RD_PNTR_WIDTH : 1])));
assign diff_pntr_pe = (full_reg && ~rst_full_ff_reg2 && carry ) ? diff_pntr_pe_max : diff_pntr_pe_asym[C_RD_PNTR_WIDTH:1];
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow_asym
//-----------------------------------------------------------------------------
// Generate FULL flag
//-----------------------------------------------------------------------------
wire comp0;
wire comp1;
wire going_full;
wire leaving_full;
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gpad
assign adj_rd_pntr_wr [C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_WR_PNTR_WIDTH <= C_RD_PNTR_WIDTH) begin : gtrim
assign adj_rd_pntr_wr = rd_pntr[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
assign comp1 = (adj_rd_pntr_wr == (wr_pntr + 1'b1));
assign comp0 = (adj_rd_pntr_wr == wr_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gf_wp_eq_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full = (comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gf_asym
assign going_full = (comp1 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_full = (comp0 & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gf_wp_gt_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full =(comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_full_comb = going_full | (~leaving_full & full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
full_i <= #`TCQ ram_full_comb;
end
//-----------------------------------------------------------------------------
// Generate EMPTY flag
//-----------------------------------------------------------------------------
wire ecomp0;
wire ecomp1;
wire going_empty;
wire leaving_empty;
wire ram_empty_comb;
generate if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : pad
assign adj_wr_pntr_rd [C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_RD_PNTR_WIDTH <= C_WR_PNTR_WIDTH) begin : trim
assign adj_wr_pntr_rd = wr_pntr[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
assign ecomp1 = (adj_wr_pntr_rd == (rd_pntr + 1'b1));
assign ecomp0 = (adj_wr_pntr_rd == rd_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : ge_wp_eq_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty = (ecomp0 & write_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : ge_wp_gt_rp
assign going_empty = (ecomp1 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_empty = (ecomp0 & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : ge_wp_lt_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty =(ecomp0 & write_allow);
end endgenerate
assign ram_empty_comb = going_empty | (~leaving_empty & empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
empty_i <= 1'b1;
else if (srst_rrst_busy)
empty_i <= #`TCQ 1'b1;
else
empty_i <= #`TCQ ram_empty_comb;
end
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (srst_rrst_busy || (SAFETY_CKT_WR_RST && C_EN_SAFETY_CKT))
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ ram_empty_comb;
end
end // always
//-----------------------------------------------------------------------------
// Generate Read and write data counts for asymmetic common clock
//-----------------------------------------------------------------------------
reg [C_GRTR_PNTR_WIDTH :0] count_dc = 0;
wire [C_GRTR_PNTR_WIDTH :0] ratio;
wire decr_by_one;
wire incr_by_ratio;
wire incr_by_one;
wire decr_by_ratio;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : rd_depth_gt_wr
assign ratio = C_DEPTH_RATIO_RD;
assign decr_by_one = (IS_FWFT == 1)? read_allow_dc : read_allow;
assign incr_by_ratio = write_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (decr_by_one) begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc - 1;
else
count_dc <= #`TCQ count_dc - 1 + ratio ;
end
else begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc + ratio ;
end
end
end
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc;
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wr_depth_gt_rd
assign ratio = C_DEPTH_RATIO_WR;
assign incr_by_one = write_allow;
assign decr_by_ratio = (IS_FWFT == 1)? read_allow_dc : read_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (incr_by_one) begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc + 1;
else
count_dc <= #`TCQ count_dc + 1 - ratio ;
end
else begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc - ratio ;
end
end
end
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc;
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
//-----------------------------------------------------------------------------
// Generate WR_ACK flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_wr_ack <= 1'b0;
else if (srst_wrst_busy)
ideal_wr_ack <= #`TCQ 1'b0;
else if (WR_EN & ~full_i)
ideal_wr_ack <= #`TCQ 1'b1;
else
ideal_wr_ack <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate VALID flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_valid <= 1'b0;
else if (srst_rrst_busy)
ideal_valid <= #`TCQ 1'b0;
else if (RD_EN & ~empty_i)
ideal_valid <= #`TCQ 1'b1;
else
ideal_valid <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate ALMOST_FULL flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_FULL == 1 || C_PROG_FULL_TYPE > 2 || C_PROG_EMPTY_TYPE > 2) begin : gaf_ss
wire fcomp2;
wire going_afull;
wire leaving_afull;
wire ram_afull_comb;
assign fcomp2 = (adj_rd_pntr_wr == (wr_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gaf_wp_eq_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull = (comp1 & read_allow & ~write_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gaf_asym
assign going_afull = (fcomp2 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_afull = (comp1 & (~write_allow) & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gaf_wp_gt_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull =((comp0 | comp1 | fcomp2) & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_afull_comb = going_afull | (~leaving_afull & almost_full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
almost_full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
almost_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
almost_full_i <= #`TCQ ram_afull_comb;
end
// end endgenerate // gaf_ss
//-----------------------------------------------------------------------------
// Generate ALMOST_EMPTY flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae_ss
wire ecomp2;
wire going_aempty;
wire leaving_aempty;
wire ram_aempty_comb;
assign ecomp2 = (adj_wr_pntr_rd == (rd_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gae_wp_eq_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty = (ecomp1 & write_allow & ~read_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gae_wp_gt_rp
assign going_aempty = (ecomp2 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_aempty = (ecomp1 & ~read_allow & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gae_wp_lt_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty =((ecomp2 | ecomp1 |ecomp0) & write_allow);
end endgenerate
assign ram_aempty_comb = going_aempty | (~leaving_aempty & almost_empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
almost_empty_i <= 1'b1;
else if (srst_rrst_busy)
almost_empty_i <= #`TCQ 1'b1;
else
almost_empty_i <= #`TCQ ram_aempty_comb;
end
// end endgenerate // gae_ss
//-----------------------------------------------------------------------------
// Generate PROG_FULL
//-----------------------------------------------------------------------------
localparam C_PF_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_PF_PARAM : // FWFT
C_PROG_FULL_THRESH_ASSERT_VAL; // STD
localparam C_PF_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_PF_PARAM: // FWFT
C_PROG_FULL_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold constant
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] temp = C_PF_ASSERT_VAL;
generate if (C_PROG_FULL_TYPE == 1) begin : single_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_ASSERT_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr>= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr) < C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b0;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate // single_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_FULL_TYPE == 2) begin : multiple_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_NEGATE_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr >= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < C_PF_NEGATE_VAL)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf3_assert_val = (C_PRELOAD_LATENCY == 0) ?
PROG_FULL_THRESH - EXTRA_WORDS_PF: // FWFT
PROG_FULL_THRESH; // STD
generate if (C_PROG_FULL_TYPE == 3) begin : single_pf_input
always @(posedge CLK or posedge RST_FULL_FF) begin//0
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin //1
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin//2
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin//3
if (diff_pntr > pf3_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == pf3_assert_val) begin//4
if (read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b1;
end else//4
prog_full_i <= #`TCQ 1'b0;
end else//3
prog_full_i <= #`TCQ prog_full_i;
end //2
else begin//5
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin//6
if (diff_pntr >= pf3_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf3_assert_val) begin//7
prog_full_i <= #`TCQ 1'b0;
end//7
end//6
else
prog_full_i <= #`TCQ prog_full_i;
end//5
end//1
end//0
end endgenerate //single_pf_input
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_ASSERT -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_ASSERT; // STD
wire [C_WR_PNTR_WIDTH-1:0] pf_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_NEGATE -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_NEGATE; // STD
generate if (C_PROG_FULL_TYPE == 4) begin : multiple_pf_inputs
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin
if (diff_pntr >= pf_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr == pf_negate_val && read_only_q) ||
diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin
if (diff_pntr >= pf_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_inputs
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY
//-----------------------------------------------------------------------------
localparam C_PE_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_ASSERT_VAL; // STD
localparam C_PE_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold constant
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 1) begin : single_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_ASSERT_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b0;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 2) begin : multiple_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_NEGATE_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_NEGATE_VAL)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate //multiple_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe3_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH -2) : // FWFT
PROG_EMPTY_THRESH; // STD
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_input
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe < pe3_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == pe3_assert_val) begin
if (write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ 1'b1;
end else
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe3_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe3_assert_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_input
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe4_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_ASSERT - 2) : // FWFT
PROG_EMPTY_THRESH_ASSERT; // STD
wire [C_RD_PNTR_WIDTH-1:0] pe4_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_NEGATE - 2) : // FWFT
PROG_EMPTY_THRESH_NEGATE; // STD
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_inputs
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe <= pe4_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (((diff_pntr_pe == pe4_negate_val) && write_only_q) ||
(diff_pntr_pe > pe4_negate_val)) begin
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe4_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe4_negate_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // multiple_pe_inputs
endmodule // fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* First-Word Fall-Through module (preload 0)
**************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USERVALID_LOW = 0,
parameter C_USERUNDERFLOW_LOW = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
(
//Inputs
input SAFETY_CKT_RD_RST,
input RD_CLK,
input RD_RST,
input SRST,
input WR_RST_BUSY,
input RD_RST_BUSY,
input RD_EN,
input FIFOEMPTY,
input [C_DOUT_WIDTH-1:0] FIFODATA,
input FIFOSBITERR,
input FIFODBITERR,
//Outputs
output reg [C_DOUT_WIDTH-1:0] USERDATA,
output USERVALID,
output USERUNDERFLOW,
output USEREMPTY,
output USERALMOSTEMPTY,
output RAMVALID,
output FIFORDEN,
output reg USERSBITERR,
output reg USERDBITERR,
output reg STAGE2_REG_EN,
output fab_read_data_valid_i_o,
output read_data_valid_i_o,
output ram_valid_i_o,
output [1:0] VALID_STAGES
);
//Internal signals
wire preloadstage1;
wire preloadstage2;
reg ram_valid_i;
reg fab_valid;
reg read_data_valid_i;
reg fab_read_data_valid_i;
reg fab_read_data_valid_i_1;
reg ram_valid_i_d;
reg read_data_valid_i_d;
reg fab_read_data_valid_i_d;
wire ram_regout_en;
reg ram_regout_en_d1;
reg ram_regout_en_d2;
wire fab_regout_en;
wire ram_rd_en;
reg empty_i = 1'b1;
reg empty_sckt = 1'b1;
reg sckt_rrst_q = 1'b0;
reg sckt_rrst_done = 1'b0;
reg empty_q = 1'b1;
reg rd_en_q = 1'b0;
reg almost_empty_i = 1'b1;
reg almost_empty_q = 1'b1;
wire rd_rst_i;
wire srst_i;
reg [C_DOUT_WIDTH-1:0] userdata_both;
wire uservalid_both;
wire uservalid_one;
reg user_sbiterr_both = 1'b0;
reg user_dbiterr_both = 1'b0;
assign ram_valid_i_o = ram_valid_i;
assign read_data_valid_i_o = read_data_valid_i;
assign fab_read_data_valid_i_o = fab_read_data_valid_i;
/*************************************************************************
* FUNCTIONS
*************************************************************************/
/*************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
//*************************************************************************
// Set power-on states for regs
//*************************************************************************
initial begin
ram_valid_i = 1'b0;
fab_valid = 1'b0;
read_data_valid_i = 1'b0;
fab_read_data_valid_i = 1'b0;
fab_read_data_valid_i_1 = 1'b0;
USERDATA = hexstr_conv(C_DOUT_RST_VAL);
userdata_both = hexstr_conv(C_DOUT_RST_VAL);
USERSBITERR = 1'b0;
USERDBITERR = 1'b0;
user_sbiterr_both = 1'b0;
user_dbiterr_both = 1'b0;
end //initial
//***************************************************************************
// connect up optional reset
//***************************************************************************
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? RD_RST : 0;
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_RD_RST : C_HAS_SRST ? SRST : 0;
reg sckt_rd_rst_fwft = 1'b0;
reg fwft_rst_done_i = 1'b0;
wire fwft_rst_done;
assign fwft_rst_done = C_EN_SAFETY_CKT ? fwft_rst_done_i : 1'b1;
always @ (posedge RD_CLK) begin
sckt_rd_rst_fwft <= #`TCQ SAFETY_CKT_RD_RST;
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i)
fwft_rst_done_i <= 1'b0;
else if (sckt_rd_rst_fwft & ~SAFETY_CKT_RD_RST)
fwft_rst_done_i <= #`TCQ 1'b1;
end
localparam INVALID = 0;
localparam STAGE1_VALID = 2;
localparam STAGE2_VALID = 1;
localparam BOTH_STAGES_VALID = 3;
reg [1:0] curr_fwft_state = INVALID;
reg [1:0] next_fwft_state = INVALID;
generate if (C_USE_EMBEDDED_REG < 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = preloadstage2;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = (RD_EN & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
reg curr_state = 0;
reg next_state = 0;
reg leaving_empty_fwft = 0;
reg going_empty_fwft = 0;
reg empty_i_q = 0;
reg ram_rd_en_fwft = 0;
generate if (C_FIFO_TYPE == 2) begin : gll_fifo
always @* begin // FSM fo FWFT
case (curr_state)
1'b0: begin
if (~FIFOEMPTY)
next_state <= 1'b1;
else
next_state <= 1'b0;
end
1'b1: begin
if (FIFOEMPTY && RD_EN)
next_state <= 1'b0;
else
next_state <= 1'b1;
end
default: next_state <= 1'b0;
endcase
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_i <= 1'b1;
empty_i_q <= 1'b1;
ram_valid_i <= 1'b0;
end else if (srst_i) begin
empty_i <= #`TCQ 1'b1;
empty_i_q <= #`TCQ 1'b1;
ram_valid_i <= #`TCQ 1'b0;
end else begin
empty_i <= #`TCQ going_empty_fwft | (~leaving_empty_fwft & empty_i);
empty_i_q <= #`TCQ FIFOEMPTY;
ram_valid_i <= #`TCQ next_state;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
curr_state <= 1'b0;
end else if (srst_i) begin
curr_state <= #`TCQ 1'b0;
end else begin
curr_state <= #`TCQ next_state;
end
end //always
wire fe_of_empty;
assign fe_of_empty = empty_i_q & ~FIFOEMPTY;
always @* begin // Finding leaving empty
case (curr_state)
1'b0: leaving_empty_fwft <= fe_of_empty;
1'b1: leaving_empty_fwft <= 1'b1;
default: leaving_empty_fwft <= 1'b0;
endcase
end
always @* begin // Finding going empty
case (curr_state)
1'b1: going_empty_fwft <= FIFOEMPTY & RD_EN;
default: going_empty_fwft <= 1'b0;
endcase
end
always @* begin // Generating FWFT rd_en
case (curr_state)
1'b0: ram_rd_en_fwft <= ~FIFOEMPTY;
1'b1: ram_rd_en_fwft <= ~FIFOEMPTY & RD_EN;
default: ram_rd_en_fwft <= 1'b0;
endcase
end
assign ram_regout_en = ram_rd_en_fwft;
//assign ram_regout_en_d1 = ram_rd_en_fwft;
//assign ram_regout_en_d2 = ram_rd_en_fwft;
assign ram_rd_en = ram_rd_en_fwft;
end endgenerate // gll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false.
// Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2) begin : gnll_fifo_ram_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (ram_rd_en == 1'b1) begin
ram_valid_i <= #`TCQ 1'b1;
end else begin
if (ram_regout_en == 1'b1)
ram_valid_i <= #`TCQ 1'b0;
else
ram_valid_i <= #`TCQ ram_valid_i;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_ram_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ ram_valid_i | (read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG < 3) begin : gnll_fifo_empty
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~ram_valid_i & ~read_data_valid_i) | (~ram_valid_i & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
generate if ( C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((ram_regout_en) | (~FIFOEMPTY & read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ FIFOEMPTY;
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
// BRAM resets synchronously
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG < 3) begin
always @ ( posedge rd_rst_i)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
//safety ckt with one register
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
//@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay
if (rd_rst_i == 1) begin
ram_regout_en_d1 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d1 <= #`TCQ 1'b0;
else
ram_regout_en_d1 <= #`TCQ ram_regout_en;
end
end //always
// assign fab_regout_en = ((ram_regout_en_d1 & ~(ram_regout_en_d2) & empty_i) | (RD_EN & !empty_i));
assign fab_regout_en = ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b0 )? 1'b1: ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1) ? RD_EN : 1'b0;
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay1
if (rd_rst_i == 1) begin
ram_regout_en_d2 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d2 <= #`TCQ 1'b0;
else
ram_regout_en_d2 <= #`TCQ ram_regout_en_d1;
end
end //always
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
always @ (posedge RD_CLK) begin
ram_valid_i_d <= #`TCQ ram_valid_i;
read_data_valid_i_d <= #`TCQ read_data_valid_i;
fab_read_data_valid_i_d <= #`TCQ fab_read_data_valid_i;
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = (ram_valid_i == 1'b1 && (read_data_valid_i == 1'b0 || fab_read_data_valid_i == 1'b0)) ? 1'b1 : (read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1 && ram_valid_i == 1'b1) ? RD_EN : 1'b0;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = ((RD_EN | ~ fab_read_data_valid_i) & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false // Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3) begin : gnll_fifo_fab_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (ram_regout_en == 1'b1) begin
fab_valid <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
fab_valid <= #`TCQ 1'b0;
else
fab_valid <= #`TCQ fab_valid;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_fab_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG == 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else begin
if (ram_regout_en == 1'b1) begin
read_data_valid_i <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ read_data_valid_i;
end
end
end //always
end
endgenerate
//generate if(C_USE_EMBEDDED_REG == 3) begin
// always @ (posedge RD_CLK or posedge rd_rst_i) begin
// if (rd_rst_i)
// read_data_valid_i <= #`TCQ 1'b0;
// else if (srst_i)
// read_data_valid_i <= #`TCQ 1'b0;
//
// if (ram_regout_en == 1'b1) begin
// fab_read_data_valid_i <= #`TCQ 1'b0;
// end else begin
// if (fab_regout_en == 1'b1)
// fab_read_data_valid_i <= #`TCQ 1'b1;
// else
// fab_read_data_valid_i <= #`TCQ fab_read_data_valid_i;
// end
// end //always
//end
//endgenerate
generate if(C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin :fabout_dvalid
if (rd_rst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else
fab_read_data_valid_i <= #`TCQ fab_valid | (fab_read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
always @ (posedge RD_CLK ) begin : proc_del1
begin
fab_read_data_valid_i_1 <= #`TCQ fab_read_data_valid_i;
end
end //always
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3 ) begin : gnll_fifo_empty_both
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~fab_valid & ~fab_read_data_valid_i) | (~fab_valid & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty_both
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
reg FIFOEMPTY_1;
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @(posedge RD_CLK) begin
FIFOEMPTY_1 <= #`TCQ FIFOEMPTY;
end
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((fab_regout_en) | (ram_valid_i & fab_read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ (~ram_valid_i);
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_sckt <= #`TCQ 1'b1;
sckt_rrst_q <= #`TCQ 1'b0;
sckt_rrst_done <= #`TCQ 1'b0;
end else begin
sckt_rrst_q <= #`TCQ SAFETY_CKT_RD_RST;
if (sckt_rrst_q && ~SAFETY_CKT_RD_RST) begin
sckt_rrst_done <= #`TCQ 1'b1;
end else if (sckt_rrst_done) begin
// rising clock edge
empty_sckt <= #`TCQ 1'b0;
end
end
end //always
// assign USEREMPTY = C_EN_SAFETY_CKT ? (sckt_rrst_done ? empty_i : empty_sckt) : empty_i;
assign USEREMPTY = empty_i;
assign USERALMOSTEMPTY = almost_empty_i;
assign FIFORDEN = ram_rd_en;
assign RAMVALID = (C_USE_EMBEDDED_REG == 3)? fab_valid : ram_valid_i;
assign uservalid_both = (C_USERVALID_LOW && C_USE_EMBEDDED_REG == 3) ? ~fab_read_data_valid_i : ((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG == 3) ? fab_read_data_valid_i : 1'b0);
assign uservalid_one = (C_USERVALID_LOW && C_USE_EMBEDDED_REG < 3) ? ~read_data_valid_i :((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG < 3) ? read_data_valid_i : 1'b0);
assign USERVALID = (C_USE_EMBEDDED_REG == 3) ? uservalid_both : uservalid_one;
assign USERUNDERFLOW = C_USERUNDERFLOW_LOW ? ~(empty_q & rd_en_q) : empty_q & rd_en_q;
//no safety ckt with both reg
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin
if (fwft_rst_done) begin
if (ram_regout_en) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end
end //always
end //if
endgenerate
//safety_ckt with both registers
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK) begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end //always
end //if
endgenerate
endmodule //fifo_generator_v13_1_3_bhv_ver_preload0
//-----------------------------------------------------------------------------
//
// Register Slice
// Register one AXI channel on forward and/or reverse signal path
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// reg_slice
//
//--------------------------------------------------------------------------
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
input wire S_VALID,
output wire S_READY,
// Master side
output wire [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA,
output wire M_VALID,
input wire M_READY
);
generate
////////////////////////////////////////////////////////////////////
//
// Both FWD and REV mode
//
////////////////////////////////////////////////////////////////////
if (C_REG_CONFIG == 32'h00000000)
begin
reg [1:0] state;
localparam [1:0]
ZERO = 2'b10,
ONE = 2'b11,
TWO = 2'b01;
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg [C_DATA_WIDTH-1:0] storage_data2 = 0;
reg load_s1;
wire load_s2;
wire load_s1_from_s2;
reg s_ready_i; //local signal of output
wire m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with either slave side data or from storage2
always @(posedge ACLK)
begin
if (load_s1)
if (load_s1_from_s2)
storage_data1 <= storage_data2;
else
storage_data1 <= S_PAYLOAD_DATA;
end
// Load storage2 with slave side data
always @(posedge ACLK)
begin
if (load_s2)
storage_data2 <= S_PAYLOAD_DATA;
end
assign M_PAYLOAD_DATA = storage_data1;
// Always load s2 on a valid transaction even if it's unnecessary
assign load_s2 = S_VALID & s_ready_i;
// Loading s1
always @ *
begin
if ( ((state == ZERO) && (S_VALID == 1)) || // Load when empty on slave transaction
// Load when ONE if we both have read and write at the same time
((state == ONE) && (S_VALID == 1) && (M_READY == 1)) ||
// Load when TWO and we have a transaction on Master side
((state == TWO) && (M_READY == 1)))
load_s1 = 1'b1;
else
load_s1 = 1'b0;
end // always @ *
assign load_s1_from_s2 = (state == TWO);
// State Machine for handling output signals
always @(posedge ACLK) begin
if (ARESET) begin
s_ready_i <= 1'b0;
state <= ZERO;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else begin
case (state)
// No transaction stored locally
ZERO: if (S_VALID) state <= ONE; // Got one so move to ONE
// One transaction stored locally
ONE: begin
if (M_READY & ~S_VALID) state <= ZERO; // Read out one so move to ZERO
if (~M_READY & S_VALID) begin
state <= TWO; // Got another one so move to TWO
s_ready_i <= 1'b0;
end
end
// TWO transaction stored locally
TWO: if (M_READY) begin
state <= ONE; // Read out one so move to ONE
s_ready_i <= 1'b1;
end
endcase // case (state)
end
end // always @ (posedge ACLK)
assign m_valid_i = state[0];
end // if (C_REG_CONFIG == 1)
////////////////////////////////////////////////////////////////////
//
// 1-stage pipeline register with bubble cycle, both FWD and REV pipelining
// Operates same as 1-deep FIFO
//
////////////////////////////////////////////////////////////////////
else if (C_REG_CONFIG == 32'h00000001)
begin
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg s_ready_i; //local signal of output
reg m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with slave side data
always @(posedge ACLK)
begin
if (ARESET) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b0;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else if (m_valid_i & M_READY) begin
s_ready_i <= 1'b1;
m_valid_i <= 1'b0;
end else if (S_VALID & s_ready_i) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b1;
end
if (~m_valid_i) begin
storage_data1 <= S_PAYLOAD_DATA;
end
end
assign M_PAYLOAD_DATA = storage_data1;
end // if (C_REG_CONFIG == 7)
else begin : default_case
// Passthrough
assign M_PAYLOAD_DATA = S_PAYLOAD_DATA;
assign M_VALID = S_VALID;
assign S_READY = M_READY;
end
endgenerate
endmodule // reg_slice
|
/*
*******************************************************************************
*
* FIFO Generator - Verilog Behavioral Model
*
*******************************************************************************
*
* (c) Copyright 1995 - 2009 Xilinx, Inc. All rights reserved.
*
* This file contains confidential and proprietary information
* of Xilinx, Inc. and is protected under U.S. and
* international copyright and other intellectual property
* laws.
*
* DISCLAIMER
* This disclaimer is not a license and does not grant any
* rights to the materials distributed herewith. Except as
* otherwise provided in a valid license issued to you by
* Xilinx, and to the maximum extent permitted by applicable
* law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
* WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
* AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
* BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
* INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
* (2) Xilinx shall not be liable (whether in contract or tort,
* including negligence, or under any other theory of
* liability) for any loss or damage of any kind or nature
* related to, arising under or in connection with these
* materials, including for any direct, or any indirect,
* special, incidental, or consequential loss or damage
* (including loss of data, profits, goodwill, or any type of
* loss or damage suffered as a result of any action brought
* by a third party) even if such damage or loss was
* reasonably foreseeable or Xilinx had been advised of the
* possibility of the same.
*
* CRITICAL APPLICATIONS
* Xilinx products are not designed or intended to be fail-
* safe, or for use in any application requiring fail-safe
* performance, such as life-support or safety devices or
* systems, Class III medical devices, nuclear facilities,
* applications related to the deployment of airbags, or any
* other applications that could lead to death, personal
* injury, or severe property or environmental damage
* (individually and collectively, "Critical
* Applications"). Customer assumes the sole risk and
* liability of any use of Xilinx products in Critical
* Applications, subject only to applicable laws and
* regulations governing limitations on product liability.
*
* THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
* PART OF THIS FILE AT ALL TIMES.
*
*******************************************************************************
*******************************************************************************
*
* Filename: fifo_generator_vlog_beh.v
*
* Author : Xilinx
*
*******************************************************************************
* Structure:
*
* fifo_generator_vlog_beh.v
* |
* +-fifo_generator_v13_1_3_bhv_ver_as
* |
* +-fifo_generator_v13_1_3_bhv_ver_ss
* |
* +-fifo_generator_v13_1_3_bhv_ver_preload0
*
*******************************************************************************
* Description:
*
* The Verilog behavioral model for the FIFO Generator.
*
* The behavioral model has three parts:
* - The behavioral model for independent clocks FIFOs (_as)
* - The behavioral model for common clock FIFOs (_ss)
* - The "preload logic" block which implements First-word Fall-through
*
*******************************************************************************
* Description:
* The verilog behavioral model for the FIFO generator core.
*
*******************************************************************************
*/
`timescale 1ps/1ps
`ifndef TCQ
`define TCQ 100
`endif
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "",
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 1,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "4kx4",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_PIPELINE_REG = 0,
parameter C_POWER_SAVING_MODE = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface, 1: AXI4 Stream, 2: AXI4/AXI3
parameter C_AXI_TYPE = 0, // 1: AXI4, 2: AXI4 Lite, 3: AXI3
parameter C_HAS_AXI_WR_CHANNEL = 0,
parameter C_HAS_AXI_RD_CHANNEL = 0,
parameter C_HAS_SLAVE_CE = 0,
parameter C_HAS_MASTER_CE = 0,
parameter C_ADD_NGC_CONSTRAINT = 0,
parameter C_USE_COMMON_UNDERFLOW = 0,
parameter C_USE_COMMON_OVERFLOW = 0,
parameter C_USE_DEFAULT_SETTINGS = 0,
// AXI Full/Lite
parameter C_AXI_ID_WIDTH = 0,
parameter C_AXI_ADDR_WIDTH = 0,
parameter C_AXI_DATA_WIDTH = 0,
parameter C_AXI_LEN_WIDTH = 8,
parameter C_AXI_LOCK_WIDTH = 2,
parameter C_HAS_AXI_ID = 0,
parameter C_HAS_AXI_AWUSER = 0,
parameter C_HAS_AXI_WUSER = 0,
parameter C_HAS_AXI_BUSER = 0,
parameter C_HAS_AXI_ARUSER = 0,
parameter C_HAS_AXI_RUSER = 0,
parameter C_AXI_ARUSER_WIDTH = 0,
parameter C_AXI_AWUSER_WIDTH = 0,
parameter C_AXI_WUSER_WIDTH = 0,
parameter C_AXI_BUSER_WIDTH = 0,
parameter C_AXI_RUSER_WIDTH = 0,
// AXI Streaming
parameter C_HAS_AXIS_TDATA = 0,
parameter C_HAS_AXIS_TID = 0,
parameter C_HAS_AXIS_TDEST = 0,
parameter C_HAS_AXIS_TUSER = 0,
parameter C_HAS_AXIS_TREADY = 0,
parameter C_HAS_AXIS_TLAST = 0,
parameter C_HAS_AXIS_TSTRB = 0,
parameter C_HAS_AXIS_TKEEP = 0,
parameter C_AXIS_TDATA_WIDTH = 1,
parameter C_AXIS_TID_WIDTH = 1,
parameter C_AXIS_TDEST_WIDTH = 1,
parameter C_AXIS_TUSER_WIDTH = 1,
parameter C_AXIS_TSTRB_WIDTH = 1,
parameter C_AXIS_TKEEP_WIDTH = 1,
// AXI Channel Type
// WACH --> Write Address Channel
// WDCH --> Write Data Channel
// WRCH --> Write Response Channel
// RACH --> Read Address Channel
// RDCH --> Read Data Channel
// AXIS --> AXI Streaming
parameter C_WACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logic
parameter C_WDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_WRCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_AXIS_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
// AXI Implementation Type
// 1 = Common Clock Block RAM FIFO
// 2 = Common Clock Distributed RAM FIFO
// 11 = Independent Clock Block RAM FIFO
// 12 = Independent Clock Distributed RAM FIFO
parameter C_IMPLEMENTATION_TYPE_WACH = 0,
parameter C_IMPLEMENTATION_TYPE_WDCH = 0,
parameter C_IMPLEMENTATION_TYPE_WRCH = 0,
parameter C_IMPLEMENTATION_TYPE_RACH = 0,
parameter C_IMPLEMENTATION_TYPE_RDCH = 0,
parameter C_IMPLEMENTATION_TYPE_AXIS = 0,
// AXI FIFO Type
// 0 = Data FIFO
// 1 = Packet FIFO
// 2 = Low Latency Sync FIFO
// 3 = Low Latency Async FIFO
parameter C_APPLICATION_TYPE_WACH = 0,
parameter C_APPLICATION_TYPE_WDCH = 0,
parameter C_APPLICATION_TYPE_WRCH = 0,
parameter C_APPLICATION_TYPE_RACH = 0,
parameter C_APPLICATION_TYPE_RDCH = 0,
parameter C_APPLICATION_TYPE_AXIS = 0,
// AXI Built-in FIFO Primitive Type
// 512x36, 1kx18, 2kx9, 4kx4, etc
parameter C_PRIM_FIFO_TYPE_WACH = "512x36",
parameter C_PRIM_FIFO_TYPE_WDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_WRCH = "512x36",
parameter C_PRIM_FIFO_TYPE_RACH = "512x36",
parameter C_PRIM_FIFO_TYPE_RDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_AXIS = "512x36",
// Enable ECC
// 0 = ECC disabled
// 1 = ECC enabled
parameter C_USE_ECC_WACH = 0,
parameter C_USE_ECC_WDCH = 0,
parameter C_USE_ECC_WRCH = 0,
parameter C_USE_ECC_RACH = 0,
parameter C_USE_ECC_RDCH = 0,
parameter C_USE_ECC_AXIS = 0,
// ECC Error Injection Type
// 0 = No Error Injection
// 1 = Single Bit Error Injection
// 2 = Double Bit Error Injection
// 3 = Single Bit and Double Bit Error Injection
parameter C_ERROR_INJECTION_TYPE_WACH = 0,
parameter C_ERROR_INJECTION_TYPE_WDCH = 0,
parameter C_ERROR_INJECTION_TYPE_WRCH = 0,
parameter C_ERROR_INJECTION_TYPE_RACH = 0,
parameter C_ERROR_INJECTION_TYPE_RDCH = 0,
parameter C_ERROR_INJECTION_TYPE_AXIS = 0,
// Input Data Width
// Accumulation of all AXI input signal's width
parameter C_DIN_WIDTH_WACH = 1,
parameter C_DIN_WIDTH_WDCH = 1,
parameter C_DIN_WIDTH_WRCH = 1,
parameter C_DIN_WIDTH_RACH = 1,
parameter C_DIN_WIDTH_RDCH = 1,
parameter C_DIN_WIDTH_AXIS = 1,
parameter C_WR_DEPTH_WACH = 16,
parameter C_WR_DEPTH_WDCH = 16,
parameter C_WR_DEPTH_WRCH = 16,
parameter C_WR_DEPTH_RACH = 16,
parameter C_WR_DEPTH_RDCH = 16,
parameter C_WR_DEPTH_AXIS = 16,
parameter C_WR_PNTR_WIDTH_WACH = 4,
parameter C_WR_PNTR_WIDTH_WDCH = 4,
parameter C_WR_PNTR_WIDTH_WRCH = 4,
parameter C_WR_PNTR_WIDTH_RACH = 4,
parameter C_WR_PNTR_WIDTH_RDCH = 4,
parameter C_WR_PNTR_WIDTH_AXIS = 4,
parameter C_HAS_DATA_COUNTS_WACH = 0,
parameter C_HAS_DATA_COUNTS_WDCH = 0,
parameter C_HAS_DATA_COUNTS_WRCH = 0,
parameter C_HAS_DATA_COUNTS_RACH = 0,
parameter C_HAS_DATA_COUNTS_RDCH = 0,
parameter C_HAS_DATA_COUNTS_AXIS = 0,
parameter C_HAS_PROG_FLAGS_WACH = 0,
parameter C_HAS_PROG_FLAGS_WDCH = 0,
parameter C_HAS_PROG_FLAGS_WRCH = 0,
parameter C_HAS_PROG_FLAGS_RACH = 0,
parameter C_HAS_PROG_FLAGS_RDCH = 0,
parameter C_HAS_PROG_FLAGS_AXIS = 0,
parameter C_PROG_FULL_TYPE_WACH = 0,
parameter C_PROG_FULL_TYPE_WDCH = 0,
parameter C_PROG_FULL_TYPE_WRCH = 0,
parameter C_PROG_FULL_TYPE_RACH = 0,
parameter C_PROG_FULL_TYPE_RDCH = 0,
parameter C_PROG_FULL_TYPE_AXIS = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_PROG_EMPTY_TYPE_WACH = 0,
parameter C_PROG_EMPTY_TYPE_WDCH = 0,
parameter C_PROG_EMPTY_TYPE_WRCH = 0,
parameter C_PROG_EMPTY_TYPE_RACH = 0,
parameter C_PROG_EMPTY_TYPE_RDCH = 0,
parameter C_PROG_EMPTY_TYPE_AXIS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_REG_SLICE_MODE_WACH = 0,
parameter C_REG_SLICE_MODE_WDCH = 0,
parameter C_REG_SLICE_MODE_WRCH = 0,
parameter C_REG_SLICE_MODE_RACH = 0,
parameter C_REG_SLICE_MODE_RDCH = 0,
parameter C_REG_SLICE_MODE_AXIS = 0
)
(
//------------------------------------------------------------------------------
// Input and Output Declarations
//------------------------------------------------------------------------------
// Conventional FIFO Interface Signals
input backup,
input backup_marker,
input clk,
input rst,
input srst,
input wr_clk,
input wr_rst,
input rd_clk,
input rd_rst,
input [C_DIN_WIDTH-1:0] din,
input wr_en,
input rd_en,
// Optional inputs
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate,
input int_clk,
input injectdbiterr,
input injectsbiterr,
input sleep,
output [C_DOUT_WIDTH-1:0] dout,
output full,
output almost_full,
output wr_ack,
output overflow,
output empty,
output almost_empty,
output valid,
output underflow,
output [C_DATA_COUNT_WIDTH-1:0] data_count,
output [C_RD_DATA_COUNT_WIDTH-1:0] rd_data_count,
output [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count,
output prog_full,
output prog_empty,
output sbiterr,
output dbiterr,
output wr_rst_busy,
output rd_rst_busy,
// AXI Global Signal
input m_aclk,
input s_aclk,
input s_aresetn,
input s_aclk_en,
input m_aclk_en,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_awlen,
input [3-1:0] s_axi_awsize,
input [2-1:0] s_axi_awburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_awlock,
input [4-1:0] s_axi_awcache,
input [3-1:0] s_axi_awprot,
input [4-1:0] s_axi_awqos,
input [4-1:0] s_axi_awregion,
input [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser,
input s_axi_awvalid,
output s_axi_awready,
input [C_AXI_ID_WIDTH-1:0] s_axi_wid,
input [C_AXI_DATA_WIDTH-1:0] s_axi_wdata,
input [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb,
input s_axi_wlast,
input [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [2-1:0] s_axi_bresp,
output [C_AXI_BUSER_WIDTH-1:0] s_axi_buser,
output s_axi_bvalid,
input s_axi_bready,
// AXI Full/Lite Master Write Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_awlen,
output [3-1:0] m_axi_awsize,
output [2-1:0] m_axi_awburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_awlock,
output [4-1:0] m_axi_awcache,
output [3-1:0] m_axi_awprot,
output [4-1:0] m_axi_awqos,
output [4-1:0] m_axi_awregion,
output [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
output m_axi_awvalid,
input m_axi_awready,
output [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output m_axi_wlast,
output [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
output m_axi_wvalid,
input m_axi_wready,
input [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input [2-1:0] m_axi_bresp,
input [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
input m_axi_bvalid,
output m_axi_bready,
// AXI Full/Lite Slave Read Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_arlen,
input [3-1:0] s_axi_arsize,
input [2-1:0] s_axi_arburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_arlock,
input [4-1:0] s_axi_arcache,
input [3-1:0] s_axi_arprot,
input [4-1:0] s_axi_arqos,
input [4-1:0] s_axi_arregion,
input [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_AXI_DATA_WIDTH-1:0] s_axi_rdata,
output [2-1:0] s_axi_rresp,
output s_axi_rlast,
output [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser,
output s_axi_rvalid,
input s_axi_rready,
// AXI Full/Lite Master Read Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_arlen,
output [3-1:0] m_axi_arsize,
output [2-1:0] m_axi_arburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_arlock,
output [4-1:0] m_axi_arcache,
output [3-1:0] m_axi_arprot,
output [4-1:0] m_axi_arqos,
output [4-1:0] m_axi_arregion,
output [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
output m_axi_arvalid,
input m_axi_arready,
input [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input [2-1:0] m_axi_rresp,
input m_axi_rlast,
input [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
input m_axi_rvalid,
output m_axi_rready,
// AXI Streaming Slave Signals (Write side)
input s_axis_tvalid,
output s_axis_tready,
input [C_AXIS_TDATA_WIDTH-1:0] s_axis_tdata,
input [C_AXIS_TSTRB_WIDTH-1:0] s_axis_tstrb,
input [C_AXIS_TKEEP_WIDTH-1:0] s_axis_tkeep,
input s_axis_tlast,
input [C_AXIS_TID_WIDTH-1:0] s_axis_tid,
input [C_AXIS_TDEST_WIDTH-1:0] s_axis_tdest,
input [C_AXIS_TUSER_WIDTH-1:0] s_axis_tuser,
// AXI Streaming Master Signals (Read side)
output m_axis_tvalid,
input m_axis_tready,
output [C_AXIS_TDATA_WIDTH-1:0] m_axis_tdata,
output [C_AXIS_TSTRB_WIDTH-1:0] m_axis_tstrb,
output [C_AXIS_TKEEP_WIDTH-1:0] m_axis_tkeep,
output m_axis_tlast,
output [C_AXIS_TID_WIDTH-1:0] m_axis_tid,
output [C_AXIS_TDEST_WIDTH-1:0] m_axis_tdest,
output [C_AXIS_TUSER_WIDTH-1:0] m_axis_tuser,
// AXI Full/Lite Write Address Channel signals
input axi_aw_injectsbiterr,
input axi_aw_injectdbiterr,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_wr_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_rd_data_count,
output axi_aw_sbiterr,
output axi_aw_dbiterr,
output axi_aw_overflow,
output axi_aw_underflow,
output axi_aw_prog_full,
output axi_aw_prog_empty,
// AXI Full/Lite Write Data Channel signals
input axi_w_injectsbiterr,
input axi_w_injectdbiterr,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_wr_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_rd_data_count,
output axi_w_sbiterr,
output axi_w_dbiterr,
output axi_w_overflow,
output axi_w_underflow,
output axi_w_prog_full,
output axi_w_prog_empty,
// AXI Full/Lite Write Response Channel signals
input axi_b_injectsbiterr,
input axi_b_injectdbiterr,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_wr_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_rd_data_count,
output axi_b_sbiterr,
output axi_b_dbiterr,
output axi_b_overflow,
output axi_b_underflow,
output axi_b_prog_full,
output axi_b_prog_empty,
// AXI Full/Lite Read Address Channel signals
input axi_ar_injectsbiterr,
input axi_ar_injectdbiterr,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_wr_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_rd_data_count,
output axi_ar_sbiterr,
output axi_ar_dbiterr,
output axi_ar_overflow,
output axi_ar_underflow,
output axi_ar_prog_full,
output axi_ar_prog_empty,
// AXI Full/Lite Read Data Channel Signals
input axi_r_injectsbiterr,
input axi_r_injectdbiterr,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_wr_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_rd_data_count,
output axi_r_sbiterr,
output axi_r_dbiterr,
output axi_r_overflow,
output axi_r_underflow,
output axi_r_prog_full,
output axi_r_prog_empty,
// AXI Streaming FIFO Related Signals
input axis_injectsbiterr,
input axis_injectdbiterr,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_full_thresh,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_wr_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_rd_data_count,
output axis_sbiterr,
output axis_dbiterr,
output axis_overflow,
output axis_underflow,
output axis_prog_full,
output axis_prog_empty
);
wire BACKUP;
wire BACKUP_MARKER;
wire CLK;
wire RST;
wire SRST;
wire WR_CLK;
wire WR_RST;
wire RD_CLK;
wire RD_RST;
wire [C_DIN_WIDTH-1:0] DIN;
wire WR_EN;
wire RD_EN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire INT_CLK;
wire INJECTDBITERR;
wire INJECTSBITERR;
wire SLEEP;
wire [C_DOUT_WIDTH-1:0] DOUT;
wire FULL;
wire ALMOST_FULL;
wire WR_ACK;
wire OVERFLOW;
wire EMPTY;
wire ALMOST_EMPTY;
wire VALID;
wire UNDERFLOW;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT;
wire PROG_FULL;
wire PROG_EMPTY;
wire SBITERR;
wire DBITERR;
wire WR_RST_BUSY;
wire RD_RST_BUSY;
wire M_ACLK;
wire S_ACLK;
wire S_ARESETN;
wire S_ACLK_EN;
wire M_ACLK_EN;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_AWLEN;
wire [3-1:0] S_AXI_AWSIZE;
wire [2-1:0] S_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_AWLOCK;
wire [4-1:0] S_AXI_AWCACHE;
wire [3-1:0] S_AXI_AWPROT;
wire [4-1:0] S_AXI_AWQOS;
wire [4-1:0] S_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER;
wire S_AXI_AWVALID;
wire S_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB;
wire S_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER;
wire S_AXI_WVALID;
wire S_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [2-1:0] S_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER;
wire S_AXI_BVALID;
wire S_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_AWLEN;
wire [3-1:0] M_AXI_AWSIZE;
wire [2-1:0] M_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_AWLOCK;
wire [4-1:0] M_AXI_AWCACHE;
wire [3-1:0] M_AXI_AWPROT;
wire [4-1:0] M_AXI_AWQOS;
wire [4-1:0] M_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER;
wire M_AXI_AWVALID;
wire M_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB;
wire M_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER;
wire M_AXI_WVALID;
wire M_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID;
wire [2-1:0] M_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER;
wire M_AXI_BVALID;
wire M_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_ARLEN;
wire [3-1:0] S_AXI_ARSIZE;
wire [2-1:0] S_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_ARLOCK;
wire [4-1:0] S_AXI_ARCACHE;
wire [3-1:0] S_AXI_ARPROT;
wire [4-1:0] S_AXI_ARQOS;
wire [4-1:0] S_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER;
wire S_AXI_ARVALID;
wire S_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA;
wire [2-1:0] S_AXI_RRESP;
wire S_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER;
wire S_AXI_RVALID;
wire S_AXI_RREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_ARLEN;
wire [3-1:0] M_AXI_ARSIZE;
wire [2-1:0] M_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_ARLOCK;
wire [4-1:0] M_AXI_ARCACHE;
wire [3-1:0] M_AXI_ARPROT;
wire [4-1:0] M_AXI_ARQOS;
wire [4-1:0] M_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER;
wire M_AXI_ARVALID;
wire M_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA;
wire [2-1:0] M_AXI_RRESP;
wire M_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER;
wire M_AXI_RVALID;
wire M_AXI_RREADY;
wire S_AXIS_TVALID;
wire S_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] S_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] S_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] S_AXIS_TKEEP;
wire S_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] S_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] S_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] S_AXIS_TUSER;
wire M_AXIS_TVALID;
wire M_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] M_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] M_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] M_AXIS_TKEEP;
wire M_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] M_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] M_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] M_AXIS_TUSER;
wire AXI_AW_INJECTSBITERR;
wire AXI_AW_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_RD_DATA_COUNT;
wire AXI_AW_SBITERR;
wire AXI_AW_DBITERR;
wire AXI_AW_OVERFLOW;
wire AXI_AW_UNDERFLOW;
wire AXI_AW_PROG_FULL;
wire AXI_AW_PROG_EMPTY;
wire AXI_W_INJECTSBITERR;
wire AXI_W_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_RD_DATA_COUNT;
wire AXI_W_SBITERR;
wire AXI_W_DBITERR;
wire AXI_W_OVERFLOW;
wire AXI_W_UNDERFLOW;
wire AXI_W_PROG_FULL;
wire AXI_W_PROG_EMPTY;
wire AXI_B_INJECTSBITERR;
wire AXI_B_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_RD_DATA_COUNT;
wire AXI_B_SBITERR;
wire AXI_B_DBITERR;
wire AXI_B_OVERFLOW;
wire AXI_B_UNDERFLOW;
wire AXI_B_PROG_FULL;
wire AXI_B_PROG_EMPTY;
wire AXI_AR_INJECTSBITERR;
wire AXI_AR_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_RD_DATA_COUNT;
wire AXI_AR_SBITERR;
wire AXI_AR_DBITERR;
wire AXI_AR_OVERFLOW;
wire AXI_AR_UNDERFLOW;
wire AXI_AR_PROG_FULL;
wire AXI_AR_PROG_EMPTY;
wire AXI_R_INJECTSBITERR;
wire AXI_R_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_RD_DATA_COUNT;
wire AXI_R_SBITERR;
wire AXI_R_DBITERR;
wire AXI_R_OVERFLOW;
wire AXI_R_UNDERFLOW;
wire AXI_R_PROG_FULL;
wire AXI_R_PROG_EMPTY;
wire AXIS_INJECTSBITERR;
wire AXIS_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_RD_DATA_COUNT;
wire AXIS_SBITERR;
wire AXIS_DBITERR;
wire AXIS_OVERFLOW;
wire AXIS_UNDERFLOW;
wire AXIS_PROG_FULL;
wire AXIS_PROG_EMPTY;
wire [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count_in;
wire wr_rst_int;
wire rd_rst_int;
wire wr_rst_busy_o;
wire wr_rst_busy_ntve;
wire wr_rst_busy_axis;
wire wr_rst_busy_wach;
wire wr_rst_busy_wdch;
wire wr_rst_busy_wrch;
wire wr_rst_busy_rach;
wire wr_rst_busy_rdch;
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// Conventional FIFO Interface Signals
assign BACKUP = backup;
assign BACKUP_MARKER = backup_marker;
assign CLK = clk;
assign RST = rst;
assign SRST = srst;
assign WR_CLK = wr_clk;
assign WR_RST = wr_rst;
assign RD_CLK = rd_clk;
assign RD_RST = rd_rst;
assign WR_EN = wr_en;
assign RD_EN = rd_en;
assign INT_CLK = int_clk;
assign INJECTDBITERR = injectdbiterr;
assign INJECTSBITERR = injectsbiterr;
assign SLEEP = sleep;
assign full = FULL;
assign almost_full = ALMOST_FULL;
assign wr_ack = WR_ACK;
assign overflow = OVERFLOW;
assign empty = EMPTY;
assign almost_empty = ALMOST_EMPTY;
assign valid = VALID;
assign underflow = UNDERFLOW;
assign prog_full = PROG_FULL;
assign prog_empty = PROG_EMPTY;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
// assign wr_rst_busy = WR_RST_BUSY | wr_rst_busy_o;
assign wr_rst_busy = wr_rst_busy_o;
assign rd_rst_busy = RD_RST_BUSY;
assign M_ACLK = m_aclk;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_ACLK_EN = s_aclk_en;
assign M_ACLK_EN = m_aclk_en;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign m_axi_awvalid = M_AXI_AWVALID;
assign M_AXI_AWREADY = m_axi_awready;
assign m_axi_wlast = M_AXI_WLAST;
assign m_axi_wvalid = M_AXI_WVALID;
assign M_AXI_WREADY = m_axi_wready;
assign M_AXI_BVALID = m_axi_bvalid;
assign m_axi_bready = M_AXI_BREADY;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign m_axi_arvalid = M_AXI_ARVALID;
assign M_AXI_ARREADY = m_axi_arready;
assign M_AXI_RLAST = m_axi_rlast;
assign M_AXI_RVALID = m_axi_rvalid;
assign m_axi_rready = M_AXI_RREADY;
assign S_AXIS_TVALID = s_axis_tvalid;
assign s_axis_tready = S_AXIS_TREADY;
assign S_AXIS_TLAST = s_axis_tlast;
assign m_axis_tvalid = M_AXIS_TVALID;
assign M_AXIS_TREADY = m_axis_tready;
assign m_axis_tlast = M_AXIS_TLAST;
assign AXI_AW_INJECTSBITERR = axi_aw_injectsbiterr;
assign AXI_AW_INJECTDBITERR = axi_aw_injectdbiterr;
assign axi_aw_sbiterr = AXI_AW_SBITERR;
assign axi_aw_dbiterr = AXI_AW_DBITERR;
assign axi_aw_overflow = AXI_AW_OVERFLOW;
assign axi_aw_underflow = AXI_AW_UNDERFLOW;
assign axi_aw_prog_full = AXI_AW_PROG_FULL;
assign axi_aw_prog_empty = AXI_AW_PROG_EMPTY;
assign AXI_W_INJECTSBITERR = axi_w_injectsbiterr;
assign AXI_W_INJECTDBITERR = axi_w_injectdbiterr;
assign axi_w_sbiterr = AXI_W_SBITERR;
assign axi_w_dbiterr = AXI_W_DBITERR;
assign axi_w_overflow = AXI_W_OVERFLOW;
assign axi_w_underflow = AXI_W_UNDERFLOW;
assign axi_w_prog_full = AXI_W_PROG_FULL;
assign axi_w_prog_empty = AXI_W_PROG_EMPTY;
assign AXI_B_INJECTSBITERR = axi_b_injectsbiterr;
assign AXI_B_INJECTDBITERR = axi_b_injectdbiterr;
assign axi_b_sbiterr = AXI_B_SBITERR;
assign axi_b_dbiterr = AXI_B_DBITERR;
assign axi_b_overflow = AXI_B_OVERFLOW;
assign axi_b_underflow = AXI_B_UNDERFLOW;
assign axi_b_prog_full = AXI_B_PROG_FULL;
assign axi_b_prog_empty = AXI_B_PROG_EMPTY;
assign AXI_AR_INJECTSBITERR = axi_ar_injectsbiterr;
assign AXI_AR_INJECTDBITERR = axi_ar_injectdbiterr;
assign axi_ar_sbiterr = AXI_AR_SBITERR;
assign axi_ar_dbiterr = AXI_AR_DBITERR;
assign axi_ar_overflow = AXI_AR_OVERFLOW;
assign axi_ar_underflow = AXI_AR_UNDERFLOW;
assign axi_ar_prog_full = AXI_AR_PROG_FULL;
assign axi_ar_prog_empty = AXI_AR_PROG_EMPTY;
assign AXI_R_INJECTSBITERR = axi_r_injectsbiterr;
assign AXI_R_INJECTDBITERR = axi_r_injectdbiterr;
assign axi_r_sbiterr = AXI_R_SBITERR;
assign axi_r_dbiterr = AXI_R_DBITERR;
assign axi_r_overflow = AXI_R_OVERFLOW;
assign axi_r_underflow = AXI_R_UNDERFLOW;
assign axi_r_prog_full = AXI_R_PROG_FULL;
assign axi_r_prog_empty = AXI_R_PROG_EMPTY;
assign AXIS_INJECTSBITERR = axis_injectsbiterr;
assign AXIS_INJECTDBITERR = axis_injectdbiterr;
assign axis_sbiterr = AXIS_SBITERR;
assign axis_dbiterr = AXIS_DBITERR;
assign axis_overflow = AXIS_OVERFLOW;
assign axis_underflow = AXIS_UNDERFLOW;
assign axis_prog_full = AXIS_PROG_FULL;
assign axis_prog_empty = AXIS_PROG_EMPTY;
assign DIN = din;
assign PROG_EMPTY_THRESH = prog_empty_thresh;
assign PROG_EMPTY_THRESH_ASSERT = prog_empty_thresh_assert;
assign PROG_EMPTY_THRESH_NEGATE = prog_empty_thresh_negate;
assign PROG_FULL_THRESH = prog_full_thresh;
assign PROG_FULL_THRESH_ASSERT = prog_full_thresh_assert;
assign PROG_FULL_THRESH_NEGATE = prog_full_thresh_negate;
assign dout = DOUT;
assign data_count = DATA_COUNT;
assign rd_data_count = RD_DATA_COUNT;
assign wr_data_count = WR_DATA_COUNT;
assign S_AXI_AWID = s_axi_awid;
assign S_AXI_AWADDR = s_axi_awaddr;
assign S_AXI_AWLEN = s_axi_awlen;
assign S_AXI_AWSIZE = s_axi_awsize;
assign S_AXI_AWBURST = s_axi_awburst;
assign S_AXI_AWLOCK = s_axi_awlock;
assign S_AXI_AWCACHE = s_axi_awcache;
assign S_AXI_AWPROT = s_axi_awprot;
assign S_AXI_AWQOS = s_axi_awqos;
assign S_AXI_AWREGION = s_axi_awregion;
assign S_AXI_AWUSER = s_axi_awuser;
assign S_AXI_WID = s_axi_wid;
assign S_AXI_WDATA = s_axi_wdata;
assign S_AXI_WSTRB = s_axi_wstrb;
assign S_AXI_WUSER = s_axi_wuser;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_buser = S_AXI_BUSER;
assign m_axi_awid = M_AXI_AWID;
assign m_axi_awaddr = M_AXI_AWADDR;
assign m_axi_awlen = M_AXI_AWLEN;
assign m_axi_awsize = M_AXI_AWSIZE;
assign m_axi_awburst = M_AXI_AWBURST;
assign m_axi_awlock = M_AXI_AWLOCK;
assign m_axi_awcache = M_AXI_AWCACHE;
assign m_axi_awprot = M_AXI_AWPROT;
assign m_axi_awqos = M_AXI_AWQOS;
assign m_axi_awregion = M_AXI_AWREGION;
assign m_axi_awuser = M_AXI_AWUSER;
assign m_axi_wid = M_AXI_WID;
assign m_axi_wdata = M_AXI_WDATA;
assign m_axi_wstrb = M_AXI_WSTRB;
assign m_axi_wuser = M_AXI_WUSER;
assign M_AXI_BID = m_axi_bid;
assign M_AXI_BRESP = m_axi_bresp;
assign M_AXI_BUSER = m_axi_buser;
assign S_AXI_ARID = s_axi_arid;
assign S_AXI_ARADDR = s_axi_araddr;
assign S_AXI_ARLEN = s_axi_arlen;
assign S_AXI_ARSIZE = s_axi_arsize;
assign S_AXI_ARBURST = s_axi_arburst;
assign S_AXI_ARLOCK = s_axi_arlock;
assign S_AXI_ARCACHE = s_axi_arcache;
assign S_AXI_ARPROT = s_axi_arprot;
assign S_AXI_ARQOS = s_axi_arqos;
assign S_AXI_ARREGION = s_axi_arregion;
assign S_AXI_ARUSER = s_axi_aruser;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_ruser = S_AXI_RUSER;
assign m_axi_arid = M_AXI_ARID;
assign m_axi_araddr = M_AXI_ARADDR;
assign m_axi_arlen = M_AXI_ARLEN;
assign m_axi_arsize = M_AXI_ARSIZE;
assign m_axi_arburst = M_AXI_ARBURST;
assign m_axi_arlock = M_AXI_ARLOCK;
assign m_axi_arcache = M_AXI_ARCACHE;
assign m_axi_arprot = M_AXI_ARPROT;
assign m_axi_arqos = M_AXI_ARQOS;
assign m_axi_arregion = M_AXI_ARREGION;
assign m_axi_aruser = M_AXI_ARUSER;
assign M_AXI_RID = m_axi_rid;
assign M_AXI_RDATA = m_axi_rdata;
assign M_AXI_RRESP = m_axi_rresp;
assign M_AXI_RUSER = m_axi_ruser;
assign S_AXIS_TDATA = s_axis_tdata;
assign S_AXIS_TSTRB = s_axis_tstrb;
assign S_AXIS_TKEEP = s_axis_tkeep;
assign S_AXIS_TID = s_axis_tid;
assign S_AXIS_TDEST = s_axis_tdest;
assign S_AXIS_TUSER = s_axis_tuser;
assign m_axis_tdata = M_AXIS_TDATA;
assign m_axis_tstrb = M_AXIS_TSTRB;
assign m_axis_tkeep = M_AXIS_TKEEP;
assign m_axis_tid = M_AXIS_TID;
assign m_axis_tdest = M_AXIS_TDEST;
assign m_axis_tuser = M_AXIS_TUSER;
assign AXI_AW_PROG_FULL_THRESH = axi_aw_prog_full_thresh;
assign AXI_AW_PROG_EMPTY_THRESH = axi_aw_prog_empty_thresh;
assign axi_aw_data_count = AXI_AW_DATA_COUNT;
assign axi_aw_wr_data_count = AXI_AW_WR_DATA_COUNT;
assign axi_aw_rd_data_count = AXI_AW_RD_DATA_COUNT;
assign AXI_W_PROG_FULL_THRESH = axi_w_prog_full_thresh;
assign AXI_W_PROG_EMPTY_THRESH = axi_w_prog_empty_thresh;
assign axi_w_data_count = AXI_W_DATA_COUNT;
assign axi_w_wr_data_count = AXI_W_WR_DATA_COUNT;
assign axi_w_rd_data_count = AXI_W_RD_DATA_COUNT;
assign AXI_B_PROG_FULL_THRESH = axi_b_prog_full_thresh;
assign AXI_B_PROG_EMPTY_THRESH = axi_b_prog_empty_thresh;
assign axi_b_data_count = AXI_B_DATA_COUNT;
assign axi_b_wr_data_count = AXI_B_WR_DATA_COUNT;
assign axi_b_rd_data_count = AXI_B_RD_DATA_COUNT;
assign AXI_AR_PROG_FULL_THRESH = axi_ar_prog_full_thresh;
assign AXI_AR_PROG_EMPTY_THRESH = axi_ar_prog_empty_thresh;
assign axi_ar_data_count = AXI_AR_DATA_COUNT;
assign axi_ar_wr_data_count = AXI_AR_WR_DATA_COUNT;
assign axi_ar_rd_data_count = AXI_AR_RD_DATA_COUNT;
assign AXI_R_PROG_FULL_THRESH = axi_r_prog_full_thresh;
assign AXI_R_PROG_EMPTY_THRESH = axi_r_prog_empty_thresh;
assign axi_r_data_count = AXI_R_DATA_COUNT;
assign axi_r_wr_data_count = AXI_R_WR_DATA_COUNT;
assign axi_r_rd_data_count = AXI_R_RD_DATA_COUNT;
assign AXIS_PROG_FULL_THRESH = axis_prog_full_thresh;
assign AXIS_PROG_EMPTY_THRESH = axis_prog_empty_thresh;
assign axis_data_count = AXIS_DATA_COUNT;
assign axis_wr_data_count = AXIS_WR_DATA_COUNT;
assign axis_rd_data_count = AXIS_RD_DATA_COUNT;
generate if (C_INTERFACE_TYPE == 0) begin : conv_fifo
fifo_generator_v13_1_3_CONV_VER
#(
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_USE_DOUT_RST == 1 ? C_DOUT_RST_VAL : 0),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_FAMILY (C_FAMILY),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RD_RST (C_HAS_RD_RST),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_HAS_WR_RST (C_HAS_WR_RST),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_FREQ (C_RD_FREQ),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE)
)
fifo_generator_v13_1_3_conv_dut
(
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.CLK (CLK),
.RST (RST),
.SRST (SRST),
.WR_CLK (WR_CLK),
.WR_RST (WR_RST),
.RD_CLK (RD_CLK),
.RD_RST (RD_RST),
.DIN (DIN),
.WR_EN (WR_EN),
.RD_EN (RD_EN),
.PROG_EMPTY_THRESH (PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT (PROG_EMPTY_THRESH_ASSERT),
.PROG_EMPTY_THRESH_NEGATE (PROG_EMPTY_THRESH_NEGATE),
.PROG_FULL_THRESH (PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT (PROG_FULL_THRESH_ASSERT),
.PROG_FULL_THRESH_NEGATE (PROG_FULL_THRESH_NEGATE),
.INT_CLK (INT_CLK),
.INJECTDBITERR (INJECTDBITERR),
.INJECTSBITERR (INJECTSBITERR),
.DOUT (DOUT),
.FULL (FULL),
.ALMOST_FULL (ALMOST_FULL),
.WR_ACK (WR_ACK),
.OVERFLOW (OVERFLOW),
.EMPTY (EMPTY),
.ALMOST_EMPTY (ALMOST_EMPTY),
.VALID (VALID),
.UNDERFLOW (UNDERFLOW),
.DATA_COUNT (DATA_COUNT),
.RD_DATA_COUNT (RD_DATA_COUNT),
.WR_DATA_COUNT (wr_data_count_in),
.PROG_FULL (PROG_FULL),
.PROG_EMPTY (PROG_EMPTY),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.wr_rst_busy_o (wr_rst_busy_o),
.wr_rst_busy (wr_rst_busy_i),
.rd_rst_busy (rd_rst_busy),
.wr_rst_i_out (wr_rst_int),
.rd_rst_i_out (rd_rst_int)
);
end endgenerate
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_AXI_SIZE_WIDTH = 3;
localparam C_AXI_BURST_WIDTH = 2;
localparam C_AXI_CACHE_WIDTH = 4;
localparam C_AXI_PROT_WIDTH = 3;
localparam C_AXI_QOS_WIDTH = 4;
localparam C_AXI_REGION_WIDTH = 4;
localparam C_AXI_BRESP_WIDTH = 2;
localparam C_AXI_RRESP_WIDTH = 2;
localparam IS_AXI_STREAMING = C_INTERFACE_TYPE == 1 ? 1 : 0;
localparam TDATA_OFFSET = C_HAS_AXIS_TDATA == 1 ? C_DIN_WIDTH_AXIS-C_AXIS_TDATA_WIDTH : C_DIN_WIDTH_AXIS;
localparam TSTRB_OFFSET = C_HAS_AXIS_TSTRB == 1 ? TDATA_OFFSET-C_AXIS_TSTRB_WIDTH : TDATA_OFFSET;
localparam TKEEP_OFFSET = C_HAS_AXIS_TKEEP == 1 ? TSTRB_OFFSET-C_AXIS_TKEEP_WIDTH : TSTRB_OFFSET;
localparam TID_OFFSET = C_HAS_AXIS_TID == 1 ? TKEEP_OFFSET-C_AXIS_TID_WIDTH : TKEEP_OFFSET;
localparam TDEST_OFFSET = C_HAS_AXIS_TDEST == 1 ? TID_OFFSET-C_AXIS_TDEST_WIDTH : TID_OFFSET;
localparam TUSER_OFFSET = C_HAS_AXIS_TUSER == 1 ? TDEST_OFFSET-C_AXIS_TUSER_WIDTH : TDEST_OFFSET;
localparam LOG_DEPTH_AXIS = find_log2(C_WR_DEPTH_AXIS);
localparam LOG_WR_DEPTH = find_log2(C_WR_DEPTH);
function [LOG_DEPTH_AXIS-1:0] bin2gray;
input [LOG_DEPTH_AXIS-1:0] x;
begin
bin2gray = x ^ (x>>1);
end
endfunction
function [LOG_DEPTH_AXIS-1:0] gray2bin;
input [LOG_DEPTH_AXIS-1:0] x;
integer i;
begin
gray2bin[LOG_DEPTH_AXIS-1] = x[LOG_DEPTH_AXIS-1];
for(i=LOG_DEPTH_AXIS-2; i>=0; i=i-1) begin
gray2bin[i] = gray2bin[i+1] ^ x[i];
end
end
endfunction
wire [(LOG_WR_DEPTH)-1 : 0] w_cnt_gc_asreg_last;
wire [LOG_WR_DEPTH-1 : 0] w_q [0:C_SYNCHRONIZER_STAGE] ;
wire [LOG_WR_DEPTH-1 : 0] w_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_rd = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_gc = 0;
reg [LOG_WR_DEPTH-1 : 0] r_cnt = 0;
wire [LOG_WR_DEPTH : 0] adj_w_cnt_rd_pad;
wire [LOG_WR_DEPTH : 0] r_inv_pad;
wire [LOG_WR_DEPTH-1 : 0] d_cnt;
reg [LOG_WR_DEPTH : 0] d_cnt_pad = 0;
reg adj_w_cnt_rd_pad_0 = 0;
reg r_inv_pad_0 = 0;
genvar l;
generate for (l = 1; ((l <= C_SYNCHRONIZER_STAGE) && (C_HAS_DATA_COUNTS_AXIS == 3 && C_INTERFACE_TYPE == 0) ); l = l + 1) begin : g_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_WR_DEPTH)
)
rd_stg_inst
(
.RST (rd_rst_int),
.CLK (RD_CLK),
.DIN (w_q[l-1]),
.DOUT (w_q[l])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS == 3) begin : fifo_ic_adapter
assign wr_eop_ad = WR_EN & !(FULL);
assign rd_eop_ad = RD_EN & !(EMPTY);
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt <= 1'b0;
else if (wr_eop_ad)
w_cnt <= w_cnt + 1;
end
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt_gc <= 1'b0;
else
w_cnt_gc <= bin2gray(w_cnt);
end
assign w_q[0] = w_cnt_gc;
assign w_cnt_gc_asreg_last = w_q[C_SYNCHRONIZER_STAGE];
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
w_cnt_rd <= 1'b0;
else
w_cnt_rd <= gray2bin(w_cnt_gc_asreg_last);
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
r_cnt <= 1'b0;
else if (rd_eop_ad)
r_cnt <= r_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_w_cnt_rd_pad[LOG_WR_DEPTH : 1] = w_cnt_rd;
assign r_inv_pad[LOG_WR_DEPTH : 1] = ~r_cnt;
assign adj_w_cnt_rd_pad[0] = adj_w_cnt_rd_pad_0;
assign r_inv_pad[0] = r_inv_pad_0;
always @ ( rd_eop_ad )
begin
if (!rd_eop_ad) begin
adj_w_cnt_rd_pad_0 <= 1'b1;
r_inv_pad_0 <= 1'b1;
end else begin
adj_w_cnt_rd_pad_0 <= 1'b0;
r_inv_pad_0 <= 1'b0;
end
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
d_cnt_pad <= 1'b0;
else
d_cnt_pad <= adj_w_cnt_rd_pad + r_inv_pad ;
end
assign d_cnt = d_cnt_pad [LOG_WR_DEPTH : 1] ;
assign WR_DATA_COUNT = d_cnt;
end endgenerate // fifo_ic_adapter
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS != 3) begin : fifo_icn_adapter
assign WR_DATA_COUNT = wr_data_count_in;
end endgenerate // fifo_icn_adapter
wire inverted_reset = ~S_ARESETN;
wire axi_rs_rst;
wire [C_DIN_WIDTH_AXIS-1:0] axis_din ;
wire [C_DIN_WIDTH_AXIS-1:0] axis_dout ;
wire axis_full ;
wire axis_almost_full ;
wire axis_empty ;
wire axis_s_axis_tready;
wire axis_m_axis_tvalid;
wire axis_wr_en ;
wire axis_rd_en ;
wire axis_we ;
wire axis_re ;
wire [C_WR_PNTR_WIDTH_AXIS:0] axis_dc;
reg axis_pkt_read = 1'b0;
wire axis_rd_rst;
wire axis_wr_rst;
generate if (C_INTERFACE_TYPE > 0 && (C_AXIS_TYPE == 1 || C_WACH_TYPE == 1 ||
C_WDCH_TYPE == 1 || C_WRCH_TYPE == 1 || C_RACH_TYPE == 1 || C_RDCH_TYPE == 1)) begin : gaxi_rs_rst
reg rst_d1 = 0 ;
reg rst_d2 = 0 ;
reg [3:0] axi_rst = 4'h0 ;
always @ (posedge inverted_reset or posedge S_ACLK) begin
if (inverted_reset) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
axi_rst <= 4'hf;
end else begin
rst_d1 <= #`TCQ 1'b0;
rst_d2 <= #`TCQ rst_d1;
axi_rst <= #`TCQ {axi_rst[2:0],1'b0};
end
end
assign axi_rs_rst = axi_rst[3];//rst_d2;
end endgenerate // gaxi_rs_rst
generate if (IS_AXI_STREAMING == 1 && C_AXIS_TYPE == 0) begin : axi_streaming
// Write protection when almost full or prog_full is high
assign axis_we = (C_PROG_FULL_TYPE_AXIS != 0) ? axis_s_axis_tready & S_AXIS_TVALID :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_s_axis_tready & S_AXIS_TVALID : S_AXIS_TVALID;
// Read protection when almost empty or prog_empty is high
assign axis_re = (C_PROG_EMPTY_TYPE_AXIS != 0) ? axis_m_axis_tvalid & M_AXIS_TREADY :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_m_axis_tvalid & M_AXIS_TREADY : M_AXIS_TREADY;
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? axis_we & S_ACLK_EN : axis_we;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? axis_re & M_ACLK_EN : axis_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_AXIS == 2 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_AXIS == 11 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_AXIS),
.C_WR_DEPTH (C_WR_DEPTH_AXIS),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_DOUT_WIDTH (C_DIN_WIDTH_AXIS),
.C_RD_DEPTH (C_WR_DEPTH_AXIS),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_AXIS),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_AXIS),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_AXIS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS),
.C_USE_ECC (C_USE_ECC_AXIS),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_AXIS),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (C_APPLICATION_TYPE_AXIS == 1 ? 1: 0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_FIFO_TYPE (C_APPLICATION_TYPE_AXIS == 1 ? 0: C_APPLICATION_TYPE_AXIS),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_axis_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (axis_wr_en),
.RD_EN (axis_rd_en),
.PROG_FULL_THRESH (AXIS_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH (AXIS_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.INJECTDBITERR (AXIS_INJECTDBITERR),
.INJECTSBITERR (AXIS_INJECTSBITERR),
.DIN (axis_din),
.DOUT (axis_dout),
.FULL (axis_full),
.EMPTY (axis_empty),
.ALMOST_FULL (axis_almost_full),
.PROG_FULL (AXIS_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXIS_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (AXIS_OVERFLOW),
.VALID (),
.UNDERFLOW (AXIS_UNDERFLOW),
.DATA_COUNT (axis_dc),
.RD_DATA_COUNT (AXIS_RD_DATA_COUNT),
.WR_DATA_COUNT (AXIS_WR_DATA_COUNT),
.SBITERR (AXIS_SBITERR),
.DBITERR (AXIS_DBITERR),
.wr_rst_busy (wr_rst_busy_axis),
.rd_rst_busy (rd_rst_busy_axis),
.wr_rst_i_out (axis_wr_rst),
.rd_rst_i_out (axis_rd_rst),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign axis_s_axis_tready = (IS_8SERIES == 0) ? ~axis_full : (C_IMPLEMENTATION_TYPE_AXIS == 5 || C_IMPLEMENTATION_TYPE_AXIS == 13) ? ~(axis_full | wr_rst_busy_axis) : ~axis_full;
assign axis_m_axis_tvalid = (C_APPLICATION_TYPE_AXIS != 1) ? ~axis_empty : ~axis_empty & axis_pkt_read;
assign S_AXIS_TREADY = axis_s_axis_tready;
assign M_AXIS_TVALID = axis_m_axis_tvalid;
end endgenerate // axi_streaming
wire axis_wr_eop;
reg axis_wr_eop_d1 = 1'b0;
wire axis_rd_eop;
integer axis_pkt_cnt;
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 1) begin : gaxis_pkt_fifo_cc
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (axis_pkt_cnt == 1) && ~axis_wr_eop_d1)
axis_pkt_read <= 1'b0;
else if ((axis_pkt_cnt > 0) || (axis_almost_full && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_wr_eop_d1 <= 1'b0;
else
axis_wr_eop_d1 <= axis_wr_eop;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_cnt <= 0;
else if (axis_wr_eop_d1 && ~axis_rd_eop)
axis_pkt_cnt <= axis_pkt_cnt + 1;
else if (axis_rd_eop && ~axis_wr_eop_d1)
axis_pkt_cnt <= axis_pkt_cnt - 1;
end
end endgenerate // gaxis_pkt_fifo_cc
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_gc = 0;
wire [(LOG_DEPTH_AXIS)-1 : 0] axis_wpkt_cnt_gc_asreg_last;
wire axis_rd_has_rst;
wire [0:C_SYNCHRONIZER_STAGE] axis_af_q ;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q [0:C_SYNCHRONIZER_STAGE] ;
wire [1:C_SYNCHRONIZER_STAGE] axis_af_q_temp = 0;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_rd = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_rpkt_cnt = 0;
wire [LOG_DEPTH_AXIS : 0] adj_axis_wpkt_cnt_rd_pad;
wire [LOG_DEPTH_AXIS : 0] rpkt_inv_pad;
wire [LOG_DEPTH_AXIS-1 : 0] diff_pkt_cnt;
reg [LOG_DEPTH_AXIS : 0] diff_pkt_cnt_pad = 0;
reg adj_axis_wpkt_cnt_rd_pad_0 = 0;
reg rpkt_inv_pad_0 = 0;
wire axis_af_rd ;
generate if (C_HAS_RST == 1) begin : rst_blk_has
assign axis_rd_has_rst = axis_rd_rst;
end endgenerate //rst_blk_has
generate if (C_HAS_RST == 0) begin :rst_blk_no
assign axis_rd_has_rst = 1'b0;
end endgenerate //rst_blk_no
genvar i;
generate for (i = 1; ((i <= C_SYNCHRONIZER_STAGE) && (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) ); i = i + 1) begin : gpkt_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_DEPTH_AXIS)
)
rd_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (wpkt_q[i-1]),
.DOUT (wpkt_q[i])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (1)
)
wr_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (axis_af_q[i-1]),
.DOUT (axis_af_q[i])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) begin : gaxis_pkt_fifo_ic
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (diff_pkt_cnt == 1))
axis_pkt_read <= 1'b0;
else if ((diff_pkt_cnt > 0) || (axis_af_rd && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt <= 1'b0;
else if (axis_wr_eop)
axis_wpkt_cnt <= axis_wpkt_cnt + 1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt_gc <= 1'b0;
else
axis_wpkt_cnt_gc <= bin2gray(axis_wpkt_cnt);
end
assign wpkt_q[0] = axis_wpkt_cnt_gc;
assign axis_wpkt_cnt_gc_asreg_last = wpkt_q[C_SYNCHRONIZER_STAGE];
assign axis_af_q[0] = axis_almost_full;
//assign axis_af_q[1:C_SYNCHRONIZER_STAGE] = axis_af_q_temp[1:C_SYNCHRONIZER_STAGE];
assign axis_af_rd = axis_af_q[C_SYNCHRONIZER_STAGE];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_wpkt_cnt_rd <= 1'b0;
else
axis_wpkt_cnt_rd <= gray2bin(axis_wpkt_cnt_gc_asreg_last);
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_rpkt_cnt <= 1'b0;
else if (axis_rd_eop)
axis_rpkt_cnt <= axis_rpkt_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_axis_wpkt_cnt_rd_pad[LOG_DEPTH_AXIS : 1] = axis_wpkt_cnt_rd;
assign rpkt_inv_pad[LOG_DEPTH_AXIS : 1] = ~axis_rpkt_cnt;
assign adj_axis_wpkt_cnt_rd_pad[0] = adj_axis_wpkt_cnt_rd_pad_0;
assign rpkt_inv_pad[0] = rpkt_inv_pad_0;
always @ ( axis_rd_eop )
begin
if (!axis_rd_eop) begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b1;
rpkt_inv_pad_0 <= 1'b1;
end else begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b0;
rpkt_inv_pad_0 <= 1'b0;
end
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
diff_pkt_cnt_pad <= 1'b0;
else
diff_pkt_cnt_pad <= adj_axis_wpkt_cnt_rd_pad + rpkt_inv_pad ;
end
assign diff_pkt_cnt = diff_pkt_cnt_pad [LOG_DEPTH_AXIS : 1] ;
end endgenerate // gaxis_pkt_fifo_ic
// Generate the accurate data count for axi stream packet fifo configuration
reg [C_WR_PNTR_WIDTH_AXIS:0] axis_dc_pkt_fifo = 0;
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 1 && C_APPLICATION_TYPE_AXIS == 1) begin : gdc_pkt
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_dc_pkt_fifo <= 0;
else if (axis_wr_en && (~axis_rd_en))
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo + 1;
else if (~axis_wr_en && axis_rd_en)
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo - 1;
end
assign AXIS_DATA_COUNT = axis_dc_pkt_fifo;
end endgenerate // gdc_pkt
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 0 && C_APPLICATION_TYPE_AXIS == 1) begin : gndc_pkt
assign AXIS_DATA_COUNT = 0;
end endgenerate // gndc_pkt
generate if (IS_AXI_STREAMING == 1 && C_APPLICATION_TYPE_AXIS != 1) begin : gdc
assign AXIS_DATA_COUNT = axis_dc;
end endgenerate // gdc
// Register Slice for Write Address Channel
generate if (C_AXIS_TYPE == 1) begin : gaxis_reg_slice
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? S_AXIS_TVALID & S_ACLK_EN : S_AXIS_TVALID;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? M_AXIS_TREADY & M_ACLK_EN : M_AXIS_TREADY;
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_AXIS),
.C_REG_CONFIG (C_REG_SLICE_MODE_AXIS)
)
axis_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (axis_din),
.S_VALID (axis_wr_en),
.S_READY (S_AXIS_TREADY),
// Master side
.M_PAYLOAD_DATA (axis_dout),
.M_VALID (M_AXIS_TVALID),
.M_READY (axis_rd_en)
);
end endgenerate // gaxis_reg_slice
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDATA == 1) begin : tdata
assign axis_din[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET] = S_AXIS_TDATA;
assign M_AXIS_TDATA = axis_dout[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TSTRB == 1) begin : tstrb
assign axis_din[TDATA_OFFSET-1:TSTRB_OFFSET] = S_AXIS_TSTRB;
assign M_AXIS_TSTRB = axis_dout[TDATA_OFFSET-1:TSTRB_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TKEEP == 1) begin : tkeep
assign axis_din[TSTRB_OFFSET-1:TKEEP_OFFSET] = S_AXIS_TKEEP;
assign M_AXIS_TKEEP = axis_dout[TSTRB_OFFSET-1:TKEEP_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TID == 1) begin : tid
assign axis_din[TKEEP_OFFSET-1:TID_OFFSET] = S_AXIS_TID;
assign M_AXIS_TID = axis_dout[TKEEP_OFFSET-1:TID_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDEST == 1) begin : tdest
assign axis_din[TID_OFFSET-1:TDEST_OFFSET] = S_AXIS_TDEST;
assign M_AXIS_TDEST = axis_dout[TID_OFFSET-1:TDEST_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TUSER == 1) begin : tuser
assign axis_din[TDEST_OFFSET-1:TUSER_OFFSET] = S_AXIS_TUSER;
assign M_AXIS_TUSER = axis_dout[TDEST_OFFSET-1:TUSER_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TLAST == 1) begin : tlast
assign axis_din[0] = S_AXIS_TLAST;
assign M_AXIS_TLAST = axis_dout[0];
end endgenerate
//###########################################################################
// AXI FULL Write Channel (axi_write_channel)
//###########################################################################
localparam IS_AXI_FULL = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE != 2)) ? 1 : 0;
localparam IS_AXI_LITE = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE == 2)) ? 1 : 0;
localparam IS_AXI_FULL_WACH = ((IS_AXI_FULL == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WDCH = ((IS_AXI_FULL == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WRCH = ((IS_AXI_FULL == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RACH = ((IS_AXI_FULL == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RDCH = ((IS_AXI_FULL == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WACH = ((IS_AXI_LITE == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WDCH = ((IS_AXI_LITE == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WRCH = ((IS_AXI_LITE == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RACH = ((IS_AXI_LITE == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RDCH = ((IS_AXI_LITE == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_WR_ADDR_CH = ((IS_AXI_FULL_WACH == 1) || (IS_AXI_LITE_WACH == 1)) ? 1 : 0;
localparam IS_WR_DATA_CH = ((IS_AXI_FULL_WDCH == 1) || (IS_AXI_LITE_WDCH == 1)) ? 1 : 0;
localparam IS_WR_RESP_CH = ((IS_AXI_FULL_WRCH == 1) || (IS_AXI_LITE_WRCH == 1)) ? 1 : 0;
localparam IS_RD_ADDR_CH = ((IS_AXI_FULL_RACH == 1) || (IS_AXI_LITE_RACH == 1)) ? 1 : 0;
localparam IS_RD_DATA_CH = ((IS_AXI_FULL_RDCH == 1) || (IS_AXI_LITE_RDCH == 1)) ? 1 : 0;
localparam AWID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WACH;
localparam AWADDR_OFFSET = AWID_OFFSET - C_AXI_ADDR_WIDTH;
localparam AWLEN_OFFSET = C_AXI_TYPE != 2 ? AWADDR_OFFSET - C_AXI_LEN_WIDTH : AWADDR_OFFSET;
localparam AWSIZE_OFFSET = C_AXI_TYPE != 2 ? AWLEN_OFFSET - C_AXI_SIZE_WIDTH : AWLEN_OFFSET;
localparam AWBURST_OFFSET = C_AXI_TYPE != 2 ? AWSIZE_OFFSET - C_AXI_BURST_WIDTH : AWSIZE_OFFSET;
localparam AWLOCK_OFFSET = C_AXI_TYPE != 2 ? AWBURST_OFFSET - C_AXI_LOCK_WIDTH : AWBURST_OFFSET;
localparam AWCACHE_OFFSET = C_AXI_TYPE != 2 ? AWLOCK_OFFSET - C_AXI_CACHE_WIDTH : AWLOCK_OFFSET;
localparam AWPROT_OFFSET = AWCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam AWQOS_OFFSET = AWPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam AWREGION_OFFSET = C_AXI_TYPE == 1 ? AWQOS_OFFSET - C_AXI_REGION_WIDTH : AWQOS_OFFSET;
localparam AWUSER_OFFSET = C_HAS_AXI_AWUSER == 1 ? AWREGION_OFFSET-C_AXI_AWUSER_WIDTH : AWREGION_OFFSET;
localparam WID_OFFSET = (C_AXI_TYPE == 3 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WDCH;
localparam WDATA_OFFSET = WID_OFFSET - C_AXI_DATA_WIDTH;
localparam WSTRB_OFFSET = WDATA_OFFSET - C_AXI_DATA_WIDTH/8;
localparam WUSER_OFFSET = C_HAS_AXI_WUSER == 1 ? WSTRB_OFFSET-C_AXI_WUSER_WIDTH : WSTRB_OFFSET;
localparam BID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WRCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WRCH;
localparam BRESP_OFFSET = BID_OFFSET - C_AXI_BRESP_WIDTH;
localparam BUSER_OFFSET = C_HAS_AXI_BUSER == 1 ? BRESP_OFFSET-C_AXI_BUSER_WIDTH : BRESP_OFFSET;
wire [C_DIN_WIDTH_WACH-1:0] wach_din ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout_pkt ;
wire wach_full ;
wire wach_almost_full ;
wire wach_prog_full ;
wire wach_empty ;
wire wach_almost_empty ;
wire wach_prog_empty ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_din ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_dout ;
wire wdch_full ;
wire wdch_almost_full ;
wire wdch_prog_full ;
wire wdch_empty ;
wire wdch_almost_empty ;
wire wdch_prog_empty ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_din ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_dout ;
wire wrch_full ;
wire wrch_almost_full ;
wire wrch_prog_full ;
wire wrch_empty ;
wire wrch_almost_empty ;
wire wrch_prog_empty ;
wire axi_aw_underflow_i;
wire axi_w_underflow_i ;
wire axi_b_underflow_i ;
wire axi_aw_overflow_i ;
wire axi_w_overflow_i ;
wire axi_b_overflow_i ;
wire axi_wr_underflow_i;
wire axi_wr_overflow_i ;
wire wach_s_axi_awready;
wire wach_m_axi_awvalid;
wire wach_wr_en ;
wire wach_rd_en ;
wire wdch_s_axi_wready ;
wire wdch_m_axi_wvalid ;
wire wdch_wr_en ;
wire wdch_rd_en ;
wire wrch_s_axi_bvalid ;
wire wrch_m_axi_bready ;
wire wrch_wr_en ;
wire wrch_rd_en ;
wire txn_count_up ;
wire txn_count_down ;
wire awvalid_en ;
wire awvalid_pkt ;
wire awready_pkt ;
integer wr_pkt_count ;
wire wach_we ;
wire wach_re ;
wire wdch_we ;
wire wdch_re ;
wire wrch_we ;
wire wrch_re ;
generate if (IS_WR_ADDR_CH == 1) begin : axi_write_address_channel
// Write protection when almost full or prog_full is high
assign wach_we = (C_PROG_FULL_TYPE_WACH != 0) ? wach_s_axi_awready & S_AXI_AWVALID : S_AXI_AWVALID;
// Read protection when almost empty or prog_empty is high
assign wach_re = (C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH == 1) ?
wach_m_axi_awvalid & awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY && wach_m_axi_awvalid :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH == 1) ?
awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY : 1'b0;
assign wach_wr_en = (C_HAS_SLAVE_CE == 1) ? wach_we & S_ACLK_EN : wach_we;
assign wach_rd_en = (C_HAS_MASTER_CE == 1) ? wach_re & M_ACLK_EN : wach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WACH == 2 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WACH == 11 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_DEPTH (C_WR_DEPTH_WACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WACH),
.C_RD_DEPTH (C_WR_DEPTH_WACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH),
.C_USE_ECC (C_USE_ECC_WACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_WACH == 1)?0:C_APPLICATION_TYPE_WACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 : 0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wach_wr_en),
.RD_EN (wach_rd_en),
.PROG_FULL_THRESH (AXI_AW_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AW_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.INJECTDBITERR (AXI_AW_INJECTDBITERR),
.INJECTSBITERR (AXI_AW_INJECTSBITERR),
.DIN (wach_din),
.DOUT (wach_dout_pkt),
.FULL (wach_full),
.EMPTY (wach_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_AW_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_AW_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_aw_overflow_i),
.VALID (),
.UNDERFLOW (axi_aw_underflow_i),
.DATA_COUNT (AXI_AW_DATA_COUNT),
.RD_DATA_COUNT (AXI_AW_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AW_WR_DATA_COUNT),
.SBITERR (AXI_AW_SBITERR),
.DBITERR (AXI_AW_DBITERR),
.wr_rst_busy (wr_rst_busy_wach),
.rd_rst_busy (rd_rst_busy_wach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wach_s_axi_awready = (IS_8SERIES == 0) ? ~wach_full : (C_IMPLEMENTATION_TYPE_WACH == 5 || C_IMPLEMENTATION_TYPE_WACH == 13) ? ~(wach_full | wr_rst_busy_wach) : ~wach_full;
assign wach_m_axi_awvalid = ~wach_empty;
assign S_AXI_AWREADY = wach_s_axi_awready;
assign AXI_AW_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_aw_underflow_i : 0;
assign AXI_AW_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_aw_overflow_i : 0;
end endgenerate // axi_write_address_channel
// Register Slice for Write Address Channel
generate if (C_WACH_TYPE == 1) begin : gwach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WACH)
)
wach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wach_din),
.S_VALID (S_AXI_AWVALID),
.S_READY (S_AXI_AWREADY),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
end endgenerate // gwach_reg_slice
generate if (C_APPLICATION_TYPE_WACH == 1 && C_HAS_AXI_WR_CHANNEL == 1) begin : axi_mm_pkt_fifo_wr
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (1)
)
wach_pkt_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (wach_dout_pkt),
.S_VALID (awvalid_pkt),
.S_READY (awready_pkt),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
assign awvalid_pkt = wach_m_axi_awvalid && awvalid_en;
assign txn_count_up = wdch_s_axi_wready && wdch_wr_en && wdch_din[0];
assign txn_count_down = wach_m_axi_awvalid && awready_pkt && awvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset == 1) begin
wr_pkt_count <= 0;
end else begin
if(txn_count_up == 1 && txn_count_down == 0) begin
wr_pkt_count <= wr_pkt_count + 1;
end else if(txn_count_up == 0 && txn_count_down == 1) begin
wr_pkt_count <= wr_pkt_count - 1;
end
end
end //Always end
assign awvalid_en = (wr_pkt_count > 0)?1:0;
end endgenerate
generate if (C_APPLICATION_TYPE_WACH != 1) begin : axi_mm_fifo_wr
assign awvalid_en = 1;
assign wach_dout = wach_dout_pkt;
assign M_AXI_AWVALID = wach_m_axi_awvalid;
end
endgenerate
generate if (IS_WR_DATA_CH == 1) begin : axi_write_data_channel
// Write protection when almost full or prog_full is high
assign wdch_we = (C_PROG_FULL_TYPE_WDCH != 0) ? wdch_s_axi_wready & S_AXI_WVALID : S_AXI_WVALID;
// Read protection when almost empty or prog_empty is high
assign wdch_re = (C_PROG_EMPTY_TYPE_WDCH != 0) ? wdch_m_axi_wvalid & M_AXI_WREADY : M_AXI_WREADY;
assign wdch_wr_en = (C_HAS_SLAVE_CE == 1) ? wdch_we & S_ACLK_EN : wdch_we;
assign wdch_rd_en = (C_HAS_MASTER_CE == 1) ? wdch_re & M_ACLK_EN : wdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WDCH == 2 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WDCH == 11 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WDCH),
.C_WR_DEPTH (C_WR_DEPTH_WDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WDCH),
.C_RD_DEPTH (C_WR_DEPTH_WDCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH),
.C_USE_ECC (C_USE_ECC_WDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wdch_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wdch_wr_en),
.RD_EN (wdch_rd_en),
.PROG_FULL_THRESH (AXI_W_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_W_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.INJECTDBITERR (AXI_W_INJECTDBITERR),
.INJECTSBITERR (AXI_W_INJECTSBITERR),
.DIN (wdch_din),
.DOUT (wdch_dout),
.FULL (wdch_full),
.EMPTY (wdch_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_W_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_W_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_w_overflow_i),
.VALID (),
.UNDERFLOW (axi_w_underflow_i),
.DATA_COUNT (AXI_W_DATA_COUNT),
.RD_DATA_COUNT (AXI_W_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_W_WR_DATA_COUNT),
.SBITERR (AXI_W_SBITERR),
.DBITERR (AXI_W_DBITERR),
.wr_rst_busy (wr_rst_busy_wdch),
.rd_rst_busy (rd_rst_busy_wdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wdch_s_axi_wready = (IS_8SERIES == 0) ? ~wdch_full : (C_IMPLEMENTATION_TYPE_WDCH == 5 || C_IMPLEMENTATION_TYPE_WDCH == 13) ? ~(wdch_full | wr_rst_busy_wdch) : ~wdch_full;
assign wdch_m_axi_wvalid = ~wdch_empty;
assign S_AXI_WREADY = wdch_s_axi_wready;
assign M_AXI_WVALID = wdch_m_axi_wvalid;
assign AXI_W_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_w_underflow_i : 0;
assign AXI_W_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_w_overflow_i : 0;
end endgenerate // axi_write_data_channel
// Register Slice for Write Data Channel
generate if (C_WDCH_TYPE == 1) begin : gwdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WDCH)
)
wdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wdch_din),
.S_VALID (S_AXI_WVALID),
.S_READY (S_AXI_WREADY),
// Master side
.M_PAYLOAD_DATA (wdch_dout),
.M_VALID (M_AXI_WVALID),
.M_READY (M_AXI_WREADY)
);
end endgenerate // gwdch_reg_slice
generate if (IS_WR_RESP_CH == 1) begin : axi_write_resp_channel
// Write protection when almost full or prog_full is high
assign wrch_we = (C_PROG_FULL_TYPE_WRCH != 0) ? wrch_m_axi_bready & M_AXI_BVALID : M_AXI_BVALID;
// Read protection when almost empty or prog_empty is high
assign wrch_re = (C_PROG_EMPTY_TYPE_WRCH != 0) ? wrch_s_axi_bvalid & S_AXI_BREADY : S_AXI_BREADY;
assign wrch_wr_en = (C_HAS_MASTER_CE == 1) ? wrch_we & M_ACLK_EN : wrch_we;
assign wrch_rd_en = (C_HAS_SLAVE_CE == 1) ? wrch_re & S_ACLK_EN : wrch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WRCH == 2 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WRCH == 11 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WRCH),
.C_WR_DEPTH (C_WR_DEPTH_WRCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WRCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_DEPTH (C_WR_DEPTH_WRCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WRCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WRCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WRCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH),
.C_USE_ECC (C_USE_ECC_WRCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WRCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WRCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wrch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wrch_wr_en),
.RD_EN (wrch_rd_en),
.PROG_FULL_THRESH (AXI_B_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_B_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.INJECTDBITERR (AXI_B_INJECTDBITERR),
.INJECTSBITERR (AXI_B_INJECTSBITERR),
.DIN (wrch_din),
.DOUT (wrch_dout),
.FULL (wrch_full),
.EMPTY (wrch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_B_PROG_FULL),
.PROG_EMPTY (AXI_B_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_b_overflow_i),
.VALID (),
.UNDERFLOW (axi_b_underflow_i),
.DATA_COUNT (AXI_B_DATA_COUNT),
.RD_DATA_COUNT (AXI_B_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_B_WR_DATA_COUNT),
.SBITERR (AXI_B_SBITERR),
.DBITERR (AXI_B_DBITERR),
.wr_rst_busy (wr_rst_busy_wrch),
.rd_rst_busy (rd_rst_busy_wrch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wrch_s_axi_bvalid = ~wrch_empty;
assign wrch_m_axi_bready = (IS_8SERIES == 0) ? ~wrch_full : (C_IMPLEMENTATION_TYPE_WRCH == 5 || C_IMPLEMENTATION_TYPE_WRCH == 13) ? ~(wrch_full | wr_rst_busy_wrch) : ~wrch_full;
assign S_AXI_BVALID = wrch_s_axi_bvalid;
assign M_AXI_BREADY = wrch_m_axi_bready;
assign AXI_B_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_b_underflow_i : 0;
assign AXI_B_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_b_overflow_i : 0;
end endgenerate // axi_write_resp_channel
// Register Slice for Write Response Channel
generate if (C_WRCH_TYPE == 1) begin : gwrch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WRCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WRCH)
)
wrch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wrch_din),
.S_VALID (M_AXI_BVALID),
.S_READY (M_AXI_BREADY),
// Master side
.M_PAYLOAD_DATA (wrch_dout),
.M_VALID (S_AXI_BVALID),
.M_READY (S_AXI_BREADY)
);
end endgenerate // gwrch_reg_slice
assign axi_wr_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_aw_underflow_i || axi_w_underflow_i || axi_b_underflow_i) : 0;
assign axi_wr_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_aw_overflow_i || axi_w_overflow_i || axi_b_overflow_i) : 0;
generate if (IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output
assign M_AXI_AWADDR = wach_dout[AWID_OFFSET-1:AWADDR_OFFSET];
assign M_AXI_AWLEN = wach_dout[AWADDR_OFFSET-1:AWLEN_OFFSET];
assign M_AXI_AWSIZE = wach_dout[AWLEN_OFFSET-1:AWSIZE_OFFSET];
assign M_AXI_AWBURST = wach_dout[AWSIZE_OFFSET-1:AWBURST_OFFSET];
assign M_AXI_AWLOCK = wach_dout[AWBURST_OFFSET-1:AWLOCK_OFFSET];
assign M_AXI_AWCACHE = wach_dout[AWLOCK_OFFSET-1:AWCACHE_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWCACHE_OFFSET-1:AWPROT_OFFSET];
assign M_AXI_AWQOS = wach_dout[AWPROT_OFFSET-1:AWQOS_OFFSET];
assign wach_din[AWID_OFFSET-1:AWADDR_OFFSET] = S_AXI_AWADDR;
assign wach_din[AWADDR_OFFSET-1:AWLEN_OFFSET] = S_AXI_AWLEN;
assign wach_din[AWLEN_OFFSET-1:AWSIZE_OFFSET] = S_AXI_AWSIZE;
assign wach_din[AWSIZE_OFFSET-1:AWBURST_OFFSET] = S_AXI_AWBURST;
assign wach_din[AWBURST_OFFSET-1:AWLOCK_OFFSET] = S_AXI_AWLOCK;
assign wach_din[AWLOCK_OFFSET-1:AWCACHE_OFFSET] = S_AXI_AWCACHE;
assign wach_din[AWCACHE_OFFSET-1:AWPROT_OFFSET] = S_AXI_AWPROT;
assign wach_din[AWPROT_OFFSET-1:AWQOS_OFFSET] = S_AXI_AWQOS;
end endgenerate // axi_wach_output
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_awregion
assign M_AXI_AWREGION = wach_dout[AWQOS_OFFSET-1:AWREGION_OFFSET];
end endgenerate // axi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_awregion
assign M_AXI_AWREGION = 0;
end endgenerate // naxi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : axi_awuser
assign M_AXI_AWUSER = wach_dout[AWREGION_OFFSET-1:AWUSER_OFFSET];
end endgenerate // axi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 0) begin : naxi_awuser
assign M_AXI_AWUSER = 0;
end endgenerate // naxi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_awid
assign M_AXI_AWID = wach_dout[C_DIN_WIDTH_WACH-1:AWID_OFFSET];
end endgenerate //axi_awid
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_awid
assign M_AXI_AWID = 0;
end endgenerate //naxi_awid
generate if (IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output
assign M_AXI_WDATA = wdch_dout[WID_OFFSET-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
assign M_AXI_WLAST = wdch_dout[0];
assign wdch_din[WID_OFFSET-1:WDATA_OFFSET] = S_AXI_WDATA;
assign wdch_din[WDATA_OFFSET-1:WSTRB_OFFSET] = S_AXI_WSTRB;
assign wdch_din[0] = S_AXI_WLAST;
end endgenerate // axi_wdch_output
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin
assign M_AXI_WID = wdch_dout[C_DIN_WIDTH_WDCH-1:WID_OFFSET];
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && (C_HAS_AXI_ID == 0 || C_AXI_TYPE != 3)) begin
assign M_AXI_WID = 0;
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1 ) begin
assign M_AXI_WUSER = wdch_dout[WSTRB_OFFSET-1:WUSER_OFFSET];
end endgenerate
generate if (C_HAS_AXI_WUSER == 0) begin
assign M_AXI_WUSER = 0;
end endgenerate
generate if (IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output
assign S_AXI_BRESP = wrch_dout[BID_OFFSET-1:BRESP_OFFSET];
assign wrch_din[BID_OFFSET-1:BRESP_OFFSET] = M_AXI_BRESP;
end endgenerate // axi_wrch_output
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : axi_buser
assign S_AXI_BUSER = wrch_dout[BRESP_OFFSET-1:BUSER_OFFSET];
end endgenerate // axi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 0) begin : naxi_buser
assign S_AXI_BUSER = 0;
end endgenerate // naxi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_bid
assign S_AXI_BID = wrch_dout[C_DIN_WIDTH_WRCH-1:BID_OFFSET];
end endgenerate // axi_bid
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_bid
assign S_AXI_BID = 0 ;
end endgenerate // naxi_bid
generate if (IS_AXI_LITE_WACH == 1 || (IS_AXI_LITE == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output1
assign wach_din = {S_AXI_AWADDR, S_AXI_AWPROT};
assign M_AXI_AWADDR = wach_dout[C_DIN_WIDTH_WACH-1:AWADDR_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWADDR_OFFSET-1:AWPROT_OFFSET];
end endgenerate // axi_wach_output1
generate if (IS_AXI_LITE_WDCH == 1 || (IS_AXI_LITE == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output1
assign wdch_din = {S_AXI_WDATA, S_AXI_WSTRB};
assign M_AXI_WDATA = wdch_dout[C_DIN_WIDTH_WDCH-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
end endgenerate // axi_wdch_output1
generate if (IS_AXI_LITE_WRCH == 1 || (IS_AXI_LITE == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output1
assign wrch_din = M_AXI_BRESP;
assign S_AXI_BRESP = wrch_dout[C_DIN_WIDTH_WRCH-1:BRESP_OFFSET];
end endgenerate // axi_wrch_output1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : gwach_din1
assign wach_din[AWREGION_OFFSET-1:AWUSER_OFFSET] = S_AXI_AWUSER;
end endgenerate // gwach_din1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwach_din2
assign wach_din[C_DIN_WIDTH_WACH-1:AWID_OFFSET] = S_AXI_AWID;
end endgenerate // gwach_din2
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : gwach_din3
assign wach_din[AWQOS_OFFSET-1:AWREGION_OFFSET] = S_AXI_AWREGION;
end endgenerate // gwach_din3
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1) begin : gwdch_din1
assign wdch_din[WSTRB_OFFSET-1:WUSER_OFFSET] = S_AXI_WUSER;
end endgenerate // gwdch_din1
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin : gwdch_din2
assign wdch_din[C_DIN_WIDTH_WDCH-1:WID_OFFSET] = S_AXI_WID;
end endgenerate // gwdch_din2
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : gwrch_din1
assign wrch_din[BRESP_OFFSET-1:BUSER_OFFSET] = M_AXI_BUSER;
end endgenerate // gwrch_din1
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwrch_din2
assign wrch_din[C_DIN_WIDTH_WRCH-1:BID_OFFSET] = M_AXI_BID;
end endgenerate // gwrch_din2
//end of axi_write_channel
//###########################################################################
// AXI FULL Read Channel (axi_read_channel)
//###########################################################################
wire [C_DIN_WIDTH_RACH-1:0] rach_din ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout_pkt ;
wire rach_full ;
wire rach_almost_full ;
wire rach_prog_full ;
wire rach_empty ;
wire rach_almost_empty ;
wire rach_prog_empty ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_din ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_dout ;
wire rdch_full ;
wire rdch_almost_full ;
wire rdch_prog_full ;
wire rdch_empty ;
wire rdch_almost_empty ;
wire rdch_prog_empty ;
wire axi_ar_underflow_i ;
wire axi_r_underflow_i ;
wire axi_ar_overflow_i ;
wire axi_r_overflow_i ;
wire axi_rd_underflow_i ;
wire axi_rd_overflow_i ;
wire rach_s_axi_arready ;
wire rach_m_axi_arvalid ;
wire rach_wr_en ;
wire rach_rd_en ;
wire rdch_m_axi_rready ;
wire rdch_s_axi_rvalid ;
wire rdch_wr_en ;
wire rdch_rd_en ;
wire arvalid_pkt ;
wire arready_pkt ;
wire arvalid_en ;
wire rdch_rd_ok ;
wire accept_next_pkt ;
integer rdch_free_space ;
integer rdch_commited_space ;
wire rach_we ;
wire rach_re ;
wire rdch_we ;
wire rdch_re ;
localparam ARID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RACH;
localparam ARADDR_OFFSET = ARID_OFFSET - C_AXI_ADDR_WIDTH;
localparam ARLEN_OFFSET = C_AXI_TYPE != 2 ? ARADDR_OFFSET - C_AXI_LEN_WIDTH : ARADDR_OFFSET;
localparam ARSIZE_OFFSET = C_AXI_TYPE != 2 ? ARLEN_OFFSET - C_AXI_SIZE_WIDTH : ARLEN_OFFSET;
localparam ARBURST_OFFSET = C_AXI_TYPE != 2 ? ARSIZE_OFFSET - C_AXI_BURST_WIDTH : ARSIZE_OFFSET;
localparam ARLOCK_OFFSET = C_AXI_TYPE != 2 ? ARBURST_OFFSET - C_AXI_LOCK_WIDTH : ARBURST_OFFSET;
localparam ARCACHE_OFFSET = C_AXI_TYPE != 2 ? ARLOCK_OFFSET - C_AXI_CACHE_WIDTH : ARLOCK_OFFSET;
localparam ARPROT_OFFSET = ARCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam ARQOS_OFFSET = ARPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam ARREGION_OFFSET = C_AXI_TYPE == 1 ? ARQOS_OFFSET - C_AXI_REGION_WIDTH : ARQOS_OFFSET;
localparam ARUSER_OFFSET = C_HAS_AXI_ARUSER == 1 ? ARREGION_OFFSET-C_AXI_ARUSER_WIDTH : ARREGION_OFFSET;
localparam RID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RDCH;
localparam RDATA_OFFSET = RID_OFFSET - C_AXI_DATA_WIDTH;
localparam RRESP_OFFSET = RDATA_OFFSET - C_AXI_RRESP_WIDTH;
localparam RUSER_OFFSET = C_HAS_AXI_RUSER == 1 ? RRESP_OFFSET-C_AXI_RUSER_WIDTH : RRESP_OFFSET;
generate if (IS_RD_ADDR_CH == 1) begin : axi_read_addr_channel
// Write protection when almost full or prog_full is high
assign rach_we = (C_PROG_FULL_TYPE_RACH != 0) ? rach_s_axi_arready & S_AXI_ARVALID : S_AXI_ARVALID;
// Read protection when almost empty or prog_empty is high
// assign rach_rd_en = (C_PROG_EMPTY_TYPE_RACH != 5) ? rach_m_axi_arvalid & M_AXI_ARREADY : M_AXI_ARREADY && arvalid_en;
assign rach_re = (C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH == 1) ?
rach_m_axi_arvalid & arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY && rach_m_axi_arvalid :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH == 1) ?
arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY : 1'b0;
assign rach_wr_en = (C_HAS_SLAVE_CE == 1) ? rach_we & S_ACLK_EN : rach_we;
assign rach_rd_en = (C_HAS_MASTER_CE == 1) ? rach_re & M_ACLK_EN : rach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RACH == 2 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RACH == 11 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RACH),
.C_WR_DEPTH (C_WR_DEPTH_RACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_DOUT_WIDTH (C_DIN_WIDTH_RACH),
.C_RD_DEPTH (C_WR_DEPTH_RACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH),
.C_USE_ECC (C_USE_ECC_RACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_RACH == 1)?0:C_APPLICATION_TYPE_RACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rach_wr_en),
.RD_EN (rach_rd_en),
.PROG_FULL_THRESH (AXI_AR_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AR_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.INJECTDBITERR (AXI_AR_INJECTDBITERR),
.INJECTSBITERR (AXI_AR_INJECTSBITERR),
.DIN (rach_din),
.DOUT (rach_dout_pkt),
.FULL (rach_full),
.EMPTY (rach_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_AR_PROG_FULL),
.PROG_EMPTY (AXI_AR_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_ar_overflow_i),
.VALID (),
.UNDERFLOW (axi_ar_underflow_i),
.DATA_COUNT (AXI_AR_DATA_COUNT),
.RD_DATA_COUNT (AXI_AR_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AR_WR_DATA_COUNT),
.SBITERR (AXI_AR_SBITERR),
.DBITERR (AXI_AR_DBITERR),
.wr_rst_busy (wr_rst_busy_rach),
.rd_rst_busy (rd_rst_busy_rach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rach_s_axi_arready = (IS_8SERIES == 0) ? ~rach_full : (C_IMPLEMENTATION_TYPE_RACH == 5 || C_IMPLEMENTATION_TYPE_RACH == 13) ? ~(rach_full | wr_rst_busy_rach) : ~rach_full;
assign rach_m_axi_arvalid = ~rach_empty;
assign S_AXI_ARREADY = rach_s_axi_arready;
assign AXI_AR_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_ar_underflow_i : 0;
assign AXI_AR_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_ar_overflow_i : 0;
end endgenerate // axi_read_addr_channel
// Register Slice for Read Address Channel
generate if (C_RACH_TYPE == 1) begin : grach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RACH)
)
rach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rach_din),
.S_VALID (S_AXI_ARVALID),
.S_READY (S_AXI_ARREADY),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice
// Register Slice for Read Address Channel for MM Packet FIFO
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH == 1) begin : grach_reg_slice_mm_pkt_fifo
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (1)
)
reg_slice_mm_pkt_fifo_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (rach_dout_pkt),
.S_VALID (arvalid_pkt),
.S_READY (arready_pkt),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice_mm_pkt_fifo
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH != 1) begin : grach_m_axi_arvalid
assign M_AXI_ARVALID = rach_m_axi_arvalid;
assign rach_dout = rach_dout_pkt;
end endgenerate // grach_m_axi_arvalid
generate if (C_APPLICATION_TYPE_RACH == 1 && C_HAS_AXI_RD_CHANNEL == 1) begin : axi_mm_pkt_fifo_rd
assign rdch_rd_ok = rdch_s_axi_rvalid && rdch_rd_en;
assign arvalid_pkt = rach_m_axi_arvalid && arvalid_en;
assign accept_next_pkt = rach_m_axi_arvalid && arready_pkt && arvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset) begin
rdch_commited_space <= 0;
end else begin
if(rdch_rd_ok && !accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space-1;
end else if(!rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1);
end else if(rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]);
end
end
end //Always end
always@(*) begin
rdch_free_space <= (C_WR_DEPTH_RDCH-(rdch_commited_space+rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1));
end
assign arvalid_en = (rdch_free_space >= 0)?1:0;
end
endgenerate
generate if (C_APPLICATION_TYPE_RACH != 1) begin : axi_mm_fifo_rd
assign arvalid_en = 1;
end
endgenerate
generate if (IS_RD_DATA_CH == 1) begin : axi_read_data_channel
// Write protection when almost full or prog_full is high
assign rdch_we = (C_PROG_FULL_TYPE_RDCH != 0) ? rdch_m_axi_rready & M_AXI_RVALID : M_AXI_RVALID;
// Read protection when almost empty or prog_empty is high
assign rdch_re = (C_PROG_EMPTY_TYPE_RDCH != 0) ? rdch_s_axi_rvalid & S_AXI_RREADY : S_AXI_RREADY;
assign rdch_wr_en = (C_HAS_MASTER_CE == 1) ? rdch_we & M_ACLK_EN : rdch_we;
assign rdch_rd_en = (C_HAS_SLAVE_CE == 1) ? rdch_re & S_ACLK_EN : rdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RDCH == 2 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RDCH == 11 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RDCH),
.C_WR_DEPTH (C_WR_DEPTH_RDCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_RDCH),
.C_RD_DEPTH (C_WR_DEPTH_RDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH),
.C_USE_ECC (C_USE_ECC_RDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_RDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rdch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rdch_wr_en),
.RD_EN (rdch_rd_en),
.PROG_FULL_THRESH (AXI_R_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_R_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.INJECTDBITERR (AXI_R_INJECTDBITERR),
.INJECTSBITERR (AXI_R_INJECTSBITERR),
.DIN (rdch_din),
.DOUT (rdch_dout),
.FULL (rdch_full),
.EMPTY (rdch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_R_PROG_FULL),
.PROG_EMPTY (AXI_R_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_r_overflow_i),
.VALID (),
.UNDERFLOW (axi_r_underflow_i),
.DATA_COUNT (AXI_R_DATA_COUNT),
.RD_DATA_COUNT (AXI_R_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_R_WR_DATA_COUNT),
.SBITERR (AXI_R_SBITERR),
.DBITERR (AXI_R_DBITERR),
.wr_rst_busy (wr_rst_busy_rdch),
.rd_rst_busy (rd_rst_busy_rdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rdch_s_axi_rvalid = ~rdch_empty;
assign rdch_m_axi_rready = (IS_8SERIES == 0) ? ~rdch_full : (C_IMPLEMENTATION_TYPE_RDCH == 5 || C_IMPLEMENTATION_TYPE_RDCH == 13) ? ~(rdch_full | wr_rst_busy_rdch) : ~rdch_full;
assign S_AXI_RVALID = rdch_s_axi_rvalid;
assign M_AXI_RREADY = rdch_m_axi_rready;
assign AXI_R_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_r_underflow_i : 0;
assign AXI_R_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_r_overflow_i : 0;
end endgenerate //axi_read_data_channel
// Register Slice for read Data Channel
generate if (C_RDCH_TYPE == 1) begin : grdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RDCH)
)
rdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rdch_din),
.S_VALID (M_AXI_RVALID),
.S_READY (M_AXI_RREADY),
// Master side
.M_PAYLOAD_DATA (rdch_dout),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY)
);
end endgenerate // grdch_reg_slice
assign axi_rd_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_ar_underflow_i || axi_r_underflow_i) : 0;
assign axi_rd_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_ar_overflow_i || axi_r_overflow_i) : 0;
generate if (IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) begin : axi_full_rach_output
assign M_AXI_ARADDR = rach_dout[ARID_OFFSET-1:ARADDR_OFFSET];
assign M_AXI_ARLEN = rach_dout[ARADDR_OFFSET-1:ARLEN_OFFSET];
assign M_AXI_ARSIZE = rach_dout[ARLEN_OFFSET-1:ARSIZE_OFFSET];
assign M_AXI_ARBURST = rach_dout[ARSIZE_OFFSET-1:ARBURST_OFFSET];
assign M_AXI_ARLOCK = rach_dout[ARBURST_OFFSET-1:ARLOCK_OFFSET];
assign M_AXI_ARCACHE = rach_dout[ARLOCK_OFFSET-1:ARCACHE_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARCACHE_OFFSET-1:ARPROT_OFFSET];
assign M_AXI_ARQOS = rach_dout[ARPROT_OFFSET-1:ARQOS_OFFSET];
assign rach_din[ARID_OFFSET-1:ARADDR_OFFSET] = S_AXI_ARADDR;
assign rach_din[ARADDR_OFFSET-1:ARLEN_OFFSET] = S_AXI_ARLEN;
assign rach_din[ARLEN_OFFSET-1:ARSIZE_OFFSET] = S_AXI_ARSIZE;
assign rach_din[ARSIZE_OFFSET-1:ARBURST_OFFSET] = S_AXI_ARBURST;
assign rach_din[ARBURST_OFFSET-1:ARLOCK_OFFSET] = S_AXI_ARLOCK;
assign rach_din[ARLOCK_OFFSET-1:ARCACHE_OFFSET] = S_AXI_ARCACHE;
assign rach_din[ARCACHE_OFFSET-1:ARPROT_OFFSET] = S_AXI_ARPROT;
assign rach_din[ARPROT_OFFSET-1:ARQOS_OFFSET] = S_AXI_ARQOS;
end endgenerate // axi_full_rach_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_arregion
assign M_AXI_ARREGION = rach_dout[ARQOS_OFFSET-1:ARREGION_OFFSET];
end endgenerate // axi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_arregion
assign M_AXI_ARREGION = 0;
end endgenerate // naxi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : axi_aruser
assign M_AXI_ARUSER = rach_dout[ARREGION_OFFSET-1:ARUSER_OFFSET];
end endgenerate // axi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 0) begin : naxi_aruser
assign M_AXI_ARUSER = 0;
end endgenerate // naxi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_arid
assign M_AXI_ARID = rach_dout[C_DIN_WIDTH_RACH-1:ARID_OFFSET];
end endgenerate // axi_arid
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_arid
assign M_AXI_ARID = 0;
end endgenerate // naxi_arid
generate if (IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) begin : axi_full_rdch_output
assign S_AXI_RDATA = rdch_dout[RID_OFFSET-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
assign S_AXI_RLAST = rdch_dout[0];
assign rdch_din[RID_OFFSET-1:RDATA_OFFSET] = M_AXI_RDATA;
assign rdch_din[RDATA_OFFSET-1:RRESP_OFFSET] = M_AXI_RRESP;
assign rdch_din[0] = M_AXI_RLAST;
end endgenerate // axi_full_rdch_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : axi_full_ruser_output
assign S_AXI_RUSER = rdch_dout[RRESP_OFFSET-1:RUSER_OFFSET];
end endgenerate // axi_full_ruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 0) begin : axi_full_nruser_output
assign S_AXI_RUSER = 0;
end endgenerate // axi_full_nruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_rid
assign S_AXI_RID = rdch_dout[C_DIN_WIDTH_RDCH-1:RID_OFFSET];
end endgenerate // axi_rid
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_rid
assign S_AXI_RID = 0;
end endgenerate // naxi_rid
generate if (IS_AXI_LITE_RACH == 1 || (IS_AXI_LITE == 1 && C_RACH_TYPE == 1)) begin : axi_lite_rach_output1
assign rach_din = {S_AXI_ARADDR, S_AXI_ARPROT};
assign M_AXI_ARADDR = rach_dout[C_DIN_WIDTH_RACH-1:ARADDR_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARADDR_OFFSET-1:ARPROT_OFFSET];
end endgenerate // axi_lite_rach_output
generate if (IS_AXI_LITE_RDCH == 1 || (IS_AXI_LITE == 1 && C_RDCH_TYPE == 1)) begin : axi_lite_rdch_output1
assign rdch_din = {M_AXI_RDATA, M_AXI_RRESP};
assign S_AXI_RDATA = rdch_dout[C_DIN_WIDTH_RDCH-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
end endgenerate // axi_lite_rdch_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : grach_din1
assign rach_din[ARREGION_OFFSET-1:ARUSER_OFFSET] = S_AXI_ARUSER;
end endgenerate // grach_din1
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grach_din2
assign rach_din[C_DIN_WIDTH_RACH-1:ARID_OFFSET] = S_AXI_ARID;
end endgenerate // grach_din2
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin
assign rach_din[ARQOS_OFFSET-1:ARREGION_OFFSET] = S_AXI_ARREGION;
end endgenerate
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : grdch_din1
assign rdch_din[RRESP_OFFSET-1:RUSER_OFFSET] = M_AXI_RUSER;
end endgenerate // grdch_din1
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grdch_din2
assign rdch_din[C_DIN_WIDTH_RDCH-1:RID_OFFSET] = M_AXI_RID;
end endgenerate // grdch_din2
//end of axi_read_channel
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_UNDERFLOW == 1) begin : gaxi_comm_uf
assign UNDERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_underflow_i || axi_rd_underflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_underflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_underflow_i : 0;
end endgenerate // gaxi_comm_uf
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_OVERFLOW == 1) begin : gaxi_comm_of
assign OVERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_overflow_i || axi_rd_overflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_overflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_overflow_i : 0;
end endgenerate // gaxi_comm_of
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic or Wiring Logic
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Write Address Channel
generate if (C_WACH_TYPE == 2) begin : gwach_pass_through
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWQOS = S_AXI_AWQOS;
assign M_AXI_AWREGION = S_AXI_AWREGION;
assign M_AXI_AWUSER = S_AXI_AWUSER;
assign S_AXI_AWREADY = M_AXI_AWREADY;
assign M_AXI_AWVALID = S_AXI_AWVALID;
end endgenerate // gwach_pass_through;
// Wiring logic for Write Data Channel
generate if (C_WDCH_TYPE == 2) begin : gwdch_pass_through
assign M_AXI_WID = S_AXI_WID;
assign M_AXI_WDATA = S_AXI_WDATA;
assign M_AXI_WSTRB = S_AXI_WSTRB;
assign M_AXI_WLAST = S_AXI_WLAST;
assign M_AXI_WUSER = S_AXI_WUSER;
assign S_AXI_WREADY = M_AXI_WREADY;
assign M_AXI_WVALID = S_AXI_WVALID;
end endgenerate // gwdch_pass_through;
// Wiring logic for Write Response Channel
generate if (C_WRCH_TYPE == 2) begin : gwrch_pass_through
assign S_AXI_BID = M_AXI_BID;
assign S_AXI_BRESP = M_AXI_BRESP;
assign S_AXI_BUSER = M_AXI_BUSER;
assign M_AXI_BREADY = S_AXI_BREADY;
assign S_AXI_BVALID = M_AXI_BVALID;
end endgenerate // gwrch_pass_through;
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Read Address Channel
generate if (C_RACH_TYPE == 2) begin : grach_pass_through
assign M_AXI_ARID = S_AXI_ARID;
assign M_AXI_ARADDR = S_AXI_ARADDR;
assign M_AXI_ARLEN = S_AXI_ARLEN;
assign M_AXI_ARSIZE = S_AXI_ARSIZE;
assign M_AXI_ARBURST = S_AXI_ARBURST;
assign M_AXI_ARLOCK = S_AXI_ARLOCK;
assign M_AXI_ARCACHE = S_AXI_ARCACHE;
assign M_AXI_ARPROT = S_AXI_ARPROT;
assign M_AXI_ARQOS = S_AXI_ARQOS;
assign M_AXI_ARREGION = S_AXI_ARREGION;
assign M_AXI_ARUSER = S_AXI_ARUSER;
assign S_AXI_ARREADY = M_AXI_ARREADY;
assign M_AXI_ARVALID = S_AXI_ARVALID;
end endgenerate // grach_pass_through;
// Wiring logic for Read Data Channel
generate if (C_RDCH_TYPE == 2) begin : grdch_pass_through
assign S_AXI_RID = M_AXI_RID;
assign S_AXI_RLAST = M_AXI_RLAST;
assign S_AXI_RUSER = M_AXI_RUSER;
assign S_AXI_RDATA = M_AXI_RDATA;
assign S_AXI_RRESP = M_AXI_RRESP;
assign S_AXI_RVALID = M_AXI_RVALID;
assign M_AXI_RREADY = S_AXI_RREADY;
end endgenerate // grdch_pass_through;
// Wiring logic for AXI Streaming
generate if (C_AXIS_TYPE == 2) begin : gaxis_pass_through
assign M_AXIS_TDATA = S_AXIS_TDATA;
assign M_AXIS_TSTRB = S_AXIS_TSTRB;
assign M_AXIS_TKEEP = S_AXIS_TKEEP;
assign M_AXIS_TID = S_AXIS_TID;
assign M_AXIS_TDEST = S_AXIS_TDEST;
assign M_AXIS_TUSER = S_AXIS_TUSER;
assign M_AXIS_TLAST = S_AXIS_TLAST;
assign S_AXIS_TREADY = M_AXIS_TREADY;
assign M_AXIS_TVALID = S_AXIS_TVALID;
end endgenerate // gaxis_pass_through;
endmodule //fifo_generator_v13_1_3
/*******************************************************************************
* Declaration of top-level module for Conventional FIFO
******************************************************************************/
module fifo_generator_v13_1_3_CONV_VER
#(
parameter C_COMMON_CLOCK = 0,
parameter C_INTERFACE_TYPE = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "virtex7", //Not allowed in Verilog model
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
parameter C_AXI_TYPE = 0
)
(
input BACKUP,
input BACKUP_MARKER,
input CLK,
input RST,
input SRST,
input WR_CLK,
input WR_RST,
input RD_CLK,
input RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input WR_EN,
input RD_EN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input INT_CLK,
input INJECTDBITERR,
input INJECTSBITERR,
output [C_DOUT_WIDTH-1:0] DOUT,
output FULL,
output ALMOST_FULL,
output WR_ACK,
output OVERFLOW,
output EMPTY,
output ALMOST_EMPTY,
output VALID,
output UNDERFLOW,
output [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_FULL,
output PROG_EMPTY,
output SBITERR,
output DBITERR,
output wr_rst_busy_o,
output wr_rst_busy,
output rd_rst_busy,
output wr_rst_i_out,
output rd_rst_i_out
);
/*
******************************************************************************
* Definition of Parameters
******************************************************************************
* C_COMMON_CLOCK : Common Clock (1), Independent Clocks (0)
* C_COUNT_TYPE : *not used
* C_DATA_COUNT_WIDTH : Width of DATA_COUNT bus
* C_DEFAULT_VALUE : *not used
* C_DIN_WIDTH : Width of DIN bus
* C_DOUT_RST_VAL : Reset value of DOUT
* C_DOUT_WIDTH : Width of DOUT bus
* C_ENABLE_RLOCS : *not used
* C_FAMILY : not used in bhv model
* C_FULL_FLAGS_RST_VAL : Full flags rst val (0 or 1)
* C_HAS_ALMOST_EMPTY : 1=Core has ALMOST_EMPTY flag
* C_HAS_ALMOST_FULL : 1=Core has ALMOST_FULL flag
* C_HAS_BACKUP : *not used
* C_HAS_DATA_COUNT : 1=Core has DATA_COUNT bus
* C_HAS_INT_CLK : not used in bhv model
* C_HAS_MEMINIT_FILE : *not used
* C_HAS_OVERFLOW : 1=Core has OVERFLOW flag
* C_HAS_RD_DATA_COUNT : 1=Core has RD_DATA_COUNT bus
* C_HAS_RD_RST : *not used
* C_HAS_RST : 1=Core has Async Rst
* C_HAS_SRST : 1=Core has Sync Rst
* C_HAS_UNDERFLOW : 1=Core has UNDERFLOW flag
* C_HAS_VALID : 1=Core has VALID flag
* C_HAS_WR_ACK : 1=Core has WR_ACK flag
* C_HAS_WR_DATA_COUNT : 1=Core has WR_DATA_COUNT bus
* C_HAS_WR_RST : *not used
* C_IMPLEMENTATION_TYPE : 0=Common-Clock Bram/Dram
* 1=Common-Clock ShiftRam
* 2=Indep. Clocks Bram/Dram
* 3=Virtex-4 Built-in
* 4=Virtex-5 Built-in
* C_INIT_WR_PNTR_VAL : *not used
* C_MEMORY_TYPE : 1=Block RAM
* 2=Distributed RAM
* 3=Shift RAM
* 4=Built-in FIFO
* C_MIF_FILE_NAME : *not used
* C_OPTIMIZATION_MODE : *not used
* C_OVERFLOW_LOW : 1=OVERFLOW active low
* C_PRELOAD_LATENCY : Latency of read: 0, 1, 2
* C_PRELOAD_REGS : 1=Use output registers
* C_PRIM_FIFO_TYPE : not used in bhv model
* C_PROG_EMPTY_THRESH_ASSERT_VAL: PROG_EMPTY assert threshold
* C_PROG_EMPTY_THRESH_NEGATE_VAL: PROG_EMPTY negate threshold
* C_PROG_EMPTY_TYPE : 0=No programmable empty
* 1=Single prog empty thresh constant
* 2=Multiple prog empty thresh constants
* 3=Single prog empty thresh input
* 4=Multiple prog empty thresh inputs
* C_PROG_FULL_THRESH_ASSERT_VAL : PROG_FULL assert threshold
* C_PROG_FULL_THRESH_NEGATE_VAL : PROG_FULL negate threshold
* C_PROG_FULL_TYPE : 0=No prog full
* 1=Single prog full thresh constant
* 2=Multiple prog full thresh constants
* 3=Single prog full thresh input
* 4=Multiple prog full thresh inputs
* C_RD_DATA_COUNT_WIDTH : Width of RD_DATA_COUNT bus
* C_RD_DEPTH : Depth of read interface (2^N)
* C_RD_FREQ : not used in bhv model
* C_RD_PNTR_WIDTH : always log2(C_RD_DEPTH)
* C_UNDERFLOW_LOW : 1=UNDERFLOW active low
* C_USE_DOUT_RST : 1=Resets DOUT on RST
* C_USE_ECC : Used for error injection purpose
* C_USE_EMBEDDED_REG : 1=Use BRAM embedded output register
* C_USE_FIFO16_FLAGS : not used in bhv model
* C_USE_FWFT_DATA_COUNT : 1=Use extra logic for FWFT data count
* C_VALID_LOW : 1=VALID active low
* C_WR_ACK_LOW : 1=WR_ACK active low
* C_WR_DATA_COUNT_WIDTH : Width of WR_DATA_COUNT bus
* C_WR_DEPTH : Depth of write interface (2^N)
* C_WR_FREQ : not used in bhv model
* C_WR_PNTR_WIDTH : always log2(C_WR_DEPTH)
* C_WR_RESPONSE_LATENCY : *not used
* C_MSGON_VAL : *not used by bhv model
* C_ENABLE_RST_SYNC : 0 = Use WR_RST & RD_RST
* 1 = Use RST
* C_ERROR_INJECTION_TYPE : 0 = No error injection
* 1 = Single bit error injection only
* 2 = Double bit error injection only
* 3 = Single and double bit error injection
******************************************************************************
* Definition of Ports
******************************************************************************
* BACKUP : Not used
* BACKUP_MARKER: Not used
* CLK : Clock
* DIN : Input data bus
* PROG_EMPTY_THRESH : Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_ASSERT: Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_NEGATE: Threshold for Programmable Empty Flag
* PROG_FULL_THRESH : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_ASSERT : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_NEGATE : Threshold for Programmable Full Flag
* RD_CLK : Read Domain Clock
* RD_EN : Read enable
* RD_RST : Read Reset
* RST : Asynchronous Reset
* SRST : Synchronous Reset
* WR_CLK : Write Domain Clock
* WR_EN : Write enable
* WR_RST : Write Reset
* INT_CLK : Internal Clock
* INJECTSBITERR: Inject Signle bit error
* INJECTDBITERR: Inject Double bit error
* ALMOST_EMPTY : One word remaining in FIFO
* ALMOST_FULL : One empty space remaining in FIFO
* DATA_COUNT : Number of data words in fifo( synchronous to CLK)
* DOUT : Output data bus
* EMPTY : Empty flag
* FULL : Full flag
* OVERFLOW : Last write rejected
* PROG_EMPTY : Programmable Empty Flag
* PROG_FULL : Programmable Full Flag
* RD_DATA_COUNT: Number of data words in fifo (synchronous to RD_CLK)
* UNDERFLOW : Last read rejected
* VALID : Last read acknowledged, DOUT bus VALID
* WR_ACK : Last write acknowledged
* WR_DATA_COUNT: Number of data words in fifo (synchronous to WR_CLK)
* SBITERR : Single Bit ECC Error Detected
* DBITERR : Double Bit ECC Error Detected
******************************************************************************
*/
//----------------------------------------------------------------------------
//- Internal Signals for delayed input signals
//- All the input signals except Clock are delayed by 100 ps and then given to
//- the models.
//----------------------------------------------------------------------------
reg rst_delayed ;
reg empty_fb ;
reg srst_delayed ;
reg wr_rst_delayed ;
reg rd_rst_delayed ;
reg wr_en_delayed ;
reg rd_en_delayed ;
reg [C_DIN_WIDTH-1:0] din_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate_delayed ;
reg injectdbiterr_delayed ;
reg injectsbiterr_delayed ;
wire empty_p0_out;
always @* rst_delayed <= #`TCQ RST ;
always @* empty_fb <= #`TCQ empty_p0_out ;
always @* srst_delayed <= #`TCQ SRST ;
always @* wr_rst_delayed <= #`TCQ WR_RST ;
always @* rd_rst_delayed <= #`TCQ RD_RST ;
always @* din_delayed <= #`TCQ DIN ;
always @* wr_en_delayed <= #`TCQ WR_EN ;
always @* rd_en_delayed <= #`TCQ RD_EN ;
always @* prog_empty_thresh_delayed <= #`TCQ PROG_EMPTY_THRESH ;
always @* prog_empty_thresh_assert_delayed <= #`TCQ PROG_EMPTY_THRESH_ASSERT ;
always @* prog_empty_thresh_negate_delayed <= #`TCQ PROG_EMPTY_THRESH_NEGATE ;
always @* prog_full_thresh_delayed <= #`TCQ PROG_FULL_THRESH ;
always @* prog_full_thresh_assert_delayed <= #`TCQ PROG_FULL_THRESH_ASSERT ;
always @* prog_full_thresh_negate_delayed <= #`TCQ PROG_FULL_THRESH_NEGATE ;
always @* injectdbiterr_delayed <= #`TCQ INJECTDBITERR ;
always @* injectsbiterr_delayed <= #`TCQ INJECTSBITERR ;
/*****************************************************************************
* Derived parameters
****************************************************************************/
//There are 2 Verilog behavioral models
// 0 = Common-Clock FIFO/ShiftRam FIFO
// 1 = Independent Clocks FIFO
// 2 = Low Latency Synchronous FIFO
// 3 = Low Latency Asynchronous FIFO
localparam C_VERILOG_IMPL = (C_FIFO_TYPE == 3) ? 2 :
(C_IMPLEMENTATION_TYPE == 2) ? 1 : 0;
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//Internal reset signals
reg rd_rst_asreg = 0;
wire rd_rst_asreg_d1;
wire rd_rst_asreg_d2;
reg rd_rst_asreg_d3 = 0;
reg rd_rst_reg = 0;
wire rd_rst_comb;
reg wr_rst_d0 = 0;
reg wr_rst_d1 = 0;
reg wr_rst_d2 = 0;
reg rd_rst_d0 = 0;
reg rd_rst_d1 = 0;
reg rd_rst_d2 = 0;
reg rd_rst_d3 = 0;
reg wrrst_done = 0;
reg rdrst_done = 0;
reg wr_rst_asreg = 0;
wire wr_rst_asreg_d1;
wire wr_rst_asreg_d2;
reg wr_rst_asreg_d3 = 0;
reg rd_rst_wr_d0 = 0;
reg rd_rst_wr_d1 = 0;
reg rd_rst_wr_d2 = 0;
reg wr_rst_reg = 0;
reg rst_active_i = 1'b1;
reg rst_delayed_d1 = 1'b1;
reg rst_delayed_d2 = 1'b1;
wire wr_rst_comb;
wire wr_rst_i;
wire rd_rst_i;
wire rst_i;
//Internal reset signals
reg rst_asreg = 0;
reg srst_asreg = 0;
wire rst_asreg_d1;
wire rst_asreg_d2;
reg srst_asreg_d1 = 0;
reg srst_asreg_d2 = 0;
reg rst_reg = 0;
reg srst_reg = 0;
wire rst_comb;
wire srst_comb;
reg rst_full_gen_i = 0;
reg rst_full_ff_i = 0;
reg [2:0] sckt_ff0_bsy_o_i = {3{1'b0}};
wire RD_CLK_P0_IN;
wire RST_P0_IN;
wire RD_EN_FIFO_IN;
wire RD_EN_P0_IN;
wire ALMOST_EMPTY_FIFO_OUT;
wire ALMOST_FULL_FIFO_OUT;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT_FIFO_OUT;
wire [C_DOUT_WIDTH-1:0] DOUT_FIFO_OUT;
wire EMPTY_FIFO_OUT;
wire fifo_empty_fb;
wire FULL_FIFO_OUT;
wire OVERFLOW_FIFO_OUT;
wire PROG_EMPTY_FIFO_OUT;
wire PROG_FULL_FIFO_OUT;
wire VALID_FIFO_OUT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT_FIFO_OUT;
wire UNDERFLOW_FIFO_OUT;
wire WR_ACK_FIFO_OUT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT_FIFO_OUT;
//***************************************************************************
// Internal Signals
// The core uses either the internal_ wires or the preload0_ wires depending
// on whether the core uses Preload0 or not.
// When using preload0, the internal signals connect the internal core to
// the preload logic, and the external core's interfaces are tied to the
// preload0 signals from the preload logic.
//***************************************************************************
wire [C_DOUT_WIDTH-1:0] DATA_P0_OUT;
wire VALID_P0_OUT;
wire EMPTY_P0_OUT;
wire ALMOSTEMPTY_P0_OUT;
reg EMPTY_P0_OUT_Q;
reg ALMOSTEMPTY_P0_OUT_Q;
wire UNDERFLOW_P0_OUT;
wire RDEN_P0_OUT;
wire [C_DOUT_WIDTH-1:0] DATA_P0_IN;
wire EMPTY_P0_IN;
reg [31:0] DATA_COUNT_FWFT;
reg SS_FWFT_WR ;
reg SS_FWFT_RD ;
wire sbiterr_fifo_out;
wire dbiterr_fifo_out;
wire inject_sbit_err;
wire inject_dbit_err;
wire safety_ckt_wr_rst;
wire safety_ckt_rd_rst;
reg sckt_wr_rst_i_q = 1'b0;
wire w_fab_read_data_valid_i;
wire w_read_data_valid_i;
wire w_ram_valid_i;
// Assign 0 if not selected to avoid 'X' propogation to S/DBITERR.
assign inject_sbit_err = ((C_ERROR_INJECTION_TYPE == 1) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectsbiterr_delayed : 0;
assign inject_dbit_err = ((C_ERROR_INJECTION_TYPE == 2) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectdbiterr_delayed : 0;
assign wr_rst_i_out = wr_rst_i;
assign rd_rst_i_out = rd_rst_i;
assign wr_rst_busy_o = wr_rst_busy | rst_full_gen_i | sckt_ff0_bsy_o_i[2];
generate if (C_FULL_FLAGS_RST_VAL == 0 && C_EN_SAFETY_CKT == 1) begin : gsckt_bsy_o
wire clk_i = C_COMMON_CLOCK ? CLK : WR_CLK;
always @ (posedge clk_i)
sckt_ff0_bsy_o_i <= {sckt_ff0_bsy_o_i[1:0],wr_rst_busy};
end endgenerate
// Choose the behavioral model to instantiate based on the C_VERILOG_IMPL
// parameter (1=Independent Clocks, 0=Common Clock)
localparam FULL_FLAGS_RST_VAL = (C_HAS_SRST == 1) ? 0 : C_FULL_FLAGS_RST_VAL;
generate
case (C_VERILOG_IMPL)
0 : begin : block1
//Common Clock Behavioral Model
fifo_generator_v13_1_3_bhv_ver_ss
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL ((C_AXI_TYPE == 0 && C_FIFO_TYPE == 1) ? 1 : C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ss
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.CLK (CLK),
.RST (rst_i),
.SRST (srst_delayed),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.USER_EMPTY_FB (empty_fb),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.DATA_COUNT (DATA_COUNT_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
1 : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.fab_read_data_valid_i (w_fab_read_data_valid_i),
.read_data_valid_i (w_read_data_valid_i),
.ram_valid_i (w_ram_valid_i),
.DBITERR (dbiterr_fifo_out)
);
end
2 : begin : ll_afifo_inst
fifo_generator_v13_1_3_beh_ver_ll_afifo
#(
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ll_afifo
(
.DIN (din_delayed),
.RD_CLK (RD_CLK),
.RD_EN (rd_en_delayed),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.WR_CLK (WR_CLK),
.WR_EN (wr_en_delayed),
.DOUT (DOUT),
.EMPTY (EMPTY),
.FULL (FULL)
);
end
default : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
endcase
endgenerate
//**************************************************************************
// Connect Internal Signals
// (Signals labeled internal_*)
// In the normal case, these signals tie directly to the FIFO's inputs and
// outputs.
// In the case of Preload Latency 0 or 1, there are intermediate
// signals between the internal FIFO and the preload logic.
//**************************************************************************
//***********************************************
// If First-Word Fall-Through, instantiate
// the preload0 (FWFT) module
//***********************************************
wire rd_en_to_fwft_fifo;
wire sbiterr_fwft;
wire dbiterr_fwft;
wire [C_DOUT_WIDTH-1:0] dout_fwft;
wire empty_fwft;
wire rd_en_fifo_in;
wire stage2_reg_en_i;
wire [1:0] valid_stages_i;
wire rst_fwft;
//wire empty_p0_out;
reg [C_SYNCHRONIZER_STAGE-1:0] pkt_empty_sync = 'b1;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
localparam IS_PKT_FIFO = (C_FIFO_TYPE == 1) ? 1 : 0;
localparam IS_AXIS_PKT_FIFO = (C_FIFO_TYPE == 1 && C_AXI_TYPE == 0) ? 1 : 0;
assign rst_fwft = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 1'b0;
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 3) begin : block2
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
fgpl0
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (RST_P0_IN),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (RD_EN_P0_IN),
.FIFOEMPTY (EMPTY_P0_IN),
.FIFODATA (DATA_P0_IN),
.FIFOSBITERR (sbiterr_fifo_out),
.FIFODBITERR (dbiterr_fifo_out),
// Output
.USERDATA (dout_fwft),
.USERVALID (VALID_P0_OUT),
.USEREMPTY (empty_fwft),
.USERALMOSTEMPTY (ALMOSTEMPTY_P0_OUT),
.USERUNDERFLOW (UNDERFLOW_P0_OUT),
.RAMVALID (),
.FIFORDEN (rd_en_fifo_in),
.USERSBITERR (sbiterr_fwft),
.USERDBITERR (dbiterr_fwft),
.STAGE2_REG_EN (stage2_reg_en_i),
.fab_read_data_valid_i_o (w_fab_read_data_valid_i),
.read_data_valid_i_o (w_read_data_valid_i),
.ram_valid_i_o (w_ram_valid_i),
.VALID_STAGES (valid_stages_i)
);
//***********************************************
// Connect inputs to preload (FWFT) module
//***********************************************
//Connect the RD_CLK of the Preload (FWFT) module to CLK if we
// have a common-clock FIFO, or RD_CLK if we have an
// independent clock FIFO
assign RD_CLK_P0_IN = ((C_VERILOG_IMPL == 0) ? CLK : RD_CLK);
assign RST_P0_IN = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 0;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
assign EMPTY_P0_IN = C_EN_SAFETY_CKT ? fifo_empty_fb : EMPTY_FIFO_OUT;
assign DATA_P0_IN = DOUT_FIFO_OUT;
//***********************************************
// Connect outputs from preload (FWFT) module
//***********************************************
assign VALID = VALID_P0_OUT ;
assign ALMOST_EMPTY = ALMOSTEMPTY_P0_OUT;
assign UNDERFLOW = UNDERFLOW_P0_OUT ;
assign RD_EN_FIFO_IN = rd_en_fifo_in;
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
assign DATA_COUNT = (C_USE_FWFT_DATA_COUNT == 0)? DATA_COUNT_FIFO_OUT:
(C_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) ? DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:0] :
DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH+1];
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
EMPTY_P0_OUT_Q <= 1;
ALMOSTEMPTY_P0_OUT_Q <= 1;
end else begin
EMPTY_P0_OUT_Q <= #`TCQ empty_p0_out;
// EMPTY_P0_OUT_Q <= #`TCQ EMPTY_FIFO_OUT;
ALMOSTEMPTY_P0_OUT_Q <= #`TCQ ALMOSTEMPTY_P0_OUT;
end
end //always
//***********************************************
// logic for common-clock data count when FWFT is selected
//***********************************************
initial begin
SS_FWFT_RD = 1'b0;
DATA_COUNT_FWFT = 0 ;
SS_FWFT_WR = 1'b0 ;
end //initial
//***********************************************
// common-clock data count is implemented as an
// up-down counter. SS_FWFT_WR and SS_FWFT_RD
// are the up/down enables for the counter.
//***********************************************
always @ (RD_EN or VALID_P0_OUT or WR_EN or FULL_FIFO_OUT or empty_p0_out) begin
if (C_VALID_LOW == 1) begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && ~VALID_P0_OUT) : (~empty_p0_out && RD_EN && ~VALID_P0_OUT) ;
end else begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && VALID_P0_OUT) : (~empty_p0_out && RD_EN && VALID_P0_OUT) ;
end
SS_FWFT_WR = (WR_EN && (~FULL_FIFO_OUT)) ;
end
//***********************************************
// common-clock data count is implemented as an
// up-down counter for FWFT. This always block
// calculates the counter.
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
DATA_COUNT_FWFT <= 0;
end else begin
//if (srst_delayed && (C_HAS_SRST == 1) ) begin
if ((srst_delayed | wr_rst_busy | rd_rst_busy) && (C_HAS_SRST == 1) ) begin
DATA_COUNT_FWFT <= #`TCQ 0;
end else begin
case ( {SS_FWFT_WR, SS_FWFT_RD})
2'b00: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
2'b01: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT - 1 ;
2'b10: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT + 1 ;
2'b11: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
endcase
end //if SRST
end //IF RST
end //always
end endgenerate // : block2
// AXI Streaming Packet FIFO
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_plus1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_reg = 0;
reg partial_packet = 0;
reg stage1_eop_d1 = 0;
reg rd_en_fifo_in_d1 = 0;
reg eop_at_stage2 = 0;
reg ram_pkt_empty = 0;
reg ram_pkt_empty_d1 = 0;
wire [C_DOUT_WIDTH-1:0] dout_p0_out;
wire packet_empty_wr;
wire wr_rst_fwft_pkt_fifo;
wire dummy_wr_eop;
wire ram_wr_en_pkt_fifo;
wire wr_eop;
wire ram_rd_en_compare;
wire stage1_eop;
wire pkt_ready_to_read;
wire rd_en_2_stage2;
// Generate Dummy WR_EOP for partial packet (Only for AXI Streaming)
// When Packet EMPTY is high, and FIFO is full, then generate the dummy WR_EOP
// When dummy WR_EOP is high, mask the actual EOP to avoid double increment of
// write packet count
generate if (IS_FWFT == 1 && IS_AXIS_PKT_FIFO == 1) begin // gdummy_wr_eop
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
partial_packet <= 1'b0;
else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy)
partial_packet <= #`TCQ 1'b0;
else if (ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]))
partial_packet <= #`TCQ 1'b1;
else if (partial_packet && din_delayed[0] && ram_wr_en_pkt_fifo)
partial_packet <= #`TCQ 1'b0;
end
end
end endgenerate // gdummy_wr_eop
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1) begin // gpkt_fifo_fwft
assign wr_rst_fwft_pkt_fifo = (C_COMMON_CLOCK == 0) ? wr_rst_i : (C_HAS_RST == 1) ? rst_i:1'b0;
assign dummy_wr_eop = ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]) && (~partial_packet);
assign packet_empty_wr = (C_COMMON_CLOCK == 1) ? empty_p0_out : pkt_empty_sync[C_SYNCHRONIZER_STAGE-1];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
stage1_eop_d1 <= 1'b0;
rd_en_fifo_in_d1 <= 1'b0;
end else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
stage1_eop_d1 <= #`TCQ 1'b0;
rd_en_fifo_in_d1 <= #`TCQ 1'b0;
end else begin
stage1_eop_d1 <= #`TCQ stage1_eop;
rd_en_fifo_in_d1 <= #`TCQ rd_en_fifo_in;
end
end
end
assign stage1_eop = (rd_en_fifo_in_d1) ? DOUT_FIFO_OUT[0] : stage1_eop_d1;
assign ram_wr_en_pkt_fifo = wr_en_delayed && (~FULL_FIFO_OUT);
assign wr_eop = ram_wr_en_pkt_fifo && ((din_delayed[0] && (~partial_packet)) || dummy_wr_eop);
assign ram_rd_en_compare = stage2_reg_en_i && stage1_eop;
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (2) // Enable low latency fwft logic
)
pkt_fifo_fwft
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (rst_fwft),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (rd_en_delayed),
.FIFOEMPTY (pkt_ready_to_read),
.FIFODATA (dout_fwft),
.FIFOSBITERR (sbiterr_fwft),
.FIFODBITERR (dbiterr_fwft),
// Output
.USERDATA (dout_p0_out),
.USERVALID (),
.USEREMPTY (empty_p0_out),
.USERALMOSTEMPTY (),
.USERUNDERFLOW (),
.RAMVALID (),
.FIFORDEN (rd_en_2_stage2),
.USERSBITERR (SBITERR),
.USERDBITERR (DBITERR),
.STAGE2_REG_EN (),
.VALID_STAGES ()
);
assign pkt_ready_to_read = ~(!(ram_pkt_empty || empty_fwft) && ((valid_stages_i[0] && valid_stages_i[1]) || eop_at_stage2));
assign rd_en_to_fwft_fifo = ~empty_fwft && rd_en_2_stage2;
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
eop_at_stage2 <= 1'b0;
else if (stage2_reg_en_i)
eop_at_stage2 <= #`TCQ stage1_eop;
end
//---------------------------------------------------------------------------
// Write and Read Packet Count
//---------------------------------------------------------------------------
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count <= 0;
else if (srst_delayed | wr_rst_busy | rd_rst_busy)
wr_pkt_count <= #`TCQ 0;
else if (wr_eop)
wr_pkt_count <= #`TCQ wr_pkt_count + 1;
end
end endgenerate // gpkt_fifo_fwft
assign DOUT = (C_FIFO_TYPE != 1) ? dout_fwft : dout_p0_out;
assign EMPTY = (C_FIFO_TYPE != 1) ? empty_fwft : empty_p0_out;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 1) begin // grss_pkt_cnt
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
rd_pkt_count <= 0;
rd_pkt_count_plus1 <= 1;
end else if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
rd_pkt_count <= #`TCQ 0;
rd_pkt_count_plus1 <= #`TCQ 1;
end else if (stage2_reg_en_i && stage1_eop) begin
rd_pkt_count <= #`TCQ rd_pkt_count + 1;
rd_pkt_count_plus1 <= #`TCQ rd_pkt_count_plus1 + 1;
end
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (SRST | wr_rst_busy | rd_rst_busy) begin
ram_pkt_empty <= #`TCQ 1'b1;
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count) && wr_eop) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count_plus1 == wr_pkt_count) && ~wr_eop && ~ALMOST_FULL_FIFO_OUT && ram_rd_en_compare) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
end endgenerate //grss_pkt_cnt
localparam SYNC_STAGE_WIDTH = (C_SYNCHRONIZER_STAGE+1)*C_WR_PNTR_WIDTH;
reg [SYNC_STAGE_WIDTH-1:0] wr_pkt_count_q = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_b2g = 0;
wire [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_rd;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 0) begin // gras_pkt_cnt
// Delay the write packet count in write clock domain to accomodate the binary to gray conversion delay
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count_b2g <= 0;
else
wr_pkt_count_b2g <= #`TCQ wr_pkt_count;
end
// Synchronize the delayed write packet count in read domain, and also compensate the gray to binay conversion delay
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
wr_pkt_count_q <= 0;
else
wr_pkt_count_q <= #`TCQ {wr_pkt_count_q[SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH-1:0],wr_pkt_count_b2g};
end
always @* begin
if (stage1_eop)
rd_pkt_count <= rd_pkt_count_reg + 1;
else
rd_pkt_count <= rd_pkt_count_reg;
end
assign wr_pkt_count_rd = wr_pkt_count_q[SYNC_STAGE_WIDTH-1:SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
rd_pkt_count_reg <= 0;
else if (rd_en_fifo_in)
rd_pkt_count_reg <= #`TCQ rd_pkt_count;
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (rd_pkt_count != wr_pkt_count_rd) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count_rd) && stage2_reg_en_i) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
// Synchronize the empty in write domain
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
pkt_empty_sync <= 'b1;
else
pkt_empty_sync <= #`TCQ {pkt_empty_sync[C_SYNCHRONIZER_STAGE-2:0], empty_p0_out};
end
end endgenerate //gras_pkt_cnt
generate if (IS_FWFT == 0 || C_FIFO_TYPE == 3) begin : STD_FIFO
//***********************************************
// If NOT First-Word Fall-Through, wire the outputs
// of the internal _ss or _as FIFO directly to the
// output, and do not instantiate the preload0
// module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VALID = VALID_FIFO_OUT;
assign EMPTY = EMPTY_FIFO_OUT;
assign ALMOST_EMPTY = ALMOST_EMPTY_FIFO_OUT;
assign EMPTY_P0_IN = 0;
assign UNDERFLOW = UNDERFLOW_FIFO_OUT;
assign DATA_COUNT = DATA_COUNT_FIFO_OUT;
assign SBITERR = sbiterr_fifo_out;
assign DBITERR = dbiterr_fifo_out;
end endgenerate // STD_FIFO
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 1) begin : NO_PKT_FIFO
assign empty_p0_out = empty_fwft;
assign SBITERR = sbiterr_fwft;
assign DBITERR = dbiterr_fwft;
assign DOUT = dout_fwft;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
end endgenerate // NO_PKT_FIFO
//***********************************************
// Connect user flags to internal signals
//***********************************************
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//RD_DATA_COUNT is 0 when EMPTY and 1 when ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block3
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : RD_DATA_COUNT_FIFO_OUT);
end //block_ic
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block30
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : RD_DATA_COUNT_FIFO_OUT);
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block30_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : (RD_DATA_COUNT_FIFO_OUT));
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30_both
endgenerate
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block3_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : (RD_DATA_COUNT_FIFO_OUT));
end //block_ic_both
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3_both
endgenerate
//If we are not using extra logic for the FWFT data count,
//then connect RD_DATA_COUNT to the RD_DATA_COUNT from the
//internal FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==0 ) begin : block31
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Always connect WR_DATA_COUNT to the WR_DATA_COUNT from the internal
//FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==1) begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
else begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Connect other flags to the internal FIFO instance
assign FULL = FULL_FIFO_OUT;
assign ALMOST_FULL = ALMOST_FULL_FIFO_OUT;
assign WR_ACK = WR_ACK_FIFO_OUT;
assign OVERFLOW = OVERFLOW_FIFO_OUT;
assign PROG_FULL = PROG_FULL_FIFO_OUT;
assign PROG_EMPTY = PROG_EMPTY_FIFO_OUT;
/**************************************************************************
* find_log2
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// if an asynchronous FIFO has been selected, display a message that the FIFO
// will not be cycle-accurate in simulation
initial begin
if (C_IMPLEMENTATION_TYPE == 2) begin
$display("WARNING: Behavioral models for independent clock FIFO configurations do not model synchronization delays. The behavioral models are functionally correct, and will represent the behavior of the configured FIFO. See the FIFO Generator User Guide for more information.");
end else if (C_MEMORY_TYPE == 4) begin
$display("FAILURE : Behavioral models do not support built-in FIFO configurations. Please use post-synthesis or post-implement simulation in Vivado.");
$finish;
end
if (C_WR_PNTR_WIDTH != find_log2(C_WR_DEPTH)) begin
$display("FAILURE : C_WR_PNTR_WIDTH is not log2 of C_WR_DEPTH.");
$finish;
end
if (C_RD_PNTR_WIDTH != find_log2(C_RD_DEPTH)) begin
$display("FAILURE : C_RD_PNTR_WIDTH is not log2 of C_RD_DEPTH.");
$finish;
end
if (C_USE_ECC == 1) begin
if (C_DIN_WIDTH != C_DOUT_WIDTH) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be equal for ECC configuration.");
$finish;
end
if (C_DIN_WIDTH == 1 && C_ERROR_INJECTION_TYPE > 1) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be > 1 for double bit error injection.");
$finish;
end
end
end //initial
/**************************************************************************
* Internal reset logic
**************************************************************************/
assign wr_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? wr_rst_reg : 0;
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? rd_rst_reg : 0;
assign rst_i = C_HAS_RST ? rst_reg : 0;
wire rst_2_sync;
wire rst_2_sync_safety = (C_ENABLE_RST_SYNC == 1) ? rst_delayed : RD_RST;
wire clk_2_sync = (C_COMMON_CLOCK == 1) ? CLK : WR_CLK;
wire clk_2_sync_safety = (C_COMMON_CLOCK == 1) ? CLK : RD_CLK;
localparam RST_SYNC_STAGES = (C_EN_SAFETY_CKT == 0) ? C_SYNCHRONIZER_STAGE :
(C_COMMON_CLOCK == 1) ? 3 : C_SYNCHRONIZER_STAGE+2;
reg [RST_SYNC_STAGES-1:0] wrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] arst_sync_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_wr = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_ext = {RST_SYNC_STAGES{1'b0}};
reg [1:0] wrst_cc = {2{1'b0}};
reg [1:0] rrst_cc = {2{1'b0}};
generate
if (C_EN_SAFETY_CKT == 1 && C_INTERFACE_TYPE == 0) begin : grst_safety_ckt
reg[1:0] rst_d1_safety =1;
reg[1:0] rst_d2_safety =1;
reg[1:0] rst_d3_safety =1;
reg[1:0] rst_d4_safety =1;
reg[1:0] rst_d5_safety =1;
reg[1:0] rst_d6_safety =1;
reg[1:0] rst_d7_safety =1;
always@(posedge rst_2_sync_safety or posedge clk_2_sync_safety) begin : prst
if (rst_2_sync_safety == 1'b1) begin
rst_d1_safety <= 1'b1;
rst_d2_safety <= 1'b1;
rst_d3_safety <= 1'b1;
rst_d4_safety <= 1'b1;
rst_d5_safety <= 1'b1;
rst_d6_safety <= 1'b1;
rst_d7_safety <= 1'b1;
end
else begin
rst_d1_safety <= #`TCQ 1'b0;
rst_d2_safety <= #`TCQ rst_d1_safety;
rst_d3_safety <= #`TCQ rst_d2_safety;
rst_d4_safety <= #`TCQ rst_d3_safety;
rst_d5_safety <= #`TCQ rst_d4_safety;
rst_d6_safety <= #`TCQ rst_d5_safety;
rst_d7_safety <= #`TCQ rst_d6_safety;
end //if
end //prst
always@(posedge rst_d7_safety or posedge WR_EN) begin : assert_safety
if(rst_d7_safety == 1 && WR_EN == 1) begin
$display("WARNING:A write attempt has been made within the 7 clock cycles of reset de-assertion. This can lead to data discrepancy when safety circuit is enabled.");
end //if
end //always
end // grst_safety_ckt
endgenerate
// if (C_EN_SAFET_CKT == 1)
// assertion:the reset shud be atleast 3 cycles wide.
generate
reg safety_ckt_wr_rst_i = 1'b0;
if (C_ENABLE_RST_SYNC == 0) begin : gnrst_sync
always @* begin
wr_rst_reg <= wr_rst_delayed;
rd_rst_reg <= rd_rst_delayed;
rst_reg <= 1'b0;
srst_reg <= 1'b0;
end
assign rst_2_sync = wr_rst_delayed;
assign wr_rst_busy = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
// end : gnrst_sync
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 0) begin : g7s_ic_rst
reg fifo_wrst_done = 1'b0;
reg fifo_rrst_done = 1'b0;
reg sckt_wrst_i = 1'b0;
reg sckt_wrst_i_q = 1'b0;
reg rd_rst_active = 1'b0;
reg rd_rst_middle = 1'b0;
reg sckt_rd_rst_d1 = 1'b0;
reg [1:0] rst_delayed_ic_w = 2'h0;
wire rst_delayed_ic_w_i;
reg [1:0] rst_delayed_ic_r = 2'h0;
wire rst_delayed_ic_r_i;
wire arst_sync_rst;
wire fifo_rst_done;
wire fifo_rst_active;
assign wr_rst_comb = !wr_rst_asreg_d2 && wr_rst_asreg;
assign rd_rst_comb = C_EN_SAFETY_CKT ? (!rd_rst_asreg_d2 && rd_rst_asreg) || rd_rst_active : !rd_rst_asreg_d2 && rd_rst_asreg;
assign rst_2_sync = rst_delayed_ic_w_i;
assign arst_sync_rst = arst_sync_q[RST_SYNC_STAGES-1];
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | fifo_rst_active : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? safety_ckt_rd_rst : 1'b0;
assign fifo_rst_done = fifo_wrst_done & fifo_rrst_done;
assign fifo_rst_active = sckt_wrst_i | wrst_ext[RST_SYNC_STAGES-1] | rrst_wr[RST_SYNC_STAGES-1];
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_w <= 2'b11;
else
rst_delayed_ic_w <= #`TCQ {rst_delayed_ic_w[0],1'b0};
end
assign rst_delayed_ic_w_i = rst_delayed_ic_w[1];
always @(posedge RD_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_r <= 2'b11;
else
rst_delayed_ic_r <= #`TCQ {rst_delayed_ic_r[0],1'b0};
end
assign rst_delayed_ic_r_i = rst_delayed_ic_r[1];
always @(posedge WR_CLK) begin
sckt_wrst_i_q <= #`TCQ sckt_wrst_i;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ sckt_wrst_i | wr_rst_busy | sckt_wr_rst_i_q;
if (arst_sync_rst && ~fifo_rst_active)
sckt_wrst_i <= #`TCQ 1'b1;
else if (sckt_wrst_i && fifo_rst_done)
sckt_wrst_i <= #`TCQ 1'b0;
else
sckt_wrst_i <= #`TCQ sckt_wrst_i;
if (rrst_wr[RST_SYNC_STAGES-2] & ~rrst_wr[RST_SYNC_STAGES-1])
fifo_rrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_rrst_done <= #`TCQ 1'b0;
else
fifo_rrst_done <= #`TCQ fifo_rrst_done;
if (wrst_ext[RST_SYNC_STAGES-2] & ~wrst_ext[RST_SYNC_STAGES-1])
fifo_wrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_wrst_done <= #`TCQ 1'b0;
else
fifo_wrst_done <= #`TCQ fifo_wrst_done;
end
always @(posedge WR_CLK or posedge rst_delayed_ic_w_i) begin
if (rst_delayed_ic_w_i == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],wr_rst_asreg};
wrst_ext <= #`TCQ {wrst_ext[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_wr <= #`TCQ {rrst_wr[RST_SYNC_STAGES-2:0],safety_ckt_rd_rst};
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_ic_w_i};
end
assign wr_rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign wr_rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge WR_CLK or posedge wr_rst_comb) begin
if (wr_rst_comb == 1'b1) begin
wr_rst_reg <= 1'b1;
end else begin
wr_rst_reg <= #`TCQ 1'b0;
end
end
always @(posedge RD_CLK or posedge rst_delayed_ic_r_i) begin
if (rst_delayed_ic_r_i == 1'b1) begin
rd_rst_asreg <= 1'b1;
end else begin
if (rd_rst_asreg_d1 == 1'b1) begin
rd_rst_asreg <= #`TCQ 1'b0;
end else begin
rd_rst_asreg <= #`TCQ rd_rst_asreg;
end
end
end
always @(posedge RD_CLK) begin
rrst_reg <= #`TCQ {rrst_reg[RST_SYNC_STAGES-2:0],rd_rst_asreg};
rrst_q <= #`TCQ {rrst_q[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_cc <= #`TCQ {rrst_cc[0],rd_rst_asreg_d2};
sckt_rd_rst_d1 <= #`TCQ safety_ckt_rd_rst;
if (!rd_rst_middle && rrst_reg[1] && !rrst_reg[2]) begin
rd_rst_active <= #`TCQ 1'b1;
rd_rst_middle <= #`TCQ 1'b1;
end else if (safety_ckt_rd_rst)
rd_rst_active <= #`TCQ 1'b0;
else if (sckt_rd_rst_d1 && !safety_ckt_rd_rst)
rd_rst_middle <= #`TCQ 1'b0;
end
assign rd_rst_asreg_d1 = rrst_reg[RST_SYNC_STAGES-2];
assign rd_rst_asreg_d2 = C_EN_SAFETY_CKT ? rrst_reg[RST_SYNC_STAGES-1] : rrst_reg[1];
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rrst_q[2] : 1'b0;
always @(posedge RD_CLK or posedge rd_rst_comb) begin
if (rd_rst_comb == 1'b1) begin
rd_rst_reg <= 1'b1;
end else begin
rd_rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_ic_rst
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 1) begin : g7s_cc_rst
reg [1:0] rst_delayed_cc = 2'h0;
wire rst_delayed_cc_i;
assign rst_comb = !rst_asreg_d2 && rst_asreg;
assign rst_2_sync = rst_delayed_cc_i;
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | wrst_cc[1] : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? arst_sync_q[1] | arst_sync_q[RST_SYNC_STAGES-1] | wrst_cc[1] : 1'b0;
always @(posedge CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1)
rst_delayed_cc <= 2'b11;
else
rst_delayed_cc <= #`TCQ {rst_delayed_cc,1'b0};
end
assign rst_delayed_cc_i = rst_delayed_cc[1];
always @(posedge CLK or posedge rst_delayed_cc_i) begin
if (rst_delayed_cc_i == 1'b1) begin
rst_asreg <= 1'b1;
end else begin
if (rst_asreg_d1 == 1'b1) begin
rst_asreg <= #`TCQ 1'b0;
end else begin
rst_asreg <= #`TCQ rst_asreg;
end
end
end
always @(posedge CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],rst_asreg};
wrst_cc <= #`TCQ {wrst_cc[0],arst_sync_q[RST_SYNC_STAGES-1]};
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ wrst_cc[1] | wr_rst_busy | sckt_wr_rst_i_q;
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_cc_i};
end
assign rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge CLK or posedge rst_comb) begin
if (rst_comb == 1'b1) begin
rst_reg <= 1'b1;
end else begin
rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_cc_rst
end else if (IS_8SERIES == 1 && C_HAS_SRST == 1 && C_COMMON_CLOCK == 1) begin : g8s_cc_rst
assign wr_rst_busy = (C_MEMORY_TYPE != 4) ? rst_reg : rst_active_i;
assign rd_rst_busy = rst_reg;
assign rst_2_sync = srst_delayed;
always @* rst_full_ff_i <= rst_reg;
always @* rst_full_gen_i <= C_FULL_FLAGS_RST_VAL == 1 ? rst_active_i : 0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
always @(posedge CLK) begin
rst_delayed_d1 <= #`TCQ srst_delayed;
rst_delayed_d2 <= #`TCQ rst_delayed_d1;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
if (rst_reg || rst_delayed_d2) begin
rst_active_i <= #`TCQ 1'b1;
end else begin
rst_active_i <= #`TCQ rst_reg;
end
end
always @(posedge CLK) begin
if (~rst_reg && srst_delayed) begin
rst_reg <= #`TCQ 1'b1;
end else if (rst_reg) begin
rst_reg <= #`TCQ 1'b0;
end else begin
rst_reg <= #`TCQ rst_reg;
end
end
// end : g8s_cc_rst
end else begin
assign wr_rst_busy = 1'b0;
assign rd_rst_busy = 1'b0;
assign safety_ckt_wr_rst = 1'b0;
assign safety_ckt_rd_rst = 1'b0;
end
endgenerate
generate
if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 1) begin : grstd1
// RST_FULL_GEN replaces the reset falling edge detection used to de-assert
// FULL, ALMOST_FULL & PROG_FULL flags if C_FULL_FLAGS_RST_VAL = 1.
// RST_FULL_FF goes to the reset pin of the final flop of FULL, ALMOST_FULL &
// PROG_FULL
reg rst_d1 = 1'b0;
reg rst_d2 = 1'b0;
reg rst_d3 = 1'b0;
reg rst_d4 = 1'b0;
reg rst_d5 = 1'b0;
always @ (posedge rst_2_sync or posedge clk_2_sync) begin
if (rst_2_sync) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
rst_d3 <= 1'b1;
rst_d4 <= 1'b1;
end else begin
if (srst_delayed) begin
rst_d1 <= #`TCQ 1'b1;
rst_d2 <= #`TCQ 1'b1;
rst_d3 <= #`TCQ 1'b1;
rst_d4 <= #`TCQ 1'b1;
end else begin
rst_d1 <= #`TCQ wr_rst_busy;
rst_d2 <= #`TCQ rst_d1;
rst_d3 <= #`TCQ rst_d2 | safety_ckt_wr_rst;
rst_d4 <= #`TCQ rst_d3;
end
end
end
always @* rst_full_ff_i <= (C_HAS_SRST == 0) ? rst_d2 : 1'b0 ;
always @* rst_full_gen_i <= rst_d3;
end else if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 0) begin : gnrst_full
always @* rst_full_ff_i <= (C_COMMON_CLOCK == 0) ? wr_rst_i : rst_i;
end
endgenerate // grstd1
endmodule //fifo_generator_v13_1_3_conv_ver
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0;
else
DOUT <= #`TCQ DIN;
end
endmodule // fifo_generator_v13_1_3_sync_stage
/*******************************************************************************
* Declaration of Independent-Clocks FIFO Module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_as
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input SAFETY_CKT_WR_RST,
input SAFETY_CKT_RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_CLK,
input RD_EN,
input RD_EN_USER,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input USER_EMPTY_FB,
input fab_read_data_valid_i,
input read_data_valid_i,
input ram_valid_i,
output reg ALMOST_EMPTY = 1'b1,
output reg ALMOST_FULL = C_FULL_FLAGS_RST_VAL,
output [C_DOUT_WIDTH-1:0] DOUT,
output reg EMPTY = 1'b1,
output reg EMPTY_FB = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL,
output OVERFLOW,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output UNDERFLOW,
output WR_ACK,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC_1 && SYMMETRIC_PORT && ERR_INJECTION;
// Array that holds the error injection type (single/double bit error) on
// a specific write operation, which is returned on read to corrupt the
// output data.
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
//The amount of data stored in the FIFO at any time is given
// by num_wr_bits (in the WR_CLK domain) and num_rd_bits (in the RD_CLK
// domain.
//num_wr_bits is calculated by considering the total words in the FIFO,
// and the state of the read pointer (which may not have yet crossed clock
// domains.)
//num_rd_bits is calculated by considering the total words in the FIFO,
// and the state of the write pointer (which may not have yet crossed clock
// domains.)
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
wire wr_rst_i = WR_RST;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire rd_rst_i = RD_RST;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
// Delayed ram_rd_en is needed only for STD Embedded register option
generate
if (C_PRELOAD_LATENCY == 2) begin : grd_d
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
end
endgenerate
generate
if (C_PRELOAD_LATENCY == 2 && C_USE_EMBEDDED_REG == 3) begin : grd_d1
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
endgenerate
// Write pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : rdg // Read depth greater than write depth
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1:0] = 0;
end else begin : rdl // Read depth lesser than or equal to write depth
assign adj_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
endgenerate
// Generate Empty and Almost Empty
// ram_rd_en used to determine EMPTY should depend on the EMPTY.
assign ram_rd_en = RD_EN & !EMPTY;
assign empty_int = ((adj_wr_pntr_rd == rd_pntr) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+1'h1))));
assign almost_empty_int = ((adj_wr_pntr_rd == (rd_pntr+1'h1)) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+2'h2))));
// Register Empty and Almost Empty
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin
EMPTY <= 1'b1;
ALMOST_EMPTY <= 1'b1;
rd_data_count_int <= {C_RD_PNTR_WIDTH{1'b0}};
end else begin
rd_data_count_int <= #`TCQ {(adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:0] - rd_pntr[C_RD_PNTR_WIDTH-1:0]), 1'b0};
if (empty_int)
EMPTY <= #`TCQ 1'b1;
else
EMPTY <= #`TCQ 1'b0;
if (!EMPTY) begin
if (almost_empty_int)
ALMOST_EMPTY <= #`TCQ 1'b1;
else
ALMOST_EMPTY <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (SAFETY_CKT_RD_RST && C_EN_SAFETY_CKT)
EMPTY_FB <= #`TCQ 1'b1;
else if (empty_int)
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ 1'b0;
end // rd_rst_i
end // always
// Read pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wdg // Write depth greater than read depth
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1:0] = 0;
end else begin : wdl // Write depth lesser than or equal to read depth
assign adj_rd_pntr_wr = rd_pntr_wr[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end
endgenerate
// Generate FULL and ALMOST_FULL
// ram_wr_en used to determine FULL should depend on the FULL.
assign ram_wr_en = WR_EN & !FULL;
assign full_int = ((adj_rd_pntr_wr == (wr_pntr+1'h1)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+2'h2))));
assign almost_full_int = ((adj_rd_pntr_wr == (wr_pntr+2'h2)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+3'h3))));
// Register FULL and ALMOST_FULL Empty
always @ (posedge WR_CLK or posedge RST_FULL_FF)
begin
if (RST_FULL_FF) begin
FULL <= C_FULL_FLAGS_RST_VAL;
ALMOST_FULL <= C_FULL_FLAGS_RST_VAL;
end else begin
if (full_int) begin
FULL <= #`TCQ 1'b1;
end else begin
FULL <= #`TCQ 1'b0;
end
if (RST_FULL_GEN) begin
ALMOST_FULL <= #`TCQ 1'b0;
end else if (!FULL) begin
if (almost_full_int)
ALMOST_FULL <= #`TCQ 1'b1;
else
ALMOST_FULL <= #`TCQ 1'b0;
end
end // wr_rst_i
end // always
always @ (posedge WR_CLK or posedge wr_rst_i)
begin
if (wr_rst_i) begin
wr_data_count_int <= {C_WR_DATA_COUNT_WIDTH{1'b0}};
end else begin
wr_data_count_int <= #`TCQ {(wr_pntr[C_WR_PNTR_WIDTH-1:0] - adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:0]), 1'b0};
end // wr_rst_i
end // always
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
stage1_valid <= 0;
stage2_valid <= 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//Pointers passed into opposite clock domain
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_EMPTY.
wire [31:0] num_read_words_pe =
num_rd_bits/(C_DOUT_WIDTH/C_DEPTH_RATIO_WR);
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_FULL.
wire [31:0] num_write_words_pf =
num_wr_bits/(C_DIN_WIDTH/C_DEPTH_RATIO_RD);
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/***************************************************************************
* Internal registers and wires
**************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire valid_i;
wire valid_out1;
wire valid_out2;
wire valid_out;
wire underflow_i;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
reg valid_d1 = 0;
reg valid_d2 = 0;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/****************************************************************************
* Function Declarations
***************************************************************************/
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
/***********************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_d2 = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_CLK;
wire RD_EN;
wire RST;
wire WR_CLK;
wire WR_EN;
*/
//***************************************************************************
// Dout may change behavior based on latency
//***************************************************************************
assign ideal_dout_out[C_DOUT_WIDTH-1:0] = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) )?
ideal_dout_d1: ideal_dout;
assign DOUT[C_DOUT_WIDTH-1:0] = ideal_dout_out;
//***************************************************************************
// Assign SBITERR and DBITERR based on latency
//***************************************************************************
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY == 2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) ) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY==2 && (C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
//***************************************************************************
// Safety-ckt logic with embedded reg/fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
// if (C_HAS_VALID == 1) begin
// assign valid_out = valid_d1;
// end
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK)
begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else begin
if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end
end
endgenerate
//***************************************************************************
// Safety-ckt logic with embedded reg + fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK) begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else begin
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end
endgenerate
//***************************************************************************
// Overflow may be active-low
//***************************************************************************
generate
if (C_HAS_OVERFLOW==1) begin : blockOF1
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end
endgenerate
assign PROG_EMPTY = ideal_prog_empty;
assign PROG_FULL = ideal_prog_full;
//***************************************************************************
// Valid may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_VALID==1) begin : blockVL1
assign valid_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out1 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG < 3)?
valid_d1: valid_i;
assign valid_out2 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG == 3)?
valid_d2: valid_i;
assign valid_out = (C_USE_EMBEDDED_REG == 3) ? valid_out2 : valid_out1;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end
endgenerate
//***************************************************************************
// Underflow may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_UNDERFLOW==1) begin : blockUF1
assign underflow_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & EMPTY) : ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end
endgenerate
//***************************************************************************
// Write acknowledge may be active low
//***************************************************************************
generate
if (C_HAS_WR_ACK==1) begin : blockWK1
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : wdc_fwft_ext
reg [C_PNTR_WIDTH-1:0] adjusted_wr_pntr = 0;
reg [C_PNTR_WIDTH-1:0] adjusted_rd_pntr = 0;
wire [C_PNTR_WIDTH-1:0] diff_wr_rd_tmp;
wire [C_PNTR_WIDTH:0] diff_wr_rd;
reg [C_PNTR_WIDTH:0] wr_data_count_i = 0;
always @* begin
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = 0;
adjusted_rd_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
end else if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin
adjusted_rd_pntr = rd_pntr_wr;
adjusted_wr_pntr = 0;
adjusted_wr_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
end else begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = rd_pntr_wr;
end
end // always @*
assign diff_wr_rd_tmp = adjusted_wr_pntr - adjusted_rd_pntr;
assign diff_wr_rd = {1'b0,diff_wr_rd_tmp};
always @ (posedge wr_rst_i or posedge WR_CLK)
begin
if (wr_rst_i)
wr_data_count_i <= 0;
else
wr_data_count_i <= #`TCQ diff_wr_rd + EXTRA_WORDS_DC;
end // always @ (posedge WR_CLK or posedge WR_CLK)
always @* begin
if (C_WR_PNTR_WIDTH >= C_RD_PNTR_WIDTH)
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:0];
else
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end // always @*
end // wdc_fwft_ext
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
reg [C_RD_PNTR_WIDTH:0] rdc_fwft_ext_as = 0;
generate if (C_USE_EMBEDDED_REG < 3) begin: rdc_fwft_ext_both
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= 0;
end else begin
if (!stage2_valid)
rdc_fwft_ext_as <= #`TCQ 0;
else if (!stage1_valid && stage2_valid)
rdc_fwft_ext_as <= #`TCQ 1;
else
rdc_fwft_ext_as <= #`TCQ diff_rd_wr + 2'h2;
end
end // always @ (posedge WR_CLK or posedge WR_CLK)
end // rdc_fwft_ext
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3) begin
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr_1;
// assign diff_rd_wr_1 = diff_rd_wr +2'h2;
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= #`TCQ 0;
end else begin
//if (fab_read_data_valid_i == 1'b0 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b0;
//else if (fab_read_data_valid_i == 1'b1 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b1;
//else
rdc_fwft_ext_as <= diff_rd_wr + 2'h2 ;
end
end
end
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = C_USE_FWFT_DATA_COUNT ?
rdc_fwft_ext_as[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH] :
rd_data_count_int[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = (C_USE_FWFT_DATA_COUNT == 1) ?
wdc_fwft_ext_as[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] :
wr_data_count_int[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate
if (C_HAS_VALID==1) begin : blockVL2
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_d2 <= 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
valid_d2 <= #`TCQ valid_d1;
end
// if (C_USE_EMBEDDED_REG == 3 && (C_EN_SAFETY_CKT == 0 || C_EN_SAFETY_CKT == 1 ) begin
// valid_d2 <= #`TCQ valid_d1;
// end
end
end
endgenerate
//Capture delayed version of dout
/**************************************************************************
*embedded/fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG < 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0)
err_type_d1 <= #`TCQ 0;
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
endgenerate
/**************************************************************************
*embedded + fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG == 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate
if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge WR_CLK) begin
ideal_overflow <= #`TCQ WR_EN & FULL;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge WR_CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (FULL | wr_rst_i);
ideal_overflow <= #`TCQ WR_EN & (FULL );
end
end
endgenerate
generate
if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ EMPTY & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ (EMPTY) & RD_EN;
//ideal_underflow <= #`TCQ (rd_rst_i | EMPTY) & RD_EN;
end
end
endgenerate
/**************************************************************************
* Write/Read Pointer Synchronization
**************************************************************************/
localparam NO_OF_SYNC_STAGE_INC_G2B = C_SYNCHRONIZER_STAGE + 1;
wire [C_WR_PNTR_WIDTH-1:0] wr_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
genvar gss;
generate for (gss = 1; gss <= NO_OF_SYNC_STAGE_INC_G2B; gss = gss + 1) begin : Sync_stage_inst
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_WR_PNTR_WIDTH)
)
rd_stg_inst
(
.RST (rd_rst_i),
.CLK (RD_CLK),
.DIN (wr_pntr_sync_stgs[gss-1]),
.DOUT (wr_pntr_sync_stgs[gss])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_RD_PNTR_WIDTH)
)
wr_stg_inst
(
.RST (wr_rst_i),
.CLK (WR_CLK),
.DIN (rd_pntr_sync_stgs[gss-1]),
.DOUT (rd_pntr_sync_stgs[gss])
);
end endgenerate // Sync_stage_inst
assign wr_pntr_sync_stgs[0] = wr_pntr_rd1;
assign rd_pntr_sync_stgs[0] = rd_pntr_wr1;
always@* begin
wr_pntr_rd <= wr_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
rd_pntr_wr <= rd_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
end
/**************************************************************************
* Write Domain Logic
**************************************************************************/
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_wp
if (wr_rst_i == 1'b1 && C_EN_SAFETY_CKT == 0)
wr_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_WR_RST == 1'b1)
wr_pntr <= #`TCQ 0;
end
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (wr_rst_i == 1'b1) begin
num_wr_bits <= 0;
next_num_wr_bits = 0;
wr_ptr <= C_WR_DEPTH - 1;
rd_ptr_wrclk <= C_RD_DEPTH - 1;
ideal_wr_ack <= 0;
ideal_wr_count <= 0;
tmp_wr_listsize = 0;
rd_ptr_wrclk_next <= 0;
wr_pntr_rd1 <= 0;
end else begin //wr_rst_i==0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
//If this is a write, handle the write by adding the value
// to the linked list, and updating all outputs appropriately
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD
>= C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full, but reporting full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//With DEPTH-1 words in the FIFO, it is almost_full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is completely empty, but it is
// reporting FULL for some reason (like reset)
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <=
C_FIFO_WR_DEPTH-2) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//FIFO is really not close to full, so change flag status.
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end //(tmp_wr_listsize == 0)
end else begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD >=
C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//This write is CAUSING the FIFO to go full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is 2 from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Still 2 from full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is not close to being full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //wr_rst_i==0
end // gen_fifo_w
/***************************************************************************
* Programmable FULL flags
***************************************************************************/
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_assert_val;
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_negate_val;
generate if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin : FWFT
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_DC;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_DC;
end else begin // STD
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL;
end endgenerate
always @(posedge WR_CLK or posedge wr_rst_i) begin
if (wr_rst_i == 1'b1) begin
diff_pntr <= 0;
end else begin
if (ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr + 2'h1);
else if (!ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr);
end
end
always @(posedge WR_CLK or posedge RST_FULL_FF) begin : gen_pf
if (RST_FULL_FF == 1'b1) begin
ideal_prog_full <= C_FULL_FLAGS_RST_VAL;
end else begin
if (RST_FULL_GEN)
ideal_prog_full <= #`TCQ 0;
//Single Programmable Full Constant Threshold
else if (C_PROG_FULL_TYPE == 1) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Constant Thresholds
end else if (C_PROG_FULL_TYPE == 2) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < pf_thr_negate_val)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Single Programmable Full Threshold Input
end else if (C_PROG_FULL_TYPE == 3) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Threshold Inputs
end else if (C_PROG_FULL_TYPE == 4) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH_ASSERT - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < (PROG_FULL_THRESH_NEGATE - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH_ASSERT)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < PROG_FULL_THRESH_NEGATE)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
end // C_PROG_FULL_TYPE
end //wr_rst_i==0
end //
/**************************************************************************
* Read Domain Logic
**************************************************************************/
/*********************************************************
* Programmable EMPTY flags
*********************************************************/
//Determine the Assert and Negate thresholds for Programmable Empty
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_assert_val;
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_negate_val;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_rd = 0;
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_pe
if (rd_rst_i) begin
diff_pntr_rd <= 0;
ideal_prog_empty <= 1'b1;
end else begin
if (ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr) - 1'h1;
else if (!ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr);
else
diff_pntr_rd <= #`TCQ diff_pntr_rd;
if (C_PROG_EMPTY_TYPE == 1) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 2) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 3) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 4) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end //C_PROG_EMPTY_TYPE
end
end // gen_pe
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH - 2'h2 : PROG_EMPTY_THRESH;
end endgenerate // single_pe_thr_input
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_ASSERT - 2'h2 : PROG_EMPTY_THRESH_ASSERT;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_NEGATE - 2'h2 : PROG_EMPTY_THRESH_NEGATE;
end endgenerate // multiple_pe_thr_input
generate if (C_PROG_EMPTY_TYPE < 3) begin : single_multiple_pe_thr_const
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2'h2 : C_PROG_EMPTY_THRESH_ASSERT_VAL;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2'h2 : C_PROG_EMPTY_THRESH_NEGATE_VAL;
end endgenerate // single_multiple_pe_thr_const
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_rp
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
rd_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_RD_RST == 1'b1)
rd_pntr <= #`TCQ 0;
end
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_r_as
/****** Reset fifo (case 1)***************************************/
if (rd_rst_i) begin
num_rd_bits <= 0;
next_num_rd_bits = 0;
rd_ptr <= C_RD_DEPTH -1;
rd_pntr_wr1 <= 0;
wr_ptr_rdclk <= C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_MEMORY_TYPE == 2 && C_USE_DOUT_RST == 1)
ideal_dout <= dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= 1'b0;
ideal_rd_count <= 0;
end else begin //rd_rst_i==0
rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
/*****************************************************************/
// Read Operation - Read Latency 1
/*****************************************************************/
if (C_PRELOAD_LATENCY==1 || C_PRELOAD_LATENCY==2) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
//If the FIFO is one from empty, but it is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is two from empty, and is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH))
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end // else: if(ideal_empty == 1'b1)
else //if (ideal_empty == 1'b0)
begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == C_FIFO_RD_DEPTH)
//If the FIFO is not close to being empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
//If the FIFO is two from empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is one from empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR == 1))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is completely empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end //(RD_EN == 1'b1)
else //if (RD_EN == 1'b0)
begin
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
/*****************************************************************/
// Read Operation - Read Latency 0
/*****************************************************************/
end else if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty, but it is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty, and is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH)) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end else begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to being empty
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH)) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is completely empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end else begin//(RD_EN == 1'b0)
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
end //if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0)
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //rd_rst_i==0
end //always gen_fifo_r_as
endmodule // fifo_generator_v13_1_3_bhv_ver_as
/*******************************************************************************
* Declaration of Low Latency Asynchronous FIFO
******************************************************************************/
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_USE_DOUT_RST = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_FIFO_TYPE = 0
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input [C_DIN_WIDTH-1:0] DIN,
input RD_CLK,
input RD_EN,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
output reg [C_DOUT_WIDTH-1:0] DOUT = 0,
output reg EMPTY = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL
);
//-----------------------------------------------------------------------------
// Low Latency Asynchronous FIFO
//-----------------------------------------------------------------------------
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
integer i;
initial begin
for (i = 0; i < C_WR_DEPTH; i = i + 1)
memory[i] = 0;
end
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_ll_afifo = 0;
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo_q = 0;
reg ll_afifo_full = 1'b0;
reg ll_afifo_empty = 1'b1;
wire write_allow;
wire read_allow;
assign write_allow = WR_EN & ~ll_afifo_full;
assign read_allow = RD_EN & ~ll_afifo_empty;
//-----------------------------------------------------------------------------
// Write Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
wr_pntr_ll_afifo <= 0;
else if (write_allow)
wr_pntr_ll_afifo <= #`TCQ wr_pntr_ll_afifo + 1;
end
//-----------------------------------------------------------------------------
// Read Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
rd_pntr_ll_afifo_q <= 0;
else
rd_pntr_ll_afifo_q <= #`TCQ rd_pntr_ll_afifo;
end
assign rd_pntr_ll_afifo = read_allow ? rd_pntr_ll_afifo_q + 1 : rd_pntr_ll_afifo_q;
//-----------------------------------------------------------------------------
// Fill the Memory
//-----------------------------------------------------------------------------
always @(posedge WR_CLK) begin
if (write_allow)
memory[wr_pntr_ll_afifo] <= #`TCQ DIN;
end
//-----------------------------------------------------------------------------
// Generate DOUT
//-----------------------------------------------------------------------------
always @(posedge RD_CLK) begin
DOUT <= #`TCQ memory[rd_pntr_ll_afifo];
end
//-----------------------------------------------------------------------------
// Generate EMPTY
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
ll_afifo_empty <= 1'b1;
else
ll_afifo_empty <= ((wr_pntr_ll_afifo == rd_pntr_ll_afifo_q) |
(read_allow & (wr_pntr_ll_afifo == (rd_pntr_ll_afifo_q + 2'h1))));
end
//-----------------------------------------------------------------------------
// Generate FULL
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
ll_afifo_full <= 1'b1;
else
ll_afifo_full <= ((rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h1)) |
(write_allow & (rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h2))));
end
always @* begin
FULL <= ll_afifo_full;
EMPTY <= ll_afifo_empty;
end
endmodule // fifo_generator_v13_1_3_beh_ver_ll_afifo
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* Declare user parameters and their defaults
*************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
/**************************************************************************
* Declare Input and Output Ports
*************************************************************************/
(
//Inputs
input SAFETY_CKT_WR_RST,
input CLK,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_EN,
input RD_EN_USER,
input USER_EMPTY_FB,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input SRST,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input WR_RST_BUSY,
input RD_RST_BUSY,
//Outputs
output ALMOST_EMPTY,
output ALMOST_FULL,
output reg [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT = 0,
output [C_DOUT_WIDTH-1:0] DOUT,
output EMPTY,
output reg EMPTY_FB = 1'b1,
output FULL,
output OVERFLOW,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output UNDERFLOW,
output WR_ACK,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
wire [C_RD_PNTR_WIDTH:0] rd_data_count_i_ss;
wire [C_WR_PNTR_WIDTH:0] wr_data_count_i_ss;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
//localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
//localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
localparam C_GRTR_PNTR_WIDTH = (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH ;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
wire [C_WR_PNTR_WIDTH:0] EXTRA_WORDS_PF = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//wire [C_RD_PNTR_WIDTH:0] EXTRA_WORDS_PE = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam EXTRA_WORDS_PF_PARAM = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//localparam EXTRA_WORDS_PE_PARAM = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
//The reset value assignments for FULL, ALMOST_FULL, and PROG_FULL are not
//changed for v3.2(IP2_Im). When the core has Sync Reset, C_HAS_SRST=1 and C_HAS_RST=0.
// Therefore, during SRST, all the FULL flags reset to 0.
localparam C_HAS_FAST_FIFO = 0;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH;
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC && SYMMETRIC_PORT && ERR_INJECTION;
localparam C_DATA_WIDTH = (ENABLE_ERR_INJECTION == 1) ? (C_DIN_WIDTH+2) : C_DIN_WIDTH;
localparam IS_ASYMMETRY = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 0 : 1;
localparam LESSER_WIDTH = (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
localparam [C_RD_PNTR_WIDTH-1 : 0] DIFF_MAX_RD = {C_RD_PNTR_WIDTH{1'b1}};
localparam [C_WR_PNTR_WIDTH-1 : 0] DIFF_MAX_WR = {C_WR_PNTR_WIDTH{1'b1}};
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
/**************************************************************************
* Internal Registers and wires
*************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire underflow_i;
wire valid_i;
wire valid_out;
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_reg = 1'b0;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
wire srst_rrst_busy;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire fwft_enabled;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg full_i = C_FULL_FLAGS_RST_VAL;
reg full_i_temp = 0;
reg empty_i = 1;
reg almost_full_i = 0;
reg almost_empty_i = 1;
reg prog_full_i = 0;
reg prog_empty_i = 1;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] diff_count = 0;
reg write_allow_q = 0;
reg read_allow_q = 0;
reg valid_d1 = 0;
reg valid_both = 0;
reg valid_d2 = 0;
wire rst_i;
wire srst_i;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
/****************************************************************************
* Function Declarations
***************************************************************************/
/****************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***************************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 ) begin
case (def_data[7:0])
8'b00000000 : begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default : begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1) begin
if ((index*4)+j < C_DOUT_WIDTH) begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
//reg valid_d1 = 0;
//user specified value for reseting the size of the fifo
//reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_dout_both = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_both = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_EN;
wire RST;
wire WR_EN;
*/
// Assign ALMOST_EPMTY
generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae
assign ALMOST_EMPTY = almost_empty_i;
end else begin : gnae
assign ALMOST_EMPTY = 0;
end endgenerate // gae
// Assign ALMOST_FULL
generate if (C_HAS_ALMOST_FULL==1) begin : gaf
assign ALMOST_FULL = almost_full_i;
end else begin : gnaf
assign ALMOST_FULL = 0;
end endgenerate // gaf
// Dout may change behavior based on latency
localparam C_FWFT_ENABLED = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign fwft_enabled = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign ideal_dout_out= ((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1))?
ideal_dout_d1: ideal_dout;
assign DOUT = ideal_dout_out;
// Assign SBITERR and DBITERR based on latency
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
assign EMPTY = empty_i;
assign FULL = full_i;
//saftey_ckt with one register
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && (C_USE_EMBEDDED_REG == 1 || C_USE_EMBEDDED_REG == 2 )) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK)
begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK)
begin
if( rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end
else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
valid_d1 <= #`TCQ valid_i;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end //if
endgenerate
//safety ckt with both registers
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK) begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end //if
endgenerate
//Overflow may be active-low
generate if (C_HAS_OVERFLOW==1) begin : gof
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end else begin : gnof
assign OVERFLOW = 0;
end endgenerate // gof
assign PROG_EMPTY = prog_empty_i;
assign PROG_FULL = prog_full_i;
//Valid may change behavior based on latency or active-low
generate if (C_HAS_VALID==1) begin : gvalid
assign valid_i = (C_PRELOAD_LATENCY == 0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out = (C_PRELOAD_LATENCY == 2 && C_MEMORY_TYPE < 2) ?
valid_d1 : valid_i;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end else begin : gnvalid
assign VALID = 0;
end endgenerate // gvalid
//Trim data count differently depending on set widths
generate if (C_HAS_DATA_COUNT == 1) begin : gdc
always @* begin
diff_count <= wr_pntr - rd_pntr;
if (C_DATA_COUNT_WIDTH > C_RD_PNTR_WIDTH) begin
DATA_COUNT[C_RD_PNTR_WIDTH-1:0] <= diff_count;
DATA_COUNT[C_DATA_COUNT_WIDTH-1] <= 1'b0 ;
end else begin
DATA_COUNT <= diff_count[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH];
end
end
// end else begin : gndc
// always @* DATA_COUNT <= 0;
end endgenerate // gdc
//Underflow may change behavior based on latency or active-low
generate if (C_HAS_UNDERFLOW==1) begin : guf
assign underflow_i = ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end else begin : gnuf
assign UNDERFLOW = 0;
end endgenerate // guf
//Write acknowledge may be active low
generate if (C_HAS_WR_ACK==1) begin : gwr_ack
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end else begin : gnwr_ack
assign WR_ACK = 0;
end endgenerate // gwr_ack
/*****************************************************************************
* Internal reset logic
****************************************************************************/
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_WR_RST : C_HAS_SRST ? (SRST | WR_RST_BUSY) : 0;
assign rst_i = C_HAS_RST ? RST : 0;
assign srst_wrst_busy = srst_i;
assign srst_rrst_busy = srst_i;
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG <3)) begin : blockVL20
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG == 3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_both <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
valid_both <= #`TCQ 1'b0;
end else begin
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge CLK or posedge rst_i) begin
if (rst_i) begin
stage1_valid <= #`TCQ 0;
stage2_valid <= #`TCQ 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT ==1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = rd_data_count_i_ss[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = wr_data_count_i_ss[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] ;
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//reg ram_rd_en_d1 = 1'b0;
//Capture delayed version of dout
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG<3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
ram_rd_en_d1 <= #`TCQ 1'b0;
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
end // always
end
endgenerate
//no safety ckt with both registers
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG==3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
fab_rd_en_d1 <= #`TCQ (ram_rd_en_d1);
if (ram_rd_en_d1 ) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end // always
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge CLK) begin
ideal_overflow <= #`TCQ WR_EN & full_i;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (rst_i | full_i);
ideal_overflow <= #`TCQ WR_EN & (WR_RST_BUSY | full_i);
end
end endgenerate // blockOF20
generate if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge CLK) begin
ideal_underflow <= #`TCQ empty_i & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge CLK) begin
//ideal_underflow <= #`TCQ (rst_i | empty_i) & RD_EN;
ideal_underflow <= #`TCQ (RD_RST_BUSY | empty_i) & RD_EN;
end
end endgenerate // blockUF20
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/*************************************************************************
* Write and Read Logic
************************************************************************/
wire write_allow;
wire read_allow;
wire read_allow_dc;
wire write_only;
wire read_only;
//wire write_only_q;
reg write_only_q;
//wire read_only_q;
reg read_only_q;
reg full_reg;
reg rst_full_ff_reg1;
reg rst_full_ff_reg2;
wire ram_full_comb;
wire carry;
assign write_allow = WR_EN & ~full_i;
assign read_allow = RD_EN & ~empty_i;
assign read_allow_dc = RD_EN_USER & ~USER_EMPTY_FB;
//assign write_only = write_allow & ~read_allow;
//assign write_only_q = write_allow_q;
//assign read_only = read_allow & ~write_allow;
//assign read_only_q = read_allow_q ;
wire [C_WR_PNTR_WIDTH-1:0] diff_pntr;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_reg1 = 0;
reg [C_RD_PNTR_WIDTH:0] diff_pntr_pe_asym = 0;
wire [C_RD_PNTR_WIDTH:0] adj_wr_pntr_rd_asym ;
wire [C_RD_PNTR_WIDTH:0] rd_pntr_asym;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_pe_reg2 = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_max;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_max;
assign diff_pntr_pe_max = DIFF_MAX_RD;
assign diff_pntr_max = DIFF_MAX_WR;
generate if (IS_ASYMMETRY == 0) begin : diff_pntr_sym
assign write_only = write_allow & ~read_allow;
assign read_only = read_allow & ~write_allow;
end endgenerate
generate if ( IS_ASYMMETRY == 1 && C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : wr_grt_rd
assign read_only = read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]) & ~write_allow;
assign write_only = write_allow & ~(read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (IS_ASYMMETRY ==1 && C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : rd_grt_wr
assign read_only = read_allow & ~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
assign write_only = write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]) & ~read_allow;
end endgenerate
//-----------------------------------------------------------------------------
// Write and Read pointer generation
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
wr_pntr <= 0;
rd_pntr <= 0;
end else begin
if (srst_i) begin
wr_pntr <= #`TCQ 0;
rd_pntr <= #`TCQ 0;
end else begin
if (write_allow) wr_pntr <= #`TCQ wr_pntr + 1;
if (read_allow) rd_pntr <= #`TCQ rd_pntr + 1;
end
end
end
generate if (C_FIFO_TYPE == 2) begin : gll_dm_dout
always @(posedge CLK) begin
if (write_allow) begin
if (ENABLE_ERR_INJECTION == 1)
memory[wr_pntr] <= #`TCQ {INJECTDBITERR,INJECTSBITERR,DIN};
else
memory[wr_pntr] <= #`TCQ DIN;
end
end
reg [C_DATA_WIDTH-1:0] dout_tmp_q;
reg [C_DATA_WIDTH-1:0] dout_tmp = 0;
reg [C_DATA_WIDTH-1:0] dout_tmp1 = 0;
always @(posedge CLK) begin
dout_tmp_q <= #`TCQ ideal_dout;
end
always @* begin
if (read_allow)
ideal_dout <= memory[rd_pntr];
else
ideal_dout <= dout_tmp_q;
end
end endgenerate // gll_dm_dout
/**************************************************************************
* Write Domain Logic
**************************************************************************/
assign ram_rd_en = RD_EN & !EMPTY;
//reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
generate if (C_FIFO_TYPE != 2) begin : gnll_din
always @(posedge CLK or posedge rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (rst_i == 1'b1) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin //rst_i==0
if (srst_wrst_busy) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin//srst_i=0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end else begin
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
//end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //srst_i==0
end //wr_rst_i==0
end // gen_fifo_w
end endgenerate
generate if (C_FIFO_TYPE < 2 && C_MEMORY_TYPE < 2) begin : gnll_dm_dout
always @(posedge CLK) begin
if (rst_i || srst_rrst_busy) begin
if (C_USE_DOUT_RST == 1) begin
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end
end
end endgenerate
generate if (C_FIFO_TYPE != 2) begin : gnll_dout
always @(posedge CLK or posedge rst_i) begin : gen_fifo_r
/****** Reset fifo (case 1)***************************************/
if (rst_i) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end else begin //rd_rst_i==0
if (srst_rrst_busy) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets synchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end //srst_i
else begin
//rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
if (RD_EN == 1'b1) begin
if (EMPTY == 1'b1) begin
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end
else
begin
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
end
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //s_rst_i==0
end //rd_rst_i==0
end //always
end endgenerate
//-----------------------------------------------------------------------------
// Generate diff_pntr for PROG_FULL generation
// Generate diff_pntr_pe for PROG_EMPTY generation
//-----------------------------------------------------------------------------
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 0) begin : reg_write_allow
always @(posedge CLK ) begin
if (rst_i) begin
write_only_q <= 1'b0;
read_only_q <= 1'b0;
diff_pntr_reg1 <= 0;
diff_pntr_pe_reg1 <= 0;
diff_pntr_reg2 <= 0;
diff_pntr_pe_reg2 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_rrst_busy) begin
read_only_q <= #`TCQ 1'b0;
diff_pntr_pe_reg1 <= #`TCQ 0;
diff_pntr_pe_reg2 <= #`TCQ 0;
end
if (srst_wrst_busy) begin
write_only_q <= #`TCQ 1'b0;
diff_pntr_reg1 <= #`TCQ 0;
diff_pntr_reg2 <= #`TCQ 0;
end
end else begin
write_only_q <= #`TCQ write_only;
read_only_q <= #`TCQ read_only;
diff_pntr_reg2 <= #`TCQ diff_pntr_reg1;
diff_pntr_pe_reg2 <= #`TCQ diff_pntr_pe_reg1;
// Add 1 to the difference pointer value when only write happens.
if (write_only)
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr + 1;
else
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
// Add 1 to the difference pointer value when write or both write & read or no write & read happen.
if (read_only)
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr - 1;
else
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr;
end
end
end
assign diff_pntr_pe = diff_pntr_pe_reg1;
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 1) begin : reg_write_allow_asym
assign adj_wr_pntr_rd_asym[C_RD_PNTR_WIDTH:0] = {adj_wr_pntr_rd,1'b1};
assign rd_pntr_asym[C_RD_PNTR_WIDTH:0] = {~rd_pntr,1'b1};
always @(posedge CLK ) begin
if (rst_i) begin
diff_pntr_pe_asym <= 0;
diff_pntr_reg1 <= 0;
full_reg <= 0;
rst_full_ff_reg1 <= 1;
rst_full_ff_reg2 <= 1;
diff_pntr_pe_reg1 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_wrst_busy)
diff_pntr_reg1 <= #`TCQ 0;
if (srst_rrst_busy)
full_reg <= #`TCQ 0;
rst_full_ff_reg1 <= #`TCQ 1;
rst_full_ff_reg2 <= #`TCQ 1;
diff_pntr_pe_asym <= #`TCQ 0;
diff_pntr_pe_reg1 <= #`TCQ 0;
end else begin
diff_pntr_pe_asym <= #`TCQ adj_wr_pntr_rd_asym + rd_pntr_asym;
full_reg <= #`TCQ full_i;
rst_full_ff_reg1 <= #`TCQ RST_FULL_FF;
rst_full_ff_reg2 <= #`TCQ rst_full_ff_reg1;
if (~full_i) begin
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
end
end
end
end
assign carry = (~(|(diff_pntr_pe_asym [C_RD_PNTR_WIDTH : 1])));
assign diff_pntr_pe = (full_reg && ~rst_full_ff_reg2 && carry ) ? diff_pntr_pe_max : diff_pntr_pe_asym[C_RD_PNTR_WIDTH:1];
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow_asym
//-----------------------------------------------------------------------------
// Generate FULL flag
//-----------------------------------------------------------------------------
wire comp0;
wire comp1;
wire going_full;
wire leaving_full;
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gpad
assign adj_rd_pntr_wr [C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_WR_PNTR_WIDTH <= C_RD_PNTR_WIDTH) begin : gtrim
assign adj_rd_pntr_wr = rd_pntr[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
assign comp1 = (adj_rd_pntr_wr == (wr_pntr + 1'b1));
assign comp0 = (adj_rd_pntr_wr == wr_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gf_wp_eq_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full = (comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gf_asym
assign going_full = (comp1 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_full = (comp0 & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gf_wp_gt_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full =(comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_full_comb = going_full | (~leaving_full & full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
full_i <= #`TCQ ram_full_comb;
end
//-----------------------------------------------------------------------------
// Generate EMPTY flag
//-----------------------------------------------------------------------------
wire ecomp0;
wire ecomp1;
wire going_empty;
wire leaving_empty;
wire ram_empty_comb;
generate if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : pad
assign adj_wr_pntr_rd [C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_RD_PNTR_WIDTH <= C_WR_PNTR_WIDTH) begin : trim
assign adj_wr_pntr_rd = wr_pntr[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
assign ecomp1 = (adj_wr_pntr_rd == (rd_pntr + 1'b1));
assign ecomp0 = (adj_wr_pntr_rd == rd_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : ge_wp_eq_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty = (ecomp0 & write_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : ge_wp_gt_rp
assign going_empty = (ecomp1 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_empty = (ecomp0 & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : ge_wp_lt_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty =(ecomp0 & write_allow);
end endgenerate
assign ram_empty_comb = going_empty | (~leaving_empty & empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
empty_i <= 1'b1;
else if (srst_rrst_busy)
empty_i <= #`TCQ 1'b1;
else
empty_i <= #`TCQ ram_empty_comb;
end
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (srst_rrst_busy || (SAFETY_CKT_WR_RST && C_EN_SAFETY_CKT))
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ ram_empty_comb;
end
end // always
//-----------------------------------------------------------------------------
// Generate Read and write data counts for asymmetic common clock
//-----------------------------------------------------------------------------
reg [C_GRTR_PNTR_WIDTH :0] count_dc = 0;
wire [C_GRTR_PNTR_WIDTH :0] ratio;
wire decr_by_one;
wire incr_by_ratio;
wire incr_by_one;
wire decr_by_ratio;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : rd_depth_gt_wr
assign ratio = C_DEPTH_RATIO_RD;
assign decr_by_one = (IS_FWFT == 1)? read_allow_dc : read_allow;
assign incr_by_ratio = write_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (decr_by_one) begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc - 1;
else
count_dc <= #`TCQ count_dc - 1 + ratio ;
end
else begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc + ratio ;
end
end
end
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc;
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wr_depth_gt_rd
assign ratio = C_DEPTH_RATIO_WR;
assign incr_by_one = write_allow;
assign decr_by_ratio = (IS_FWFT == 1)? read_allow_dc : read_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (incr_by_one) begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc + 1;
else
count_dc <= #`TCQ count_dc + 1 - ratio ;
end
else begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc - ratio ;
end
end
end
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc;
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
//-----------------------------------------------------------------------------
// Generate WR_ACK flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_wr_ack <= 1'b0;
else if (srst_wrst_busy)
ideal_wr_ack <= #`TCQ 1'b0;
else if (WR_EN & ~full_i)
ideal_wr_ack <= #`TCQ 1'b1;
else
ideal_wr_ack <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate VALID flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_valid <= 1'b0;
else if (srst_rrst_busy)
ideal_valid <= #`TCQ 1'b0;
else if (RD_EN & ~empty_i)
ideal_valid <= #`TCQ 1'b1;
else
ideal_valid <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate ALMOST_FULL flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_FULL == 1 || C_PROG_FULL_TYPE > 2 || C_PROG_EMPTY_TYPE > 2) begin : gaf_ss
wire fcomp2;
wire going_afull;
wire leaving_afull;
wire ram_afull_comb;
assign fcomp2 = (adj_rd_pntr_wr == (wr_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gaf_wp_eq_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull = (comp1 & read_allow & ~write_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gaf_asym
assign going_afull = (fcomp2 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_afull = (comp1 & (~write_allow) & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gaf_wp_gt_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull =((comp0 | comp1 | fcomp2) & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_afull_comb = going_afull | (~leaving_afull & almost_full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
almost_full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
almost_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
almost_full_i <= #`TCQ ram_afull_comb;
end
// end endgenerate // gaf_ss
//-----------------------------------------------------------------------------
// Generate ALMOST_EMPTY flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae_ss
wire ecomp2;
wire going_aempty;
wire leaving_aempty;
wire ram_aempty_comb;
assign ecomp2 = (adj_wr_pntr_rd == (rd_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gae_wp_eq_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty = (ecomp1 & write_allow & ~read_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gae_wp_gt_rp
assign going_aempty = (ecomp2 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_aempty = (ecomp1 & ~read_allow & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gae_wp_lt_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty =((ecomp2 | ecomp1 |ecomp0) & write_allow);
end endgenerate
assign ram_aempty_comb = going_aempty | (~leaving_aempty & almost_empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
almost_empty_i <= 1'b1;
else if (srst_rrst_busy)
almost_empty_i <= #`TCQ 1'b1;
else
almost_empty_i <= #`TCQ ram_aempty_comb;
end
// end endgenerate // gae_ss
//-----------------------------------------------------------------------------
// Generate PROG_FULL
//-----------------------------------------------------------------------------
localparam C_PF_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_PF_PARAM : // FWFT
C_PROG_FULL_THRESH_ASSERT_VAL; // STD
localparam C_PF_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_PF_PARAM: // FWFT
C_PROG_FULL_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold constant
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] temp = C_PF_ASSERT_VAL;
generate if (C_PROG_FULL_TYPE == 1) begin : single_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_ASSERT_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr>= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr) < C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b0;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate // single_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_FULL_TYPE == 2) begin : multiple_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_NEGATE_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr >= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < C_PF_NEGATE_VAL)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf3_assert_val = (C_PRELOAD_LATENCY == 0) ?
PROG_FULL_THRESH - EXTRA_WORDS_PF: // FWFT
PROG_FULL_THRESH; // STD
generate if (C_PROG_FULL_TYPE == 3) begin : single_pf_input
always @(posedge CLK or posedge RST_FULL_FF) begin//0
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin //1
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin//2
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin//3
if (diff_pntr > pf3_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == pf3_assert_val) begin//4
if (read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b1;
end else//4
prog_full_i <= #`TCQ 1'b0;
end else//3
prog_full_i <= #`TCQ prog_full_i;
end //2
else begin//5
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin//6
if (diff_pntr >= pf3_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf3_assert_val) begin//7
prog_full_i <= #`TCQ 1'b0;
end//7
end//6
else
prog_full_i <= #`TCQ prog_full_i;
end//5
end//1
end//0
end endgenerate //single_pf_input
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_ASSERT -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_ASSERT; // STD
wire [C_WR_PNTR_WIDTH-1:0] pf_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_NEGATE -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_NEGATE; // STD
generate if (C_PROG_FULL_TYPE == 4) begin : multiple_pf_inputs
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin
if (diff_pntr >= pf_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr == pf_negate_val && read_only_q) ||
diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin
if (diff_pntr >= pf_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_inputs
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY
//-----------------------------------------------------------------------------
localparam C_PE_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_ASSERT_VAL; // STD
localparam C_PE_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold constant
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 1) begin : single_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_ASSERT_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b0;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 2) begin : multiple_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_NEGATE_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_NEGATE_VAL)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate //multiple_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe3_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH -2) : // FWFT
PROG_EMPTY_THRESH; // STD
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_input
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe < pe3_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == pe3_assert_val) begin
if (write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ 1'b1;
end else
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe3_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe3_assert_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_input
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe4_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_ASSERT - 2) : // FWFT
PROG_EMPTY_THRESH_ASSERT; // STD
wire [C_RD_PNTR_WIDTH-1:0] pe4_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_NEGATE - 2) : // FWFT
PROG_EMPTY_THRESH_NEGATE; // STD
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_inputs
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe <= pe4_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (((diff_pntr_pe == pe4_negate_val) && write_only_q) ||
(diff_pntr_pe > pe4_negate_val)) begin
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe4_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe4_negate_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // multiple_pe_inputs
endmodule // fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* First-Word Fall-Through module (preload 0)
**************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USERVALID_LOW = 0,
parameter C_USERUNDERFLOW_LOW = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
(
//Inputs
input SAFETY_CKT_RD_RST,
input RD_CLK,
input RD_RST,
input SRST,
input WR_RST_BUSY,
input RD_RST_BUSY,
input RD_EN,
input FIFOEMPTY,
input [C_DOUT_WIDTH-1:0] FIFODATA,
input FIFOSBITERR,
input FIFODBITERR,
//Outputs
output reg [C_DOUT_WIDTH-1:0] USERDATA,
output USERVALID,
output USERUNDERFLOW,
output USEREMPTY,
output USERALMOSTEMPTY,
output RAMVALID,
output FIFORDEN,
output reg USERSBITERR,
output reg USERDBITERR,
output reg STAGE2_REG_EN,
output fab_read_data_valid_i_o,
output read_data_valid_i_o,
output ram_valid_i_o,
output [1:0] VALID_STAGES
);
//Internal signals
wire preloadstage1;
wire preloadstage2;
reg ram_valid_i;
reg fab_valid;
reg read_data_valid_i;
reg fab_read_data_valid_i;
reg fab_read_data_valid_i_1;
reg ram_valid_i_d;
reg read_data_valid_i_d;
reg fab_read_data_valid_i_d;
wire ram_regout_en;
reg ram_regout_en_d1;
reg ram_regout_en_d2;
wire fab_regout_en;
wire ram_rd_en;
reg empty_i = 1'b1;
reg empty_sckt = 1'b1;
reg sckt_rrst_q = 1'b0;
reg sckt_rrst_done = 1'b0;
reg empty_q = 1'b1;
reg rd_en_q = 1'b0;
reg almost_empty_i = 1'b1;
reg almost_empty_q = 1'b1;
wire rd_rst_i;
wire srst_i;
reg [C_DOUT_WIDTH-1:0] userdata_both;
wire uservalid_both;
wire uservalid_one;
reg user_sbiterr_both = 1'b0;
reg user_dbiterr_both = 1'b0;
assign ram_valid_i_o = ram_valid_i;
assign read_data_valid_i_o = read_data_valid_i;
assign fab_read_data_valid_i_o = fab_read_data_valid_i;
/*************************************************************************
* FUNCTIONS
*************************************************************************/
/*************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
//*************************************************************************
// Set power-on states for regs
//*************************************************************************
initial begin
ram_valid_i = 1'b0;
fab_valid = 1'b0;
read_data_valid_i = 1'b0;
fab_read_data_valid_i = 1'b0;
fab_read_data_valid_i_1 = 1'b0;
USERDATA = hexstr_conv(C_DOUT_RST_VAL);
userdata_both = hexstr_conv(C_DOUT_RST_VAL);
USERSBITERR = 1'b0;
USERDBITERR = 1'b0;
user_sbiterr_both = 1'b0;
user_dbiterr_both = 1'b0;
end //initial
//***************************************************************************
// connect up optional reset
//***************************************************************************
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? RD_RST : 0;
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_RD_RST : C_HAS_SRST ? SRST : 0;
reg sckt_rd_rst_fwft = 1'b0;
reg fwft_rst_done_i = 1'b0;
wire fwft_rst_done;
assign fwft_rst_done = C_EN_SAFETY_CKT ? fwft_rst_done_i : 1'b1;
always @ (posedge RD_CLK) begin
sckt_rd_rst_fwft <= #`TCQ SAFETY_CKT_RD_RST;
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i)
fwft_rst_done_i <= 1'b0;
else if (sckt_rd_rst_fwft & ~SAFETY_CKT_RD_RST)
fwft_rst_done_i <= #`TCQ 1'b1;
end
localparam INVALID = 0;
localparam STAGE1_VALID = 2;
localparam STAGE2_VALID = 1;
localparam BOTH_STAGES_VALID = 3;
reg [1:0] curr_fwft_state = INVALID;
reg [1:0] next_fwft_state = INVALID;
generate if (C_USE_EMBEDDED_REG < 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = preloadstage2;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = (RD_EN & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
reg curr_state = 0;
reg next_state = 0;
reg leaving_empty_fwft = 0;
reg going_empty_fwft = 0;
reg empty_i_q = 0;
reg ram_rd_en_fwft = 0;
generate if (C_FIFO_TYPE == 2) begin : gll_fifo
always @* begin // FSM fo FWFT
case (curr_state)
1'b0: begin
if (~FIFOEMPTY)
next_state <= 1'b1;
else
next_state <= 1'b0;
end
1'b1: begin
if (FIFOEMPTY && RD_EN)
next_state <= 1'b0;
else
next_state <= 1'b1;
end
default: next_state <= 1'b0;
endcase
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_i <= 1'b1;
empty_i_q <= 1'b1;
ram_valid_i <= 1'b0;
end else if (srst_i) begin
empty_i <= #`TCQ 1'b1;
empty_i_q <= #`TCQ 1'b1;
ram_valid_i <= #`TCQ 1'b0;
end else begin
empty_i <= #`TCQ going_empty_fwft | (~leaving_empty_fwft & empty_i);
empty_i_q <= #`TCQ FIFOEMPTY;
ram_valid_i <= #`TCQ next_state;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
curr_state <= 1'b0;
end else if (srst_i) begin
curr_state <= #`TCQ 1'b0;
end else begin
curr_state <= #`TCQ next_state;
end
end //always
wire fe_of_empty;
assign fe_of_empty = empty_i_q & ~FIFOEMPTY;
always @* begin // Finding leaving empty
case (curr_state)
1'b0: leaving_empty_fwft <= fe_of_empty;
1'b1: leaving_empty_fwft <= 1'b1;
default: leaving_empty_fwft <= 1'b0;
endcase
end
always @* begin // Finding going empty
case (curr_state)
1'b1: going_empty_fwft <= FIFOEMPTY & RD_EN;
default: going_empty_fwft <= 1'b0;
endcase
end
always @* begin // Generating FWFT rd_en
case (curr_state)
1'b0: ram_rd_en_fwft <= ~FIFOEMPTY;
1'b1: ram_rd_en_fwft <= ~FIFOEMPTY & RD_EN;
default: ram_rd_en_fwft <= 1'b0;
endcase
end
assign ram_regout_en = ram_rd_en_fwft;
//assign ram_regout_en_d1 = ram_rd_en_fwft;
//assign ram_regout_en_d2 = ram_rd_en_fwft;
assign ram_rd_en = ram_rd_en_fwft;
end endgenerate // gll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false.
// Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2) begin : gnll_fifo_ram_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (ram_rd_en == 1'b1) begin
ram_valid_i <= #`TCQ 1'b1;
end else begin
if (ram_regout_en == 1'b1)
ram_valid_i <= #`TCQ 1'b0;
else
ram_valid_i <= #`TCQ ram_valid_i;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_ram_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ ram_valid_i | (read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG < 3) begin : gnll_fifo_empty
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~ram_valid_i & ~read_data_valid_i) | (~ram_valid_i & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
generate if ( C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((ram_regout_en) | (~FIFOEMPTY & read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ FIFOEMPTY;
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
// BRAM resets synchronously
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG < 3) begin
always @ ( posedge rd_rst_i)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
//safety ckt with one register
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
//@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay
if (rd_rst_i == 1) begin
ram_regout_en_d1 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d1 <= #`TCQ 1'b0;
else
ram_regout_en_d1 <= #`TCQ ram_regout_en;
end
end //always
// assign fab_regout_en = ((ram_regout_en_d1 & ~(ram_regout_en_d2) & empty_i) | (RD_EN & !empty_i));
assign fab_regout_en = ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b0 )? 1'b1: ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1) ? RD_EN : 1'b0;
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay1
if (rd_rst_i == 1) begin
ram_regout_en_d2 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d2 <= #`TCQ 1'b0;
else
ram_regout_en_d2 <= #`TCQ ram_regout_en_d1;
end
end //always
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
always @ (posedge RD_CLK) begin
ram_valid_i_d <= #`TCQ ram_valid_i;
read_data_valid_i_d <= #`TCQ read_data_valid_i;
fab_read_data_valid_i_d <= #`TCQ fab_read_data_valid_i;
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = (ram_valid_i == 1'b1 && (read_data_valid_i == 1'b0 || fab_read_data_valid_i == 1'b0)) ? 1'b1 : (read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1 && ram_valid_i == 1'b1) ? RD_EN : 1'b0;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = ((RD_EN | ~ fab_read_data_valid_i) & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false // Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3) begin : gnll_fifo_fab_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (ram_regout_en == 1'b1) begin
fab_valid <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
fab_valid <= #`TCQ 1'b0;
else
fab_valid <= #`TCQ fab_valid;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_fab_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG == 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else begin
if (ram_regout_en == 1'b1) begin
read_data_valid_i <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ read_data_valid_i;
end
end
end //always
end
endgenerate
//generate if(C_USE_EMBEDDED_REG == 3) begin
// always @ (posedge RD_CLK or posedge rd_rst_i) begin
// if (rd_rst_i)
// read_data_valid_i <= #`TCQ 1'b0;
// else if (srst_i)
// read_data_valid_i <= #`TCQ 1'b0;
//
// if (ram_regout_en == 1'b1) begin
// fab_read_data_valid_i <= #`TCQ 1'b0;
// end else begin
// if (fab_regout_en == 1'b1)
// fab_read_data_valid_i <= #`TCQ 1'b1;
// else
// fab_read_data_valid_i <= #`TCQ fab_read_data_valid_i;
// end
// end //always
//end
//endgenerate
generate if(C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin :fabout_dvalid
if (rd_rst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else
fab_read_data_valid_i <= #`TCQ fab_valid | (fab_read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
always @ (posedge RD_CLK ) begin : proc_del1
begin
fab_read_data_valid_i_1 <= #`TCQ fab_read_data_valid_i;
end
end //always
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3 ) begin : gnll_fifo_empty_both
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~fab_valid & ~fab_read_data_valid_i) | (~fab_valid & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty_both
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
reg FIFOEMPTY_1;
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @(posedge RD_CLK) begin
FIFOEMPTY_1 <= #`TCQ FIFOEMPTY;
end
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((fab_regout_en) | (ram_valid_i & fab_read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ (~ram_valid_i);
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_sckt <= #`TCQ 1'b1;
sckt_rrst_q <= #`TCQ 1'b0;
sckt_rrst_done <= #`TCQ 1'b0;
end else begin
sckt_rrst_q <= #`TCQ SAFETY_CKT_RD_RST;
if (sckt_rrst_q && ~SAFETY_CKT_RD_RST) begin
sckt_rrst_done <= #`TCQ 1'b1;
end else if (sckt_rrst_done) begin
// rising clock edge
empty_sckt <= #`TCQ 1'b0;
end
end
end //always
// assign USEREMPTY = C_EN_SAFETY_CKT ? (sckt_rrst_done ? empty_i : empty_sckt) : empty_i;
assign USEREMPTY = empty_i;
assign USERALMOSTEMPTY = almost_empty_i;
assign FIFORDEN = ram_rd_en;
assign RAMVALID = (C_USE_EMBEDDED_REG == 3)? fab_valid : ram_valid_i;
assign uservalid_both = (C_USERVALID_LOW && C_USE_EMBEDDED_REG == 3) ? ~fab_read_data_valid_i : ((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG == 3) ? fab_read_data_valid_i : 1'b0);
assign uservalid_one = (C_USERVALID_LOW && C_USE_EMBEDDED_REG < 3) ? ~read_data_valid_i :((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG < 3) ? read_data_valid_i : 1'b0);
assign USERVALID = (C_USE_EMBEDDED_REG == 3) ? uservalid_both : uservalid_one;
assign USERUNDERFLOW = C_USERUNDERFLOW_LOW ? ~(empty_q & rd_en_q) : empty_q & rd_en_q;
//no safety ckt with both reg
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin
if (fwft_rst_done) begin
if (ram_regout_en) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end
end //always
end //if
endgenerate
//safety_ckt with both registers
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK) begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end //always
end //if
endgenerate
endmodule //fifo_generator_v13_1_3_bhv_ver_preload0
//-----------------------------------------------------------------------------
//
// Register Slice
// Register one AXI channel on forward and/or reverse signal path
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// reg_slice
//
//--------------------------------------------------------------------------
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
input wire S_VALID,
output wire S_READY,
// Master side
output wire [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA,
output wire M_VALID,
input wire M_READY
);
generate
////////////////////////////////////////////////////////////////////
//
// Both FWD and REV mode
//
////////////////////////////////////////////////////////////////////
if (C_REG_CONFIG == 32'h00000000)
begin
reg [1:0] state;
localparam [1:0]
ZERO = 2'b10,
ONE = 2'b11,
TWO = 2'b01;
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg [C_DATA_WIDTH-1:0] storage_data2 = 0;
reg load_s1;
wire load_s2;
wire load_s1_from_s2;
reg s_ready_i; //local signal of output
wire m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with either slave side data or from storage2
always @(posedge ACLK)
begin
if (load_s1)
if (load_s1_from_s2)
storage_data1 <= storage_data2;
else
storage_data1 <= S_PAYLOAD_DATA;
end
// Load storage2 with slave side data
always @(posedge ACLK)
begin
if (load_s2)
storage_data2 <= S_PAYLOAD_DATA;
end
assign M_PAYLOAD_DATA = storage_data1;
// Always load s2 on a valid transaction even if it's unnecessary
assign load_s2 = S_VALID & s_ready_i;
// Loading s1
always @ *
begin
if ( ((state == ZERO) && (S_VALID == 1)) || // Load when empty on slave transaction
// Load when ONE if we both have read and write at the same time
((state == ONE) && (S_VALID == 1) && (M_READY == 1)) ||
// Load when TWO and we have a transaction on Master side
((state == TWO) && (M_READY == 1)))
load_s1 = 1'b1;
else
load_s1 = 1'b0;
end // always @ *
assign load_s1_from_s2 = (state == TWO);
// State Machine for handling output signals
always @(posedge ACLK) begin
if (ARESET) begin
s_ready_i <= 1'b0;
state <= ZERO;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else begin
case (state)
// No transaction stored locally
ZERO: if (S_VALID) state <= ONE; // Got one so move to ONE
// One transaction stored locally
ONE: begin
if (M_READY & ~S_VALID) state <= ZERO; // Read out one so move to ZERO
if (~M_READY & S_VALID) begin
state <= TWO; // Got another one so move to TWO
s_ready_i <= 1'b0;
end
end
// TWO transaction stored locally
TWO: if (M_READY) begin
state <= ONE; // Read out one so move to ONE
s_ready_i <= 1'b1;
end
endcase // case (state)
end
end // always @ (posedge ACLK)
assign m_valid_i = state[0];
end // if (C_REG_CONFIG == 1)
////////////////////////////////////////////////////////////////////
//
// 1-stage pipeline register with bubble cycle, both FWD and REV pipelining
// Operates same as 1-deep FIFO
//
////////////////////////////////////////////////////////////////////
else if (C_REG_CONFIG == 32'h00000001)
begin
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg s_ready_i; //local signal of output
reg m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with slave side data
always @(posedge ACLK)
begin
if (ARESET) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b0;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else if (m_valid_i & M_READY) begin
s_ready_i <= 1'b1;
m_valid_i <= 1'b0;
end else if (S_VALID & s_ready_i) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b1;
end
if (~m_valid_i) begin
storage_data1 <= S_PAYLOAD_DATA;
end
end
assign M_PAYLOAD_DATA = storage_data1;
end // if (C_REG_CONFIG == 7)
else begin : default_case
// Passthrough
assign M_PAYLOAD_DATA = S_PAYLOAD_DATA;
assign M_VALID = S_VALID;
assign S_READY = M_READY;
end
endgenerate
endmodule // reg_slice
|
/*
*******************************************************************************
*
* FIFO Generator - Verilog Behavioral Model
*
*******************************************************************************
*
* (c) Copyright 1995 - 2009 Xilinx, Inc. All rights reserved.
*
* This file contains confidential and proprietary information
* of Xilinx, Inc. and is protected under U.S. and
* international copyright and other intellectual property
* laws.
*
* DISCLAIMER
* This disclaimer is not a license and does not grant any
* rights to the materials distributed herewith. Except as
* otherwise provided in a valid license issued to you by
* Xilinx, and to the maximum extent permitted by applicable
* law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
* WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
* AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
* BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
* INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
* (2) Xilinx shall not be liable (whether in contract or tort,
* including negligence, or under any other theory of
* liability) for any loss or damage of any kind or nature
* related to, arising under or in connection with these
* materials, including for any direct, or any indirect,
* special, incidental, or consequential loss or damage
* (including loss of data, profits, goodwill, or any type of
* loss or damage suffered as a result of any action brought
* by a third party) even if such damage or loss was
* reasonably foreseeable or Xilinx had been advised of the
* possibility of the same.
*
* CRITICAL APPLICATIONS
* Xilinx products are not designed or intended to be fail-
* safe, or for use in any application requiring fail-safe
* performance, such as life-support or safety devices or
* systems, Class III medical devices, nuclear facilities,
* applications related to the deployment of airbags, or any
* other applications that could lead to death, personal
* injury, or severe property or environmental damage
* (individually and collectively, "Critical
* Applications"). Customer assumes the sole risk and
* liability of any use of Xilinx products in Critical
* Applications, subject only to applicable laws and
* regulations governing limitations on product liability.
*
* THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
* PART OF THIS FILE AT ALL TIMES.
*
*******************************************************************************
*******************************************************************************
*
* Filename: fifo_generator_vlog_beh.v
*
* Author : Xilinx
*
*******************************************************************************
* Structure:
*
* fifo_generator_vlog_beh.v
* |
* +-fifo_generator_v13_1_3_bhv_ver_as
* |
* +-fifo_generator_v13_1_3_bhv_ver_ss
* |
* +-fifo_generator_v13_1_3_bhv_ver_preload0
*
*******************************************************************************
* Description:
*
* The Verilog behavioral model for the FIFO Generator.
*
* The behavioral model has three parts:
* - The behavioral model for independent clocks FIFOs (_as)
* - The behavioral model for common clock FIFOs (_ss)
* - The "preload logic" block which implements First-word Fall-through
*
*******************************************************************************
* Description:
* The verilog behavioral model for the FIFO generator core.
*
*******************************************************************************
*/
`timescale 1ps/1ps
`ifndef TCQ
`define TCQ 100
`endif
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "",
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 1,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "4kx4",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_PIPELINE_REG = 0,
parameter C_POWER_SAVING_MODE = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface, 1: AXI4 Stream, 2: AXI4/AXI3
parameter C_AXI_TYPE = 0, // 1: AXI4, 2: AXI4 Lite, 3: AXI3
parameter C_HAS_AXI_WR_CHANNEL = 0,
parameter C_HAS_AXI_RD_CHANNEL = 0,
parameter C_HAS_SLAVE_CE = 0,
parameter C_HAS_MASTER_CE = 0,
parameter C_ADD_NGC_CONSTRAINT = 0,
parameter C_USE_COMMON_UNDERFLOW = 0,
parameter C_USE_COMMON_OVERFLOW = 0,
parameter C_USE_DEFAULT_SETTINGS = 0,
// AXI Full/Lite
parameter C_AXI_ID_WIDTH = 0,
parameter C_AXI_ADDR_WIDTH = 0,
parameter C_AXI_DATA_WIDTH = 0,
parameter C_AXI_LEN_WIDTH = 8,
parameter C_AXI_LOCK_WIDTH = 2,
parameter C_HAS_AXI_ID = 0,
parameter C_HAS_AXI_AWUSER = 0,
parameter C_HAS_AXI_WUSER = 0,
parameter C_HAS_AXI_BUSER = 0,
parameter C_HAS_AXI_ARUSER = 0,
parameter C_HAS_AXI_RUSER = 0,
parameter C_AXI_ARUSER_WIDTH = 0,
parameter C_AXI_AWUSER_WIDTH = 0,
parameter C_AXI_WUSER_WIDTH = 0,
parameter C_AXI_BUSER_WIDTH = 0,
parameter C_AXI_RUSER_WIDTH = 0,
// AXI Streaming
parameter C_HAS_AXIS_TDATA = 0,
parameter C_HAS_AXIS_TID = 0,
parameter C_HAS_AXIS_TDEST = 0,
parameter C_HAS_AXIS_TUSER = 0,
parameter C_HAS_AXIS_TREADY = 0,
parameter C_HAS_AXIS_TLAST = 0,
parameter C_HAS_AXIS_TSTRB = 0,
parameter C_HAS_AXIS_TKEEP = 0,
parameter C_AXIS_TDATA_WIDTH = 1,
parameter C_AXIS_TID_WIDTH = 1,
parameter C_AXIS_TDEST_WIDTH = 1,
parameter C_AXIS_TUSER_WIDTH = 1,
parameter C_AXIS_TSTRB_WIDTH = 1,
parameter C_AXIS_TKEEP_WIDTH = 1,
// AXI Channel Type
// WACH --> Write Address Channel
// WDCH --> Write Data Channel
// WRCH --> Write Response Channel
// RACH --> Read Address Channel
// RDCH --> Read Data Channel
// AXIS --> AXI Streaming
parameter C_WACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logic
parameter C_WDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_WRCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_AXIS_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
// AXI Implementation Type
// 1 = Common Clock Block RAM FIFO
// 2 = Common Clock Distributed RAM FIFO
// 11 = Independent Clock Block RAM FIFO
// 12 = Independent Clock Distributed RAM FIFO
parameter C_IMPLEMENTATION_TYPE_WACH = 0,
parameter C_IMPLEMENTATION_TYPE_WDCH = 0,
parameter C_IMPLEMENTATION_TYPE_WRCH = 0,
parameter C_IMPLEMENTATION_TYPE_RACH = 0,
parameter C_IMPLEMENTATION_TYPE_RDCH = 0,
parameter C_IMPLEMENTATION_TYPE_AXIS = 0,
// AXI FIFO Type
// 0 = Data FIFO
// 1 = Packet FIFO
// 2 = Low Latency Sync FIFO
// 3 = Low Latency Async FIFO
parameter C_APPLICATION_TYPE_WACH = 0,
parameter C_APPLICATION_TYPE_WDCH = 0,
parameter C_APPLICATION_TYPE_WRCH = 0,
parameter C_APPLICATION_TYPE_RACH = 0,
parameter C_APPLICATION_TYPE_RDCH = 0,
parameter C_APPLICATION_TYPE_AXIS = 0,
// AXI Built-in FIFO Primitive Type
// 512x36, 1kx18, 2kx9, 4kx4, etc
parameter C_PRIM_FIFO_TYPE_WACH = "512x36",
parameter C_PRIM_FIFO_TYPE_WDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_WRCH = "512x36",
parameter C_PRIM_FIFO_TYPE_RACH = "512x36",
parameter C_PRIM_FIFO_TYPE_RDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_AXIS = "512x36",
// Enable ECC
// 0 = ECC disabled
// 1 = ECC enabled
parameter C_USE_ECC_WACH = 0,
parameter C_USE_ECC_WDCH = 0,
parameter C_USE_ECC_WRCH = 0,
parameter C_USE_ECC_RACH = 0,
parameter C_USE_ECC_RDCH = 0,
parameter C_USE_ECC_AXIS = 0,
// ECC Error Injection Type
// 0 = No Error Injection
// 1 = Single Bit Error Injection
// 2 = Double Bit Error Injection
// 3 = Single Bit and Double Bit Error Injection
parameter C_ERROR_INJECTION_TYPE_WACH = 0,
parameter C_ERROR_INJECTION_TYPE_WDCH = 0,
parameter C_ERROR_INJECTION_TYPE_WRCH = 0,
parameter C_ERROR_INJECTION_TYPE_RACH = 0,
parameter C_ERROR_INJECTION_TYPE_RDCH = 0,
parameter C_ERROR_INJECTION_TYPE_AXIS = 0,
// Input Data Width
// Accumulation of all AXI input signal's width
parameter C_DIN_WIDTH_WACH = 1,
parameter C_DIN_WIDTH_WDCH = 1,
parameter C_DIN_WIDTH_WRCH = 1,
parameter C_DIN_WIDTH_RACH = 1,
parameter C_DIN_WIDTH_RDCH = 1,
parameter C_DIN_WIDTH_AXIS = 1,
parameter C_WR_DEPTH_WACH = 16,
parameter C_WR_DEPTH_WDCH = 16,
parameter C_WR_DEPTH_WRCH = 16,
parameter C_WR_DEPTH_RACH = 16,
parameter C_WR_DEPTH_RDCH = 16,
parameter C_WR_DEPTH_AXIS = 16,
parameter C_WR_PNTR_WIDTH_WACH = 4,
parameter C_WR_PNTR_WIDTH_WDCH = 4,
parameter C_WR_PNTR_WIDTH_WRCH = 4,
parameter C_WR_PNTR_WIDTH_RACH = 4,
parameter C_WR_PNTR_WIDTH_RDCH = 4,
parameter C_WR_PNTR_WIDTH_AXIS = 4,
parameter C_HAS_DATA_COUNTS_WACH = 0,
parameter C_HAS_DATA_COUNTS_WDCH = 0,
parameter C_HAS_DATA_COUNTS_WRCH = 0,
parameter C_HAS_DATA_COUNTS_RACH = 0,
parameter C_HAS_DATA_COUNTS_RDCH = 0,
parameter C_HAS_DATA_COUNTS_AXIS = 0,
parameter C_HAS_PROG_FLAGS_WACH = 0,
parameter C_HAS_PROG_FLAGS_WDCH = 0,
parameter C_HAS_PROG_FLAGS_WRCH = 0,
parameter C_HAS_PROG_FLAGS_RACH = 0,
parameter C_HAS_PROG_FLAGS_RDCH = 0,
parameter C_HAS_PROG_FLAGS_AXIS = 0,
parameter C_PROG_FULL_TYPE_WACH = 0,
parameter C_PROG_FULL_TYPE_WDCH = 0,
parameter C_PROG_FULL_TYPE_WRCH = 0,
parameter C_PROG_FULL_TYPE_RACH = 0,
parameter C_PROG_FULL_TYPE_RDCH = 0,
parameter C_PROG_FULL_TYPE_AXIS = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_PROG_EMPTY_TYPE_WACH = 0,
parameter C_PROG_EMPTY_TYPE_WDCH = 0,
parameter C_PROG_EMPTY_TYPE_WRCH = 0,
parameter C_PROG_EMPTY_TYPE_RACH = 0,
parameter C_PROG_EMPTY_TYPE_RDCH = 0,
parameter C_PROG_EMPTY_TYPE_AXIS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_REG_SLICE_MODE_WACH = 0,
parameter C_REG_SLICE_MODE_WDCH = 0,
parameter C_REG_SLICE_MODE_WRCH = 0,
parameter C_REG_SLICE_MODE_RACH = 0,
parameter C_REG_SLICE_MODE_RDCH = 0,
parameter C_REG_SLICE_MODE_AXIS = 0
)
(
//------------------------------------------------------------------------------
// Input and Output Declarations
//------------------------------------------------------------------------------
// Conventional FIFO Interface Signals
input backup,
input backup_marker,
input clk,
input rst,
input srst,
input wr_clk,
input wr_rst,
input rd_clk,
input rd_rst,
input [C_DIN_WIDTH-1:0] din,
input wr_en,
input rd_en,
// Optional inputs
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate,
input int_clk,
input injectdbiterr,
input injectsbiterr,
input sleep,
output [C_DOUT_WIDTH-1:0] dout,
output full,
output almost_full,
output wr_ack,
output overflow,
output empty,
output almost_empty,
output valid,
output underflow,
output [C_DATA_COUNT_WIDTH-1:0] data_count,
output [C_RD_DATA_COUNT_WIDTH-1:0] rd_data_count,
output [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count,
output prog_full,
output prog_empty,
output sbiterr,
output dbiterr,
output wr_rst_busy,
output rd_rst_busy,
// AXI Global Signal
input m_aclk,
input s_aclk,
input s_aresetn,
input s_aclk_en,
input m_aclk_en,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_awlen,
input [3-1:0] s_axi_awsize,
input [2-1:0] s_axi_awburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_awlock,
input [4-1:0] s_axi_awcache,
input [3-1:0] s_axi_awprot,
input [4-1:0] s_axi_awqos,
input [4-1:0] s_axi_awregion,
input [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser,
input s_axi_awvalid,
output s_axi_awready,
input [C_AXI_ID_WIDTH-1:0] s_axi_wid,
input [C_AXI_DATA_WIDTH-1:0] s_axi_wdata,
input [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb,
input s_axi_wlast,
input [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [2-1:0] s_axi_bresp,
output [C_AXI_BUSER_WIDTH-1:0] s_axi_buser,
output s_axi_bvalid,
input s_axi_bready,
// AXI Full/Lite Master Write Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_awlen,
output [3-1:0] m_axi_awsize,
output [2-1:0] m_axi_awburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_awlock,
output [4-1:0] m_axi_awcache,
output [3-1:0] m_axi_awprot,
output [4-1:0] m_axi_awqos,
output [4-1:0] m_axi_awregion,
output [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
output m_axi_awvalid,
input m_axi_awready,
output [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output m_axi_wlast,
output [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
output m_axi_wvalid,
input m_axi_wready,
input [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input [2-1:0] m_axi_bresp,
input [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
input m_axi_bvalid,
output m_axi_bready,
// AXI Full/Lite Slave Read Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_arlen,
input [3-1:0] s_axi_arsize,
input [2-1:0] s_axi_arburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_arlock,
input [4-1:0] s_axi_arcache,
input [3-1:0] s_axi_arprot,
input [4-1:0] s_axi_arqos,
input [4-1:0] s_axi_arregion,
input [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_AXI_DATA_WIDTH-1:0] s_axi_rdata,
output [2-1:0] s_axi_rresp,
output s_axi_rlast,
output [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser,
output s_axi_rvalid,
input s_axi_rready,
// AXI Full/Lite Master Read Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_arlen,
output [3-1:0] m_axi_arsize,
output [2-1:0] m_axi_arburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_arlock,
output [4-1:0] m_axi_arcache,
output [3-1:0] m_axi_arprot,
output [4-1:0] m_axi_arqos,
output [4-1:0] m_axi_arregion,
output [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
output m_axi_arvalid,
input m_axi_arready,
input [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input [2-1:0] m_axi_rresp,
input m_axi_rlast,
input [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
input m_axi_rvalid,
output m_axi_rready,
// AXI Streaming Slave Signals (Write side)
input s_axis_tvalid,
output s_axis_tready,
input [C_AXIS_TDATA_WIDTH-1:0] s_axis_tdata,
input [C_AXIS_TSTRB_WIDTH-1:0] s_axis_tstrb,
input [C_AXIS_TKEEP_WIDTH-1:0] s_axis_tkeep,
input s_axis_tlast,
input [C_AXIS_TID_WIDTH-1:0] s_axis_tid,
input [C_AXIS_TDEST_WIDTH-1:0] s_axis_tdest,
input [C_AXIS_TUSER_WIDTH-1:0] s_axis_tuser,
// AXI Streaming Master Signals (Read side)
output m_axis_tvalid,
input m_axis_tready,
output [C_AXIS_TDATA_WIDTH-1:0] m_axis_tdata,
output [C_AXIS_TSTRB_WIDTH-1:0] m_axis_tstrb,
output [C_AXIS_TKEEP_WIDTH-1:0] m_axis_tkeep,
output m_axis_tlast,
output [C_AXIS_TID_WIDTH-1:0] m_axis_tid,
output [C_AXIS_TDEST_WIDTH-1:0] m_axis_tdest,
output [C_AXIS_TUSER_WIDTH-1:0] m_axis_tuser,
// AXI Full/Lite Write Address Channel signals
input axi_aw_injectsbiterr,
input axi_aw_injectdbiterr,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_wr_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_rd_data_count,
output axi_aw_sbiterr,
output axi_aw_dbiterr,
output axi_aw_overflow,
output axi_aw_underflow,
output axi_aw_prog_full,
output axi_aw_prog_empty,
// AXI Full/Lite Write Data Channel signals
input axi_w_injectsbiterr,
input axi_w_injectdbiterr,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_wr_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_rd_data_count,
output axi_w_sbiterr,
output axi_w_dbiterr,
output axi_w_overflow,
output axi_w_underflow,
output axi_w_prog_full,
output axi_w_prog_empty,
// AXI Full/Lite Write Response Channel signals
input axi_b_injectsbiterr,
input axi_b_injectdbiterr,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_wr_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_rd_data_count,
output axi_b_sbiterr,
output axi_b_dbiterr,
output axi_b_overflow,
output axi_b_underflow,
output axi_b_prog_full,
output axi_b_prog_empty,
// AXI Full/Lite Read Address Channel signals
input axi_ar_injectsbiterr,
input axi_ar_injectdbiterr,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_wr_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_rd_data_count,
output axi_ar_sbiterr,
output axi_ar_dbiterr,
output axi_ar_overflow,
output axi_ar_underflow,
output axi_ar_prog_full,
output axi_ar_prog_empty,
// AXI Full/Lite Read Data Channel Signals
input axi_r_injectsbiterr,
input axi_r_injectdbiterr,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_wr_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_rd_data_count,
output axi_r_sbiterr,
output axi_r_dbiterr,
output axi_r_overflow,
output axi_r_underflow,
output axi_r_prog_full,
output axi_r_prog_empty,
// AXI Streaming FIFO Related Signals
input axis_injectsbiterr,
input axis_injectdbiterr,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_full_thresh,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_wr_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_rd_data_count,
output axis_sbiterr,
output axis_dbiterr,
output axis_overflow,
output axis_underflow,
output axis_prog_full,
output axis_prog_empty
);
wire BACKUP;
wire BACKUP_MARKER;
wire CLK;
wire RST;
wire SRST;
wire WR_CLK;
wire WR_RST;
wire RD_CLK;
wire RD_RST;
wire [C_DIN_WIDTH-1:0] DIN;
wire WR_EN;
wire RD_EN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire INT_CLK;
wire INJECTDBITERR;
wire INJECTSBITERR;
wire SLEEP;
wire [C_DOUT_WIDTH-1:0] DOUT;
wire FULL;
wire ALMOST_FULL;
wire WR_ACK;
wire OVERFLOW;
wire EMPTY;
wire ALMOST_EMPTY;
wire VALID;
wire UNDERFLOW;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT;
wire PROG_FULL;
wire PROG_EMPTY;
wire SBITERR;
wire DBITERR;
wire WR_RST_BUSY;
wire RD_RST_BUSY;
wire M_ACLK;
wire S_ACLK;
wire S_ARESETN;
wire S_ACLK_EN;
wire M_ACLK_EN;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_AWLEN;
wire [3-1:0] S_AXI_AWSIZE;
wire [2-1:0] S_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_AWLOCK;
wire [4-1:0] S_AXI_AWCACHE;
wire [3-1:0] S_AXI_AWPROT;
wire [4-1:0] S_AXI_AWQOS;
wire [4-1:0] S_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER;
wire S_AXI_AWVALID;
wire S_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB;
wire S_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER;
wire S_AXI_WVALID;
wire S_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [2-1:0] S_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER;
wire S_AXI_BVALID;
wire S_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_AWLEN;
wire [3-1:0] M_AXI_AWSIZE;
wire [2-1:0] M_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_AWLOCK;
wire [4-1:0] M_AXI_AWCACHE;
wire [3-1:0] M_AXI_AWPROT;
wire [4-1:0] M_AXI_AWQOS;
wire [4-1:0] M_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER;
wire M_AXI_AWVALID;
wire M_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB;
wire M_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER;
wire M_AXI_WVALID;
wire M_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID;
wire [2-1:0] M_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER;
wire M_AXI_BVALID;
wire M_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_ARLEN;
wire [3-1:0] S_AXI_ARSIZE;
wire [2-1:0] S_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_ARLOCK;
wire [4-1:0] S_AXI_ARCACHE;
wire [3-1:0] S_AXI_ARPROT;
wire [4-1:0] S_AXI_ARQOS;
wire [4-1:0] S_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER;
wire S_AXI_ARVALID;
wire S_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA;
wire [2-1:0] S_AXI_RRESP;
wire S_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER;
wire S_AXI_RVALID;
wire S_AXI_RREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_ARLEN;
wire [3-1:0] M_AXI_ARSIZE;
wire [2-1:0] M_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_ARLOCK;
wire [4-1:0] M_AXI_ARCACHE;
wire [3-1:0] M_AXI_ARPROT;
wire [4-1:0] M_AXI_ARQOS;
wire [4-1:0] M_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER;
wire M_AXI_ARVALID;
wire M_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA;
wire [2-1:0] M_AXI_RRESP;
wire M_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER;
wire M_AXI_RVALID;
wire M_AXI_RREADY;
wire S_AXIS_TVALID;
wire S_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] S_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] S_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] S_AXIS_TKEEP;
wire S_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] S_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] S_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] S_AXIS_TUSER;
wire M_AXIS_TVALID;
wire M_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] M_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] M_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] M_AXIS_TKEEP;
wire M_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] M_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] M_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] M_AXIS_TUSER;
wire AXI_AW_INJECTSBITERR;
wire AXI_AW_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_RD_DATA_COUNT;
wire AXI_AW_SBITERR;
wire AXI_AW_DBITERR;
wire AXI_AW_OVERFLOW;
wire AXI_AW_UNDERFLOW;
wire AXI_AW_PROG_FULL;
wire AXI_AW_PROG_EMPTY;
wire AXI_W_INJECTSBITERR;
wire AXI_W_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_RD_DATA_COUNT;
wire AXI_W_SBITERR;
wire AXI_W_DBITERR;
wire AXI_W_OVERFLOW;
wire AXI_W_UNDERFLOW;
wire AXI_W_PROG_FULL;
wire AXI_W_PROG_EMPTY;
wire AXI_B_INJECTSBITERR;
wire AXI_B_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_RD_DATA_COUNT;
wire AXI_B_SBITERR;
wire AXI_B_DBITERR;
wire AXI_B_OVERFLOW;
wire AXI_B_UNDERFLOW;
wire AXI_B_PROG_FULL;
wire AXI_B_PROG_EMPTY;
wire AXI_AR_INJECTSBITERR;
wire AXI_AR_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_RD_DATA_COUNT;
wire AXI_AR_SBITERR;
wire AXI_AR_DBITERR;
wire AXI_AR_OVERFLOW;
wire AXI_AR_UNDERFLOW;
wire AXI_AR_PROG_FULL;
wire AXI_AR_PROG_EMPTY;
wire AXI_R_INJECTSBITERR;
wire AXI_R_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_RD_DATA_COUNT;
wire AXI_R_SBITERR;
wire AXI_R_DBITERR;
wire AXI_R_OVERFLOW;
wire AXI_R_UNDERFLOW;
wire AXI_R_PROG_FULL;
wire AXI_R_PROG_EMPTY;
wire AXIS_INJECTSBITERR;
wire AXIS_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_RD_DATA_COUNT;
wire AXIS_SBITERR;
wire AXIS_DBITERR;
wire AXIS_OVERFLOW;
wire AXIS_UNDERFLOW;
wire AXIS_PROG_FULL;
wire AXIS_PROG_EMPTY;
wire [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count_in;
wire wr_rst_int;
wire rd_rst_int;
wire wr_rst_busy_o;
wire wr_rst_busy_ntve;
wire wr_rst_busy_axis;
wire wr_rst_busy_wach;
wire wr_rst_busy_wdch;
wire wr_rst_busy_wrch;
wire wr_rst_busy_rach;
wire wr_rst_busy_rdch;
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// Conventional FIFO Interface Signals
assign BACKUP = backup;
assign BACKUP_MARKER = backup_marker;
assign CLK = clk;
assign RST = rst;
assign SRST = srst;
assign WR_CLK = wr_clk;
assign WR_RST = wr_rst;
assign RD_CLK = rd_clk;
assign RD_RST = rd_rst;
assign WR_EN = wr_en;
assign RD_EN = rd_en;
assign INT_CLK = int_clk;
assign INJECTDBITERR = injectdbiterr;
assign INJECTSBITERR = injectsbiterr;
assign SLEEP = sleep;
assign full = FULL;
assign almost_full = ALMOST_FULL;
assign wr_ack = WR_ACK;
assign overflow = OVERFLOW;
assign empty = EMPTY;
assign almost_empty = ALMOST_EMPTY;
assign valid = VALID;
assign underflow = UNDERFLOW;
assign prog_full = PROG_FULL;
assign prog_empty = PROG_EMPTY;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
// assign wr_rst_busy = WR_RST_BUSY | wr_rst_busy_o;
assign wr_rst_busy = wr_rst_busy_o;
assign rd_rst_busy = RD_RST_BUSY;
assign M_ACLK = m_aclk;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_ACLK_EN = s_aclk_en;
assign M_ACLK_EN = m_aclk_en;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign m_axi_awvalid = M_AXI_AWVALID;
assign M_AXI_AWREADY = m_axi_awready;
assign m_axi_wlast = M_AXI_WLAST;
assign m_axi_wvalid = M_AXI_WVALID;
assign M_AXI_WREADY = m_axi_wready;
assign M_AXI_BVALID = m_axi_bvalid;
assign m_axi_bready = M_AXI_BREADY;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign m_axi_arvalid = M_AXI_ARVALID;
assign M_AXI_ARREADY = m_axi_arready;
assign M_AXI_RLAST = m_axi_rlast;
assign M_AXI_RVALID = m_axi_rvalid;
assign m_axi_rready = M_AXI_RREADY;
assign S_AXIS_TVALID = s_axis_tvalid;
assign s_axis_tready = S_AXIS_TREADY;
assign S_AXIS_TLAST = s_axis_tlast;
assign m_axis_tvalid = M_AXIS_TVALID;
assign M_AXIS_TREADY = m_axis_tready;
assign m_axis_tlast = M_AXIS_TLAST;
assign AXI_AW_INJECTSBITERR = axi_aw_injectsbiterr;
assign AXI_AW_INJECTDBITERR = axi_aw_injectdbiterr;
assign axi_aw_sbiterr = AXI_AW_SBITERR;
assign axi_aw_dbiterr = AXI_AW_DBITERR;
assign axi_aw_overflow = AXI_AW_OVERFLOW;
assign axi_aw_underflow = AXI_AW_UNDERFLOW;
assign axi_aw_prog_full = AXI_AW_PROG_FULL;
assign axi_aw_prog_empty = AXI_AW_PROG_EMPTY;
assign AXI_W_INJECTSBITERR = axi_w_injectsbiterr;
assign AXI_W_INJECTDBITERR = axi_w_injectdbiterr;
assign axi_w_sbiterr = AXI_W_SBITERR;
assign axi_w_dbiterr = AXI_W_DBITERR;
assign axi_w_overflow = AXI_W_OVERFLOW;
assign axi_w_underflow = AXI_W_UNDERFLOW;
assign axi_w_prog_full = AXI_W_PROG_FULL;
assign axi_w_prog_empty = AXI_W_PROG_EMPTY;
assign AXI_B_INJECTSBITERR = axi_b_injectsbiterr;
assign AXI_B_INJECTDBITERR = axi_b_injectdbiterr;
assign axi_b_sbiterr = AXI_B_SBITERR;
assign axi_b_dbiterr = AXI_B_DBITERR;
assign axi_b_overflow = AXI_B_OVERFLOW;
assign axi_b_underflow = AXI_B_UNDERFLOW;
assign axi_b_prog_full = AXI_B_PROG_FULL;
assign axi_b_prog_empty = AXI_B_PROG_EMPTY;
assign AXI_AR_INJECTSBITERR = axi_ar_injectsbiterr;
assign AXI_AR_INJECTDBITERR = axi_ar_injectdbiterr;
assign axi_ar_sbiterr = AXI_AR_SBITERR;
assign axi_ar_dbiterr = AXI_AR_DBITERR;
assign axi_ar_overflow = AXI_AR_OVERFLOW;
assign axi_ar_underflow = AXI_AR_UNDERFLOW;
assign axi_ar_prog_full = AXI_AR_PROG_FULL;
assign axi_ar_prog_empty = AXI_AR_PROG_EMPTY;
assign AXI_R_INJECTSBITERR = axi_r_injectsbiterr;
assign AXI_R_INJECTDBITERR = axi_r_injectdbiterr;
assign axi_r_sbiterr = AXI_R_SBITERR;
assign axi_r_dbiterr = AXI_R_DBITERR;
assign axi_r_overflow = AXI_R_OVERFLOW;
assign axi_r_underflow = AXI_R_UNDERFLOW;
assign axi_r_prog_full = AXI_R_PROG_FULL;
assign axi_r_prog_empty = AXI_R_PROG_EMPTY;
assign AXIS_INJECTSBITERR = axis_injectsbiterr;
assign AXIS_INJECTDBITERR = axis_injectdbiterr;
assign axis_sbiterr = AXIS_SBITERR;
assign axis_dbiterr = AXIS_DBITERR;
assign axis_overflow = AXIS_OVERFLOW;
assign axis_underflow = AXIS_UNDERFLOW;
assign axis_prog_full = AXIS_PROG_FULL;
assign axis_prog_empty = AXIS_PROG_EMPTY;
assign DIN = din;
assign PROG_EMPTY_THRESH = prog_empty_thresh;
assign PROG_EMPTY_THRESH_ASSERT = prog_empty_thresh_assert;
assign PROG_EMPTY_THRESH_NEGATE = prog_empty_thresh_negate;
assign PROG_FULL_THRESH = prog_full_thresh;
assign PROG_FULL_THRESH_ASSERT = prog_full_thresh_assert;
assign PROG_FULL_THRESH_NEGATE = prog_full_thresh_negate;
assign dout = DOUT;
assign data_count = DATA_COUNT;
assign rd_data_count = RD_DATA_COUNT;
assign wr_data_count = WR_DATA_COUNT;
assign S_AXI_AWID = s_axi_awid;
assign S_AXI_AWADDR = s_axi_awaddr;
assign S_AXI_AWLEN = s_axi_awlen;
assign S_AXI_AWSIZE = s_axi_awsize;
assign S_AXI_AWBURST = s_axi_awburst;
assign S_AXI_AWLOCK = s_axi_awlock;
assign S_AXI_AWCACHE = s_axi_awcache;
assign S_AXI_AWPROT = s_axi_awprot;
assign S_AXI_AWQOS = s_axi_awqos;
assign S_AXI_AWREGION = s_axi_awregion;
assign S_AXI_AWUSER = s_axi_awuser;
assign S_AXI_WID = s_axi_wid;
assign S_AXI_WDATA = s_axi_wdata;
assign S_AXI_WSTRB = s_axi_wstrb;
assign S_AXI_WUSER = s_axi_wuser;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_buser = S_AXI_BUSER;
assign m_axi_awid = M_AXI_AWID;
assign m_axi_awaddr = M_AXI_AWADDR;
assign m_axi_awlen = M_AXI_AWLEN;
assign m_axi_awsize = M_AXI_AWSIZE;
assign m_axi_awburst = M_AXI_AWBURST;
assign m_axi_awlock = M_AXI_AWLOCK;
assign m_axi_awcache = M_AXI_AWCACHE;
assign m_axi_awprot = M_AXI_AWPROT;
assign m_axi_awqos = M_AXI_AWQOS;
assign m_axi_awregion = M_AXI_AWREGION;
assign m_axi_awuser = M_AXI_AWUSER;
assign m_axi_wid = M_AXI_WID;
assign m_axi_wdata = M_AXI_WDATA;
assign m_axi_wstrb = M_AXI_WSTRB;
assign m_axi_wuser = M_AXI_WUSER;
assign M_AXI_BID = m_axi_bid;
assign M_AXI_BRESP = m_axi_bresp;
assign M_AXI_BUSER = m_axi_buser;
assign S_AXI_ARID = s_axi_arid;
assign S_AXI_ARADDR = s_axi_araddr;
assign S_AXI_ARLEN = s_axi_arlen;
assign S_AXI_ARSIZE = s_axi_arsize;
assign S_AXI_ARBURST = s_axi_arburst;
assign S_AXI_ARLOCK = s_axi_arlock;
assign S_AXI_ARCACHE = s_axi_arcache;
assign S_AXI_ARPROT = s_axi_arprot;
assign S_AXI_ARQOS = s_axi_arqos;
assign S_AXI_ARREGION = s_axi_arregion;
assign S_AXI_ARUSER = s_axi_aruser;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_ruser = S_AXI_RUSER;
assign m_axi_arid = M_AXI_ARID;
assign m_axi_araddr = M_AXI_ARADDR;
assign m_axi_arlen = M_AXI_ARLEN;
assign m_axi_arsize = M_AXI_ARSIZE;
assign m_axi_arburst = M_AXI_ARBURST;
assign m_axi_arlock = M_AXI_ARLOCK;
assign m_axi_arcache = M_AXI_ARCACHE;
assign m_axi_arprot = M_AXI_ARPROT;
assign m_axi_arqos = M_AXI_ARQOS;
assign m_axi_arregion = M_AXI_ARREGION;
assign m_axi_aruser = M_AXI_ARUSER;
assign M_AXI_RID = m_axi_rid;
assign M_AXI_RDATA = m_axi_rdata;
assign M_AXI_RRESP = m_axi_rresp;
assign M_AXI_RUSER = m_axi_ruser;
assign S_AXIS_TDATA = s_axis_tdata;
assign S_AXIS_TSTRB = s_axis_tstrb;
assign S_AXIS_TKEEP = s_axis_tkeep;
assign S_AXIS_TID = s_axis_tid;
assign S_AXIS_TDEST = s_axis_tdest;
assign S_AXIS_TUSER = s_axis_tuser;
assign m_axis_tdata = M_AXIS_TDATA;
assign m_axis_tstrb = M_AXIS_TSTRB;
assign m_axis_tkeep = M_AXIS_TKEEP;
assign m_axis_tid = M_AXIS_TID;
assign m_axis_tdest = M_AXIS_TDEST;
assign m_axis_tuser = M_AXIS_TUSER;
assign AXI_AW_PROG_FULL_THRESH = axi_aw_prog_full_thresh;
assign AXI_AW_PROG_EMPTY_THRESH = axi_aw_prog_empty_thresh;
assign axi_aw_data_count = AXI_AW_DATA_COUNT;
assign axi_aw_wr_data_count = AXI_AW_WR_DATA_COUNT;
assign axi_aw_rd_data_count = AXI_AW_RD_DATA_COUNT;
assign AXI_W_PROG_FULL_THRESH = axi_w_prog_full_thresh;
assign AXI_W_PROG_EMPTY_THRESH = axi_w_prog_empty_thresh;
assign axi_w_data_count = AXI_W_DATA_COUNT;
assign axi_w_wr_data_count = AXI_W_WR_DATA_COUNT;
assign axi_w_rd_data_count = AXI_W_RD_DATA_COUNT;
assign AXI_B_PROG_FULL_THRESH = axi_b_prog_full_thresh;
assign AXI_B_PROG_EMPTY_THRESH = axi_b_prog_empty_thresh;
assign axi_b_data_count = AXI_B_DATA_COUNT;
assign axi_b_wr_data_count = AXI_B_WR_DATA_COUNT;
assign axi_b_rd_data_count = AXI_B_RD_DATA_COUNT;
assign AXI_AR_PROG_FULL_THRESH = axi_ar_prog_full_thresh;
assign AXI_AR_PROG_EMPTY_THRESH = axi_ar_prog_empty_thresh;
assign axi_ar_data_count = AXI_AR_DATA_COUNT;
assign axi_ar_wr_data_count = AXI_AR_WR_DATA_COUNT;
assign axi_ar_rd_data_count = AXI_AR_RD_DATA_COUNT;
assign AXI_R_PROG_FULL_THRESH = axi_r_prog_full_thresh;
assign AXI_R_PROG_EMPTY_THRESH = axi_r_prog_empty_thresh;
assign axi_r_data_count = AXI_R_DATA_COUNT;
assign axi_r_wr_data_count = AXI_R_WR_DATA_COUNT;
assign axi_r_rd_data_count = AXI_R_RD_DATA_COUNT;
assign AXIS_PROG_FULL_THRESH = axis_prog_full_thresh;
assign AXIS_PROG_EMPTY_THRESH = axis_prog_empty_thresh;
assign axis_data_count = AXIS_DATA_COUNT;
assign axis_wr_data_count = AXIS_WR_DATA_COUNT;
assign axis_rd_data_count = AXIS_RD_DATA_COUNT;
generate if (C_INTERFACE_TYPE == 0) begin : conv_fifo
fifo_generator_v13_1_3_CONV_VER
#(
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_USE_DOUT_RST == 1 ? C_DOUT_RST_VAL : 0),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_FAMILY (C_FAMILY),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RD_RST (C_HAS_RD_RST),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_HAS_WR_RST (C_HAS_WR_RST),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_FREQ (C_RD_FREQ),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE)
)
fifo_generator_v13_1_3_conv_dut
(
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.CLK (CLK),
.RST (RST),
.SRST (SRST),
.WR_CLK (WR_CLK),
.WR_RST (WR_RST),
.RD_CLK (RD_CLK),
.RD_RST (RD_RST),
.DIN (DIN),
.WR_EN (WR_EN),
.RD_EN (RD_EN),
.PROG_EMPTY_THRESH (PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT (PROG_EMPTY_THRESH_ASSERT),
.PROG_EMPTY_THRESH_NEGATE (PROG_EMPTY_THRESH_NEGATE),
.PROG_FULL_THRESH (PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT (PROG_FULL_THRESH_ASSERT),
.PROG_FULL_THRESH_NEGATE (PROG_FULL_THRESH_NEGATE),
.INT_CLK (INT_CLK),
.INJECTDBITERR (INJECTDBITERR),
.INJECTSBITERR (INJECTSBITERR),
.DOUT (DOUT),
.FULL (FULL),
.ALMOST_FULL (ALMOST_FULL),
.WR_ACK (WR_ACK),
.OVERFLOW (OVERFLOW),
.EMPTY (EMPTY),
.ALMOST_EMPTY (ALMOST_EMPTY),
.VALID (VALID),
.UNDERFLOW (UNDERFLOW),
.DATA_COUNT (DATA_COUNT),
.RD_DATA_COUNT (RD_DATA_COUNT),
.WR_DATA_COUNT (wr_data_count_in),
.PROG_FULL (PROG_FULL),
.PROG_EMPTY (PROG_EMPTY),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.wr_rst_busy_o (wr_rst_busy_o),
.wr_rst_busy (wr_rst_busy_i),
.rd_rst_busy (rd_rst_busy),
.wr_rst_i_out (wr_rst_int),
.rd_rst_i_out (rd_rst_int)
);
end endgenerate
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_AXI_SIZE_WIDTH = 3;
localparam C_AXI_BURST_WIDTH = 2;
localparam C_AXI_CACHE_WIDTH = 4;
localparam C_AXI_PROT_WIDTH = 3;
localparam C_AXI_QOS_WIDTH = 4;
localparam C_AXI_REGION_WIDTH = 4;
localparam C_AXI_BRESP_WIDTH = 2;
localparam C_AXI_RRESP_WIDTH = 2;
localparam IS_AXI_STREAMING = C_INTERFACE_TYPE == 1 ? 1 : 0;
localparam TDATA_OFFSET = C_HAS_AXIS_TDATA == 1 ? C_DIN_WIDTH_AXIS-C_AXIS_TDATA_WIDTH : C_DIN_WIDTH_AXIS;
localparam TSTRB_OFFSET = C_HAS_AXIS_TSTRB == 1 ? TDATA_OFFSET-C_AXIS_TSTRB_WIDTH : TDATA_OFFSET;
localparam TKEEP_OFFSET = C_HAS_AXIS_TKEEP == 1 ? TSTRB_OFFSET-C_AXIS_TKEEP_WIDTH : TSTRB_OFFSET;
localparam TID_OFFSET = C_HAS_AXIS_TID == 1 ? TKEEP_OFFSET-C_AXIS_TID_WIDTH : TKEEP_OFFSET;
localparam TDEST_OFFSET = C_HAS_AXIS_TDEST == 1 ? TID_OFFSET-C_AXIS_TDEST_WIDTH : TID_OFFSET;
localparam TUSER_OFFSET = C_HAS_AXIS_TUSER == 1 ? TDEST_OFFSET-C_AXIS_TUSER_WIDTH : TDEST_OFFSET;
localparam LOG_DEPTH_AXIS = find_log2(C_WR_DEPTH_AXIS);
localparam LOG_WR_DEPTH = find_log2(C_WR_DEPTH);
function [LOG_DEPTH_AXIS-1:0] bin2gray;
input [LOG_DEPTH_AXIS-1:0] x;
begin
bin2gray = x ^ (x>>1);
end
endfunction
function [LOG_DEPTH_AXIS-1:0] gray2bin;
input [LOG_DEPTH_AXIS-1:0] x;
integer i;
begin
gray2bin[LOG_DEPTH_AXIS-1] = x[LOG_DEPTH_AXIS-1];
for(i=LOG_DEPTH_AXIS-2; i>=0; i=i-1) begin
gray2bin[i] = gray2bin[i+1] ^ x[i];
end
end
endfunction
wire [(LOG_WR_DEPTH)-1 : 0] w_cnt_gc_asreg_last;
wire [LOG_WR_DEPTH-1 : 0] w_q [0:C_SYNCHRONIZER_STAGE] ;
wire [LOG_WR_DEPTH-1 : 0] w_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_rd = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_gc = 0;
reg [LOG_WR_DEPTH-1 : 0] r_cnt = 0;
wire [LOG_WR_DEPTH : 0] adj_w_cnt_rd_pad;
wire [LOG_WR_DEPTH : 0] r_inv_pad;
wire [LOG_WR_DEPTH-1 : 0] d_cnt;
reg [LOG_WR_DEPTH : 0] d_cnt_pad = 0;
reg adj_w_cnt_rd_pad_0 = 0;
reg r_inv_pad_0 = 0;
genvar l;
generate for (l = 1; ((l <= C_SYNCHRONIZER_STAGE) && (C_HAS_DATA_COUNTS_AXIS == 3 && C_INTERFACE_TYPE == 0) ); l = l + 1) begin : g_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_WR_DEPTH)
)
rd_stg_inst
(
.RST (rd_rst_int),
.CLK (RD_CLK),
.DIN (w_q[l-1]),
.DOUT (w_q[l])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS == 3) begin : fifo_ic_adapter
assign wr_eop_ad = WR_EN & !(FULL);
assign rd_eop_ad = RD_EN & !(EMPTY);
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt <= 1'b0;
else if (wr_eop_ad)
w_cnt <= w_cnt + 1;
end
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt_gc <= 1'b0;
else
w_cnt_gc <= bin2gray(w_cnt);
end
assign w_q[0] = w_cnt_gc;
assign w_cnt_gc_asreg_last = w_q[C_SYNCHRONIZER_STAGE];
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
w_cnt_rd <= 1'b0;
else
w_cnt_rd <= gray2bin(w_cnt_gc_asreg_last);
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
r_cnt <= 1'b0;
else if (rd_eop_ad)
r_cnt <= r_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_w_cnt_rd_pad[LOG_WR_DEPTH : 1] = w_cnt_rd;
assign r_inv_pad[LOG_WR_DEPTH : 1] = ~r_cnt;
assign adj_w_cnt_rd_pad[0] = adj_w_cnt_rd_pad_0;
assign r_inv_pad[0] = r_inv_pad_0;
always @ ( rd_eop_ad )
begin
if (!rd_eop_ad) begin
adj_w_cnt_rd_pad_0 <= 1'b1;
r_inv_pad_0 <= 1'b1;
end else begin
adj_w_cnt_rd_pad_0 <= 1'b0;
r_inv_pad_0 <= 1'b0;
end
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
d_cnt_pad <= 1'b0;
else
d_cnt_pad <= adj_w_cnt_rd_pad + r_inv_pad ;
end
assign d_cnt = d_cnt_pad [LOG_WR_DEPTH : 1] ;
assign WR_DATA_COUNT = d_cnt;
end endgenerate // fifo_ic_adapter
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS != 3) begin : fifo_icn_adapter
assign WR_DATA_COUNT = wr_data_count_in;
end endgenerate // fifo_icn_adapter
wire inverted_reset = ~S_ARESETN;
wire axi_rs_rst;
wire [C_DIN_WIDTH_AXIS-1:0] axis_din ;
wire [C_DIN_WIDTH_AXIS-1:0] axis_dout ;
wire axis_full ;
wire axis_almost_full ;
wire axis_empty ;
wire axis_s_axis_tready;
wire axis_m_axis_tvalid;
wire axis_wr_en ;
wire axis_rd_en ;
wire axis_we ;
wire axis_re ;
wire [C_WR_PNTR_WIDTH_AXIS:0] axis_dc;
reg axis_pkt_read = 1'b0;
wire axis_rd_rst;
wire axis_wr_rst;
generate if (C_INTERFACE_TYPE > 0 && (C_AXIS_TYPE == 1 || C_WACH_TYPE == 1 ||
C_WDCH_TYPE == 1 || C_WRCH_TYPE == 1 || C_RACH_TYPE == 1 || C_RDCH_TYPE == 1)) begin : gaxi_rs_rst
reg rst_d1 = 0 ;
reg rst_d2 = 0 ;
reg [3:0] axi_rst = 4'h0 ;
always @ (posedge inverted_reset or posedge S_ACLK) begin
if (inverted_reset) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
axi_rst <= 4'hf;
end else begin
rst_d1 <= #`TCQ 1'b0;
rst_d2 <= #`TCQ rst_d1;
axi_rst <= #`TCQ {axi_rst[2:0],1'b0};
end
end
assign axi_rs_rst = axi_rst[3];//rst_d2;
end endgenerate // gaxi_rs_rst
generate if (IS_AXI_STREAMING == 1 && C_AXIS_TYPE == 0) begin : axi_streaming
// Write protection when almost full or prog_full is high
assign axis_we = (C_PROG_FULL_TYPE_AXIS != 0) ? axis_s_axis_tready & S_AXIS_TVALID :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_s_axis_tready & S_AXIS_TVALID : S_AXIS_TVALID;
// Read protection when almost empty or prog_empty is high
assign axis_re = (C_PROG_EMPTY_TYPE_AXIS != 0) ? axis_m_axis_tvalid & M_AXIS_TREADY :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_m_axis_tvalid & M_AXIS_TREADY : M_AXIS_TREADY;
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? axis_we & S_ACLK_EN : axis_we;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? axis_re & M_ACLK_EN : axis_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_AXIS == 2 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_AXIS == 11 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_AXIS),
.C_WR_DEPTH (C_WR_DEPTH_AXIS),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_DOUT_WIDTH (C_DIN_WIDTH_AXIS),
.C_RD_DEPTH (C_WR_DEPTH_AXIS),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_AXIS),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_AXIS),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_AXIS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS),
.C_USE_ECC (C_USE_ECC_AXIS),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_AXIS),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (C_APPLICATION_TYPE_AXIS == 1 ? 1: 0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_FIFO_TYPE (C_APPLICATION_TYPE_AXIS == 1 ? 0: C_APPLICATION_TYPE_AXIS),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_axis_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (axis_wr_en),
.RD_EN (axis_rd_en),
.PROG_FULL_THRESH (AXIS_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH (AXIS_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.INJECTDBITERR (AXIS_INJECTDBITERR),
.INJECTSBITERR (AXIS_INJECTSBITERR),
.DIN (axis_din),
.DOUT (axis_dout),
.FULL (axis_full),
.EMPTY (axis_empty),
.ALMOST_FULL (axis_almost_full),
.PROG_FULL (AXIS_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXIS_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (AXIS_OVERFLOW),
.VALID (),
.UNDERFLOW (AXIS_UNDERFLOW),
.DATA_COUNT (axis_dc),
.RD_DATA_COUNT (AXIS_RD_DATA_COUNT),
.WR_DATA_COUNT (AXIS_WR_DATA_COUNT),
.SBITERR (AXIS_SBITERR),
.DBITERR (AXIS_DBITERR),
.wr_rst_busy (wr_rst_busy_axis),
.rd_rst_busy (rd_rst_busy_axis),
.wr_rst_i_out (axis_wr_rst),
.rd_rst_i_out (axis_rd_rst),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign axis_s_axis_tready = (IS_8SERIES == 0) ? ~axis_full : (C_IMPLEMENTATION_TYPE_AXIS == 5 || C_IMPLEMENTATION_TYPE_AXIS == 13) ? ~(axis_full | wr_rst_busy_axis) : ~axis_full;
assign axis_m_axis_tvalid = (C_APPLICATION_TYPE_AXIS != 1) ? ~axis_empty : ~axis_empty & axis_pkt_read;
assign S_AXIS_TREADY = axis_s_axis_tready;
assign M_AXIS_TVALID = axis_m_axis_tvalid;
end endgenerate // axi_streaming
wire axis_wr_eop;
reg axis_wr_eop_d1 = 1'b0;
wire axis_rd_eop;
integer axis_pkt_cnt;
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 1) begin : gaxis_pkt_fifo_cc
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (axis_pkt_cnt == 1) && ~axis_wr_eop_d1)
axis_pkt_read <= 1'b0;
else if ((axis_pkt_cnt > 0) || (axis_almost_full && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_wr_eop_d1 <= 1'b0;
else
axis_wr_eop_d1 <= axis_wr_eop;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_cnt <= 0;
else if (axis_wr_eop_d1 && ~axis_rd_eop)
axis_pkt_cnt <= axis_pkt_cnt + 1;
else if (axis_rd_eop && ~axis_wr_eop_d1)
axis_pkt_cnt <= axis_pkt_cnt - 1;
end
end endgenerate // gaxis_pkt_fifo_cc
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_gc = 0;
wire [(LOG_DEPTH_AXIS)-1 : 0] axis_wpkt_cnt_gc_asreg_last;
wire axis_rd_has_rst;
wire [0:C_SYNCHRONIZER_STAGE] axis_af_q ;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q [0:C_SYNCHRONIZER_STAGE] ;
wire [1:C_SYNCHRONIZER_STAGE] axis_af_q_temp = 0;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_rd = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_rpkt_cnt = 0;
wire [LOG_DEPTH_AXIS : 0] adj_axis_wpkt_cnt_rd_pad;
wire [LOG_DEPTH_AXIS : 0] rpkt_inv_pad;
wire [LOG_DEPTH_AXIS-1 : 0] diff_pkt_cnt;
reg [LOG_DEPTH_AXIS : 0] diff_pkt_cnt_pad = 0;
reg adj_axis_wpkt_cnt_rd_pad_0 = 0;
reg rpkt_inv_pad_0 = 0;
wire axis_af_rd ;
generate if (C_HAS_RST == 1) begin : rst_blk_has
assign axis_rd_has_rst = axis_rd_rst;
end endgenerate //rst_blk_has
generate if (C_HAS_RST == 0) begin :rst_blk_no
assign axis_rd_has_rst = 1'b0;
end endgenerate //rst_blk_no
genvar i;
generate for (i = 1; ((i <= C_SYNCHRONIZER_STAGE) && (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) ); i = i + 1) begin : gpkt_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_DEPTH_AXIS)
)
rd_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (wpkt_q[i-1]),
.DOUT (wpkt_q[i])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (1)
)
wr_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (axis_af_q[i-1]),
.DOUT (axis_af_q[i])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) begin : gaxis_pkt_fifo_ic
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (diff_pkt_cnt == 1))
axis_pkt_read <= 1'b0;
else if ((diff_pkt_cnt > 0) || (axis_af_rd && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt <= 1'b0;
else if (axis_wr_eop)
axis_wpkt_cnt <= axis_wpkt_cnt + 1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt_gc <= 1'b0;
else
axis_wpkt_cnt_gc <= bin2gray(axis_wpkt_cnt);
end
assign wpkt_q[0] = axis_wpkt_cnt_gc;
assign axis_wpkt_cnt_gc_asreg_last = wpkt_q[C_SYNCHRONIZER_STAGE];
assign axis_af_q[0] = axis_almost_full;
//assign axis_af_q[1:C_SYNCHRONIZER_STAGE] = axis_af_q_temp[1:C_SYNCHRONIZER_STAGE];
assign axis_af_rd = axis_af_q[C_SYNCHRONIZER_STAGE];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_wpkt_cnt_rd <= 1'b0;
else
axis_wpkt_cnt_rd <= gray2bin(axis_wpkt_cnt_gc_asreg_last);
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_rpkt_cnt <= 1'b0;
else if (axis_rd_eop)
axis_rpkt_cnt <= axis_rpkt_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_axis_wpkt_cnt_rd_pad[LOG_DEPTH_AXIS : 1] = axis_wpkt_cnt_rd;
assign rpkt_inv_pad[LOG_DEPTH_AXIS : 1] = ~axis_rpkt_cnt;
assign adj_axis_wpkt_cnt_rd_pad[0] = adj_axis_wpkt_cnt_rd_pad_0;
assign rpkt_inv_pad[0] = rpkt_inv_pad_0;
always @ ( axis_rd_eop )
begin
if (!axis_rd_eop) begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b1;
rpkt_inv_pad_0 <= 1'b1;
end else begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b0;
rpkt_inv_pad_0 <= 1'b0;
end
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
diff_pkt_cnt_pad <= 1'b0;
else
diff_pkt_cnt_pad <= adj_axis_wpkt_cnt_rd_pad + rpkt_inv_pad ;
end
assign diff_pkt_cnt = diff_pkt_cnt_pad [LOG_DEPTH_AXIS : 1] ;
end endgenerate // gaxis_pkt_fifo_ic
// Generate the accurate data count for axi stream packet fifo configuration
reg [C_WR_PNTR_WIDTH_AXIS:0] axis_dc_pkt_fifo = 0;
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 1 && C_APPLICATION_TYPE_AXIS == 1) begin : gdc_pkt
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_dc_pkt_fifo <= 0;
else if (axis_wr_en && (~axis_rd_en))
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo + 1;
else if (~axis_wr_en && axis_rd_en)
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo - 1;
end
assign AXIS_DATA_COUNT = axis_dc_pkt_fifo;
end endgenerate // gdc_pkt
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 0 && C_APPLICATION_TYPE_AXIS == 1) begin : gndc_pkt
assign AXIS_DATA_COUNT = 0;
end endgenerate // gndc_pkt
generate if (IS_AXI_STREAMING == 1 && C_APPLICATION_TYPE_AXIS != 1) begin : gdc
assign AXIS_DATA_COUNT = axis_dc;
end endgenerate // gdc
// Register Slice for Write Address Channel
generate if (C_AXIS_TYPE == 1) begin : gaxis_reg_slice
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? S_AXIS_TVALID & S_ACLK_EN : S_AXIS_TVALID;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? M_AXIS_TREADY & M_ACLK_EN : M_AXIS_TREADY;
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_AXIS),
.C_REG_CONFIG (C_REG_SLICE_MODE_AXIS)
)
axis_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (axis_din),
.S_VALID (axis_wr_en),
.S_READY (S_AXIS_TREADY),
// Master side
.M_PAYLOAD_DATA (axis_dout),
.M_VALID (M_AXIS_TVALID),
.M_READY (axis_rd_en)
);
end endgenerate // gaxis_reg_slice
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDATA == 1) begin : tdata
assign axis_din[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET] = S_AXIS_TDATA;
assign M_AXIS_TDATA = axis_dout[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TSTRB == 1) begin : tstrb
assign axis_din[TDATA_OFFSET-1:TSTRB_OFFSET] = S_AXIS_TSTRB;
assign M_AXIS_TSTRB = axis_dout[TDATA_OFFSET-1:TSTRB_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TKEEP == 1) begin : tkeep
assign axis_din[TSTRB_OFFSET-1:TKEEP_OFFSET] = S_AXIS_TKEEP;
assign M_AXIS_TKEEP = axis_dout[TSTRB_OFFSET-1:TKEEP_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TID == 1) begin : tid
assign axis_din[TKEEP_OFFSET-1:TID_OFFSET] = S_AXIS_TID;
assign M_AXIS_TID = axis_dout[TKEEP_OFFSET-1:TID_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDEST == 1) begin : tdest
assign axis_din[TID_OFFSET-1:TDEST_OFFSET] = S_AXIS_TDEST;
assign M_AXIS_TDEST = axis_dout[TID_OFFSET-1:TDEST_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TUSER == 1) begin : tuser
assign axis_din[TDEST_OFFSET-1:TUSER_OFFSET] = S_AXIS_TUSER;
assign M_AXIS_TUSER = axis_dout[TDEST_OFFSET-1:TUSER_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TLAST == 1) begin : tlast
assign axis_din[0] = S_AXIS_TLAST;
assign M_AXIS_TLAST = axis_dout[0];
end endgenerate
//###########################################################################
// AXI FULL Write Channel (axi_write_channel)
//###########################################################################
localparam IS_AXI_FULL = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE != 2)) ? 1 : 0;
localparam IS_AXI_LITE = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE == 2)) ? 1 : 0;
localparam IS_AXI_FULL_WACH = ((IS_AXI_FULL == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WDCH = ((IS_AXI_FULL == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WRCH = ((IS_AXI_FULL == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RACH = ((IS_AXI_FULL == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RDCH = ((IS_AXI_FULL == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WACH = ((IS_AXI_LITE == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WDCH = ((IS_AXI_LITE == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WRCH = ((IS_AXI_LITE == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RACH = ((IS_AXI_LITE == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RDCH = ((IS_AXI_LITE == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_WR_ADDR_CH = ((IS_AXI_FULL_WACH == 1) || (IS_AXI_LITE_WACH == 1)) ? 1 : 0;
localparam IS_WR_DATA_CH = ((IS_AXI_FULL_WDCH == 1) || (IS_AXI_LITE_WDCH == 1)) ? 1 : 0;
localparam IS_WR_RESP_CH = ((IS_AXI_FULL_WRCH == 1) || (IS_AXI_LITE_WRCH == 1)) ? 1 : 0;
localparam IS_RD_ADDR_CH = ((IS_AXI_FULL_RACH == 1) || (IS_AXI_LITE_RACH == 1)) ? 1 : 0;
localparam IS_RD_DATA_CH = ((IS_AXI_FULL_RDCH == 1) || (IS_AXI_LITE_RDCH == 1)) ? 1 : 0;
localparam AWID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WACH;
localparam AWADDR_OFFSET = AWID_OFFSET - C_AXI_ADDR_WIDTH;
localparam AWLEN_OFFSET = C_AXI_TYPE != 2 ? AWADDR_OFFSET - C_AXI_LEN_WIDTH : AWADDR_OFFSET;
localparam AWSIZE_OFFSET = C_AXI_TYPE != 2 ? AWLEN_OFFSET - C_AXI_SIZE_WIDTH : AWLEN_OFFSET;
localparam AWBURST_OFFSET = C_AXI_TYPE != 2 ? AWSIZE_OFFSET - C_AXI_BURST_WIDTH : AWSIZE_OFFSET;
localparam AWLOCK_OFFSET = C_AXI_TYPE != 2 ? AWBURST_OFFSET - C_AXI_LOCK_WIDTH : AWBURST_OFFSET;
localparam AWCACHE_OFFSET = C_AXI_TYPE != 2 ? AWLOCK_OFFSET - C_AXI_CACHE_WIDTH : AWLOCK_OFFSET;
localparam AWPROT_OFFSET = AWCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam AWQOS_OFFSET = AWPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam AWREGION_OFFSET = C_AXI_TYPE == 1 ? AWQOS_OFFSET - C_AXI_REGION_WIDTH : AWQOS_OFFSET;
localparam AWUSER_OFFSET = C_HAS_AXI_AWUSER == 1 ? AWREGION_OFFSET-C_AXI_AWUSER_WIDTH : AWREGION_OFFSET;
localparam WID_OFFSET = (C_AXI_TYPE == 3 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WDCH;
localparam WDATA_OFFSET = WID_OFFSET - C_AXI_DATA_WIDTH;
localparam WSTRB_OFFSET = WDATA_OFFSET - C_AXI_DATA_WIDTH/8;
localparam WUSER_OFFSET = C_HAS_AXI_WUSER == 1 ? WSTRB_OFFSET-C_AXI_WUSER_WIDTH : WSTRB_OFFSET;
localparam BID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WRCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WRCH;
localparam BRESP_OFFSET = BID_OFFSET - C_AXI_BRESP_WIDTH;
localparam BUSER_OFFSET = C_HAS_AXI_BUSER == 1 ? BRESP_OFFSET-C_AXI_BUSER_WIDTH : BRESP_OFFSET;
wire [C_DIN_WIDTH_WACH-1:0] wach_din ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout_pkt ;
wire wach_full ;
wire wach_almost_full ;
wire wach_prog_full ;
wire wach_empty ;
wire wach_almost_empty ;
wire wach_prog_empty ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_din ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_dout ;
wire wdch_full ;
wire wdch_almost_full ;
wire wdch_prog_full ;
wire wdch_empty ;
wire wdch_almost_empty ;
wire wdch_prog_empty ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_din ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_dout ;
wire wrch_full ;
wire wrch_almost_full ;
wire wrch_prog_full ;
wire wrch_empty ;
wire wrch_almost_empty ;
wire wrch_prog_empty ;
wire axi_aw_underflow_i;
wire axi_w_underflow_i ;
wire axi_b_underflow_i ;
wire axi_aw_overflow_i ;
wire axi_w_overflow_i ;
wire axi_b_overflow_i ;
wire axi_wr_underflow_i;
wire axi_wr_overflow_i ;
wire wach_s_axi_awready;
wire wach_m_axi_awvalid;
wire wach_wr_en ;
wire wach_rd_en ;
wire wdch_s_axi_wready ;
wire wdch_m_axi_wvalid ;
wire wdch_wr_en ;
wire wdch_rd_en ;
wire wrch_s_axi_bvalid ;
wire wrch_m_axi_bready ;
wire wrch_wr_en ;
wire wrch_rd_en ;
wire txn_count_up ;
wire txn_count_down ;
wire awvalid_en ;
wire awvalid_pkt ;
wire awready_pkt ;
integer wr_pkt_count ;
wire wach_we ;
wire wach_re ;
wire wdch_we ;
wire wdch_re ;
wire wrch_we ;
wire wrch_re ;
generate if (IS_WR_ADDR_CH == 1) begin : axi_write_address_channel
// Write protection when almost full or prog_full is high
assign wach_we = (C_PROG_FULL_TYPE_WACH != 0) ? wach_s_axi_awready & S_AXI_AWVALID : S_AXI_AWVALID;
// Read protection when almost empty or prog_empty is high
assign wach_re = (C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH == 1) ?
wach_m_axi_awvalid & awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY && wach_m_axi_awvalid :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH == 1) ?
awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY : 1'b0;
assign wach_wr_en = (C_HAS_SLAVE_CE == 1) ? wach_we & S_ACLK_EN : wach_we;
assign wach_rd_en = (C_HAS_MASTER_CE == 1) ? wach_re & M_ACLK_EN : wach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WACH == 2 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WACH == 11 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_DEPTH (C_WR_DEPTH_WACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WACH),
.C_RD_DEPTH (C_WR_DEPTH_WACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH),
.C_USE_ECC (C_USE_ECC_WACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_WACH == 1)?0:C_APPLICATION_TYPE_WACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 : 0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wach_wr_en),
.RD_EN (wach_rd_en),
.PROG_FULL_THRESH (AXI_AW_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AW_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.INJECTDBITERR (AXI_AW_INJECTDBITERR),
.INJECTSBITERR (AXI_AW_INJECTSBITERR),
.DIN (wach_din),
.DOUT (wach_dout_pkt),
.FULL (wach_full),
.EMPTY (wach_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_AW_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_AW_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_aw_overflow_i),
.VALID (),
.UNDERFLOW (axi_aw_underflow_i),
.DATA_COUNT (AXI_AW_DATA_COUNT),
.RD_DATA_COUNT (AXI_AW_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AW_WR_DATA_COUNT),
.SBITERR (AXI_AW_SBITERR),
.DBITERR (AXI_AW_DBITERR),
.wr_rst_busy (wr_rst_busy_wach),
.rd_rst_busy (rd_rst_busy_wach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wach_s_axi_awready = (IS_8SERIES == 0) ? ~wach_full : (C_IMPLEMENTATION_TYPE_WACH == 5 || C_IMPLEMENTATION_TYPE_WACH == 13) ? ~(wach_full | wr_rst_busy_wach) : ~wach_full;
assign wach_m_axi_awvalid = ~wach_empty;
assign S_AXI_AWREADY = wach_s_axi_awready;
assign AXI_AW_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_aw_underflow_i : 0;
assign AXI_AW_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_aw_overflow_i : 0;
end endgenerate // axi_write_address_channel
// Register Slice for Write Address Channel
generate if (C_WACH_TYPE == 1) begin : gwach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WACH)
)
wach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wach_din),
.S_VALID (S_AXI_AWVALID),
.S_READY (S_AXI_AWREADY),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
end endgenerate // gwach_reg_slice
generate if (C_APPLICATION_TYPE_WACH == 1 && C_HAS_AXI_WR_CHANNEL == 1) begin : axi_mm_pkt_fifo_wr
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (1)
)
wach_pkt_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (wach_dout_pkt),
.S_VALID (awvalid_pkt),
.S_READY (awready_pkt),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
assign awvalid_pkt = wach_m_axi_awvalid && awvalid_en;
assign txn_count_up = wdch_s_axi_wready && wdch_wr_en && wdch_din[0];
assign txn_count_down = wach_m_axi_awvalid && awready_pkt && awvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset == 1) begin
wr_pkt_count <= 0;
end else begin
if(txn_count_up == 1 && txn_count_down == 0) begin
wr_pkt_count <= wr_pkt_count + 1;
end else if(txn_count_up == 0 && txn_count_down == 1) begin
wr_pkt_count <= wr_pkt_count - 1;
end
end
end //Always end
assign awvalid_en = (wr_pkt_count > 0)?1:0;
end endgenerate
generate if (C_APPLICATION_TYPE_WACH != 1) begin : axi_mm_fifo_wr
assign awvalid_en = 1;
assign wach_dout = wach_dout_pkt;
assign M_AXI_AWVALID = wach_m_axi_awvalid;
end
endgenerate
generate if (IS_WR_DATA_CH == 1) begin : axi_write_data_channel
// Write protection when almost full or prog_full is high
assign wdch_we = (C_PROG_FULL_TYPE_WDCH != 0) ? wdch_s_axi_wready & S_AXI_WVALID : S_AXI_WVALID;
// Read protection when almost empty or prog_empty is high
assign wdch_re = (C_PROG_EMPTY_TYPE_WDCH != 0) ? wdch_m_axi_wvalid & M_AXI_WREADY : M_AXI_WREADY;
assign wdch_wr_en = (C_HAS_SLAVE_CE == 1) ? wdch_we & S_ACLK_EN : wdch_we;
assign wdch_rd_en = (C_HAS_MASTER_CE == 1) ? wdch_re & M_ACLK_EN : wdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WDCH == 2 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WDCH == 11 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WDCH),
.C_WR_DEPTH (C_WR_DEPTH_WDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WDCH),
.C_RD_DEPTH (C_WR_DEPTH_WDCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH),
.C_USE_ECC (C_USE_ECC_WDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wdch_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wdch_wr_en),
.RD_EN (wdch_rd_en),
.PROG_FULL_THRESH (AXI_W_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_W_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.INJECTDBITERR (AXI_W_INJECTDBITERR),
.INJECTSBITERR (AXI_W_INJECTSBITERR),
.DIN (wdch_din),
.DOUT (wdch_dout),
.FULL (wdch_full),
.EMPTY (wdch_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_W_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_W_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_w_overflow_i),
.VALID (),
.UNDERFLOW (axi_w_underflow_i),
.DATA_COUNT (AXI_W_DATA_COUNT),
.RD_DATA_COUNT (AXI_W_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_W_WR_DATA_COUNT),
.SBITERR (AXI_W_SBITERR),
.DBITERR (AXI_W_DBITERR),
.wr_rst_busy (wr_rst_busy_wdch),
.rd_rst_busy (rd_rst_busy_wdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wdch_s_axi_wready = (IS_8SERIES == 0) ? ~wdch_full : (C_IMPLEMENTATION_TYPE_WDCH == 5 || C_IMPLEMENTATION_TYPE_WDCH == 13) ? ~(wdch_full | wr_rst_busy_wdch) : ~wdch_full;
assign wdch_m_axi_wvalid = ~wdch_empty;
assign S_AXI_WREADY = wdch_s_axi_wready;
assign M_AXI_WVALID = wdch_m_axi_wvalid;
assign AXI_W_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_w_underflow_i : 0;
assign AXI_W_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_w_overflow_i : 0;
end endgenerate // axi_write_data_channel
// Register Slice for Write Data Channel
generate if (C_WDCH_TYPE == 1) begin : gwdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WDCH)
)
wdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wdch_din),
.S_VALID (S_AXI_WVALID),
.S_READY (S_AXI_WREADY),
// Master side
.M_PAYLOAD_DATA (wdch_dout),
.M_VALID (M_AXI_WVALID),
.M_READY (M_AXI_WREADY)
);
end endgenerate // gwdch_reg_slice
generate if (IS_WR_RESP_CH == 1) begin : axi_write_resp_channel
// Write protection when almost full or prog_full is high
assign wrch_we = (C_PROG_FULL_TYPE_WRCH != 0) ? wrch_m_axi_bready & M_AXI_BVALID : M_AXI_BVALID;
// Read protection when almost empty or prog_empty is high
assign wrch_re = (C_PROG_EMPTY_TYPE_WRCH != 0) ? wrch_s_axi_bvalid & S_AXI_BREADY : S_AXI_BREADY;
assign wrch_wr_en = (C_HAS_MASTER_CE == 1) ? wrch_we & M_ACLK_EN : wrch_we;
assign wrch_rd_en = (C_HAS_SLAVE_CE == 1) ? wrch_re & S_ACLK_EN : wrch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WRCH == 2 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WRCH == 11 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WRCH),
.C_WR_DEPTH (C_WR_DEPTH_WRCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WRCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_DEPTH (C_WR_DEPTH_WRCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WRCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WRCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WRCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH),
.C_USE_ECC (C_USE_ECC_WRCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WRCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WRCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wrch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wrch_wr_en),
.RD_EN (wrch_rd_en),
.PROG_FULL_THRESH (AXI_B_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_B_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.INJECTDBITERR (AXI_B_INJECTDBITERR),
.INJECTSBITERR (AXI_B_INJECTSBITERR),
.DIN (wrch_din),
.DOUT (wrch_dout),
.FULL (wrch_full),
.EMPTY (wrch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_B_PROG_FULL),
.PROG_EMPTY (AXI_B_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_b_overflow_i),
.VALID (),
.UNDERFLOW (axi_b_underflow_i),
.DATA_COUNT (AXI_B_DATA_COUNT),
.RD_DATA_COUNT (AXI_B_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_B_WR_DATA_COUNT),
.SBITERR (AXI_B_SBITERR),
.DBITERR (AXI_B_DBITERR),
.wr_rst_busy (wr_rst_busy_wrch),
.rd_rst_busy (rd_rst_busy_wrch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wrch_s_axi_bvalid = ~wrch_empty;
assign wrch_m_axi_bready = (IS_8SERIES == 0) ? ~wrch_full : (C_IMPLEMENTATION_TYPE_WRCH == 5 || C_IMPLEMENTATION_TYPE_WRCH == 13) ? ~(wrch_full | wr_rst_busy_wrch) : ~wrch_full;
assign S_AXI_BVALID = wrch_s_axi_bvalid;
assign M_AXI_BREADY = wrch_m_axi_bready;
assign AXI_B_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_b_underflow_i : 0;
assign AXI_B_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_b_overflow_i : 0;
end endgenerate // axi_write_resp_channel
// Register Slice for Write Response Channel
generate if (C_WRCH_TYPE == 1) begin : gwrch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WRCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WRCH)
)
wrch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wrch_din),
.S_VALID (M_AXI_BVALID),
.S_READY (M_AXI_BREADY),
// Master side
.M_PAYLOAD_DATA (wrch_dout),
.M_VALID (S_AXI_BVALID),
.M_READY (S_AXI_BREADY)
);
end endgenerate // gwrch_reg_slice
assign axi_wr_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_aw_underflow_i || axi_w_underflow_i || axi_b_underflow_i) : 0;
assign axi_wr_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_aw_overflow_i || axi_w_overflow_i || axi_b_overflow_i) : 0;
generate if (IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output
assign M_AXI_AWADDR = wach_dout[AWID_OFFSET-1:AWADDR_OFFSET];
assign M_AXI_AWLEN = wach_dout[AWADDR_OFFSET-1:AWLEN_OFFSET];
assign M_AXI_AWSIZE = wach_dout[AWLEN_OFFSET-1:AWSIZE_OFFSET];
assign M_AXI_AWBURST = wach_dout[AWSIZE_OFFSET-1:AWBURST_OFFSET];
assign M_AXI_AWLOCK = wach_dout[AWBURST_OFFSET-1:AWLOCK_OFFSET];
assign M_AXI_AWCACHE = wach_dout[AWLOCK_OFFSET-1:AWCACHE_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWCACHE_OFFSET-1:AWPROT_OFFSET];
assign M_AXI_AWQOS = wach_dout[AWPROT_OFFSET-1:AWQOS_OFFSET];
assign wach_din[AWID_OFFSET-1:AWADDR_OFFSET] = S_AXI_AWADDR;
assign wach_din[AWADDR_OFFSET-1:AWLEN_OFFSET] = S_AXI_AWLEN;
assign wach_din[AWLEN_OFFSET-1:AWSIZE_OFFSET] = S_AXI_AWSIZE;
assign wach_din[AWSIZE_OFFSET-1:AWBURST_OFFSET] = S_AXI_AWBURST;
assign wach_din[AWBURST_OFFSET-1:AWLOCK_OFFSET] = S_AXI_AWLOCK;
assign wach_din[AWLOCK_OFFSET-1:AWCACHE_OFFSET] = S_AXI_AWCACHE;
assign wach_din[AWCACHE_OFFSET-1:AWPROT_OFFSET] = S_AXI_AWPROT;
assign wach_din[AWPROT_OFFSET-1:AWQOS_OFFSET] = S_AXI_AWQOS;
end endgenerate // axi_wach_output
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_awregion
assign M_AXI_AWREGION = wach_dout[AWQOS_OFFSET-1:AWREGION_OFFSET];
end endgenerate // axi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_awregion
assign M_AXI_AWREGION = 0;
end endgenerate // naxi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : axi_awuser
assign M_AXI_AWUSER = wach_dout[AWREGION_OFFSET-1:AWUSER_OFFSET];
end endgenerate // axi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 0) begin : naxi_awuser
assign M_AXI_AWUSER = 0;
end endgenerate // naxi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_awid
assign M_AXI_AWID = wach_dout[C_DIN_WIDTH_WACH-1:AWID_OFFSET];
end endgenerate //axi_awid
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_awid
assign M_AXI_AWID = 0;
end endgenerate //naxi_awid
generate if (IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output
assign M_AXI_WDATA = wdch_dout[WID_OFFSET-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
assign M_AXI_WLAST = wdch_dout[0];
assign wdch_din[WID_OFFSET-1:WDATA_OFFSET] = S_AXI_WDATA;
assign wdch_din[WDATA_OFFSET-1:WSTRB_OFFSET] = S_AXI_WSTRB;
assign wdch_din[0] = S_AXI_WLAST;
end endgenerate // axi_wdch_output
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin
assign M_AXI_WID = wdch_dout[C_DIN_WIDTH_WDCH-1:WID_OFFSET];
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && (C_HAS_AXI_ID == 0 || C_AXI_TYPE != 3)) begin
assign M_AXI_WID = 0;
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1 ) begin
assign M_AXI_WUSER = wdch_dout[WSTRB_OFFSET-1:WUSER_OFFSET];
end endgenerate
generate if (C_HAS_AXI_WUSER == 0) begin
assign M_AXI_WUSER = 0;
end endgenerate
generate if (IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output
assign S_AXI_BRESP = wrch_dout[BID_OFFSET-1:BRESP_OFFSET];
assign wrch_din[BID_OFFSET-1:BRESP_OFFSET] = M_AXI_BRESP;
end endgenerate // axi_wrch_output
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : axi_buser
assign S_AXI_BUSER = wrch_dout[BRESP_OFFSET-1:BUSER_OFFSET];
end endgenerate // axi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 0) begin : naxi_buser
assign S_AXI_BUSER = 0;
end endgenerate // naxi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_bid
assign S_AXI_BID = wrch_dout[C_DIN_WIDTH_WRCH-1:BID_OFFSET];
end endgenerate // axi_bid
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_bid
assign S_AXI_BID = 0 ;
end endgenerate // naxi_bid
generate if (IS_AXI_LITE_WACH == 1 || (IS_AXI_LITE == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output1
assign wach_din = {S_AXI_AWADDR, S_AXI_AWPROT};
assign M_AXI_AWADDR = wach_dout[C_DIN_WIDTH_WACH-1:AWADDR_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWADDR_OFFSET-1:AWPROT_OFFSET];
end endgenerate // axi_wach_output1
generate if (IS_AXI_LITE_WDCH == 1 || (IS_AXI_LITE == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output1
assign wdch_din = {S_AXI_WDATA, S_AXI_WSTRB};
assign M_AXI_WDATA = wdch_dout[C_DIN_WIDTH_WDCH-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
end endgenerate // axi_wdch_output1
generate if (IS_AXI_LITE_WRCH == 1 || (IS_AXI_LITE == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output1
assign wrch_din = M_AXI_BRESP;
assign S_AXI_BRESP = wrch_dout[C_DIN_WIDTH_WRCH-1:BRESP_OFFSET];
end endgenerate // axi_wrch_output1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : gwach_din1
assign wach_din[AWREGION_OFFSET-1:AWUSER_OFFSET] = S_AXI_AWUSER;
end endgenerate // gwach_din1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwach_din2
assign wach_din[C_DIN_WIDTH_WACH-1:AWID_OFFSET] = S_AXI_AWID;
end endgenerate // gwach_din2
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : gwach_din3
assign wach_din[AWQOS_OFFSET-1:AWREGION_OFFSET] = S_AXI_AWREGION;
end endgenerate // gwach_din3
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1) begin : gwdch_din1
assign wdch_din[WSTRB_OFFSET-1:WUSER_OFFSET] = S_AXI_WUSER;
end endgenerate // gwdch_din1
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin : gwdch_din2
assign wdch_din[C_DIN_WIDTH_WDCH-1:WID_OFFSET] = S_AXI_WID;
end endgenerate // gwdch_din2
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : gwrch_din1
assign wrch_din[BRESP_OFFSET-1:BUSER_OFFSET] = M_AXI_BUSER;
end endgenerate // gwrch_din1
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwrch_din2
assign wrch_din[C_DIN_WIDTH_WRCH-1:BID_OFFSET] = M_AXI_BID;
end endgenerate // gwrch_din2
//end of axi_write_channel
//###########################################################################
// AXI FULL Read Channel (axi_read_channel)
//###########################################################################
wire [C_DIN_WIDTH_RACH-1:0] rach_din ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout_pkt ;
wire rach_full ;
wire rach_almost_full ;
wire rach_prog_full ;
wire rach_empty ;
wire rach_almost_empty ;
wire rach_prog_empty ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_din ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_dout ;
wire rdch_full ;
wire rdch_almost_full ;
wire rdch_prog_full ;
wire rdch_empty ;
wire rdch_almost_empty ;
wire rdch_prog_empty ;
wire axi_ar_underflow_i ;
wire axi_r_underflow_i ;
wire axi_ar_overflow_i ;
wire axi_r_overflow_i ;
wire axi_rd_underflow_i ;
wire axi_rd_overflow_i ;
wire rach_s_axi_arready ;
wire rach_m_axi_arvalid ;
wire rach_wr_en ;
wire rach_rd_en ;
wire rdch_m_axi_rready ;
wire rdch_s_axi_rvalid ;
wire rdch_wr_en ;
wire rdch_rd_en ;
wire arvalid_pkt ;
wire arready_pkt ;
wire arvalid_en ;
wire rdch_rd_ok ;
wire accept_next_pkt ;
integer rdch_free_space ;
integer rdch_commited_space ;
wire rach_we ;
wire rach_re ;
wire rdch_we ;
wire rdch_re ;
localparam ARID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RACH;
localparam ARADDR_OFFSET = ARID_OFFSET - C_AXI_ADDR_WIDTH;
localparam ARLEN_OFFSET = C_AXI_TYPE != 2 ? ARADDR_OFFSET - C_AXI_LEN_WIDTH : ARADDR_OFFSET;
localparam ARSIZE_OFFSET = C_AXI_TYPE != 2 ? ARLEN_OFFSET - C_AXI_SIZE_WIDTH : ARLEN_OFFSET;
localparam ARBURST_OFFSET = C_AXI_TYPE != 2 ? ARSIZE_OFFSET - C_AXI_BURST_WIDTH : ARSIZE_OFFSET;
localparam ARLOCK_OFFSET = C_AXI_TYPE != 2 ? ARBURST_OFFSET - C_AXI_LOCK_WIDTH : ARBURST_OFFSET;
localparam ARCACHE_OFFSET = C_AXI_TYPE != 2 ? ARLOCK_OFFSET - C_AXI_CACHE_WIDTH : ARLOCK_OFFSET;
localparam ARPROT_OFFSET = ARCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam ARQOS_OFFSET = ARPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam ARREGION_OFFSET = C_AXI_TYPE == 1 ? ARQOS_OFFSET - C_AXI_REGION_WIDTH : ARQOS_OFFSET;
localparam ARUSER_OFFSET = C_HAS_AXI_ARUSER == 1 ? ARREGION_OFFSET-C_AXI_ARUSER_WIDTH : ARREGION_OFFSET;
localparam RID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RDCH;
localparam RDATA_OFFSET = RID_OFFSET - C_AXI_DATA_WIDTH;
localparam RRESP_OFFSET = RDATA_OFFSET - C_AXI_RRESP_WIDTH;
localparam RUSER_OFFSET = C_HAS_AXI_RUSER == 1 ? RRESP_OFFSET-C_AXI_RUSER_WIDTH : RRESP_OFFSET;
generate if (IS_RD_ADDR_CH == 1) begin : axi_read_addr_channel
// Write protection when almost full or prog_full is high
assign rach_we = (C_PROG_FULL_TYPE_RACH != 0) ? rach_s_axi_arready & S_AXI_ARVALID : S_AXI_ARVALID;
// Read protection when almost empty or prog_empty is high
// assign rach_rd_en = (C_PROG_EMPTY_TYPE_RACH != 5) ? rach_m_axi_arvalid & M_AXI_ARREADY : M_AXI_ARREADY && arvalid_en;
assign rach_re = (C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH == 1) ?
rach_m_axi_arvalid & arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY && rach_m_axi_arvalid :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH == 1) ?
arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY : 1'b0;
assign rach_wr_en = (C_HAS_SLAVE_CE == 1) ? rach_we & S_ACLK_EN : rach_we;
assign rach_rd_en = (C_HAS_MASTER_CE == 1) ? rach_re & M_ACLK_EN : rach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RACH == 2 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RACH == 11 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RACH),
.C_WR_DEPTH (C_WR_DEPTH_RACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_DOUT_WIDTH (C_DIN_WIDTH_RACH),
.C_RD_DEPTH (C_WR_DEPTH_RACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH),
.C_USE_ECC (C_USE_ECC_RACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_RACH == 1)?0:C_APPLICATION_TYPE_RACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rach_wr_en),
.RD_EN (rach_rd_en),
.PROG_FULL_THRESH (AXI_AR_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AR_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.INJECTDBITERR (AXI_AR_INJECTDBITERR),
.INJECTSBITERR (AXI_AR_INJECTSBITERR),
.DIN (rach_din),
.DOUT (rach_dout_pkt),
.FULL (rach_full),
.EMPTY (rach_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_AR_PROG_FULL),
.PROG_EMPTY (AXI_AR_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_ar_overflow_i),
.VALID (),
.UNDERFLOW (axi_ar_underflow_i),
.DATA_COUNT (AXI_AR_DATA_COUNT),
.RD_DATA_COUNT (AXI_AR_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AR_WR_DATA_COUNT),
.SBITERR (AXI_AR_SBITERR),
.DBITERR (AXI_AR_DBITERR),
.wr_rst_busy (wr_rst_busy_rach),
.rd_rst_busy (rd_rst_busy_rach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rach_s_axi_arready = (IS_8SERIES == 0) ? ~rach_full : (C_IMPLEMENTATION_TYPE_RACH == 5 || C_IMPLEMENTATION_TYPE_RACH == 13) ? ~(rach_full | wr_rst_busy_rach) : ~rach_full;
assign rach_m_axi_arvalid = ~rach_empty;
assign S_AXI_ARREADY = rach_s_axi_arready;
assign AXI_AR_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_ar_underflow_i : 0;
assign AXI_AR_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_ar_overflow_i : 0;
end endgenerate // axi_read_addr_channel
// Register Slice for Read Address Channel
generate if (C_RACH_TYPE == 1) begin : grach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RACH)
)
rach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rach_din),
.S_VALID (S_AXI_ARVALID),
.S_READY (S_AXI_ARREADY),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice
// Register Slice for Read Address Channel for MM Packet FIFO
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH == 1) begin : grach_reg_slice_mm_pkt_fifo
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (1)
)
reg_slice_mm_pkt_fifo_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (rach_dout_pkt),
.S_VALID (arvalid_pkt),
.S_READY (arready_pkt),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice_mm_pkt_fifo
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH != 1) begin : grach_m_axi_arvalid
assign M_AXI_ARVALID = rach_m_axi_arvalid;
assign rach_dout = rach_dout_pkt;
end endgenerate // grach_m_axi_arvalid
generate if (C_APPLICATION_TYPE_RACH == 1 && C_HAS_AXI_RD_CHANNEL == 1) begin : axi_mm_pkt_fifo_rd
assign rdch_rd_ok = rdch_s_axi_rvalid && rdch_rd_en;
assign arvalid_pkt = rach_m_axi_arvalid && arvalid_en;
assign accept_next_pkt = rach_m_axi_arvalid && arready_pkt && arvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset) begin
rdch_commited_space <= 0;
end else begin
if(rdch_rd_ok && !accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space-1;
end else if(!rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1);
end else if(rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]);
end
end
end //Always end
always@(*) begin
rdch_free_space <= (C_WR_DEPTH_RDCH-(rdch_commited_space+rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1));
end
assign arvalid_en = (rdch_free_space >= 0)?1:0;
end
endgenerate
generate if (C_APPLICATION_TYPE_RACH != 1) begin : axi_mm_fifo_rd
assign arvalid_en = 1;
end
endgenerate
generate if (IS_RD_DATA_CH == 1) begin : axi_read_data_channel
// Write protection when almost full or prog_full is high
assign rdch_we = (C_PROG_FULL_TYPE_RDCH != 0) ? rdch_m_axi_rready & M_AXI_RVALID : M_AXI_RVALID;
// Read protection when almost empty or prog_empty is high
assign rdch_re = (C_PROG_EMPTY_TYPE_RDCH != 0) ? rdch_s_axi_rvalid & S_AXI_RREADY : S_AXI_RREADY;
assign rdch_wr_en = (C_HAS_MASTER_CE == 1) ? rdch_we & M_ACLK_EN : rdch_we;
assign rdch_rd_en = (C_HAS_SLAVE_CE == 1) ? rdch_re & S_ACLK_EN : rdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RDCH == 2 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RDCH == 11 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RDCH),
.C_WR_DEPTH (C_WR_DEPTH_RDCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_RDCH),
.C_RD_DEPTH (C_WR_DEPTH_RDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH),
.C_USE_ECC (C_USE_ECC_RDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_RDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rdch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rdch_wr_en),
.RD_EN (rdch_rd_en),
.PROG_FULL_THRESH (AXI_R_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_R_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.INJECTDBITERR (AXI_R_INJECTDBITERR),
.INJECTSBITERR (AXI_R_INJECTSBITERR),
.DIN (rdch_din),
.DOUT (rdch_dout),
.FULL (rdch_full),
.EMPTY (rdch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_R_PROG_FULL),
.PROG_EMPTY (AXI_R_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_r_overflow_i),
.VALID (),
.UNDERFLOW (axi_r_underflow_i),
.DATA_COUNT (AXI_R_DATA_COUNT),
.RD_DATA_COUNT (AXI_R_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_R_WR_DATA_COUNT),
.SBITERR (AXI_R_SBITERR),
.DBITERR (AXI_R_DBITERR),
.wr_rst_busy (wr_rst_busy_rdch),
.rd_rst_busy (rd_rst_busy_rdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rdch_s_axi_rvalid = ~rdch_empty;
assign rdch_m_axi_rready = (IS_8SERIES == 0) ? ~rdch_full : (C_IMPLEMENTATION_TYPE_RDCH == 5 || C_IMPLEMENTATION_TYPE_RDCH == 13) ? ~(rdch_full | wr_rst_busy_rdch) : ~rdch_full;
assign S_AXI_RVALID = rdch_s_axi_rvalid;
assign M_AXI_RREADY = rdch_m_axi_rready;
assign AXI_R_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_r_underflow_i : 0;
assign AXI_R_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_r_overflow_i : 0;
end endgenerate //axi_read_data_channel
// Register Slice for read Data Channel
generate if (C_RDCH_TYPE == 1) begin : grdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RDCH)
)
rdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rdch_din),
.S_VALID (M_AXI_RVALID),
.S_READY (M_AXI_RREADY),
// Master side
.M_PAYLOAD_DATA (rdch_dout),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY)
);
end endgenerate // grdch_reg_slice
assign axi_rd_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_ar_underflow_i || axi_r_underflow_i) : 0;
assign axi_rd_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_ar_overflow_i || axi_r_overflow_i) : 0;
generate if (IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) begin : axi_full_rach_output
assign M_AXI_ARADDR = rach_dout[ARID_OFFSET-1:ARADDR_OFFSET];
assign M_AXI_ARLEN = rach_dout[ARADDR_OFFSET-1:ARLEN_OFFSET];
assign M_AXI_ARSIZE = rach_dout[ARLEN_OFFSET-1:ARSIZE_OFFSET];
assign M_AXI_ARBURST = rach_dout[ARSIZE_OFFSET-1:ARBURST_OFFSET];
assign M_AXI_ARLOCK = rach_dout[ARBURST_OFFSET-1:ARLOCK_OFFSET];
assign M_AXI_ARCACHE = rach_dout[ARLOCK_OFFSET-1:ARCACHE_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARCACHE_OFFSET-1:ARPROT_OFFSET];
assign M_AXI_ARQOS = rach_dout[ARPROT_OFFSET-1:ARQOS_OFFSET];
assign rach_din[ARID_OFFSET-1:ARADDR_OFFSET] = S_AXI_ARADDR;
assign rach_din[ARADDR_OFFSET-1:ARLEN_OFFSET] = S_AXI_ARLEN;
assign rach_din[ARLEN_OFFSET-1:ARSIZE_OFFSET] = S_AXI_ARSIZE;
assign rach_din[ARSIZE_OFFSET-1:ARBURST_OFFSET] = S_AXI_ARBURST;
assign rach_din[ARBURST_OFFSET-1:ARLOCK_OFFSET] = S_AXI_ARLOCK;
assign rach_din[ARLOCK_OFFSET-1:ARCACHE_OFFSET] = S_AXI_ARCACHE;
assign rach_din[ARCACHE_OFFSET-1:ARPROT_OFFSET] = S_AXI_ARPROT;
assign rach_din[ARPROT_OFFSET-1:ARQOS_OFFSET] = S_AXI_ARQOS;
end endgenerate // axi_full_rach_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_arregion
assign M_AXI_ARREGION = rach_dout[ARQOS_OFFSET-1:ARREGION_OFFSET];
end endgenerate // axi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_arregion
assign M_AXI_ARREGION = 0;
end endgenerate // naxi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : axi_aruser
assign M_AXI_ARUSER = rach_dout[ARREGION_OFFSET-1:ARUSER_OFFSET];
end endgenerate // axi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 0) begin : naxi_aruser
assign M_AXI_ARUSER = 0;
end endgenerate // naxi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_arid
assign M_AXI_ARID = rach_dout[C_DIN_WIDTH_RACH-1:ARID_OFFSET];
end endgenerate // axi_arid
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_arid
assign M_AXI_ARID = 0;
end endgenerate // naxi_arid
generate if (IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) begin : axi_full_rdch_output
assign S_AXI_RDATA = rdch_dout[RID_OFFSET-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
assign S_AXI_RLAST = rdch_dout[0];
assign rdch_din[RID_OFFSET-1:RDATA_OFFSET] = M_AXI_RDATA;
assign rdch_din[RDATA_OFFSET-1:RRESP_OFFSET] = M_AXI_RRESP;
assign rdch_din[0] = M_AXI_RLAST;
end endgenerate // axi_full_rdch_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : axi_full_ruser_output
assign S_AXI_RUSER = rdch_dout[RRESP_OFFSET-1:RUSER_OFFSET];
end endgenerate // axi_full_ruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 0) begin : axi_full_nruser_output
assign S_AXI_RUSER = 0;
end endgenerate // axi_full_nruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_rid
assign S_AXI_RID = rdch_dout[C_DIN_WIDTH_RDCH-1:RID_OFFSET];
end endgenerate // axi_rid
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_rid
assign S_AXI_RID = 0;
end endgenerate // naxi_rid
generate if (IS_AXI_LITE_RACH == 1 || (IS_AXI_LITE == 1 && C_RACH_TYPE == 1)) begin : axi_lite_rach_output1
assign rach_din = {S_AXI_ARADDR, S_AXI_ARPROT};
assign M_AXI_ARADDR = rach_dout[C_DIN_WIDTH_RACH-1:ARADDR_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARADDR_OFFSET-1:ARPROT_OFFSET];
end endgenerate // axi_lite_rach_output
generate if (IS_AXI_LITE_RDCH == 1 || (IS_AXI_LITE == 1 && C_RDCH_TYPE == 1)) begin : axi_lite_rdch_output1
assign rdch_din = {M_AXI_RDATA, M_AXI_RRESP};
assign S_AXI_RDATA = rdch_dout[C_DIN_WIDTH_RDCH-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
end endgenerate // axi_lite_rdch_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : grach_din1
assign rach_din[ARREGION_OFFSET-1:ARUSER_OFFSET] = S_AXI_ARUSER;
end endgenerate // grach_din1
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grach_din2
assign rach_din[C_DIN_WIDTH_RACH-1:ARID_OFFSET] = S_AXI_ARID;
end endgenerate // grach_din2
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin
assign rach_din[ARQOS_OFFSET-1:ARREGION_OFFSET] = S_AXI_ARREGION;
end endgenerate
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : grdch_din1
assign rdch_din[RRESP_OFFSET-1:RUSER_OFFSET] = M_AXI_RUSER;
end endgenerate // grdch_din1
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grdch_din2
assign rdch_din[C_DIN_WIDTH_RDCH-1:RID_OFFSET] = M_AXI_RID;
end endgenerate // grdch_din2
//end of axi_read_channel
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_UNDERFLOW == 1) begin : gaxi_comm_uf
assign UNDERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_underflow_i || axi_rd_underflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_underflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_underflow_i : 0;
end endgenerate // gaxi_comm_uf
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_OVERFLOW == 1) begin : gaxi_comm_of
assign OVERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_overflow_i || axi_rd_overflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_overflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_overflow_i : 0;
end endgenerate // gaxi_comm_of
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic or Wiring Logic
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Write Address Channel
generate if (C_WACH_TYPE == 2) begin : gwach_pass_through
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWQOS = S_AXI_AWQOS;
assign M_AXI_AWREGION = S_AXI_AWREGION;
assign M_AXI_AWUSER = S_AXI_AWUSER;
assign S_AXI_AWREADY = M_AXI_AWREADY;
assign M_AXI_AWVALID = S_AXI_AWVALID;
end endgenerate // gwach_pass_through;
// Wiring logic for Write Data Channel
generate if (C_WDCH_TYPE == 2) begin : gwdch_pass_through
assign M_AXI_WID = S_AXI_WID;
assign M_AXI_WDATA = S_AXI_WDATA;
assign M_AXI_WSTRB = S_AXI_WSTRB;
assign M_AXI_WLAST = S_AXI_WLAST;
assign M_AXI_WUSER = S_AXI_WUSER;
assign S_AXI_WREADY = M_AXI_WREADY;
assign M_AXI_WVALID = S_AXI_WVALID;
end endgenerate // gwdch_pass_through;
// Wiring logic for Write Response Channel
generate if (C_WRCH_TYPE == 2) begin : gwrch_pass_through
assign S_AXI_BID = M_AXI_BID;
assign S_AXI_BRESP = M_AXI_BRESP;
assign S_AXI_BUSER = M_AXI_BUSER;
assign M_AXI_BREADY = S_AXI_BREADY;
assign S_AXI_BVALID = M_AXI_BVALID;
end endgenerate // gwrch_pass_through;
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Read Address Channel
generate if (C_RACH_TYPE == 2) begin : grach_pass_through
assign M_AXI_ARID = S_AXI_ARID;
assign M_AXI_ARADDR = S_AXI_ARADDR;
assign M_AXI_ARLEN = S_AXI_ARLEN;
assign M_AXI_ARSIZE = S_AXI_ARSIZE;
assign M_AXI_ARBURST = S_AXI_ARBURST;
assign M_AXI_ARLOCK = S_AXI_ARLOCK;
assign M_AXI_ARCACHE = S_AXI_ARCACHE;
assign M_AXI_ARPROT = S_AXI_ARPROT;
assign M_AXI_ARQOS = S_AXI_ARQOS;
assign M_AXI_ARREGION = S_AXI_ARREGION;
assign M_AXI_ARUSER = S_AXI_ARUSER;
assign S_AXI_ARREADY = M_AXI_ARREADY;
assign M_AXI_ARVALID = S_AXI_ARVALID;
end endgenerate // grach_pass_through;
// Wiring logic for Read Data Channel
generate if (C_RDCH_TYPE == 2) begin : grdch_pass_through
assign S_AXI_RID = M_AXI_RID;
assign S_AXI_RLAST = M_AXI_RLAST;
assign S_AXI_RUSER = M_AXI_RUSER;
assign S_AXI_RDATA = M_AXI_RDATA;
assign S_AXI_RRESP = M_AXI_RRESP;
assign S_AXI_RVALID = M_AXI_RVALID;
assign M_AXI_RREADY = S_AXI_RREADY;
end endgenerate // grdch_pass_through;
// Wiring logic for AXI Streaming
generate if (C_AXIS_TYPE == 2) begin : gaxis_pass_through
assign M_AXIS_TDATA = S_AXIS_TDATA;
assign M_AXIS_TSTRB = S_AXIS_TSTRB;
assign M_AXIS_TKEEP = S_AXIS_TKEEP;
assign M_AXIS_TID = S_AXIS_TID;
assign M_AXIS_TDEST = S_AXIS_TDEST;
assign M_AXIS_TUSER = S_AXIS_TUSER;
assign M_AXIS_TLAST = S_AXIS_TLAST;
assign S_AXIS_TREADY = M_AXIS_TREADY;
assign M_AXIS_TVALID = S_AXIS_TVALID;
end endgenerate // gaxis_pass_through;
endmodule //fifo_generator_v13_1_3
/*******************************************************************************
* Declaration of top-level module for Conventional FIFO
******************************************************************************/
module fifo_generator_v13_1_3_CONV_VER
#(
parameter C_COMMON_CLOCK = 0,
parameter C_INTERFACE_TYPE = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "virtex7", //Not allowed in Verilog model
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
parameter C_AXI_TYPE = 0
)
(
input BACKUP,
input BACKUP_MARKER,
input CLK,
input RST,
input SRST,
input WR_CLK,
input WR_RST,
input RD_CLK,
input RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input WR_EN,
input RD_EN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input INT_CLK,
input INJECTDBITERR,
input INJECTSBITERR,
output [C_DOUT_WIDTH-1:0] DOUT,
output FULL,
output ALMOST_FULL,
output WR_ACK,
output OVERFLOW,
output EMPTY,
output ALMOST_EMPTY,
output VALID,
output UNDERFLOW,
output [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_FULL,
output PROG_EMPTY,
output SBITERR,
output DBITERR,
output wr_rst_busy_o,
output wr_rst_busy,
output rd_rst_busy,
output wr_rst_i_out,
output rd_rst_i_out
);
/*
******************************************************************************
* Definition of Parameters
******************************************************************************
* C_COMMON_CLOCK : Common Clock (1), Independent Clocks (0)
* C_COUNT_TYPE : *not used
* C_DATA_COUNT_WIDTH : Width of DATA_COUNT bus
* C_DEFAULT_VALUE : *not used
* C_DIN_WIDTH : Width of DIN bus
* C_DOUT_RST_VAL : Reset value of DOUT
* C_DOUT_WIDTH : Width of DOUT bus
* C_ENABLE_RLOCS : *not used
* C_FAMILY : not used in bhv model
* C_FULL_FLAGS_RST_VAL : Full flags rst val (0 or 1)
* C_HAS_ALMOST_EMPTY : 1=Core has ALMOST_EMPTY flag
* C_HAS_ALMOST_FULL : 1=Core has ALMOST_FULL flag
* C_HAS_BACKUP : *not used
* C_HAS_DATA_COUNT : 1=Core has DATA_COUNT bus
* C_HAS_INT_CLK : not used in bhv model
* C_HAS_MEMINIT_FILE : *not used
* C_HAS_OVERFLOW : 1=Core has OVERFLOW flag
* C_HAS_RD_DATA_COUNT : 1=Core has RD_DATA_COUNT bus
* C_HAS_RD_RST : *not used
* C_HAS_RST : 1=Core has Async Rst
* C_HAS_SRST : 1=Core has Sync Rst
* C_HAS_UNDERFLOW : 1=Core has UNDERFLOW flag
* C_HAS_VALID : 1=Core has VALID flag
* C_HAS_WR_ACK : 1=Core has WR_ACK flag
* C_HAS_WR_DATA_COUNT : 1=Core has WR_DATA_COUNT bus
* C_HAS_WR_RST : *not used
* C_IMPLEMENTATION_TYPE : 0=Common-Clock Bram/Dram
* 1=Common-Clock ShiftRam
* 2=Indep. Clocks Bram/Dram
* 3=Virtex-4 Built-in
* 4=Virtex-5 Built-in
* C_INIT_WR_PNTR_VAL : *not used
* C_MEMORY_TYPE : 1=Block RAM
* 2=Distributed RAM
* 3=Shift RAM
* 4=Built-in FIFO
* C_MIF_FILE_NAME : *not used
* C_OPTIMIZATION_MODE : *not used
* C_OVERFLOW_LOW : 1=OVERFLOW active low
* C_PRELOAD_LATENCY : Latency of read: 0, 1, 2
* C_PRELOAD_REGS : 1=Use output registers
* C_PRIM_FIFO_TYPE : not used in bhv model
* C_PROG_EMPTY_THRESH_ASSERT_VAL: PROG_EMPTY assert threshold
* C_PROG_EMPTY_THRESH_NEGATE_VAL: PROG_EMPTY negate threshold
* C_PROG_EMPTY_TYPE : 0=No programmable empty
* 1=Single prog empty thresh constant
* 2=Multiple prog empty thresh constants
* 3=Single prog empty thresh input
* 4=Multiple prog empty thresh inputs
* C_PROG_FULL_THRESH_ASSERT_VAL : PROG_FULL assert threshold
* C_PROG_FULL_THRESH_NEGATE_VAL : PROG_FULL negate threshold
* C_PROG_FULL_TYPE : 0=No prog full
* 1=Single prog full thresh constant
* 2=Multiple prog full thresh constants
* 3=Single prog full thresh input
* 4=Multiple prog full thresh inputs
* C_RD_DATA_COUNT_WIDTH : Width of RD_DATA_COUNT bus
* C_RD_DEPTH : Depth of read interface (2^N)
* C_RD_FREQ : not used in bhv model
* C_RD_PNTR_WIDTH : always log2(C_RD_DEPTH)
* C_UNDERFLOW_LOW : 1=UNDERFLOW active low
* C_USE_DOUT_RST : 1=Resets DOUT on RST
* C_USE_ECC : Used for error injection purpose
* C_USE_EMBEDDED_REG : 1=Use BRAM embedded output register
* C_USE_FIFO16_FLAGS : not used in bhv model
* C_USE_FWFT_DATA_COUNT : 1=Use extra logic for FWFT data count
* C_VALID_LOW : 1=VALID active low
* C_WR_ACK_LOW : 1=WR_ACK active low
* C_WR_DATA_COUNT_WIDTH : Width of WR_DATA_COUNT bus
* C_WR_DEPTH : Depth of write interface (2^N)
* C_WR_FREQ : not used in bhv model
* C_WR_PNTR_WIDTH : always log2(C_WR_DEPTH)
* C_WR_RESPONSE_LATENCY : *not used
* C_MSGON_VAL : *not used by bhv model
* C_ENABLE_RST_SYNC : 0 = Use WR_RST & RD_RST
* 1 = Use RST
* C_ERROR_INJECTION_TYPE : 0 = No error injection
* 1 = Single bit error injection only
* 2 = Double bit error injection only
* 3 = Single and double bit error injection
******************************************************************************
* Definition of Ports
******************************************************************************
* BACKUP : Not used
* BACKUP_MARKER: Not used
* CLK : Clock
* DIN : Input data bus
* PROG_EMPTY_THRESH : Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_ASSERT: Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_NEGATE: Threshold for Programmable Empty Flag
* PROG_FULL_THRESH : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_ASSERT : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_NEGATE : Threshold for Programmable Full Flag
* RD_CLK : Read Domain Clock
* RD_EN : Read enable
* RD_RST : Read Reset
* RST : Asynchronous Reset
* SRST : Synchronous Reset
* WR_CLK : Write Domain Clock
* WR_EN : Write enable
* WR_RST : Write Reset
* INT_CLK : Internal Clock
* INJECTSBITERR: Inject Signle bit error
* INJECTDBITERR: Inject Double bit error
* ALMOST_EMPTY : One word remaining in FIFO
* ALMOST_FULL : One empty space remaining in FIFO
* DATA_COUNT : Number of data words in fifo( synchronous to CLK)
* DOUT : Output data bus
* EMPTY : Empty flag
* FULL : Full flag
* OVERFLOW : Last write rejected
* PROG_EMPTY : Programmable Empty Flag
* PROG_FULL : Programmable Full Flag
* RD_DATA_COUNT: Number of data words in fifo (synchronous to RD_CLK)
* UNDERFLOW : Last read rejected
* VALID : Last read acknowledged, DOUT bus VALID
* WR_ACK : Last write acknowledged
* WR_DATA_COUNT: Number of data words in fifo (synchronous to WR_CLK)
* SBITERR : Single Bit ECC Error Detected
* DBITERR : Double Bit ECC Error Detected
******************************************************************************
*/
//----------------------------------------------------------------------------
//- Internal Signals for delayed input signals
//- All the input signals except Clock are delayed by 100 ps and then given to
//- the models.
//----------------------------------------------------------------------------
reg rst_delayed ;
reg empty_fb ;
reg srst_delayed ;
reg wr_rst_delayed ;
reg rd_rst_delayed ;
reg wr_en_delayed ;
reg rd_en_delayed ;
reg [C_DIN_WIDTH-1:0] din_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate_delayed ;
reg injectdbiterr_delayed ;
reg injectsbiterr_delayed ;
wire empty_p0_out;
always @* rst_delayed <= #`TCQ RST ;
always @* empty_fb <= #`TCQ empty_p0_out ;
always @* srst_delayed <= #`TCQ SRST ;
always @* wr_rst_delayed <= #`TCQ WR_RST ;
always @* rd_rst_delayed <= #`TCQ RD_RST ;
always @* din_delayed <= #`TCQ DIN ;
always @* wr_en_delayed <= #`TCQ WR_EN ;
always @* rd_en_delayed <= #`TCQ RD_EN ;
always @* prog_empty_thresh_delayed <= #`TCQ PROG_EMPTY_THRESH ;
always @* prog_empty_thresh_assert_delayed <= #`TCQ PROG_EMPTY_THRESH_ASSERT ;
always @* prog_empty_thresh_negate_delayed <= #`TCQ PROG_EMPTY_THRESH_NEGATE ;
always @* prog_full_thresh_delayed <= #`TCQ PROG_FULL_THRESH ;
always @* prog_full_thresh_assert_delayed <= #`TCQ PROG_FULL_THRESH_ASSERT ;
always @* prog_full_thresh_negate_delayed <= #`TCQ PROG_FULL_THRESH_NEGATE ;
always @* injectdbiterr_delayed <= #`TCQ INJECTDBITERR ;
always @* injectsbiterr_delayed <= #`TCQ INJECTSBITERR ;
/*****************************************************************************
* Derived parameters
****************************************************************************/
//There are 2 Verilog behavioral models
// 0 = Common-Clock FIFO/ShiftRam FIFO
// 1 = Independent Clocks FIFO
// 2 = Low Latency Synchronous FIFO
// 3 = Low Latency Asynchronous FIFO
localparam C_VERILOG_IMPL = (C_FIFO_TYPE == 3) ? 2 :
(C_IMPLEMENTATION_TYPE == 2) ? 1 : 0;
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//Internal reset signals
reg rd_rst_asreg = 0;
wire rd_rst_asreg_d1;
wire rd_rst_asreg_d2;
reg rd_rst_asreg_d3 = 0;
reg rd_rst_reg = 0;
wire rd_rst_comb;
reg wr_rst_d0 = 0;
reg wr_rst_d1 = 0;
reg wr_rst_d2 = 0;
reg rd_rst_d0 = 0;
reg rd_rst_d1 = 0;
reg rd_rst_d2 = 0;
reg rd_rst_d3 = 0;
reg wrrst_done = 0;
reg rdrst_done = 0;
reg wr_rst_asreg = 0;
wire wr_rst_asreg_d1;
wire wr_rst_asreg_d2;
reg wr_rst_asreg_d3 = 0;
reg rd_rst_wr_d0 = 0;
reg rd_rst_wr_d1 = 0;
reg rd_rst_wr_d2 = 0;
reg wr_rst_reg = 0;
reg rst_active_i = 1'b1;
reg rst_delayed_d1 = 1'b1;
reg rst_delayed_d2 = 1'b1;
wire wr_rst_comb;
wire wr_rst_i;
wire rd_rst_i;
wire rst_i;
//Internal reset signals
reg rst_asreg = 0;
reg srst_asreg = 0;
wire rst_asreg_d1;
wire rst_asreg_d2;
reg srst_asreg_d1 = 0;
reg srst_asreg_d2 = 0;
reg rst_reg = 0;
reg srst_reg = 0;
wire rst_comb;
wire srst_comb;
reg rst_full_gen_i = 0;
reg rst_full_ff_i = 0;
reg [2:0] sckt_ff0_bsy_o_i = {3{1'b0}};
wire RD_CLK_P0_IN;
wire RST_P0_IN;
wire RD_EN_FIFO_IN;
wire RD_EN_P0_IN;
wire ALMOST_EMPTY_FIFO_OUT;
wire ALMOST_FULL_FIFO_OUT;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT_FIFO_OUT;
wire [C_DOUT_WIDTH-1:0] DOUT_FIFO_OUT;
wire EMPTY_FIFO_OUT;
wire fifo_empty_fb;
wire FULL_FIFO_OUT;
wire OVERFLOW_FIFO_OUT;
wire PROG_EMPTY_FIFO_OUT;
wire PROG_FULL_FIFO_OUT;
wire VALID_FIFO_OUT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT_FIFO_OUT;
wire UNDERFLOW_FIFO_OUT;
wire WR_ACK_FIFO_OUT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT_FIFO_OUT;
//***************************************************************************
// Internal Signals
// The core uses either the internal_ wires or the preload0_ wires depending
// on whether the core uses Preload0 or not.
// When using preload0, the internal signals connect the internal core to
// the preload logic, and the external core's interfaces are tied to the
// preload0 signals from the preload logic.
//***************************************************************************
wire [C_DOUT_WIDTH-1:0] DATA_P0_OUT;
wire VALID_P0_OUT;
wire EMPTY_P0_OUT;
wire ALMOSTEMPTY_P0_OUT;
reg EMPTY_P0_OUT_Q;
reg ALMOSTEMPTY_P0_OUT_Q;
wire UNDERFLOW_P0_OUT;
wire RDEN_P0_OUT;
wire [C_DOUT_WIDTH-1:0] DATA_P0_IN;
wire EMPTY_P0_IN;
reg [31:0] DATA_COUNT_FWFT;
reg SS_FWFT_WR ;
reg SS_FWFT_RD ;
wire sbiterr_fifo_out;
wire dbiterr_fifo_out;
wire inject_sbit_err;
wire inject_dbit_err;
wire safety_ckt_wr_rst;
wire safety_ckt_rd_rst;
reg sckt_wr_rst_i_q = 1'b0;
wire w_fab_read_data_valid_i;
wire w_read_data_valid_i;
wire w_ram_valid_i;
// Assign 0 if not selected to avoid 'X' propogation to S/DBITERR.
assign inject_sbit_err = ((C_ERROR_INJECTION_TYPE == 1) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectsbiterr_delayed : 0;
assign inject_dbit_err = ((C_ERROR_INJECTION_TYPE == 2) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectdbiterr_delayed : 0;
assign wr_rst_i_out = wr_rst_i;
assign rd_rst_i_out = rd_rst_i;
assign wr_rst_busy_o = wr_rst_busy | rst_full_gen_i | sckt_ff0_bsy_o_i[2];
generate if (C_FULL_FLAGS_RST_VAL == 0 && C_EN_SAFETY_CKT == 1) begin : gsckt_bsy_o
wire clk_i = C_COMMON_CLOCK ? CLK : WR_CLK;
always @ (posedge clk_i)
sckt_ff0_bsy_o_i <= {sckt_ff0_bsy_o_i[1:0],wr_rst_busy};
end endgenerate
// Choose the behavioral model to instantiate based on the C_VERILOG_IMPL
// parameter (1=Independent Clocks, 0=Common Clock)
localparam FULL_FLAGS_RST_VAL = (C_HAS_SRST == 1) ? 0 : C_FULL_FLAGS_RST_VAL;
generate
case (C_VERILOG_IMPL)
0 : begin : block1
//Common Clock Behavioral Model
fifo_generator_v13_1_3_bhv_ver_ss
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL ((C_AXI_TYPE == 0 && C_FIFO_TYPE == 1) ? 1 : C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ss
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.CLK (CLK),
.RST (rst_i),
.SRST (srst_delayed),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.USER_EMPTY_FB (empty_fb),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.DATA_COUNT (DATA_COUNT_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
1 : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.fab_read_data_valid_i (w_fab_read_data_valid_i),
.read_data_valid_i (w_read_data_valid_i),
.ram_valid_i (w_ram_valid_i),
.DBITERR (dbiterr_fifo_out)
);
end
2 : begin : ll_afifo_inst
fifo_generator_v13_1_3_beh_ver_ll_afifo
#(
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ll_afifo
(
.DIN (din_delayed),
.RD_CLK (RD_CLK),
.RD_EN (rd_en_delayed),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.WR_CLK (WR_CLK),
.WR_EN (wr_en_delayed),
.DOUT (DOUT),
.EMPTY (EMPTY),
.FULL (FULL)
);
end
default : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
endcase
endgenerate
//**************************************************************************
// Connect Internal Signals
// (Signals labeled internal_*)
// In the normal case, these signals tie directly to the FIFO's inputs and
// outputs.
// In the case of Preload Latency 0 or 1, there are intermediate
// signals between the internal FIFO and the preload logic.
//**************************************************************************
//***********************************************
// If First-Word Fall-Through, instantiate
// the preload0 (FWFT) module
//***********************************************
wire rd_en_to_fwft_fifo;
wire sbiterr_fwft;
wire dbiterr_fwft;
wire [C_DOUT_WIDTH-1:0] dout_fwft;
wire empty_fwft;
wire rd_en_fifo_in;
wire stage2_reg_en_i;
wire [1:0] valid_stages_i;
wire rst_fwft;
//wire empty_p0_out;
reg [C_SYNCHRONIZER_STAGE-1:0] pkt_empty_sync = 'b1;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
localparam IS_PKT_FIFO = (C_FIFO_TYPE == 1) ? 1 : 0;
localparam IS_AXIS_PKT_FIFO = (C_FIFO_TYPE == 1 && C_AXI_TYPE == 0) ? 1 : 0;
assign rst_fwft = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 1'b0;
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 3) begin : block2
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
fgpl0
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (RST_P0_IN),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (RD_EN_P0_IN),
.FIFOEMPTY (EMPTY_P0_IN),
.FIFODATA (DATA_P0_IN),
.FIFOSBITERR (sbiterr_fifo_out),
.FIFODBITERR (dbiterr_fifo_out),
// Output
.USERDATA (dout_fwft),
.USERVALID (VALID_P0_OUT),
.USEREMPTY (empty_fwft),
.USERALMOSTEMPTY (ALMOSTEMPTY_P0_OUT),
.USERUNDERFLOW (UNDERFLOW_P0_OUT),
.RAMVALID (),
.FIFORDEN (rd_en_fifo_in),
.USERSBITERR (sbiterr_fwft),
.USERDBITERR (dbiterr_fwft),
.STAGE2_REG_EN (stage2_reg_en_i),
.fab_read_data_valid_i_o (w_fab_read_data_valid_i),
.read_data_valid_i_o (w_read_data_valid_i),
.ram_valid_i_o (w_ram_valid_i),
.VALID_STAGES (valid_stages_i)
);
//***********************************************
// Connect inputs to preload (FWFT) module
//***********************************************
//Connect the RD_CLK of the Preload (FWFT) module to CLK if we
// have a common-clock FIFO, or RD_CLK if we have an
// independent clock FIFO
assign RD_CLK_P0_IN = ((C_VERILOG_IMPL == 0) ? CLK : RD_CLK);
assign RST_P0_IN = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 0;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
assign EMPTY_P0_IN = C_EN_SAFETY_CKT ? fifo_empty_fb : EMPTY_FIFO_OUT;
assign DATA_P0_IN = DOUT_FIFO_OUT;
//***********************************************
// Connect outputs from preload (FWFT) module
//***********************************************
assign VALID = VALID_P0_OUT ;
assign ALMOST_EMPTY = ALMOSTEMPTY_P0_OUT;
assign UNDERFLOW = UNDERFLOW_P0_OUT ;
assign RD_EN_FIFO_IN = rd_en_fifo_in;
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
assign DATA_COUNT = (C_USE_FWFT_DATA_COUNT == 0)? DATA_COUNT_FIFO_OUT:
(C_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) ? DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:0] :
DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH+1];
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
EMPTY_P0_OUT_Q <= 1;
ALMOSTEMPTY_P0_OUT_Q <= 1;
end else begin
EMPTY_P0_OUT_Q <= #`TCQ empty_p0_out;
// EMPTY_P0_OUT_Q <= #`TCQ EMPTY_FIFO_OUT;
ALMOSTEMPTY_P0_OUT_Q <= #`TCQ ALMOSTEMPTY_P0_OUT;
end
end //always
//***********************************************
// logic for common-clock data count when FWFT is selected
//***********************************************
initial begin
SS_FWFT_RD = 1'b0;
DATA_COUNT_FWFT = 0 ;
SS_FWFT_WR = 1'b0 ;
end //initial
//***********************************************
// common-clock data count is implemented as an
// up-down counter. SS_FWFT_WR and SS_FWFT_RD
// are the up/down enables for the counter.
//***********************************************
always @ (RD_EN or VALID_P0_OUT or WR_EN or FULL_FIFO_OUT or empty_p0_out) begin
if (C_VALID_LOW == 1) begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && ~VALID_P0_OUT) : (~empty_p0_out && RD_EN && ~VALID_P0_OUT) ;
end else begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && VALID_P0_OUT) : (~empty_p0_out && RD_EN && VALID_P0_OUT) ;
end
SS_FWFT_WR = (WR_EN && (~FULL_FIFO_OUT)) ;
end
//***********************************************
// common-clock data count is implemented as an
// up-down counter for FWFT. This always block
// calculates the counter.
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
DATA_COUNT_FWFT <= 0;
end else begin
//if (srst_delayed && (C_HAS_SRST == 1) ) begin
if ((srst_delayed | wr_rst_busy | rd_rst_busy) && (C_HAS_SRST == 1) ) begin
DATA_COUNT_FWFT <= #`TCQ 0;
end else begin
case ( {SS_FWFT_WR, SS_FWFT_RD})
2'b00: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
2'b01: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT - 1 ;
2'b10: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT + 1 ;
2'b11: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
endcase
end //if SRST
end //IF RST
end //always
end endgenerate // : block2
// AXI Streaming Packet FIFO
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_plus1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_reg = 0;
reg partial_packet = 0;
reg stage1_eop_d1 = 0;
reg rd_en_fifo_in_d1 = 0;
reg eop_at_stage2 = 0;
reg ram_pkt_empty = 0;
reg ram_pkt_empty_d1 = 0;
wire [C_DOUT_WIDTH-1:0] dout_p0_out;
wire packet_empty_wr;
wire wr_rst_fwft_pkt_fifo;
wire dummy_wr_eop;
wire ram_wr_en_pkt_fifo;
wire wr_eop;
wire ram_rd_en_compare;
wire stage1_eop;
wire pkt_ready_to_read;
wire rd_en_2_stage2;
// Generate Dummy WR_EOP for partial packet (Only for AXI Streaming)
// When Packet EMPTY is high, and FIFO is full, then generate the dummy WR_EOP
// When dummy WR_EOP is high, mask the actual EOP to avoid double increment of
// write packet count
generate if (IS_FWFT == 1 && IS_AXIS_PKT_FIFO == 1) begin // gdummy_wr_eop
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
partial_packet <= 1'b0;
else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy)
partial_packet <= #`TCQ 1'b0;
else if (ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]))
partial_packet <= #`TCQ 1'b1;
else if (partial_packet && din_delayed[0] && ram_wr_en_pkt_fifo)
partial_packet <= #`TCQ 1'b0;
end
end
end endgenerate // gdummy_wr_eop
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1) begin // gpkt_fifo_fwft
assign wr_rst_fwft_pkt_fifo = (C_COMMON_CLOCK == 0) ? wr_rst_i : (C_HAS_RST == 1) ? rst_i:1'b0;
assign dummy_wr_eop = ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]) && (~partial_packet);
assign packet_empty_wr = (C_COMMON_CLOCK == 1) ? empty_p0_out : pkt_empty_sync[C_SYNCHRONIZER_STAGE-1];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
stage1_eop_d1 <= 1'b0;
rd_en_fifo_in_d1 <= 1'b0;
end else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
stage1_eop_d1 <= #`TCQ 1'b0;
rd_en_fifo_in_d1 <= #`TCQ 1'b0;
end else begin
stage1_eop_d1 <= #`TCQ stage1_eop;
rd_en_fifo_in_d1 <= #`TCQ rd_en_fifo_in;
end
end
end
assign stage1_eop = (rd_en_fifo_in_d1) ? DOUT_FIFO_OUT[0] : stage1_eop_d1;
assign ram_wr_en_pkt_fifo = wr_en_delayed && (~FULL_FIFO_OUT);
assign wr_eop = ram_wr_en_pkt_fifo && ((din_delayed[0] && (~partial_packet)) || dummy_wr_eop);
assign ram_rd_en_compare = stage2_reg_en_i && stage1_eop;
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (2) // Enable low latency fwft logic
)
pkt_fifo_fwft
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (rst_fwft),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (rd_en_delayed),
.FIFOEMPTY (pkt_ready_to_read),
.FIFODATA (dout_fwft),
.FIFOSBITERR (sbiterr_fwft),
.FIFODBITERR (dbiterr_fwft),
// Output
.USERDATA (dout_p0_out),
.USERVALID (),
.USEREMPTY (empty_p0_out),
.USERALMOSTEMPTY (),
.USERUNDERFLOW (),
.RAMVALID (),
.FIFORDEN (rd_en_2_stage2),
.USERSBITERR (SBITERR),
.USERDBITERR (DBITERR),
.STAGE2_REG_EN (),
.VALID_STAGES ()
);
assign pkt_ready_to_read = ~(!(ram_pkt_empty || empty_fwft) && ((valid_stages_i[0] && valid_stages_i[1]) || eop_at_stage2));
assign rd_en_to_fwft_fifo = ~empty_fwft && rd_en_2_stage2;
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
eop_at_stage2 <= 1'b0;
else if (stage2_reg_en_i)
eop_at_stage2 <= #`TCQ stage1_eop;
end
//---------------------------------------------------------------------------
// Write and Read Packet Count
//---------------------------------------------------------------------------
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count <= 0;
else if (srst_delayed | wr_rst_busy | rd_rst_busy)
wr_pkt_count <= #`TCQ 0;
else if (wr_eop)
wr_pkt_count <= #`TCQ wr_pkt_count + 1;
end
end endgenerate // gpkt_fifo_fwft
assign DOUT = (C_FIFO_TYPE != 1) ? dout_fwft : dout_p0_out;
assign EMPTY = (C_FIFO_TYPE != 1) ? empty_fwft : empty_p0_out;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 1) begin // grss_pkt_cnt
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
rd_pkt_count <= 0;
rd_pkt_count_plus1 <= 1;
end else if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
rd_pkt_count <= #`TCQ 0;
rd_pkt_count_plus1 <= #`TCQ 1;
end else if (stage2_reg_en_i && stage1_eop) begin
rd_pkt_count <= #`TCQ rd_pkt_count + 1;
rd_pkt_count_plus1 <= #`TCQ rd_pkt_count_plus1 + 1;
end
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (SRST | wr_rst_busy | rd_rst_busy) begin
ram_pkt_empty <= #`TCQ 1'b1;
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count) && wr_eop) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count_plus1 == wr_pkt_count) && ~wr_eop && ~ALMOST_FULL_FIFO_OUT && ram_rd_en_compare) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
end endgenerate //grss_pkt_cnt
localparam SYNC_STAGE_WIDTH = (C_SYNCHRONIZER_STAGE+1)*C_WR_PNTR_WIDTH;
reg [SYNC_STAGE_WIDTH-1:0] wr_pkt_count_q = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_b2g = 0;
wire [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_rd;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 0) begin // gras_pkt_cnt
// Delay the write packet count in write clock domain to accomodate the binary to gray conversion delay
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count_b2g <= 0;
else
wr_pkt_count_b2g <= #`TCQ wr_pkt_count;
end
// Synchronize the delayed write packet count in read domain, and also compensate the gray to binay conversion delay
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
wr_pkt_count_q <= 0;
else
wr_pkt_count_q <= #`TCQ {wr_pkt_count_q[SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH-1:0],wr_pkt_count_b2g};
end
always @* begin
if (stage1_eop)
rd_pkt_count <= rd_pkt_count_reg + 1;
else
rd_pkt_count <= rd_pkt_count_reg;
end
assign wr_pkt_count_rd = wr_pkt_count_q[SYNC_STAGE_WIDTH-1:SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
rd_pkt_count_reg <= 0;
else if (rd_en_fifo_in)
rd_pkt_count_reg <= #`TCQ rd_pkt_count;
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (rd_pkt_count != wr_pkt_count_rd) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count_rd) && stage2_reg_en_i) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
// Synchronize the empty in write domain
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
pkt_empty_sync <= 'b1;
else
pkt_empty_sync <= #`TCQ {pkt_empty_sync[C_SYNCHRONIZER_STAGE-2:0], empty_p0_out};
end
end endgenerate //gras_pkt_cnt
generate if (IS_FWFT == 0 || C_FIFO_TYPE == 3) begin : STD_FIFO
//***********************************************
// If NOT First-Word Fall-Through, wire the outputs
// of the internal _ss or _as FIFO directly to the
// output, and do not instantiate the preload0
// module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VALID = VALID_FIFO_OUT;
assign EMPTY = EMPTY_FIFO_OUT;
assign ALMOST_EMPTY = ALMOST_EMPTY_FIFO_OUT;
assign EMPTY_P0_IN = 0;
assign UNDERFLOW = UNDERFLOW_FIFO_OUT;
assign DATA_COUNT = DATA_COUNT_FIFO_OUT;
assign SBITERR = sbiterr_fifo_out;
assign DBITERR = dbiterr_fifo_out;
end endgenerate // STD_FIFO
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 1) begin : NO_PKT_FIFO
assign empty_p0_out = empty_fwft;
assign SBITERR = sbiterr_fwft;
assign DBITERR = dbiterr_fwft;
assign DOUT = dout_fwft;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
end endgenerate // NO_PKT_FIFO
//***********************************************
// Connect user flags to internal signals
//***********************************************
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//RD_DATA_COUNT is 0 when EMPTY and 1 when ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block3
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : RD_DATA_COUNT_FIFO_OUT);
end //block_ic
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block30
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : RD_DATA_COUNT_FIFO_OUT);
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block30_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : (RD_DATA_COUNT_FIFO_OUT));
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30_both
endgenerate
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block3_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : (RD_DATA_COUNT_FIFO_OUT));
end //block_ic_both
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3_both
endgenerate
//If we are not using extra logic for the FWFT data count,
//then connect RD_DATA_COUNT to the RD_DATA_COUNT from the
//internal FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==0 ) begin : block31
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Always connect WR_DATA_COUNT to the WR_DATA_COUNT from the internal
//FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==1) begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
else begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Connect other flags to the internal FIFO instance
assign FULL = FULL_FIFO_OUT;
assign ALMOST_FULL = ALMOST_FULL_FIFO_OUT;
assign WR_ACK = WR_ACK_FIFO_OUT;
assign OVERFLOW = OVERFLOW_FIFO_OUT;
assign PROG_FULL = PROG_FULL_FIFO_OUT;
assign PROG_EMPTY = PROG_EMPTY_FIFO_OUT;
/**************************************************************************
* find_log2
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// if an asynchronous FIFO has been selected, display a message that the FIFO
// will not be cycle-accurate in simulation
initial begin
if (C_IMPLEMENTATION_TYPE == 2) begin
$display("WARNING: Behavioral models for independent clock FIFO configurations do not model synchronization delays. The behavioral models are functionally correct, and will represent the behavior of the configured FIFO. See the FIFO Generator User Guide for more information.");
end else if (C_MEMORY_TYPE == 4) begin
$display("FAILURE : Behavioral models do not support built-in FIFO configurations. Please use post-synthesis or post-implement simulation in Vivado.");
$finish;
end
if (C_WR_PNTR_WIDTH != find_log2(C_WR_DEPTH)) begin
$display("FAILURE : C_WR_PNTR_WIDTH is not log2 of C_WR_DEPTH.");
$finish;
end
if (C_RD_PNTR_WIDTH != find_log2(C_RD_DEPTH)) begin
$display("FAILURE : C_RD_PNTR_WIDTH is not log2 of C_RD_DEPTH.");
$finish;
end
if (C_USE_ECC == 1) begin
if (C_DIN_WIDTH != C_DOUT_WIDTH) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be equal for ECC configuration.");
$finish;
end
if (C_DIN_WIDTH == 1 && C_ERROR_INJECTION_TYPE > 1) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be > 1 for double bit error injection.");
$finish;
end
end
end //initial
/**************************************************************************
* Internal reset logic
**************************************************************************/
assign wr_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? wr_rst_reg : 0;
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? rd_rst_reg : 0;
assign rst_i = C_HAS_RST ? rst_reg : 0;
wire rst_2_sync;
wire rst_2_sync_safety = (C_ENABLE_RST_SYNC == 1) ? rst_delayed : RD_RST;
wire clk_2_sync = (C_COMMON_CLOCK == 1) ? CLK : WR_CLK;
wire clk_2_sync_safety = (C_COMMON_CLOCK == 1) ? CLK : RD_CLK;
localparam RST_SYNC_STAGES = (C_EN_SAFETY_CKT == 0) ? C_SYNCHRONIZER_STAGE :
(C_COMMON_CLOCK == 1) ? 3 : C_SYNCHRONIZER_STAGE+2;
reg [RST_SYNC_STAGES-1:0] wrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] arst_sync_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_wr = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_ext = {RST_SYNC_STAGES{1'b0}};
reg [1:0] wrst_cc = {2{1'b0}};
reg [1:0] rrst_cc = {2{1'b0}};
generate
if (C_EN_SAFETY_CKT == 1 && C_INTERFACE_TYPE == 0) begin : grst_safety_ckt
reg[1:0] rst_d1_safety =1;
reg[1:0] rst_d2_safety =1;
reg[1:0] rst_d3_safety =1;
reg[1:0] rst_d4_safety =1;
reg[1:0] rst_d5_safety =1;
reg[1:0] rst_d6_safety =1;
reg[1:0] rst_d7_safety =1;
always@(posedge rst_2_sync_safety or posedge clk_2_sync_safety) begin : prst
if (rst_2_sync_safety == 1'b1) begin
rst_d1_safety <= 1'b1;
rst_d2_safety <= 1'b1;
rst_d3_safety <= 1'b1;
rst_d4_safety <= 1'b1;
rst_d5_safety <= 1'b1;
rst_d6_safety <= 1'b1;
rst_d7_safety <= 1'b1;
end
else begin
rst_d1_safety <= #`TCQ 1'b0;
rst_d2_safety <= #`TCQ rst_d1_safety;
rst_d3_safety <= #`TCQ rst_d2_safety;
rst_d4_safety <= #`TCQ rst_d3_safety;
rst_d5_safety <= #`TCQ rst_d4_safety;
rst_d6_safety <= #`TCQ rst_d5_safety;
rst_d7_safety <= #`TCQ rst_d6_safety;
end //if
end //prst
always@(posedge rst_d7_safety or posedge WR_EN) begin : assert_safety
if(rst_d7_safety == 1 && WR_EN == 1) begin
$display("WARNING:A write attempt has been made within the 7 clock cycles of reset de-assertion. This can lead to data discrepancy when safety circuit is enabled.");
end //if
end //always
end // grst_safety_ckt
endgenerate
// if (C_EN_SAFET_CKT == 1)
// assertion:the reset shud be atleast 3 cycles wide.
generate
reg safety_ckt_wr_rst_i = 1'b0;
if (C_ENABLE_RST_SYNC == 0) begin : gnrst_sync
always @* begin
wr_rst_reg <= wr_rst_delayed;
rd_rst_reg <= rd_rst_delayed;
rst_reg <= 1'b0;
srst_reg <= 1'b0;
end
assign rst_2_sync = wr_rst_delayed;
assign wr_rst_busy = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
// end : gnrst_sync
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 0) begin : g7s_ic_rst
reg fifo_wrst_done = 1'b0;
reg fifo_rrst_done = 1'b0;
reg sckt_wrst_i = 1'b0;
reg sckt_wrst_i_q = 1'b0;
reg rd_rst_active = 1'b0;
reg rd_rst_middle = 1'b0;
reg sckt_rd_rst_d1 = 1'b0;
reg [1:0] rst_delayed_ic_w = 2'h0;
wire rst_delayed_ic_w_i;
reg [1:0] rst_delayed_ic_r = 2'h0;
wire rst_delayed_ic_r_i;
wire arst_sync_rst;
wire fifo_rst_done;
wire fifo_rst_active;
assign wr_rst_comb = !wr_rst_asreg_d2 && wr_rst_asreg;
assign rd_rst_comb = C_EN_SAFETY_CKT ? (!rd_rst_asreg_d2 && rd_rst_asreg) || rd_rst_active : !rd_rst_asreg_d2 && rd_rst_asreg;
assign rst_2_sync = rst_delayed_ic_w_i;
assign arst_sync_rst = arst_sync_q[RST_SYNC_STAGES-1];
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | fifo_rst_active : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? safety_ckt_rd_rst : 1'b0;
assign fifo_rst_done = fifo_wrst_done & fifo_rrst_done;
assign fifo_rst_active = sckt_wrst_i | wrst_ext[RST_SYNC_STAGES-1] | rrst_wr[RST_SYNC_STAGES-1];
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_w <= 2'b11;
else
rst_delayed_ic_w <= #`TCQ {rst_delayed_ic_w[0],1'b0};
end
assign rst_delayed_ic_w_i = rst_delayed_ic_w[1];
always @(posedge RD_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_r <= 2'b11;
else
rst_delayed_ic_r <= #`TCQ {rst_delayed_ic_r[0],1'b0};
end
assign rst_delayed_ic_r_i = rst_delayed_ic_r[1];
always @(posedge WR_CLK) begin
sckt_wrst_i_q <= #`TCQ sckt_wrst_i;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ sckt_wrst_i | wr_rst_busy | sckt_wr_rst_i_q;
if (arst_sync_rst && ~fifo_rst_active)
sckt_wrst_i <= #`TCQ 1'b1;
else if (sckt_wrst_i && fifo_rst_done)
sckt_wrst_i <= #`TCQ 1'b0;
else
sckt_wrst_i <= #`TCQ sckt_wrst_i;
if (rrst_wr[RST_SYNC_STAGES-2] & ~rrst_wr[RST_SYNC_STAGES-1])
fifo_rrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_rrst_done <= #`TCQ 1'b0;
else
fifo_rrst_done <= #`TCQ fifo_rrst_done;
if (wrst_ext[RST_SYNC_STAGES-2] & ~wrst_ext[RST_SYNC_STAGES-1])
fifo_wrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_wrst_done <= #`TCQ 1'b0;
else
fifo_wrst_done <= #`TCQ fifo_wrst_done;
end
always @(posedge WR_CLK or posedge rst_delayed_ic_w_i) begin
if (rst_delayed_ic_w_i == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],wr_rst_asreg};
wrst_ext <= #`TCQ {wrst_ext[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_wr <= #`TCQ {rrst_wr[RST_SYNC_STAGES-2:0],safety_ckt_rd_rst};
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_ic_w_i};
end
assign wr_rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign wr_rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge WR_CLK or posedge wr_rst_comb) begin
if (wr_rst_comb == 1'b1) begin
wr_rst_reg <= 1'b1;
end else begin
wr_rst_reg <= #`TCQ 1'b0;
end
end
always @(posedge RD_CLK or posedge rst_delayed_ic_r_i) begin
if (rst_delayed_ic_r_i == 1'b1) begin
rd_rst_asreg <= 1'b1;
end else begin
if (rd_rst_asreg_d1 == 1'b1) begin
rd_rst_asreg <= #`TCQ 1'b0;
end else begin
rd_rst_asreg <= #`TCQ rd_rst_asreg;
end
end
end
always @(posedge RD_CLK) begin
rrst_reg <= #`TCQ {rrst_reg[RST_SYNC_STAGES-2:0],rd_rst_asreg};
rrst_q <= #`TCQ {rrst_q[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_cc <= #`TCQ {rrst_cc[0],rd_rst_asreg_d2};
sckt_rd_rst_d1 <= #`TCQ safety_ckt_rd_rst;
if (!rd_rst_middle && rrst_reg[1] && !rrst_reg[2]) begin
rd_rst_active <= #`TCQ 1'b1;
rd_rst_middle <= #`TCQ 1'b1;
end else if (safety_ckt_rd_rst)
rd_rst_active <= #`TCQ 1'b0;
else if (sckt_rd_rst_d1 && !safety_ckt_rd_rst)
rd_rst_middle <= #`TCQ 1'b0;
end
assign rd_rst_asreg_d1 = rrst_reg[RST_SYNC_STAGES-2];
assign rd_rst_asreg_d2 = C_EN_SAFETY_CKT ? rrst_reg[RST_SYNC_STAGES-1] : rrst_reg[1];
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rrst_q[2] : 1'b0;
always @(posedge RD_CLK or posedge rd_rst_comb) begin
if (rd_rst_comb == 1'b1) begin
rd_rst_reg <= 1'b1;
end else begin
rd_rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_ic_rst
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 1) begin : g7s_cc_rst
reg [1:0] rst_delayed_cc = 2'h0;
wire rst_delayed_cc_i;
assign rst_comb = !rst_asreg_d2 && rst_asreg;
assign rst_2_sync = rst_delayed_cc_i;
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | wrst_cc[1] : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? arst_sync_q[1] | arst_sync_q[RST_SYNC_STAGES-1] | wrst_cc[1] : 1'b0;
always @(posedge CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1)
rst_delayed_cc <= 2'b11;
else
rst_delayed_cc <= #`TCQ {rst_delayed_cc,1'b0};
end
assign rst_delayed_cc_i = rst_delayed_cc[1];
always @(posedge CLK or posedge rst_delayed_cc_i) begin
if (rst_delayed_cc_i == 1'b1) begin
rst_asreg <= 1'b1;
end else begin
if (rst_asreg_d1 == 1'b1) begin
rst_asreg <= #`TCQ 1'b0;
end else begin
rst_asreg <= #`TCQ rst_asreg;
end
end
end
always @(posedge CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],rst_asreg};
wrst_cc <= #`TCQ {wrst_cc[0],arst_sync_q[RST_SYNC_STAGES-1]};
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ wrst_cc[1] | wr_rst_busy | sckt_wr_rst_i_q;
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_cc_i};
end
assign rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge CLK or posedge rst_comb) begin
if (rst_comb == 1'b1) begin
rst_reg <= 1'b1;
end else begin
rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_cc_rst
end else if (IS_8SERIES == 1 && C_HAS_SRST == 1 && C_COMMON_CLOCK == 1) begin : g8s_cc_rst
assign wr_rst_busy = (C_MEMORY_TYPE != 4) ? rst_reg : rst_active_i;
assign rd_rst_busy = rst_reg;
assign rst_2_sync = srst_delayed;
always @* rst_full_ff_i <= rst_reg;
always @* rst_full_gen_i <= C_FULL_FLAGS_RST_VAL == 1 ? rst_active_i : 0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
always @(posedge CLK) begin
rst_delayed_d1 <= #`TCQ srst_delayed;
rst_delayed_d2 <= #`TCQ rst_delayed_d1;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
if (rst_reg || rst_delayed_d2) begin
rst_active_i <= #`TCQ 1'b1;
end else begin
rst_active_i <= #`TCQ rst_reg;
end
end
always @(posedge CLK) begin
if (~rst_reg && srst_delayed) begin
rst_reg <= #`TCQ 1'b1;
end else if (rst_reg) begin
rst_reg <= #`TCQ 1'b0;
end else begin
rst_reg <= #`TCQ rst_reg;
end
end
// end : g8s_cc_rst
end else begin
assign wr_rst_busy = 1'b0;
assign rd_rst_busy = 1'b0;
assign safety_ckt_wr_rst = 1'b0;
assign safety_ckt_rd_rst = 1'b0;
end
endgenerate
generate
if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 1) begin : grstd1
// RST_FULL_GEN replaces the reset falling edge detection used to de-assert
// FULL, ALMOST_FULL & PROG_FULL flags if C_FULL_FLAGS_RST_VAL = 1.
// RST_FULL_FF goes to the reset pin of the final flop of FULL, ALMOST_FULL &
// PROG_FULL
reg rst_d1 = 1'b0;
reg rst_d2 = 1'b0;
reg rst_d3 = 1'b0;
reg rst_d4 = 1'b0;
reg rst_d5 = 1'b0;
always @ (posedge rst_2_sync or posedge clk_2_sync) begin
if (rst_2_sync) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
rst_d3 <= 1'b1;
rst_d4 <= 1'b1;
end else begin
if (srst_delayed) begin
rst_d1 <= #`TCQ 1'b1;
rst_d2 <= #`TCQ 1'b1;
rst_d3 <= #`TCQ 1'b1;
rst_d4 <= #`TCQ 1'b1;
end else begin
rst_d1 <= #`TCQ wr_rst_busy;
rst_d2 <= #`TCQ rst_d1;
rst_d3 <= #`TCQ rst_d2 | safety_ckt_wr_rst;
rst_d4 <= #`TCQ rst_d3;
end
end
end
always @* rst_full_ff_i <= (C_HAS_SRST == 0) ? rst_d2 : 1'b0 ;
always @* rst_full_gen_i <= rst_d3;
end else if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 0) begin : gnrst_full
always @* rst_full_ff_i <= (C_COMMON_CLOCK == 0) ? wr_rst_i : rst_i;
end
endgenerate // grstd1
endmodule //fifo_generator_v13_1_3_conv_ver
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0;
else
DOUT <= #`TCQ DIN;
end
endmodule // fifo_generator_v13_1_3_sync_stage
/*******************************************************************************
* Declaration of Independent-Clocks FIFO Module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_as
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input SAFETY_CKT_WR_RST,
input SAFETY_CKT_RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_CLK,
input RD_EN,
input RD_EN_USER,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input USER_EMPTY_FB,
input fab_read_data_valid_i,
input read_data_valid_i,
input ram_valid_i,
output reg ALMOST_EMPTY = 1'b1,
output reg ALMOST_FULL = C_FULL_FLAGS_RST_VAL,
output [C_DOUT_WIDTH-1:0] DOUT,
output reg EMPTY = 1'b1,
output reg EMPTY_FB = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL,
output OVERFLOW,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output UNDERFLOW,
output WR_ACK,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC_1 && SYMMETRIC_PORT && ERR_INJECTION;
// Array that holds the error injection type (single/double bit error) on
// a specific write operation, which is returned on read to corrupt the
// output data.
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
//The amount of data stored in the FIFO at any time is given
// by num_wr_bits (in the WR_CLK domain) and num_rd_bits (in the RD_CLK
// domain.
//num_wr_bits is calculated by considering the total words in the FIFO,
// and the state of the read pointer (which may not have yet crossed clock
// domains.)
//num_rd_bits is calculated by considering the total words in the FIFO,
// and the state of the write pointer (which may not have yet crossed clock
// domains.)
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
wire wr_rst_i = WR_RST;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire rd_rst_i = RD_RST;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
// Delayed ram_rd_en is needed only for STD Embedded register option
generate
if (C_PRELOAD_LATENCY == 2) begin : grd_d
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
end
endgenerate
generate
if (C_PRELOAD_LATENCY == 2 && C_USE_EMBEDDED_REG == 3) begin : grd_d1
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
endgenerate
// Write pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : rdg // Read depth greater than write depth
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1:0] = 0;
end else begin : rdl // Read depth lesser than or equal to write depth
assign adj_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
endgenerate
// Generate Empty and Almost Empty
// ram_rd_en used to determine EMPTY should depend on the EMPTY.
assign ram_rd_en = RD_EN & !EMPTY;
assign empty_int = ((adj_wr_pntr_rd == rd_pntr) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+1'h1))));
assign almost_empty_int = ((adj_wr_pntr_rd == (rd_pntr+1'h1)) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+2'h2))));
// Register Empty and Almost Empty
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin
EMPTY <= 1'b1;
ALMOST_EMPTY <= 1'b1;
rd_data_count_int <= {C_RD_PNTR_WIDTH{1'b0}};
end else begin
rd_data_count_int <= #`TCQ {(adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:0] - rd_pntr[C_RD_PNTR_WIDTH-1:0]), 1'b0};
if (empty_int)
EMPTY <= #`TCQ 1'b1;
else
EMPTY <= #`TCQ 1'b0;
if (!EMPTY) begin
if (almost_empty_int)
ALMOST_EMPTY <= #`TCQ 1'b1;
else
ALMOST_EMPTY <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (SAFETY_CKT_RD_RST && C_EN_SAFETY_CKT)
EMPTY_FB <= #`TCQ 1'b1;
else if (empty_int)
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ 1'b0;
end // rd_rst_i
end // always
// Read pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wdg // Write depth greater than read depth
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1:0] = 0;
end else begin : wdl // Write depth lesser than or equal to read depth
assign adj_rd_pntr_wr = rd_pntr_wr[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end
endgenerate
// Generate FULL and ALMOST_FULL
// ram_wr_en used to determine FULL should depend on the FULL.
assign ram_wr_en = WR_EN & !FULL;
assign full_int = ((adj_rd_pntr_wr == (wr_pntr+1'h1)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+2'h2))));
assign almost_full_int = ((adj_rd_pntr_wr == (wr_pntr+2'h2)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+3'h3))));
// Register FULL and ALMOST_FULL Empty
always @ (posedge WR_CLK or posedge RST_FULL_FF)
begin
if (RST_FULL_FF) begin
FULL <= C_FULL_FLAGS_RST_VAL;
ALMOST_FULL <= C_FULL_FLAGS_RST_VAL;
end else begin
if (full_int) begin
FULL <= #`TCQ 1'b1;
end else begin
FULL <= #`TCQ 1'b0;
end
if (RST_FULL_GEN) begin
ALMOST_FULL <= #`TCQ 1'b0;
end else if (!FULL) begin
if (almost_full_int)
ALMOST_FULL <= #`TCQ 1'b1;
else
ALMOST_FULL <= #`TCQ 1'b0;
end
end // wr_rst_i
end // always
always @ (posedge WR_CLK or posedge wr_rst_i)
begin
if (wr_rst_i) begin
wr_data_count_int <= {C_WR_DATA_COUNT_WIDTH{1'b0}};
end else begin
wr_data_count_int <= #`TCQ {(wr_pntr[C_WR_PNTR_WIDTH-1:0] - adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:0]), 1'b0};
end // wr_rst_i
end // always
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
stage1_valid <= 0;
stage2_valid <= 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//Pointers passed into opposite clock domain
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_EMPTY.
wire [31:0] num_read_words_pe =
num_rd_bits/(C_DOUT_WIDTH/C_DEPTH_RATIO_WR);
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_FULL.
wire [31:0] num_write_words_pf =
num_wr_bits/(C_DIN_WIDTH/C_DEPTH_RATIO_RD);
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/***************************************************************************
* Internal registers and wires
**************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire valid_i;
wire valid_out1;
wire valid_out2;
wire valid_out;
wire underflow_i;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
reg valid_d1 = 0;
reg valid_d2 = 0;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/****************************************************************************
* Function Declarations
***************************************************************************/
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
/***********************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_d2 = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_CLK;
wire RD_EN;
wire RST;
wire WR_CLK;
wire WR_EN;
*/
//***************************************************************************
// Dout may change behavior based on latency
//***************************************************************************
assign ideal_dout_out[C_DOUT_WIDTH-1:0] = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) )?
ideal_dout_d1: ideal_dout;
assign DOUT[C_DOUT_WIDTH-1:0] = ideal_dout_out;
//***************************************************************************
// Assign SBITERR and DBITERR based on latency
//***************************************************************************
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY == 2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) ) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY==2 && (C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
//***************************************************************************
// Safety-ckt logic with embedded reg/fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
// if (C_HAS_VALID == 1) begin
// assign valid_out = valid_d1;
// end
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK)
begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else begin
if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end
end
endgenerate
//***************************************************************************
// Safety-ckt logic with embedded reg + fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK) begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else begin
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end
endgenerate
//***************************************************************************
// Overflow may be active-low
//***************************************************************************
generate
if (C_HAS_OVERFLOW==1) begin : blockOF1
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end
endgenerate
assign PROG_EMPTY = ideal_prog_empty;
assign PROG_FULL = ideal_prog_full;
//***************************************************************************
// Valid may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_VALID==1) begin : blockVL1
assign valid_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out1 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG < 3)?
valid_d1: valid_i;
assign valid_out2 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG == 3)?
valid_d2: valid_i;
assign valid_out = (C_USE_EMBEDDED_REG == 3) ? valid_out2 : valid_out1;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end
endgenerate
//***************************************************************************
// Underflow may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_UNDERFLOW==1) begin : blockUF1
assign underflow_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & EMPTY) : ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end
endgenerate
//***************************************************************************
// Write acknowledge may be active low
//***************************************************************************
generate
if (C_HAS_WR_ACK==1) begin : blockWK1
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : wdc_fwft_ext
reg [C_PNTR_WIDTH-1:0] adjusted_wr_pntr = 0;
reg [C_PNTR_WIDTH-1:0] adjusted_rd_pntr = 0;
wire [C_PNTR_WIDTH-1:0] diff_wr_rd_tmp;
wire [C_PNTR_WIDTH:0] diff_wr_rd;
reg [C_PNTR_WIDTH:0] wr_data_count_i = 0;
always @* begin
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = 0;
adjusted_rd_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
end else if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin
adjusted_rd_pntr = rd_pntr_wr;
adjusted_wr_pntr = 0;
adjusted_wr_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
end else begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = rd_pntr_wr;
end
end // always @*
assign diff_wr_rd_tmp = adjusted_wr_pntr - adjusted_rd_pntr;
assign diff_wr_rd = {1'b0,diff_wr_rd_tmp};
always @ (posedge wr_rst_i or posedge WR_CLK)
begin
if (wr_rst_i)
wr_data_count_i <= 0;
else
wr_data_count_i <= #`TCQ diff_wr_rd + EXTRA_WORDS_DC;
end // always @ (posedge WR_CLK or posedge WR_CLK)
always @* begin
if (C_WR_PNTR_WIDTH >= C_RD_PNTR_WIDTH)
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:0];
else
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end // always @*
end // wdc_fwft_ext
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
reg [C_RD_PNTR_WIDTH:0] rdc_fwft_ext_as = 0;
generate if (C_USE_EMBEDDED_REG < 3) begin: rdc_fwft_ext_both
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= 0;
end else begin
if (!stage2_valid)
rdc_fwft_ext_as <= #`TCQ 0;
else if (!stage1_valid && stage2_valid)
rdc_fwft_ext_as <= #`TCQ 1;
else
rdc_fwft_ext_as <= #`TCQ diff_rd_wr + 2'h2;
end
end // always @ (posedge WR_CLK or posedge WR_CLK)
end // rdc_fwft_ext
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3) begin
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr_1;
// assign diff_rd_wr_1 = diff_rd_wr +2'h2;
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= #`TCQ 0;
end else begin
//if (fab_read_data_valid_i == 1'b0 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b0;
//else if (fab_read_data_valid_i == 1'b1 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b1;
//else
rdc_fwft_ext_as <= diff_rd_wr + 2'h2 ;
end
end
end
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = C_USE_FWFT_DATA_COUNT ?
rdc_fwft_ext_as[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH] :
rd_data_count_int[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = (C_USE_FWFT_DATA_COUNT == 1) ?
wdc_fwft_ext_as[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] :
wr_data_count_int[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate
if (C_HAS_VALID==1) begin : blockVL2
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_d2 <= 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
valid_d2 <= #`TCQ valid_d1;
end
// if (C_USE_EMBEDDED_REG == 3 && (C_EN_SAFETY_CKT == 0 || C_EN_SAFETY_CKT == 1 ) begin
// valid_d2 <= #`TCQ valid_d1;
// end
end
end
endgenerate
//Capture delayed version of dout
/**************************************************************************
*embedded/fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG < 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0)
err_type_d1 <= #`TCQ 0;
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
endgenerate
/**************************************************************************
*embedded + fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG == 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate
if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge WR_CLK) begin
ideal_overflow <= #`TCQ WR_EN & FULL;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge WR_CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (FULL | wr_rst_i);
ideal_overflow <= #`TCQ WR_EN & (FULL );
end
end
endgenerate
generate
if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ EMPTY & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ (EMPTY) & RD_EN;
//ideal_underflow <= #`TCQ (rd_rst_i | EMPTY) & RD_EN;
end
end
endgenerate
/**************************************************************************
* Write/Read Pointer Synchronization
**************************************************************************/
localparam NO_OF_SYNC_STAGE_INC_G2B = C_SYNCHRONIZER_STAGE + 1;
wire [C_WR_PNTR_WIDTH-1:0] wr_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
genvar gss;
generate for (gss = 1; gss <= NO_OF_SYNC_STAGE_INC_G2B; gss = gss + 1) begin : Sync_stage_inst
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_WR_PNTR_WIDTH)
)
rd_stg_inst
(
.RST (rd_rst_i),
.CLK (RD_CLK),
.DIN (wr_pntr_sync_stgs[gss-1]),
.DOUT (wr_pntr_sync_stgs[gss])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_RD_PNTR_WIDTH)
)
wr_stg_inst
(
.RST (wr_rst_i),
.CLK (WR_CLK),
.DIN (rd_pntr_sync_stgs[gss-1]),
.DOUT (rd_pntr_sync_stgs[gss])
);
end endgenerate // Sync_stage_inst
assign wr_pntr_sync_stgs[0] = wr_pntr_rd1;
assign rd_pntr_sync_stgs[0] = rd_pntr_wr1;
always@* begin
wr_pntr_rd <= wr_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
rd_pntr_wr <= rd_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
end
/**************************************************************************
* Write Domain Logic
**************************************************************************/
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_wp
if (wr_rst_i == 1'b1 && C_EN_SAFETY_CKT == 0)
wr_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_WR_RST == 1'b1)
wr_pntr <= #`TCQ 0;
end
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (wr_rst_i == 1'b1) begin
num_wr_bits <= 0;
next_num_wr_bits = 0;
wr_ptr <= C_WR_DEPTH - 1;
rd_ptr_wrclk <= C_RD_DEPTH - 1;
ideal_wr_ack <= 0;
ideal_wr_count <= 0;
tmp_wr_listsize = 0;
rd_ptr_wrclk_next <= 0;
wr_pntr_rd1 <= 0;
end else begin //wr_rst_i==0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
//If this is a write, handle the write by adding the value
// to the linked list, and updating all outputs appropriately
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD
>= C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full, but reporting full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//With DEPTH-1 words in the FIFO, it is almost_full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is completely empty, but it is
// reporting FULL for some reason (like reset)
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <=
C_FIFO_WR_DEPTH-2) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//FIFO is really not close to full, so change flag status.
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end //(tmp_wr_listsize == 0)
end else begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD >=
C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//This write is CAUSING the FIFO to go full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is 2 from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Still 2 from full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is not close to being full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //wr_rst_i==0
end // gen_fifo_w
/***************************************************************************
* Programmable FULL flags
***************************************************************************/
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_assert_val;
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_negate_val;
generate if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin : FWFT
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_DC;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_DC;
end else begin // STD
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL;
end endgenerate
always @(posedge WR_CLK or posedge wr_rst_i) begin
if (wr_rst_i == 1'b1) begin
diff_pntr <= 0;
end else begin
if (ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr + 2'h1);
else if (!ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr);
end
end
always @(posedge WR_CLK or posedge RST_FULL_FF) begin : gen_pf
if (RST_FULL_FF == 1'b1) begin
ideal_prog_full <= C_FULL_FLAGS_RST_VAL;
end else begin
if (RST_FULL_GEN)
ideal_prog_full <= #`TCQ 0;
//Single Programmable Full Constant Threshold
else if (C_PROG_FULL_TYPE == 1) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Constant Thresholds
end else if (C_PROG_FULL_TYPE == 2) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < pf_thr_negate_val)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Single Programmable Full Threshold Input
end else if (C_PROG_FULL_TYPE == 3) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Threshold Inputs
end else if (C_PROG_FULL_TYPE == 4) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH_ASSERT - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < (PROG_FULL_THRESH_NEGATE - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH_ASSERT)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < PROG_FULL_THRESH_NEGATE)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
end // C_PROG_FULL_TYPE
end //wr_rst_i==0
end //
/**************************************************************************
* Read Domain Logic
**************************************************************************/
/*********************************************************
* Programmable EMPTY flags
*********************************************************/
//Determine the Assert and Negate thresholds for Programmable Empty
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_assert_val;
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_negate_val;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_rd = 0;
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_pe
if (rd_rst_i) begin
diff_pntr_rd <= 0;
ideal_prog_empty <= 1'b1;
end else begin
if (ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr) - 1'h1;
else if (!ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr);
else
diff_pntr_rd <= #`TCQ diff_pntr_rd;
if (C_PROG_EMPTY_TYPE == 1) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 2) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 3) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 4) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end //C_PROG_EMPTY_TYPE
end
end // gen_pe
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH - 2'h2 : PROG_EMPTY_THRESH;
end endgenerate // single_pe_thr_input
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_ASSERT - 2'h2 : PROG_EMPTY_THRESH_ASSERT;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_NEGATE - 2'h2 : PROG_EMPTY_THRESH_NEGATE;
end endgenerate // multiple_pe_thr_input
generate if (C_PROG_EMPTY_TYPE < 3) begin : single_multiple_pe_thr_const
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2'h2 : C_PROG_EMPTY_THRESH_ASSERT_VAL;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2'h2 : C_PROG_EMPTY_THRESH_NEGATE_VAL;
end endgenerate // single_multiple_pe_thr_const
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_rp
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
rd_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_RD_RST == 1'b1)
rd_pntr <= #`TCQ 0;
end
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_r_as
/****** Reset fifo (case 1)***************************************/
if (rd_rst_i) begin
num_rd_bits <= 0;
next_num_rd_bits = 0;
rd_ptr <= C_RD_DEPTH -1;
rd_pntr_wr1 <= 0;
wr_ptr_rdclk <= C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_MEMORY_TYPE == 2 && C_USE_DOUT_RST == 1)
ideal_dout <= dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= 1'b0;
ideal_rd_count <= 0;
end else begin //rd_rst_i==0
rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
/*****************************************************************/
// Read Operation - Read Latency 1
/*****************************************************************/
if (C_PRELOAD_LATENCY==1 || C_PRELOAD_LATENCY==2) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
//If the FIFO is one from empty, but it is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is two from empty, and is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH))
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end // else: if(ideal_empty == 1'b1)
else //if (ideal_empty == 1'b0)
begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == C_FIFO_RD_DEPTH)
//If the FIFO is not close to being empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
//If the FIFO is two from empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is one from empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR == 1))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is completely empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end //(RD_EN == 1'b1)
else //if (RD_EN == 1'b0)
begin
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
/*****************************************************************/
// Read Operation - Read Latency 0
/*****************************************************************/
end else if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty, but it is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty, and is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH)) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end else begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to being empty
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH)) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is completely empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end else begin//(RD_EN == 1'b0)
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
end //if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0)
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //rd_rst_i==0
end //always gen_fifo_r_as
endmodule // fifo_generator_v13_1_3_bhv_ver_as
/*******************************************************************************
* Declaration of Low Latency Asynchronous FIFO
******************************************************************************/
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_USE_DOUT_RST = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_FIFO_TYPE = 0
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input [C_DIN_WIDTH-1:0] DIN,
input RD_CLK,
input RD_EN,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
output reg [C_DOUT_WIDTH-1:0] DOUT = 0,
output reg EMPTY = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL
);
//-----------------------------------------------------------------------------
// Low Latency Asynchronous FIFO
//-----------------------------------------------------------------------------
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
integer i;
initial begin
for (i = 0; i < C_WR_DEPTH; i = i + 1)
memory[i] = 0;
end
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_ll_afifo = 0;
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo_q = 0;
reg ll_afifo_full = 1'b0;
reg ll_afifo_empty = 1'b1;
wire write_allow;
wire read_allow;
assign write_allow = WR_EN & ~ll_afifo_full;
assign read_allow = RD_EN & ~ll_afifo_empty;
//-----------------------------------------------------------------------------
// Write Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
wr_pntr_ll_afifo <= 0;
else if (write_allow)
wr_pntr_ll_afifo <= #`TCQ wr_pntr_ll_afifo + 1;
end
//-----------------------------------------------------------------------------
// Read Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
rd_pntr_ll_afifo_q <= 0;
else
rd_pntr_ll_afifo_q <= #`TCQ rd_pntr_ll_afifo;
end
assign rd_pntr_ll_afifo = read_allow ? rd_pntr_ll_afifo_q + 1 : rd_pntr_ll_afifo_q;
//-----------------------------------------------------------------------------
// Fill the Memory
//-----------------------------------------------------------------------------
always @(posedge WR_CLK) begin
if (write_allow)
memory[wr_pntr_ll_afifo] <= #`TCQ DIN;
end
//-----------------------------------------------------------------------------
// Generate DOUT
//-----------------------------------------------------------------------------
always @(posedge RD_CLK) begin
DOUT <= #`TCQ memory[rd_pntr_ll_afifo];
end
//-----------------------------------------------------------------------------
// Generate EMPTY
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
ll_afifo_empty <= 1'b1;
else
ll_afifo_empty <= ((wr_pntr_ll_afifo == rd_pntr_ll_afifo_q) |
(read_allow & (wr_pntr_ll_afifo == (rd_pntr_ll_afifo_q + 2'h1))));
end
//-----------------------------------------------------------------------------
// Generate FULL
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
ll_afifo_full <= 1'b1;
else
ll_afifo_full <= ((rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h1)) |
(write_allow & (rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h2))));
end
always @* begin
FULL <= ll_afifo_full;
EMPTY <= ll_afifo_empty;
end
endmodule // fifo_generator_v13_1_3_beh_ver_ll_afifo
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* Declare user parameters and their defaults
*************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
/**************************************************************************
* Declare Input and Output Ports
*************************************************************************/
(
//Inputs
input SAFETY_CKT_WR_RST,
input CLK,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_EN,
input RD_EN_USER,
input USER_EMPTY_FB,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input SRST,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input WR_RST_BUSY,
input RD_RST_BUSY,
//Outputs
output ALMOST_EMPTY,
output ALMOST_FULL,
output reg [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT = 0,
output [C_DOUT_WIDTH-1:0] DOUT,
output EMPTY,
output reg EMPTY_FB = 1'b1,
output FULL,
output OVERFLOW,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output UNDERFLOW,
output WR_ACK,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
wire [C_RD_PNTR_WIDTH:0] rd_data_count_i_ss;
wire [C_WR_PNTR_WIDTH:0] wr_data_count_i_ss;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
//localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
//localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
localparam C_GRTR_PNTR_WIDTH = (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH ;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
wire [C_WR_PNTR_WIDTH:0] EXTRA_WORDS_PF = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//wire [C_RD_PNTR_WIDTH:0] EXTRA_WORDS_PE = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam EXTRA_WORDS_PF_PARAM = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//localparam EXTRA_WORDS_PE_PARAM = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
//The reset value assignments for FULL, ALMOST_FULL, and PROG_FULL are not
//changed for v3.2(IP2_Im). When the core has Sync Reset, C_HAS_SRST=1 and C_HAS_RST=0.
// Therefore, during SRST, all the FULL flags reset to 0.
localparam C_HAS_FAST_FIFO = 0;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH;
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC && SYMMETRIC_PORT && ERR_INJECTION;
localparam C_DATA_WIDTH = (ENABLE_ERR_INJECTION == 1) ? (C_DIN_WIDTH+2) : C_DIN_WIDTH;
localparam IS_ASYMMETRY = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 0 : 1;
localparam LESSER_WIDTH = (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
localparam [C_RD_PNTR_WIDTH-1 : 0] DIFF_MAX_RD = {C_RD_PNTR_WIDTH{1'b1}};
localparam [C_WR_PNTR_WIDTH-1 : 0] DIFF_MAX_WR = {C_WR_PNTR_WIDTH{1'b1}};
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
/**************************************************************************
* Internal Registers and wires
*************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire underflow_i;
wire valid_i;
wire valid_out;
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_reg = 1'b0;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
wire srst_rrst_busy;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire fwft_enabled;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg full_i = C_FULL_FLAGS_RST_VAL;
reg full_i_temp = 0;
reg empty_i = 1;
reg almost_full_i = 0;
reg almost_empty_i = 1;
reg prog_full_i = 0;
reg prog_empty_i = 1;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] diff_count = 0;
reg write_allow_q = 0;
reg read_allow_q = 0;
reg valid_d1 = 0;
reg valid_both = 0;
reg valid_d2 = 0;
wire rst_i;
wire srst_i;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
/****************************************************************************
* Function Declarations
***************************************************************************/
/****************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***************************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 ) begin
case (def_data[7:0])
8'b00000000 : begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default : begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1) begin
if ((index*4)+j < C_DOUT_WIDTH) begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
//reg valid_d1 = 0;
//user specified value for reseting the size of the fifo
//reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_dout_both = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_both = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_EN;
wire RST;
wire WR_EN;
*/
// Assign ALMOST_EPMTY
generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae
assign ALMOST_EMPTY = almost_empty_i;
end else begin : gnae
assign ALMOST_EMPTY = 0;
end endgenerate // gae
// Assign ALMOST_FULL
generate if (C_HAS_ALMOST_FULL==1) begin : gaf
assign ALMOST_FULL = almost_full_i;
end else begin : gnaf
assign ALMOST_FULL = 0;
end endgenerate // gaf
// Dout may change behavior based on latency
localparam C_FWFT_ENABLED = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign fwft_enabled = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign ideal_dout_out= ((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1))?
ideal_dout_d1: ideal_dout;
assign DOUT = ideal_dout_out;
// Assign SBITERR and DBITERR based on latency
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
assign EMPTY = empty_i;
assign FULL = full_i;
//saftey_ckt with one register
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && (C_USE_EMBEDDED_REG == 1 || C_USE_EMBEDDED_REG == 2 )) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK)
begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK)
begin
if( rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end
else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
valid_d1 <= #`TCQ valid_i;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end //if
endgenerate
//safety ckt with both registers
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK) begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end //if
endgenerate
//Overflow may be active-low
generate if (C_HAS_OVERFLOW==1) begin : gof
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end else begin : gnof
assign OVERFLOW = 0;
end endgenerate // gof
assign PROG_EMPTY = prog_empty_i;
assign PROG_FULL = prog_full_i;
//Valid may change behavior based on latency or active-low
generate if (C_HAS_VALID==1) begin : gvalid
assign valid_i = (C_PRELOAD_LATENCY == 0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out = (C_PRELOAD_LATENCY == 2 && C_MEMORY_TYPE < 2) ?
valid_d1 : valid_i;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end else begin : gnvalid
assign VALID = 0;
end endgenerate // gvalid
//Trim data count differently depending on set widths
generate if (C_HAS_DATA_COUNT == 1) begin : gdc
always @* begin
diff_count <= wr_pntr - rd_pntr;
if (C_DATA_COUNT_WIDTH > C_RD_PNTR_WIDTH) begin
DATA_COUNT[C_RD_PNTR_WIDTH-1:0] <= diff_count;
DATA_COUNT[C_DATA_COUNT_WIDTH-1] <= 1'b0 ;
end else begin
DATA_COUNT <= diff_count[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH];
end
end
// end else begin : gndc
// always @* DATA_COUNT <= 0;
end endgenerate // gdc
//Underflow may change behavior based on latency or active-low
generate if (C_HAS_UNDERFLOW==1) begin : guf
assign underflow_i = ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end else begin : gnuf
assign UNDERFLOW = 0;
end endgenerate // guf
//Write acknowledge may be active low
generate if (C_HAS_WR_ACK==1) begin : gwr_ack
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end else begin : gnwr_ack
assign WR_ACK = 0;
end endgenerate // gwr_ack
/*****************************************************************************
* Internal reset logic
****************************************************************************/
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_WR_RST : C_HAS_SRST ? (SRST | WR_RST_BUSY) : 0;
assign rst_i = C_HAS_RST ? RST : 0;
assign srst_wrst_busy = srst_i;
assign srst_rrst_busy = srst_i;
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG <3)) begin : blockVL20
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG == 3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_both <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
valid_both <= #`TCQ 1'b0;
end else begin
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge CLK or posedge rst_i) begin
if (rst_i) begin
stage1_valid <= #`TCQ 0;
stage2_valid <= #`TCQ 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT ==1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = rd_data_count_i_ss[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = wr_data_count_i_ss[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] ;
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//reg ram_rd_en_d1 = 1'b0;
//Capture delayed version of dout
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG<3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
ram_rd_en_d1 <= #`TCQ 1'b0;
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
end // always
end
endgenerate
//no safety ckt with both registers
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG==3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
fab_rd_en_d1 <= #`TCQ (ram_rd_en_d1);
if (ram_rd_en_d1 ) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end // always
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge CLK) begin
ideal_overflow <= #`TCQ WR_EN & full_i;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (rst_i | full_i);
ideal_overflow <= #`TCQ WR_EN & (WR_RST_BUSY | full_i);
end
end endgenerate // blockOF20
generate if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge CLK) begin
ideal_underflow <= #`TCQ empty_i & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge CLK) begin
//ideal_underflow <= #`TCQ (rst_i | empty_i) & RD_EN;
ideal_underflow <= #`TCQ (RD_RST_BUSY | empty_i) & RD_EN;
end
end endgenerate // blockUF20
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/*************************************************************************
* Write and Read Logic
************************************************************************/
wire write_allow;
wire read_allow;
wire read_allow_dc;
wire write_only;
wire read_only;
//wire write_only_q;
reg write_only_q;
//wire read_only_q;
reg read_only_q;
reg full_reg;
reg rst_full_ff_reg1;
reg rst_full_ff_reg2;
wire ram_full_comb;
wire carry;
assign write_allow = WR_EN & ~full_i;
assign read_allow = RD_EN & ~empty_i;
assign read_allow_dc = RD_EN_USER & ~USER_EMPTY_FB;
//assign write_only = write_allow & ~read_allow;
//assign write_only_q = write_allow_q;
//assign read_only = read_allow & ~write_allow;
//assign read_only_q = read_allow_q ;
wire [C_WR_PNTR_WIDTH-1:0] diff_pntr;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_reg1 = 0;
reg [C_RD_PNTR_WIDTH:0] diff_pntr_pe_asym = 0;
wire [C_RD_PNTR_WIDTH:0] adj_wr_pntr_rd_asym ;
wire [C_RD_PNTR_WIDTH:0] rd_pntr_asym;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_pe_reg2 = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_max;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_max;
assign diff_pntr_pe_max = DIFF_MAX_RD;
assign diff_pntr_max = DIFF_MAX_WR;
generate if (IS_ASYMMETRY == 0) begin : diff_pntr_sym
assign write_only = write_allow & ~read_allow;
assign read_only = read_allow & ~write_allow;
end endgenerate
generate if ( IS_ASYMMETRY == 1 && C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : wr_grt_rd
assign read_only = read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]) & ~write_allow;
assign write_only = write_allow & ~(read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (IS_ASYMMETRY ==1 && C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : rd_grt_wr
assign read_only = read_allow & ~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
assign write_only = write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]) & ~read_allow;
end endgenerate
//-----------------------------------------------------------------------------
// Write and Read pointer generation
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
wr_pntr <= 0;
rd_pntr <= 0;
end else begin
if (srst_i) begin
wr_pntr <= #`TCQ 0;
rd_pntr <= #`TCQ 0;
end else begin
if (write_allow) wr_pntr <= #`TCQ wr_pntr + 1;
if (read_allow) rd_pntr <= #`TCQ rd_pntr + 1;
end
end
end
generate if (C_FIFO_TYPE == 2) begin : gll_dm_dout
always @(posedge CLK) begin
if (write_allow) begin
if (ENABLE_ERR_INJECTION == 1)
memory[wr_pntr] <= #`TCQ {INJECTDBITERR,INJECTSBITERR,DIN};
else
memory[wr_pntr] <= #`TCQ DIN;
end
end
reg [C_DATA_WIDTH-1:0] dout_tmp_q;
reg [C_DATA_WIDTH-1:0] dout_tmp = 0;
reg [C_DATA_WIDTH-1:0] dout_tmp1 = 0;
always @(posedge CLK) begin
dout_tmp_q <= #`TCQ ideal_dout;
end
always @* begin
if (read_allow)
ideal_dout <= memory[rd_pntr];
else
ideal_dout <= dout_tmp_q;
end
end endgenerate // gll_dm_dout
/**************************************************************************
* Write Domain Logic
**************************************************************************/
assign ram_rd_en = RD_EN & !EMPTY;
//reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
generate if (C_FIFO_TYPE != 2) begin : gnll_din
always @(posedge CLK or posedge rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (rst_i == 1'b1) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin //rst_i==0
if (srst_wrst_busy) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin//srst_i=0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end else begin
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
//end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //srst_i==0
end //wr_rst_i==0
end // gen_fifo_w
end endgenerate
generate if (C_FIFO_TYPE < 2 && C_MEMORY_TYPE < 2) begin : gnll_dm_dout
always @(posedge CLK) begin
if (rst_i || srst_rrst_busy) begin
if (C_USE_DOUT_RST == 1) begin
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end
end
end endgenerate
generate if (C_FIFO_TYPE != 2) begin : gnll_dout
always @(posedge CLK or posedge rst_i) begin : gen_fifo_r
/****** Reset fifo (case 1)***************************************/
if (rst_i) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end else begin //rd_rst_i==0
if (srst_rrst_busy) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets synchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end //srst_i
else begin
//rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
if (RD_EN == 1'b1) begin
if (EMPTY == 1'b1) begin
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end
else
begin
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
end
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //s_rst_i==0
end //rd_rst_i==0
end //always
end endgenerate
//-----------------------------------------------------------------------------
// Generate diff_pntr for PROG_FULL generation
// Generate diff_pntr_pe for PROG_EMPTY generation
//-----------------------------------------------------------------------------
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 0) begin : reg_write_allow
always @(posedge CLK ) begin
if (rst_i) begin
write_only_q <= 1'b0;
read_only_q <= 1'b0;
diff_pntr_reg1 <= 0;
diff_pntr_pe_reg1 <= 0;
diff_pntr_reg2 <= 0;
diff_pntr_pe_reg2 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_rrst_busy) begin
read_only_q <= #`TCQ 1'b0;
diff_pntr_pe_reg1 <= #`TCQ 0;
diff_pntr_pe_reg2 <= #`TCQ 0;
end
if (srst_wrst_busy) begin
write_only_q <= #`TCQ 1'b0;
diff_pntr_reg1 <= #`TCQ 0;
diff_pntr_reg2 <= #`TCQ 0;
end
end else begin
write_only_q <= #`TCQ write_only;
read_only_q <= #`TCQ read_only;
diff_pntr_reg2 <= #`TCQ diff_pntr_reg1;
diff_pntr_pe_reg2 <= #`TCQ diff_pntr_pe_reg1;
// Add 1 to the difference pointer value when only write happens.
if (write_only)
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr + 1;
else
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
// Add 1 to the difference pointer value when write or both write & read or no write & read happen.
if (read_only)
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr - 1;
else
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr;
end
end
end
assign diff_pntr_pe = diff_pntr_pe_reg1;
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 1) begin : reg_write_allow_asym
assign adj_wr_pntr_rd_asym[C_RD_PNTR_WIDTH:0] = {adj_wr_pntr_rd,1'b1};
assign rd_pntr_asym[C_RD_PNTR_WIDTH:0] = {~rd_pntr,1'b1};
always @(posedge CLK ) begin
if (rst_i) begin
diff_pntr_pe_asym <= 0;
diff_pntr_reg1 <= 0;
full_reg <= 0;
rst_full_ff_reg1 <= 1;
rst_full_ff_reg2 <= 1;
diff_pntr_pe_reg1 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_wrst_busy)
diff_pntr_reg1 <= #`TCQ 0;
if (srst_rrst_busy)
full_reg <= #`TCQ 0;
rst_full_ff_reg1 <= #`TCQ 1;
rst_full_ff_reg2 <= #`TCQ 1;
diff_pntr_pe_asym <= #`TCQ 0;
diff_pntr_pe_reg1 <= #`TCQ 0;
end else begin
diff_pntr_pe_asym <= #`TCQ adj_wr_pntr_rd_asym + rd_pntr_asym;
full_reg <= #`TCQ full_i;
rst_full_ff_reg1 <= #`TCQ RST_FULL_FF;
rst_full_ff_reg2 <= #`TCQ rst_full_ff_reg1;
if (~full_i) begin
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
end
end
end
end
assign carry = (~(|(diff_pntr_pe_asym [C_RD_PNTR_WIDTH : 1])));
assign diff_pntr_pe = (full_reg && ~rst_full_ff_reg2 && carry ) ? diff_pntr_pe_max : diff_pntr_pe_asym[C_RD_PNTR_WIDTH:1];
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow_asym
//-----------------------------------------------------------------------------
// Generate FULL flag
//-----------------------------------------------------------------------------
wire comp0;
wire comp1;
wire going_full;
wire leaving_full;
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gpad
assign adj_rd_pntr_wr [C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_WR_PNTR_WIDTH <= C_RD_PNTR_WIDTH) begin : gtrim
assign adj_rd_pntr_wr = rd_pntr[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
assign comp1 = (adj_rd_pntr_wr == (wr_pntr + 1'b1));
assign comp0 = (adj_rd_pntr_wr == wr_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gf_wp_eq_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full = (comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gf_asym
assign going_full = (comp1 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_full = (comp0 & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gf_wp_gt_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full =(comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_full_comb = going_full | (~leaving_full & full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
full_i <= #`TCQ ram_full_comb;
end
//-----------------------------------------------------------------------------
// Generate EMPTY flag
//-----------------------------------------------------------------------------
wire ecomp0;
wire ecomp1;
wire going_empty;
wire leaving_empty;
wire ram_empty_comb;
generate if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : pad
assign adj_wr_pntr_rd [C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_RD_PNTR_WIDTH <= C_WR_PNTR_WIDTH) begin : trim
assign adj_wr_pntr_rd = wr_pntr[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
assign ecomp1 = (adj_wr_pntr_rd == (rd_pntr + 1'b1));
assign ecomp0 = (adj_wr_pntr_rd == rd_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : ge_wp_eq_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty = (ecomp0 & write_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : ge_wp_gt_rp
assign going_empty = (ecomp1 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_empty = (ecomp0 & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : ge_wp_lt_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty =(ecomp0 & write_allow);
end endgenerate
assign ram_empty_comb = going_empty | (~leaving_empty & empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
empty_i <= 1'b1;
else if (srst_rrst_busy)
empty_i <= #`TCQ 1'b1;
else
empty_i <= #`TCQ ram_empty_comb;
end
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (srst_rrst_busy || (SAFETY_CKT_WR_RST && C_EN_SAFETY_CKT))
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ ram_empty_comb;
end
end // always
//-----------------------------------------------------------------------------
// Generate Read and write data counts for asymmetic common clock
//-----------------------------------------------------------------------------
reg [C_GRTR_PNTR_WIDTH :0] count_dc = 0;
wire [C_GRTR_PNTR_WIDTH :0] ratio;
wire decr_by_one;
wire incr_by_ratio;
wire incr_by_one;
wire decr_by_ratio;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : rd_depth_gt_wr
assign ratio = C_DEPTH_RATIO_RD;
assign decr_by_one = (IS_FWFT == 1)? read_allow_dc : read_allow;
assign incr_by_ratio = write_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (decr_by_one) begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc - 1;
else
count_dc <= #`TCQ count_dc - 1 + ratio ;
end
else begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc + ratio ;
end
end
end
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc;
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wr_depth_gt_rd
assign ratio = C_DEPTH_RATIO_WR;
assign incr_by_one = write_allow;
assign decr_by_ratio = (IS_FWFT == 1)? read_allow_dc : read_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (incr_by_one) begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc + 1;
else
count_dc <= #`TCQ count_dc + 1 - ratio ;
end
else begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc - ratio ;
end
end
end
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc;
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
//-----------------------------------------------------------------------------
// Generate WR_ACK flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_wr_ack <= 1'b0;
else if (srst_wrst_busy)
ideal_wr_ack <= #`TCQ 1'b0;
else if (WR_EN & ~full_i)
ideal_wr_ack <= #`TCQ 1'b1;
else
ideal_wr_ack <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate VALID flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_valid <= 1'b0;
else if (srst_rrst_busy)
ideal_valid <= #`TCQ 1'b0;
else if (RD_EN & ~empty_i)
ideal_valid <= #`TCQ 1'b1;
else
ideal_valid <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate ALMOST_FULL flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_FULL == 1 || C_PROG_FULL_TYPE > 2 || C_PROG_EMPTY_TYPE > 2) begin : gaf_ss
wire fcomp2;
wire going_afull;
wire leaving_afull;
wire ram_afull_comb;
assign fcomp2 = (adj_rd_pntr_wr == (wr_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gaf_wp_eq_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull = (comp1 & read_allow & ~write_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gaf_asym
assign going_afull = (fcomp2 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_afull = (comp1 & (~write_allow) & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gaf_wp_gt_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull =((comp0 | comp1 | fcomp2) & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_afull_comb = going_afull | (~leaving_afull & almost_full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
almost_full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
almost_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
almost_full_i <= #`TCQ ram_afull_comb;
end
// end endgenerate // gaf_ss
//-----------------------------------------------------------------------------
// Generate ALMOST_EMPTY flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae_ss
wire ecomp2;
wire going_aempty;
wire leaving_aempty;
wire ram_aempty_comb;
assign ecomp2 = (adj_wr_pntr_rd == (rd_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gae_wp_eq_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty = (ecomp1 & write_allow & ~read_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gae_wp_gt_rp
assign going_aempty = (ecomp2 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_aempty = (ecomp1 & ~read_allow & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gae_wp_lt_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty =((ecomp2 | ecomp1 |ecomp0) & write_allow);
end endgenerate
assign ram_aempty_comb = going_aempty | (~leaving_aempty & almost_empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
almost_empty_i <= 1'b1;
else if (srst_rrst_busy)
almost_empty_i <= #`TCQ 1'b1;
else
almost_empty_i <= #`TCQ ram_aempty_comb;
end
// end endgenerate // gae_ss
//-----------------------------------------------------------------------------
// Generate PROG_FULL
//-----------------------------------------------------------------------------
localparam C_PF_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_PF_PARAM : // FWFT
C_PROG_FULL_THRESH_ASSERT_VAL; // STD
localparam C_PF_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_PF_PARAM: // FWFT
C_PROG_FULL_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold constant
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] temp = C_PF_ASSERT_VAL;
generate if (C_PROG_FULL_TYPE == 1) begin : single_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_ASSERT_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr>= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr) < C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b0;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate // single_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_FULL_TYPE == 2) begin : multiple_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_NEGATE_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr >= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < C_PF_NEGATE_VAL)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf3_assert_val = (C_PRELOAD_LATENCY == 0) ?
PROG_FULL_THRESH - EXTRA_WORDS_PF: // FWFT
PROG_FULL_THRESH; // STD
generate if (C_PROG_FULL_TYPE == 3) begin : single_pf_input
always @(posedge CLK or posedge RST_FULL_FF) begin//0
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin //1
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin//2
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin//3
if (diff_pntr > pf3_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == pf3_assert_val) begin//4
if (read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b1;
end else//4
prog_full_i <= #`TCQ 1'b0;
end else//3
prog_full_i <= #`TCQ prog_full_i;
end //2
else begin//5
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin//6
if (diff_pntr >= pf3_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf3_assert_val) begin//7
prog_full_i <= #`TCQ 1'b0;
end//7
end//6
else
prog_full_i <= #`TCQ prog_full_i;
end//5
end//1
end//0
end endgenerate //single_pf_input
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_ASSERT -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_ASSERT; // STD
wire [C_WR_PNTR_WIDTH-1:0] pf_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_NEGATE -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_NEGATE; // STD
generate if (C_PROG_FULL_TYPE == 4) begin : multiple_pf_inputs
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin
if (diff_pntr >= pf_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr == pf_negate_val && read_only_q) ||
diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin
if (diff_pntr >= pf_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_inputs
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY
//-----------------------------------------------------------------------------
localparam C_PE_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_ASSERT_VAL; // STD
localparam C_PE_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold constant
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 1) begin : single_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_ASSERT_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b0;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 2) begin : multiple_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_NEGATE_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_NEGATE_VAL)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate //multiple_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe3_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH -2) : // FWFT
PROG_EMPTY_THRESH; // STD
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_input
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe < pe3_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == pe3_assert_val) begin
if (write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ 1'b1;
end else
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe3_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe3_assert_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_input
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe4_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_ASSERT - 2) : // FWFT
PROG_EMPTY_THRESH_ASSERT; // STD
wire [C_RD_PNTR_WIDTH-1:0] pe4_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_NEGATE - 2) : // FWFT
PROG_EMPTY_THRESH_NEGATE; // STD
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_inputs
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe <= pe4_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (((diff_pntr_pe == pe4_negate_val) && write_only_q) ||
(diff_pntr_pe > pe4_negate_val)) begin
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe4_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe4_negate_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // multiple_pe_inputs
endmodule // fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* First-Word Fall-Through module (preload 0)
**************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USERVALID_LOW = 0,
parameter C_USERUNDERFLOW_LOW = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
(
//Inputs
input SAFETY_CKT_RD_RST,
input RD_CLK,
input RD_RST,
input SRST,
input WR_RST_BUSY,
input RD_RST_BUSY,
input RD_EN,
input FIFOEMPTY,
input [C_DOUT_WIDTH-1:0] FIFODATA,
input FIFOSBITERR,
input FIFODBITERR,
//Outputs
output reg [C_DOUT_WIDTH-1:0] USERDATA,
output USERVALID,
output USERUNDERFLOW,
output USEREMPTY,
output USERALMOSTEMPTY,
output RAMVALID,
output FIFORDEN,
output reg USERSBITERR,
output reg USERDBITERR,
output reg STAGE2_REG_EN,
output fab_read_data_valid_i_o,
output read_data_valid_i_o,
output ram_valid_i_o,
output [1:0] VALID_STAGES
);
//Internal signals
wire preloadstage1;
wire preloadstage2;
reg ram_valid_i;
reg fab_valid;
reg read_data_valid_i;
reg fab_read_data_valid_i;
reg fab_read_data_valid_i_1;
reg ram_valid_i_d;
reg read_data_valid_i_d;
reg fab_read_data_valid_i_d;
wire ram_regout_en;
reg ram_regout_en_d1;
reg ram_regout_en_d2;
wire fab_regout_en;
wire ram_rd_en;
reg empty_i = 1'b1;
reg empty_sckt = 1'b1;
reg sckt_rrst_q = 1'b0;
reg sckt_rrst_done = 1'b0;
reg empty_q = 1'b1;
reg rd_en_q = 1'b0;
reg almost_empty_i = 1'b1;
reg almost_empty_q = 1'b1;
wire rd_rst_i;
wire srst_i;
reg [C_DOUT_WIDTH-1:0] userdata_both;
wire uservalid_both;
wire uservalid_one;
reg user_sbiterr_both = 1'b0;
reg user_dbiterr_both = 1'b0;
assign ram_valid_i_o = ram_valid_i;
assign read_data_valid_i_o = read_data_valid_i;
assign fab_read_data_valid_i_o = fab_read_data_valid_i;
/*************************************************************************
* FUNCTIONS
*************************************************************************/
/*************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
//*************************************************************************
// Set power-on states for regs
//*************************************************************************
initial begin
ram_valid_i = 1'b0;
fab_valid = 1'b0;
read_data_valid_i = 1'b0;
fab_read_data_valid_i = 1'b0;
fab_read_data_valid_i_1 = 1'b0;
USERDATA = hexstr_conv(C_DOUT_RST_VAL);
userdata_both = hexstr_conv(C_DOUT_RST_VAL);
USERSBITERR = 1'b0;
USERDBITERR = 1'b0;
user_sbiterr_both = 1'b0;
user_dbiterr_both = 1'b0;
end //initial
//***************************************************************************
// connect up optional reset
//***************************************************************************
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? RD_RST : 0;
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_RD_RST : C_HAS_SRST ? SRST : 0;
reg sckt_rd_rst_fwft = 1'b0;
reg fwft_rst_done_i = 1'b0;
wire fwft_rst_done;
assign fwft_rst_done = C_EN_SAFETY_CKT ? fwft_rst_done_i : 1'b1;
always @ (posedge RD_CLK) begin
sckt_rd_rst_fwft <= #`TCQ SAFETY_CKT_RD_RST;
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i)
fwft_rst_done_i <= 1'b0;
else if (sckt_rd_rst_fwft & ~SAFETY_CKT_RD_RST)
fwft_rst_done_i <= #`TCQ 1'b1;
end
localparam INVALID = 0;
localparam STAGE1_VALID = 2;
localparam STAGE2_VALID = 1;
localparam BOTH_STAGES_VALID = 3;
reg [1:0] curr_fwft_state = INVALID;
reg [1:0] next_fwft_state = INVALID;
generate if (C_USE_EMBEDDED_REG < 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = preloadstage2;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = (RD_EN & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
reg curr_state = 0;
reg next_state = 0;
reg leaving_empty_fwft = 0;
reg going_empty_fwft = 0;
reg empty_i_q = 0;
reg ram_rd_en_fwft = 0;
generate if (C_FIFO_TYPE == 2) begin : gll_fifo
always @* begin // FSM fo FWFT
case (curr_state)
1'b0: begin
if (~FIFOEMPTY)
next_state <= 1'b1;
else
next_state <= 1'b0;
end
1'b1: begin
if (FIFOEMPTY && RD_EN)
next_state <= 1'b0;
else
next_state <= 1'b1;
end
default: next_state <= 1'b0;
endcase
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_i <= 1'b1;
empty_i_q <= 1'b1;
ram_valid_i <= 1'b0;
end else if (srst_i) begin
empty_i <= #`TCQ 1'b1;
empty_i_q <= #`TCQ 1'b1;
ram_valid_i <= #`TCQ 1'b0;
end else begin
empty_i <= #`TCQ going_empty_fwft | (~leaving_empty_fwft & empty_i);
empty_i_q <= #`TCQ FIFOEMPTY;
ram_valid_i <= #`TCQ next_state;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
curr_state <= 1'b0;
end else if (srst_i) begin
curr_state <= #`TCQ 1'b0;
end else begin
curr_state <= #`TCQ next_state;
end
end //always
wire fe_of_empty;
assign fe_of_empty = empty_i_q & ~FIFOEMPTY;
always @* begin // Finding leaving empty
case (curr_state)
1'b0: leaving_empty_fwft <= fe_of_empty;
1'b1: leaving_empty_fwft <= 1'b1;
default: leaving_empty_fwft <= 1'b0;
endcase
end
always @* begin // Finding going empty
case (curr_state)
1'b1: going_empty_fwft <= FIFOEMPTY & RD_EN;
default: going_empty_fwft <= 1'b0;
endcase
end
always @* begin // Generating FWFT rd_en
case (curr_state)
1'b0: ram_rd_en_fwft <= ~FIFOEMPTY;
1'b1: ram_rd_en_fwft <= ~FIFOEMPTY & RD_EN;
default: ram_rd_en_fwft <= 1'b0;
endcase
end
assign ram_regout_en = ram_rd_en_fwft;
//assign ram_regout_en_d1 = ram_rd_en_fwft;
//assign ram_regout_en_d2 = ram_rd_en_fwft;
assign ram_rd_en = ram_rd_en_fwft;
end endgenerate // gll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false.
// Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2) begin : gnll_fifo_ram_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (ram_rd_en == 1'b1) begin
ram_valid_i <= #`TCQ 1'b1;
end else begin
if (ram_regout_en == 1'b1)
ram_valid_i <= #`TCQ 1'b0;
else
ram_valid_i <= #`TCQ ram_valid_i;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_ram_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ ram_valid_i | (read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG < 3) begin : gnll_fifo_empty
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~ram_valid_i & ~read_data_valid_i) | (~ram_valid_i & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
generate if ( C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((ram_regout_en) | (~FIFOEMPTY & read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ FIFOEMPTY;
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
// BRAM resets synchronously
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG < 3) begin
always @ ( posedge rd_rst_i)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
//safety ckt with one register
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
//@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay
if (rd_rst_i == 1) begin
ram_regout_en_d1 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d1 <= #`TCQ 1'b0;
else
ram_regout_en_d1 <= #`TCQ ram_regout_en;
end
end //always
// assign fab_regout_en = ((ram_regout_en_d1 & ~(ram_regout_en_d2) & empty_i) | (RD_EN & !empty_i));
assign fab_regout_en = ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b0 )? 1'b1: ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1) ? RD_EN : 1'b0;
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay1
if (rd_rst_i == 1) begin
ram_regout_en_d2 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d2 <= #`TCQ 1'b0;
else
ram_regout_en_d2 <= #`TCQ ram_regout_en_d1;
end
end //always
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
always @ (posedge RD_CLK) begin
ram_valid_i_d <= #`TCQ ram_valid_i;
read_data_valid_i_d <= #`TCQ read_data_valid_i;
fab_read_data_valid_i_d <= #`TCQ fab_read_data_valid_i;
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = (ram_valid_i == 1'b1 && (read_data_valid_i == 1'b0 || fab_read_data_valid_i == 1'b0)) ? 1'b1 : (read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1 && ram_valid_i == 1'b1) ? RD_EN : 1'b0;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = ((RD_EN | ~ fab_read_data_valid_i) & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false // Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3) begin : gnll_fifo_fab_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (ram_regout_en == 1'b1) begin
fab_valid <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
fab_valid <= #`TCQ 1'b0;
else
fab_valid <= #`TCQ fab_valid;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_fab_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG == 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else begin
if (ram_regout_en == 1'b1) begin
read_data_valid_i <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ read_data_valid_i;
end
end
end //always
end
endgenerate
//generate if(C_USE_EMBEDDED_REG == 3) begin
// always @ (posedge RD_CLK or posedge rd_rst_i) begin
// if (rd_rst_i)
// read_data_valid_i <= #`TCQ 1'b0;
// else if (srst_i)
// read_data_valid_i <= #`TCQ 1'b0;
//
// if (ram_regout_en == 1'b1) begin
// fab_read_data_valid_i <= #`TCQ 1'b0;
// end else begin
// if (fab_regout_en == 1'b1)
// fab_read_data_valid_i <= #`TCQ 1'b1;
// else
// fab_read_data_valid_i <= #`TCQ fab_read_data_valid_i;
// end
// end //always
//end
//endgenerate
generate if(C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin :fabout_dvalid
if (rd_rst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else
fab_read_data_valid_i <= #`TCQ fab_valid | (fab_read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
always @ (posedge RD_CLK ) begin : proc_del1
begin
fab_read_data_valid_i_1 <= #`TCQ fab_read_data_valid_i;
end
end //always
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3 ) begin : gnll_fifo_empty_both
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~fab_valid & ~fab_read_data_valid_i) | (~fab_valid & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty_both
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
reg FIFOEMPTY_1;
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @(posedge RD_CLK) begin
FIFOEMPTY_1 <= #`TCQ FIFOEMPTY;
end
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((fab_regout_en) | (ram_valid_i & fab_read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ (~ram_valid_i);
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_sckt <= #`TCQ 1'b1;
sckt_rrst_q <= #`TCQ 1'b0;
sckt_rrst_done <= #`TCQ 1'b0;
end else begin
sckt_rrst_q <= #`TCQ SAFETY_CKT_RD_RST;
if (sckt_rrst_q && ~SAFETY_CKT_RD_RST) begin
sckt_rrst_done <= #`TCQ 1'b1;
end else if (sckt_rrst_done) begin
// rising clock edge
empty_sckt <= #`TCQ 1'b0;
end
end
end //always
// assign USEREMPTY = C_EN_SAFETY_CKT ? (sckt_rrst_done ? empty_i : empty_sckt) : empty_i;
assign USEREMPTY = empty_i;
assign USERALMOSTEMPTY = almost_empty_i;
assign FIFORDEN = ram_rd_en;
assign RAMVALID = (C_USE_EMBEDDED_REG == 3)? fab_valid : ram_valid_i;
assign uservalid_both = (C_USERVALID_LOW && C_USE_EMBEDDED_REG == 3) ? ~fab_read_data_valid_i : ((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG == 3) ? fab_read_data_valid_i : 1'b0);
assign uservalid_one = (C_USERVALID_LOW && C_USE_EMBEDDED_REG < 3) ? ~read_data_valid_i :((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG < 3) ? read_data_valid_i : 1'b0);
assign USERVALID = (C_USE_EMBEDDED_REG == 3) ? uservalid_both : uservalid_one;
assign USERUNDERFLOW = C_USERUNDERFLOW_LOW ? ~(empty_q & rd_en_q) : empty_q & rd_en_q;
//no safety ckt with both reg
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin
if (fwft_rst_done) begin
if (ram_regout_en) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end
end //always
end //if
endgenerate
//safety_ckt with both registers
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK) begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end //always
end //if
endgenerate
endmodule //fifo_generator_v13_1_3_bhv_ver_preload0
//-----------------------------------------------------------------------------
//
// Register Slice
// Register one AXI channel on forward and/or reverse signal path
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// reg_slice
//
//--------------------------------------------------------------------------
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
input wire S_VALID,
output wire S_READY,
// Master side
output wire [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA,
output wire M_VALID,
input wire M_READY
);
generate
////////////////////////////////////////////////////////////////////
//
// Both FWD and REV mode
//
////////////////////////////////////////////////////////////////////
if (C_REG_CONFIG == 32'h00000000)
begin
reg [1:0] state;
localparam [1:0]
ZERO = 2'b10,
ONE = 2'b11,
TWO = 2'b01;
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg [C_DATA_WIDTH-1:0] storage_data2 = 0;
reg load_s1;
wire load_s2;
wire load_s1_from_s2;
reg s_ready_i; //local signal of output
wire m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with either slave side data or from storage2
always @(posedge ACLK)
begin
if (load_s1)
if (load_s1_from_s2)
storage_data1 <= storage_data2;
else
storage_data1 <= S_PAYLOAD_DATA;
end
// Load storage2 with slave side data
always @(posedge ACLK)
begin
if (load_s2)
storage_data2 <= S_PAYLOAD_DATA;
end
assign M_PAYLOAD_DATA = storage_data1;
// Always load s2 on a valid transaction even if it's unnecessary
assign load_s2 = S_VALID & s_ready_i;
// Loading s1
always @ *
begin
if ( ((state == ZERO) && (S_VALID == 1)) || // Load when empty on slave transaction
// Load when ONE if we both have read and write at the same time
((state == ONE) && (S_VALID == 1) && (M_READY == 1)) ||
// Load when TWO and we have a transaction on Master side
((state == TWO) && (M_READY == 1)))
load_s1 = 1'b1;
else
load_s1 = 1'b0;
end // always @ *
assign load_s1_from_s2 = (state == TWO);
// State Machine for handling output signals
always @(posedge ACLK) begin
if (ARESET) begin
s_ready_i <= 1'b0;
state <= ZERO;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else begin
case (state)
// No transaction stored locally
ZERO: if (S_VALID) state <= ONE; // Got one so move to ONE
// One transaction stored locally
ONE: begin
if (M_READY & ~S_VALID) state <= ZERO; // Read out one so move to ZERO
if (~M_READY & S_VALID) begin
state <= TWO; // Got another one so move to TWO
s_ready_i <= 1'b0;
end
end
// TWO transaction stored locally
TWO: if (M_READY) begin
state <= ONE; // Read out one so move to ONE
s_ready_i <= 1'b1;
end
endcase // case (state)
end
end // always @ (posedge ACLK)
assign m_valid_i = state[0];
end // if (C_REG_CONFIG == 1)
////////////////////////////////////////////////////////////////////
//
// 1-stage pipeline register with bubble cycle, both FWD and REV pipelining
// Operates same as 1-deep FIFO
//
////////////////////////////////////////////////////////////////////
else if (C_REG_CONFIG == 32'h00000001)
begin
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg s_ready_i; //local signal of output
reg m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with slave side data
always @(posedge ACLK)
begin
if (ARESET) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b0;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else if (m_valid_i & M_READY) begin
s_ready_i <= 1'b1;
m_valid_i <= 1'b0;
end else if (S_VALID & s_ready_i) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b1;
end
if (~m_valid_i) begin
storage_data1 <= S_PAYLOAD_DATA;
end
end
assign M_PAYLOAD_DATA = storage_data1;
end // if (C_REG_CONFIG == 7)
else begin : default_case
// Passthrough
assign M_PAYLOAD_DATA = S_PAYLOAD_DATA;
assign M_VALID = S_VALID;
assign S_READY = M_READY;
end
endgenerate
endmodule // reg_slice
|
/*
*******************************************************************************
*
* FIFO Generator - Verilog Behavioral Model
*
*******************************************************************************
*
* (c) Copyright 1995 - 2009 Xilinx, Inc. All rights reserved.
*
* This file contains confidential and proprietary information
* of Xilinx, Inc. and is protected under U.S. and
* international copyright and other intellectual property
* laws.
*
* DISCLAIMER
* This disclaimer is not a license and does not grant any
* rights to the materials distributed herewith. Except as
* otherwise provided in a valid license issued to you by
* Xilinx, and to the maximum extent permitted by applicable
* law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
* WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
* AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
* BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
* INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
* (2) Xilinx shall not be liable (whether in contract or tort,
* including negligence, or under any other theory of
* liability) for any loss or damage of any kind or nature
* related to, arising under or in connection with these
* materials, including for any direct, or any indirect,
* special, incidental, or consequential loss or damage
* (including loss of data, profits, goodwill, or any type of
* loss or damage suffered as a result of any action brought
* by a third party) even if such damage or loss was
* reasonably foreseeable or Xilinx had been advised of the
* possibility of the same.
*
* CRITICAL APPLICATIONS
* Xilinx products are not designed or intended to be fail-
* safe, or for use in any application requiring fail-safe
* performance, such as life-support or safety devices or
* systems, Class III medical devices, nuclear facilities,
* applications related to the deployment of airbags, or any
* other applications that could lead to death, personal
* injury, or severe property or environmental damage
* (individually and collectively, "Critical
* Applications"). Customer assumes the sole risk and
* liability of any use of Xilinx products in Critical
* Applications, subject only to applicable laws and
* regulations governing limitations on product liability.
*
* THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
* PART OF THIS FILE AT ALL TIMES.
*
*******************************************************************************
*******************************************************************************
*
* Filename: fifo_generator_vlog_beh.v
*
* Author : Xilinx
*
*******************************************************************************
* Structure:
*
* fifo_generator_vlog_beh.v
* |
* +-fifo_generator_v13_1_3_bhv_ver_as
* |
* +-fifo_generator_v13_1_3_bhv_ver_ss
* |
* +-fifo_generator_v13_1_3_bhv_ver_preload0
*
*******************************************************************************
* Description:
*
* The Verilog behavioral model for the FIFO Generator.
*
* The behavioral model has three parts:
* - The behavioral model for independent clocks FIFOs (_as)
* - The behavioral model for common clock FIFOs (_ss)
* - The "preload logic" block which implements First-word Fall-through
*
*******************************************************************************
* Description:
* The verilog behavioral model for the FIFO generator core.
*
*******************************************************************************
*/
`timescale 1ps/1ps
`ifndef TCQ
`define TCQ 100
`endif
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "",
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 1,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "4kx4",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_PIPELINE_REG = 0,
parameter C_POWER_SAVING_MODE = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface, 1: AXI4 Stream, 2: AXI4/AXI3
parameter C_AXI_TYPE = 0, // 1: AXI4, 2: AXI4 Lite, 3: AXI3
parameter C_HAS_AXI_WR_CHANNEL = 0,
parameter C_HAS_AXI_RD_CHANNEL = 0,
parameter C_HAS_SLAVE_CE = 0,
parameter C_HAS_MASTER_CE = 0,
parameter C_ADD_NGC_CONSTRAINT = 0,
parameter C_USE_COMMON_UNDERFLOW = 0,
parameter C_USE_COMMON_OVERFLOW = 0,
parameter C_USE_DEFAULT_SETTINGS = 0,
// AXI Full/Lite
parameter C_AXI_ID_WIDTH = 0,
parameter C_AXI_ADDR_WIDTH = 0,
parameter C_AXI_DATA_WIDTH = 0,
parameter C_AXI_LEN_WIDTH = 8,
parameter C_AXI_LOCK_WIDTH = 2,
parameter C_HAS_AXI_ID = 0,
parameter C_HAS_AXI_AWUSER = 0,
parameter C_HAS_AXI_WUSER = 0,
parameter C_HAS_AXI_BUSER = 0,
parameter C_HAS_AXI_ARUSER = 0,
parameter C_HAS_AXI_RUSER = 0,
parameter C_AXI_ARUSER_WIDTH = 0,
parameter C_AXI_AWUSER_WIDTH = 0,
parameter C_AXI_WUSER_WIDTH = 0,
parameter C_AXI_BUSER_WIDTH = 0,
parameter C_AXI_RUSER_WIDTH = 0,
// AXI Streaming
parameter C_HAS_AXIS_TDATA = 0,
parameter C_HAS_AXIS_TID = 0,
parameter C_HAS_AXIS_TDEST = 0,
parameter C_HAS_AXIS_TUSER = 0,
parameter C_HAS_AXIS_TREADY = 0,
parameter C_HAS_AXIS_TLAST = 0,
parameter C_HAS_AXIS_TSTRB = 0,
parameter C_HAS_AXIS_TKEEP = 0,
parameter C_AXIS_TDATA_WIDTH = 1,
parameter C_AXIS_TID_WIDTH = 1,
parameter C_AXIS_TDEST_WIDTH = 1,
parameter C_AXIS_TUSER_WIDTH = 1,
parameter C_AXIS_TSTRB_WIDTH = 1,
parameter C_AXIS_TKEEP_WIDTH = 1,
// AXI Channel Type
// WACH --> Write Address Channel
// WDCH --> Write Data Channel
// WRCH --> Write Response Channel
// RACH --> Read Address Channel
// RDCH --> Read Data Channel
// AXIS --> AXI Streaming
parameter C_WACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logic
parameter C_WDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_WRCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_AXIS_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
// AXI Implementation Type
// 1 = Common Clock Block RAM FIFO
// 2 = Common Clock Distributed RAM FIFO
// 11 = Independent Clock Block RAM FIFO
// 12 = Independent Clock Distributed RAM FIFO
parameter C_IMPLEMENTATION_TYPE_WACH = 0,
parameter C_IMPLEMENTATION_TYPE_WDCH = 0,
parameter C_IMPLEMENTATION_TYPE_WRCH = 0,
parameter C_IMPLEMENTATION_TYPE_RACH = 0,
parameter C_IMPLEMENTATION_TYPE_RDCH = 0,
parameter C_IMPLEMENTATION_TYPE_AXIS = 0,
// AXI FIFO Type
// 0 = Data FIFO
// 1 = Packet FIFO
// 2 = Low Latency Sync FIFO
// 3 = Low Latency Async FIFO
parameter C_APPLICATION_TYPE_WACH = 0,
parameter C_APPLICATION_TYPE_WDCH = 0,
parameter C_APPLICATION_TYPE_WRCH = 0,
parameter C_APPLICATION_TYPE_RACH = 0,
parameter C_APPLICATION_TYPE_RDCH = 0,
parameter C_APPLICATION_TYPE_AXIS = 0,
// AXI Built-in FIFO Primitive Type
// 512x36, 1kx18, 2kx9, 4kx4, etc
parameter C_PRIM_FIFO_TYPE_WACH = "512x36",
parameter C_PRIM_FIFO_TYPE_WDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_WRCH = "512x36",
parameter C_PRIM_FIFO_TYPE_RACH = "512x36",
parameter C_PRIM_FIFO_TYPE_RDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_AXIS = "512x36",
// Enable ECC
// 0 = ECC disabled
// 1 = ECC enabled
parameter C_USE_ECC_WACH = 0,
parameter C_USE_ECC_WDCH = 0,
parameter C_USE_ECC_WRCH = 0,
parameter C_USE_ECC_RACH = 0,
parameter C_USE_ECC_RDCH = 0,
parameter C_USE_ECC_AXIS = 0,
// ECC Error Injection Type
// 0 = No Error Injection
// 1 = Single Bit Error Injection
// 2 = Double Bit Error Injection
// 3 = Single Bit and Double Bit Error Injection
parameter C_ERROR_INJECTION_TYPE_WACH = 0,
parameter C_ERROR_INJECTION_TYPE_WDCH = 0,
parameter C_ERROR_INJECTION_TYPE_WRCH = 0,
parameter C_ERROR_INJECTION_TYPE_RACH = 0,
parameter C_ERROR_INJECTION_TYPE_RDCH = 0,
parameter C_ERROR_INJECTION_TYPE_AXIS = 0,
// Input Data Width
// Accumulation of all AXI input signal's width
parameter C_DIN_WIDTH_WACH = 1,
parameter C_DIN_WIDTH_WDCH = 1,
parameter C_DIN_WIDTH_WRCH = 1,
parameter C_DIN_WIDTH_RACH = 1,
parameter C_DIN_WIDTH_RDCH = 1,
parameter C_DIN_WIDTH_AXIS = 1,
parameter C_WR_DEPTH_WACH = 16,
parameter C_WR_DEPTH_WDCH = 16,
parameter C_WR_DEPTH_WRCH = 16,
parameter C_WR_DEPTH_RACH = 16,
parameter C_WR_DEPTH_RDCH = 16,
parameter C_WR_DEPTH_AXIS = 16,
parameter C_WR_PNTR_WIDTH_WACH = 4,
parameter C_WR_PNTR_WIDTH_WDCH = 4,
parameter C_WR_PNTR_WIDTH_WRCH = 4,
parameter C_WR_PNTR_WIDTH_RACH = 4,
parameter C_WR_PNTR_WIDTH_RDCH = 4,
parameter C_WR_PNTR_WIDTH_AXIS = 4,
parameter C_HAS_DATA_COUNTS_WACH = 0,
parameter C_HAS_DATA_COUNTS_WDCH = 0,
parameter C_HAS_DATA_COUNTS_WRCH = 0,
parameter C_HAS_DATA_COUNTS_RACH = 0,
parameter C_HAS_DATA_COUNTS_RDCH = 0,
parameter C_HAS_DATA_COUNTS_AXIS = 0,
parameter C_HAS_PROG_FLAGS_WACH = 0,
parameter C_HAS_PROG_FLAGS_WDCH = 0,
parameter C_HAS_PROG_FLAGS_WRCH = 0,
parameter C_HAS_PROG_FLAGS_RACH = 0,
parameter C_HAS_PROG_FLAGS_RDCH = 0,
parameter C_HAS_PROG_FLAGS_AXIS = 0,
parameter C_PROG_FULL_TYPE_WACH = 0,
parameter C_PROG_FULL_TYPE_WDCH = 0,
parameter C_PROG_FULL_TYPE_WRCH = 0,
parameter C_PROG_FULL_TYPE_RACH = 0,
parameter C_PROG_FULL_TYPE_RDCH = 0,
parameter C_PROG_FULL_TYPE_AXIS = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_PROG_EMPTY_TYPE_WACH = 0,
parameter C_PROG_EMPTY_TYPE_WDCH = 0,
parameter C_PROG_EMPTY_TYPE_WRCH = 0,
parameter C_PROG_EMPTY_TYPE_RACH = 0,
parameter C_PROG_EMPTY_TYPE_RDCH = 0,
parameter C_PROG_EMPTY_TYPE_AXIS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_REG_SLICE_MODE_WACH = 0,
parameter C_REG_SLICE_MODE_WDCH = 0,
parameter C_REG_SLICE_MODE_WRCH = 0,
parameter C_REG_SLICE_MODE_RACH = 0,
parameter C_REG_SLICE_MODE_RDCH = 0,
parameter C_REG_SLICE_MODE_AXIS = 0
)
(
//------------------------------------------------------------------------------
// Input and Output Declarations
//------------------------------------------------------------------------------
// Conventional FIFO Interface Signals
input backup,
input backup_marker,
input clk,
input rst,
input srst,
input wr_clk,
input wr_rst,
input rd_clk,
input rd_rst,
input [C_DIN_WIDTH-1:0] din,
input wr_en,
input rd_en,
// Optional inputs
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate,
input int_clk,
input injectdbiterr,
input injectsbiterr,
input sleep,
output [C_DOUT_WIDTH-1:0] dout,
output full,
output almost_full,
output wr_ack,
output overflow,
output empty,
output almost_empty,
output valid,
output underflow,
output [C_DATA_COUNT_WIDTH-1:0] data_count,
output [C_RD_DATA_COUNT_WIDTH-1:0] rd_data_count,
output [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count,
output prog_full,
output prog_empty,
output sbiterr,
output dbiterr,
output wr_rst_busy,
output rd_rst_busy,
// AXI Global Signal
input m_aclk,
input s_aclk,
input s_aresetn,
input s_aclk_en,
input m_aclk_en,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_awlen,
input [3-1:0] s_axi_awsize,
input [2-1:0] s_axi_awburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_awlock,
input [4-1:0] s_axi_awcache,
input [3-1:0] s_axi_awprot,
input [4-1:0] s_axi_awqos,
input [4-1:0] s_axi_awregion,
input [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser,
input s_axi_awvalid,
output s_axi_awready,
input [C_AXI_ID_WIDTH-1:0] s_axi_wid,
input [C_AXI_DATA_WIDTH-1:0] s_axi_wdata,
input [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb,
input s_axi_wlast,
input [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [2-1:0] s_axi_bresp,
output [C_AXI_BUSER_WIDTH-1:0] s_axi_buser,
output s_axi_bvalid,
input s_axi_bready,
// AXI Full/Lite Master Write Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_awlen,
output [3-1:0] m_axi_awsize,
output [2-1:0] m_axi_awburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_awlock,
output [4-1:0] m_axi_awcache,
output [3-1:0] m_axi_awprot,
output [4-1:0] m_axi_awqos,
output [4-1:0] m_axi_awregion,
output [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
output m_axi_awvalid,
input m_axi_awready,
output [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output m_axi_wlast,
output [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
output m_axi_wvalid,
input m_axi_wready,
input [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input [2-1:0] m_axi_bresp,
input [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
input m_axi_bvalid,
output m_axi_bready,
// AXI Full/Lite Slave Read Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_arlen,
input [3-1:0] s_axi_arsize,
input [2-1:0] s_axi_arburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_arlock,
input [4-1:0] s_axi_arcache,
input [3-1:0] s_axi_arprot,
input [4-1:0] s_axi_arqos,
input [4-1:0] s_axi_arregion,
input [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_AXI_DATA_WIDTH-1:0] s_axi_rdata,
output [2-1:0] s_axi_rresp,
output s_axi_rlast,
output [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser,
output s_axi_rvalid,
input s_axi_rready,
// AXI Full/Lite Master Read Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_arlen,
output [3-1:0] m_axi_arsize,
output [2-1:0] m_axi_arburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_arlock,
output [4-1:0] m_axi_arcache,
output [3-1:0] m_axi_arprot,
output [4-1:0] m_axi_arqos,
output [4-1:0] m_axi_arregion,
output [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
output m_axi_arvalid,
input m_axi_arready,
input [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input [2-1:0] m_axi_rresp,
input m_axi_rlast,
input [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
input m_axi_rvalid,
output m_axi_rready,
// AXI Streaming Slave Signals (Write side)
input s_axis_tvalid,
output s_axis_tready,
input [C_AXIS_TDATA_WIDTH-1:0] s_axis_tdata,
input [C_AXIS_TSTRB_WIDTH-1:0] s_axis_tstrb,
input [C_AXIS_TKEEP_WIDTH-1:0] s_axis_tkeep,
input s_axis_tlast,
input [C_AXIS_TID_WIDTH-1:0] s_axis_tid,
input [C_AXIS_TDEST_WIDTH-1:0] s_axis_tdest,
input [C_AXIS_TUSER_WIDTH-1:0] s_axis_tuser,
// AXI Streaming Master Signals (Read side)
output m_axis_tvalid,
input m_axis_tready,
output [C_AXIS_TDATA_WIDTH-1:0] m_axis_tdata,
output [C_AXIS_TSTRB_WIDTH-1:0] m_axis_tstrb,
output [C_AXIS_TKEEP_WIDTH-1:0] m_axis_tkeep,
output m_axis_tlast,
output [C_AXIS_TID_WIDTH-1:0] m_axis_tid,
output [C_AXIS_TDEST_WIDTH-1:0] m_axis_tdest,
output [C_AXIS_TUSER_WIDTH-1:0] m_axis_tuser,
// AXI Full/Lite Write Address Channel signals
input axi_aw_injectsbiterr,
input axi_aw_injectdbiterr,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_wr_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_rd_data_count,
output axi_aw_sbiterr,
output axi_aw_dbiterr,
output axi_aw_overflow,
output axi_aw_underflow,
output axi_aw_prog_full,
output axi_aw_prog_empty,
// AXI Full/Lite Write Data Channel signals
input axi_w_injectsbiterr,
input axi_w_injectdbiterr,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_wr_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_rd_data_count,
output axi_w_sbiterr,
output axi_w_dbiterr,
output axi_w_overflow,
output axi_w_underflow,
output axi_w_prog_full,
output axi_w_prog_empty,
// AXI Full/Lite Write Response Channel signals
input axi_b_injectsbiterr,
input axi_b_injectdbiterr,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_wr_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_rd_data_count,
output axi_b_sbiterr,
output axi_b_dbiterr,
output axi_b_overflow,
output axi_b_underflow,
output axi_b_prog_full,
output axi_b_prog_empty,
// AXI Full/Lite Read Address Channel signals
input axi_ar_injectsbiterr,
input axi_ar_injectdbiterr,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_wr_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_rd_data_count,
output axi_ar_sbiterr,
output axi_ar_dbiterr,
output axi_ar_overflow,
output axi_ar_underflow,
output axi_ar_prog_full,
output axi_ar_prog_empty,
// AXI Full/Lite Read Data Channel Signals
input axi_r_injectsbiterr,
input axi_r_injectdbiterr,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_wr_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_rd_data_count,
output axi_r_sbiterr,
output axi_r_dbiterr,
output axi_r_overflow,
output axi_r_underflow,
output axi_r_prog_full,
output axi_r_prog_empty,
// AXI Streaming FIFO Related Signals
input axis_injectsbiterr,
input axis_injectdbiterr,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_full_thresh,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_wr_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_rd_data_count,
output axis_sbiterr,
output axis_dbiterr,
output axis_overflow,
output axis_underflow,
output axis_prog_full,
output axis_prog_empty
);
wire BACKUP;
wire BACKUP_MARKER;
wire CLK;
wire RST;
wire SRST;
wire WR_CLK;
wire WR_RST;
wire RD_CLK;
wire RD_RST;
wire [C_DIN_WIDTH-1:0] DIN;
wire WR_EN;
wire RD_EN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire INT_CLK;
wire INJECTDBITERR;
wire INJECTSBITERR;
wire SLEEP;
wire [C_DOUT_WIDTH-1:0] DOUT;
wire FULL;
wire ALMOST_FULL;
wire WR_ACK;
wire OVERFLOW;
wire EMPTY;
wire ALMOST_EMPTY;
wire VALID;
wire UNDERFLOW;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT;
wire PROG_FULL;
wire PROG_EMPTY;
wire SBITERR;
wire DBITERR;
wire WR_RST_BUSY;
wire RD_RST_BUSY;
wire M_ACLK;
wire S_ACLK;
wire S_ARESETN;
wire S_ACLK_EN;
wire M_ACLK_EN;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_AWLEN;
wire [3-1:0] S_AXI_AWSIZE;
wire [2-1:0] S_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_AWLOCK;
wire [4-1:0] S_AXI_AWCACHE;
wire [3-1:0] S_AXI_AWPROT;
wire [4-1:0] S_AXI_AWQOS;
wire [4-1:0] S_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER;
wire S_AXI_AWVALID;
wire S_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB;
wire S_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER;
wire S_AXI_WVALID;
wire S_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [2-1:0] S_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER;
wire S_AXI_BVALID;
wire S_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_AWLEN;
wire [3-1:0] M_AXI_AWSIZE;
wire [2-1:0] M_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_AWLOCK;
wire [4-1:0] M_AXI_AWCACHE;
wire [3-1:0] M_AXI_AWPROT;
wire [4-1:0] M_AXI_AWQOS;
wire [4-1:0] M_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER;
wire M_AXI_AWVALID;
wire M_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB;
wire M_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER;
wire M_AXI_WVALID;
wire M_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID;
wire [2-1:0] M_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER;
wire M_AXI_BVALID;
wire M_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_ARLEN;
wire [3-1:0] S_AXI_ARSIZE;
wire [2-1:0] S_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_ARLOCK;
wire [4-1:0] S_AXI_ARCACHE;
wire [3-1:0] S_AXI_ARPROT;
wire [4-1:0] S_AXI_ARQOS;
wire [4-1:0] S_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER;
wire S_AXI_ARVALID;
wire S_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA;
wire [2-1:0] S_AXI_RRESP;
wire S_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER;
wire S_AXI_RVALID;
wire S_AXI_RREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_ARLEN;
wire [3-1:0] M_AXI_ARSIZE;
wire [2-1:0] M_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_ARLOCK;
wire [4-1:0] M_AXI_ARCACHE;
wire [3-1:0] M_AXI_ARPROT;
wire [4-1:0] M_AXI_ARQOS;
wire [4-1:0] M_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER;
wire M_AXI_ARVALID;
wire M_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA;
wire [2-1:0] M_AXI_RRESP;
wire M_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER;
wire M_AXI_RVALID;
wire M_AXI_RREADY;
wire S_AXIS_TVALID;
wire S_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] S_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] S_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] S_AXIS_TKEEP;
wire S_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] S_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] S_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] S_AXIS_TUSER;
wire M_AXIS_TVALID;
wire M_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] M_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] M_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] M_AXIS_TKEEP;
wire M_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] M_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] M_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] M_AXIS_TUSER;
wire AXI_AW_INJECTSBITERR;
wire AXI_AW_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_RD_DATA_COUNT;
wire AXI_AW_SBITERR;
wire AXI_AW_DBITERR;
wire AXI_AW_OVERFLOW;
wire AXI_AW_UNDERFLOW;
wire AXI_AW_PROG_FULL;
wire AXI_AW_PROG_EMPTY;
wire AXI_W_INJECTSBITERR;
wire AXI_W_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_RD_DATA_COUNT;
wire AXI_W_SBITERR;
wire AXI_W_DBITERR;
wire AXI_W_OVERFLOW;
wire AXI_W_UNDERFLOW;
wire AXI_W_PROG_FULL;
wire AXI_W_PROG_EMPTY;
wire AXI_B_INJECTSBITERR;
wire AXI_B_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_RD_DATA_COUNT;
wire AXI_B_SBITERR;
wire AXI_B_DBITERR;
wire AXI_B_OVERFLOW;
wire AXI_B_UNDERFLOW;
wire AXI_B_PROG_FULL;
wire AXI_B_PROG_EMPTY;
wire AXI_AR_INJECTSBITERR;
wire AXI_AR_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_RD_DATA_COUNT;
wire AXI_AR_SBITERR;
wire AXI_AR_DBITERR;
wire AXI_AR_OVERFLOW;
wire AXI_AR_UNDERFLOW;
wire AXI_AR_PROG_FULL;
wire AXI_AR_PROG_EMPTY;
wire AXI_R_INJECTSBITERR;
wire AXI_R_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_RD_DATA_COUNT;
wire AXI_R_SBITERR;
wire AXI_R_DBITERR;
wire AXI_R_OVERFLOW;
wire AXI_R_UNDERFLOW;
wire AXI_R_PROG_FULL;
wire AXI_R_PROG_EMPTY;
wire AXIS_INJECTSBITERR;
wire AXIS_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_RD_DATA_COUNT;
wire AXIS_SBITERR;
wire AXIS_DBITERR;
wire AXIS_OVERFLOW;
wire AXIS_UNDERFLOW;
wire AXIS_PROG_FULL;
wire AXIS_PROG_EMPTY;
wire [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count_in;
wire wr_rst_int;
wire rd_rst_int;
wire wr_rst_busy_o;
wire wr_rst_busy_ntve;
wire wr_rst_busy_axis;
wire wr_rst_busy_wach;
wire wr_rst_busy_wdch;
wire wr_rst_busy_wrch;
wire wr_rst_busy_rach;
wire wr_rst_busy_rdch;
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// Conventional FIFO Interface Signals
assign BACKUP = backup;
assign BACKUP_MARKER = backup_marker;
assign CLK = clk;
assign RST = rst;
assign SRST = srst;
assign WR_CLK = wr_clk;
assign WR_RST = wr_rst;
assign RD_CLK = rd_clk;
assign RD_RST = rd_rst;
assign WR_EN = wr_en;
assign RD_EN = rd_en;
assign INT_CLK = int_clk;
assign INJECTDBITERR = injectdbiterr;
assign INJECTSBITERR = injectsbiterr;
assign SLEEP = sleep;
assign full = FULL;
assign almost_full = ALMOST_FULL;
assign wr_ack = WR_ACK;
assign overflow = OVERFLOW;
assign empty = EMPTY;
assign almost_empty = ALMOST_EMPTY;
assign valid = VALID;
assign underflow = UNDERFLOW;
assign prog_full = PROG_FULL;
assign prog_empty = PROG_EMPTY;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
// assign wr_rst_busy = WR_RST_BUSY | wr_rst_busy_o;
assign wr_rst_busy = wr_rst_busy_o;
assign rd_rst_busy = RD_RST_BUSY;
assign M_ACLK = m_aclk;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_ACLK_EN = s_aclk_en;
assign M_ACLK_EN = m_aclk_en;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign m_axi_awvalid = M_AXI_AWVALID;
assign M_AXI_AWREADY = m_axi_awready;
assign m_axi_wlast = M_AXI_WLAST;
assign m_axi_wvalid = M_AXI_WVALID;
assign M_AXI_WREADY = m_axi_wready;
assign M_AXI_BVALID = m_axi_bvalid;
assign m_axi_bready = M_AXI_BREADY;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign m_axi_arvalid = M_AXI_ARVALID;
assign M_AXI_ARREADY = m_axi_arready;
assign M_AXI_RLAST = m_axi_rlast;
assign M_AXI_RVALID = m_axi_rvalid;
assign m_axi_rready = M_AXI_RREADY;
assign S_AXIS_TVALID = s_axis_tvalid;
assign s_axis_tready = S_AXIS_TREADY;
assign S_AXIS_TLAST = s_axis_tlast;
assign m_axis_tvalid = M_AXIS_TVALID;
assign M_AXIS_TREADY = m_axis_tready;
assign m_axis_tlast = M_AXIS_TLAST;
assign AXI_AW_INJECTSBITERR = axi_aw_injectsbiterr;
assign AXI_AW_INJECTDBITERR = axi_aw_injectdbiterr;
assign axi_aw_sbiterr = AXI_AW_SBITERR;
assign axi_aw_dbiterr = AXI_AW_DBITERR;
assign axi_aw_overflow = AXI_AW_OVERFLOW;
assign axi_aw_underflow = AXI_AW_UNDERFLOW;
assign axi_aw_prog_full = AXI_AW_PROG_FULL;
assign axi_aw_prog_empty = AXI_AW_PROG_EMPTY;
assign AXI_W_INJECTSBITERR = axi_w_injectsbiterr;
assign AXI_W_INJECTDBITERR = axi_w_injectdbiterr;
assign axi_w_sbiterr = AXI_W_SBITERR;
assign axi_w_dbiterr = AXI_W_DBITERR;
assign axi_w_overflow = AXI_W_OVERFLOW;
assign axi_w_underflow = AXI_W_UNDERFLOW;
assign axi_w_prog_full = AXI_W_PROG_FULL;
assign axi_w_prog_empty = AXI_W_PROG_EMPTY;
assign AXI_B_INJECTSBITERR = axi_b_injectsbiterr;
assign AXI_B_INJECTDBITERR = axi_b_injectdbiterr;
assign axi_b_sbiterr = AXI_B_SBITERR;
assign axi_b_dbiterr = AXI_B_DBITERR;
assign axi_b_overflow = AXI_B_OVERFLOW;
assign axi_b_underflow = AXI_B_UNDERFLOW;
assign axi_b_prog_full = AXI_B_PROG_FULL;
assign axi_b_prog_empty = AXI_B_PROG_EMPTY;
assign AXI_AR_INJECTSBITERR = axi_ar_injectsbiterr;
assign AXI_AR_INJECTDBITERR = axi_ar_injectdbiterr;
assign axi_ar_sbiterr = AXI_AR_SBITERR;
assign axi_ar_dbiterr = AXI_AR_DBITERR;
assign axi_ar_overflow = AXI_AR_OVERFLOW;
assign axi_ar_underflow = AXI_AR_UNDERFLOW;
assign axi_ar_prog_full = AXI_AR_PROG_FULL;
assign axi_ar_prog_empty = AXI_AR_PROG_EMPTY;
assign AXI_R_INJECTSBITERR = axi_r_injectsbiterr;
assign AXI_R_INJECTDBITERR = axi_r_injectdbiterr;
assign axi_r_sbiterr = AXI_R_SBITERR;
assign axi_r_dbiterr = AXI_R_DBITERR;
assign axi_r_overflow = AXI_R_OVERFLOW;
assign axi_r_underflow = AXI_R_UNDERFLOW;
assign axi_r_prog_full = AXI_R_PROG_FULL;
assign axi_r_prog_empty = AXI_R_PROG_EMPTY;
assign AXIS_INJECTSBITERR = axis_injectsbiterr;
assign AXIS_INJECTDBITERR = axis_injectdbiterr;
assign axis_sbiterr = AXIS_SBITERR;
assign axis_dbiterr = AXIS_DBITERR;
assign axis_overflow = AXIS_OVERFLOW;
assign axis_underflow = AXIS_UNDERFLOW;
assign axis_prog_full = AXIS_PROG_FULL;
assign axis_prog_empty = AXIS_PROG_EMPTY;
assign DIN = din;
assign PROG_EMPTY_THRESH = prog_empty_thresh;
assign PROG_EMPTY_THRESH_ASSERT = prog_empty_thresh_assert;
assign PROG_EMPTY_THRESH_NEGATE = prog_empty_thresh_negate;
assign PROG_FULL_THRESH = prog_full_thresh;
assign PROG_FULL_THRESH_ASSERT = prog_full_thresh_assert;
assign PROG_FULL_THRESH_NEGATE = prog_full_thresh_negate;
assign dout = DOUT;
assign data_count = DATA_COUNT;
assign rd_data_count = RD_DATA_COUNT;
assign wr_data_count = WR_DATA_COUNT;
assign S_AXI_AWID = s_axi_awid;
assign S_AXI_AWADDR = s_axi_awaddr;
assign S_AXI_AWLEN = s_axi_awlen;
assign S_AXI_AWSIZE = s_axi_awsize;
assign S_AXI_AWBURST = s_axi_awburst;
assign S_AXI_AWLOCK = s_axi_awlock;
assign S_AXI_AWCACHE = s_axi_awcache;
assign S_AXI_AWPROT = s_axi_awprot;
assign S_AXI_AWQOS = s_axi_awqos;
assign S_AXI_AWREGION = s_axi_awregion;
assign S_AXI_AWUSER = s_axi_awuser;
assign S_AXI_WID = s_axi_wid;
assign S_AXI_WDATA = s_axi_wdata;
assign S_AXI_WSTRB = s_axi_wstrb;
assign S_AXI_WUSER = s_axi_wuser;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_buser = S_AXI_BUSER;
assign m_axi_awid = M_AXI_AWID;
assign m_axi_awaddr = M_AXI_AWADDR;
assign m_axi_awlen = M_AXI_AWLEN;
assign m_axi_awsize = M_AXI_AWSIZE;
assign m_axi_awburst = M_AXI_AWBURST;
assign m_axi_awlock = M_AXI_AWLOCK;
assign m_axi_awcache = M_AXI_AWCACHE;
assign m_axi_awprot = M_AXI_AWPROT;
assign m_axi_awqos = M_AXI_AWQOS;
assign m_axi_awregion = M_AXI_AWREGION;
assign m_axi_awuser = M_AXI_AWUSER;
assign m_axi_wid = M_AXI_WID;
assign m_axi_wdata = M_AXI_WDATA;
assign m_axi_wstrb = M_AXI_WSTRB;
assign m_axi_wuser = M_AXI_WUSER;
assign M_AXI_BID = m_axi_bid;
assign M_AXI_BRESP = m_axi_bresp;
assign M_AXI_BUSER = m_axi_buser;
assign S_AXI_ARID = s_axi_arid;
assign S_AXI_ARADDR = s_axi_araddr;
assign S_AXI_ARLEN = s_axi_arlen;
assign S_AXI_ARSIZE = s_axi_arsize;
assign S_AXI_ARBURST = s_axi_arburst;
assign S_AXI_ARLOCK = s_axi_arlock;
assign S_AXI_ARCACHE = s_axi_arcache;
assign S_AXI_ARPROT = s_axi_arprot;
assign S_AXI_ARQOS = s_axi_arqos;
assign S_AXI_ARREGION = s_axi_arregion;
assign S_AXI_ARUSER = s_axi_aruser;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_ruser = S_AXI_RUSER;
assign m_axi_arid = M_AXI_ARID;
assign m_axi_araddr = M_AXI_ARADDR;
assign m_axi_arlen = M_AXI_ARLEN;
assign m_axi_arsize = M_AXI_ARSIZE;
assign m_axi_arburst = M_AXI_ARBURST;
assign m_axi_arlock = M_AXI_ARLOCK;
assign m_axi_arcache = M_AXI_ARCACHE;
assign m_axi_arprot = M_AXI_ARPROT;
assign m_axi_arqos = M_AXI_ARQOS;
assign m_axi_arregion = M_AXI_ARREGION;
assign m_axi_aruser = M_AXI_ARUSER;
assign M_AXI_RID = m_axi_rid;
assign M_AXI_RDATA = m_axi_rdata;
assign M_AXI_RRESP = m_axi_rresp;
assign M_AXI_RUSER = m_axi_ruser;
assign S_AXIS_TDATA = s_axis_tdata;
assign S_AXIS_TSTRB = s_axis_tstrb;
assign S_AXIS_TKEEP = s_axis_tkeep;
assign S_AXIS_TID = s_axis_tid;
assign S_AXIS_TDEST = s_axis_tdest;
assign S_AXIS_TUSER = s_axis_tuser;
assign m_axis_tdata = M_AXIS_TDATA;
assign m_axis_tstrb = M_AXIS_TSTRB;
assign m_axis_tkeep = M_AXIS_TKEEP;
assign m_axis_tid = M_AXIS_TID;
assign m_axis_tdest = M_AXIS_TDEST;
assign m_axis_tuser = M_AXIS_TUSER;
assign AXI_AW_PROG_FULL_THRESH = axi_aw_prog_full_thresh;
assign AXI_AW_PROG_EMPTY_THRESH = axi_aw_prog_empty_thresh;
assign axi_aw_data_count = AXI_AW_DATA_COUNT;
assign axi_aw_wr_data_count = AXI_AW_WR_DATA_COUNT;
assign axi_aw_rd_data_count = AXI_AW_RD_DATA_COUNT;
assign AXI_W_PROG_FULL_THRESH = axi_w_prog_full_thresh;
assign AXI_W_PROG_EMPTY_THRESH = axi_w_prog_empty_thresh;
assign axi_w_data_count = AXI_W_DATA_COUNT;
assign axi_w_wr_data_count = AXI_W_WR_DATA_COUNT;
assign axi_w_rd_data_count = AXI_W_RD_DATA_COUNT;
assign AXI_B_PROG_FULL_THRESH = axi_b_prog_full_thresh;
assign AXI_B_PROG_EMPTY_THRESH = axi_b_prog_empty_thresh;
assign axi_b_data_count = AXI_B_DATA_COUNT;
assign axi_b_wr_data_count = AXI_B_WR_DATA_COUNT;
assign axi_b_rd_data_count = AXI_B_RD_DATA_COUNT;
assign AXI_AR_PROG_FULL_THRESH = axi_ar_prog_full_thresh;
assign AXI_AR_PROG_EMPTY_THRESH = axi_ar_prog_empty_thresh;
assign axi_ar_data_count = AXI_AR_DATA_COUNT;
assign axi_ar_wr_data_count = AXI_AR_WR_DATA_COUNT;
assign axi_ar_rd_data_count = AXI_AR_RD_DATA_COUNT;
assign AXI_R_PROG_FULL_THRESH = axi_r_prog_full_thresh;
assign AXI_R_PROG_EMPTY_THRESH = axi_r_prog_empty_thresh;
assign axi_r_data_count = AXI_R_DATA_COUNT;
assign axi_r_wr_data_count = AXI_R_WR_DATA_COUNT;
assign axi_r_rd_data_count = AXI_R_RD_DATA_COUNT;
assign AXIS_PROG_FULL_THRESH = axis_prog_full_thresh;
assign AXIS_PROG_EMPTY_THRESH = axis_prog_empty_thresh;
assign axis_data_count = AXIS_DATA_COUNT;
assign axis_wr_data_count = AXIS_WR_DATA_COUNT;
assign axis_rd_data_count = AXIS_RD_DATA_COUNT;
generate if (C_INTERFACE_TYPE == 0) begin : conv_fifo
fifo_generator_v13_1_3_CONV_VER
#(
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_USE_DOUT_RST == 1 ? C_DOUT_RST_VAL : 0),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_FAMILY (C_FAMILY),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RD_RST (C_HAS_RD_RST),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_HAS_WR_RST (C_HAS_WR_RST),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_FREQ (C_RD_FREQ),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE)
)
fifo_generator_v13_1_3_conv_dut
(
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.CLK (CLK),
.RST (RST),
.SRST (SRST),
.WR_CLK (WR_CLK),
.WR_RST (WR_RST),
.RD_CLK (RD_CLK),
.RD_RST (RD_RST),
.DIN (DIN),
.WR_EN (WR_EN),
.RD_EN (RD_EN),
.PROG_EMPTY_THRESH (PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT (PROG_EMPTY_THRESH_ASSERT),
.PROG_EMPTY_THRESH_NEGATE (PROG_EMPTY_THRESH_NEGATE),
.PROG_FULL_THRESH (PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT (PROG_FULL_THRESH_ASSERT),
.PROG_FULL_THRESH_NEGATE (PROG_FULL_THRESH_NEGATE),
.INT_CLK (INT_CLK),
.INJECTDBITERR (INJECTDBITERR),
.INJECTSBITERR (INJECTSBITERR),
.DOUT (DOUT),
.FULL (FULL),
.ALMOST_FULL (ALMOST_FULL),
.WR_ACK (WR_ACK),
.OVERFLOW (OVERFLOW),
.EMPTY (EMPTY),
.ALMOST_EMPTY (ALMOST_EMPTY),
.VALID (VALID),
.UNDERFLOW (UNDERFLOW),
.DATA_COUNT (DATA_COUNT),
.RD_DATA_COUNT (RD_DATA_COUNT),
.WR_DATA_COUNT (wr_data_count_in),
.PROG_FULL (PROG_FULL),
.PROG_EMPTY (PROG_EMPTY),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.wr_rst_busy_o (wr_rst_busy_o),
.wr_rst_busy (wr_rst_busy_i),
.rd_rst_busy (rd_rst_busy),
.wr_rst_i_out (wr_rst_int),
.rd_rst_i_out (rd_rst_int)
);
end endgenerate
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_AXI_SIZE_WIDTH = 3;
localparam C_AXI_BURST_WIDTH = 2;
localparam C_AXI_CACHE_WIDTH = 4;
localparam C_AXI_PROT_WIDTH = 3;
localparam C_AXI_QOS_WIDTH = 4;
localparam C_AXI_REGION_WIDTH = 4;
localparam C_AXI_BRESP_WIDTH = 2;
localparam C_AXI_RRESP_WIDTH = 2;
localparam IS_AXI_STREAMING = C_INTERFACE_TYPE == 1 ? 1 : 0;
localparam TDATA_OFFSET = C_HAS_AXIS_TDATA == 1 ? C_DIN_WIDTH_AXIS-C_AXIS_TDATA_WIDTH : C_DIN_WIDTH_AXIS;
localparam TSTRB_OFFSET = C_HAS_AXIS_TSTRB == 1 ? TDATA_OFFSET-C_AXIS_TSTRB_WIDTH : TDATA_OFFSET;
localparam TKEEP_OFFSET = C_HAS_AXIS_TKEEP == 1 ? TSTRB_OFFSET-C_AXIS_TKEEP_WIDTH : TSTRB_OFFSET;
localparam TID_OFFSET = C_HAS_AXIS_TID == 1 ? TKEEP_OFFSET-C_AXIS_TID_WIDTH : TKEEP_OFFSET;
localparam TDEST_OFFSET = C_HAS_AXIS_TDEST == 1 ? TID_OFFSET-C_AXIS_TDEST_WIDTH : TID_OFFSET;
localparam TUSER_OFFSET = C_HAS_AXIS_TUSER == 1 ? TDEST_OFFSET-C_AXIS_TUSER_WIDTH : TDEST_OFFSET;
localparam LOG_DEPTH_AXIS = find_log2(C_WR_DEPTH_AXIS);
localparam LOG_WR_DEPTH = find_log2(C_WR_DEPTH);
function [LOG_DEPTH_AXIS-1:0] bin2gray;
input [LOG_DEPTH_AXIS-1:0] x;
begin
bin2gray = x ^ (x>>1);
end
endfunction
function [LOG_DEPTH_AXIS-1:0] gray2bin;
input [LOG_DEPTH_AXIS-1:0] x;
integer i;
begin
gray2bin[LOG_DEPTH_AXIS-1] = x[LOG_DEPTH_AXIS-1];
for(i=LOG_DEPTH_AXIS-2; i>=0; i=i-1) begin
gray2bin[i] = gray2bin[i+1] ^ x[i];
end
end
endfunction
wire [(LOG_WR_DEPTH)-1 : 0] w_cnt_gc_asreg_last;
wire [LOG_WR_DEPTH-1 : 0] w_q [0:C_SYNCHRONIZER_STAGE] ;
wire [LOG_WR_DEPTH-1 : 0] w_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_rd = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_gc = 0;
reg [LOG_WR_DEPTH-1 : 0] r_cnt = 0;
wire [LOG_WR_DEPTH : 0] adj_w_cnt_rd_pad;
wire [LOG_WR_DEPTH : 0] r_inv_pad;
wire [LOG_WR_DEPTH-1 : 0] d_cnt;
reg [LOG_WR_DEPTH : 0] d_cnt_pad = 0;
reg adj_w_cnt_rd_pad_0 = 0;
reg r_inv_pad_0 = 0;
genvar l;
generate for (l = 1; ((l <= C_SYNCHRONIZER_STAGE) && (C_HAS_DATA_COUNTS_AXIS == 3 && C_INTERFACE_TYPE == 0) ); l = l + 1) begin : g_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_WR_DEPTH)
)
rd_stg_inst
(
.RST (rd_rst_int),
.CLK (RD_CLK),
.DIN (w_q[l-1]),
.DOUT (w_q[l])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS == 3) begin : fifo_ic_adapter
assign wr_eop_ad = WR_EN & !(FULL);
assign rd_eop_ad = RD_EN & !(EMPTY);
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt <= 1'b0;
else if (wr_eop_ad)
w_cnt <= w_cnt + 1;
end
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt_gc <= 1'b0;
else
w_cnt_gc <= bin2gray(w_cnt);
end
assign w_q[0] = w_cnt_gc;
assign w_cnt_gc_asreg_last = w_q[C_SYNCHRONIZER_STAGE];
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
w_cnt_rd <= 1'b0;
else
w_cnt_rd <= gray2bin(w_cnt_gc_asreg_last);
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
r_cnt <= 1'b0;
else if (rd_eop_ad)
r_cnt <= r_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_w_cnt_rd_pad[LOG_WR_DEPTH : 1] = w_cnt_rd;
assign r_inv_pad[LOG_WR_DEPTH : 1] = ~r_cnt;
assign adj_w_cnt_rd_pad[0] = adj_w_cnt_rd_pad_0;
assign r_inv_pad[0] = r_inv_pad_0;
always @ ( rd_eop_ad )
begin
if (!rd_eop_ad) begin
adj_w_cnt_rd_pad_0 <= 1'b1;
r_inv_pad_0 <= 1'b1;
end else begin
adj_w_cnt_rd_pad_0 <= 1'b0;
r_inv_pad_0 <= 1'b0;
end
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
d_cnt_pad <= 1'b0;
else
d_cnt_pad <= adj_w_cnt_rd_pad + r_inv_pad ;
end
assign d_cnt = d_cnt_pad [LOG_WR_DEPTH : 1] ;
assign WR_DATA_COUNT = d_cnt;
end endgenerate // fifo_ic_adapter
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS != 3) begin : fifo_icn_adapter
assign WR_DATA_COUNT = wr_data_count_in;
end endgenerate // fifo_icn_adapter
wire inverted_reset = ~S_ARESETN;
wire axi_rs_rst;
wire [C_DIN_WIDTH_AXIS-1:0] axis_din ;
wire [C_DIN_WIDTH_AXIS-1:0] axis_dout ;
wire axis_full ;
wire axis_almost_full ;
wire axis_empty ;
wire axis_s_axis_tready;
wire axis_m_axis_tvalid;
wire axis_wr_en ;
wire axis_rd_en ;
wire axis_we ;
wire axis_re ;
wire [C_WR_PNTR_WIDTH_AXIS:0] axis_dc;
reg axis_pkt_read = 1'b0;
wire axis_rd_rst;
wire axis_wr_rst;
generate if (C_INTERFACE_TYPE > 0 && (C_AXIS_TYPE == 1 || C_WACH_TYPE == 1 ||
C_WDCH_TYPE == 1 || C_WRCH_TYPE == 1 || C_RACH_TYPE == 1 || C_RDCH_TYPE == 1)) begin : gaxi_rs_rst
reg rst_d1 = 0 ;
reg rst_d2 = 0 ;
reg [3:0] axi_rst = 4'h0 ;
always @ (posedge inverted_reset or posedge S_ACLK) begin
if (inverted_reset) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
axi_rst <= 4'hf;
end else begin
rst_d1 <= #`TCQ 1'b0;
rst_d2 <= #`TCQ rst_d1;
axi_rst <= #`TCQ {axi_rst[2:0],1'b0};
end
end
assign axi_rs_rst = axi_rst[3];//rst_d2;
end endgenerate // gaxi_rs_rst
generate if (IS_AXI_STREAMING == 1 && C_AXIS_TYPE == 0) begin : axi_streaming
// Write protection when almost full or prog_full is high
assign axis_we = (C_PROG_FULL_TYPE_AXIS != 0) ? axis_s_axis_tready & S_AXIS_TVALID :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_s_axis_tready & S_AXIS_TVALID : S_AXIS_TVALID;
// Read protection when almost empty or prog_empty is high
assign axis_re = (C_PROG_EMPTY_TYPE_AXIS != 0) ? axis_m_axis_tvalid & M_AXIS_TREADY :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_m_axis_tvalid & M_AXIS_TREADY : M_AXIS_TREADY;
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? axis_we & S_ACLK_EN : axis_we;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? axis_re & M_ACLK_EN : axis_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_AXIS == 2 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_AXIS == 11 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_AXIS),
.C_WR_DEPTH (C_WR_DEPTH_AXIS),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_DOUT_WIDTH (C_DIN_WIDTH_AXIS),
.C_RD_DEPTH (C_WR_DEPTH_AXIS),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_AXIS),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_AXIS),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_AXIS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS),
.C_USE_ECC (C_USE_ECC_AXIS),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_AXIS),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (C_APPLICATION_TYPE_AXIS == 1 ? 1: 0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_FIFO_TYPE (C_APPLICATION_TYPE_AXIS == 1 ? 0: C_APPLICATION_TYPE_AXIS),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_axis_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (axis_wr_en),
.RD_EN (axis_rd_en),
.PROG_FULL_THRESH (AXIS_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH (AXIS_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.INJECTDBITERR (AXIS_INJECTDBITERR),
.INJECTSBITERR (AXIS_INJECTSBITERR),
.DIN (axis_din),
.DOUT (axis_dout),
.FULL (axis_full),
.EMPTY (axis_empty),
.ALMOST_FULL (axis_almost_full),
.PROG_FULL (AXIS_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXIS_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (AXIS_OVERFLOW),
.VALID (),
.UNDERFLOW (AXIS_UNDERFLOW),
.DATA_COUNT (axis_dc),
.RD_DATA_COUNT (AXIS_RD_DATA_COUNT),
.WR_DATA_COUNT (AXIS_WR_DATA_COUNT),
.SBITERR (AXIS_SBITERR),
.DBITERR (AXIS_DBITERR),
.wr_rst_busy (wr_rst_busy_axis),
.rd_rst_busy (rd_rst_busy_axis),
.wr_rst_i_out (axis_wr_rst),
.rd_rst_i_out (axis_rd_rst),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign axis_s_axis_tready = (IS_8SERIES == 0) ? ~axis_full : (C_IMPLEMENTATION_TYPE_AXIS == 5 || C_IMPLEMENTATION_TYPE_AXIS == 13) ? ~(axis_full | wr_rst_busy_axis) : ~axis_full;
assign axis_m_axis_tvalid = (C_APPLICATION_TYPE_AXIS != 1) ? ~axis_empty : ~axis_empty & axis_pkt_read;
assign S_AXIS_TREADY = axis_s_axis_tready;
assign M_AXIS_TVALID = axis_m_axis_tvalid;
end endgenerate // axi_streaming
wire axis_wr_eop;
reg axis_wr_eop_d1 = 1'b0;
wire axis_rd_eop;
integer axis_pkt_cnt;
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 1) begin : gaxis_pkt_fifo_cc
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (axis_pkt_cnt == 1) && ~axis_wr_eop_d1)
axis_pkt_read <= 1'b0;
else if ((axis_pkt_cnt > 0) || (axis_almost_full && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_wr_eop_d1 <= 1'b0;
else
axis_wr_eop_d1 <= axis_wr_eop;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_cnt <= 0;
else if (axis_wr_eop_d1 && ~axis_rd_eop)
axis_pkt_cnt <= axis_pkt_cnt + 1;
else if (axis_rd_eop && ~axis_wr_eop_d1)
axis_pkt_cnt <= axis_pkt_cnt - 1;
end
end endgenerate // gaxis_pkt_fifo_cc
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_gc = 0;
wire [(LOG_DEPTH_AXIS)-1 : 0] axis_wpkt_cnt_gc_asreg_last;
wire axis_rd_has_rst;
wire [0:C_SYNCHRONIZER_STAGE] axis_af_q ;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q [0:C_SYNCHRONIZER_STAGE] ;
wire [1:C_SYNCHRONIZER_STAGE] axis_af_q_temp = 0;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_rd = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_rpkt_cnt = 0;
wire [LOG_DEPTH_AXIS : 0] adj_axis_wpkt_cnt_rd_pad;
wire [LOG_DEPTH_AXIS : 0] rpkt_inv_pad;
wire [LOG_DEPTH_AXIS-1 : 0] diff_pkt_cnt;
reg [LOG_DEPTH_AXIS : 0] diff_pkt_cnt_pad = 0;
reg adj_axis_wpkt_cnt_rd_pad_0 = 0;
reg rpkt_inv_pad_0 = 0;
wire axis_af_rd ;
generate if (C_HAS_RST == 1) begin : rst_blk_has
assign axis_rd_has_rst = axis_rd_rst;
end endgenerate //rst_blk_has
generate if (C_HAS_RST == 0) begin :rst_blk_no
assign axis_rd_has_rst = 1'b0;
end endgenerate //rst_blk_no
genvar i;
generate for (i = 1; ((i <= C_SYNCHRONIZER_STAGE) && (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) ); i = i + 1) begin : gpkt_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_DEPTH_AXIS)
)
rd_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (wpkt_q[i-1]),
.DOUT (wpkt_q[i])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (1)
)
wr_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (axis_af_q[i-1]),
.DOUT (axis_af_q[i])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) begin : gaxis_pkt_fifo_ic
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (diff_pkt_cnt == 1))
axis_pkt_read <= 1'b0;
else if ((diff_pkt_cnt > 0) || (axis_af_rd && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt <= 1'b0;
else if (axis_wr_eop)
axis_wpkt_cnt <= axis_wpkt_cnt + 1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt_gc <= 1'b0;
else
axis_wpkt_cnt_gc <= bin2gray(axis_wpkt_cnt);
end
assign wpkt_q[0] = axis_wpkt_cnt_gc;
assign axis_wpkt_cnt_gc_asreg_last = wpkt_q[C_SYNCHRONIZER_STAGE];
assign axis_af_q[0] = axis_almost_full;
//assign axis_af_q[1:C_SYNCHRONIZER_STAGE] = axis_af_q_temp[1:C_SYNCHRONIZER_STAGE];
assign axis_af_rd = axis_af_q[C_SYNCHRONIZER_STAGE];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_wpkt_cnt_rd <= 1'b0;
else
axis_wpkt_cnt_rd <= gray2bin(axis_wpkt_cnt_gc_asreg_last);
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_rpkt_cnt <= 1'b0;
else if (axis_rd_eop)
axis_rpkt_cnt <= axis_rpkt_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_axis_wpkt_cnt_rd_pad[LOG_DEPTH_AXIS : 1] = axis_wpkt_cnt_rd;
assign rpkt_inv_pad[LOG_DEPTH_AXIS : 1] = ~axis_rpkt_cnt;
assign adj_axis_wpkt_cnt_rd_pad[0] = adj_axis_wpkt_cnt_rd_pad_0;
assign rpkt_inv_pad[0] = rpkt_inv_pad_0;
always @ ( axis_rd_eop )
begin
if (!axis_rd_eop) begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b1;
rpkt_inv_pad_0 <= 1'b1;
end else begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b0;
rpkt_inv_pad_0 <= 1'b0;
end
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
diff_pkt_cnt_pad <= 1'b0;
else
diff_pkt_cnt_pad <= adj_axis_wpkt_cnt_rd_pad + rpkt_inv_pad ;
end
assign diff_pkt_cnt = diff_pkt_cnt_pad [LOG_DEPTH_AXIS : 1] ;
end endgenerate // gaxis_pkt_fifo_ic
// Generate the accurate data count for axi stream packet fifo configuration
reg [C_WR_PNTR_WIDTH_AXIS:0] axis_dc_pkt_fifo = 0;
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 1 && C_APPLICATION_TYPE_AXIS == 1) begin : gdc_pkt
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_dc_pkt_fifo <= 0;
else if (axis_wr_en && (~axis_rd_en))
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo + 1;
else if (~axis_wr_en && axis_rd_en)
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo - 1;
end
assign AXIS_DATA_COUNT = axis_dc_pkt_fifo;
end endgenerate // gdc_pkt
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 0 && C_APPLICATION_TYPE_AXIS == 1) begin : gndc_pkt
assign AXIS_DATA_COUNT = 0;
end endgenerate // gndc_pkt
generate if (IS_AXI_STREAMING == 1 && C_APPLICATION_TYPE_AXIS != 1) begin : gdc
assign AXIS_DATA_COUNT = axis_dc;
end endgenerate // gdc
// Register Slice for Write Address Channel
generate if (C_AXIS_TYPE == 1) begin : gaxis_reg_slice
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? S_AXIS_TVALID & S_ACLK_EN : S_AXIS_TVALID;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? M_AXIS_TREADY & M_ACLK_EN : M_AXIS_TREADY;
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_AXIS),
.C_REG_CONFIG (C_REG_SLICE_MODE_AXIS)
)
axis_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (axis_din),
.S_VALID (axis_wr_en),
.S_READY (S_AXIS_TREADY),
// Master side
.M_PAYLOAD_DATA (axis_dout),
.M_VALID (M_AXIS_TVALID),
.M_READY (axis_rd_en)
);
end endgenerate // gaxis_reg_slice
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDATA == 1) begin : tdata
assign axis_din[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET] = S_AXIS_TDATA;
assign M_AXIS_TDATA = axis_dout[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TSTRB == 1) begin : tstrb
assign axis_din[TDATA_OFFSET-1:TSTRB_OFFSET] = S_AXIS_TSTRB;
assign M_AXIS_TSTRB = axis_dout[TDATA_OFFSET-1:TSTRB_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TKEEP == 1) begin : tkeep
assign axis_din[TSTRB_OFFSET-1:TKEEP_OFFSET] = S_AXIS_TKEEP;
assign M_AXIS_TKEEP = axis_dout[TSTRB_OFFSET-1:TKEEP_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TID == 1) begin : tid
assign axis_din[TKEEP_OFFSET-1:TID_OFFSET] = S_AXIS_TID;
assign M_AXIS_TID = axis_dout[TKEEP_OFFSET-1:TID_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDEST == 1) begin : tdest
assign axis_din[TID_OFFSET-1:TDEST_OFFSET] = S_AXIS_TDEST;
assign M_AXIS_TDEST = axis_dout[TID_OFFSET-1:TDEST_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TUSER == 1) begin : tuser
assign axis_din[TDEST_OFFSET-1:TUSER_OFFSET] = S_AXIS_TUSER;
assign M_AXIS_TUSER = axis_dout[TDEST_OFFSET-1:TUSER_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TLAST == 1) begin : tlast
assign axis_din[0] = S_AXIS_TLAST;
assign M_AXIS_TLAST = axis_dout[0];
end endgenerate
//###########################################################################
// AXI FULL Write Channel (axi_write_channel)
//###########################################################################
localparam IS_AXI_FULL = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE != 2)) ? 1 : 0;
localparam IS_AXI_LITE = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE == 2)) ? 1 : 0;
localparam IS_AXI_FULL_WACH = ((IS_AXI_FULL == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WDCH = ((IS_AXI_FULL == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WRCH = ((IS_AXI_FULL == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RACH = ((IS_AXI_FULL == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RDCH = ((IS_AXI_FULL == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WACH = ((IS_AXI_LITE == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WDCH = ((IS_AXI_LITE == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WRCH = ((IS_AXI_LITE == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RACH = ((IS_AXI_LITE == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RDCH = ((IS_AXI_LITE == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_WR_ADDR_CH = ((IS_AXI_FULL_WACH == 1) || (IS_AXI_LITE_WACH == 1)) ? 1 : 0;
localparam IS_WR_DATA_CH = ((IS_AXI_FULL_WDCH == 1) || (IS_AXI_LITE_WDCH == 1)) ? 1 : 0;
localparam IS_WR_RESP_CH = ((IS_AXI_FULL_WRCH == 1) || (IS_AXI_LITE_WRCH == 1)) ? 1 : 0;
localparam IS_RD_ADDR_CH = ((IS_AXI_FULL_RACH == 1) || (IS_AXI_LITE_RACH == 1)) ? 1 : 0;
localparam IS_RD_DATA_CH = ((IS_AXI_FULL_RDCH == 1) || (IS_AXI_LITE_RDCH == 1)) ? 1 : 0;
localparam AWID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WACH;
localparam AWADDR_OFFSET = AWID_OFFSET - C_AXI_ADDR_WIDTH;
localparam AWLEN_OFFSET = C_AXI_TYPE != 2 ? AWADDR_OFFSET - C_AXI_LEN_WIDTH : AWADDR_OFFSET;
localparam AWSIZE_OFFSET = C_AXI_TYPE != 2 ? AWLEN_OFFSET - C_AXI_SIZE_WIDTH : AWLEN_OFFSET;
localparam AWBURST_OFFSET = C_AXI_TYPE != 2 ? AWSIZE_OFFSET - C_AXI_BURST_WIDTH : AWSIZE_OFFSET;
localparam AWLOCK_OFFSET = C_AXI_TYPE != 2 ? AWBURST_OFFSET - C_AXI_LOCK_WIDTH : AWBURST_OFFSET;
localparam AWCACHE_OFFSET = C_AXI_TYPE != 2 ? AWLOCK_OFFSET - C_AXI_CACHE_WIDTH : AWLOCK_OFFSET;
localparam AWPROT_OFFSET = AWCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam AWQOS_OFFSET = AWPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam AWREGION_OFFSET = C_AXI_TYPE == 1 ? AWQOS_OFFSET - C_AXI_REGION_WIDTH : AWQOS_OFFSET;
localparam AWUSER_OFFSET = C_HAS_AXI_AWUSER == 1 ? AWREGION_OFFSET-C_AXI_AWUSER_WIDTH : AWREGION_OFFSET;
localparam WID_OFFSET = (C_AXI_TYPE == 3 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WDCH;
localparam WDATA_OFFSET = WID_OFFSET - C_AXI_DATA_WIDTH;
localparam WSTRB_OFFSET = WDATA_OFFSET - C_AXI_DATA_WIDTH/8;
localparam WUSER_OFFSET = C_HAS_AXI_WUSER == 1 ? WSTRB_OFFSET-C_AXI_WUSER_WIDTH : WSTRB_OFFSET;
localparam BID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WRCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WRCH;
localparam BRESP_OFFSET = BID_OFFSET - C_AXI_BRESP_WIDTH;
localparam BUSER_OFFSET = C_HAS_AXI_BUSER == 1 ? BRESP_OFFSET-C_AXI_BUSER_WIDTH : BRESP_OFFSET;
wire [C_DIN_WIDTH_WACH-1:0] wach_din ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout_pkt ;
wire wach_full ;
wire wach_almost_full ;
wire wach_prog_full ;
wire wach_empty ;
wire wach_almost_empty ;
wire wach_prog_empty ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_din ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_dout ;
wire wdch_full ;
wire wdch_almost_full ;
wire wdch_prog_full ;
wire wdch_empty ;
wire wdch_almost_empty ;
wire wdch_prog_empty ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_din ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_dout ;
wire wrch_full ;
wire wrch_almost_full ;
wire wrch_prog_full ;
wire wrch_empty ;
wire wrch_almost_empty ;
wire wrch_prog_empty ;
wire axi_aw_underflow_i;
wire axi_w_underflow_i ;
wire axi_b_underflow_i ;
wire axi_aw_overflow_i ;
wire axi_w_overflow_i ;
wire axi_b_overflow_i ;
wire axi_wr_underflow_i;
wire axi_wr_overflow_i ;
wire wach_s_axi_awready;
wire wach_m_axi_awvalid;
wire wach_wr_en ;
wire wach_rd_en ;
wire wdch_s_axi_wready ;
wire wdch_m_axi_wvalid ;
wire wdch_wr_en ;
wire wdch_rd_en ;
wire wrch_s_axi_bvalid ;
wire wrch_m_axi_bready ;
wire wrch_wr_en ;
wire wrch_rd_en ;
wire txn_count_up ;
wire txn_count_down ;
wire awvalid_en ;
wire awvalid_pkt ;
wire awready_pkt ;
integer wr_pkt_count ;
wire wach_we ;
wire wach_re ;
wire wdch_we ;
wire wdch_re ;
wire wrch_we ;
wire wrch_re ;
generate if (IS_WR_ADDR_CH == 1) begin : axi_write_address_channel
// Write protection when almost full or prog_full is high
assign wach_we = (C_PROG_FULL_TYPE_WACH != 0) ? wach_s_axi_awready & S_AXI_AWVALID : S_AXI_AWVALID;
// Read protection when almost empty or prog_empty is high
assign wach_re = (C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH == 1) ?
wach_m_axi_awvalid & awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY && wach_m_axi_awvalid :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH == 1) ?
awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY : 1'b0;
assign wach_wr_en = (C_HAS_SLAVE_CE == 1) ? wach_we & S_ACLK_EN : wach_we;
assign wach_rd_en = (C_HAS_MASTER_CE == 1) ? wach_re & M_ACLK_EN : wach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WACH == 2 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WACH == 11 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_DEPTH (C_WR_DEPTH_WACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WACH),
.C_RD_DEPTH (C_WR_DEPTH_WACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH),
.C_USE_ECC (C_USE_ECC_WACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_WACH == 1)?0:C_APPLICATION_TYPE_WACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 : 0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wach_wr_en),
.RD_EN (wach_rd_en),
.PROG_FULL_THRESH (AXI_AW_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AW_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.INJECTDBITERR (AXI_AW_INJECTDBITERR),
.INJECTSBITERR (AXI_AW_INJECTSBITERR),
.DIN (wach_din),
.DOUT (wach_dout_pkt),
.FULL (wach_full),
.EMPTY (wach_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_AW_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_AW_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_aw_overflow_i),
.VALID (),
.UNDERFLOW (axi_aw_underflow_i),
.DATA_COUNT (AXI_AW_DATA_COUNT),
.RD_DATA_COUNT (AXI_AW_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AW_WR_DATA_COUNT),
.SBITERR (AXI_AW_SBITERR),
.DBITERR (AXI_AW_DBITERR),
.wr_rst_busy (wr_rst_busy_wach),
.rd_rst_busy (rd_rst_busy_wach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wach_s_axi_awready = (IS_8SERIES == 0) ? ~wach_full : (C_IMPLEMENTATION_TYPE_WACH == 5 || C_IMPLEMENTATION_TYPE_WACH == 13) ? ~(wach_full | wr_rst_busy_wach) : ~wach_full;
assign wach_m_axi_awvalid = ~wach_empty;
assign S_AXI_AWREADY = wach_s_axi_awready;
assign AXI_AW_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_aw_underflow_i : 0;
assign AXI_AW_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_aw_overflow_i : 0;
end endgenerate // axi_write_address_channel
// Register Slice for Write Address Channel
generate if (C_WACH_TYPE == 1) begin : gwach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WACH)
)
wach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wach_din),
.S_VALID (S_AXI_AWVALID),
.S_READY (S_AXI_AWREADY),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
end endgenerate // gwach_reg_slice
generate if (C_APPLICATION_TYPE_WACH == 1 && C_HAS_AXI_WR_CHANNEL == 1) begin : axi_mm_pkt_fifo_wr
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (1)
)
wach_pkt_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (wach_dout_pkt),
.S_VALID (awvalid_pkt),
.S_READY (awready_pkt),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
assign awvalid_pkt = wach_m_axi_awvalid && awvalid_en;
assign txn_count_up = wdch_s_axi_wready && wdch_wr_en && wdch_din[0];
assign txn_count_down = wach_m_axi_awvalid && awready_pkt && awvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset == 1) begin
wr_pkt_count <= 0;
end else begin
if(txn_count_up == 1 && txn_count_down == 0) begin
wr_pkt_count <= wr_pkt_count + 1;
end else if(txn_count_up == 0 && txn_count_down == 1) begin
wr_pkt_count <= wr_pkt_count - 1;
end
end
end //Always end
assign awvalid_en = (wr_pkt_count > 0)?1:0;
end endgenerate
generate if (C_APPLICATION_TYPE_WACH != 1) begin : axi_mm_fifo_wr
assign awvalid_en = 1;
assign wach_dout = wach_dout_pkt;
assign M_AXI_AWVALID = wach_m_axi_awvalid;
end
endgenerate
generate if (IS_WR_DATA_CH == 1) begin : axi_write_data_channel
// Write protection when almost full or prog_full is high
assign wdch_we = (C_PROG_FULL_TYPE_WDCH != 0) ? wdch_s_axi_wready & S_AXI_WVALID : S_AXI_WVALID;
// Read protection when almost empty or prog_empty is high
assign wdch_re = (C_PROG_EMPTY_TYPE_WDCH != 0) ? wdch_m_axi_wvalid & M_AXI_WREADY : M_AXI_WREADY;
assign wdch_wr_en = (C_HAS_SLAVE_CE == 1) ? wdch_we & S_ACLK_EN : wdch_we;
assign wdch_rd_en = (C_HAS_MASTER_CE == 1) ? wdch_re & M_ACLK_EN : wdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WDCH == 2 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WDCH == 11 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WDCH),
.C_WR_DEPTH (C_WR_DEPTH_WDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WDCH),
.C_RD_DEPTH (C_WR_DEPTH_WDCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH),
.C_USE_ECC (C_USE_ECC_WDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wdch_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wdch_wr_en),
.RD_EN (wdch_rd_en),
.PROG_FULL_THRESH (AXI_W_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_W_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.INJECTDBITERR (AXI_W_INJECTDBITERR),
.INJECTSBITERR (AXI_W_INJECTSBITERR),
.DIN (wdch_din),
.DOUT (wdch_dout),
.FULL (wdch_full),
.EMPTY (wdch_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_W_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_W_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_w_overflow_i),
.VALID (),
.UNDERFLOW (axi_w_underflow_i),
.DATA_COUNT (AXI_W_DATA_COUNT),
.RD_DATA_COUNT (AXI_W_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_W_WR_DATA_COUNT),
.SBITERR (AXI_W_SBITERR),
.DBITERR (AXI_W_DBITERR),
.wr_rst_busy (wr_rst_busy_wdch),
.rd_rst_busy (rd_rst_busy_wdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wdch_s_axi_wready = (IS_8SERIES == 0) ? ~wdch_full : (C_IMPLEMENTATION_TYPE_WDCH == 5 || C_IMPLEMENTATION_TYPE_WDCH == 13) ? ~(wdch_full | wr_rst_busy_wdch) : ~wdch_full;
assign wdch_m_axi_wvalid = ~wdch_empty;
assign S_AXI_WREADY = wdch_s_axi_wready;
assign M_AXI_WVALID = wdch_m_axi_wvalid;
assign AXI_W_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_w_underflow_i : 0;
assign AXI_W_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_w_overflow_i : 0;
end endgenerate // axi_write_data_channel
// Register Slice for Write Data Channel
generate if (C_WDCH_TYPE == 1) begin : gwdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WDCH)
)
wdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wdch_din),
.S_VALID (S_AXI_WVALID),
.S_READY (S_AXI_WREADY),
// Master side
.M_PAYLOAD_DATA (wdch_dout),
.M_VALID (M_AXI_WVALID),
.M_READY (M_AXI_WREADY)
);
end endgenerate // gwdch_reg_slice
generate if (IS_WR_RESP_CH == 1) begin : axi_write_resp_channel
// Write protection when almost full or prog_full is high
assign wrch_we = (C_PROG_FULL_TYPE_WRCH != 0) ? wrch_m_axi_bready & M_AXI_BVALID : M_AXI_BVALID;
// Read protection when almost empty or prog_empty is high
assign wrch_re = (C_PROG_EMPTY_TYPE_WRCH != 0) ? wrch_s_axi_bvalid & S_AXI_BREADY : S_AXI_BREADY;
assign wrch_wr_en = (C_HAS_MASTER_CE == 1) ? wrch_we & M_ACLK_EN : wrch_we;
assign wrch_rd_en = (C_HAS_SLAVE_CE == 1) ? wrch_re & S_ACLK_EN : wrch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WRCH == 2 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WRCH == 11 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WRCH),
.C_WR_DEPTH (C_WR_DEPTH_WRCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WRCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_DEPTH (C_WR_DEPTH_WRCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WRCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WRCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WRCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH),
.C_USE_ECC (C_USE_ECC_WRCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WRCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WRCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wrch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wrch_wr_en),
.RD_EN (wrch_rd_en),
.PROG_FULL_THRESH (AXI_B_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_B_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.INJECTDBITERR (AXI_B_INJECTDBITERR),
.INJECTSBITERR (AXI_B_INJECTSBITERR),
.DIN (wrch_din),
.DOUT (wrch_dout),
.FULL (wrch_full),
.EMPTY (wrch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_B_PROG_FULL),
.PROG_EMPTY (AXI_B_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_b_overflow_i),
.VALID (),
.UNDERFLOW (axi_b_underflow_i),
.DATA_COUNT (AXI_B_DATA_COUNT),
.RD_DATA_COUNT (AXI_B_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_B_WR_DATA_COUNT),
.SBITERR (AXI_B_SBITERR),
.DBITERR (AXI_B_DBITERR),
.wr_rst_busy (wr_rst_busy_wrch),
.rd_rst_busy (rd_rst_busy_wrch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wrch_s_axi_bvalid = ~wrch_empty;
assign wrch_m_axi_bready = (IS_8SERIES == 0) ? ~wrch_full : (C_IMPLEMENTATION_TYPE_WRCH == 5 || C_IMPLEMENTATION_TYPE_WRCH == 13) ? ~(wrch_full | wr_rst_busy_wrch) : ~wrch_full;
assign S_AXI_BVALID = wrch_s_axi_bvalid;
assign M_AXI_BREADY = wrch_m_axi_bready;
assign AXI_B_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_b_underflow_i : 0;
assign AXI_B_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_b_overflow_i : 0;
end endgenerate // axi_write_resp_channel
// Register Slice for Write Response Channel
generate if (C_WRCH_TYPE == 1) begin : gwrch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WRCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WRCH)
)
wrch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wrch_din),
.S_VALID (M_AXI_BVALID),
.S_READY (M_AXI_BREADY),
// Master side
.M_PAYLOAD_DATA (wrch_dout),
.M_VALID (S_AXI_BVALID),
.M_READY (S_AXI_BREADY)
);
end endgenerate // gwrch_reg_slice
assign axi_wr_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_aw_underflow_i || axi_w_underflow_i || axi_b_underflow_i) : 0;
assign axi_wr_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_aw_overflow_i || axi_w_overflow_i || axi_b_overflow_i) : 0;
generate if (IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output
assign M_AXI_AWADDR = wach_dout[AWID_OFFSET-1:AWADDR_OFFSET];
assign M_AXI_AWLEN = wach_dout[AWADDR_OFFSET-1:AWLEN_OFFSET];
assign M_AXI_AWSIZE = wach_dout[AWLEN_OFFSET-1:AWSIZE_OFFSET];
assign M_AXI_AWBURST = wach_dout[AWSIZE_OFFSET-1:AWBURST_OFFSET];
assign M_AXI_AWLOCK = wach_dout[AWBURST_OFFSET-1:AWLOCK_OFFSET];
assign M_AXI_AWCACHE = wach_dout[AWLOCK_OFFSET-1:AWCACHE_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWCACHE_OFFSET-1:AWPROT_OFFSET];
assign M_AXI_AWQOS = wach_dout[AWPROT_OFFSET-1:AWQOS_OFFSET];
assign wach_din[AWID_OFFSET-1:AWADDR_OFFSET] = S_AXI_AWADDR;
assign wach_din[AWADDR_OFFSET-1:AWLEN_OFFSET] = S_AXI_AWLEN;
assign wach_din[AWLEN_OFFSET-1:AWSIZE_OFFSET] = S_AXI_AWSIZE;
assign wach_din[AWSIZE_OFFSET-1:AWBURST_OFFSET] = S_AXI_AWBURST;
assign wach_din[AWBURST_OFFSET-1:AWLOCK_OFFSET] = S_AXI_AWLOCK;
assign wach_din[AWLOCK_OFFSET-1:AWCACHE_OFFSET] = S_AXI_AWCACHE;
assign wach_din[AWCACHE_OFFSET-1:AWPROT_OFFSET] = S_AXI_AWPROT;
assign wach_din[AWPROT_OFFSET-1:AWQOS_OFFSET] = S_AXI_AWQOS;
end endgenerate // axi_wach_output
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_awregion
assign M_AXI_AWREGION = wach_dout[AWQOS_OFFSET-1:AWREGION_OFFSET];
end endgenerate // axi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_awregion
assign M_AXI_AWREGION = 0;
end endgenerate // naxi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : axi_awuser
assign M_AXI_AWUSER = wach_dout[AWREGION_OFFSET-1:AWUSER_OFFSET];
end endgenerate // axi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 0) begin : naxi_awuser
assign M_AXI_AWUSER = 0;
end endgenerate // naxi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_awid
assign M_AXI_AWID = wach_dout[C_DIN_WIDTH_WACH-1:AWID_OFFSET];
end endgenerate //axi_awid
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_awid
assign M_AXI_AWID = 0;
end endgenerate //naxi_awid
generate if (IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output
assign M_AXI_WDATA = wdch_dout[WID_OFFSET-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
assign M_AXI_WLAST = wdch_dout[0];
assign wdch_din[WID_OFFSET-1:WDATA_OFFSET] = S_AXI_WDATA;
assign wdch_din[WDATA_OFFSET-1:WSTRB_OFFSET] = S_AXI_WSTRB;
assign wdch_din[0] = S_AXI_WLAST;
end endgenerate // axi_wdch_output
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin
assign M_AXI_WID = wdch_dout[C_DIN_WIDTH_WDCH-1:WID_OFFSET];
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && (C_HAS_AXI_ID == 0 || C_AXI_TYPE != 3)) begin
assign M_AXI_WID = 0;
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1 ) begin
assign M_AXI_WUSER = wdch_dout[WSTRB_OFFSET-1:WUSER_OFFSET];
end endgenerate
generate if (C_HAS_AXI_WUSER == 0) begin
assign M_AXI_WUSER = 0;
end endgenerate
generate if (IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output
assign S_AXI_BRESP = wrch_dout[BID_OFFSET-1:BRESP_OFFSET];
assign wrch_din[BID_OFFSET-1:BRESP_OFFSET] = M_AXI_BRESP;
end endgenerate // axi_wrch_output
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : axi_buser
assign S_AXI_BUSER = wrch_dout[BRESP_OFFSET-1:BUSER_OFFSET];
end endgenerate // axi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 0) begin : naxi_buser
assign S_AXI_BUSER = 0;
end endgenerate // naxi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_bid
assign S_AXI_BID = wrch_dout[C_DIN_WIDTH_WRCH-1:BID_OFFSET];
end endgenerate // axi_bid
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_bid
assign S_AXI_BID = 0 ;
end endgenerate // naxi_bid
generate if (IS_AXI_LITE_WACH == 1 || (IS_AXI_LITE == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output1
assign wach_din = {S_AXI_AWADDR, S_AXI_AWPROT};
assign M_AXI_AWADDR = wach_dout[C_DIN_WIDTH_WACH-1:AWADDR_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWADDR_OFFSET-1:AWPROT_OFFSET];
end endgenerate // axi_wach_output1
generate if (IS_AXI_LITE_WDCH == 1 || (IS_AXI_LITE == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output1
assign wdch_din = {S_AXI_WDATA, S_AXI_WSTRB};
assign M_AXI_WDATA = wdch_dout[C_DIN_WIDTH_WDCH-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
end endgenerate // axi_wdch_output1
generate if (IS_AXI_LITE_WRCH == 1 || (IS_AXI_LITE == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output1
assign wrch_din = M_AXI_BRESP;
assign S_AXI_BRESP = wrch_dout[C_DIN_WIDTH_WRCH-1:BRESP_OFFSET];
end endgenerate // axi_wrch_output1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : gwach_din1
assign wach_din[AWREGION_OFFSET-1:AWUSER_OFFSET] = S_AXI_AWUSER;
end endgenerate // gwach_din1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwach_din2
assign wach_din[C_DIN_WIDTH_WACH-1:AWID_OFFSET] = S_AXI_AWID;
end endgenerate // gwach_din2
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : gwach_din3
assign wach_din[AWQOS_OFFSET-1:AWREGION_OFFSET] = S_AXI_AWREGION;
end endgenerate // gwach_din3
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1) begin : gwdch_din1
assign wdch_din[WSTRB_OFFSET-1:WUSER_OFFSET] = S_AXI_WUSER;
end endgenerate // gwdch_din1
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin : gwdch_din2
assign wdch_din[C_DIN_WIDTH_WDCH-1:WID_OFFSET] = S_AXI_WID;
end endgenerate // gwdch_din2
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : gwrch_din1
assign wrch_din[BRESP_OFFSET-1:BUSER_OFFSET] = M_AXI_BUSER;
end endgenerate // gwrch_din1
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwrch_din2
assign wrch_din[C_DIN_WIDTH_WRCH-1:BID_OFFSET] = M_AXI_BID;
end endgenerate // gwrch_din2
//end of axi_write_channel
//###########################################################################
// AXI FULL Read Channel (axi_read_channel)
//###########################################################################
wire [C_DIN_WIDTH_RACH-1:0] rach_din ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout_pkt ;
wire rach_full ;
wire rach_almost_full ;
wire rach_prog_full ;
wire rach_empty ;
wire rach_almost_empty ;
wire rach_prog_empty ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_din ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_dout ;
wire rdch_full ;
wire rdch_almost_full ;
wire rdch_prog_full ;
wire rdch_empty ;
wire rdch_almost_empty ;
wire rdch_prog_empty ;
wire axi_ar_underflow_i ;
wire axi_r_underflow_i ;
wire axi_ar_overflow_i ;
wire axi_r_overflow_i ;
wire axi_rd_underflow_i ;
wire axi_rd_overflow_i ;
wire rach_s_axi_arready ;
wire rach_m_axi_arvalid ;
wire rach_wr_en ;
wire rach_rd_en ;
wire rdch_m_axi_rready ;
wire rdch_s_axi_rvalid ;
wire rdch_wr_en ;
wire rdch_rd_en ;
wire arvalid_pkt ;
wire arready_pkt ;
wire arvalid_en ;
wire rdch_rd_ok ;
wire accept_next_pkt ;
integer rdch_free_space ;
integer rdch_commited_space ;
wire rach_we ;
wire rach_re ;
wire rdch_we ;
wire rdch_re ;
localparam ARID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RACH;
localparam ARADDR_OFFSET = ARID_OFFSET - C_AXI_ADDR_WIDTH;
localparam ARLEN_OFFSET = C_AXI_TYPE != 2 ? ARADDR_OFFSET - C_AXI_LEN_WIDTH : ARADDR_OFFSET;
localparam ARSIZE_OFFSET = C_AXI_TYPE != 2 ? ARLEN_OFFSET - C_AXI_SIZE_WIDTH : ARLEN_OFFSET;
localparam ARBURST_OFFSET = C_AXI_TYPE != 2 ? ARSIZE_OFFSET - C_AXI_BURST_WIDTH : ARSIZE_OFFSET;
localparam ARLOCK_OFFSET = C_AXI_TYPE != 2 ? ARBURST_OFFSET - C_AXI_LOCK_WIDTH : ARBURST_OFFSET;
localparam ARCACHE_OFFSET = C_AXI_TYPE != 2 ? ARLOCK_OFFSET - C_AXI_CACHE_WIDTH : ARLOCK_OFFSET;
localparam ARPROT_OFFSET = ARCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam ARQOS_OFFSET = ARPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam ARREGION_OFFSET = C_AXI_TYPE == 1 ? ARQOS_OFFSET - C_AXI_REGION_WIDTH : ARQOS_OFFSET;
localparam ARUSER_OFFSET = C_HAS_AXI_ARUSER == 1 ? ARREGION_OFFSET-C_AXI_ARUSER_WIDTH : ARREGION_OFFSET;
localparam RID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RDCH;
localparam RDATA_OFFSET = RID_OFFSET - C_AXI_DATA_WIDTH;
localparam RRESP_OFFSET = RDATA_OFFSET - C_AXI_RRESP_WIDTH;
localparam RUSER_OFFSET = C_HAS_AXI_RUSER == 1 ? RRESP_OFFSET-C_AXI_RUSER_WIDTH : RRESP_OFFSET;
generate if (IS_RD_ADDR_CH == 1) begin : axi_read_addr_channel
// Write protection when almost full or prog_full is high
assign rach_we = (C_PROG_FULL_TYPE_RACH != 0) ? rach_s_axi_arready & S_AXI_ARVALID : S_AXI_ARVALID;
// Read protection when almost empty or prog_empty is high
// assign rach_rd_en = (C_PROG_EMPTY_TYPE_RACH != 5) ? rach_m_axi_arvalid & M_AXI_ARREADY : M_AXI_ARREADY && arvalid_en;
assign rach_re = (C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH == 1) ?
rach_m_axi_arvalid & arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY && rach_m_axi_arvalid :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH == 1) ?
arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY : 1'b0;
assign rach_wr_en = (C_HAS_SLAVE_CE == 1) ? rach_we & S_ACLK_EN : rach_we;
assign rach_rd_en = (C_HAS_MASTER_CE == 1) ? rach_re & M_ACLK_EN : rach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RACH == 2 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RACH == 11 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RACH),
.C_WR_DEPTH (C_WR_DEPTH_RACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_DOUT_WIDTH (C_DIN_WIDTH_RACH),
.C_RD_DEPTH (C_WR_DEPTH_RACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH),
.C_USE_ECC (C_USE_ECC_RACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_RACH == 1)?0:C_APPLICATION_TYPE_RACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rach_wr_en),
.RD_EN (rach_rd_en),
.PROG_FULL_THRESH (AXI_AR_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AR_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.INJECTDBITERR (AXI_AR_INJECTDBITERR),
.INJECTSBITERR (AXI_AR_INJECTSBITERR),
.DIN (rach_din),
.DOUT (rach_dout_pkt),
.FULL (rach_full),
.EMPTY (rach_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_AR_PROG_FULL),
.PROG_EMPTY (AXI_AR_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_ar_overflow_i),
.VALID (),
.UNDERFLOW (axi_ar_underflow_i),
.DATA_COUNT (AXI_AR_DATA_COUNT),
.RD_DATA_COUNT (AXI_AR_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AR_WR_DATA_COUNT),
.SBITERR (AXI_AR_SBITERR),
.DBITERR (AXI_AR_DBITERR),
.wr_rst_busy (wr_rst_busy_rach),
.rd_rst_busy (rd_rst_busy_rach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rach_s_axi_arready = (IS_8SERIES == 0) ? ~rach_full : (C_IMPLEMENTATION_TYPE_RACH == 5 || C_IMPLEMENTATION_TYPE_RACH == 13) ? ~(rach_full | wr_rst_busy_rach) : ~rach_full;
assign rach_m_axi_arvalid = ~rach_empty;
assign S_AXI_ARREADY = rach_s_axi_arready;
assign AXI_AR_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_ar_underflow_i : 0;
assign AXI_AR_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_ar_overflow_i : 0;
end endgenerate // axi_read_addr_channel
// Register Slice for Read Address Channel
generate if (C_RACH_TYPE == 1) begin : grach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RACH)
)
rach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rach_din),
.S_VALID (S_AXI_ARVALID),
.S_READY (S_AXI_ARREADY),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice
// Register Slice for Read Address Channel for MM Packet FIFO
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH == 1) begin : grach_reg_slice_mm_pkt_fifo
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (1)
)
reg_slice_mm_pkt_fifo_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (rach_dout_pkt),
.S_VALID (arvalid_pkt),
.S_READY (arready_pkt),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice_mm_pkt_fifo
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH != 1) begin : grach_m_axi_arvalid
assign M_AXI_ARVALID = rach_m_axi_arvalid;
assign rach_dout = rach_dout_pkt;
end endgenerate // grach_m_axi_arvalid
generate if (C_APPLICATION_TYPE_RACH == 1 && C_HAS_AXI_RD_CHANNEL == 1) begin : axi_mm_pkt_fifo_rd
assign rdch_rd_ok = rdch_s_axi_rvalid && rdch_rd_en;
assign arvalid_pkt = rach_m_axi_arvalid && arvalid_en;
assign accept_next_pkt = rach_m_axi_arvalid && arready_pkt && arvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset) begin
rdch_commited_space <= 0;
end else begin
if(rdch_rd_ok && !accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space-1;
end else if(!rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1);
end else if(rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]);
end
end
end //Always end
always@(*) begin
rdch_free_space <= (C_WR_DEPTH_RDCH-(rdch_commited_space+rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1));
end
assign arvalid_en = (rdch_free_space >= 0)?1:0;
end
endgenerate
generate if (C_APPLICATION_TYPE_RACH != 1) begin : axi_mm_fifo_rd
assign arvalid_en = 1;
end
endgenerate
generate if (IS_RD_DATA_CH == 1) begin : axi_read_data_channel
// Write protection when almost full or prog_full is high
assign rdch_we = (C_PROG_FULL_TYPE_RDCH != 0) ? rdch_m_axi_rready & M_AXI_RVALID : M_AXI_RVALID;
// Read protection when almost empty or prog_empty is high
assign rdch_re = (C_PROG_EMPTY_TYPE_RDCH != 0) ? rdch_s_axi_rvalid & S_AXI_RREADY : S_AXI_RREADY;
assign rdch_wr_en = (C_HAS_MASTER_CE == 1) ? rdch_we & M_ACLK_EN : rdch_we;
assign rdch_rd_en = (C_HAS_SLAVE_CE == 1) ? rdch_re & S_ACLK_EN : rdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RDCH == 2 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RDCH == 11 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RDCH),
.C_WR_DEPTH (C_WR_DEPTH_RDCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_RDCH),
.C_RD_DEPTH (C_WR_DEPTH_RDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH),
.C_USE_ECC (C_USE_ECC_RDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_RDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rdch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rdch_wr_en),
.RD_EN (rdch_rd_en),
.PROG_FULL_THRESH (AXI_R_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_R_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.INJECTDBITERR (AXI_R_INJECTDBITERR),
.INJECTSBITERR (AXI_R_INJECTSBITERR),
.DIN (rdch_din),
.DOUT (rdch_dout),
.FULL (rdch_full),
.EMPTY (rdch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_R_PROG_FULL),
.PROG_EMPTY (AXI_R_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_r_overflow_i),
.VALID (),
.UNDERFLOW (axi_r_underflow_i),
.DATA_COUNT (AXI_R_DATA_COUNT),
.RD_DATA_COUNT (AXI_R_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_R_WR_DATA_COUNT),
.SBITERR (AXI_R_SBITERR),
.DBITERR (AXI_R_DBITERR),
.wr_rst_busy (wr_rst_busy_rdch),
.rd_rst_busy (rd_rst_busy_rdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rdch_s_axi_rvalid = ~rdch_empty;
assign rdch_m_axi_rready = (IS_8SERIES == 0) ? ~rdch_full : (C_IMPLEMENTATION_TYPE_RDCH == 5 || C_IMPLEMENTATION_TYPE_RDCH == 13) ? ~(rdch_full | wr_rst_busy_rdch) : ~rdch_full;
assign S_AXI_RVALID = rdch_s_axi_rvalid;
assign M_AXI_RREADY = rdch_m_axi_rready;
assign AXI_R_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_r_underflow_i : 0;
assign AXI_R_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_r_overflow_i : 0;
end endgenerate //axi_read_data_channel
// Register Slice for read Data Channel
generate if (C_RDCH_TYPE == 1) begin : grdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RDCH)
)
rdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rdch_din),
.S_VALID (M_AXI_RVALID),
.S_READY (M_AXI_RREADY),
// Master side
.M_PAYLOAD_DATA (rdch_dout),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY)
);
end endgenerate // grdch_reg_slice
assign axi_rd_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_ar_underflow_i || axi_r_underflow_i) : 0;
assign axi_rd_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_ar_overflow_i || axi_r_overflow_i) : 0;
generate if (IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) begin : axi_full_rach_output
assign M_AXI_ARADDR = rach_dout[ARID_OFFSET-1:ARADDR_OFFSET];
assign M_AXI_ARLEN = rach_dout[ARADDR_OFFSET-1:ARLEN_OFFSET];
assign M_AXI_ARSIZE = rach_dout[ARLEN_OFFSET-1:ARSIZE_OFFSET];
assign M_AXI_ARBURST = rach_dout[ARSIZE_OFFSET-1:ARBURST_OFFSET];
assign M_AXI_ARLOCK = rach_dout[ARBURST_OFFSET-1:ARLOCK_OFFSET];
assign M_AXI_ARCACHE = rach_dout[ARLOCK_OFFSET-1:ARCACHE_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARCACHE_OFFSET-1:ARPROT_OFFSET];
assign M_AXI_ARQOS = rach_dout[ARPROT_OFFSET-1:ARQOS_OFFSET];
assign rach_din[ARID_OFFSET-1:ARADDR_OFFSET] = S_AXI_ARADDR;
assign rach_din[ARADDR_OFFSET-1:ARLEN_OFFSET] = S_AXI_ARLEN;
assign rach_din[ARLEN_OFFSET-1:ARSIZE_OFFSET] = S_AXI_ARSIZE;
assign rach_din[ARSIZE_OFFSET-1:ARBURST_OFFSET] = S_AXI_ARBURST;
assign rach_din[ARBURST_OFFSET-1:ARLOCK_OFFSET] = S_AXI_ARLOCK;
assign rach_din[ARLOCK_OFFSET-1:ARCACHE_OFFSET] = S_AXI_ARCACHE;
assign rach_din[ARCACHE_OFFSET-1:ARPROT_OFFSET] = S_AXI_ARPROT;
assign rach_din[ARPROT_OFFSET-1:ARQOS_OFFSET] = S_AXI_ARQOS;
end endgenerate // axi_full_rach_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_arregion
assign M_AXI_ARREGION = rach_dout[ARQOS_OFFSET-1:ARREGION_OFFSET];
end endgenerate // axi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_arregion
assign M_AXI_ARREGION = 0;
end endgenerate // naxi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : axi_aruser
assign M_AXI_ARUSER = rach_dout[ARREGION_OFFSET-1:ARUSER_OFFSET];
end endgenerate // axi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 0) begin : naxi_aruser
assign M_AXI_ARUSER = 0;
end endgenerate // naxi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_arid
assign M_AXI_ARID = rach_dout[C_DIN_WIDTH_RACH-1:ARID_OFFSET];
end endgenerate // axi_arid
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_arid
assign M_AXI_ARID = 0;
end endgenerate // naxi_arid
generate if (IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) begin : axi_full_rdch_output
assign S_AXI_RDATA = rdch_dout[RID_OFFSET-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
assign S_AXI_RLAST = rdch_dout[0];
assign rdch_din[RID_OFFSET-1:RDATA_OFFSET] = M_AXI_RDATA;
assign rdch_din[RDATA_OFFSET-1:RRESP_OFFSET] = M_AXI_RRESP;
assign rdch_din[0] = M_AXI_RLAST;
end endgenerate // axi_full_rdch_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : axi_full_ruser_output
assign S_AXI_RUSER = rdch_dout[RRESP_OFFSET-1:RUSER_OFFSET];
end endgenerate // axi_full_ruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 0) begin : axi_full_nruser_output
assign S_AXI_RUSER = 0;
end endgenerate // axi_full_nruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_rid
assign S_AXI_RID = rdch_dout[C_DIN_WIDTH_RDCH-1:RID_OFFSET];
end endgenerate // axi_rid
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_rid
assign S_AXI_RID = 0;
end endgenerate // naxi_rid
generate if (IS_AXI_LITE_RACH == 1 || (IS_AXI_LITE == 1 && C_RACH_TYPE == 1)) begin : axi_lite_rach_output1
assign rach_din = {S_AXI_ARADDR, S_AXI_ARPROT};
assign M_AXI_ARADDR = rach_dout[C_DIN_WIDTH_RACH-1:ARADDR_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARADDR_OFFSET-1:ARPROT_OFFSET];
end endgenerate // axi_lite_rach_output
generate if (IS_AXI_LITE_RDCH == 1 || (IS_AXI_LITE == 1 && C_RDCH_TYPE == 1)) begin : axi_lite_rdch_output1
assign rdch_din = {M_AXI_RDATA, M_AXI_RRESP};
assign S_AXI_RDATA = rdch_dout[C_DIN_WIDTH_RDCH-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
end endgenerate // axi_lite_rdch_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : grach_din1
assign rach_din[ARREGION_OFFSET-1:ARUSER_OFFSET] = S_AXI_ARUSER;
end endgenerate // grach_din1
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grach_din2
assign rach_din[C_DIN_WIDTH_RACH-1:ARID_OFFSET] = S_AXI_ARID;
end endgenerate // grach_din2
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin
assign rach_din[ARQOS_OFFSET-1:ARREGION_OFFSET] = S_AXI_ARREGION;
end endgenerate
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : grdch_din1
assign rdch_din[RRESP_OFFSET-1:RUSER_OFFSET] = M_AXI_RUSER;
end endgenerate // grdch_din1
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grdch_din2
assign rdch_din[C_DIN_WIDTH_RDCH-1:RID_OFFSET] = M_AXI_RID;
end endgenerate // grdch_din2
//end of axi_read_channel
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_UNDERFLOW == 1) begin : gaxi_comm_uf
assign UNDERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_underflow_i || axi_rd_underflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_underflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_underflow_i : 0;
end endgenerate // gaxi_comm_uf
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_OVERFLOW == 1) begin : gaxi_comm_of
assign OVERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_overflow_i || axi_rd_overflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_overflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_overflow_i : 0;
end endgenerate // gaxi_comm_of
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic or Wiring Logic
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Write Address Channel
generate if (C_WACH_TYPE == 2) begin : gwach_pass_through
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWQOS = S_AXI_AWQOS;
assign M_AXI_AWREGION = S_AXI_AWREGION;
assign M_AXI_AWUSER = S_AXI_AWUSER;
assign S_AXI_AWREADY = M_AXI_AWREADY;
assign M_AXI_AWVALID = S_AXI_AWVALID;
end endgenerate // gwach_pass_through;
// Wiring logic for Write Data Channel
generate if (C_WDCH_TYPE == 2) begin : gwdch_pass_through
assign M_AXI_WID = S_AXI_WID;
assign M_AXI_WDATA = S_AXI_WDATA;
assign M_AXI_WSTRB = S_AXI_WSTRB;
assign M_AXI_WLAST = S_AXI_WLAST;
assign M_AXI_WUSER = S_AXI_WUSER;
assign S_AXI_WREADY = M_AXI_WREADY;
assign M_AXI_WVALID = S_AXI_WVALID;
end endgenerate // gwdch_pass_through;
// Wiring logic for Write Response Channel
generate if (C_WRCH_TYPE == 2) begin : gwrch_pass_through
assign S_AXI_BID = M_AXI_BID;
assign S_AXI_BRESP = M_AXI_BRESP;
assign S_AXI_BUSER = M_AXI_BUSER;
assign M_AXI_BREADY = S_AXI_BREADY;
assign S_AXI_BVALID = M_AXI_BVALID;
end endgenerate // gwrch_pass_through;
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Read Address Channel
generate if (C_RACH_TYPE == 2) begin : grach_pass_through
assign M_AXI_ARID = S_AXI_ARID;
assign M_AXI_ARADDR = S_AXI_ARADDR;
assign M_AXI_ARLEN = S_AXI_ARLEN;
assign M_AXI_ARSIZE = S_AXI_ARSIZE;
assign M_AXI_ARBURST = S_AXI_ARBURST;
assign M_AXI_ARLOCK = S_AXI_ARLOCK;
assign M_AXI_ARCACHE = S_AXI_ARCACHE;
assign M_AXI_ARPROT = S_AXI_ARPROT;
assign M_AXI_ARQOS = S_AXI_ARQOS;
assign M_AXI_ARREGION = S_AXI_ARREGION;
assign M_AXI_ARUSER = S_AXI_ARUSER;
assign S_AXI_ARREADY = M_AXI_ARREADY;
assign M_AXI_ARVALID = S_AXI_ARVALID;
end endgenerate // grach_pass_through;
// Wiring logic for Read Data Channel
generate if (C_RDCH_TYPE == 2) begin : grdch_pass_through
assign S_AXI_RID = M_AXI_RID;
assign S_AXI_RLAST = M_AXI_RLAST;
assign S_AXI_RUSER = M_AXI_RUSER;
assign S_AXI_RDATA = M_AXI_RDATA;
assign S_AXI_RRESP = M_AXI_RRESP;
assign S_AXI_RVALID = M_AXI_RVALID;
assign M_AXI_RREADY = S_AXI_RREADY;
end endgenerate // grdch_pass_through;
// Wiring logic for AXI Streaming
generate if (C_AXIS_TYPE == 2) begin : gaxis_pass_through
assign M_AXIS_TDATA = S_AXIS_TDATA;
assign M_AXIS_TSTRB = S_AXIS_TSTRB;
assign M_AXIS_TKEEP = S_AXIS_TKEEP;
assign M_AXIS_TID = S_AXIS_TID;
assign M_AXIS_TDEST = S_AXIS_TDEST;
assign M_AXIS_TUSER = S_AXIS_TUSER;
assign M_AXIS_TLAST = S_AXIS_TLAST;
assign S_AXIS_TREADY = M_AXIS_TREADY;
assign M_AXIS_TVALID = S_AXIS_TVALID;
end endgenerate // gaxis_pass_through;
endmodule //fifo_generator_v13_1_3
/*******************************************************************************
* Declaration of top-level module for Conventional FIFO
******************************************************************************/
module fifo_generator_v13_1_3_CONV_VER
#(
parameter C_COMMON_CLOCK = 0,
parameter C_INTERFACE_TYPE = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "virtex7", //Not allowed in Verilog model
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
parameter C_AXI_TYPE = 0
)
(
input BACKUP,
input BACKUP_MARKER,
input CLK,
input RST,
input SRST,
input WR_CLK,
input WR_RST,
input RD_CLK,
input RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input WR_EN,
input RD_EN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input INT_CLK,
input INJECTDBITERR,
input INJECTSBITERR,
output [C_DOUT_WIDTH-1:0] DOUT,
output FULL,
output ALMOST_FULL,
output WR_ACK,
output OVERFLOW,
output EMPTY,
output ALMOST_EMPTY,
output VALID,
output UNDERFLOW,
output [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_FULL,
output PROG_EMPTY,
output SBITERR,
output DBITERR,
output wr_rst_busy_o,
output wr_rst_busy,
output rd_rst_busy,
output wr_rst_i_out,
output rd_rst_i_out
);
/*
******************************************************************************
* Definition of Parameters
******************************************************************************
* C_COMMON_CLOCK : Common Clock (1), Independent Clocks (0)
* C_COUNT_TYPE : *not used
* C_DATA_COUNT_WIDTH : Width of DATA_COUNT bus
* C_DEFAULT_VALUE : *not used
* C_DIN_WIDTH : Width of DIN bus
* C_DOUT_RST_VAL : Reset value of DOUT
* C_DOUT_WIDTH : Width of DOUT bus
* C_ENABLE_RLOCS : *not used
* C_FAMILY : not used in bhv model
* C_FULL_FLAGS_RST_VAL : Full flags rst val (0 or 1)
* C_HAS_ALMOST_EMPTY : 1=Core has ALMOST_EMPTY flag
* C_HAS_ALMOST_FULL : 1=Core has ALMOST_FULL flag
* C_HAS_BACKUP : *not used
* C_HAS_DATA_COUNT : 1=Core has DATA_COUNT bus
* C_HAS_INT_CLK : not used in bhv model
* C_HAS_MEMINIT_FILE : *not used
* C_HAS_OVERFLOW : 1=Core has OVERFLOW flag
* C_HAS_RD_DATA_COUNT : 1=Core has RD_DATA_COUNT bus
* C_HAS_RD_RST : *not used
* C_HAS_RST : 1=Core has Async Rst
* C_HAS_SRST : 1=Core has Sync Rst
* C_HAS_UNDERFLOW : 1=Core has UNDERFLOW flag
* C_HAS_VALID : 1=Core has VALID flag
* C_HAS_WR_ACK : 1=Core has WR_ACK flag
* C_HAS_WR_DATA_COUNT : 1=Core has WR_DATA_COUNT bus
* C_HAS_WR_RST : *not used
* C_IMPLEMENTATION_TYPE : 0=Common-Clock Bram/Dram
* 1=Common-Clock ShiftRam
* 2=Indep. Clocks Bram/Dram
* 3=Virtex-4 Built-in
* 4=Virtex-5 Built-in
* C_INIT_WR_PNTR_VAL : *not used
* C_MEMORY_TYPE : 1=Block RAM
* 2=Distributed RAM
* 3=Shift RAM
* 4=Built-in FIFO
* C_MIF_FILE_NAME : *not used
* C_OPTIMIZATION_MODE : *not used
* C_OVERFLOW_LOW : 1=OVERFLOW active low
* C_PRELOAD_LATENCY : Latency of read: 0, 1, 2
* C_PRELOAD_REGS : 1=Use output registers
* C_PRIM_FIFO_TYPE : not used in bhv model
* C_PROG_EMPTY_THRESH_ASSERT_VAL: PROG_EMPTY assert threshold
* C_PROG_EMPTY_THRESH_NEGATE_VAL: PROG_EMPTY negate threshold
* C_PROG_EMPTY_TYPE : 0=No programmable empty
* 1=Single prog empty thresh constant
* 2=Multiple prog empty thresh constants
* 3=Single prog empty thresh input
* 4=Multiple prog empty thresh inputs
* C_PROG_FULL_THRESH_ASSERT_VAL : PROG_FULL assert threshold
* C_PROG_FULL_THRESH_NEGATE_VAL : PROG_FULL negate threshold
* C_PROG_FULL_TYPE : 0=No prog full
* 1=Single prog full thresh constant
* 2=Multiple prog full thresh constants
* 3=Single prog full thresh input
* 4=Multiple prog full thresh inputs
* C_RD_DATA_COUNT_WIDTH : Width of RD_DATA_COUNT bus
* C_RD_DEPTH : Depth of read interface (2^N)
* C_RD_FREQ : not used in bhv model
* C_RD_PNTR_WIDTH : always log2(C_RD_DEPTH)
* C_UNDERFLOW_LOW : 1=UNDERFLOW active low
* C_USE_DOUT_RST : 1=Resets DOUT on RST
* C_USE_ECC : Used for error injection purpose
* C_USE_EMBEDDED_REG : 1=Use BRAM embedded output register
* C_USE_FIFO16_FLAGS : not used in bhv model
* C_USE_FWFT_DATA_COUNT : 1=Use extra logic for FWFT data count
* C_VALID_LOW : 1=VALID active low
* C_WR_ACK_LOW : 1=WR_ACK active low
* C_WR_DATA_COUNT_WIDTH : Width of WR_DATA_COUNT bus
* C_WR_DEPTH : Depth of write interface (2^N)
* C_WR_FREQ : not used in bhv model
* C_WR_PNTR_WIDTH : always log2(C_WR_DEPTH)
* C_WR_RESPONSE_LATENCY : *not used
* C_MSGON_VAL : *not used by bhv model
* C_ENABLE_RST_SYNC : 0 = Use WR_RST & RD_RST
* 1 = Use RST
* C_ERROR_INJECTION_TYPE : 0 = No error injection
* 1 = Single bit error injection only
* 2 = Double bit error injection only
* 3 = Single and double bit error injection
******************************************************************************
* Definition of Ports
******************************************************************************
* BACKUP : Not used
* BACKUP_MARKER: Not used
* CLK : Clock
* DIN : Input data bus
* PROG_EMPTY_THRESH : Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_ASSERT: Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_NEGATE: Threshold for Programmable Empty Flag
* PROG_FULL_THRESH : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_ASSERT : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_NEGATE : Threshold for Programmable Full Flag
* RD_CLK : Read Domain Clock
* RD_EN : Read enable
* RD_RST : Read Reset
* RST : Asynchronous Reset
* SRST : Synchronous Reset
* WR_CLK : Write Domain Clock
* WR_EN : Write enable
* WR_RST : Write Reset
* INT_CLK : Internal Clock
* INJECTSBITERR: Inject Signle bit error
* INJECTDBITERR: Inject Double bit error
* ALMOST_EMPTY : One word remaining in FIFO
* ALMOST_FULL : One empty space remaining in FIFO
* DATA_COUNT : Number of data words in fifo( synchronous to CLK)
* DOUT : Output data bus
* EMPTY : Empty flag
* FULL : Full flag
* OVERFLOW : Last write rejected
* PROG_EMPTY : Programmable Empty Flag
* PROG_FULL : Programmable Full Flag
* RD_DATA_COUNT: Number of data words in fifo (synchronous to RD_CLK)
* UNDERFLOW : Last read rejected
* VALID : Last read acknowledged, DOUT bus VALID
* WR_ACK : Last write acknowledged
* WR_DATA_COUNT: Number of data words in fifo (synchronous to WR_CLK)
* SBITERR : Single Bit ECC Error Detected
* DBITERR : Double Bit ECC Error Detected
******************************************************************************
*/
//----------------------------------------------------------------------------
//- Internal Signals for delayed input signals
//- All the input signals except Clock are delayed by 100 ps and then given to
//- the models.
//----------------------------------------------------------------------------
reg rst_delayed ;
reg empty_fb ;
reg srst_delayed ;
reg wr_rst_delayed ;
reg rd_rst_delayed ;
reg wr_en_delayed ;
reg rd_en_delayed ;
reg [C_DIN_WIDTH-1:0] din_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate_delayed ;
reg injectdbiterr_delayed ;
reg injectsbiterr_delayed ;
wire empty_p0_out;
always @* rst_delayed <= #`TCQ RST ;
always @* empty_fb <= #`TCQ empty_p0_out ;
always @* srst_delayed <= #`TCQ SRST ;
always @* wr_rst_delayed <= #`TCQ WR_RST ;
always @* rd_rst_delayed <= #`TCQ RD_RST ;
always @* din_delayed <= #`TCQ DIN ;
always @* wr_en_delayed <= #`TCQ WR_EN ;
always @* rd_en_delayed <= #`TCQ RD_EN ;
always @* prog_empty_thresh_delayed <= #`TCQ PROG_EMPTY_THRESH ;
always @* prog_empty_thresh_assert_delayed <= #`TCQ PROG_EMPTY_THRESH_ASSERT ;
always @* prog_empty_thresh_negate_delayed <= #`TCQ PROG_EMPTY_THRESH_NEGATE ;
always @* prog_full_thresh_delayed <= #`TCQ PROG_FULL_THRESH ;
always @* prog_full_thresh_assert_delayed <= #`TCQ PROG_FULL_THRESH_ASSERT ;
always @* prog_full_thresh_negate_delayed <= #`TCQ PROG_FULL_THRESH_NEGATE ;
always @* injectdbiterr_delayed <= #`TCQ INJECTDBITERR ;
always @* injectsbiterr_delayed <= #`TCQ INJECTSBITERR ;
/*****************************************************************************
* Derived parameters
****************************************************************************/
//There are 2 Verilog behavioral models
// 0 = Common-Clock FIFO/ShiftRam FIFO
// 1 = Independent Clocks FIFO
// 2 = Low Latency Synchronous FIFO
// 3 = Low Latency Asynchronous FIFO
localparam C_VERILOG_IMPL = (C_FIFO_TYPE == 3) ? 2 :
(C_IMPLEMENTATION_TYPE == 2) ? 1 : 0;
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//Internal reset signals
reg rd_rst_asreg = 0;
wire rd_rst_asreg_d1;
wire rd_rst_asreg_d2;
reg rd_rst_asreg_d3 = 0;
reg rd_rst_reg = 0;
wire rd_rst_comb;
reg wr_rst_d0 = 0;
reg wr_rst_d1 = 0;
reg wr_rst_d2 = 0;
reg rd_rst_d0 = 0;
reg rd_rst_d1 = 0;
reg rd_rst_d2 = 0;
reg rd_rst_d3 = 0;
reg wrrst_done = 0;
reg rdrst_done = 0;
reg wr_rst_asreg = 0;
wire wr_rst_asreg_d1;
wire wr_rst_asreg_d2;
reg wr_rst_asreg_d3 = 0;
reg rd_rst_wr_d0 = 0;
reg rd_rst_wr_d1 = 0;
reg rd_rst_wr_d2 = 0;
reg wr_rst_reg = 0;
reg rst_active_i = 1'b1;
reg rst_delayed_d1 = 1'b1;
reg rst_delayed_d2 = 1'b1;
wire wr_rst_comb;
wire wr_rst_i;
wire rd_rst_i;
wire rst_i;
//Internal reset signals
reg rst_asreg = 0;
reg srst_asreg = 0;
wire rst_asreg_d1;
wire rst_asreg_d2;
reg srst_asreg_d1 = 0;
reg srst_asreg_d2 = 0;
reg rst_reg = 0;
reg srst_reg = 0;
wire rst_comb;
wire srst_comb;
reg rst_full_gen_i = 0;
reg rst_full_ff_i = 0;
reg [2:0] sckt_ff0_bsy_o_i = {3{1'b0}};
wire RD_CLK_P0_IN;
wire RST_P0_IN;
wire RD_EN_FIFO_IN;
wire RD_EN_P0_IN;
wire ALMOST_EMPTY_FIFO_OUT;
wire ALMOST_FULL_FIFO_OUT;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT_FIFO_OUT;
wire [C_DOUT_WIDTH-1:0] DOUT_FIFO_OUT;
wire EMPTY_FIFO_OUT;
wire fifo_empty_fb;
wire FULL_FIFO_OUT;
wire OVERFLOW_FIFO_OUT;
wire PROG_EMPTY_FIFO_OUT;
wire PROG_FULL_FIFO_OUT;
wire VALID_FIFO_OUT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT_FIFO_OUT;
wire UNDERFLOW_FIFO_OUT;
wire WR_ACK_FIFO_OUT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT_FIFO_OUT;
//***************************************************************************
// Internal Signals
// The core uses either the internal_ wires or the preload0_ wires depending
// on whether the core uses Preload0 or not.
// When using preload0, the internal signals connect the internal core to
// the preload logic, and the external core's interfaces are tied to the
// preload0 signals from the preload logic.
//***************************************************************************
wire [C_DOUT_WIDTH-1:0] DATA_P0_OUT;
wire VALID_P0_OUT;
wire EMPTY_P0_OUT;
wire ALMOSTEMPTY_P0_OUT;
reg EMPTY_P0_OUT_Q;
reg ALMOSTEMPTY_P0_OUT_Q;
wire UNDERFLOW_P0_OUT;
wire RDEN_P0_OUT;
wire [C_DOUT_WIDTH-1:0] DATA_P0_IN;
wire EMPTY_P0_IN;
reg [31:0] DATA_COUNT_FWFT;
reg SS_FWFT_WR ;
reg SS_FWFT_RD ;
wire sbiterr_fifo_out;
wire dbiterr_fifo_out;
wire inject_sbit_err;
wire inject_dbit_err;
wire safety_ckt_wr_rst;
wire safety_ckt_rd_rst;
reg sckt_wr_rst_i_q = 1'b0;
wire w_fab_read_data_valid_i;
wire w_read_data_valid_i;
wire w_ram_valid_i;
// Assign 0 if not selected to avoid 'X' propogation to S/DBITERR.
assign inject_sbit_err = ((C_ERROR_INJECTION_TYPE == 1) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectsbiterr_delayed : 0;
assign inject_dbit_err = ((C_ERROR_INJECTION_TYPE == 2) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectdbiterr_delayed : 0;
assign wr_rst_i_out = wr_rst_i;
assign rd_rst_i_out = rd_rst_i;
assign wr_rst_busy_o = wr_rst_busy | rst_full_gen_i | sckt_ff0_bsy_o_i[2];
generate if (C_FULL_FLAGS_RST_VAL == 0 && C_EN_SAFETY_CKT == 1) begin : gsckt_bsy_o
wire clk_i = C_COMMON_CLOCK ? CLK : WR_CLK;
always @ (posedge clk_i)
sckt_ff0_bsy_o_i <= {sckt_ff0_bsy_o_i[1:0],wr_rst_busy};
end endgenerate
// Choose the behavioral model to instantiate based on the C_VERILOG_IMPL
// parameter (1=Independent Clocks, 0=Common Clock)
localparam FULL_FLAGS_RST_VAL = (C_HAS_SRST == 1) ? 0 : C_FULL_FLAGS_RST_VAL;
generate
case (C_VERILOG_IMPL)
0 : begin : block1
//Common Clock Behavioral Model
fifo_generator_v13_1_3_bhv_ver_ss
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL ((C_AXI_TYPE == 0 && C_FIFO_TYPE == 1) ? 1 : C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ss
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.CLK (CLK),
.RST (rst_i),
.SRST (srst_delayed),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.USER_EMPTY_FB (empty_fb),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.DATA_COUNT (DATA_COUNT_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
1 : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.fab_read_data_valid_i (w_fab_read_data_valid_i),
.read_data_valid_i (w_read_data_valid_i),
.ram_valid_i (w_ram_valid_i),
.DBITERR (dbiterr_fifo_out)
);
end
2 : begin : ll_afifo_inst
fifo_generator_v13_1_3_beh_ver_ll_afifo
#(
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ll_afifo
(
.DIN (din_delayed),
.RD_CLK (RD_CLK),
.RD_EN (rd_en_delayed),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.WR_CLK (WR_CLK),
.WR_EN (wr_en_delayed),
.DOUT (DOUT),
.EMPTY (EMPTY),
.FULL (FULL)
);
end
default : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
endcase
endgenerate
//**************************************************************************
// Connect Internal Signals
// (Signals labeled internal_*)
// In the normal case, these signals tie directly to the FIFO's inputs and
// outputs.
// In the case of Preload Latency 0 or 1, there are intermediate
// signals between the internal FIFO and the preload logic.
//**************************************************************************
//***********************************************
// If First-Word Fall-Through, instantiate
// the preload0 (FWFT) module
//***********************************************
wire rd_en_to_fwft_fifo;
wire sbiterr_fwft;
wire dbiterr_fwft;
wire [C_DOUT_WIDTH-1:0] dout_fwft;
wire empty_fwft;
wire rd_en_fifo_in;
wire stage2_reg_en_i;
wire [1:0] valid_stages_i;
wire rst_fwft;
//wire empty_p0_out;
reg [C_SYNCHRONIZER_STAGE-1:0] pkt_empty_sync = 'b1;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
localparam IS_PKT_FIFO = (C_FIFO_TYPE == 1) ? 1 : 0;
localparam IS_AXIS_PKT_FIFO = (C_FIFO_TYPE == 1 && C_AXI_TYPE == 0) ? 1 : 0;
assign rst_fwft = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 1'b0;
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 3) begin : block2
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
fgpl0
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (RST_P0_IN),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (RD_EN_P0_IN),
.FIFOEMPTY (EMPTY_P0_IN),
.FIFODATA (DATA_P0_IN),
.FIFOSBITERR (sbiterr_fifo_out),
.FIFODBITERR (dbiterr_fifo_out),
// Output
.USERDATA (dout_fwft),
.USERVALID (VALID_P0_OUT),
.USEREMPTY (empty_fwft),
.USERALMOSTEMPTY (ALMOSTEMPTY_P0_OUT),
.USERUNDERFLOW (UNDERFLOW_P0_OUT),
.RAMVALID (),
.FIFORDEN (rd_en_fifo_in),
.USERSBITERR (sbiterr_fwft),
.USERDBITERR (dbiterr_fwft),
.STAGE2_REG_EN (stage2_reg_en_i),
.fab_read_data_valid_i_o (w_fab_read_data_valid_i),
.read_data_valid_i_o (w_read_data_valid_i),
.ram_valid_i_o (w_ram_valid_i),
.VALID_STAGES (valid_stages_i)
);
//***********************************************
// Connect inputs to preload (FWFT) module
//***********************************************
//Connect the RD_CLK of the Preload (FWFT) module to CLK if we
// have a common-clock FIFO, or RD_CLK if we have an
// independent clock FIFO
assign RD_CLK_P0_IN = ((C_VERILOG_IMPL == 0) ? CLK : RD_CLK);
assign RST_P0_IN = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 0;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
assign EMPTY_P0_IN = C_EN_SAFETY_CKT ? fifo_empty_fb : EMPTY_FIFO_OUT;
assign DATA_P0_IN = DOUT_FIFO_OUT;
//***********************************************
// Connect outputs from preload (FWFT) module
//***********************************************
assign VALID = VALID_P0_OUT ;
assign ALMOST_EMPTY = ALMOSTEMPTY_P0_OUT;
assign UNDERFLOW = UNDERFLOW_P0_OUT ;
assign RD_EN_FIFO_IN = rd_en_fifo_in;
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
assign DATA_COUNT = (C_USE_FWFT_DATA_COUNT == 0)? DATA_COUNT_FIFO_OUT:
(C_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) ? DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:0] :
DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH+1];
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
EMPTY_P0_OUT_Q <= 1;
ALMOSTEMPTY_P0_OUT_Q <= 1;
end else begin
EMPTY_P0_OUT_Q <= #`TCQ empty_p0_out;
// EMPTY_P0_OUT_Q <= #`TCQ EMPTY_FIFO_OUT;
ALMOSTEMPTY_P0_OUT_Q <= #`TCQ ALMOSTEMPTY_P0_OUT;
end
end //always
//***********************************************
// logic for common-clock data count when FWFT is selected
//***********************************************
initial begin
SS_FWFT_RD = 1'b0;
DATA_COUNT_FWFT = 0 ;
SS_FWFT_WR = 1'b0 ;
end //initial
//***********************************************
// common-clock data count is implemented as an
// up-down counter. SS_FWFT_WR and SS_FWFT_RD
// are the up/down enables for the counter.
//***********************************************
always @ (RD_EN or VALID_P0_OUT or WR_EN or FULL_FIFO_OUT or empty_p0_out) begin
if (C_VALID_LOW == 1) begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && ~VALID_P0_OUT) : (~empty_p0_out && RD_EN && ~VALID_P0_OUT) ;
end else begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && VALID_P0_OUT) : (~empty_p0_out && RD_EN && VALID_P0_OUT) ;
end
SS_FWFT_WR = (WR_EN && (~FULL_FIFO_OUT)) ;
end
//***********************************************
// common-clock data count is implemented as an
// up-down counter for FWFT. This always block
// calculates the counter.
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
DATA_COUNT_FWFT <= 0;
end else begin
//if (srst_delayed && (C_HAS_SRST == 1) ) begin
if ((srst_delayed | wr_rst_busy | rd_rst_busy) && (C_HAS_SRST == 1) ) begin
DATA_COUNT_FWFT <= #`TCQ 0;
end else begin
case ( {SS_FWFT_WR, SS_FWFT_RD})
2'b00: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
2'b01: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT - 1 ;
2'b10: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT + 1 ;
2'b11: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
endcase
end //if SRST
end //IF RST
end //always
end endgenerate // : block2
// AXI Streaming Packet FIFO
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_plus1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_reg = 0;
reg partial_packet = 0;
reg stage1_eop_d1 = 0;
reg rd_en_fifo_in_d1 = 0;
reg eop_at_stage2 = 0;
reg ram_pkt_empty = 0;
reg ram_pkt_empty_d1 = 0;
wire [C_DOUT_WIDTH-1:0] dout_p0_out;
wire packet_empty_wr;
wire wr_rst_fwft_pkt_fifo;
wire dummy_wr_eop;
wire ram_wr_en_pkt_fifo;
wire wr_eop;
wire ram_rd_en_compare;
wire stage1_eop;
wire pkt_ready_to_read;
wire rd_en_2_stage2;
// Generate Dummy WR_EOP for partial packet (Only for AXI Streaming)
// When Packet EMPTY is high, and FIFO is full, then generate the dummy WR_EOP
// When dummy WR_EOP is high, mask the actual EOP to avoid double increment of
// write packet count
generate if (IS_FWFT == 1 && IS_AXIS_PKT_FIFO == 1) begin // gdummy_wr_eop
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
partial_packet <= 1'b0;
else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy)
partial_packet <= #`TCQ 1'b0;
else if (ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]))
partial_packet <= #`TCQ 1'b1;
else if (partial_packet && din_delayed[0] && ram_wr_en_pkt_fifo)
partial_packet <= #`TCQ 1'b0;
end
end
end endgenerate // gdummy_wr_eop
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1) begin // gpkt_fifo_fwft
assign wr_rst_fwft_pkt_fifo = (C_COMMON_CLOCK == 0) ? wr_rst_i : (C_HAS_RST == 1) ? rst_i:1'b0;
assign dummy_wr_eop = ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]) && (~partial_packet);
assign packet_empty_wr = (C_COMMON_CLOCK == 1) ? empty_p0_out : pkt_empty_sync[C_SYNCHRONIZER_STAGE-1];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
stage1_eop_d1 <= 1'b0;
rd_en_fifo_in_d1 <= 1'b0;
end else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
stage1_eop_d1 <= #`TCQ 1'b0;
rd_en_fifo_in_d1 <= #`TCQ 1'b0;
end else begin
stage1_eop_d1 <= #`TCQ stage1_eop;
rd_en_fifo_in_d1 <= #`TCQ rd_en_fifo_in;
end
end
end
assign stage1_eop = (rd_en_fifo_in_d1) ? DOUT_FIFO_OUT[0] : stage1_eop_d1;
assign ram_wr_en_pkt_fifo = wr_en_delayed && (~FULL_FIFO_OUT);
assign wr_eop = ram_wr_en_pkt_fifo && ((din_delayed[0] && (~partial_packet)) || dummy_wr_eop);
assign ram_rd_en_compare = stage2_reg_en_i && stage1_eop;
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (2) // Enable low latency fwft logic
)
pkt_fifo_fwft
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (rst_fwft),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (rd_en_delayed),
.FIFOEMPTY (pkt_ready_to_read),
.FIFODATA (dout_fwft),
.FIFOSBITERR (sbiterr_fwft),
.FIFODBITERR (dbiterr_fwft),
// Output
.USERDATA (dout_p0_out),
.USERVALID (),
.USEREMPTY (empty_p0_out),
.USERALMOSTEMPTY (),
.USERUNDERFLOW (),
.RAMVALID (),
.FIFORDEN (rd_en_2_stage2),
.USERSBITERR (SBITERR),
.USERDBITERR (DBITERR),
.STAGE2_REG_EN (),
.VALID_STAGES ()
);
assign pkt_ready_to_read = ~(!(ram_pkt_empty || empty_fwft) && ((valid_stages_i[0] && valid_stages_i[1]) || eop_at_stage2));
assign rd_en_to_fwft_fifo = ~empty_fwft && rd_en_2_stage2;
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
eop_at_stage2 <= 1'b0;
else if (stage2_reg_en_i)
eop_at_stage2 <= #`TCQ stage1_eop;
end
//---------------------------------------------------------------------------
// Write and Read Packet Count
//---------------------------------------------------------------------------
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count <= 0;
else if (srst_delayed | wr_rst_busy | rd_rst_busy)
wr_pkt_count <= #`TCQ 0;
else if (wr_eop)
wr_pkt_count <= #`TCQ wr_pkt_count + 1;
end
end endgenerate // gpkt_fifo_fwft
assign DOUT = (C_FIFO_TYPE != 1) ? dout_fwft : dout_p0_out;
assign EMPTY = (C_FIFO_TYPE != 1) ? empty_fwft : empty_p0_out;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 1) begin // grss_pkt_cnt
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
rd_pkt_count <= 0;
rd_pkt_count_plus1 <= 1;
end else if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
rd_pkt_count <= #`TCQ 0;
rd_pkt_count_plus1 <= #`TCQ 1;
end else if (stage2_reg_en_i && stage1_eop) begin
rd_pkt_count <= #`TCQ rd_pkt_count + 1;
rd_pkt_count_plus1 <= #`TCQ rd_pkt_count_plus1 + 1;
end
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (SRST | wr_rst_busy | rd_rst_busy) begin
ram_pkt_empty <= #`TCQ 1'b1;
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count) && wr_eop) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count_plus1 == wr_pkt_count) && ~wr_eop && ~ALMOST_FULL_FIFO_OUT && ram_rd_en_compare) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
end endgenerate //grss_pkt_cnt
localparam SYNC_STAGE_WIDTH = (C_SYNCHRONIZER_STAGE+1)*C_WR_PNTR_WIDTH;
reg [SYNC_STAGE_WIDTH-1:0] wr_pkt_count_q = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_b2g = 0;
wire [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_rd;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 0) begin // gras_pkt_cnt
// Delay the write packet count in write clock domain to accomodate the binary to gray conversion delay
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count_b2g <= 0;
else
wr_pkt_count_b2g <= #`TCQ wr_pkt_count;
end
// Synchronize the delayed write packet count in read domain, and also compensate the gray to binay conversion delay
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
wr_pkt_count_q <= 0;
else
wr_pkt_count_q <= #`TCQ {wr_pkt_count_q[SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH-1:0],wr_pkt_count_b2g};
end
always @* begin
if (stage1_eop)
rd_pkt_count <= rd_pkt_count_reg + 1;
else
rd_pkt_count <= rd_pkt_count_reg;
end
assign wr_pkt_count_rd = wr_pkt_count_q[SYNC_STAGE_WIDTH-1:SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
rd_pkt_count_reg <= 0;
else if (rd_en_fifo_in)
rd_pkt_count_reg <= #`TCQ rd_pkt_count;
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (rd_pkt_count != wr_pkt_count_rd) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count_rd) && stage2_reg_en_i) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
// Synchronize the empty in write domain
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
pkt_empty_sync <= 'b1;
else
pkt_empty_sync <= #`TCQ {pkt_empty_sync[C_SYNCHRONIZER_STAGE-2:0], empty_p0_out};
end
end endgenerate //gras_pkt_cnt
generate if (IS_FWFT == 0 || C_FIFO_TYPE == 3) begin : STD_FIFO
//***********************************************
// If NOT First-Word Fall-Through, wire the outputs
// of the internal _ss or _as FIFO directly to the
// output, and do not instantiate the preload0
// module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VALID = VALID_FIFO_OUT;
assign EMPTY = EMPTY_FIFO_OUT;
assign ALMOST_EMPTY = ALMOST_EMPTY_FIFO_OUT;
assign EMPTY_P0_IN = 0;
assign UNDERFLOW = UNDERFLOW_FIFO_OUT;
assign DATA_COUNT = DATA_COUNT_FIFO_OUT;
assign SBITERR = sbiterr_fifo_out;
assign DBITERR = dbiterr_fifo_out;
end endgenerate // STD_FIFO
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 1) begin : NO_PKT_FIFO
assign empty_p0_out = empty_fwft;
assign SBITERR = sbiterr_fwft;
assign DBITERR = dbiterr_fwft;
assign DOUT = dout_fwft;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
end endgenerate // NO_PKT_FIFO
//***********************************************
// Connect user flags to internal signals
//***********************************************
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//RD_DATA_COUNT is 0 when EMPTY and 1 when ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block3
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : RD_DATA_COUNT_FIFO_OUT);
end //block_ic
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block30
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : RD_DATA_COUNT_FIFO_OUT);
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block30_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : (RD_DATA_COUNT_FIFO_OUT));
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30_both
endgenerate
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block3_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : (RD_DATA_COUNT_FIFO_OUT));
end //block_ic_both
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3_both
endgenerate
//If we are not using extra logic for the FWFT data count,
//then connect RD_DATA_COUNT to the RD_DATA_COUNT from the
//internal FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==0 ) begin : block31
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Always connect WR_DATA_COUNT to the WR_DATA_COUNT from the internal
//FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==1) begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
else begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Connect other flags to the internal FIFO instance
assign FULL = FULL_FIFO_OUT;
assign ALMOST_FULL = ALMOST_FULL_FIFO_OUT;
assign WR_ACK = WR_ACK_FIFO_OUT;
assign OVERFLOW = OVERFLOW_FIFO_OUT;
assign PROG_FULL = PROG_FULL_FIFO_OUT;
assign PROG_EMPTY = PROG_EMPTY_FIFO_OUT;
/**************************************************************************
* find_log2
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// if an asynchronous FIFO has been selected, display a message that the FIFO
// will not be cycle-accurate in simulation
initial begin
if (C_IMPLEMENTATION_TYPE == 2) begin
$display("WARNING: Behavioral models for independent clock FIFO configurations do not model synchronization delays. The behavioral models are functionally correct, and will represent the behavior of the configured FIFO. See the FIFO Generator User Guide for more information.");
end else if (C_MEMORY_TYPE == 4) begin
$display("FAILURE : Behavioral models do not support built-in FIFO configurations. Please use post-synthesis or post-implement simulation in Vivado.");
$finish;
end
if (C_WR_PNTR_WIDTH != find_log2(C_WR_DEPTH)) begin
$display("FAILURE : C_WR_PNTR_WIDTH is not log2 of C_WR_DEPTH.");
$finish;
end
if (C_RD_PNTR_WIDTH != find_log2(C_RD_DEPTH)) begin
$display("FAILURE : C_RD_PNTR_WIDTH is not log2 of C_RD_DEPTH.");
$finish;
end
if (C_USE_ECC == 1) begin
if (C_DIN_WIDTH != C_DOUT_WIDTH) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be equal for ECC configuration.");
$finish;
end
if (C_DIN_WIDTH == 1 && C_ERROR_INJECTION_TYPE > 1) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be > 1 for double bit error injection.");
$finish;
end
end
end //initial
/**************************************************************************
* Internal reset logic
**************************************************************************/
assign wr_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? wr_rst_reg : 0;
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? rd_rst_reg : 0;
assign rst_i = C_HAS_RST ? rst_reg : 0;
wire rst_2_sync;
wire rst_2_sync_safety = (C_ENABLE_RST_SYNC == 1) ? rst_delayed : RD_RST;
wire clk_2_sync = (C_COMMON_CLOCK == 1) ? CLK : WR_CLK;
wire clk_2_sync_safety = (C_COMMON_CLOCK == 1) ? CLK : RD_CLK;
localparam RST_SYNC_STAGES = (C_EN_SAFETY_CKT == 0) ? C_SYNCHRONIZER_STAGE :
(C_COMMON_CLOCK == 1) ? 3 : C_SYNCHRONIZER_STAGE+2;
reg [RST_SYNC_STAGES-1:0] wrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] arst_sync_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_wr = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_ext = {RST_SYNC_STAGES{1'b0}};
reg [1:0] wrst_cc = {2{1'b0}};
reg [1:0] rrst_cc = {2{1'b0}};
generate
if (C_EN_SAFETY_CKT == 1 && C_INTERFACE_TYPE == 0) begin : grst_safety_ckt
reg[1:0] rst_d1_safety =1;
reg[1:0] rst_d2_safety =1;
reg[1:0] rst_d3_safety =1;
reg[1:0] rst_d4_safety =1;
reg[1:0] rst_d5_safety =1;
reg[1:0] rst_d6_safety =1;
reg[1:0] rst_d7_safety =1;
always@(posedge rst_2_sync_safety or posedge clk_2_sync_safety) begin : prst
if (rst_2_sync_safety == 1'b1) begin
rst_d1_safety <= 1'b1;
rst_d2_safety <= 1'b1;
rst_d3_safety <= 1'b1;
rst_d4_safety <= 1'b1;
rst_d5_safety <= 1'b1;
rst_d6_safety <= 1'b1;
rst_d7_safety <= 1'b1;
end
else begin
rst_d1_safety <= #`TCQ 1'b0;
rst_d2_safety <= #`TCQ rst_d1_safety;
rst_d3_safety <= #`TCQ rst_d2_safety;
rst_d4_safety <= #`TCQ rst_d3_safety;
rst_d5_safety <= #`TCQ rst_d4_safety;
rst_d6_safety <= #`TCQ rst_d5_safety;
rst_d7_safety <= #`TCQ rst_d6_safety;
end //if
end //prst
always@(posedge rst_d7_safety or posedge WR_EN) begin : assert_safety
if(rst_d7_safety == 1 && WR_EN == 1) begin
$display("WARNING:A write attempt has been made within the 7 clock cycles of reset de-assertion. This can lead to data discrepancy when safety circuit is enabled.");
end //if
end //always
end // grst_safety_ckt
endgenerate
// if (C_EN_SAFET_CKT == 1)
// assertion:the reset shud be atleast 3 cycles wide.
generate
reg safety_ckt_wr_rst_i = 1'b0;
if (C_ENABLE_RST_SYNC == 0) begin : gnrst_sync
always @* begin
wr_rst_reg <= wr_rst_delayed;
rd_rst_reg <= rd_rst_delayed;
rst_reg <= 1'b0;
srst_reg <= 1'b0;
end
assign rst_2_sync = wr_rst_delayed;
assign wr_rst_busy = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
// end : gnrst_sync
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 0) begin : g7s_ic_rst
reg fifo_wrst_done = 1'b0;
reg fifo_rrst_done = 1'b0;
reg sckt_wrst_i = 1'b0;
reg sckt_wrst_i_q = 1'b0;
reg rd_rst_active = 1'b0;
reg rd_rst_middle = 1'b0;
reg sckt_rd_rst_d1 = 1'b0;
reg [1:0] rst_delayed_ic_w = 2'h0;
wire rst_delayed_ic_w_i;
reg [1:0] rst_delayed_ic_r = 2'h0;
wire rst_delayed_ic_r_i;
wire arst_sync_rst;
wire fifo_rst_done;
wire fifo_rst_active;
assign wr_rst_comb = !wr_rst_asreg_d2 && wr_rst_asreg;
assign rd_rst_comb = C_EN_SAFETY_CKT ? (!rd_rst_asreg_d2 && rd_rst_asreg) || rd_rst_active : !rd_rst_asreg_d2 && rd_rst_asreg;
assign rst_2_sync = rst_delayed_ic_w_i;
assign arst_sync_rst = arst_sync_q[RST_SYNC_STAGES-1];
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | fifo_rst_active : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? safety_ckt_rd_rst : 1'b0;
assign fifo_rst_done = fifo_wrst_done & fifo_rrst_done;
assign fifo_rst_active = sckt_wrst_i | wrst_ext[RST_SYNC_STAGES-1] | rrst_wr[RST_SYNC_STAGES-1];
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_w <= 2'b11;
else
rst_delayed_ic_w <= #`TCQ {rst_delayed_ic_w[0],1'b0};
end
assign rst_delayed_ic_w_i = rst_delayed_ic_w[1];
always @(posedge RD_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_r <= 2'b11;
else
rst_delayed_ic_r <= #`TCQ {rst_delayed_ic_r[0],1'b0};
end
assign rst_delayed_ic_r_i = rst_delayed_ic_r[1];
always @(posedge WR_CLK) begin
sckt_wrst_i_q <= #`TCQ sckt_wrst_i;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ sckt_wrst_i | wr_rst_busy | sckt_wr_rst_i_q;
if (arst_sync_rst && ~fifo_rst_active)
sckt_wrst_i <= #`TCQ 1'b1;
else if (sckt_wrst_i && fifo_rst_done)
sckt_wrst_i <= #`TCQ 1'b0;
else
sckt_wrst_i <= #`TCQ sckt_wrst_i;
if (rrst_wr[RST_SYNC_STAGES-2] & ~rrst_wr[RST_SYNC_STAGES-1])
fifo_rrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_rrst_done <= #`TCQ 1'b0;
else
fifo_rrst_done <= #`TCQ fifo_rrst_done;
if (wrst_ext[RST_SYNC_STAGES-2] & ~wrst_ext[RST_SYNC_STAGES-1])
fifo_wrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_wrst_done <= #`TCQ 1'b0;
else
fifo_wrst_done <= #`TCQ fifo_wrst_done;
end
always @(posedge WR_CLK or posedge rst_delayed_ic_w_i) begin
if (rst_delayed_ic_w_i == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],wr_rst_asreg};
wrst_ext <= #`TCQ {wrst_ext[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_wr <= #`TCQ {rrst_wr[RST_SYNC_STAGES-2:0],safety_ckt_rd_rst};
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_ic_w_i};
end
assign wr_rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign wr_rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge WR_CLK or posedge wr_rst_comb) begin
if (wr_rst_comb == 1'b1) begin
wr_rst_reg <= 1'b1;
end else begin
wr_rst_reg <= #`TCQ 1'b0;
end
end
always @(posedge RD_CLK or posedge rst_delayed_ic_r_i) begin
if (rst_delayed_ic_r_i == 1'b1) begin
rd_rst_asreg <= 1'b1;
end else begin
if (rd_rst_asreg_d1 == 1'b1) begin
rd_rst_asreg <= #`TCQ 1'b0;
end else begin
rd_rst_asreg <= #`TCQ rd_rst_asreg;
end
end
end
always @(posedge RD_CLK) begin
rrst_reg <= #`TCQ {rrst_reg[RST_SYNC_STAGES-2:0],rd_rst_asreg};
rrst_q <= #`TCQ {rrst_q[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_cc <= #`TCQ {rrst_cc[0],rd_rst_asreg_d2};
sckt_rd_rst_d1 <= #`TCQ safety_ckt_rd_rst;
if (!rd_rst_middle && rrst_reg[1] && !rrst_reg[2]) begin
rd_rst_active <= #`TCQ 1'b1;
rd_rst_middle <= #`TCQ 1'b1;
end else if (safety_ckt_rd_rst)
rd_rst_active <= #`TCQ 1'b0;
else if (sckt_rd_rst_d1 && !safety_ckt_rd_rst)
rd_rst_middle <= #`TCQ 1'b0;
end
assign rd_rst_asreg_d1 = rrst_reg[RST_SYNC_STAGES-2];
assign rd_rst_asreg_d2 = C_EN_SAFETY_CKT ? rrst_reg[RST_SYNC_STAGES-1] : rrst_reg[1];
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rrst_q[2] : 1'b0;
always @(posedge RD_CLK or posedge rd_rst_comb) begin
if (rd_rst_comb == 1'b1) begin
rd_rst_reg <= 1'b1;
end else begin
rd_rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_ic_rst
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 1) begin : g7s_cc_rst
reg [1:0] rst_delayed_cc = 2'h0;
wire rst_delayed_cc_i;
assign rst_comb = !rst_asreg_d2 && rst_asreg;
assign rst_2_sync = rst_delayed_cc_i;
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | wrst_cc[1] : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? arst_sync_q[1] | arst_sync_q[RST_SYNC_STAGES-1] | wrst_cc[1] : 1'b0;
always @(posedge CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1)
rst_delayed_cc <= 2'b11;
else
rst_delayed_cc <= #`TCQ {rst_delayed_cc,1'b0};
end
assign rst_delayed_cc_i = rst_delayed_cc[1];
always @(posedge CLK or posedge rst_delayed_cc_i) begin
if (rst_delayed_cc_i == 1'b1) begin
rst_asreg <= 1'b1;
end else begin
if (rst_asreg_d1 == 1'b1) begin
rst_asreg <= #`TCQ 1'b0;
end else begin
rst_asreg <= #`TCQ rst_asreg;
end
end
end
always @(posedge CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],rst_asreg};
wrst_cc <= #`TCQ {wrst_cc[0],arst_sync_q[RST_SYNC_STAGES-1]};
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ wrst_cc[1] | wr_rst_busy | sckt_wr_rst_i_q;
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_cc_i};
end
assign rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge CLK or posedge rst_comb) begin
if (rst_comb == 1'b1) begin
rst_reg <= 1'b1;
end else begin
rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_cc_rst
end else if (IS_8SERIES == 1 && C_HAS_SRST == 1 && C_COMMON_CLOCK == 1) begin : g8s_cc_rst
assign wr_rst_busy = (C_MEMORY_TYPE != 4) ? rst_reg : rst_active_i;
assign rd_rst_busy = rst_reg;
assign rst_2_sync = srst_delayed;
always @* rst_full_ff_i <= rst_reg;
always @* rst_full_gen_i <= C_FULL_FLAGS_RST_VAL == 1 ? rst_active_i : 0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
always @(posedge CLK) begin
rst_delayed_d1 <= #`TCQ srst_delayed;
rst_delayed_d2 <= #`TCQ rst_delayed_d1;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
if (rst_reg || rst_delayed_d2) begin
rst_active_i <= #`TCQ 1'b1;
end else begin
rst_active_i <= #`TCQ rst_reg;
end
end
always @(posedge CLK) begin
if (~rst_reg && srst_delayed) begin
rst_reg <= #`TCQ 1'b1;
end else if (rst_reg) begin
rst_reg <= #`TCQ 1'b0;
end else begin
rst_reg <= #`TCQ rst_reg;
end
end
// end : g8s_cc_rst
end else begin
assign wr_rst_busy = 1'b0;
assign rd_rst_busy = 1'b0;
assign safety_ckt_wr_rst = 1'b0;
assign safety_ckt_rd_rst = 1'b0;
end
endgenerate
generate
if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 1) begin : grstd1
// RST_FULL_GEN replaces the reset falling edge detection used to de-assert
// FULL, ALMOST_FULL & PROG_FULL flags if C_FULL_FLAGS_RST_VAL = 1.
// RST_FULL_FF goes to the reset pin of the final flop of FULL, ALMOST_FULL &
// PROG_FULL
reg rst_d1 = 1'b0;
reg rst_d2 = 1'b0;
reg rst_d3 = 1'b0;
reg rst_d4 = 1'b0;
reg rst_d5 = 1'b0;
always @ (posedge rst_2_sync or posedge clk_2_sync) begin
if (rst_2_sync) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
rst_d3 <= 1'b1;
rst_d4 <= 1'b1;
end else begin
if (srst_delayed) begin
rst_d1 <= #`TCQ 1'b1;
rst_d2 <= #`TCQ 1'b1;
rst_d3 <= #`TCQ 1'b1;
rst_d4 <= #`TCQ 1'b1;
end else begin
rst_d1 <= #`TCQ wr_rst_busy;
rst_d2 <= #`TCQ rst_d1;
rst_d3 <= #`TCQ rst_d2 | safety_ckt_wr_rst;
rst_d4 <= #`TCQ rst_d3;
end
end
end
always @* rst_full_ff_i <= (C_HAS_SRST == 0) ? rst_d2 : 1'b0 ;
always @* rst_full_gen_i <= rst_d3;
end else if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 0) begin : gnrst_full
always @* rst_full_ff_i <= (C_COMMON_CLOCK == 0) ? wr_rst_i : rst_i;
end
endgenerate // grstd1
endmodule //fifo_generator_v13_1_3_conv_ver
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0;
else
DOUT <= #`TCQ DIN;
end
endmodule // fifo_generator_v13_1_3_sync_stage
/*******************************************************************************
* Declaration of Independent-Clocks FIFO Module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_as
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input SAFETY_CKT_WR_RST,
input SAFETY_CKT_RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_CLK,
input RD_EN,
input RD_EN_USER,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input USER_EMPTY_FB,
input fab_read_data_valid_i,
input read_data_valid_i,
input ram_valid_i,
output reg ALMOST_EMPTY = 1'b1,
output reg ALMOST_FULL = C_FULL_FLAGS_RST_VAL,
output [C_DOUT_WIDTH-1:0] DOUT,
output reg EMPTY = 1'b1,
output reg EMPTY_FB = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL,
output OVERFLOW,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output UNDERFLOW,
output WR_ACK,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC_1 && SYMMETRIC_PORT && ERR_INJECTION;
// Array that holds the error injection type (single/double bit error) on
// a specific write operation, which is returned on read to corrupt the
// output data.
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
//The amount of data stored in the FIFO at any time is given
// by num_wr_bits (in the WR_CLK domain) and num_rd_bits (in the RD_CLK
// domain.
//num_wr_bits is calculated by considering the total words in the FIFO,
// and the state of the read pointer (which may not have yet crossed clock
// domains.)
//num_rd_bits is calculated by considering the total words in the FIFO,
// and the state of the write pointer (which may not have yet crossed clock
// domains.)
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
wire wr_rst_i = WR_RST;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire rd_rst_i = RD_RST;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
// Delayed ram_rd_en is needed only for STD Embedded register option
generate
if (C_PRELOAD_LATENCY == 2) begin : grd_d
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
end
endgenerate
generate
if (C_PRELOAD_LATENCY == 2 && C_USE_EMBEDDED_REG == 3) begin : grd_d1
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
endgenerate
// Write pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : rdg // Read depth greater than write depth
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1:0] = 0;
end else begin : rdl // Read depth lesser than or equal to write depth
assign adj_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
endgenerate
// Generate Empty and Almost Empty
// ram_rd_en used to determine EMPTY should depend on the EMPTY.
assign ram_rd_en = RD_EN & !EMPTY;
assign empty_int = ((adj_wr_pntr_rd == rd_pntr) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+1'h1))));
assign almost_empty_int = ((adj_wr_pntr_rd == (rd_pntr+1'h1)) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+2'h2))));
// Register Empty and Almost Empty
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin
EMPTY <= 1'b1;
ALMOST_EMPTY <= 1'b1;
rd_data_count_int <= {C_RD_PNTR_WIDTH{1'b0}};
end else begin
rd_data_count_int <= #`TCQ {(adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:0] - rd_pntr[C_RD_PNTR_WIDTH-1:0]), 1'b0};
if (empty_int)
EMPTY <= #`TCQ 1'b1;
else
EMPTY <= #`TCQ 1'b0;
if (!EMPTY) begin
if (almost_empty_int)
ALMOST_EMPTY <= #`TCQ 1'b1;
else
ALMOST_EMPTY <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (SAFETY_CKT_RD_RST && C_EN_SAFETY_CKT)
EMPTY_FB <= #`TCQ 1'b1;
else if (empty_int)
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ 1'b0;
end // rd_rst_i
end // always
// Read pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wdg // Write depth greater than read depth
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1:0] = 0;
end else begin : wdl // Write depth lesser than or equal to read depth
assign adj_rd_pntr_wr = rd_pntr_wr[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end
endgenerate
// Generate FULL and ALMOST_FULL
// ram_wr_en used to determine FULL should depend on the FULL.
assign ram_wr_en = WR_EN & !FULL;
assign full_int = ((adj_rd_pntr_wr == (wr_pntr+1'h1)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+2'h2))));
assign almost_full_int = ((adj_rd_pntr_wr == (wr_pntr+2'h2)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+3'h3))));
// Register FULL and ALMOST_FULL Empty
always @ (posedge WR_CLK or posedge RST_FULL_FF)
begin
if (RST_FULL_FF) begin
FULL <= C_FULL_FLAGS_RST_VAL;
ALMOST_FULL <= C_FULL_FLAGS_RST_VAL;
end else begin
if (full_int) begin
FULL <= #`TCQ 1'b1;
end else begin
FULL <= #`TCQ 1'b0;
end
if (RST_FULL_GEN) begin
ALMOST_FULL <= #`TCQ 1'b0;
end else if (!FULL) begin
if (almost_full_int)
ALMOST_FULL <= #`TCQ 1'b1;
else
ALMOST_FULL <= #`TCQ 1'b0;
end
end // wr_rst_i
end // always
always @ (posedge WR_CLK or posedge wr_rst_i)
begin
if (wr_rst_i) begin
wr_data_count_int <= {C_WR_DATA_COUNT_WIDTH{1'b0}};
end else begin
wr_data_count_int <= #`TCQ {(wr_pntr[C_WR_PNTR_WIDTH-1:0] - adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:0]), 1'b0};
end // wr_rst_i
end // always
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
stage1_valid <= 0;
stage2_valid <= 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//Pointers passed into opposite clock domain
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_EMPTY.
wire [31:0] num_read_words_pe =
num_rd_bits/(C_DOUT_WIDTH/C_DEPTH_RATIO_WR);
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_FULL.
wire [31:0] num_write_words_pf =
num_wr_bits/(C_DIN_WIDTH/C_DEPTH_RATIO_RD);
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/***************************************************************************
* Internal registers and wires
**************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire valid_i;
wire valid_out1;
wire valid_out2;
wire valid_out;
wire underflow_i;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
reg valid_d1 = 0;
reg valid_d2 = 0;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/****************************************************************************
* Function Declarations
***************************************************************************/
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
/***********************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_d2 = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_CLK;
wire RD_EN;
wire RST;
wire WR_CLK;
wire WR_EN;
*/
//***************************************************************************
// Dout may change behavior based on latency
//***************************************************************************
assign ideal_dout_out[C_DOUT_WIDTH-1:0] = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) )?
ideal_dout_d1: ideal_dout;
assign DOUT[C_DOUT_WIDTH-1:0] = ideal_dout_out;
//***************************************************************************
// Assign SBITERR and DBITERR based on latency
//***************************************************************************
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY == 2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) ) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY==2 && (C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
//***************************************************************************
// Safety-ckt logic with embedded reg/fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
// if (C_HAS_VALID == 1) begin
// assign valid_out = valid_d1;
// end
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK)
begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else begin
if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end
end
endgenerate
//***************************************************************************
// Safety-ckt logic with embedded reg + fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK) begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else begin
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end
endgenerate
//***************************************************************************
// Overflow may be active-low
//***************************************************************************
generate
if (C_HAS_OVERFLOW==1) begin : blockOF1
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end
endgenerate
assign PROG_EMPTY = ideal_prog_empty;
assign PROG_FULL = ideal_prog_full;
//***************************************************************************
// Valid may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_VALID==1) begin : blockVL1
assign valid_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out1 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG < 3)?
valid_d1: valid_i;
assign valid_out2 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG == 3)?
valid_d2: valid_i;
assign valid_out = (C_USE_EMBEDDED_REG == 3) ? valid_out2 : valid_out1;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end
endgenerate
//***************************************************************************
// Underflow may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_UNDERFLOW==1) begin : blockUF1
assign underflow_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & EMPTY) : ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end
endgenerate
//***************************************************************************
// Write acknowledge may be active low
//***************************************************************************
generate
if (C_HAS_WR_ACK==1) begin : blockWK1
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : wdc_fwft_ext
reg [C_PNTR_WIDTH-1:0] adjusted_wr_pntr = 0;
reg [C_PNTR_WIDTH-1:0] adjusted_rd_pntr = 0;
wire [C_PNTR_WIDTH-1:0] diff_wr_rd_tmp;
wire [C_PNTR_WIDTH:0] diff_wr_rd;
reg [C_PNTR_WIDTH:0] wr_data_count_i = 0;
always @* begin
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = 0;
adjusted_rd_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
end else if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin
adjusted_rd_pntr = rd_pntr_wr;
adjusted_wr_pntr = 0;
adjusted_wr_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
end else begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = rd_pntr_wr;
end
end // always @*
assign diff_wr_rd_tmp = adjusted_wr_pntr - adjusted_rd_pntr;
assign diff_wr_rd = {1'b0,diff_wr_rd_tmp};
always @ (posedge wr_rst_i or posedge WR_CLK)
begin
if (wr_rst_i)
wr_data_count_i <= 0;
else
wr_data_count_i <= #`TCQ diff_wr_rd + EXTRA_WORDS_DC;
end // always @ (posedge WR_CLK or posedge WR_CLK)
always @* begin
if (C_WR_PNTR_WIDTH >= C_RD_PNTR_WIDTH)
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:0];
else
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end // always @*
end // wdc_fwft_ext
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
reg [C_RD_PNTR_WIDTH:0] rdc_fwft_ext_as = 0;
generate if (C_USE_EMBEDDED_REG < 3) begin: rdc_fwft_ext_both
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= 0;
end else begin
if (!stage2_valid)
rdc_fwft_ext_as <= #`TCQ 0;
else if (!stage1_valid && stage2_valid)
rdc_fwft_ext_as <= #`TCQ 1;
else
rdc_fwft_ext_as <= #`TCQ diff_rd_wr + 2'h2;
end
end // always @ (posedge WR_CLK or posedge WR_CLK)
end // rdc_fwft_ext
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3) begin
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr_1;
// assign diff_rd_wr_1 = diff_rd_wr +2'h2;
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= #`TCQ 0;
end else begin
//if (fab_read_data_valid_i == 1'b0 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b0;
//else if (fab_read_data_valid_i == 1'b1 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b1;
//else
rdc_fwft_ext_as <= diff_rd_wr + 2'h2 ;
end
end
end
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = C_USE_FWFT_DATA_COUNT ?
rdc_fwft_ext_as[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH] :
rd_data_count_int[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = (C_USE_FWFT_DATA_COUNT == 1) ?
wdc_fwft_ext_as[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] :
wr_data_count_int[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate
if (C_HAS_VALID==1) begin : blockVL2
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_d2 <= 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
valid_d2 <= #`TCQ valid_d1;
end
// if (C_USE_EMBEDDED_REG == 3 && (C_EN_SAFETY_CKT == 0 || C_EN_SAFETY_CKT == 1 ) begin
// valid_d2 <= #`TCQ valid_d1;
// end
end
end
endgenerate
//Capture delayed version of dout
/**************************************************************************
*embedded/fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG < 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0)
err_type_d1 <= #`TCQ 0;
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
endgenerate
/**************************************************************************
*embedded + fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG == 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate
if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge WR_CLK) begin
ideal_overflow <= #`TCQ WR_EN & FULL;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge WR_CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (FULL | wr_rst_i);
ideal_overflow <= #`TCQ WR_EN & (FULL );
end
end
endgenerate
generate
if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ EMPTY & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ (EMPTY) & RD_EN;
//ideal_underflow <= #`TCQ (rd_rst_i | EMPTY) & RD_EN;
end
end
endgenerate
/**************************************************************************
* Write/Read Pointer Synchronization
**************************************************************************/
localparam NO_OF_SYNC_STAGE_INC_G2B = C_SYNCHRONIZER_STAGE + 1;
wire [C_WR_PNTR_WIDTH-1:0] wr_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
genvar gss;
generate for (gss = 1; gss <= NO_OF_SYNC_STAGE_INC_G2B; gss = gss + 1) begin : Sync_stage_inst
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_WR_PNTR_WIDTH)
)
rd_stg_inst
(
.RST (rd_rst_i),
.CLK (RD_CLK),
.DIN (wr_pntr_sync_stgs[gss-1]),
.DOUT (wr_pntr_sync_stgs[gss])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_RD_PNTR_WIDTH)
)
wr_stg_inst
(
.RST (wr_rst_i),
.CLK (WR_CLK),
.DIN (rd_pntr_sync_stgs[gss-1]),
.DOUT (rd_pntr_sync_stgs[gss])
);
end endgenerate // Sync_stage_inst
assign wr_pntr_sync_stgs[0] = wr_pntr_rd1;
assign rd_pntr_sync_stgs[0] = rd_pntr_wr1;
always@* begin
wr_pntr_rd <= wr_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
rd_pntr_wr <= rd_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
end
/**************************************************************************
* Write Domain Logic
**************************************************************************/
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_wp
if (wr_rst_i == 1'b1 && C_EN_SAFETY_CKT == 0)
wr_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_WR_RST == 1'b1)
wr_pntr <= #`TCQ 0;
end
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (wr_rst_i == 1'b1) begin
num_wr_bits <= 0;
next_num_wr_bits = 0;
wr_ptr <= C_WR_DEPTH - 1;
rd_ptr_wrclk <= C_RD_DEPTH - 1;
ideal_wr_ack <= 0;
ideal_wr_count <= 0;
tmp_wr_listsize = 0;
rd_ptr_wrclk_next <= 0;
wr_pntr_rd1 <= 0;
end else begin //wr_rst_i==0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
//If this is a write, handle the write by adding the value
// to the linked list, and updating all outputs appropriately
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD
>= C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full, but reporting full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//With DEPTH-1 words in the FIFO, it is almost_full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is completely empty, but it is
// reporting FULL for some reason (like reset)
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <=
C_FIFO_WR_DEPTH-2) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//FIFO is really not close to full, so change flag status.
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end //(tmp_wr_listsize == 0)
end else begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD >=
C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//This write is CAUSING the FIFO to go full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is 2 from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Still 2 from full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is not close to being full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //wr_rst_i==0
end // gen_fifo_w
/***************************************************************************
* Programmable FULL flags
***************************************************************************/
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_assert_val;
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_negate_val;
generate if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin : FWFT
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_DC;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_DC;
end else begin // STD
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL;
end endgenerate
always @(posedge WR_CLK or posedge wr_rst_i) begin
if (wr_rst_i == 1'b1) begin
diff_pntr <= 0;
end else begin
if (ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr + 2'h1);
else if (!ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr);
end
end
always @(posedge WR_CLK or posedge RST_FULL_FF) begin : gen_pf
if (RST_FULL_FF == 1'b1) begin
ideal_prog_full <= C_FULL_FLAGS_RST_VAL;
end else begin
if (RST_FULL_GEN)
ideal_prog_full <= #`TCQ 0;
//Single Programmable Full Constant Threshold
else if (C_PROG_FULL_TYPE == 1) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Constant Thresholds
end else if (C_PROG_FULL_TYPE == 2) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < pf_thr_negate_val)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Single Programmable Full Threshold Input
end else if (C_PROG_FULL_TYPE == 3) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Threshold Inputs
end else if (C_PROG_FULL_TYPE == 4) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH_ASSERT - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < (PROG_FULL_THRESH_NEGATE - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH_ASSERT)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < PROG_FULL_THRESH_NEGATE)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
end // C_PROG_FULL_TYPE
end //wr_rst_i==0
end //
/**************************************************************************
* Read Domain Logic
**************************************************************************/
/*********************************************************
* Programmable EMPTY flags
*********************************************************/
//Determine the Assert and Negate thresholds for Programmable Empty
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_assert_val;
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_negate_val;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_rd = 0;
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_pe
if (rd_rst_i) begin
diff_pntr_rd <= 0;
ideal_prog_empty <= 1'b1;
end else begin
if (ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr) - 1'h1;
else if (!ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr);
else
diff_pntr_rd <= #`TCQ diff_pntr_rd;
if (C_PROG_EMPTY_TYPE == 1) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 2) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 3) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 4) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end //C_PROG_EMPTY_TYPE
end
end // gen_pe
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH - 2'h2 : PROG_EMPTY_THRESH;
end endgenerate // single_pe_thr_input
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_ASSERT - 2'h2 : PROG_EMPTY_THRESH_ASSERT;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_NEGATE - 2'h2 : PROG_EMPTY_THRESH_NEGATE;
end endgenerate // multiple_pe_thr_input
generate if (C_PROG_EMPTY_TYPE < 3) begin : single_multiple_pe_thr_const
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2'h2 : C_PROG_EMPTY_THRESH_ASSERT_VAL;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2'h2 : C_PROG_EMPTY_THRESH_NEGATE_VAL;
end endgenerate // single_multiple_pe_thr_const
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_rp
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
rd_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_RD_RST == 1'b1)
rd_pntr <= #`TCQ 0;
end
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_r_as
/****** Reset fifo (case 1)***************************************/
if (rd_rst_i) begin
num_rd_bits <= 0;
next_num_rd_bits = 0;
rd_ptr <= C_RD_DEPTH -1;
rd_pntr_wr1 <= 0;
wr_ptr_rdclk <= C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_MEMORY_TYPE == 2 && C_USE_DOUT_RST == 1)
ideal_dout <= dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= 1'b0;
ideal_rd_count <= 0;
end else begin //rd_rst_i==0
rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
/*****************************************************************/
// Read Operation - Read Latency 1
/*****************************************************************/
if (C_PRELOAD_LATENCY==1 || C_PRELOAD_LATENCY==2) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
//If the FIFO is one from empty, but it is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is two from empty, and is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH))
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end // else: if(ideal_empty == 1'b1)
else //if (ideal_empty == 1'b0)
begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == C_FIFO_RD_DEPTH)
//If the FIFO is not close to being empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
//If the FIFO is two from empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is one from empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR == 1))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is completely empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end //(RD_EN == 1'b1)
else //if (RD_EN == 1'b0)
begin
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
/*****************************************************************/
// Read Operation - Read Latency 0
/*****************************************************************/
end else if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty, but it is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty, and is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH)) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end else begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to being empty
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH)) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is completely empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end else begin//(RD_EN == 1'b0)
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
end //if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0)
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //rd_rst_i==0
end //always gen_fifo_r_as
endmodule // fifo_generator_v13_1_3_bhv_ver_as
/*******************************************************************************
* Declaration of Low Latency Asynchronous FIFO
******************************************************************************/
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_USE_DOUT_RST = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_FIFO_TYPE = 0
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input [C_DIN_WIDTH-1:0] DIN,
input RD_CLK,
input RD_EN,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
output reg [C_DOUT_WIDTH-1:0] DOUT = 0,
output reg EMPTY = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL
);
//-----------------------------------------------------------------------------
// Low Latency Asynchronous FIFO
//-----------------------------------------------------------------------------
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
integer i;
initial begin
for (i = 0; i < C_WR_DEPTH; i = i + 1)
memory[i] = 0;
end
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_ll_afifo = 0;
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo_q = 0;
reg ll_afifo_full = 1'b0;
reg ll_afifo_empty = 1'b1;
wire write_allow;
wire read_allow;
assign write_allow = WR_EN & ~ll_afifo_full;
assign read_allow = RD_EN & ~ll_afifo_empty;
//-----------------------------------------------------------------------------
// Write Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
wr_pntr_ll_afifo <= 0;
else if (write_allow)
wr_pntr_ll_afifo <= #`TCQ wr_pntr_ll_afifo + 1;
end
//-----------------------------------------------------------------------------
// Read Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
rd_pntr_ll_afifo_q <= 0;
else
rd_pntr_ll_afifo_q <= #`TCQ rd_pntr_ll_afifo;
end
assign rd_pntr_ll_afifo = read_allow ? rd_pntr_ll_afifo_q + 1 : rd_pntr_ll_afifo_q;
//-----------------------------------------------------------------------------
// Fill the Memory
//-----------------------------------------------------------------------------
always @(posedge WR_CLK) begin
if (write_allow)
memory[wr_pntr_ll_afifo] <= #`TCQ DIN;
end
//-----------------------------------------------------------------------------
// Generate DOUT
//-----------------------------------------------------------------------------
always @(posedge RD_CLK) begin
DOUT <= #`TCQ memory[rd_pntr_ll_afifo];
end
//-----------------------------------------------------------------------------
// Generate EMPTY
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
ll_afifo_empty <= 1'b1;
else
ll_afifo_empty <= ((wr_pntr_ll_afifo == rd_pntr_ll_afifo_q) |
(read_allow & (wr_pntr_ll_afifo == (rd_pntr_ll_afifo_q + 2'h1))));
end
//-----------------------------------------------------------------------------
// Generate FULL
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
ll_afifo_full <= 1'b1;
else
ll_afifo_full <= ((rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h1)) |
(write_allow & (rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h2))));
end
always @* begin
FULL <= ll_afifo_full;
EMPTY <= ll_afifo_empty;
end
endmodule // fifo_generator_v13_1_3_beh_ver_ll_afifo
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* Declare user parameters and their defaults
*************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
/**************************************************************************
* Declare Input and Output Ports
*************************************************************************/
(
//Inputs
input SAFETY_CKT_WR_RST,
input CLK,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_EN,
input RD_EN_USER,
input USER_EMPTY_FB,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input SRST,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input WR_RST_BUSY,
input RD_RST_BUSY,
//Outputs
output ALMOST_EMPTY,
output ALMOST_FULL,
output reg [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT = 0,
output [C_DOUT_WIDTH-1:0] DOUT,
output EMPTY,
output reg EMPTY_FB = 1'b1,
output FULL,
output OVERFLOW,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output UNDERFLOW,
output WR_ACK,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
wire [C_RD_PNTR_WIDTH:0] rd_data_count_i_ss;
wire [C_WR_PNTR_WIDTH:0] wr_data_count_i_ss;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
//localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
//localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
localparam C_GRTR_PNTR_WIDTH = (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH ;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
wire [C_WR_PNTR_WIDTH:0] EXTRA_WORDS_PF = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//wire [C_RD_PNTR_WIDTH:0] EXTRA_WORDS_PE = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam EXTRA_WORDS_PF_PARAM = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//localparam EXTRA_WORDS_PE_PARAM = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
//The reset value assignments for FULL, ALMOST_FULL, and PROG_FULL are not
//changed for v3.2(IP2_Im). When the core has Sync Reset, C_HAS_SRST=1 and C_HAS_RST=0.
// Therefore, during SRST, all the FULL flags reset to 0.
localparam C_HAS_FAST_FIFO = 0;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH;
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC && SYMMETRIC_PORT && ERR_INJECTION;
localparam C_DATA_WIDTH = (ENABLE_ERR_INJECTION == 1) ? (C_DIN_WIDTH+2) : C_DIN_WIDTH;
localparam IS_ASYMMETRY = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 0 : 1;
localparam LESSER_WIDTH = (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
localparam [C_RD_PNTR_WIDTH-1 : 0] DIFF_MAX_RD = {C_RD_PNTR_WIDTH{1'b1}};
localparam [C_WR_PNTR_WIDTH-1 : 0] DIFF_MAX_WR = {C_WR_PNTR_WIDTH{1'b1}};
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
/**************************************************************************
* Internal Registers and wires
*************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire underflow_i;
wire valid_i;
wire valid_out;
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_reg = 1'b0;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
wire srst_rrst_busy;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire fwft_enabled;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg full_i = C_FULL_FLAGS_RST_VAL;
reg full_i_temp = 0;
reg empty_i = 1;
reg almost_full_i = 0;
reg almost_empty_i = 1;
reg prog_full_i = 0;
reg prog_empty_i = 1;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] diff_count = 0;
reg write_allow_q = 0;
reg read_allow_q = 0;
reg valid_d1 = 0;
reg valid_both = 0;
reg valid_d2 = 0;
wire rst_i;
wire srst_i;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
/****************************************************************************
* Function Declarations
***************************************************************************/
/****************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***************************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 ) begin
case (def_data[7:0])
8'b00000000 : begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default : begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1) begin
if ((index*4)+j < C_DOUT_WIDTH) begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
//reg valid_d1 = 0;
//user specified value for reseting the size of the fifo
//reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_dout_both = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_both = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_EN;
wire RST;
wire WR_EN;
*/
// Assign ALMOST_EPMTY
generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae
assign ALMOST_EMPTY = almost_empty_i;
end else begin : gnae
assign ALMOST_EMPTY = 0;
end endgenerate // gae
// Assign ALMOST_FULL
generate if (C_HAS_ALMOST_FULL==1) begin : gaf
assign ALMOST_FULL = almost_full_i;
end else begin : gnaf
assign ALMOST_FULL = 0;
end endgenerate // gaf
// Dout may change behavior based on latency
localparam C_FWFT_ENABLED = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign fwft_enabled = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign ideal_dout_out= ((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1))?
ideal_dout_d1: ideal_dout;
assign DOUT = ideal_dout_out;
// Assign SBITERR and DBITERR based on latency
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
assign EMPTY = empty_i;
assign FULL = full_i;
//saftey_ckt with one register
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && (C_USE_EMBEDDED_REG == 1 || C_USE_EMBEDDED_REG == 2 )) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK)
begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK)
begin
if( rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end
else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
valid_d1 <= #`TCQ valid_i;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end //if
endgenerate
//safety ckt with both registers
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK) begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end //if
endgenerate
//Overflow may be active-low
generate if (C_HAS_OVERFLOW==1) begin : gof
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end else begin : gnof
assign OVERFLOW = 0;
end endgenerate // gof
assign PROG_EMPTY = prog_empty_i;
assign PROG_FULL = prog_full_i;
//Valid may change behavior based on latency or active-low
generate if (C_HAS_VALID==1) begin : gvalid
assign valid_i = (C_PRELOAD_LATENCY == 0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out = (C_PRELOAD_LATENCY == 2 && C_MEMORY_TYPE < 2) ?
valid_d1 : valid_i;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end else begin : gnvalid
assign VALID = 0;
end endgenerate // gvalid
//Trim data count differently depending on set widths
generate if (C_HAS_DATA_COUNT == 1) begin : gdc
always @* begin
diff_count <= wr_pntr - rd_pntr;
if (C_DATA_COUNT_WIDTH > C_RD_PNTR_WIDTH) begin
DATA_COUNT[C_RD_PNTR_WIDTH-1:0] <= diff_count;
DATA_COUNT[C_DATA_COUNT_WIDTH-1] <= 1'b0 ;
end else begin
DATA_COUNT <= diff_count[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH];
end
end
// end else begin : gndc
// always @* DATA_COUNT <= 0;
end endgenerate // gdc
//Underflow may change behavior based on latency or active-low
generate if (C_HAS_UNDERFLOW==1) begin : guf
assign underflow_i = ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end else begin : gnuf
assign UNDERFLOW = 0;
end endgenerate // guf
//Write acknowledge may be active low
generate if (C_HAS_WR_ACK==1) begin : gwr_ack
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end else begin : gnwr_ack
assign WR_ACK = 0;
end endgenerate // gwr_ack
/*****************************************************************************
* Internal reset logic
****************************************************************************/
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_WR_RST : C_HAS_SRST ? (SRST | WR_RST_BUSY) : 0;
assign rst_i = C_HAS_RST ? RST : 0;
assign srst_wrst_busy = srst_i;
assign srst_rrst_busy = srst_i;
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG <3)) begin : blockVL20
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG == 3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_both <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
valid_both <= #`TCQ 1'b0;
end else begin
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge CLK or posedge rst_i) begin
if (rst_i) begin
stage1_valid <= #`TCQ 0;
stage2_valid <= #`TCQ 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT ==1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = rd_data_count_i_ss[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = wr_data_count_i_ss[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] ;
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//reg ram_rd_en_d1 = 1'b0;
//Capture delayed version of dout
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG<3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
ram_rd_en_d1 <= #`TCQ 1'b0;
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
end // always
end
endgenerate
//no safety ckt with both registers
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG==3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
fab_rd_en_d1 <= #`TCQ (ram_rd_en_d1);
if (ram_rd_en_d1 ) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end // always
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge CLK) begin
ideal_overflow <= #`TCQ WR_EN & full_i;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (rst_i | full_i);
ideal_overflow <= #`TCQ WR_EN & (WR_RST_BUSY | full_i);
end
end endgenerate // blockOF20
generate if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge CLK) begin
ideal_underflow <= #`TCQ empty_i & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge CLK) begin
//ideal_underflow <= #`TCQ (rst_i | empty_i) & RD_EN;
ideal_underflow <= #`TCQ (RD_RST_BUSY | empty_i) & RD_EN;
end
end endgenerate // blockUF20
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/*************************************************************************
* Write and Read Logic
************************************************************************/
wire write_allow;
wire read_allow;
wire read_allow_dc;
wire write_only;
wire read_only;
//wire write_only_q;
reg write_only_q;
//wire read_only_q;
reg read_only_q;
reg full_reg;
reg rst_full_ff_reg1;
reg rst_full_ff_reg2;
wire ram_full_comb;
wire carry;
assign write_allow = WR_EN & ~full_i;
assign read_allow = RD_EN & ~empty_i;
assign read_allow_dc = RD_EN_USER & ~USER_EMPTY_FB;
//assign write_only = write_allow & ~read_allow;
//assign write_only_q = write_allow_q;
//assign read_only = read_allow & ~write_allow;
//assign read_only_q = read_allow_q ;
wire [C_WR_PNTR_WIDTH-1:0] diff_pntr;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_reg1 = 0;
reg [C_RD_PNTR_WIDTH:0] diff_pntr_pe_asym = 0;
wire [C_RD_PNTR_WIDTH:0] adj_wr_pntr_rd_asym ;
wire [C_RD_PNTR_WIDTH:0] rd_pntr_asym;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_pe_reg2 = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_max;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_max;
assign diff_pntr_pe_max = DIFF_MAX_RD;
assign diff_pntr_max = DIFF_MAX_WR;
generate if (IS_ASYMMETRY == 0) begin : diff_pntr_sym
assign write_only = write_allow & ~read_allow;
assign read_only = read_allow & ~write_allow;
end endgenerate
generate if ( IS_ASYMMETRY == 1 && C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : wr_grt_rd
assign read_only = read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]) & ~write_allow;
assign write_only = write_allow & ~(read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (IS_ASYMMETRY ==1 && C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : rd_grt_wr
assign read_only = read_allow & ~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
assign write_only = write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]) & ~read_allow;
end endgenerate
//-----------------------------------------------------------------------------
// Write and Read pointer generation
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
wr_pntr <= 0;
rd_pntr <= 0;
end else begin
if (srst_i) begin
wr_pntr <= #`TCQ 0;
rd_pntr <= #`TCQ 0;
end else begin
if (write_allow) wr_pntr <= #`TCQ wr_pntr + 1;
if (read_allow) rd_pntr <= #`TCQ rd_pntr + 1;
end
end
end
generate if (C_FIFO_TYPE == 2) begin : gll_dm_dout
always @(posedge CLK) begin
if (write_allow) begin
if (ENABLE_ERR_INJECTION == 1)
memory[wr_pntr] <= #`TCQ {INJECTDBITERR,INJECTSBITERR,DIN};
else
memory[wr_pntr] <= #`TCQ DIN;
end
end
reg [C_DATA_WIDTH-1:0] dout_tmp_q;
reg [C_DATA_WIDTH-1:0] dout_tmp = 0;
reg [C_DATA_WIDTH-1:0] dout_tmp1 = 0;
always @(posedge CLK) begin
dout_tmp_q <= #`TCQ ideal_dout;
end
always @* begin
if (read_allow)
ideal_dout <= memory[rd_pntr];
else
ideal_dout <= dout_tmp_q;
end
end endgenerate // gll_dm_dout
/**************************************************************************
* Write Domain Logic
**************************************************************************/
assign ram_rd_en = RD_EN & !EMPTY;
//reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
generate if (C_FIFO_TYPE != 2) begin : gnll_din
always @(posedge CLK or posedge rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (rst_i == 1'b1) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin //rst_i==0
if (srst_wrst_busy) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin//srst_i=0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end else begin
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
//end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //srst_i==0
end //wr_rst_i==0
end // gen_fifo_w
end endgenerate
generate if (C_FIFO_TYPE < 2 && C_MEMORY_TYPE < 2) begin : gnll_dm_dout
always @(posedge CLK) begin
if (rst_i || srst_rrst_busy) begin
if (C_USE_DOUT_RST == 1) begin
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end
end
end endgenerate
generate if (C_FIFO_TYPE != 2) begin : gnll_dout
always @(posedge CLK or posedge rst_i) begin : gen_fifo_r
/****** Reset fifo (case 1)***************************************/
if (rst_i) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end else begin //rd_rst_i==0
if (srst_rrst_busy) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets synchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end //srst_i
else begin
//rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
if (RD_EN == 1'b1) begin
if (EMPTY == 1'b1) begin
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end
else
begin
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
end
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //s_rst_i==0
end //rd_rst_i==0
end //always
end endgenerate
//-----------------------------------------------------------------------------
// Generate diff_pntr for PROG_FULL generation
// Generate diff_pntr_pe for PROG_EMPTY generation
//-----------------------------------------------------------------------------
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 0) begin : reg_write_allow
always @(posedge CLK ) begin
if (rst_i) begin
write_only_q <= 1'b0;
read_only_q <= 1'b0;
diff_pntr_reg1 <= 0;
diff_pntr_pe_reg1 <= 0;
diff_pntr_reg2 <= 0;
diff_pntr_pe_reg2 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_rrst_busy) begin
read_only_q <= #`TCQ 1'b0;
diff_pntr_pe_reg1 <= #`TCQ 0;
diff_pntr_pe_reg2 <= #`TCQ 0;
end
if (srst_wrst_busy) begin
write_only_q <= #`TCQ 1'b0;
diff_pntr_reg1 <= #`TCQ 0;
diff_pntr_reg2 <= #`TCQ 0;
end
end else begin
write_only_q <= #`TCQ write_only;
read_only_q <= #`TCQ read_only;
diff_pntr_reg2 <= #`TCQ diff_pntr_reg1;
diff_pntr_pe_reg2 <= #`TCQ diff_pntr_pe_reg1;
// Add 1 to the difference pointer value when only write happens.
if (write_only)
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr + 1;
else
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
// Add 1 to the difference pointer value when write or both write & read or no write & read happen.
if (read_only)
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr - 1;
else
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr;
end
end
end
assign diff_pntr_pe = diff_pntr_pe_reg1;
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 1) begin : reg_write_allow_asym
assign adj_wr_pntr_rd_asym[C_RD_PNTR_WIDTH:0] = {adj_wr_pntr_rd,1'b1};
assign rd_pntr_asym[C_RD_PNTR_WIDTH:0] = {~rd_pntr,1'b1};
always @(posedge CLK ) begin
if (rst_i) begin
diff_pntr_pe_asym <= 0;
diff_pntr_reg1 <= 0;
full_reg <= 0;
rst_full_ff_reg1 <= 1;
rst_full_ff_reg2 <= 1;
diff_pntr_pe_reg1 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_wrst_busy)
diff_pntr_reg1 <= #`TCQ 0;
if (srst_rrst_busy)
full_reg <= #`TCQ 0;
rst_full_ff_reg1 <= #`TCQ 1;
rst_full_ff_reg2 <= #`TCQ 1;
diff_pntr_pe_asym <= #`TCQ 0;
diff_pntr_pe_reg1 <= #`TCQ 0;
end else begin
diff_pntr_pe_asym <= #`TCQ adj_wr_pntr_rd_asym + rd_pntr_asym;
full_reg <= #`TCQ full_i;
rst_full_ff_reg1 <= #`TCQ RST_FULL_FF;
rst_full_ff_reg2 <= #`TCQ rst_full_ff_reg1;
if (~full_i) begin
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
end
end
end
end
assign carry = (~(|(diff_pntr_pe_asym [C_RD_PNTR_WIDTH : 1])));
assign diff_pntr_pe = (full_reg && ~rst_full_ff_reg2 && carry ) ? diff_pntr_pe_max : diff_pntr_pe_asym[C_RD_PNTR_WIDTH:1];
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow_asym
//-----------------------------------------------------------------------------
// Generate FULL flag
//-----------------------------------------------------------------------------
wire comp0;
wire comp1;
wire going_full;
wire leaving_full;
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gpad
assign adj_rd_pntr_wr [C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_WR_PNTR_WIDTH <= C_RD_PNTR_WIDTH) begin : gtrim
assign adj_rd_pntr_wr = rd_pntr[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
assign comp1 = (adj_rd_pntr_wr == (wr_pntr + 1'b1));
assign comp0 = (adj_rd_pntr_wr == wr_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gf_wp_eq_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full = (comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gf_asym
assign going_full = (comp1 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_full = (comp0 & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gf_wp_gt_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full =(comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_full_comb = going_full | (~leaving_full & full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
full_i <= #`TCQ ram_full_comb;
end
//-----------------------------------------------------------------------------
// Generate EMPTY flag
//-----------------------------------------------------------------------------
wire ecomp0;
wire ecomp1;
wire going_empty;
wire leaving_empty;
wire ram_empty_comb;
generate if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : pad
assign adj_wr_pntr_rd [C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_RD_PNTR_WIDTH <= C_WR_PNTR_WIDTH) begin : trim
assign adj_wr_pntr_rd = wr_pntr[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
assign ecomp1 = (adj_wr_pntr_rd == (rd_pntr + 1'b1));
assign ecomp0 = (adj_wr_pntr_rd == rd_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : ge_wp_eq_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty = (ecomp0 & write_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : ge_wp_gt_rp
assign going_empty = (ecomp1 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_empty = (ecomp0 & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : ge_wp_lt_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty =(ecomp0 & write_allow);
end endgenerate
assign ram_empty_comb = going_empty | (~leaving_empty & empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
empty_i <= 1'b1;
else if (srst_rrst_busy)
empty_i <= #`TCQ 1'b1;
else
empty_i <= #`TCQ ram_empty_comb;
end
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (srst_rrst_busy || (SAFETY_CKT_WR_RST && C_EN_SAFETY_CKT))
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ ram_empty_comb;
end
end // always
//-----------------------------------------------------------------------------
// Generate Read and write data counts for asymmetic common clock
//-----------------------------------------------------------------------------
reg [C_GRTR_PNTR_WIDTH :0] count_dc = 0;
wire [C_GRTR_PNTR_WIDTH :0] ratio;
wire decr_by_one;
wire incr_by_ratio;
wire incr_by_one;
wire decr_by_ratio;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : rd_depth_gt_wr
assign ratio = C_DEPTH_RATIO_RD;
assign decr_by_one = (IS_FWFT == 1)? read_allow_dc : read_allow;
assign incr_by_ratio = write_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (decr_by_one) begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc - 1;
else
count_dc <= #`TCQ count_dc - 1 + ratio ;
end
else begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc + ratio ;
end
end
end
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc;
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wr_depth_gt_rd
assign ratio = C_DEPTH_RATIO_WR;
assign incr_by_one = write_allow;
assign decr_by_ratio = (IS_FWFT == 1)? read_allow_dc : read_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (incr_by_one) begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc + 1;
else
count_dc <= #`TCQ count_dc + 1 - ratio ;
end
else begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc - ratio ;
end
end
end
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc;
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
//-----------------------------------------------------------------------------
// Generate WR_ACK flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_wr_ack <= 1'b0;
else if (srst_wrst_busy)
ideal_wr_ack <= #`TCQ 1'b0;
else if (WR_EN & ~full_i)
ideal_wr_ack <= #`TCQ 1'b1;
else
ideal_wr_ack <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate VALID flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_valid <= 1'b0;
else if (srst_rrst_busy)
ideal_valid <= #`TCQ 1'b0;
else if (RD_EN & ~empty_i)
ideal_valid <= #`TCQ 1'b1;
else
ideal_valid <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate ALMOST_FULL flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_FULL == 1 || C_PROG_FULL_TYPE > 2 || C_PROG_EMPTY_TYPE > 2) begin : gaf_ss
wire fcomp2;
wire going_afull;
wire leaving_afull;
wire ram_afull_comb;
assign fcomp2 = (adj_rd_pntr_wr == (wr_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gaf_wp_eq_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull = (comp1 & read_allow & ~write_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gaf_asym
assign going_afull = (fcomp2 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_afull = (comp1 & (~write_allow) & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gaf_wp_gt_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull =((comp0 | comp1 | fcomp2) & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_afull_comb = going_afull | (~leaving_afull & almost_full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
almost_full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
almost_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
almost_full_i <= #`TCQ ram_afull_comb;
end
// end endgenerate // gaf_ss
//-----------------------------------------------------------------------------
// Generate ALMOST_EMPTY flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae_ss
wire ecomp2;
wire going_aempty;
wire leaving_aempty;
wire ram_aempty_comb;
assign ecomp2 = (adj_wr_pntr_rd == (rd_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gae_wp_eq_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty = (ecomp1 & write_allow & ~read_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gae_wp_gt_rp
assign going_aempty = (ecomp2 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_aempty = (ecomp1 & ~read_allow & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gae_wp_lt_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty =((ecomp2 | ecomp1 |ecomp0) & write_allow);
end endgenerate
assign ram_aempty_comb = going_aempty | (~leaving_aempty & almost_empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
almost_empty_i <= 1'b1;
else if (srst_rrst_busy)
almost_empty_i <= #`TCQ 1'b1;
else
almost_empty_i <= #`TCQ ram_aempty_comb;
end
// end endgenerate // gae_ss
//-----------------------------------------------------------------------------
// Generate PROG_FULL
//-----------------------------------------------------------------------------
localparam C_PF_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_PF_PARAM : // FWFT
C_PROG_FULL_THRESH_ASSERT_VAL; // STD
localparam C_PF_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_PF_PARAM: // FWFT
C_PROG_FULL_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold constant
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] temp = C_PF_ASSERT_VAL;
generate if (C_PROG_FULL_TYPE == 1) begin : single_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_ASSERT_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr>= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr) < C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b0;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate // single_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_FULL_TYPE == 2) begin : multiple_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_NEGATE_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr >= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < C_PF_NEGATE_VAL)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf3_assert_val = (C_PRELOAD_LATENCY == 0) ?
PROG_FULL_THRESH - EXTRA_WORDS_PF: // FWFT
PROG_FULL_THRESH; // STD
generate if (C_PROG_FULL_TYPE == 3) begin : single_pf_input
always @(posedge CLK or posedge RST_FULL_FF) begin//0
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin //1
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin//2
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin//3
if (diff_pntr > pf3_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == pf3_assert_val) begin//4
if (read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b1;
end else//4
prog_full_i <= #`TCQ 1'b0;
end else//3
prog_full_i <= #`TCQ prog_full_i;
end //2
else begin//5
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin//6
if (diff_pntr >= pf3_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf3_assert_val) begin//7
prog_full_i <= #`TCQ 1'b0;
end//7
end//6
else
prog_full_i <= #`TCQ prog_full_i;
end//5
end//1
end//0
end endgenerate //single_pf_input
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_ASSERT -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_ASSERT; // STD
wire [C_WR_PNTR_WIDTH-1:0] pf_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_NEGATE -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_NEGATE; // STD
generate if (C_PROG_FULL_TYPE == 4) begin : multiple_pf_inputs
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin
if (diff_pntr >= pf_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr == pf_negate_val && read_only_q) ||
diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin
if (diff_pntr >= pf_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_inputs
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY
//-----------------------------------------------------------------------------
localparam C_PE_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_ASSERT_VAL; // STD
localparam C_PE_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold constant
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 1) begin : single_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_ASSERT_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b0;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 2) begin : multiple_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_NEGATE_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_NEGATE_VAL)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate //multiple_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe3_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH -2) : // FWFT
PROG_EMPTY_THRESH; // STD
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_input
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe < pe3_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == pe3_assert_val) begin
if (write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ 1'b1;
end else
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe3_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe3_assert_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_input
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe4_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_ASSERT - 2) : // FWFT
PROG_EMPTY_THRESH_ASSERT; // STD
wire [C_RD_PNTR_WIDTH-1:0] pe4_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_NEGATE - 2) : // FWFT
PROG_EMPTY_THRESH_NEGATE; // STD
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_inputs
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe <= pe4_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (((diff_pntr_pe == pe4_negate_val) && write_only_q) ||
(diff_pntr_pe > pe4_negate_val)) begin
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe4_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe4_negate_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // multiple_pe_inputs
endmodule // fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* First-Word Fall-Through module (preload 0)
**************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USERVALID_LOW = 0,
parameter C_USERUNDERFLOW_LOW = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
(
//Inputs
input SAFETY_CKT_RD_RST,
input RD_CLK,
input RD_RST,
input SRST,
input WR_RST_BUSY,
input RD_RST_BUSY,
input RD_EN,
input FIFOEMPTY,
input [C_DOUT_WIDTH-1:0] FIFODATA,
input FIFOSBITERR,
input FIFODBITERR,
//Outputs
output reg [C_DOUT_WIDTH-1:0] USERDATA,
output USERVALID,
output USERUNDERFLOW,
output USEREMPTY,
output USERALMOSTEMPTY,
output RAMVALID,
output FIFORDEN,
output reg USERSBITERR,
output reg USERDBITERR,
output reg STAGE2_REG_EN,
output fab_read_data_valid_i_o,
output read_data_valid_i_o,
output ram_valid_i_o,
output [1:0] VALID_STAGES
);
//Internal signals
wire preloadstage1;
wire preloadstage2;
reg ram_valid_i;
reg fab_valid;
reg read_data_valid_i;
reg fab_read_data_valid_i;
reg fab_read_data_valid_i_1;
reg ram_valid_i_d;
reg read_data_valid_i_d;
reg fab_read_data_valid_i_d;
wire ram_regout_en;
reg ram_regout_en_d1;
reg ram_regout_en_d2;
wire fab_regout_en;
wire ram_rd_en;
reg empty_i = 1'b1;
reg empty_sckt = 1'b1;
reg sckt_rrst_q = 1'b0;
reg sckt_rrst_done = 1'b0;
reg empty_q = 1'b1;
reg rd_en_q = 1'b0;
reg almost_empty_i = 1'b1;
reg almost_empty_q = 1'b1;
wire rd_rst_i;
wire srst_i;
reg [C_DOUT_WIDTH-1:0] userdata_both;
wire uservalid_both;
wire uservalid_one;
reg user_sbiterr_both = 1'b0;
reg user_dbiterr_both = 1'b0;
assign ram_valid_i_o = ram_valid_i;
assign read_data_valid_i_o = read_data_valid_i;
assign fab_read_data_valid_i_o = fab_read_data_valid_i;
/*************************************************************************
* FUNCTIONS
*************************************************************************/
/*************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
//*************************************************************************
// Set power-on states for regs
//*************************************************************************
initial begin
ram_valid_i = 1'b0;
fab_valid = 1'b0;
read_data_valid_i = 1'b0;
fab_read_data_valid_i = 1'b0;
fab_read_data_valid_i_1 = 1'b0;
USERDATA = hexstr_conv(C_DOUT_RST_VAL);
userdata_both = hexstr_conv(C_DOUT_RST_VAL);
USERSBITERR = 1'b0;
USERDBITERR = 1'b0;
user_sbiterr_both = 1'b0;
user_dbiterr_both = 1'b0;
end //initial
//***************************************************************************
// connect up optional reset
//***************************************************************************
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? RD_RST : 0;
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_RD_RST : C_HAS_SRST ? SRST : 0;
reg sckt_rd_rst_fwft = 1'b0;
reg fwft_rst_done_i = 1'b0;
wire fwft_rst_done;
assign fwft_rst_done = C_EN_SAFETY_CKT ? fwft_rst_done_i : 1'b1;
always @ (posedge RD_CLK) begin
sckt_rd_rst_fwft <= #`TCQ SAFETY_CKT_RD_RST;
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i)
fwft_rst_done_i <= 1'b0;
else if (sckt_rd_rst_fwft & ~SAFETY_CKT_RD_RST)
fwft_rst_done_i <= #`TCQ 1'b1;
end
localparam INVALID = 0;
localparam STAGE1_VALID = 2;
localparam STAGE2_VALID = 1;
localparam BOTH_STAGES_VALID = 3;
reg [1:0] curr_fwft_state = INVALID;
reg [1:0] next_fwft_state = INVALID;
generate if (C_USE_EMBEDDED_REG < 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = preloadstage2;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = (RD_EN & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
reg curr_state = 0;
reg next_state = 0;
reg leaving_empty_fwft = 0;
reg going_empty_fwft = 0;
reg empty_i_q = 0;
reg ram_rd_en_fwft = 0;
generate if (C_FIFO_TYPE == 2) begin : gll_fifo
always @* begin // FSM fo FWFT
case (curr_state)
1'b0: begin
if (~FIFOEMPTY)
next_state <= 1'b1;
else
next_state <= 1'b0;
end
1'b1: begin
if (FIFOEMPTY && RD_EN)
next_state <= 1'b0;
else
next_state <= 1'b1;
end
default: next_state <= 1'b0;
endcase
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_i <= 1'b1;
empty_i_q <= 1'b1;
ram_valid_i <= 1'b0;
end else if (srst_i) begin
empty_i <= #`TCQ 1'b1;
empty_i_q <= #`TCQ 1'b1;
ram_valid_i <= #`TCQ 1'b0;
end else begin
empty_i <= #`TCQ going_empty_fwft | (~leaving_empty_fwft & empty_i);
empty_i_q <= #`TCQ FIFOEMPTY;
ram_valid_i <= #`TCQ next_state;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
curr_state <= 1'b0;
end else if (srst_i) begin
curr_state <= #`TCQ 1'b0;
end else begin
curr_state <= #`TCQ next_state;
end
end //always
wire fe_of_empty;
assign fe_of_empty = empty_i_q & ~FIFOEMPTY;
always @* begin // Finding leaving empty
case (curr_state)
1'b0: leaving_empty_fwft <= fe_of_empty;
1'b1: leaving_empty_fwft <= 1'b1;
default: leaving_empty_fwft <= 1'b0;
endcase
end
always @* begin // Finding going empty
case (curr_state)
1'b1: going_empty_fwft <= FIFOEMPTY & RD_EN;
default: going_empty_fwft <= 1'b0;
endcase
end
always @* begin // Generating FWFT rd_en
case (curr_state)
1'b0: ram_rd_en_fwft <= ~FIFOEMPTY;
1'b1: ram_rd_en_fwft <= ~FIFOEMPTY & RD_EN;
default: ram_rd_en_fwft <= 1'b0;
endcase
end
assign ram_regout_en = ram_rd_en_fwft;
//assign ram_regout_en_d1 = ram_rd_en_fwft;
//assign ram_regout_en_d2 = ram_rd_en_fwft;
assign ram_rd_en = ram_rd_en_fwft;
end endgenerate // gll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false.
// Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2) begin : gnll_fifo_ram_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (ram_rd_en == 1'b1) begin
ram_valid_i <= #`TCQ 1'b1;
end else begin
if (ram_regout_en == 1'b1)
ram_valid_i <= #`TCQ 1'b0;
else
ram_valid_i <= #`TCQ ram_valid_i;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_ram_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ ram_valid_i | (read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG < 3) begin : gnll_fifo_empty
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~ram_valid_i & ~read_data_valid_i) | (~ram_valid_i & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
generate if ( C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((ram_regout_en) | (~FIFOEMPTY & read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ FIFOEMPTY;
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
// BRAM resets synchronously
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG < 3) begin
always @ ( posedge rd_rst_i)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
//safety ckt with one register
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
//@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay
if (rd_rst_i == 1) begin
ram_regout_en_d1 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d1 <= #`TCQ 1'b0;
else
ram_regout_en_d1 <= #`TCQ ram_regout_en;
end
end //always
// assign fab_regout_en = ((ram_regout_en_d1 & ~(ram_regout_en_d2) & empty_i) | (RD_EN & !empty_i));
assign fab_regout_en = ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b0 )? 1'b1: ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1) ? RD_EN : 1'b0;
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay1
if (rd_rst_i == 1) begin
ram_regout_en_d2 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d2 <= #`TCQ 1'b0;
else
ram_regout_en_d2 <= #`TCQ ram_regout_en_d1;
end
end //always
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
always @ (posedge RD_CLK) begin
ram_valid_i_d <= #`TCQ ram_valid_i;
read_data_valid_i_d <= #`TCQ read_data_valid_i;
fab_read_data_valid_i_d <= #`TCQ fab_read_data_valid_i;
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = (ram_valid_i == 1'b1 && (read_data_valid_i == 1'b0 || fab_read_data_valid_i == 1'b0)) ? 1'b1 : (read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1 && ram_valid_i == 1'b1) ? RD_EN : 1'b0;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = ((RD_EN | ~ fab_read_data_valid_i) & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false // Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3) begin : gnll_fifo_fab_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (ram_regout_en == 1'b1) begin
fab_valid <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
fab_valid <= #`TCQ 1'b0;
else
fab_valid <= #`TCQ fab_valid;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_fab_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG == 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else begin
if (ram_regout_en == 1'b1) begin
read_data_valid_i <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ read_data_valid_i;
end
end
end //always
end
endgenerate
//generate if(C_USE_EMBEDDED_REG == 3) begin
// always @ (posedge RD_CLK or posedge rd_rst_i) begin
// if (rd_rst_i)
// read_data_valid_i <= #`TCQ 1'b0;
// else if (srst_i)
// read_data_valid_i <= #`TCQ 1'b0;
//
// if (ram_regout_en == 1'b1) begin
// fab_read_data_valid_i <= #`TCQ 1'b0;
// end else begin
// if (fab_regout_en == 1'b1)
// fab_read_data_valid_i <= #`TCQ 1'b1;
// else
// fab_read_data_valid_i <= #`TCQ fab_read_data_valid_i;
// end
// end //always
//end
//endgenerate
generate if(C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin :fabout_dvalid
if (rd_rst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else
fab_read_data_valid_i <= #`TCQ fab_valid | (fab_read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
always @ (posedge RD_CLK ) begin : proc_del1
begin
fab_read_data_valid_i_1 <= #`TCQ fab_read_data_valid_i;
end
end //always
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3 ) begin : gnll_fifo_empty_both
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~fab_valid & ~fab_read_data_valid_i) | (~fab_valid & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty_both
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
reg FIFOEMPTY_1;
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @(posedge RD_CLK) begin
FIFOEMPTY_1 <= #`TCQ FIFOEMPTY;
end
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((fab_regout_en) | (ram_valid_i & fab_read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ (~ram_valid_i);
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_sckt <= #`TCQ 1'b1;
sckt_rrst_q <= #`TCQ 1'b0;
sckt_rrst_done <= #`TCQ 1'b0;
end else begin
sckt_rrst_q <= #`TCQ SAFETY_CKT_RD_RST;
if (sckt_rrst_q && ~SAFETY_CKT_RD_RST) begin
sckt_rrst_done <= #`TCQ 1'b1;
end else if (sckt_rrst_done) begin
// rising clock edge
empty_sckt <= #`TCQ 1'b0;
end
end
end //always
// assign USEREMPTY = C_EN_SAFETY_CKT ? (sckt_rrst_done ? empty_i : empty_sckt) : empty_i;
assign USEREMPTY = empty_i;
assign USERALMOSTEMPTY = almost_empty_i;
assign FIFORDEN = ram_rd_en;
assign RAMVALID = (C_USE_EMBEDDED_REG == 3)? fab_valid : ram_valid_i;
assign uservalid_both = (C_USERVALID_LOW && C_USE_EMBEDDED_REG == 3) ? ~fab_read_data_valid_i : ((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG == 3) ? fab_read_data_valid_i : 1'b0);
assign uservalid_one = (C_USERVALID_LOW && C_USE_EMBEDDED_REG < 3) ? ~read_data_valid_i :((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG < 3) ? read_data_valid_i : 1'b0);
assign USERVALID = (C_USE_EMBEDDED_REG == 3) ? uservalid_both : uservalid_one;
assign USERUNDERFLOW = C_USERUNDERFLOW_LOW ? ~(empty_q & rd_en_q) : empty_q & rd_en_q;
//no safety ckt with both reg
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin
if (fwft_rst_done) begin
if (ram_regout_en) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end
end //always
end //if
endgenerate
//safety_ckt with both registers
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK) begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end //always
end //if
endgenerate
endmodule //fifo_generator_v13_1_3_bhv_ver_preload0
//-----------------------------------------------------------------------------
//
// Register Slice
// Register one AXI channel on forward and/or reverse signal path
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// reg_slice
//
//--------------------------------------------------------------------------
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
input wire S_VALID,
output wire S_READY,
// Master side
output wire [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA,
output wire M_VALID,
input wire M_READY
);
generate
////////////////////////////////////////////////////////////////////
//
// Both FWD and REV mode
//
////////////////////////////////////////////////////////////////////
if (C_REG_CONFIG == 32'h00000000)
begin
reg [1:0] state;
localparam [1:0]
ZERO = 2'b10,
ONE = 2'b11,
TWO = 2'b01;
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg [C_DATA_WIDTH-1:0] storage_data2 = 0;
reg load_s1;
wire load_s2;
wire load_s1_from_s2;
reg s_ready_i; //local signal of output
wire m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with either slave side data or from storage2
always @(posedge ACLK)
begin
if (load_s1)
if (load_s1_from_s2)
storage_data1 <= storage_data2;
else
storage_data1 <= S_PAYLOAD_DATA;
end
// Load storage2 with slave side data
always @(posedge ACLK)
begin
if (load_s2)
storage_data2 <= S_PAYLOAD_DATA;
end
assign M_PAYLOAD_DATA = storage_data1;
// Always load s2 on a valid transaction even if it's unnecessary
assign load_s2 = S_VALID & s_ready_i;
// Loading s1
always @ *
begin
if ( ((state == ZERO) && (S_VALID == 1)) || // Load when empty on slave transaction
// Load when ONE if we both have read and write at the same time
((state == ONE) && (S_VALID == 1) && (M_READY == 1)) ||
// Load when TWO and we have a transaction on Master side
((state == TWO) && (M_READY == 1)))
load_s1 = 1'b1;
else
load_s1 = 1'b0;
end // always @ *
assign load_s1_from_s2 = (state == TWO);
// State Machine for handling output signals
always @(posedge ACLK) begin
if (ARESET) begin
s_ready_i <= 1'b0;
state <= ZERO;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else begin
case (state)
// No transaction stored locally
ZERO: if (S_VALID) state <= ONE; // Got one so move to ONE
// One transaction stored locally
ONE: begin
if (M_READY & ~S_VALID) state <= ZERO; // Read out one so move to ZERO
if (~M_READY & S_VALID) begin
state <= TWO; // Got another one so move to TWO
s_ready_i <= 1'b0;
end
end
// TWO transaction stored locally
TWO: if (M_READY) begin
state <= ONE; // Read out one so move to ONE
s_ready_i <= 1'b1;
end
endcase // case (state)
end
end // always @ (posedge ACLK)
assign m_valid_i = state[0];
end // if (C_REG_CONFIG == 1)
////////////////////////////////////////////////////////////////////
//
// 1-stage pipeline register with bubble cycle, both FWD and REV pipelining
// Operates same as 1-deep FIFO
//
////////////////////////////////////////////////////////////////////
else if (C_REG_CONFIG == 32'h00000001)
begin
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg s_ready_i; //local signal of output
reg m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with slave side data
always @(posedge ACLK)
begin
if (ARESET) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b0;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else if (m_valid_i & M_READY) begin
s_ready_i <= 1'b1;
m_valid_i <= 1'b0;
end else if (S_VALID & s_ready_i) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b1;
end
if (~m_valid_i) begin
storage_data1 <= S_PAYLOAD_DATA;
end
end
assign M_PAYLOAD_DATA = storage_data1;
end // if (C_REG_CONFIG == 7)
else begin : default_case
// Passthrough
assign M_PAYLOAD_DATA = S_PAYLOAD_DATA;
assign M_VALID = S_VALID;
assign S_READY = M_READY;
end
endgenerate
endmodule // reg_slice
|
/*
*******************************************************************************
*
* FIFO Generator - Verilog Behavioral Model
*
*******************************************************************************
*
* (c) Copyright 1995 - 2009 Xilinx, Inc. All rights reserved.
*
* This file contains confidential and proprietary information
* of Xilinx, Inc. and is protected under U.S. and
* international copyright and other intellectual property
* laws.
*
* DISCLAIMER
* This disclaimer is not a license and does not grant any
* rights to the materials distributed herewith. Except as
* otherwise provided in a valid license issued to you by
* Xilinx, and to the maximum extent permitted by applicable
* law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
* WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
* AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
* BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
* INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
* (2) Xilinx shall not be liable (whether in contract or tort,
* including negligence, or under any other theory of
* liability) for any loss or damage of any kind or nature
* related to, arising under or in connection with these
* materials, including for any direct, or any indirect,
* special, incidental, or consequential loss or damage
* (including loss of data, profits, goodwill, or any type of
* loss or damage suffered as a result of any action brought
* by a third party) even if such damage or loss was
* reasonably foreseeable or Xilinx had been advised of the
* possibility of the same.
*
* CRITICAL APPLICATIONS
* Xilinx products are not designed or intended to be fail-
* safe, or for use in any application requiring fail-safe
* performance, such as life-support or safety devices or
* systems, Class III medical devices, nuclear facilities,
* applications related to the deployment of airbags, or any
* other applications that could lead to death, personal
* injury, or severe property or environmental damage
* (individually and collectively, "Critical
* Applications"). Customer assumes the sole risk and
* liability of any use of Xilinx products in Critical
* Applications, subject only to applicable laws and
* regulations governing limitations on product liability.
*
* THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
* PART OF THIS FILE AT ALL TIMES.
*
*******************************************************************************
*******************************************************************************
*
* Filename: fifo_generator_vlog_beh.v
*
* Author : Xilinx
*
*******************************************************************************
* Structure:
*
* fifo_generator_vlog_beh.v
* |
* +-fifo_generator_v13_1_3_bhv_ver_as
* |
* +-fifo_generator_v13_1_3_bhv_ver_ss
* |
* +-fifo_generator_v13_1_3_bhv_ver_preload0
*
*******************************************************************************
* Description:
*
* The Verilog behavioral model for the FIFO Generator.
*
* The behavioral model has three parts:
* - The behavioral model for independent clocks FIFOs (_as)
* - The behavioral model for common clock FIFOs (_ss)
* - The "preload logic" block which implements First-word Fall-through
*
*******************************************************************************
* Description:
* The verilog behavioral model for the FIFO generator core.
*
*******************************************************************************
*/
`timescale 1ps/1ps
`ifndef TCQ
`define TCQ 100
`endif
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "",
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 1,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "4kx4",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_PIPELINE_REG = 0,
parameter C_POWER_SAVING_MODE = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface, 1: AXI4 Stream, 2: AXI4/AXI3
parameter C_AXI_TYPE = 0, // 1: AXI4, 2: AXI4 Lite, 3: AXI3
parameter C_HAS_AXI_WR_CHANNEL = 0,
parameter C_HAS_AXI_RD_CHANNEL = 0,
parameter C_HAS_SLAVE_CE = 0,
parameter C_HAS_MASTER_CE = 0,
parameter C_ADD_NGC_CONSTRAINT = 0,
parameter C_USE_COMMON_UNDERFLOW = 0,
parameter C_USE_COMMON_OVERFLOW = 0,
parameter C_USE_DEFAULT_SETTINGS = 0,
// AXI Full/Lite
parameter C_AXI_ID_WIDTH = 0,
parameter C_AXI_ADDR_WIDTH = 0,
parameter C_AXI_DATA_WIDTH = 0,
parameter C_AXI_LEN_WIDTH = 8,
parameter C_AXI_LOCK_WIDTH = 2,
parameter C_HAS_AXI_ID = 0,
parameter C_HAS_AXI_AWUSER = 0,
parameter C_HAS_AXI_WUSER = 0,
parameter C_HAS_AXI_BUSER = 0,
parameter C_HAS_AXI_ARUSER = 0,
parameter C_HAS_AXI_RUSER = 0,
parameter C_AXI_ARUSER_WIDTH = 0,
parameter C_AXI_AWUSER_WIDTH = 0,
parameter C_AXI_WUSER_WIDTH = 0,
parameter C_AXI_BUSER_WIDTH = 0,
parameter C_AXI_RUSER_WIDTH = 0,
// AXI Streaming
parameter C_HAS_AXIS_TDATA = 0,
parameter C_HAS_AXIS_TID = 0,
parameter C_HAS_AXIS_TDEST = 0,
parameter C_HAS_AXIS_TUSER = 0,
parameter C_HAS_AXIS_TREADY = 0,
parameter C_HAS_AXIS_TLAST = 0,
parameter C_HAS_AXIS_TSTRB = 0,
parameter C_HAS_AXIS_TKEEP = 0,
parameter C_AXIS_TDATA_WIDTH = 1,
parameter C_AXIS_TID_WIDTH = 1,
parameter C_AXIS_TDEST_WIDTH = 1,
parameter C_AXIS_TUSER_WIDTH = 1,
parameter C_AXIS_TSTRB_WIDTH = 1,
parameter C_AXIS_TKEEP_WIDTH = 1,
// AXI Channel Type
// WACH --> Write Address Channel
// WDCH --> Write Data Channel
// WRCH --> Write Response Channel
// RACH --> Read Address Channel
// RDCH --> Read Data Channel
// AXIS --> AXI Streaming
parameter C_WACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logic
parameter C_WDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_WRCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_AXIS_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
// AXI Implementation Type
// 1 = Common Clock Block RAM FIFO
// 2 = Common Clock Distributed RAM FIFO
// 11 = Independent Clock Block RAM FIFO
// 12 = Independent Clock Distributed RAM FIFO
parameter C_IMPLEMENTATION_TYPE_WACH = 0,
parameter C_IMPLEMENTATION_TYPE_WDCH = 0,
parameter C_IMPLEMENTATION_TYPE_WRCH = 0,
parameter C_IMPLEMENTATION_TYPE_RACH = 0,
parameter C_IMPLEMENTATION_TYPE_RDCH = 0,
parameter C_IMPLEMENTATION_TYPE_AXIS = 0,
// AXI FIFO Type
// 0 = Data FIFO
// 1 = Packet FIFO
// 2 = Low Latency Sync FIFO
// 3 = Low Latency Async FIFO
parameter C_APPLICATION_TYPE_WACH = 0,
parameter C_APPLICATION_TYPE_WDCH = 0,
parameter C_APPLICATION_TYPE_WRCH = 0,
parameter C_APPLICATION_TYPE_RACH = 0,
parameter C_APPLICATION_TYPE_RDCH = 0,
parameter C_APPLICATION_TYPE_AXIS = 0,
// AXI Built-in FIFO Primitive Type
// 512x36, 1kx18, 2kx9, 4kx4, etc
parameter C_PRIM_FIFO_TYPE_WACH = "512x36",
parameter C_PRIM_FIFO_TYPE_WDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_WRCH = "512x36",
parameter C_PRIM_FIFO_TYPE_RACH = "512x36",
parameter C_PRIM_FIFO_TYPE_RDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_AXIS = "512x36",
// Enable ECC
// 0 = ECC disabled
// 1 = ECC enabled
parameter C_USE_ECC_WACH = 0,
parameter C_USE_ECC_WDCH = 0,
parameter C_USE_ECC_WRCH = 0,
parameter C_USE_ECC_RACH = 0,
parameter C_USE_ECC_RDCH = 0,
parameter C_USE_ECC_AXIS = 0,
// ECC Error Injection Type
// 0 = No Error Injection
// 1 = Single Bit Error Injection
// 2 = Double Bit Error Injection
// 3 = Single Bit and Double Bit Error Injection
parameter C_ERROR_INJECTION_TYPE_WACH = 0,
parameter C_ERROR_INJECTION_TYPE_WDCH = 0,
parameter C_ERROR_INJECTION_TYPE_WRCH = 0,
parameter C_ERROR_INJECTION_TYPE_RACH = 0,
parameter C_ERROR_INJECTION_TYPE_RDCH = 0,
parameter C_ERROR_INJECTION_TYPE_AXIS = 0,
// Input Data Width
// Accumulation of all AXI input signal's width
parameter C_DIN_WIDTH_WACH = 1,
parameter C_DIN_WIDTH_WDCH = 1,
parameter C_DIN_WIDTH_WRCH = 1,
parameter C_DIN_WIDTH_RACH = 1,
parameter C_DIN_WIDTH_RDCH = 1,
parameter C_DIN_WIDTH_AXIS = 1,
parameter C_WR_DEPTH_WACH = 16,
parameter C_WR_DEPTH_WDCH = 16,
parameter C_WR_DEPTH_WRCH = 16,
parameter C_WR_DEPTH_RACH = 16,
parameter C_WR_DEPTH_RDCH = 16,
parameter C_WR_DEPTH_AXIS = 16,
parameter C_WR_PNTR_WIDTH_WACH = 4,
parameter C_WR_PNTR_WIDTH_WDCH = 4,
parameter C_WR_PNTR_WIDTH_WRCH = 4,
parameter C_WR_PNTR_WIDTH_RACH = 4,
parameter C_WR_PNTR_WIDTH_RDCH = 4,
parameter C_WR_PNTR_WIDTH_AXIS = 4,
parameter C_HAS_DATA_COUNTS_WACH = 0,
parameter C_HAS_DATA_COUNTS_WDCH = 0,
parameter C_HAS_DATA_COUNTS_WRCH = 0,
parameter C_HAS_DATA_COUNTS_RACH = 0,
parameter C_HAS_DATA_COUNTS_RDCH = 0,
parameter C_HAS_DATA_COUNTS_AXIS = 0,
parameter C_HAS_PROG_FLAGS_WACH = 0,
parameter C_HAS_PROG_FLAGS_WDCH = 0,
parameter C_HAS_PROG_FLAGS_WRCH = 0,
parameter C_HAS_PROG_FLAGS_RACH = 0,
parameter C_HAS_PROG_FLAGS_RDCH = 0,
parameter C_HAS_PROG_FLAGS_AXIS = 0,
parameter C_PROG_FULL_TYPE_WACH = 0,
parameter C_PROG_FULL_TYPE_WDCH = 0,
parameter C_PROG_FULL_TYPE_WRCH = 0,
parameter C_PROG_FULL_TYPE_RACH = 0,
parameter C_PROG_FULL_TYPE_RDCH = 0,
parameter C_PROG_FULL_TYPE_AXIS = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_PROG_EMPTY_TYPE_WACH = 0,
parameter C_PROG_EMPTY_TYPE_WDCH = 0,
parameter C_PROG_EMPTY_TYPE_WRCH = 0,
parameter C_PROG_EMPTY_TYPE_RACH = 0,
parameter C_PROG_EMPTY_TYPE_RDCH = 0,
parameter C_PROG_EMPTY_TYPE_AXIS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_REG_SLICE_MODE_WACH = 0,
parameter C_REG_SLICE_MODE_WDCH = 0,
parameter C_REG_SLICE_MODE_WRCH = 0,
parameter C_REG_SLICE_MODE_RACH = 0,
parameter C_REG_SLICE_MODE_RDCH = 0,
parameter C_REG_SLICE_MODE_AXIS = 0
)
(
//------------------------------------------------------------------------------
// Input and Output Declarations
//------------------------------------------------------------------------------
// Conventional FIFO Interface Signals
input backup,
input backup_marker,
input clk,
input rst,
input srst,
input wr_clk,
input wr_rst,
input rd_clk,
input rd_rst,
input [C_DIN_WIDTH-1:0] din,
input wr_en,
input rd_en,
// Optional inputs
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate,
input int_clk,
input injectdbiterr,
input injectsbiterr,
input sleep,
output [C_DOUT_WIDTH-1:0] dout,
output full,
output almost_full,
output wr_ack,
output overflow,
output empty,
output almost_empty,
output valid,
output underflow,
output [C_DATA_COUNT_WIDTH-1:0] data_count,
output [C_RD_DATA_COUNT_WIDTH-1:0] rd_data_count,
output [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count,
output prog_full,
output prog_empty,
output sbiterr,
output dbiterr,
output wr_rst_busy,
output rd_rst_busy,
// AXI Global Signal
input m_aclk,
input s_aclk,
input s_aresetn,
input s_aclk_en,
input m_aclk_en,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_awlen,
input [3-1:0] s_axi_awsize,
input [2-1:0] s_axi_awburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_awlock,
input [4-1:0] s_axi_awcache,
input [3-1:0] s_axi_awprot,
input [4-1:0] s_axi_awqos,
input [4-1:0] s_axi_awregion,
input [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser,
input s_axi_awvalid,
output s_axi_awready,
input [C_AXI_ID_WIDTH-1:0] s_axi_wid,
input [C_AXI_DATA_WIDTH-1:0] s_axi_wdata,
input [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb,
input s_axi_wlast,
input [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [2-1:0] s_axi_bresp,
output [C_AXI_BUSER_WIDTH-1:0] s_axi_buser,
output s_axi_bvalid,
input s_axi_bready,
// AXI Full/Lite Master Write Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_awlen,
output [3-1:0] m_axi_awsize,
output [2-1:0] m_axi_awburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_awlock,
output [4-1:0] m_axi_awcache,
output [3-1:0] m_axi_awprot,
output [4-1:0] m_axi_awqos,
output [4-1:0] m_axi_awregion,
output [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
output m_axi_awvalid,
input m_axi_awready,
output [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output m_axi_wlast,
output [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
output m_axi_wvalid,
input m_axi_wready,
input [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input [2-1:0] m_axi_bresp,
input [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
input m_axi_bvalid,
output m_axi_bready,
// AXI Full/Lite Slave Read Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_arlen,
input [3-1:0] s_axi_arsize,
input [2-1:0] s_axi_arburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_arlock,
input [4-1:0] s_axi_arcache,
input [3-1:0] s_axi_arprot,
input [4-1:0] s_axi_arqos,
input [4-1:0] s_axi_arregion,
input [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_AXI_DATA_WIDTH-1:0] s_axi_rdata,
output [2-1:0] s_axi_rresp,
output s_axi_rlast,
output [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser,
output s_axi_rvalid,
input s_axi_rready,
// AXI Full/Lite Master Read Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_arlen,
output [3-1:0] m_axi_arsize,
output [2-1:0] m_axi_arburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_arlock,
output [4-1:0] m_axi_arcache,
output [3-1:0] m_axi_arprot,
output [4-1:0] m_axi_arqos,
output [4-1:0] m_axi_arregion,
output [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
output m_axi_arvalid,
input m_axi_arready,
input [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input [2-1:0] m_axi_rresp,
input m_axi_rlast,
input [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
input m_axi_rvalid,
output m_axi_rready,
// AXI Streaming Slave Signals (Write side)
input s_axis_tvalid,
output s_axis_tready,
input [C_AXIS_TDATA_WIDTH-1:0] s_axis_tdata,
input [C_AXIS_TSTRB_WIDTH-1:0] s_axis_tstrb,
input [C_AXIS_TKEEP_WIDTH-1:0] s_axis_tkeep,
input s_axis_tlast,
input [C_AXIS_TID_WIDTH-1:0] s_axis_tid,
input [C_AXIS_TDEST_WIDTH-1:0] s_axis_tdest,
input [C_AXIS_TUSER_WIDTH-1:0] s_axis_tuser,
// AXI Streaming Master Signals (Read side)
output m_axis_tvalid,
input m_axis_tready,
output [C_AXIS_TDATA_WIDTH-1:0] m_axis_tdata,
output [C_AXIS_TSTRB_WIDTH-1:0] m_axis_tstrb,
output [C_AXIS_TKEEP_WIDTH-1:0] m_axis_tkeep,
output m_axis_tlast,
output [C_AXIS_TID_WIDTH-1:0] m_axis_tid,
output [C_AXIS_TDEST_WIDTH-1:0] m_axis_tdest,
output [C_AXIS_TUSER_WIDTH-1:0] m_axis_tuser,
// AXI Full/Lite Write Address Channel signals
input axi_aw_injectsbiterr,
input axi_aw_injectdbiterr,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_wr_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_rd_data_count,
output axi_aw_sbiterr,
output axi_aw_dbiterr,
output axi_aw_overflow,
output axi_aw_underflow,
output axi_aw_prog_full,
output axi_aw_prog_empty,
// AXI Full/Lite Write Data Channel signals
input axi_w_injectsbiterr,
input axi_w_injectdbiterr,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_wr_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_rd_data_count,
output axi_w_sbiterr,
output axi_w_dbiterr,
output axi_w_overflow,
output axi_w_underflow,
output axi_w_prog_full,
output axi_w_prog_empty,
// AXI Full/Lite Write Response Channel signals
input axi_b_injectsbiterr,
input axi_b_injectdbiterr,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_wr_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_rd_data_count,
output axi_b_sbiterr,
output axi_b_dbiterr,
output axi_b_overflow,
output axi_b_underflow,
output axi_b_prog_full,
output axi_b_prog_empty,
// AXI Full/Lite Read Address Channel signals
input axi_ar_injectsbiterr,
input axi_ar_injectdbiterr,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_wr_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_rd_data_count,
output axi_ar_sbiterr,
output axi_ar_dbiterr,
output axi_ar_overflow,
output axi_ar_underflow,
output axi_ar_prog_full,
output axi_ar_prog_empty,
// AXI Full/Lite Read Data Channel Signals
input axi_r_injectsbiterr,
input axi_r_injectdbiterr,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_wr_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_rd_data_count,
output axi_r_sbiterr,
output axi_r_dbiterr,
output axi_r_overflow,
output axi_r_underflow,
output axi_r_prog_full,
output axi_r_prog_empty,
// AXI Streaming FIFO Related Signals
input axis_injectsbiterr,
input axis_injectdbiterr,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_full_thresh,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_wr_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_rd_data_count,
output axis_sbiterr,
output axis_dbiterr,
output axis_overflow,
output axis_underflow,
output axis_prog_full,
output axis_prog_empty
);
wire BACKUP;
wire BACKUP_MARKER;
wire CLK;
wire RST;
wire SRST;
wire WR_CLK;
wire WR_RST;
wire RD_CLK;
wire RD_RST;
wire [C_DIN_WIDTH-1:0] DIN;
wire WR_EN;
wire RD_EN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire INT_CLK;
wire INJECTDBITERR;
wire INJECTSBITERR;
wire SLEEP;
wire [C_DOUT_WIDTH-1:0] DOUT;
wire FULL;
wire ALMOST_FULL;
wire WR_ACK;
wire OVERFLOW;
wire EMPTY;
wire ALMOST_EMPTY;
wire VALID;
wire UNDERFLOW;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT;
wire PROG_FULL;
wire PROG_EMPTY;
wire SBITERR;
wire DBITERR;
wire WR_RST_BUSY;
wire RD_RST_BUSY;
wire M_ACLK;
wire S_ACLK;
wire S_ARESETN;
wire S_ACLK_EN;
wire M_ACLK_EN;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_AWLEN;
wire [3-1:0] S_AXI_AWSIZE;
wire [2-1:0] S_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_AWLOCK;
wire [4-1:0] S_AXI_AWCACHE;
wire [3-1:0] S_AXI_AWPROT;
wire [4-1:0] S_AXI_AWQOS;
wire [4-1:0] S_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER;
wire S_AXI_AWVALID;
wire S_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB;
wire S_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER;
wire S_AXI_WVALID;
wire S_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [2-1:0] S_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER;
wire S_AXI_BVALID;
wire S_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_AWLEN;
wire [3-1:0] M_AXI_AWSIZE;
wire [2-1:0] M_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_AWLOCK;
wire [4-1:0] M_AXI_AWCACHE;
wire [3-1:0] M_AXI_AWPROT;
wire [4-1:0] M_AXI_AWQOS;
wire [4-1:0] M_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER;
wire M_AXI_AWVALID;
wire M_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB;
wire M_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER;
wire M_AXI_WVALID;
wire M_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID;
wire [2-1:0] M_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER;
wire M_AXI_BVALID;
wire M_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_ARLEN;
wire [3-1:0] S_AXI_ARSIZE;
wire [2-1:0] S_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_ARLOCK;
wire [4-1:0] S_AXI_ARCACHE;
wire [3-1:0] S_AXI_ARPROT;
wire [4-1:0] S_AXI_ARQOS;
wire [4-1:0] S_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER;
wire S_AXI_ARVALID;
wire S_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA;
wire [2-1:0] S_AXI_RRESP;
wire S_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER;
wire S_AXI_RVALID;
wire S_AXI_RREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_ARLEN;
wire [3-1:0] M_AXI_ARSIZE;
wire [2-1:0] M_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_ARLOCK;
wire [4-1:0] M_AXI_ARCACHE;
wire [3-1:0] M_AXI_ARPROT;
wire [4-1:0] M_AXI_ARQOS;
wire [4-1:0] M_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER;
wire M_AXI_ARVALID;
wire M_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA;
wire [2-1:0] M_AXI_RRESP;
wire M_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER;
wire M_AXI_RVALID;
wire M_AXI_RREADY;
wire S_AXIS_TVALID;
wire S_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] S_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] S_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] S_AXIS_TKEEP;
wire S_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] S_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] S_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] S_AXIS_TUSER;
wire M_AXIS_TVALID;
wire M_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] M_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] M_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] M_AXIS_TKEEP;
wire M_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] M_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] M_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] M_AXIS_TUSER;
wire AXI_AW_INJECTSBITERR;
wire AXI_AW_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_RD_DATA_COUNT;
wire AXI_AW_SBITERR;
wire AXI_AW_DBITERR;
wire AXI_AW_OVERFLOW;
wire AXI_AW_UNDERFLOW;
wire AXI_AW_PROG_FULL;
wire AXI_AW_PROG_EMPTY;
wire AXI_W_INJECTSBITERR;
wire AXI_W_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_RD_DATA_COUNT;
wire AXI_W_SBITERR;
wire AXI_W_DBITERR;
wire AXI_W_OVERFLOW;
wire AXI_W_UNDERFLOW;
wire AXI_W_PROG_FULL;
wire AXI_W_PROG_EMPTY;
wire AXI_B_INJECTSBITERR;
wire AXI_B_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_RD_DATA_COUNT;
wire AXI_B_SBITERR;
wire AXI_B_DBITERR;
wire AXI_B_OVERFLOW;
wire AXI_B_UNDERFLOW;
wire AXI_B_PROG_FULL;
wire AXI_B_PROG_EMPTY;
wire AXI_AR_INJECTSBITERR;
wire AXI_AR_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_RD_DATA_COUNT;
wire AXI_AR_SBITERR;
wire AXI_AR_DBITERR;
wire AXI_AR_OVERFLOW;
wire AXI_AR_UNDERFLOW;
wire AXI_AR_PROG_FULL;
wire AXI_AR_PROG_EMPTY;
wire AXI_R_INJECTSBITERR;
wire AXI_R_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_RD_DATA_COUNT;
wire AXI_R_SBITERR;
wire AXI_R_DBITERR;
wire AXI_R_OVERFLOW;
wire AXI_R_UNDERFLOW;
wire AXI_R_PROG_FULL;
wire AXI_R_PROG_EMPTY;
wire AXIS_INJECTSBITERR;
wire AXIS_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_RD_DATA_COUNT;
wire AXIS_SBITERR;
wire AXIS_DBITERR;
wire AXIS_OVERFLOW;
wire AXIS_UNDERFLOW;
wire AXIS_PROG_FULL;
wire AXIS_PROG_EMPTY;
wire [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count_in;
wire wr_rst_int;
wire rd_rst_int;
wire wr_rst_busy_o;
wire wr_rst_busy_ntve;
wire wr_rst_busy_axis;
wire wr_rst_busy_wach;
wire wr_rst_busy_wdch;
wire wr_rst_busy_wrch;
wire wr_rst_busy_rach;
wire wr_rst_busy_rdch;
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// Conventional FIFO Interface Signals
assign BACKUP = backup;
assign BACKUP_MARKER = backup_marker;
assign CLK = clk;
assign RST = rst;
assign SRST = srst;
assign WR_CLK = wr_clk;
assign WR_RST = wr_rst;
assign RD_CLK = rd_clk;
assign RD_RST = rd_rst;
assign WR_EN = wr_en;
assign RD_EN = rd_en;
assign INT_CLK = int_clk;
assign INJECTDBITERR = injectdbiterr;
assign INJECTSBITERR = injectsbiterr;
assign SLEEP = sleep;
assign full = FULL;
assign almost_full = ALMOST_FULL;
assign wr_ack = WR_ACK;
assign overflow = OVERFLOW;
assign empty = EMPTY;
assign almost_empty = ALMOST_EMPTY;
assign valid = VALID;
assign underflow = UNDERFLOW;
assign prog_full = PROG_FULL;
assign prog_empty = PROG_EMPTY;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
// assign wr_rst_busy = WR_RST_BUSY | wr_rst_busy_o;
assign wr_rst_busy = wr_rst_busy_o;
assign rd_rst_busy = RD_RST_BUSY;
assign M_ACLK = m_aclk;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_ACLK_EN = s_aclk_en;
assign M_ACLK_EN = m_aclk_en;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign m_axi_awvalid = M_AXI_AWVALID;
assign M_AXI_AWREADY = m_axi_awready;
assign m_axi_wlast = M_AXI_WLAST;
assign m_axi_wvalid = M_AXI_WVALID;
assign M_AXI_WREADY = m_axi_wready;
assign M_AXI_BVALID = m_axi_bvalid;
assign m_axi_bready = M_AXI_BREADY;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign m_axi_arvalid = M_AXI_ARVALID;
assign M_AXI_ARREADY = m_axi_arready;
assign M_AXI_RLAST = m_axi_rlast;
assign M_AXI_RVALID = m_axi_rvalid;
assign m_axi_rready = M_AXI_RREADY;
assign S_AXIS_TVALID = s_axis_tvalid;
assign s_axis_tready = S_AXIS_TREADY;
assign S_AXIS_TLAST = s_axis_tlast;
assign m_axis_tvalid = M_AXIS_TVALID;
assign M_AXIS_TREADY = m_axis_tready;
assign m_axis_tlast = M_AXIS_TLAST;
assign AXI_AW_INJECTSBITERR = axi_aw_injectsbiterr;
assign AXI_AW_INJECTDBITERR = axi_aw_injectdbiterr;
assign axi_aw_sbiterr = AXI_AW_SBITERR;
assign axi_aw_dbiterr = AXI_AW_DBITERR;
assign axi_aw_overflow = AXI_AW_OVERFLOW;
assign axi_aw_underflow = AXI_AW_UNDERFLOW;
assign axi_aw_prog_full = AXI_AW_PROG_FULL;
assign axi_aw_prog_empty = AXI_AW_PROG_EMPTY;
assign AXI_W_INJECTSBITERR = axi_w_injectsbiterr;
assign AXI_W_INJECTDBITERR = axi_w_injectdbiterr;
assign axi_w_sbiterr = AXI_W_SBITERR;
assign axi_w_dbiterr = AXI_W_DBITERR;
assign axi_w_overflow = AXI_W_OVERFLOW;
assign axi_w_underflow = AXI_W_UNDERFLOW;
assign axi_w_prog_full = AXI_W_PROG_FULL;
assign axi_w_prog_empty = AXI_W_PROG_EMPTY;
assign AXI_B_INJECTSBITERR = axi_b_injectsbiterr;
assign AXI_B_INJECTDBITERR = axi_b_injectdbiterr;
assign axi_b_sbiterr = AXI_B_SBITERR;
assign axi_b_dbiterr = AXI_B_DBITERR;
assign axi_b_overflow = AXI_B_OVERFLOW;
assign axi_b_underflow = AXI_B_UNDERFLOW;
assign axi_b_prog_full = AXI_B_PROG_FULL;
assign axi_b_prog_empty = AXI_B_PROG_EMPTY;
assign AXI_AR_INJECTSBITERR = axi_ar_injectsbiterr;
assign AXI_AR_INJECTDBITERR = axi_ar_injectdbiterr;
assign axi_ar_sbiterr = AXI_AR_SBITERR;
assign axi_ar_dbiterr = AXI_AR_DBITERR;
assign axi_ar_overflow = AXI_AR_OVERFLOW;
assign axi_ar_underflow = AXI_AR_UNDERFLOW;
assign axi_ar_prog_full = AXI_AR_PROG_FULL;
assign axi_ar_prog_empty = AXI_AR_PROG_EMPTY;
assign AXI_R_INJECTSBITERR = axi_r_injectsbiterr;
assign AXI_R_INJECTDBITERR = axi_r_injectdbiterr;
assign axi_r_sbiterr = AXI_R_SBITERR;
assign axi_r_dbiterr = AXI_R_DBITERR;
assign axi_r_overflow = AXI_R_OVERFLOW;
assign axi_r_underflow = AXI_R_UNDERFLOW;
assign axi_r_prog_full = AXI_R_PROG_FULL;
assign axi_r_prog_empty = AXI_R_PROG_EMPTY;
assign AXIS_INJECTSBITERR = axis_injectsbiterr;
assign AXIS_INJECTDBITERR = axis_injectdbiterr;
assign axis_sbiterr = AXIS_SBITERR;
assign axis_dbiterr = AXIS_DBITERR;
assign axis_overflow = AXIS_OVERFLOW;
assign axis_underflow = AXIS_UNDERFLOW;
assign axis_prog_full = AXIS_PROG_FULL;
assign axis_prog_empty = AXIS_PROG_EMPTY;
assign DIN = din;
assign PROG_EMPTY_THRESH = prog_empty_thresh;
assign PROG_EMPTY_THRESH_ASSERT = prog_empty_thresh_assert;
assign PROG_EMPTY_THRESH_NEGATE = prog_empty_thresh_negate;
assign PROG_FULL_THRESH = prog_full_thresh;
assign PROG_FULL_THRESH_ASSERT = prog_full_thresh_assert;
assign PROG_FULL_THRESH_NEGATE = prog_full_thresh_negate;
assign dout = DOUT;
assign data_count = DATA_COUNT;
assign rd_data_count = RD_DATA_COUNT;
assign wr_data_count = WR_DATA_COUNT;
assign S_AXI_AWID = s_axi_awid;
assign S_AXI_AWADDR = s_axi_awaddr;
assign S_AXI_AWLEN = s_axi_awlen;
assign S_AXI_AWSIZE = s_axi_awsize;
assign S_AXI_AWBURST = s_axi_awburst;
assign S_AXI_AWLOCK = s_axi_awlock;
assign S_AXI_AWCACHE = s_axi_awcache;
assign S_AXI_AWPROT = s_axi_awprot;
assign S_AXI_AWQOS = s_axi_awqos;
assign S_AXI_AWREGION = s_axi_awregion;
assign S_AXI_AWUSER = s_axi_awuser;
assign S_AXI_WID = s_axi_wid;
assign S_AXI_WDATA = s_axi_wdata;
assign S_AXI_WSTRB = s_axi_wstrb;
assign S_AXI_WUSER = s_axi_wuser;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_buser = S_AXI_BUSER;
assign m_axi_awid = M_AXI_AWID;
assign m_axi_awaddr = M_AXI_AWADDR;
assign m_axi_awlen = M_AXI_AWLEN;
assign m_axi_awsize = M_AXI_AWSIZE;
assign m_axi_awburst = M_AXI_AWBURST;
assign m_axi_awlock = M_AXI_AWLOCK;
assign m_axi_awcache = M_AXI_AWCACHE;
assign m_axi_awprot = M_AXI_AWPROT;
assign m_axi_awqos = M_AXI_AWQOS;
assign m_axi_awregion = M_AXI_AWREGION;
assign m_axi_awuser = M_AXI_AWUSER;
assign m_axi_wid = M_AXI_WID;
assign m_axi_wdata = M_AXI_WDATA;
assign m_axi_wstrb = M_AXI_WSTRB;
assign m_axi_wuser = M_AXI_WUSER;
assign M_AXI_BID = m_axi_bid;
assign M_AXI_BRESP = m_axi_bresp;
assign M_AXI_BUSER = m_axi_buser;
assign S_AXI_ARID = s_axi_arid;
assign S_AXI_ARADDR = s_axi_araddr;
assign S_AXI_ARLEN = s_axi_arlen;
assign S_AXI_ARSIZE = s_axi_arsize;
assign S_AXI_ARBURST = s_axi_arburst;
assign S_AXI_ARLOCK = s_axi_arlock;
assign S_AXI_ARCACHE = s_axi_arcache;
assign S_AXI_ARPROT = s_axi_arprot;
assign S_AXI_ARQOS = s_axi_arqos;
assign S_AXI_ARREGION = s_axi_arregion;
assign S_AXI_ARUSER = s_axi_aruser;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_ruser = S_AXI_RUSER;
assign m_axi_arid = M_AXI_ARID;
assign m_axi_araddr = M_AXI_ARADDR;
assign m_axi_arlen = M_AXI_ARLEN;
assign m_axi_arsize = M_AXI_ARSIZE;
assign m_axi_arburst = M_AXI_ARBURST;
assign m_axi_arlock = M_AXI_ARLOCK;
assign m_axi_arcache = M_AXI_ARCACHE;
assign m_axi_arprot = M_AXI_ARPROT;
assign m_axi_arqos = M_AXI_ARQOS;
assign m_axi_arregion = M_AXI_ARREGION;
assign m_axi_aruser = M_AXI_ARUSER;
assign M_AXI_RID = m_axi_rid;
assign M_AXI_RDATA = m_axi_rdata;
assign M_AXI_RRESP = m_axi_rresp;
assign M_AXI_RUSER = m_axi_ruser;
assign S_AXIS_TDATA = s_axis_tdata;
assign S_AXIS_TSTRB = s_axis_tstrb;
assign S_AXIS_TKEEP = s_axis_tkeep;
assign S_AXIS_TID = s_axis_tid;
assign S_AXIS_TDEST = s_axis_tdest;
assign S_AXIS_TUSER = s_axis_tuser;
assign m_axis_tdata = M_AXIS_TDATA;
assign m_axis_tstrb = M_AXIS_TSTRB;
assign m_axis_tkeep = M_AXIS_TKEEP;
assign m_axis_tid = M_AXIS_TID;
assign m_axis_tdest = M_AXIS_TDEST;
assign m_axis_tuser = M_AXIS_TUSER;
assign AXI_AW_PROG_FULL_THRESH = axi_aw_prog_full_thresh;
assign AXI_AW_PROG_EMPTY_THRESH = axi_aw_prog_empty_thresh;
assign axi_aw_data_count = AXI_AW_DATA_COUNT;
assign axi_aw_wr_data_count = AXI_AW_WR_DATA_COUNT;
assign axi_aw_rd_data_count = AXI_AW_RD_DATA_COUNT;
assign AXI_W_PROG_FULL_THRESH = axi_w_prog_full_thresh;
assign AXI_W_PROG_EMPTY_THRESH = axi_w_prog_empty_thresh;
assign axi_w_data_count = AXI_W_DATA_COUNT;
assign axi_w_wr_data_count = AXI_W_WR_DATA_COUNT;
assign axi_w_rd_data_count = AXI_W_RD_DATA_COUNT;
assign AXI_B_PROG_FULL_THRESH = axi_b_prog_full_thresh;
assign AXI_B_PROG_EMPTY_THRESH = axi_b_prog_empty_thresh;
assign axi_b_data_count = AXI_B_DATA_COUNT;
assign axi_b_wr_data_count = AXI_B_WR_DATA_COUNT;
assign axi_b_rd_data_count = AXI_B_RD_DATA_COUNT;
assign AXI_AR_PROG_FULL_THRESH = axi_ar_prog_full_thresh;
assign AXI_AR_PROG_EMPTY_THRESH = axi_ar_prog_empty_thresh;
assign axi_ar_data_count = AXI_AR_DATA_COUNT;
assign axi_ar_wr_data_count = AXI_AR_WR_DATA_COUNT;
assign axi_ar_rd_data_count = AXI_AR_RD_DATA_COUNT;
assign AXI_R_PROG_FULL_THRESH = axi_r_prog_full_thresh;
assign AXI_R_PROG_EMPTY_THRESH = axi_r_prog_empty_thresh;
assign axi_r_data_count = AXI_R_DATA_COUNT;
assign axi_r_wr_data_count = AXI_R_WR_DATA_COUNT;
assign axi_r_rd_data_count = AXI_R_RD_DATA_COUNT;
assign AXIS_PROG_FULL_THRESH = axis_prog_full_thresh;
assign AXIS_PROG_EMPTY_THRESH = axis_prog_empty_thresh;
assign axis_data_count = AXIS_DATA_COUNT;
assign axis_wr_data_count = AXIS_WR_DATA_COUNT;
assign axis_rd_data_count = AXIS_RD_DATA_COUNT;
generate if (C_INTERFACE_TYPE == 0) begin : conv_fifo
fifo_generator_v13_1_3_CONV_VER
#(
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_USE_DOUT_RST == 1 ? C_DOUT_RST_VAL : 0),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_FAMILY (C_FAMILY),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RD_RST (C_HAS_RD_RST),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_HAS_WR_RST (C_HAS_WR_RST),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_FREQ (C_RD_FREQ),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE)
)
fifo_generator_v13_1_3_conv_dut
(
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.CLK (CLK),
.RST (RST),
.SRST (SRST),
.WR_CLK (WR_CLK),
.WR_RST (WR_RST),
.RD_CLK (RD_CLK),
.RD_RST (RD_RST),
.DIN (DIN),
.WR_EN (WR_EN),
.RD_EN (RD_EN),
.PROG_EMPTY_THRESH (PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT (PROG_EMPTY_THRESH_ASSERT),
.PROG_EMPTY_THRESH_NEGATE (PROG_EMPTY_THRESH_NEGATE),
.PROG_FULL_THRESH (PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT (PROG_FULL_THRESH_ASSERT),
.PROG_FULL_THRESH_NEGATE (PROG_FULL_THRESH_NEGATE),
.INT_CLK (INT_CLK),
.INJECTDBITERR (INJECTDBITERR),
.INJECTSBITERR (INJECTSBITERR),
.DOUT (DOUT),
.FULL (FULL),
.ALMOST_FULL (ALMOST_FULL),
.WR_ACK (WR_ACK),
.OVERFLOW (OVERFLOW),
.EMPTY (EMPTY),
.ALMOST_EMPTY (ALMOST_EMPTY),
.VALID (VALID),
.UNDERFLOW (UNDERFLOW),
.DATA_COUNT (DATA_COUNT),
.RD_DATA_COUNT (RD_DATA_COUNT),
.WR_DATA_COUNT (wr_data_count_in),
.PROG_FULL (PROG_FULL),
.PROG_EMPTY (PROG_EMPTY),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.wr_rst_busy_o (wr_rst_busy_o),
.wr_rst_busy (wr_rst_busy_i),
.rd_rst_busy (rd_rst_busy),
.wr_rst_i_out (wr_rst_int),
.rd_rst_i_out (rd_rst_int)
);
end endgenerate
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_AXI_SIZE_WIDTH = 3;
localparam C_AXI_BURST_WIDTH = 2;
localparam C_AXI_CACHE_WIDTH = 4;
localparam C_AXI_PROT_WIDTH = 3;
localparam C_AXI_QOS_WIDTH = 4;
localparam C_AXI_REGION_WIDTH = 4;
localparam C_AXI_BRESP_WIDTH = 2;
localparam C_AXI_RRESP_WIDTH = 2;
localparam IS_AXI_STREAMING = C_INTERFACE_TYPE == 1 ? 1 : 0;
localparam TDATA_OFFSET = C_HAS_AXIS_TDATA == 1 ? C_DIN_WIDTH_AXIS-C_AXIS_TDATA_WIDTH : C_DIN_WIDTH_AXIS;
localparam TSTRB_OFFSET = C_HAS_AXIS_TSTRB == 1 ? TDATA_OFFSET-C_AXIS_TSTRB_WIDTH : TDATA_OFFSET;
localparam TKEEP_OFFSET = C_HAS_AXIS_TKEEP == 1 ? TSTRB_OFFSET-C_AXIS_TKEEP_WIDTH : TSTRB_OFFSET;
localparam TID_OFFSET = C_HAS_AXIS_TID == 1 ? TKEEP_OFFSET-C_AXIS_TID_WIDTH : TKEEP_OFFSET;
localparam TDEST_OFFSET = C_HAS_AXIS_TDEST == 1 ? TID_OFFSET-C_AXIS_TDEST_WIDTH : TID_OFFSET;
localparam TUSER_OFFSET = C_HAS_AXIS_TUSER == 1 ? TDEST_OFFSET-C_AXIS_TUSER_WIDTH : TDEST_OFFSET;
localparam LOG_DEPTH_AXIS = find_log2(C_WR_DEPTH_AXIS);
localparam LOG_WR_DEPTH = find_log2(C_WR_DEPTH);
function [LOG_DEPTH_AXIS-1:0] bin2gray;
input [LOG_DEPTH_AXIS-1:0] x;
begin
bin2gray = x ^ (x>>1);
end
endfunction
function [LOG_DEPTH_AXIS-1:0] gray2bin;
input [LOG_DEPTH_AXIS-1:0] x;
integer i;
begin
gray2bin[LOG_DEPTH_AXIS-1] = x[LOG_DEPTH_AXIS-1];
for(i=LOG_DEPTH_AXIS-2; i>=0; i=i-1) begin
gray2bin[i] = gray2bin[i+1] ^ x[i];
end
end
endfunction
wire [(LOG_WR_DEPTH)-1 : 0] w_cnt_gc_asreg_last;
wire [LOG_WR_DEPTH-1 : 0] w_q [0:C_SYNCHRONIZER_STAGE] ;
wire [LOG_WR_DEPTH-1 : 0] w_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_rd = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_gc = 0;
reg [LOG_WR_DEPTH-1 : 0] r_cnt = 0;
wire [LOG_WR_DEPTH : 0] adj_w_cnt_rd_pad;
wire [LOG_WR_DEPTH : 0] r_inv_pad;
wire [LOG_WR_DEPTH-1 : 0] d_cnt;
reg [LOG_WR_DEPTH : 0] d_cnt_pad = 0;
reg adj_w_cnt_rd_pad_0 = 0;
reg r_inv_pad_0 = 0;
genvar l;
generate for (l = 1; ((l <= C_SYNCHRONIZER_STAGE) && (C_HAS_DATA_COUNTS_AXIS == 3 && C_INTERFACE_TYPE == 0) ); l = l + 1) begin : g_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_WR_DEPTH)
)
rd_stg_inst
(
.RST (rd_rst_int),
.CLK (RD_CLK),
.DIN (w_q[l-1]),
.DOUT (w_q[l])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS == 3) begin : fifo_ic_adapter
assign wr_eop_ad = WR_EN & !(FULL);
assign rd_eop_ad = RD_EN & !(EMPTY);
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt <= 1'b0;
else if (wr_eop_ad)
w_cnt <= w_cnt + 1;
end
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt_gc <= 1'b0;
else
w_cnt_gc <= bin2gray(w_cnt);
end
assign w_q[0] = w_cnt_gc;
assign w_cnt_gc_asreg_last = w_q[C_SYNCHRONIZER_STAGE];
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
w_cnt_rd <= 1'b0;
else
w_cnt_rd <= gray2bin(w_cnt_gc_asreg_last);
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
r_cnt <= 1'b0;
else if (rd_eop_ad)
r_cnt <= r_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_w_cnt_rd_pad[LOG_WR_DEPTH : 1] = w_cnt_rd;
assign r_inv_pad[LOG_WR_DEPTH : 1] = ~r_cnt;
assign adj_w_cnt_rd_pad[0] = adj_w_cnt_rd_pad_0;
assign r_inv_pad[0] = r_inv_pad_0;
always @ ( rd_eop_ad )
begin
if (!rd_eop_ad) begin
adj_w_cnt_rd_pad_0 <= 1'b1;
r_inv_pad_0 <= 1'b1;
end else begin
adj_w_cnt_rd_pad_0 <= 1'b0;
r_inv_pad_0 <= 1'b0;
end
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
d_cnt_pad <= 1'b0;
else
d_cnt_pad <= adj_w_cnt_rd_pad + r_inv_pad ;
end
assign d_cnt = d_cnt_pad [LOG_WR_DEPTH : 1] ;
assign WR_DATA_COUNT = d_cnt;
end endgenerate // fifo_ic_adapter
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS != 3) begin : fifo_icn_adapter
assign WR_DATA_COUNT = wr_data_count_in;
end endgenerate // fifo_icn_adapter
wire inverted_reset = ~S_ARESETN;
wire axi_rs_rst;
wire [C_DIN_WIDTH_AXIS-1:0] axis_din ;
wire [C_DIN_WIDTH_AXIS-1:0] axis_dout ;
wire axis_full ;
wire axis_almost_full ;
wire axis_empty ;
wire axis_s_axis_tready;
wire axis_m_axis_tvalid;
wire axis_wr_en ;
wire axis_rd_en ;
wire axis_we ;
wire axis_re ;
wire [C_WR_PNTR_WIDTH_AXIS:0] axis_dc;
reg axis_pkt_read = 1'b0;
wire axis_rd_rst;
wire axis_wr_rst;
generate if (C_INTERFACE_TYPE > 0 && (C_AXIS_TYPE == 1 || C_WACH_TYPE == 1 ||
C_WDCH_TYPE == 1 || C_WRCH_TYPE == 1 || C_RACH_TYPE == 1 || C_RDCH_TYPE == 1)) begin : gaxi_rs_rst
reg rst_d1 = 0 ;
reg rst_d2 = 0 ;
reg [3:0] axi_rst = 4'h0 ;
always @ (posedge inverted_reset or posedge S_ACLK) begin
if (inverted_reset) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
axi_rst <= 4'hf;
end else begin
rst_d1 <= #`TCQ 1'b0;
rst_d2 <= #`TCQ rst_d1;
axi_rst <= #`TCQ {axi_rst[2:0],1'b0};
end
end
assign axi_rs_rst = axi_rst[3];//rst_d2;
end endgenerate // gaxi_rs_rst
generate if (IS_AXI_STREAMING == 1 && C_AXIS_TYPE == 0) begin : axi_streaming
// Write protection when almost full or prog_full is high
assign axis_we = (C_PROG_FULL_TYPE_AXIS != 0) ? axis_s_axis_tready & S_AXIS_TVALID :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_s_axis_tready & S_AXIS_TVALID : S_AXIS_TVALID;
// Read protection when almost empty or prog_empty is high
assign axis_re = (C_PROG_EMPTY_TYPE_AXIS != 0) ? axis_m_axis_tvalid & M_AXIS_TREADY :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_m_axis_tvalid & M_AXIS_TREADY : M_AXIS_TREADY;
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? axis_we & S_ACLK_EN : axis_we;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? axis_re & M_ACLK_EN : axis_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_AXIS == 2 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_AXIS == 11 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_AXIS),
.C_WR_DEPTH (C_WR_DEPTH_AXIS),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_DOUT_WIDTH (C_DIN_WIDTH_AXIS),
.C_RD_DEPTH (C_WR_DEPTH_AXIS),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_AXIS),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_AXIS),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_AXIS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS),
.C_USE_ECC (C_USE_ECC_AXIS),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_AXIS),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (C_APPLICATION_TYPE_AXIS == 1 ? 1: 0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_FIFO_TYPE (C_APPLICATION_TYPE_AXIS == 1 ? 0: C_APPLICATION_TYPE_AXIS),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_axis_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (axis_wr_en),
.RD_EN (axis_rd_en),
.PROG_FULL_THRESH (AXIS_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH (AXIS_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.INJECTDBITERR (AXIS_INJECTDBITERR),
.INJECTSBITERR (AXIS_INJECTSBITERR),
.DIN (axis_din),
.DOUT (axis_dout),
.FULL (axis_full),
.EMPTY (axis_empty),
.ALMOST_FULL (axis_almost_full),
.PROG_FULL (AXIS_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXIS_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (AXIS_OVERFLOW),
.VALID (),
.UNDERFLOW (AXIS_UNDERFLOW),
.DATA_COUNT (axis_dc),
.RD_DATA_COUNT (AXIS_RD_DATA_COUNT),
.WR_DATA_COUNT (AXIS_WR_DATA_COUNT),
.SBITERR (AXIS_SBITERR),
.DBITERR (AXIS_DBITERR),
.wr_rst_busy (wr_rst_busy_axis),
.rd_rst_busy (rd_rst_busy_axis),
.wr_rst_i_out (axis_wr_rst),
.rd_rst_i_out (axis_rd_rst),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign axis_s_axis_tready = (IS_8SERIES == 0) ? ~axis_full : (C_IMPLEMENTATION_TYPE_AXIS == 5 || C_IMPLEMENTATION_TYPE_AXIS == 13) ? ~(axis_full | wr_rst_busy_axis) : ~axis_full;
assign axis_m_axis_tvalid = (C_APPLICATION_TYPE_AXIS != 1) ? ~axis_empty : ~axis_empty & axis_pkt_read;
assign S_AXIS_TREADY = axis_s_axis_tready;
assign M_AXIS_TVALID = axis_m_axis_tvalid;
end endgenerate // axi_streaming
wire axis_wr_eop;
reg axis_wr_eop_d1 = 1'b0;
wire axis_rd_eop;
integer axis_pkt_cnt;
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 1) begin : gaxis_pkt_fifo_cc
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (axis_pkt_cnt == 1) && ~axis_wr_eop_d1)
axis_pkt_read <= 1'b0;
else if ((axis_pkt_cnt > 0) || (axis_almost_full && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_wr_eop_d1 <= 1'b0;
else
axis_wr_eop_d1 <= axis_wr_eop;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_cnt <= 0;
else if (axis_wr_eop_d1 && ~axis_rd_eop)
axis_pkt_cnt <= axis_pkt_cnt + 1;
else if (axis_rd_eop && ~axis_wr_eop_d1)
axis_pkt_cnt <= axis_pkt_cnt - 1;
end
end endgenerate // gaxis_pkt_fifo_cc
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_gc = 0;
wire [(LOG_DEPTH_AXIS)-1 : 0] axis_wpkt_cnt_gc_asreg_last;
wire axis_rd_has_rst;
wire [0:C_SYNCHRONIZER_STAGE] axis_af_q ;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q [0:C_SYNCHRONIZER_STAGE] ;
wire [1:C_SYNCHRONIZER_STAGE] axis_af_q_temp = 0;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_rd = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_rpkt_cnt = 0;
wire [LOG_DEPTH_AXIS : 0] adj_axis_wpkt_cnt_rd_pad;
wire [LOG_DEPTH_AXIS : 0] rpkt_inv_pad;
wire [LOG_DEPTH_AXIS-1 : 0] diff_pkt_cnt;
reg [LOG_DEPTH_AXIS : 0] diff_pkt_cnt_pad = 0;
reg adj_axis_wpkt_cnt_rd_pad_0 = 0;
reg rpkt_inv_pad_0 = 0;
wire axis_af_rd ;
generate if (C_HAS_RST == 1) begin : rst_blk_has
assign axis_rd_has_rst = axis_rd_rst;
end endgenerate //rst_blk_has
generate if (C_HAS_RST == 0) begin :rst_blk_no
assign axis_rd_has_rst = 1'b0;
end endgenerate //rst_blk_no
genvar i;
generate for (i = 1; ((i <= C_SYNCHRONIZER_STAGE) && (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) ); i = i + 1) begin : gpkt_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_DEPTH_AXIS)
)
rd_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (wpkt_q[i-1]),
.DOUT (wpkt_q[i])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (1)
)
wr_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (axis_af_q[i-1]),
.DOUT (axis_af_q[i])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) begin : gaxis_pkt_fifo_ic
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (diff_pkt_cnt == 1))
axis_pkt_read <= 1'b0;
else if ((diff_pkt_cnt > 0) || (axis_af_rd && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt <= 1'b0;
else if (axis_wr_eop)
axis_wpkt_cnt <= axis_wpkt_cnt + 1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt_gc <= 1'b0;
else
axis_wpkt_cnt_gc <= bin2gray(axis_wpkt_cnt);
end
assign wpkt_q[0] = axis_wpkt_cnt_gc;
assign axis_wpkt_cnt_gc_asreg_last = wpkt_q[C_SYNCHRONIZER_STAGE];
assign axis_af_q[0] = axis_almost_full;
//assign axis_af_q[1:C_SYNCHRONIZER_STAGE] = axis_af_q_temp[1:C_SYNCHRONIZER_STAGE];
assign axis_af_rd = axis_af_q[C_SYNCHRONIZER_STAGE];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_wpkt_cnt_rd <= 1'b0;
else
axis_wpkt_cnt_rd <= gray2bin(axis_wpkt_cnt_gc_asreg_last);
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_rpkt_cnt <= 1'b0;
else if (axis_rd_eop)
axis_rpkt_cnt <= axis_rpkt_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_axis_wpkt_cnt_rd_pad[LOG_DEPTH_AXIS : 1] = axis_wpkt_cnt_rd;
assign rpkt_inv_pad[LOG_DEPTH_AXIS : 1] = ~axis_rpkt_cnt;
assign adj_axis_wpkt_cnt_rd_pad[0] = adj_axis_wpkt_cnt_rd_pad_0;
assign rpkt_inv_pad[0] = rpkt_inv_pad_0;
always @ ( axis_rd_eop )
begin
if (!axis_rd_eop) begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b1;
rpkt_inv_pad_0 <= 1'b1;
end else begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b0;
rpkt_inv_pad_0 <= 1'b0;
end
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
diff_pkt_cnt_pad <= 1'b0;
else
diff_pkt_cnt_pad <= adj_axis_wpkt_cnt_rd_pad + rpkt_inv_pad ;
end
assign diff_pkt_cnt = diff_pkt_cnt_pad [LOG_DEPTH_AXIS : 1] ;
end endgenerate // gaxis_pkt_fifo_ic
// Generate the accurate data count for axi stream packet fifo configuration
reg [C_WR_PNTR_WIDTH_AXIS:0] axis_dc_pkt_fifo = 0;
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 1 && C_APPLICATION_TYPE_AXIS == 1) begin : gdc_pkt
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_dc_pkt_fifo <= 0;
else if (axis_wr_en && (~axis_rd_en))
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo + 1;
else if (~axis_wr_en && axis_rd_en)
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo - 1;
end
assign AXIS_DATA_COUNT = axis_dc_pkt_fifo;
end endgenerate // gdc_pkt
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 0 && C_APPLICATION_TYPE_AXIS == 1) begin : gndc_pkt
assign AXIS_DATA_COUNT = 0;
end endgenerate // gndc_pkt
generate if (IS_AXI_STREAMING == 1 && C_APPLICATION_TYPE_AXIS != 1) begin : gdc
assign AXIS_DATA_COUNT = axis_dc;
end endgenerate // gdc
// Register Slice for Write Address Channel
generate if (C_AXIS_TYPE == 1) begin : gaxis_reg_slice
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? S_AXIS_TVALID & S_ACLK_EN : S_AXIS_TVALID;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? M_AXIS_TREADY & M_ACLK_EN : M_AXIS_TREADY;
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_AXIS),
.C_REG_CONFIG (C_REG_SLICE_MODE_AXIS)
)
axis_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (axis_din),
.S_VALID (axis_wr_en),
.S_READY (S_AXIS_TREADY),
// Master side
.M_PAYLOAD_DATA (axis_dout),
.M_VALID (M_AXIS_TVALID),
.M_READY (axis_rd_en)
);
end endgenerate // gaxis_reg_slice
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDATA == 1) begin : tdata
assign axis_din[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET] = S_AXIS_TDATA;
assign M_AXIS_TDATA = axis_dout[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TSTRB == 1) begin : tstrb
assign axis_din[TDATA_OFFSET-1:TSTRB_OFFSET] = S_AXIS_TSTRB;
assign M_AXIS_TSTRB = axis_dout[TDATA_OFFSET-1:TSTRB_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TKEEP == 1) begin : tkeep
assign axis_din[TSTRB_OFFSET-1:TKEEP_OFFSET] = S_AXIS_TKEEP;
assign M_AXIS_TKEEP = axis_dout[TSTRB_OFFSET-1:TKEEP_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TID == 1) begin : tid
assign axis_din[TKEEP_OFFSET-1:TID_OFFSET] = S_AXIS_TID;
assign M_AXIS_TID = axis_dout[TKEEP_OFFSET-1:TID_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDEST == 1) begin : tdest
assign axis_din[TID_OFFSET-1:TDEST_OFFSET] = S_AXIS_TDEST;
assign M_AXIS_TDEST = axis_dout[TID_OFFSET-1:TDEST_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TUSER == 1) begin : tuser
assign axis_din[TDEST_OFFSET-1:TUSER_OFFSET] = S_AXIS_TUSER;
assign M_AXIS_TUSER = axis_dout[TDEST_OFFSET-1:TUSER_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TLAST == 1) begin : tlast
assign axis_din[0] = S_AXIS_TLAST;
assign M_AXIS_TLAST = axis_dout[0];
end endgenerate
//###########################################################################
// AXI FULL Write Channel (axi_write_channel)
//###########################################################################
localparam IS_AXI_FULL = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE != 2)) ? 1 : 0;
localparam IS_AXI_LITE = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE == 2)) ? 1 : 0;
localparam IS_AXI_FULL_WACH = ((IS_AXI_FULL == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WDCH = ((IS_AXI_FULL == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WRCH = ((IS_AXI_FULL == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RACH = ((IS_AXI_FULL == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RDCH = ((IS_AXI_FULL == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WACH = ((IS_AXI_LITE == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WDCH = ((IS_AXI_LITE == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WRCH = ((IS_AXI_LITE == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RACH = ((IS_AXI_LITE == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RDCH = ((IS_AXI_LITE == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_WR_ADDR_CH = ((IS_AXI_FULL_WACH == 1) || (IS_AXI_LITE_WACH == 1)) ? 1 : 0;
localparam IS_WR_DATA_CH = ((IS_AXI_FULL_WDCH == 1) || (IS_AXI_LITE_WDCH == 1)) ? 1 : 0;
localparam IS_WR_RESP_CH = ((IS_AXI_FULL_WRCH == 1) || (IS_AXI_LITE_WRCH == 1)) ? 1 : 0;
localparam IS_RD_ADDR_CH = ((IS_AXI_FULL_RACH == 1) || (IS_AXI_LITE_RACH == 1)) ? 1 : 0;
localparam IS_RD_DATA_CH = ((IS_AXI_FULL_RDCH == 1) || (IS_AXI_LITE_RDCH == 1)) ? 1 : 0;
localparam AWID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WACH;
localparam AWADDR_OFFSET = AWID_OFFSET - C_AXI_ADDR_WIDTH;
localparam AWLEN_OFFSET = C_AXI_TYPE != 2 ? AWADDR_OFFSET - C_AXI_LEN_WIDTH : AWADDR_OFFSET;
localparam AWSIZE_OFFSET = C_AXI_TYPE != 2 ? AWLEN_OFFSET - C_AXI_SIZE_WIDTH : AWLEN_OFFSET;
localparam AWBURST_OFFSET = C_AXI_TYPE != 2 ? AWSIZE_OFFSET - C_AXI_BURST_WIDTH : AWSIZE_OFFSET;
localparam AWLOCK_OFFSET = C_AXI_TYPE != 2 ? AWBURST_OFFSET - C_AXI_LOCK_WIDTH : AWBURST_OFFSET;
localparam AWCACHE_OFFSET = C_AXI_TYPE != 2 ? AWLOCK_OFFSET - C_AXI_CACHE_WIDTH : AWLOCK_OFFSET;
localparam AWPROT_OFFSET = AWCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam AWQOS_OFFSET = AWPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam AWREGION_OFFSET = C_AXI_TYPE == 1 ? AWQOS_OFFSET - C_AXI_REGION_WIDTH : AWQOS_OFFSET;
localparam AWUSER_OFFSET = C_HAS_AXI_AWUSER == 1 ? AWREGION_OFFSET-C_AXI_AWUSER_WIDTH : AWREGION_OFFSET;
localparam WID_OFFSET = (C_AXI_TYPE == 3 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WDCH;
localparam WDATA_OFFSET = WID_OFFSET - C_AXI_DATA_WIDTH;
localparam WSTRB_OFFSET = WDATA_OFFSET - C_AXI_DATA_WIDTH/8;
localparam WUSER_OFFSET = C_HAS_AXI_WUSER == 1 ? WSTRB_OFFSET-C_AXI_WUSER_WIDTH : WSTRB_OFFSET;
localparam BID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WRCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WRCH;
localparam BRESP_OFFSET = BID_OFFSET - C_AXI_BRESP_WIDTH;
localparam BUSER_OFFSET = C_HAS_AXI_BUSER == 1 ? BRESP_OFFSET-C_AXI_BUSER_WIDTH : BRESP_OFFSET;
wire [C_DIN_WIDTH_WACH-1:0] wach_din ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout_pkt ;
wire wach_full ;
wire wach_almost_full ;
wire wach_prog_full ;
wire wach_empty ;
wire wach_almost_empty ;
wire wach_prog_empty ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_din ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_dout ;
wire wdch_full ;
wire wdch_almost_full ;
wire wdch_prog_full ;
wire wdch_empty ;
wire wdch_almost_empty ;
wire wdch_prog_empty ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_din ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_dout ;
wire wrch_full ;
wire wrch_almost_full ;
wire wrch_prog_full ;
wire wrch_empty ;
wire wrch_almost_empty ;
wire wrch_prog_empty ;
wire axi_aw_underflow_i;
wire axi_w_underflow_i ;
wire axi_b_underflow_i ;
wire axi_aw_overflow_i ;
wire axi_w_overflow_i ;
wire axi_b_overflow_i ;
wire axi_wr_underflow_i;
wire axi_wr_overflow_i ;
wire wach_s_axi_awready;
wire wach_m_axi_awvalid;
wire wach_wr_en ;
wire wach_rd_en ;
wire wdch_s_axi_wready ;
wire wdch_m_axi_wvalid ;
wire wdch_wr_en ;
wire wdch_rd_en ;
wire wrch_s_axi_bvalid ;
wire wrch_m_axi_bready ;
wire wrch_wr_en ;
wire wrch_rd_en ;
wire txn_count_up ;
wire txn_count_down ;
wire awvalid_en ;
wire awvalid_pkt ;
wire awready_pkt ;
integer wr_pkt_count ;
wire wach_we ;
wire wach_re ;
wire wdch_we ;
wire wdch_re ;
wire wrch_we ;
wire wrch_re ;
generate if (IS_WR_ADDR_CH == 1) begin : axi_write_address_channel
// Write protection when almost full or prog_full is high
assign wach_we = (C_PROG_FULL_TYPE_WACH != 0) ? wach_s_axi_awready & S_AXI_AWVALID : S_AXI_AWVALID;
// Read protection when almost empty or prog_empty is high
assign wach_re = (C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH == 1) ?
wach_m_axi_awvalid & awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY && wach_m_axi_awvalid :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH == 1) ?
awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY : 1'b0;
assign wach_wr_en = (C_HAS_SLAVE_CE == 1) ? wach_we & S_ACLK_EN : wach_we;
assign wach_rd_en = (C_HAS_MASTER_CE == 1) ? wach_re & M_ACLK_EN : wach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WACH == 2 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WACH == 11 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_DEPTH (C_WR_DEPTH_WACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WACH),
.C_RD_DEPTH (C_WR_DEPTH_WACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH),
.C_USE_ECC (C_USE_ECC_WACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_WACH == 1)?0:C_APPLICATION_TYPE_WACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 : 0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wach_wr_en),
.RD_EN (wach_rd_en),
.PROG_FULL_THRESH (AXI_AW_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AW_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.INJECTDBITERR (AXI_AW_INJECTDBITERR),
.INJECTSBITERR (AXI_AW_INJECTSBITERR),
.DIN (wach_din),
.DOUT (wach_dout_pkt),
.FULL (wach_full),
.EMPTY (wach_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_AW_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_AW_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_aw_overflow_i),
.VALID (),
.UNDERFLOW (axi_aw_underflow_i),
.DATA_COUNT (AXI_AW_DATA_COUNT),
.RD_DATA_COUNT (AXI_AW_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AW_WR_DATA_COUNT),
.SBITERR (AXI_AW_SBITERR),
.DBITERR (AXI_AW_DBITERR),
.wr_rst_busy (wr_rst_busy_wach),
.rd_rst_busy (rd_rst_busy_wach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wach_s_axi_awready = (IS_8SERIES == 0) ? ~wach_full : (C_IMPLEMENTATION_TYPE_WACH == 5 || C_IMPLEMENTATION_TYPE_WACH == 13) ? ~(wach_full | wr_rst_busy_wach) : ~wach_full;
assign wach_m_axi_awvalid = ~wach_empty;
assign S_AXI_AWREADY = wach_s_axi_awready;
assign AXI_AW_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_aw_underflow_i : 0;
assign AXI_AW_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_aw_overflow_i : 0;
end endgenerate // axi_write_address_channel
// Register Slice for Write Address Channel
generate if (C_WACH_TYPE == 1) begin : gwach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WACH)
)
wach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wach_din),
.S_VALID (S_AXI_AWVALID),
.S_READY (S_AXI_AWREADY),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
end endgenerate // gwach_reg_slice
generate if (C_APPLICATION_TYPE_WACH == 1 && C_HAS_AXI_WR_CHANNEL == 1) begin : axi_mm_pkt_fifo_wr
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (1)
)
wach_pkt_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (wach_dout_pkt),
.S_VALID (awvalid_pkt),
.S_READY (awready_pkt),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
assign awvalid_pkt = wach_m_axi_awvalid && awvalid_en;
assign txn_count_up = wdch_s_axi_wready && wdch_wr_en && wdch_din[0];
assign txn_count_down = wach_m_axi_awvalid && awready_pkt && awvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset == 1) begin
wr_pkt_count <= 0;
end else begin
if(txn_count_up == 1 && txn_count_down == 0) begin
wr_pkt_count <= wr_pkt_count + 1;
end else if(txn_count_up == 0 && txn_count_down == 1) begin
wr_pkt_count <= wr_pkt_count - 1;
end
end
end //Always end
assign awvalid_en = (wr_pkt_count > 0)?1:0;
end endgenerate
generate if (C_APPLICATION_TYPE_WACH != 1) begin : axi_mm_fifo_wr
assign awvalid_en = 1;
assign wach_dout = wach_dout_pkt;
assign M_AXI_AWVALID = wach_m_axi_awvalid;
end
endgenerate
generate if (IS_WR_DATA_CH == 1) begin : axi_write_data_channel
// Write protection when almost full or prog_full is high
assign wdch_we = (C_PROG_FULL_TYPE_WDCH != 0) ? wdch_s_axi_wready & S_AXI_WVALID : S_AXI_WVALID;
// Read protection when almost empty or prog_empty is high
assign wdch_re = (C_PROG_EMPTY_TYPE_WDCH != 0) ? wdch_m_axi_wvalid & M_AXI_WREADY : M_AXI_WREADY;
assign wdch_wr_en = (C_HAS_SLAVE_CE == 1) ? wdch_we & S_ACLK_EN : wdch_we;
assign wdch_rd_en = (C_HAS_MASTER_CE == 1) ? wdch_re & M_ACLK_EN : wdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WDCH == 2 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WDCH == 11 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WDCH),
.C_WR_DEPTH (C_WR_DEPTH_WDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WDCH),
.C_RD_DEPTH (C_WR_DEPTH_WDCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH),
.C_USE_ECC (C_USE_ECC_WDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wdch_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wdch_wr_en),
.RD_EN (wdch_rd_en),
.PROG_FULL_THRESH (AXI_W_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_W_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.INJECTDBITERR (AXI_W_INJECTDBITERR),
.INJECTSBITERR (AXI_W_INJECTSBITERR),
.DIN (wdch_din),
.DOUT (wdch_dout),
.FULL (wdch_full),
.EMPTY (wdch_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_W_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_W_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_w_overflow_i),
.VALID (),
.UNDERFLOW (axi_w_underflow_i),
.DATA_COUNT (AXI_W_DATA_COUNT),
.RD_DATA_COUNT (AXI_W_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_W_WR_DATA_COUNT),
.SBITERR (AXI_W_SBITERR),
.DBITERR (AXI_W_DBITERR),
.wr_rst_busy (wr_rst_busy_wdch),
.rd_rst_busy (rd_rst_busy_wdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wdch_s_axi_wready = (IS_8SERIES == 0) ? ~wdch_full : (C_IMPLEMENTATION_TYPE_WDCH == 5 || C_IMPLEMENTATION_TYPE_WDCH == 13) ? ~(wdch_full | wr_rst_busy_wdch) : ~wdch_full;
assign wdch_m_axi_wvalid = ~wdch_empty;
assign S_AXI_WREADY = wdch_s_axi_wready;
assign M_AXI_WVALID = wdch_m_axi_wvalid;
assign AXI_W_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_w_underflow_i : 0;
assign AXI_W_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_w_overflow_i : 0;
end endgenerate // axi_write_data_channel
// Register Slice for Write Data Channel
generate if (C_WDCH_TYPE == 1) begin : gwdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WDCH)
)
wdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wdch_din),
.S_VALID (S_AXI_WVALID),
.S_READY (S_AXI_WREADY),
// Master side
.M_PAYLOAD_DATA (wdch_dout),
.M_VALID (M_AXI_WVALID),
.M_READY (M_AXI_WREADY)
);
end endgenerate // gwdch_reg_slice
generate if (IS_WR_RESP_CH == 1) begin : axi_write_resp_channel
// Write protection when almost full or prog_full is high
assign wrch_we = (C_PROG_FULL_TYPE_WRCH != 0) ? wrch_m_axi_bready & M_AXI_BVALID : M_AXI_BVALID;
// Read protection when almost empty or prog_empty is high
assign wrch_re = (C_PROG_EMPTY_TYPE_WRCH != 0) ? wrch_s_axi_bvalid & S_AXI_BREADY : S_AXI_BREADY;
assign wrch_wr_en = (C_HAS_MASTER_CE == 1) ? wrch_we & M_ACLK_EN : wrch_we;
assign wrch_rd_en = (C_HAS_SLAVE_CE == 1) ? wrch_re & S_ACLK_EN : wrch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WRCH == 2 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WRCH == 11 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WRCH),
.C_WR_DEPTH (C_WR_DEPTH_WRCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WRCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_DEPTH (C_WR_DEPTH_WRCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WRCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WRCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WRCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH),
.C_USE_ECC (C_USE_ECC_WRCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WRCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WRCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wrch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wrch_wr_en),
.RD_EN (wrch_rd_en),
.PROG_FULL_THRESH (AXI_B_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_B_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.INJECTDBITERR (AXI_B_INJECTDBITERR),
.INJECTSBITERR (AXI_B_INJECTSBITERR),
.DIN (wrch_din),
.DOUT (wrch_dout),
.FULL (wrch_full),
.EMPTY (wrch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_B_PROG_FULL),
.PROG_EMPTY (AXI_B_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_b_overflow_i),
.VALID (),
.UNDERFLOW (axi_b_underflow_i),
.DATA_COUNT (AXI_B_DATA_COUNT),
.RD_DATA_COUNT (AXI_B_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_B_WR_DATA_COUNT),
.SBITERR (AXI_B_SBITERR),
.DBITERR (AXI_B_DBITERR),
.wr_rst_busy (wr_rst_busy_wrch),
.rd_rst_busy (rd_rst_busy_wrch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wrch_s_axi_bvalid = ~wrch_empty;
assign wrch_m_axi_bready = (IS_8SERIES == 0) ? ~wrch_full : (C_IMPLEMENTATION_TYPE_WRCH == 5 || C_IMPLEMENTATION_TYPE_WRCH == 13) ? ~(wrch_full | wr_rst_busy_wrch) : ~wrch_full;
assign S_AXI_BVALID = wrch_s_axi_bvalid;
assign M_AXI_BREADY = wrch_m_axi_bready;
assign AXI_B_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_b_underflow_i : 0;
assign AXI_B_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_b_overflow_i : 0;
end endgenerate // axi_write_resp_channel
// Register Slice for Write Response Channel
generate if (C_WRCH_TYPE == 1) begin : gwrch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WRCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WRCH)
)
wrch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wrch_din),
.S_VALID (M_AXI_BVALID),
.S_READY (M_AXI_BREADY),
// Master side
.M_PAYLOAD_DATA (wrch_dout),
.M_VALID (S_AXI_BVALID),
.M_READY (S_AXI_BREADY)
);
end endgenerate // gwrch_reg_slice
assign axi_wr_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_aw_underflow_i || axi_w_underflow_i || axi_b_underflow_i) : 0;
assign axi_wr_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_aw_overflow_i || axi_w_overflow_i || axi_b_overflow_i) : 0;
generate if (IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output
assign M_AXI_AWADDR = wach_dout[AWID_OFFSET-1:AWADDR_OFFSET];
assign M_AXI_AWLEN = wach_dout[AWADDR_OFFSET-1:AWLEN_OFFSET];
assign M_AXI_AWSIZE = wach_dout[AWLEN_OFFSET-1:AWSIZE_OFFSET];
assign M_AXI_AWBURST = wach_dout[AWSIZE_OFFSET-1:AWBURST_OFFSET];
assign M_AXI_AWLOCK = wach_dout[AWBURST_OFFSET-1:AWLOCK_OFFSET];
assign M_AXI_AWCACHE = wach_dout[AWLOCK_OFFSET-1:AWCACHE_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWCACHE_OFFSET-1:AWPROT_OFFSET];
assign M_AXI_AWQOS = wach_dout[AWPROT_OFFSET-1:AWQOS_OFFSET];
assign wach_din[AWID_OFFSET-1:AWADDR_OFFSET] = S_AXI_AWADDR;
assign wach_din[AWADDR_OFFSET-1:AWLEN_OFFSET] = S_AXI_AWLEN;
assign wach_din[AWLEN_OFFSET-1:AWSIZE_OFFSET] = S_AXI_AWSIZE;
assign wach_din[AWSIZE_OFFSET-1:AWBURST_OFFSET] = S_AXI_AWBURST;
assign wach_din[AWBURST_OFFSET-1:AWLOCK_OFFSET] = S_AXI_AWLOCK;
assign wach_din[AWLOCK_OFFSET-1:AWCACHE_OFFSET] = S_AXI_AWCACHE;
assign wach_din[AWCACHE_OFFSET-1:AWPROT_OFFSET] = S_AXI_AWPROT;
assign wach_din[AWPROT_OFFSET-1:AWQOS_OFFSET] = S_AXI_AWQOS;
end endgenerate // axi_wach_output
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_awregion
assign M_AXI_AWREGION = wach_dout[AWQOS_OFFSET-1:AWREGION_OFFSET];
end endgenerate // axi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_awregion
assign M_AXI_AWREGION = 0;
end endgenerate // naxi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : axi_awuser
assign M_AXI_AWUSER = wach_dout[AWREGION_OFFSET-1:AWUSER_OFFSET];
end endgenerate // axi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 0) begin : naxi_awuser
assign M_AXI_AWUSER = 0;
end endgenerate // naxi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_awid
assign M_AXI_AWID = wach_dout[C_DIN_WIDTH_WACH-1:AWID_OFFSET];
end endgenerate //axi_awid
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_awid
assign M_AXI_AWID = 0;
end endgenerate //naxi_awid
generate if (IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output
assign M_AXI_WDATA = wdch_dout[WID_OFFSET-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
assign M_AXI_WLAST = wdch_dout[0];
assign wdch_din[WID_OFFSET-1:WDATA_OFFSET] = S_AXI_WDATA;
assign wdch_din[WDATA_OFFSET-1:WSTRB_OFFSET] = S_AXI_WSTRB;
assign wdch_din[0] = S_AXI_WLAST;
end endgenerate // axi_wdch_output
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin
assign M_AXI_WID = wdch_dout[C_DIN_WIDTH_WDCH-1:WID_OFFSET];
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && (C_HAS_AXI_ID == 0 || C_AXI_TYPE != 3)) begin
assign M_AXI_WID = 0;
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1 ) begin
assign M_AXI_WUSER = wdch_dout[WSTRB_OFFSET-1:WUSER_OFFSET];
end endgenerate
generate if (C_HAS_AXI_WUSER == 0) begin
assign M_AXI_WUSER = 0;
end endgenerate
generate if (IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output
assign S_AXI_BRESP = wrch_dout[BID_OFFSET-1:BRESP_OFFSET];
assign wrch_din[BID_OFFSET-1:BRESP_OFFSET] = M_AXI_BRESP;
end endgenerate // axi_wrch_output
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : axi_buser
assign S_AXI_BUSER = wrch_dout[BRESP_OFFSET-1:BUSER_OFFSET];
end endgenerate // axi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 0) begin : naxi_buser
assign S_AXI_BUSER = 0;
end endgenerate // naxi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_bid
assign S_AXI_BID = wrch_dout[C_DIN_WIDTH_WRCH-1:BID_OFFSET];
end endgenerate // axi_bid
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_bid
assign S_AXI_BID = 0 ;
end endgenerate // naxi_bid
generate if (IS_AXI_LITE_WACH == 1 || (IS_AXI_LITE == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output1
assign wach_din = {S_AXI_AWADDR, S_AXI_AWPROT};
assign M_AXI_AWADDR = wach_dout[C_DIN_WIDTH_WACH-1:AWADDR_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWADDR_OFFSET-1:AWPROT_OFFSET];
end endgenerate // axi_wach_output1
generate if (IS_AXI_LITE_WDCH == 1 || (IS_AXI_LITE == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output1
assign wdch_din = {S_AXI_WDATA, S_AXI_WSTRB};
assign M_AXI_WDATA = wdch_dout[C_DIN_WIDTH_WDCH-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
end endgenerate // axi_wdch_output1
generate if (IS_AXI_LITE_WRCH == 1 || (IS_AXI_LITE == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output1
assign wrch_din = M_AXI_BRESP;
assign S_AXI_BRESP = wrch_dout[C_DIN_WIDTH_WRCH-1:BRESP_OFFSET];
end endgenerate // axi_wrch_output1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : gwach_din1
assign wach_din[AWREGION_OFFSET-1:AWUSER_OFFSET] = S_AXI_AWUSER;
end endgenerate // gwach_din1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwach_din2
assign wach_din[C_DIN_WIDTH_WACH-1:AWID_OFFSET] = S_AXI_AWID;
end endgenerate // gwach_din2
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : gwach_din3
assign wach_din[AWQOS_OFFSET-1:AWREGION_OFFSET] = S_AXI_AWREGION;
end endgenerate // gwach_din3
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1) begin : gwdch_din1
assign wdch_din[WSTRB_OFFSET-1:WUSER_OFFSET] = S_AXI_WUSER;
end endgenerate // gwdch_din1
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin : gwdch_din2
assign wdch_din[C_DIN_WIDTH_WDCH-1:WID_OFFSET] = S_AXI_WID;
end endgenerate // gwdch_din2
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : gwrch_din1
assign wrch_din[BRESP_OFFSET-1:BUSER_OFFSET] = M_AXI_BUSER;
end endgenerate // gwrch_din1
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwrch_din2
assign wrch_din[C_DIN_WIDTH_WRCH-1:BID_OFFSET] = M_AXI_BID;
end endgenerate // gwrch_din2
//end of axi_write_channel
//###########################################################################
// AXI FULL Read Channel (axi_read_channel)
//###########################################################################
wire [C_DIN_WIDTH_RACH-1:0] rach_din ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout_pkt ;
wire rach_full ;
wire rach_almost_full ;
wire rach_prog_full ;
wire rach_empty ;
wire rach_almost_empty ;
wire rach_prog_empty ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_din ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_dout ;
wire rdch_full ;
wire rdch_almost_full ;
wire rdch_prog_full ;
wire rdch_empty ;
wire rdch_almost_empty ;
wire rdch_prog_empty ;
wire axi_ar_underflow_i ;
wire axi_r_underflow_i ;
wire axi_ar_overflow_i ;
wire axi_r_overflow_i ;
wire axi_rd_underflow_i ;
wire axi_rd_overflow_i ;
wire rach_s_axi_arready ;
wire rach_m_axi_arvalid ;
wire rach_wr_en ;
wire rach_rd_en ;
wire rdch_m_axi_rready ;
wire rdch_s_axi_rvalid ;
wire rdch_wr_en ;
wire rdch_rd_en ;
wire arvalid_pkt ;
wire arready_pkt ;
wire arvalid_en ;
wire rdch_rd_ok ;
wire accept_next_pkt ;
integer rdch_free_space ;
integer rdch_commited_space ;
wire rach_we ;
wire rach_re ;
wire rdch_we ;
wire rdch_re ;
localparam ARID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RACH;
localparam ARADDR_OFFSET = ARID_OFFSET - C_AXI_ADDR_WIDTH;
localparam ARLEN_OFFSET = C_AXI_TYPE != 2 ? ARADDR_OFFSET - C_AXI_LEN_WIDTH : ARADDR_OFFSET;
localparam ARSIZE_OFFSET = C_AXI_TYPE != 2 ? ARLEN_OFFSET - C_AXI_SIZE_WIDTH : ARLEN_OFFSET;
localparam ARBURST_OFFSET = C_AXI_TYPE != 2 ? ARSIZE_OFFSET - C_AXI_BURST_WIDTH : ARSIZE_OFFSET;
localparam ARLOCK_OFFSET = C_AXI_TYPE != 2 ? ARBURST_OFFSET - C_AXI_LOCK_WIDTH : ARBURST_OFFSET;
localparam ARCACHE_OFFSET = C_AXI_TYPE != 2 ? ARLOCK_OFFSET - C_AXI_CACHE_WIDTH : ARLOCK_OFFSET;
localparam ARPROT_OFFSET = ARCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam ARQOS_OFFSET = ARPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam ARREGION_OFFSET = C_AXI_TYPE == 1 ? ARQOS_OFFSET - C_AXI_REGION_WIDTH : ARQOS_OFFSET;
localparam ARUSER_OFFSET = C_HAS_AXI_ARUSER == 1 ? ARREGION_OFFSET-C_AXI_ARUSER_WIDTH : ARREGION_OFFSET;
localparam RID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RDCH;
localparam RDATA_OFFSET = RID_OFFSET - C_AXI_DATA_WIDTH;
localparam RRESP_OFFSET = RDATA_OFFSET - C_AXI_RRESP_WIDTH;
localparam RUSER_OFFSET = C_HAS_AXI_RUSER == 1 ? RRESP_OFFSET-C_AXI_RUSER_WIDTH : RRESP_OFFSET;
generate if (IS_RD_ADDR_CH == 1) begin : axi_read_addr_channel
// Write protection when almost full or prog_full is high
assign rach_we = (C_PROG_FULL_TYPE_RACH != 0) ? rach_s_axi_arready & S_AXI_ARVALID : S_AXI_ARVALID;
// Read protection when almost empty or prog_empty is high
// assign rach_rd_en = (C_PROG_EMPTY_TYPE_RACH != 5) ? rach_m_axi_arvalid & M_AXI_ARREADY : M_AXI_ARREADY && arvalid_en;
assign rach_re = (C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH == 1) ?
rach_m_axi_arvalid & arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY && rach_m_axi_arvalid :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH == 1) ?
arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY : 1'b0;
assign rach_wr_en = (C_HAS_SLAVE_CE == 1) ? rach_we & S_ACLK_EN : rach_we;
assign rach_rd_en = (C_HAS_MASTER_CE == 1) ? rach_re & M_ACLK_EN : rach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RACH == 2 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RACH == 11 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RACH),
.C_WR_DEPTH (C_WR_DEPTH_RACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_DOUT_WIDTH (C_DIN_WIDTH_RACH),
.C_RD_DEPTH (C_WR_DEPTH_RACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH),
.C_USE_ECC (C_USE_ECC_RACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_RACH == 1)?0:C_APPLICATION_TYPE_RACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rach_wr_en),
.RD_EN (rach_rd_en),
.PROG_FULL_THRESH (AXI_AR_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AR_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.INJECTDBITERR (AXI_AR_INJECTDBITERR),
.INJECTSBITERR (AXI_AR_INJECTSBITERR),
.DIN (rach_din),
.DOUT (rach_dout_pkt),
.FULL (rach_full),
.EMPTY (rach_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_AR_PROG_FULL),
.PROG_EMPTY (AXI_AR_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_ar_overflow_i),
.VALID (),
.UNDERFLOW (axi_ar_underflow_i),
.DATA_COUNT (AXI_AR_DATA_COUNT),
.RD_DATA_COUNT (AXI_AR_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AR_WR_DATA_COUNT),
.SBITERR (AXI_AR_SBITERR),
.DBITERR (AXI_AR_DBITERR),
.wr_rst_busy (wr_rst_busy_rach),
.rd_rst_busy (rd_rst_busy_rach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rach_s_axi_arready = (IS_8SERIES == 0) ? ~rach_full : (C_IMPLEMENTATION_TYPE_RACH == 5 || C_IMPLEMENTATION_TYPE_RACH == 13) ? ~(rach_full | wr_rst_busy_rach) : ~rach_full;
assign rach_m_axi_arvalid = ~rach_empty;
assign S_AXI_ARREADY = rach_s_axi_arready;
assign AXI_AR_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_ar_underflow_i : 0;
assign AXI_AR_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_ar_overflow_i : 0;
end endgenerate // axi_read_addr_channel
// Register Slice for Read Address Channel
generate if (C_RACH_TYPE == 1) begin : grach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RACH)
)
rach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rach_din),
.S_VALID (S_AXI_ARVALID),
.S_READY (S_AXI_ARREADY),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice
// Register Slice for Read Address Channel for MM Packet FIFO
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH == 1) begin : grach_reg_slice_mm_pkt_fifo
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (1)
)
reg_slice_mm_pkt_fifo_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (rach_dout_pkt),
.S_VALID (arvalid_pkt),
.S_READY (arready_pkt),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice_mm_pkt_fifo
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH != 1) begin : grach_m_axi_arvalid
assign M_AXI_ARVALID = rach_m_axi_arvalid;
assign rach_dout = rach_dout_pkt;
end endgenerate // grach_m_axi_arvalid
generate if (C_APPLICATION_TYPE_RACH == 1 && C_HAS_AXI_RD_CHANNEL == 1) begin : axi_mm_pkt_fifo_rd
assign rdch_rd_ok = rdch_s_axi_rvalid && rdch_rd_en;
assign arvalid_pkt = rach_m_axi_arvalid && arvalid_en;
assign accept_next_pkt = rach_m_axi_arvalid && arready_pkt && arvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset) begin
rdch_commited_space <= 0;
end else begin
if(rdch_rd_ok && !accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space-1;
end else if(!rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1);
end else if(rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]);
end
end
end //Always end
always@(*) begin
rdch_free_space <= (C_WR_DEPTH_RDCH-(rdch_commited_space+rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1));
end
assign arvalid_en = (rdch_free_space >= 0)?1:0;
end
endgenerate
generate if (C_APPLICATION_TYPE_RACH != 1) begin : axi_mm_fifo_rd
assign arvalid_en = 1;
end
endgenerate
generate if (IS_RD_DATA_CH == 1) begin : axi_read_data_channel
// Write protection when almost full or prog_full is high
assign rdch_we = (C_PROG_FULL_TYPE_RDCH != 0) ? rdch_m_axi_rready & M_AXI_RVALID : M_AXI_RVALID;
// Read protection when almost empty or prog_empty is high
assign rdch_re = (C_PROG_EMPTY_TYPE_RDCH != 0) ? rdch_s_axi_rvalid & S_AXI_RREADY : S_AXI_RREADY;
assign rdch_wr_en = (C_HAS_MASTER_CE == 1) ? rdch_we & M_ACLK_EN : rdch_we;
assign rdch_rd_en = (C_HAS_SLAVE_CE == 1) ? rdch_re & S_ACLK_EN : rdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RDCH == 2 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RDCH == 11 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RDCH),
.C_WR_DEPTH (C_WR_DEPTH_RDCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_RDCH),
.C_RD_DEPTH (C_WR_DEPTH_RDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH),
.C_USE_ECC (C_USE_ECC_RDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_RDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rdch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rdch_wr_en),
.RD_EN (rdch_rd_en),
.PROG_FULL_THRESH (AXI_R_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_R_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.INJECTDBITERR (AXI_R_INJECTDBITERR),
.INJECTSBITERR (AXI_R_INJECTSBITERR),
.DIN (rdch_din),
.DOUT (rdch_dout),
.FULL (rdch_full),
.EMPTY (rdch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_R_PROG_FULL),
.PROG_EMPTY (AXI_R_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_r_overflow_i),
.VALID (),
.UNDERFLOW (axi_r_underflow_i),
.DATA_COUNT (AXI_R_DATA_COUNT),
.RD_DATA_COUNT (AXI_R_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_R_WR_DATA_COUNT),
.SBITERR (AXI_R_SBITERR),
.DBITERR (AXI_R_DBITERR),
.wr_rst_busy (wr_rst_busy_rdch),
.rd_rst_busy (rd_rst_busy_rdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rdch_s_axi_rvalid = ~rdch_empty;
assign rdch_m_axi_rready = (IS_8SERIES == 0) ? ~rdch_full : (C_IMPLEMENTATION_TYPE_RDCH == 5 || C_IMPLEMENTATION_TYPE_RDCH == 13) ? ~(rdch_full | wr_rst_busy_rdch) : ~rdch_full;
assign S_AXI_RVALID = rdch_s_axi_rvalid;
assign M_AXI_RREADY = rdch_m_axi_rready;
assign AXI_R_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_r_underflow_i : 0;
assign AXI_R_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_r_overflow_i : 0;
end endgenerate //axi_read_data_channel
// Register Slice for read Data Channel
generate if (C_RDCH_TYPE == 1) begin : grdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RDCH)
)
rdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rdch_din),
.S_VALID (M_AXI_RVALID),
.S_READY (M_AXI_RREADY),
// Master side
.M_PAYLOAD_DATA (rdch_dout),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY)
);
end endgenerate // grdch_reg_slice
assign axi_rd_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_ar_underflow_i || axi_r_underflow_i) : 0;
assign axi_rd_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_ar_overflow_i || axi_r_overflow_i) : 0;
generate if (IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) begin : axi_full_rach_output
assign M_AXI_ARADDR = rach_dout[ARID_OFFSET-1:ARADDR_OFFSET];
assign M_AXI_ARLEN = rach_dout[ARADDR_OFFSET-1:ARLEN_OFFSET];
assign M_AXI_ARSIZE = rach_dout[ARLEN_OFFSET-1:ARSIZE_OFFSET];
assign M_AXI_ARBURST = rach_dout[ARSIZE_OFFSET-1:ARBURST_OFFSET];
assign M_AXI_ARLOCK = rach_dout[ARBURST_OFFSET-1:ARLOCK_OFFSET];
assign M_AXI_ARCACHE = rach_dout[ARLOCK_OFFSET-1:ARCACHE_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARCACHE_OFFSET-1:ARPROT_OFFSET];
assign M_AXI_ARQOS = rach_dout[ARPROT_OFFSET-1:ARQOS_OFFSET];
assign rach_din[ARID_OFFSET-1:ARADDR_OFFSET] = S_AXI_ARADDR;
assign rach_din[ARADDR_OFFSET-1:ARLEN_OFFSET] = S_AXI_ARLEN;
assign rach_din[ARLEN_OFFSET-1:ARSIZE_OFFSET] = S_AXI_ARSIZE;
assign rach_din[ARSIZE_OFFSET-1:ARBURST_OFFSET] = S_AXI_ARBURST;
assign rach_din[ARBURST_OFFSET-1:ARLOCK_OFFSET] = S_AXI_ARLOCK;
assign rach_din[ARLOCK_OFFSET-1:ARCACHE_OFFSET] = S_AXI_ARCACHE;
assign rach_din[ARCACHE_OFFSET-1:ARPROT_OFFSET] = S_AXI_ARPROT;
assign rach_din[ARPROT_OFFSET-1:ARQOS_OFFSET] = S_AXI_ARQOS;
end endgenerate // axi_full_rach_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_arregion
assign M_AXI_ARREGION = rach_dout[ARQOS_OFFSET-1:ARREGION_OFFSET];
end endgenerate // axi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_arregion
assign M_AXI_ARREGION = 0;
end endgenerate // naxi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : axi_aruser
assign M_AXI_ARUSER = rach_dout[ARREGION_OFFSET-1:ARUSER_OFFSET];
end endgenerate // axi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 0) begin : naxi_aruser
assign M_AXI_ARUSER = 0;
end endgenerate // naxi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_arid
assign M_AXI_ARID = rach_dout[C_DIN_WIDTH_RACH-1:ARID_OFFSET];
end endgenerate // axi_arid
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_arid
assign M_AXI_ARID = 0;
end endgenerate // naxi_arid
generate if (IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) begin : axi_full_rdch_output
assign S_AXI_RDATA = rdch_dout[RID_OFFSET-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
assign S_AXI_RLAST = rdch_dout[0];
assign rdch_din[RID_OFFSET-1:RDATA_OFFSET] = M_AXI_RDATA;
assign rdch_din[RDATA_OFFSET-1:RRESP_OFFSET] = M_AXI_RRESP;
assign rdch_din[0] = M_AXI_RLAST;
end endgenerate // axi_full_rdch_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : axi_full_ruser_output
assign S_AXI_RUSER = rdch_dout[RRESP_OFFSET-1:RUSER_OFFSET];
end endgenerate // axi_full_ruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 0) begin : axi_full_nruser_output
assign S_AXI_RUSER = 0;
end endgenerate // axi_full_nruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_rid
assign S_AXI_RID = rdch_dout[C_DIN_WIDTH_RDCH-1:RID_OFFSET];
end endgenerate // axi_rid
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_rid
assign S_AXI_RID = 0;
end endgenerate // naxi_rid
generate if (IS_AXI_LITE_RACH == 1 || (IS_AXI_LITE == 1 && C_RACH_TYPE == 1)) begin : axi_lite_rach_output1
assign rach_din = {S_AXI_ARADDR, S_AXI_ARPROT};
assign M_AXI_ARADDR = rach_dout[C_DIN_WIDTH_RACH-1:ARADDR_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARADDR_OFFSET-1:ARPROT_OFFSET];
end endgenerate // axi_lite_rach_output
generate if (IS_AXI_LITE_RDCH == 1 || (IS_AXI_LITE == 1 && C_RDCH_TYPE == 1)) begin : axi_lite_rdch_output1
assign rdch_din = {M_AXI_RDATA, M_AXI_RRESP};
assign S_AXI_RDATA = rdch_dout[C_DIN_WIDTH_RDCH-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
end endgenerate // axi_lite_rdch_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : grach_din1
assign rach_din[ARREGION_OFFSET-1:ARUSER_OFFSET] = S_AXI_ARUSER;
end endgenerate // grach_din1
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grach_din2
assign rach_din[C_DIN_WIDTH_RACH-1:ARID_OFFSET] = S_AXI_ARID;
end endgenerate // grach_din2
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin
assign rach_din[ARQOS_OFFSET-1:ARREGION_OFFSET] = S_AXI_ARREGION;
end endgenerate
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : grdch_din1
assign rdch_din[RRESP_OFFSET-1:RUSER_OFFSET] = M_AXI_RUSER;
end endgenerate // grdch_din1
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grdch_din2
assign rdch_din[C_DIN_WIDTH_RDCH-1:RID_OFFSET] = M_AXI_RID;
end endgenerate // grdch_din2
//end of axi_read_channel
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_UNDERFLOW == 1) begin : gaxi_comm_uf
assign UNDERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_underflow_i || axi_rd_underflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_underflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_underflow_i : 0;
end endgenerate // gaxi_comm_uf
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_OVERFLOW == 1) begin : gaxi_comm_of
assign OVERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_overflow_i || axi_rd_overflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_overflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_overflow_i : 0;
end endgenerate // gaxi_comm_of
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic or Wiring Logic
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Write Address Channel
generate if (C_WACH_TYPE == 2) begin : gwach_pass_through
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWQOS = S_AXI_AWQOS;
assign M_AXI_AWREGION = S_AXI_AWREGION;
assign M_AXI_AWUSER = S_AXI_AWUSER;
assign S_AXI_AWREADY = M_AXI_AWREADY;
assign M_AXI_AWVALID = S_AXI_AWVALID;
end endgenerate // gwach_pass_through;
// Wiring logic for Write Data Channel
generate if (C_WDCH_TYPE == 2) begin : gwdch_pass_through
assign M_AXI_WID = S_AXI_WID;
assign M_AXI_WDATA = S_AXI_WDATA;
assign M_AXI_WSTRB = S_AXI_WSTRB;
assign M_AXI_WLAST = S_AXI_WLAST;
assign M_AXI_WUSER = S_AXI_WUSER;
assign S_AXI_WREADY = M_AXI_WREADY;
assign M_AXI_WVALID = S_AXI_WVALID;
end endgenerate // gwdch_pass_through;
// Wiring logic for Write Response Channel
generate if (C_WRCH_TYPE == 2) begin : gwrch_pass_through
assign S_AXI_BID = M_AXI_BID;
assign S_AXI_BRESP = M_AXI_BRESP;
assign S_AXI_BUSER = M_AXI_BUSER;
assign M_AXI_BREADY = S_AXI_BREADY;
assign S_AXI_BVALID = M_AXI_BVALID;
end endgenerate // gwrch_pass_through;
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Read Address Channel
generate if (C_RACH_TYPE == 2) begin : grach_pass_through
assign M_AXI_ARID = S_AXI_ARID;
assign M_AXI_ARADDR = S_AXI_ARADDR;
assign M_AXI_ARLEN = S_AXI_ARLEN;
assign M_AXI_ARSIZE = S_AXI_ARSIZE;
assign M_AXI_ARBURST = S_AXI_ARBURST;
assign M_AXI_ARLOCK = S_AXI_ARLOCK;
assign M_AXI_ARCACHE = S_AXI_ARCACHE;
assign M_AXI_ARPROT = S_AXI_ARPROT;
assign M_AXI_ARQOS = S_AXI_ARQOS;
assign M_AXI_ARREGION = S_AXI_ARREGION;
assign M_AXI_ARUSER = S_AXI_ARUSER;
assign S_AXI_ARREADY = M_AXI_ARREADY;
assign M_AXI_ARVALID = S_AXI_ARVALID;
end endgenerate // grach_pass_through;
// Wiring logic for Read Data Channel
generate if (C_RDCH_TYPE == 2) begin : grdch_pass_through
assign S_AXI_RID = M_AXI_RID;
assign S_AXI_RLAST = M_AXI_RLAST;
assign S_AXI_RUSER = M_AXI_RUSER;
assign S_AXI_RDATA = M_AXI_RDATA;
assign S_AXI_RRESP = M_AXI_RRESP;
assign S_AXI_RVALID = M_AXI_RVALID;
assign M_AXI_RREADY = S_AXI_RREADY;
end endgenerate // grdch_pass_through;
// Wiring logic for AXI Streaming
generate if (C_AXIS_TYPE == 2) begin : gaxis_pass_through
assign M_AXIS_TDATA = S_AXIS_TDATA;
assign M_AXIS_TSTRB = S_AXIS_TSTRB;
assign M_AXIS_TKEEP = S_AXIS_TKEEP;
assign M_AXIS_TID = S_AXIS_TID;
assign M_AXIS_TDEST = S_AXIS_TDEST;
assign M_AXIS_TUSER = S_AXIS_TUSER;
assign M_AXIS_TLAST = S_AXIS_TLAST;
assign S_AXIS_TREADY = M_AXIS_TREADY;
assign M_AXIS_TVALID = S_AXIS_TVALID;
end endgenerate // gaxis_pass_through;
endmodule //fifo_generator_v13_1_3
/*******************************************************************************
* Declaration of top-level module for Conventional FIFO
******************************************************************************/
module fifo_generator_v13_1_3_CONV_VER
#(
parameter C_COMMON_CLOCK = 0,
parameter C_INTERFACE_TYPE = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "virtex7", //Not allowed in Verilog model
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
parameter C_AXI_TYPE = 0
)
(
input BACKUP,
input BACKUP_MARKER,
input CLK,
input RST,
input SRST,
input WR_CLK,
input WR_RST,
input RD_CLK,
input RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input WR_EN,
input RD_EN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input INT_CLK,
input INJECTDBITERR,
input INJECTSBITERR,
output [C_DOUT_WIDTH-1:0] DOUT,
output FULL,
output ALMOST_FULL,
output WR_ACK,
output OVERFLOW,
output EMPTY,
output ALMOST_EMPTY,
output VALID,
output UNDERFLOW,
output [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_FULL,
output PROG_EMPTY,
output SBITERR,
output DBITERR,
output wr_rst_busy_o,
output wr_rst_busy,
output rd_rst_busy,
output wr_rst_i_out,
output rd_rst_i_out
);
/*
******************************************************************************
* Definition of Parameters
******************************************************************************
* C_COMMON_CLOCK : Common Clock (1), Independent Clocks (0)
* C_COUNT_TYPE : *not used
* C_DATA_COUNT_WIDTH : Width of DATA_COUNT bus
* C_DEFAULT_VALUE : *not used
* C_DIN_WIDTH : Width of DIN bus
* C_DOUT_RST_VAL : Reset value of DOUT
* C_DOUT_WIDTH : Width of DOUT bus
* C_ENABLE_RLOCS : *not used
* C_FAMILY : not used in bhv model
* C_FULL_FLAGS_RST_VAL : Full flags rst val (0 or 1)
* C_HAS_ALMOST_EMPTY : 1=Core has ALMOST_EMPTY flag
* C_HAS_ALMOST_FULL : 1=Core has ALMOST_FULL flag
* C_HAS_BACKUP : *not used
* C_HAS_DATA_COUNT : 1=Core has DATA_COUNT bus
* C_HAS_INT_CLK : not used in bhv model
* C_HAS_MEMINIT_FILE : *not used
* C_HAS_OVERFLOW : 1=Core has OVERFLOW flag
* C_HAS_RD_DATA_COUNT : 1=Core has RD_DATA_COUNT bus
* C_HAS_RD_RST : *not used
* C_HAS_RST : 1=Core has Async Rst
* C_HAS_SRST : 1=Core has Sync Rst
* C_HAS_UNDERFLOW : 1=Core has UNDERFLOW flag
* C_HAS_VALID : 1=Core has VALID flag
* C_HAS_WR_ACK : 1=Core has WR_ACK flag
* C_HAS_WR_DATA_COUNT : 1=Core has WR_DATA_COUNT bus
* C_HAS_WR_RST : *not used
* C_IMPLEMENTATION_TYPE : 0=Common-Clock Bram/Dram
* 1=Common-Clock ShiftRam
* 2=Indep. Clocks Bram/Dram
* 3=Virtex-4 Built-in
* 4=Virtex-5 Built-in
* C_INIT_WR_PNTR_VAL : *not used
* C_MEMORY_TYPE : 1=Block RAM
* 2=Distributed RAM
* 3=Shift RAM
* 4=Built-in FIFO
* C_MIF_FILE_NAME : *not used
* C_OPTIMIZATION_MODE : *not used
* C_OVERFLOW_LOW : 1=OVERFLOW active low
* C_PRELOAD_LATENCY : Latency of read: 0, 1, 2
* C_PRELOAD_REGS : 1=Use output registers
* C_PRIM_FIFO_TYPE : not used in bhv model
* C_PROG_EMPTY_THRESH_ASSERT_VAL: PROG_EMPTY assert threshold
* C_PROG_EMPTY_THRESH_NEGATE_VAL: PROG_EMPTY negate threshold
* C_PROG_EMPTY_TYPE : 0=No programmable empty
* 1=Single prog empty thresh constant
* 2=Multiple prog empty thresh constants
* 3=Single prog empty thresh input
* 4=Multiple prog empty thresh inputs
* C_PROG_FULL_THRESH_ASSERT_VAL : PROG_FULL assert threshold
* C_PROG_FULL_THRESH_NEGATE_VAL : PROG_FULL negate threshold
* C_PROG_FULL_TYPE : 0=No prog full
* 1=Single prog full thresh constant
* 2=Multiple prog full thresh constants
* 3=Single prog full thresh input
* 4=Multiple prog full thresh inputs
* C_RD_DATA_COUNT_WIDTH : Width of RD_DATA_COUNT bus
* C_RD_DEPTH : Depth of read interface (2^N)
* C_RD_FREQ : not used in bhv model
* C_RD_PNTR_WIDTH : always log2(C_RD_DEPTH)
* C_UNDERFLOW_LOW : 1=UNDERFLOW active low
* C_USE_DOUT_RST : 1=Resets DOUT on RST
* C_USE_ECC : Used for error injection purpose
* C_USE_EMBEDDED_REG : 1=Use BRAM embedded output register
* C_USE_FIFO16_FLAGS : not used in bhv model
* C_USE_FWFT_DATA_COUNT : 1=Use extra logic for FWFT data count
* C_VALID_LOW : 1=VALID active low
* C_WR_ACK_LOW : 1=WR_ACK active low
* C_WR_DATA_COUNT_WIDTH : Width of WR_DATA_COUNT bus
* C_WR_DEPTH : Depth of write interface (2^N)
* C_WR_FREQ : not used in bhv model
* C_WR_PNTR_WIDTH : always log2(C_WR_DEPTH)
* C_WR_RESPONSE_LATENCY : *not used
* C_MSGON_VAL : *not used by bhv model
* C_ENABLE_RST_SYNC : 0 = Use WR_RST & RD_RST
* 1 = Use RST
* C_ERROR_INJECTION_TYPE : 0 = No error injection
* 1 = Single bit error injection only
* 2 = Double bit error injection only
* 3 = Single and double bit error injection
******************************************************************************
* Definition of Ports
******************************************************************************
* BACKUP : Not used
* BACKUP_MARKER: Not used
* CLK : Clock
* DIN : Input data bus
* PROG_EMPTY_THRESH : Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_ASSERT: Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_NEGATE: Threshold for Programmable Empty Flag
* PROG_FULL_THRESH : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_ASSERT : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_NEGATE : Threshold for Programmable Full Flag
* RD_CLK : Read Domain Clock
* RD_EN : Read enable
* RD_RST : Read Reset
* RST : Asynchronous Reset
* SRST : Synchronous Reset
* WR_CLK : Write Domain Clock
* WR_EN : Write enable
* WR_RST : Write Reset
* INT_CLK : Internal Clock
* INJECTSBITERR: Inject Signle bit error
* INJECTDBITERR: Inject Double bit error
* ALMOST_EMPTY : One word remaining in FIFO
* ALMOST_FULL : One empty space remaining in FIFO
* DATA_COUNT : Number of data words in fifo( synchronous to CLK)
* DOUT : Output data bus
* EMPTY : Empty flag
* FULL : Full flag
* OVERFLOW : Last write rejected
* PROG_EMPTY : Programmable Empty Flag
* PROG_FULL : Programmable Full Flag
* RD_DATA_COUNT: Number of data words in fifo (synchronous to RD_CLK)
* UNDERFLOW : Last read rejected
* VALID : Last read acknowledged, DOUT bus VALID
* WR_ACK : Last write acknowledged
* WR_DATA_COUNT: Number of data words in fifo (synchronous to WR_CLK)
* SBITERR : Single Bit ECC Error Detected
* DBITERR : Double Bit ECC Error Detected
******************************************************************************
*/
//----------------------------------------------------------------------------
//- Internal Signals for delayed input signals
//- All the input signals except Clock are delayed by 100 ps and then given to
//- the models.
//----------------------------------------------------------------------------
reg rst_delayed ;
reg empty_fb ;
reg srst_delayed ;
reg wr_rst_delayed ;
reg rd_rst_delayed ;
reg wr_en_delayed ;
reg rd_en_delayed ;
reg [C_DIN_WIDTH-1:0] din_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate_delayed ;
reg injectdbiterr_delayed ;
reg injectsbiterr_delayed ;
wire empty_p0_out;
always @* rst_delayed <= #`TCQ RST ;
always @* empty_fb <= #`TCQ empty_p0_out ;
always @* srst_delayed <= #`TCQ SRST ;
always @* wr_rst_delayed <= #`TCQ WR_RST ;
always @* rd_rst_delayed <= #`TCQ RD_RST ;
always @* din_delayed <= #`TCQ DIN ;
always @* wr_en_delayed <= #`TCQ WR_EN ;
always @* rd_en_delayed <= #`TCQ RD_EN ;
always @* prog_empty_thresh_delayed <= #`TCQ PROG_EMPTY_THRESH ;
always @* prog_empty_thresh_assert_delayed <= #`TCQ PROG_EMPTY_THRESH_ASSERT ;
always @* prog_empty_thresh_negate_delayed <= #`TCQ PROG_EMPTY_THRESH_NEGATE ;
always @* prog_full_thresh_delayed <= #`TCQ PROG_FULL_THRESH ;
always @* prog_full_thresh_assert_delayed <= #`TCQ PROG_FULL_THRESH_ASSERT ;
always @* prog_full_thresh_negate_delayed <= #`TCQ PROG_FULL_THRESH_NEGATE ;
always @* injectdbiterr_delayed <= #`TCQ INJECTDBITERR ;
always @* injectsbiterr_delayed <= #`TCQ INJECTSBITERR ;
/*****************************************************************************
* Derived parameters
****************************************************************************/
//There are 2 Verilog behavioral models
// 0 = Common-Clock FIFO/ShiftRam FIFO
// 1 = Independent Clocks FIFO
// 2 = Low Latency Synchronous FIFO
// 3 = Low Latency Asynchronous FIFO
localparam C_VERILOG_IMPL = (C_FIFO_TYPE == 3) ? 2 :
(C_IMPLEMENTATION_TYPE == 2) ? 1 : 0;
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//Internal reset signals
reg rd_rst_asreg = 0;
wire rd_rst_asreg_d1;
wire rd_rst_asreg_d2;
reg rd_rst_asreg_d3 = 0;
reg rd_rst_reg = 0;
wire rd_rst_comb;
reg wr_rst_d0 = 0;
reg wr_rst_d1 = 0;
reg wr_rst_d2 = 0;
reg rd_rst_d0 = 0;
reg rd_rst_d1 = 0;
reg rd_rst_d2 = 0;
reg rd_rst_d3 = 0;
reg wrrst_done = 0;
reg rdrst_done = 0;
reg wr_rst_asreg = 0;
wire wr_rst_asreg_d1;
wire wr_rst_asreg_d2;
reg wr_rst_asreg_d3 = 0;
reg rd_rst_wr_d0 = 0;
reg rd_rst_wr_d1 = 0;
reg rd_rst_wr_d2 = 0;
reg wr_rst_reg = 0;
reg rst_active_i = 1'b1;
reg rst_delayed_d1 = 1'b1;
reg rst_delayed_d2 = 1'b1;
wire wr_rst_comb;
wire wr_rst_i;
wire rd_rst_i;
wire rst_i;
//Internal reset signals
reg rst_asreg = 0;
reg srst_asreg = 0;
wire rst_asreg_d1;
wire rst_asreg_d2;
reg srst_asreg_d1 = 0;
reg srst_asreg_d2 = 0;
reg rst_reg = 0;
reg srst_reg = 0;
wire rst_comb;
wire srst_comb;
reg rst_full_gen_i = 0;
reg rst_full_ff_i = 0;
reg [2:0] sckt_ff0_bsy_o_i = {3{1'b0}};
wire RD_CLK_P0_IN;
wire RST_P0_IN;
wire RD_EN_FIFO_IN;
wire RD_EN_P0_IN;
wire ALMOST_EMPTY_FIFO_OUT;
wire ALMOST_FULL_FIFO_OUT;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT_FIFO_OUT;
wire [C_DOUT_WIDTH-1:0] DOUT_FIFO_OUT;
wire EMPTY_FIFO_OUT;
wire fifo_empty_fb;
wire FULL_FIFO_OUT;
wire OVERFLOW_FIFO_OUT;
wire PROG_EMPTY_FIFO_OUT;
wire PROG_FULL_FIFO_OUT;
wire VALID_FIFO_OUT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT_FIFO_OUT;
wire UNDERFLOW_FIFO_OUT;
wire WR_ACK_FIFO_OUT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT_FIFO_OUT;
//***************************************************************************
// Internal Signals
// The core uses either the internal_ wires or the preload0_ wires depending
// on whether the core uses Preload0 or not.
// When using preload0, the internal signals connect the internal core to
// the preload logic, and the external core's interfaces are tied to the
// preload0 signals from the preload logic.
//***************************************************************************
wire [C_DOUT_WIDTH-1:0] DATA_P0_OUT;
wire VALID_P0_OUT;
wire EMPTY_P0_OUT;
wire ALMOSTEMPTY_P0_OUT;
reg EMPTY_P0_OUT_Q;
reg ALMOSTEMPTY_P0_OUT_Q;
wire UNDERFLOW_P0_OUT;
wire RDEN_P0_OUT;
wire [C_DOUT_WIDTH-1:0] DATA_P0_IN;
wire EMPTY_P0_IN;
reg [31:0] DATA_COUNT_FWFT;
reg SS_FWFT_WR ;
reg SS_FWFT_RD ;
wire sbiterr_fifo_out;
wire dbiterr_fifo_out;
wire inject_sbit_err;
wire inject_dbit_err;
wire safety_ckt_wr_rst;
wire safety_ckt_rd_rst;
reg sckt_wr_rst_i_q = 1'b0;
wire w_fab_read_data_valid_i;
wire w_read_data_valid_i;
wire w_ram_valid_i;
// Assign 0 if not selected to avoid 'X' propogation to S/DBITERR.
assign inject_sbit_err = ((C_ERROR_INJECTION_TYPE == 1) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectsbiterr_delayed : 0;
assign inject_dbit_err = ((C_ERROR_INJECTION_TYPE == 2) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectdbiterr_delayed : 0;
assign wr_rst_i_out = wr_rst_i;
assign rd_rst_i_out = rd_rst_i;
assign wr_rst_busy_o = wr_rst_busy | rst_full_gen_i | sckt_ff0_bsy_o_i[2];
generate if (C_FULL_FLAGS_RST_VAL == 0 && C_EN_SAFETY_CKT == 1) begin : gsckt_bsy_o
wire clk_i = C_COMMON_CLOCK ? CLK : WR_CLK;
always @ (posedge clk_i)
sckt_ff0_bsy_o_i <= {sckt_ff0_bsy_o_i[1:0],wr_rst_busy};
end endgenerate
// Choose the behavioral model to instantiate based on the C_VERILOG_IMPL
// parameter (1=Independent Clocks, 0=Common Clock)
localparam FULL_FLAGS_RST_VAL = (C_HAS_SRST == 1) ? 0 : C_FULL_FLAGS_RST_VAL;
generate
case (C_VERILOG_IMPL)
0 : begin : block1
//Common Clock Behavioral Model
fifo_generator_v13_1_3_bhv_ver_ss
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL ((C_AXI_TYPE == 0 && C_FIFO_TYPE == 1) ? 1 : C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ss
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.CLK (CLK),
.RST (rst_i),
.SRST (srst_delayed),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.USER_EMPTY_FB (empty_fb),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.DATA_COUNT (DATA_COUNT_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
1 : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.fab_read_data_valid_i (w_fab_read_data_valid_i),
.read_data_valid_i (w_read_data_valid_i),
.ram_valid_i (w_ram_valid_i),
.DBITERR (dbiterr_fifo_out)
);
end
2 : begin : ll_afifo_inst
fifo_generator_v13_1_3_beh_ver_ll_afifo
#(
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ll_afifo
(
.DIN (din_delayed),
.RD_CLK (RD_CLK),
.RD_EN (rd_en_delayed),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.WR_CLK (WR_CLK),
.WR_EN (wr_en_delayed),
.DOUT (DOUT),
.EMPTY (EMPTY),
.FULL (FULL)
);
end
default : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
endcase
endgenerate
//**************************************************************************
// Connect Internal Signals
// (Signals labeled internal_*)
// In the normal case, these signals tie directly to the FIFO's inputs and
// outputs.
// In the case of Preload Latency 0 or 1, there are intermediate
// signals between the internal FIFO and the preload logic.
//**************************************************************************
//***********************************************
// If First-Word Fall-Through, instantiate
// the preload0 (FWFT) module
//***********************************************
wire rd_en_to_fwft_fifo;
wire sbiterr_fwft;
wire dbiterr_fwft;
wire [C_DOUT_WIDTH-1:0] dout_fwft;
wire empty_fwft;
wire rd_en_fifo_in;
wire stage2_reg_en_i;
wire [1:0] valid_stages_i;
wire rst_fwft;
//wire empty_p0_out;
reg [C_SYNCHRONIZER_STAGE-1:0] pkt_empty_sync = 'b1;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
localparam IS_PKT_FIFO = (C_FIFO_TYPE == 1) ? 1 : 0;
localparam IS_AXIS_PKT_FIFO = (C_FIFO_TYPE == 1 && C_AXI_TYPE == 0) ? 1 : 0;
assign rst_fwft = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 1'b0;
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 3) begin : block2
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
fgpl0
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (RST_P0_IN),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (RD_EN_P0_IN),
.FIFOEMPTY (EMPTY_P0_IN),
.FIFODATA (DATA_P0_IN),
.FIFOSBITERR (sbiterr_fifo_out),
.FIFODBITERR (dbiterr_fifo_out),
// Output
.USERDATA (dout_fwft),
.USERVALID (VALID_P0_OUT),
.USEREMPTY (empty_fwft),
.USERALMOSTEMPTY (ALMOSTEMPTY_P0_OUT),
.USERUNDERFLOW (UNDERFLOW_P0_OUT),
.RAMVALID (),
.FIFORDEN (rd_en_fifo_in),
.USERSBITERR (sbiterr_fwft),
.USERDBITERR (dbiterr_fwft),
.STAGE2_REG_EN (stage2_reg_en_i),
.fab_read_data_valid_i_o (w_fab_read_data_valid_i),
.read_data_valid_i_o (w_read_data_valid_i),
.ram_valid_i_o (w_ram_valid_i),
.VALID_STAGES (valid_stages_i)
);
//***********************************************
// Connect inputs to preload (FWFT) module
//***********************************************
//Connect the RD_CLK of the Preload (FWFT) module to CLK if we
// have a common-clock FIFO, or RD_CLK if we have an
// independent clock FIFO
assign RD_CLK_P0_IN = ((C_VERILOG_IMPL == 0) ? CLK : RD_CLK);
assign RST_P0_IN = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 0;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
assign EMPTY_P0_IN = C_EN_SAFETY_CKT ? fifo_empty_fb : EMPTY_FIFO_OUT;
assign DATA_P0_IN = DOUT_FIFO_OUT;
//***********************************************
// Connect outputs from preload (FWFT) module
//***********************************************
assign VALID = VALID_P0_OUT ;
assign ALMOST_EMPTY = ALMOSTEMPTY_P0_OUT;
assign UNDERFLOW = UNDERFLOW_P0_OUT ;
assign RD_EN_FIFO_IN = rd_en_fifo_in;
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
assign DATA_COUNT = (C_USE_FWFT_DATA_COUNT == 0)? DATA_COUNT_FIFO_OUT:
(C_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) ? DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:0] :
DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH+1];
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
EMPTY_P0_OUT_Q <= 1;
ALMOSTEMPTY_P0_OUT_Q <= 1;
end else begin
EMPTY_P0_OUT_Q <= #`TCQ empty_p0_out;
// EMPTY_P0_OUT_Q <= #`TCQ EMPTY_FIFO_OUT;
ALMOSTEMPTY_P0_OUT_Q <= #`TCQ ALMOSTEMPTY_P0_OUT;
end
end //always
//***********************************************
// logic for common-clock data count when FWFT is selected
//***********************************************
initial begin
SS_FWFT_RD = 1'b0;
DATA_COUNT_FWFT = 0 ;
SS_FWFT_WR = 1'b0 ;
end //initial
//***********************************************
// common-clock data count is implemented as an
// up-down counter. SS_FWFT_WR and SS_FWFT_RD
// are the up/down enables for the counter.
//***********************************************
always @ (RD_EN or VALID_P0_OUT or WR_EN or FULL_FIFO_OUT or empty_p0_out) begin
if (C_VALID_LOW == 1) begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && ~VALID_P0_OUT) : (~empty_p0_out && RD_EN && ~VALID_P0_OUT) ;
end else begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && VALID_P0_OUT) : (~empty_p0_out && RD_EN && VALID_P0_OUT) ;
end
SS_FWFT_WR = (WR_EN && (~FULL_FIFO_OUT)) ;
end
//***********************************************
// common-clock data count is implemented as an
// up-down counter for FWFT. This always block
// calculates the counter.
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
DATA_COUNT_FWFT <= 0;
end else begin
//if (srst_delayed && (C_HAS_SRST == 1) ) begin
if ((srst_delayed | wr_rst_busy | rd_rst_busy) && (C_HAS_SRST == 1) ) begin
DATA_COUNT_FWFT <= #`TCQ 0;
end else begin
case ( {SS_FWFT_WR, SS_FWFT_RD})
2'b00: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
2'b01: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT - 1 ;
2'b10: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT + 1 ;
2'b11: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
endcase
end //if SRST
end //IF RST
end //always
end endgenerate // : block2
// AXI Streaming Packet FIFO
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_plus1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_reg = 0;
reg partial_packet = 0;
reg stage1_eop_d1 = 0;
reg rd_en_fifo_in_d1 = 0;
reg eop_at_stage2 = 0;
reg ram_pkt_empty = 0;
reg ram_pkt_empty_d1 = 0;
wire [C_DOUT_WIDTH-1:0] dout_p0_out;
wire packet_empty_wr;
wire wr_rst_fwft_pkt_fifo;
wire dummy_wr_eop;
wire ram_wr_en_pkt_fifo;
wire wr_eop;
wire ram_rd_en_compare;
wire stage1_eop;
wire pkt_ready_to_read;
wire rd_en_2_stage2;
// Generate Dummy WR_EOP for partial packet (Only for AXI Streaming)
// When Packet EMPTY is high, and FIFO is full, then generate the dummy WR_EOP
// When dummy WR_EOP is high, mask the actual EOP to avoid double increment of
// write packet count
generate if (IS_FWFT == 1 && IS_AXIS_PKT_FIFO == 1) begin // gdummy_wr_eop
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
partial_packet <= 1'b0;
else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy)
partial_packet <= #`TCQ 1'b0;
else if (ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]))
partial_packet <= #`TCQ 1'b1;
else if (partial_packet && din_delayed[0] && ram_wr_en_pkt_fifo)
partial_packet <= #`TCQ 1'b0;
end
end
end endgenerate // gdummy_wr_eop
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1) begin // gpkt_fifo_fwft
assign wr_rst_fwft_pkt_fifo = (C_COMMON_CLOCK == 0) ? wr_rst_i : (C_HAS_RST == 1) ? rst_i:1'b0;
assign dummy_wr_eop = ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]) && (~partial_packet);
assign packet_empty_wr = (C_COMMON_CLOCK == 1) ? empty_p0_out : pkt_empty_sync[C_SYNCHRONIZER_STAGE-1];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
stage1_eop_d1 <= 1'b0;
rd_en_fifo_in_d1 <= 1'b0;
end else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
stage1_eop_d1 <= #`TCQ 1'b0;
rd_en_fifo_in_d1 <= #`TCQ 1'b0;
end else begin
stage1_eop_d1 <= #`TCQ stage1_eop;
rd_en_fifo_in_d1 <= #`TCQ rd_en_fifo_in;
end
end
end
assign stage1_eop = (rd_en_fifo_in_d1) ? DOUT_FIFO_OUT[0] : stage1_eop_d1;
assign ram_wr_en_pkt_fifo = wr_en_delayed && (~FULL_FIFO_OUT);
assign wr_eop = ram_wr_en_pkt_fifo && ((din_delayed[0] && (~partial_packet)) || dummy_wr_eop);
assign ram_rd_en_compare = stage2_reg_en_i && stage1_eop;
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (2) // Enable low latency fwft logic
)
pkt_fifo_fwft
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (rst_fwft),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (rd_en_delayed),
.FIFOEMPTY (pkt_ready_to_read),
.FIFODATA (dout_fwft),
.FIFOSBITERR (sbiterr_fwft),
.FIFODBITERR (dbiterr_fwft),
// Output
.USERDATA (dout_p0_out),
.USERVALID (),
.USEREMPTY (empty_p0_out),
.USERALMOSTEMPTY (),
.USERUNDERFLOW (),
.RAMVALID (),
.FIFORDEN (rd_en_2_stage2),
.USERSBITERR (SBITERR),
.USERDBITERR (DBITERR),
.STAGE2_REG_EN (),
.VALID_STAGES ()
);
assign pkt_ready_to_read = ~(!(ram_pkt_empty || empty_fwft) && ((valid_stages_i[0] && valid_stages_i[1]) || eop_at_stage2));
assign rd_en_to_fwft_fifo = ~empty_fwft && rd_en_2_stage2;
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
eop_at_stage2 <= 1'b0;
else if (stage2_reg_en_i)
eop_at_stage2 <= #`TCQ stage1_eop;
end
//---------------------------------------------------------------------------
// Write and Read Packet Count
//---------------------------------------------------------------------------
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count <= 0;
else if (srst_delayed | wr_rst_busy | rd_rst_busy)
wr_pkt_count <= #`TCQ 0;
else if (wr_eop)
wr_pkt_count <= #`TCQ wr_pkt_count + 1;
end
end endgenerate // gpkt_fifo_fwft
assign DOUT = (C_FIFO_TYPE != 1) ? dout_fwft : dout_p0_out;
assign EMPTY = (C_FIFO_TYPE != 1) ? empty_fwft : empty_p0_out;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 1) begin // grss_pkt_cnt
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
rd_pkt_count <= 0;
rd_pkt_count_plus1 <= 1;
end else if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
rd_pkt_count <= #`TCQ 0;
rd_pkt_count_plus1 <= #`TCQ 1;
end else if (stage2_reg_en_i && stage1_eop) begin
rd_pkt_count <= #`TCQ rd_pkt_count + 1;
rd_pkt_count_plus1 <= #`TCQ rd_pkt_count_plus1 + 1;
end
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (SRST | wr_rst_busy | rd_rst_busy) begin
ram_pkt_empty <= #`TCQ 1'b1;
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count) && wr_eop) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count_plus1 == wr_pkt_count) && ~wr_eop && ~ALMOST_FULL_FIFO_OUT && ram_rd_en_compare) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
end endgenerate //grss_pkt_cnt
localparam SYNC_STAGE_WIDTH = (C_SYNCHRONIZER_STAGE+1)*C_WR_PNTR_WIDTH;
reg [SYNC_STAGE_WIDTH-1:0] wr_pkt_count_q = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_b2g = 0;
wire [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_rd;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 0) begin // gras_pkt_cnt
// Delay the write packet count in write clock domain to accomodate the binary to gray conversion delay
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count_b2g <= 0;
else
wr_pkt_count_b2g <= #`TCQ wr_pkt_count;
end
// Synchronize the delayed write packet count in read domain, and also compensate the gray to binay conversion delay
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
wr_pkt_count_q <= 0;
else
wr_pkt_count_q <= #`TCQ {wr_pkt_count_q[SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH-1:0],wr_pkt_count_b2g};
end
always @* begin
if (stage1_eop)
rd_pkt_count <= rd_pkt_count_reg + 1;
else
rd_pkt_count <= rd_pkt_count_reg;
end
assign wr_pkt_count_rd = wr_pkt_count_q[SYNC_STAGE_WIDTH-1:SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
rd_pkt_count_reg <= 0;
else if (rd_en_fifo_in)
rd_pkt_count_reg <= #`TCQ rd_pkt_count;
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (rd_pkt_count != wr_pkt_count_rd) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count_rd) && stage2_reg_en_i) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
// Synchronize the empty in write domain
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
pkt_empty_sync <= 'b1;
else
pkt_empty_sync <= #`TCQ {pkt_empty_sync[C_SYNCHRONIZER_STAGE-2:0], empty_p0_out};
end
end endgenerate //gras_pkt_cnt
generate if (IS_FWFT == 0 || C_FIFO_TYPE == 3) begin : STD_FIFO
//***********************************************
// If NOT First-Word Fall-Through, wire the outputs
// of the internal _ss or _as FIFO directly to the
// output, and do not instantiate the preload0
// module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VALID = VALID_FIFO_OUT;
assign EMPTY = EMPTY_FIFO_OUT;
assign ALMOST_EMPTY = ALMOST_EMPTY_FIFO_OUT;
assign EMPTY_P0_IN = 0;
assign UNDERFLOW = UNDERFLOW_FIFO_OUT;
assign DATA_COUNT = DATA_COUNT_FIFO_OUT;
assign SBITERR = sbiterr_fifo_out;
assign DBITERR = dbiterr_fifo_out;
end endgenerate // STD_FIFO
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 1) begin : NO_PKT_FIFO
assign empty_p0_out = empty_fwft;
assign SBITERR = sbiterr_fwft;
assign DBITERR = dbiterr_fwft;
assign DOUT = dout_fwft;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
end endgenerate // NO_PKT_FIFO
//***********************************************
// Connect user flags to internal signals
//***********************************************
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//RD_DATA_COUNT is 0 when EMPTY and 1 when ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block3
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : RD_DATA_COUNT_FIFO_OUT);
end //block_ic
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block30
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : RD_DATA_COUNT_FIFO_OUT);
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block30_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : (RD_DATA_COUNT_FIFO_OUT));
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30_both
endgenerate
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block3_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : (RD_DATA_COUNT_FIFO_OUT));
end //block_ic_both
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3_both
endgenerate
//If we are not using extra logic for the FWFT data count,
//then connect RD_DATA_COUNT to the RD_DATA_COUNT from the
//internal FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==0 ) begin : block31
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Always connect WR_DATA_COUNT to the WR_DATA_COUNT from the internal
//FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==1) begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
else begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Connect other flags to the internal FIFO instance
assign FULL = FULL_FIFO_OUT;
assign ALMOST_FULL = ALMOST_FULL_FIFO_OUT;
assign WR_ACK = WR_ACK_FIFO_OUT;
assign OVERFLOW = OVERFLOW_FIFO_OUT;
assign PROG_FULL = PROG_FULL_FIFO_OUT;
assign PROG_EMPTY = PROG_EMPTY_FIFO_OUT;
/**************************************************************************
* find_log2
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// if an asynchronous FIFO has been selected, display a message that the FIFO
// will not be cycle-accurate in simulation
initial begin
if (C_IMPLEMENTATION_TYPE == 2) begin
$display("WARNING: Behavioral models for independent clock FIFO configurations do not model synchronization delays. The behavioral models are functionally correct, and will represent the behavior of the configured FIFO. See the FIFO Generator User Guide for more information.");
end else if (C_MEMORY_TYPE == 4) begin
$display("FAILURE : Behavioral models do not support built-in FIFO configurations. Please use post-synthesis or post-implement simulation in Vivado.");
$finish;
end
if (C_WR_PNTR_WIDTH != find_log2(C_WR_DEPTH)) begin
$display("FAILURE : C_WR_PNTR_WIDTH is not log2 of C_WR_DEPTH.");
$finish;
end
if (C_RD_PNTR_WIDTH != find_log2(C_RD_DEPTH)) begin
$display("FAILURE : C_RD_PNTR_WIDTH is not log2 of C_RD_DEPTH.");
$finish;
end
if (C_USE_ECC == 1) begin
if (C_DIN_WIDTH != C_DOUT_WIDTH) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be equal for ECC configuration.");
$finish;
end
if (C_DIN_WIDTH == 1 && C_ERROR_INJECTION_TYPE > 1) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be > 1 for double bit error injection.");
$finish;
end
end
end //initial
/**************************************************************************
* Internal reset logic
**************************************************************************/
assign wr_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? wr_rst_reg : 0;
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? rd_rst_reg : 0;
assign rst_i = C_HAS_RST ? rst_reg : 0;
wire rst_2_sync;
wire rst_2_sync_safety = (C_ENABLE_RST_SYNC == 1) ? rst_delayed : RD_RST;
wire clk_2_sync = (C_COMMON_CLOCK == 1) ? CLK : WR_CLK;
wire clk_2_sync_safety = (C_COMMON_CLOCK == 1) ? CLK : RD_CLK;
localparam RST_SYNC_STAGES = (C_EN_SAFETY_CKT == 0) ? C_SYNCHRONIZER_STAGE :
(C_COMMON_CLOCK == 1) ? 3 : C_SYNCHRONIZER_STAGE+2;
reg [RST_SYNC_STAGES-1:0] wrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] arst_sync_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_wr = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_ext = {RST_SYNC_STAGES{1'b0}};
reg [1:0] wrst_cc = {2{1'b0}};
reg [1:0] rrst_cc = {2{1'b0}};
generate
if (C_EN_SAFETY_CKT == 1 && C_INTERFACE_TYPE == 0) begin : grst_safety_ckt
reg[1:0] rst_d1_safety =1;
reg[1:0] rst_d2_safety =1;
reg[1:0] rst_d3_safety =1;
reg[1:0] rst_d4_safety =1;
reg[1:0] rst_d5_safety =1;
reg[1:0] rst_d6_safety =1;
reg[1:0] rst_d7_safety =1;
always@(posedge rst_2_sync_safety or posedge clk_2_sync_safety) begin : prst
if (rst_2_sync_safety == 1'b1) begin
rst_d1_safety <= 1'b1;
rst_d2_safety <= 1'b1;
rst_d3_safety <= 1'b1;
rst_d4_safety <= 1'b1;
rst_d5_safety <= 1'b1;
rst_d6_safety <= 1'b1;
rst_d7_safety <= 1'b1;
end
else begin
rst_d1_safety <= #`TCQ 1'b0;
rst_d2_safety <= #`TCQ rst_d1_safety;
rst_d3_safety <= #`TCQ rst_d2_safety;
rst_d4_safety <= #`TCQ rst_d3_safety;
rst_d5_safety <= #`TCQ rst_d4_safety;
rst_d6_safety <= #`TCQ rst_d5_safety;
rst_d7_safety <= #`TCQ rst_d6_safety;
end //if
end //prst
always@(posedge rst_d7_safety or posedge WR_EN) begin : assert_safety
if(rst_d7_safety == 1 && WR_EN == 1) begin
$display("WARNING:A write attempt has been made within the 7 clock cycles of reset de-assertion. This can lead to data discrepancy when safety circuit is enabled.");
end //if
end //always
end // grst_safety_ckt
endgenerate
// if (C_EN_SAFET_CKT == 1)
// assertion:the reset shud be atleast 3 cycles wide.
generate
reg safety_ckt_wr_rst_i = 1'b0;
if (C_ENABLE_RST_SYNC == 0) begin : gnrst_sync
always @* begin
wr_rst_reg <= wr_rst_delayed;
rd_rst_reg <= rd_rst_delayed;
rst_reg <= 1'b0;
srst_reg <= 1'b0;
end
assign rst_2_sync = wr_rst_delayed;
assign wr_rst_busy = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
// end : gnrst_sync
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 0) begin : g7s_ic_rst
reg fifo_wrst_done = 1'b0;
reg fifo_rrst_done = 1'b0;
reg sckt_wrst_i = 1'b0;
reg sckt_wrst_i_q = 1'b0;
reg rd_rst_active = 1'b0;
reg rd_rst_middle = 1'b0;
reg sckt_rd_rst_d1 = 1'b0;
reg [1:0] rst_delayed_ic_w = 2'h0;
wire rst_delayed_ic_w_i;
reg [1:0] rst_delayed_ic_r = 2'h0;
wire rst_delayed_ic_r_i;
wire arst_sync_rst;
wire fifo_rst_done;
wire fifo_rst_active;
assign wr_rst_comb = !wr_rst_asreg_d2 && wr_rst_asreg;
assign rd_rst_comb = C_EN_SAFETY_CKT ? (!rd_rst_asreg_d2 && rd_rst_asreg) || rd_rst_active : !rd_rst_asreg_d2 && rd_rst_asreg;
assign rst_2_sync = rst_delayed_ic_w_i;
assign arst_sync_rst = arst_sync_q[RST_SYNC_STAGES-1];
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | fifo_rst_active : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? safety_ckt_rd_rst : 1'b0;
assign fifo_rst_done = fifo_wrst_done & fifo_rrst_done;
assign fifo_rst_active = sckt_wrst_i | wrst_ext[RST_SYNC_STAGES-1] | rrst_wr[RST_SYNC_STAGES-1];
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_w <= 2'b11;
else
rst_delayed_ic_w <= #`TCQ {rst_delayed_ic_w[0],1'b0};
end
assign rst_delayed_ic_w_i = rst_delayed_ic_w[1];
always @(posedge RD_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_r <= 2'b11;
else
rst_delayed_ic_r <= #`TCQ {rst_delayed_ic_r[0],1'b0};
end
assign rst_delayed_ic_r_i = rst_delayed_ic_r[1];
always @(posedge WR_CLK) begin
sckt_wrst_i_q <= #`TCQ sckt_wrst_i;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ sckt_wrst_i | wr_rst_busy | sckt_wr_rst_i_q;
if (arst_sync_rst && ~fifo_rst_active)
sckt_wrst_i <= #`TCQ 1'b1;
else if (sckt_wrst_i && fifo_rst_done)
sckt_wrst_i <= #`TCQ 1'b0;
else
sckt_wrst_i <= #`TCQ sckt_wrst_i;
if (rrst_wr[RST_SYNC_STAGES-2] & ~rrst_wr[RST_SYNC_STAGES-1])
fifo_rrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_rrst_done <= #`TCQ 1'b0;
else
fifo_rrst_done <= #`TCQ fifo_rrst_done;
if (wrst_ext[RST_SYNC_STAGES-2] & ~wrst_ext[RST_SYNC_STAGES-1])
fifo_wrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_wrst_done <= #`TCQ 1'b0;
else
fifo_wrst_done <= #`TCQ fifo_wrst_done;
end
always @(posedge WR_CLK or posedge rst_delayed_ic_w_i) begin
if (rst_delayed_ic_w_i == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],wr_rst_asreg};
wrst_ext <= #`TCQ {wrst_ext[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_wr <= #`TCQ {rrst_wr[RST_SYNC_STAGES-2:0],safety_ckt_rd_rst};
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_ic_w_i};
end
assign wr_rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign wr_rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge WR_CLK or posedge wr_rst_comb) begin
if (wr_rst_comb == 1'b1) begin
wr_rst_reg <= 1'b1;
end else begin
wr_rst_reg <= #`TCQ 1'b0;
end
end
always @(posedge RD_CLK or posedge rst_delayed_ic_r_i) begin
if (rst_delayed_ic_r_i == 1'b1) begin
rd_rst_asreg <= 1'b1;
end else begin
if (rd_rst_asreg_d1 == 1'b1) begin
rd_rst_asreg <= #`TCQ 1'b0;
end else begin
rd_rst_asreg <= #`TCQ rd_rst_asreg;
end
end
end
always @(posedge RD_CLK) begin
rrst_reg <= #`TCQ {rrst_reg[RST_SYNC_STAGES-2:0],rd_rst_asreg};
rrst_q <= #`TCQ {rrst_q[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_cc <= #`TCQ {rrst_cc[0],rd_rst_asreg_d2};
sckt_rd_rst_d1 <= #`TCQ safety_ckt_rd_rst;
if (!rd_rst_middle && rrst_reg[1] && !rrst_reg[2]) begin
rd_rst_active <= #`TCQ 1'b1;
rd_rst_middle <= #`TCQ 1'b1;
end else if (safety_ckt_rd_rst)
rd_rst_active <= #`TCQ 1'b0;
else if (sckt_rd_rst_d1 && !safety_ckt_rd_rst)
rd_rst_middle <= #`TCQ 1'b0;
end
assign rd_rst_asreg_d1 = rrst_reg[RST_SYNC_STAGES-2];
assign rd_rst_asreg_d2 = C_EN_SAFETY_CKT ? rrst_reg[RST_SYNC_STAGES-1] : rrst_reg[1];
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rrst_q[2] : 1'b0;
always @(posedge RD_CLK or posedge rd_rst_comb) begin
if (rd_rst_comb == 1'b1) begin
rd_rst_reg <= 1'b1;
end else begin
rd_rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_ic_rst
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 1) begin : g7s_cc_rst
reg [1:0] rst_delayed_cc = 2'h0;
wire rst_delayed_cc_i;
assign rst_comb = !rst_asreg_d2 && rst_asreg;
assign rst_2_sync = rst_delayed_cc_i;
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | wrst_cc[1] : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? arst_sync_q[1] | arst_sync_q[RST_SYNC_STAGES-1] | wrst_cc[1] : 1'b0;
always @(posedge CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1)
rst_delayed_cc <= 2'b11;
else
rst_delayed_cc <= #`TCQ {rst_delayed_cc,1'b0};
end
assign rst_delayed_cc_i = rst_delayed_cc[1];
always @(posedge CLK or posedge rst_delayed_cc_i) begin
if (rst_delayed_cc_i == 1'b1) begin
rst_asreg <= 1'b1;
end else begin
if (rst_asreg_d1 == 1'b1) begin
rst_asreg <= #`TCQ 1'b0;
end else begin
rst_asreg <= #`TCQ rst_asreg;
end
end
end
always @(posedge CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],rst_asreg};
wrst_cc <= #`TCQ {wrst_cc[0],arst_sync_q[RST_SYNC_STAGES-1]};
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ wrst_cc[1] | wr_rst_busy | sckt_wr_rst_i_q;
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_cc_i};
end
assign rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge CLK or posedge rst_comb) begin
if (rst_comb == 1'b1) begin
rst_reg <= 1'b1;
end else begin
rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_cc_rst
end else if (IS_8SERIES == 1 && C_HAS_SRST == 1 && C_COMMON_CLOCK == 1) begin : g8s_cc_rst
assign wr_rst_busy = (C_MEMORY_TYPE != 4) ? rst_reg : rst_active_i;
assign rd_rst_busy = rst_reg;
assign rst_2_sync = srst_delayed;
always @* rst_full_ff_i <= rst_reg;
always @* rst_full_gen_i <= C_FULL_FLAGS_RST_VAL == 1 ? rst_active_i : 0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
always @(posedge CLK) begin
rst_delayed_d1 <= #`TCQ srst_delayed;
rst_delayed_d2 <= #`TCQ rst_delayed_d1;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
if (rst_reg || rst_delayed_d2) begin
rst_active_i <= #`TCQ 1'b1;
end else begin
rst_active_i <= #`TCQ rst_reg;
end
end
always @(posedge CLK) begin
if (~rst_reg && srst_delayed) begin
rst_reg <= #`TCQ 1'b1;
end else if (rst_reg) begin
rst_reg <= #`TCQ 1'b0;
end else begin
rst_reg <= #`TCQ rst_reg;
end
end
// end : g8s_cc_rst
end else begin
assign wr_rst_busy = 1'b0;
assign rd_rst_busy = 1'b0;
assign safety_ckt_wr_rst = 1'b0;
assign safety_ckt_rd_rst = 1'b0;
end
endgenerate
generate
if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 1) begin : grstd1
// RST_FULL_GEN replaces the reset falling edge detection used to de-assert
// FULL, ALMOST_FULL & PROG_FULL flags if C_FULL_FLAGS_RST_VAL = 1.
// RST_FULL_FF goes to the reset pin of the final flop of FULL, ALMOST_FULL &
// PROG_FULL
reg rst_d1 = 1'b0;
reg rst_d2 = 1'b0;
reg rst_d3 = 1'b0;
reg rst_d4 = 1'b0;
reg rst_d5 = 1'b0;
always @ (posedge rst_2_sync or posedge clk_2_sync) begin
if (rst_2_sync) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
rst_d3 <= 1'b1;
rst_d4 <= 1'b1;
end else begin
if (srst_delayed) begin
rst_d1 <= #`TCQ 1'b1;
rst_d2 <= #`TCQ 1'b1;
rst_d3 <= #`TCQ 1'b1;
rst_d4 <= #`TCQ 1'b1;
end else begin
rst_d1 <= #`TCQ wr_rst_busy;
rst_d2 <= #`TCQ rst_d1;
rst_d3 <= #`TCQ rst_d2 | safety_ckt_wr_rst;
rst_d4 <= #`TCQ rst_d3;
end
end
end
always @* rst_full_ff_i <= (C_HAS_SRST == 0) ? rst_d2 : 1'b0 ;
always @* rst_full_gen_i <= rst_d3;
end else if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 0) begin : gnrst_full
always @* rst_full_ff_i <= (C_COMMON_CLOCK == 0) ? wr_rst_i : rst_i;
end
endgenerate // grstd1
endmodule //fifo_generator_v13_1_3_conv_ver
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0;
else
DOUT <= #`TCQ DIN;
end
endmodule // fifo_generator_v13_1_3_sync_stage
/*******************************************************************************
* Declaration of Independent-Clocks FIFO Module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_as
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input SAFETY_CKT_WR_RST,
input SAFETY_CKT_RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_CLK,
input RD_EN,
input RD_EN_USER,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input USER_EMPTY_FB,
input fab_read_data_valid_i,
input read_data_valid_i,
input ram_valid_i,
output reg ALMOST_EMPTY = 1'b1,
output reg ALMOST_FULL = C_FULL_FLAGS_RST_VAL,
output [C_DOUT_WIDTH-1:0] DOUT,
output reg EMPTY = 1'b1,
output reg EMPTY_FB = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL,
output OVERFLOW,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output UNDERFLOW,
output WR_ACK,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC_1 && SYMMETRIC_PORT && ERR_INJECTION;
// Array that holds the error injection type (single/double bit error) on
// a specific write operation, which is returned on read to corrupt the
// output data.
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
//The amount of data stored in the FIFO at any time is given
// by num_wr_bits (in the WR_CLK domain) and num_rd_bits (in the RD_CLK
// domain.
//num_wr_bits is calculated by considering the total words in the FIFO,
// and the state of the read pointer (which may not have yet crossed clock
// domains.)
//num_rd_bits is calculated by considering the total words in the FIFO,
// and the state of the write pointer (which may not have yet crossed clock
// domains.)
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
wire wr_rst_i = WR_RST;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire rd_rst_i = RD_RST;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
// Delayed ram_rd_en is needed only for STD Embedded register option
generate
if (C_PRELOAD_LATENCY == 2) begin : grd_d
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
end
endgenerate
generate
if (C_PRELOAD_LATENCY == 2 && C_USE_EMBEDDED_REG == 3) begin : grd_d1
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
endgenerate
// Write pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : rdg // Read depth greater than write depth
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1:0] = 0;
end else begin : rdl // Read depth lesser than or equal to write depth
assign adj_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
endgenerate
// Generate Empty and Almost Empty
// ram_rd_en used to determine EMPTY should depend on the EMPTY.
assign ram_rd_en = RD_EN & !EMPTY;
assign empty_int = ((adj_wr_pntr_rd == rd_pntr) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+1'h1))));
assign almost_empty_int = ((adj_wr_pntr_rd == (rd_pntr+1'h1)) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+2'h2))));
// Register Empty and Almost Empty
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin
EMPTY <= 1'b1;
ALMOST_EMPTY <= 1'b1;
rd_data_count_int <= {C_RD_PNTR_WIDTH{1'b0}};
end else begin
rd_data_count_int <= #`TCQ {(adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:0] - rd_pntr[C_RD_PNTR_WIDTH-1:0]), 1'b0};
if (empty_int)
EMPTY <= #`TCQ 1'b1;
else
EMPTY <= #`TCQ 1'b0;
if (!EMPTY) begin
if (almost_empty_int)
ALMOST_EMPTY <= #`TCQ 1'b1;
else
ALMOST_EMPTY <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (SAFETY_CKT_RD_RST && C_EN_SAFETY_CKT)
EMPTY_FB <= #`TCQ 1'b1;
else if (empty_int)
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ 1'b0;
end // rd_rst_i
end // always
// Read pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wdg // Write depth greater than read depth
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1:0] = 0;
end else begin : wdl // Write depth lesser than or equal to read depth
assign adj_rd_pntr_wr = rd_pntr_wr[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end
endgenerate
// Generate FULL and ALMOST_FULL
// ram_wr_en used to determine FULL should depend on the FULL.
assign ram_wr_en = WR_EN & !FULL;
assign full_int = ((adj_rd_pntr_wr == (wr_pntr+1'h1)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+2'h2))));
assign almost_full_int = ((adj_rd_pntr_wr == (wr_pntr+2'h2)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+3'h3))));
// Register FULL and ALMOST_FULL Empty
always @ (posedge WR_CLK or posedge RST_FULL_FF)
begin
if (RST_FULL_FF) begin
FULL <= C_FULL_FLAGS_RST_VAL;
ALMOST_FULL <= C_FULL_FLAGS_RST_VAL;
end else begin
if (full_int) begin
FULL <= #`TCQ 1'b1;
end else begin
FULL <= #`TCQ 1'b0;
end
if (RST_FULL_GEN) begin
ALMOST_FULL <= #`TCQ 1'b0;
end else if (!FULL) begin
if (almost_full_int)
ALMOST_FULL <= #`TCQ 1'b1;
else
ALMOST_FULL <= #`TCQ 1'b0;
end
end // wr_rst_i
end // always
always @ (posedge WR_CLK or posedge wr_rst_i)
begin
if (wr_rst_i) begin
wr_data_count_int <= {C_WR_DATA_COUNT_WIDTH{1'b0}};
end else begin
wr_data_count_int <= #`TCQ {(wr_pntr[C_WR_PNTR_WIDTH-1:0] - adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:0]), 1'b0};
end // wr_rst_i
end // always
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
stage1_valid <= 0;
stage2_valid <= 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//Pointers passed into opposite clock domain
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_EMPTY.
wire [31:0] num_read_words_pe =
num_rd_bits/(C_DOUT_WIDTH/C_DEPTH_RATIO_WR);
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_FULL.
wire [31:0] num_write_words_pf =
num_wr_bits/(C_DIN_WIDTH/C_DEPTH_RATIO_RD);
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/***************************************************************************
* Internal registers and wires
**************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire valid_i;
wire valid_out1;
wire valid_out2;
wire valid_out;
wire underflow_i;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
reg valid_d1 = 0;
reg valid_d2 = 0;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/****************************************************************************
* Function Declarations
***************************************************************************/
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
/***********************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_d2 = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_CLK;
wire RD_EN;
wire RST;
wire WR_CLK;
wire WR_EN;
*/
//***************************************************************************
// Dout may change behavior based on latency
//***************************************************************************
assign ideal_dout_out[C_DOUT_WIDTH-1:0] = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) )?
ideal_dout_d1: ideal_dout;
assign DOUT[C_DOUT_WIDTH-1:0] = ideal_dout_out;
//***************************************************************************
// Assign SBITERR and DBITERR based on latency
//***************************************************************************
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY == 2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) ) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY==2 && (C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
//***************************************************************************
// Safety-ckt logic with embedded reg/fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
// if (C_HAS_VALID == 1) begin
// assign valid_out = valid_d1;
// end
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK)
begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else begin
if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end
end
endgenerate
//***************************************************************************
// Safety-ckt logic with embedded reg + fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK) begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else begin
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end
endgenerate
//***************************************************************************
// Overflow may be active-low
//***************************************************************************
generate
if (C_HAS_OVERFLOW==1) begin : blockOF1
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end
endgenerate
assign PROG_EMPTY = ideal_prog_empty;
assign PROG_FULL = ideal_prog_full;
//***************************************************************************
// Valid may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_VALID==1) begin : blockVL1
assign valid_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out1 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG < 3)?
valid_d1: valid_i;
assign valid_out2 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG == 3)?
valid_d2: valid_i;
assign valid_out = (C_USE_EMBEDDED_REG == 3) ? valid_out2 : valid_out1;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end
endgenerate
//***************************************************************************
// Underflow may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_UNDERFLOW==1) begin : blockUF1
assign underflow_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & EMPTY) : ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end
endgenerate
//***************************************************************************
// Write acknowledge may be active low
//***************************************************************************
generate
if (C_HAS_WR_ACK==1) begin : blockWK1
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : wdc_fwft_ext
reg [C_PNTR_WIDTH-1:0] adjusted_wr_pntr = 0;
reg [C_PNTR_WIDTH-1:0] adjusted_rd_pntr = 0;
wire [C_PNTR_WIDTH-1:0] diff_wr_rd_tmp;
wire [C_PNTR_WIDTH:0] diff_wr_rd;
reg [C_PNTR_WIDTH:0] wr_data_count_i = 0;
always @* begin
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = 0;
adjusted_rd_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
end else if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin
adjusted_rd_pntr = rd_pntr_wr;
adjusted_wr_pntr = 0;
adjusted_wr_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
end else begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = rd_pntr_wr;
end
end // always @*
assign diff_wr_rd_tmp = adjusted_wr_pntr - adjusted_rd_pntr;
assign diff_wr_rd = {1'b0,diff_wr_rd_tmp};
always @ (posedge wr_rst_i or posedge WR_CLK)
begin
if (wr_rst_i)
wr_data_count_i <= 0;
else
wr_data_count_i <= #`TCQ diff_wr_rd + EXTRA_WORDS_DC;
end // always @ (posedge WR_CLK or posedge WR_CLK)
always @* begin
if (C_WR_PNTR_WIDTH >= C_RD_PNTR_WIDTH)
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:0];
else
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end // always @*
end // wdc_fwft_ext
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
reg [C_RD_PNTR_WIDTH:0] rdc_fwft_ext_as = 0;
generate if (C_USE_EMBEDDED_REG < 3) begin: rdc_fwft_ext_both
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= 0;
end else begin
if (!stage2_valid)
rdc_fwft_ext_as <= #`TCQ 0;
else if (!stage1_valid && stage2_valid)
rdc_fwft_ext_as <= #`TCQ 1;
else
rdc_fwft_ext_as <= #`TCQ diff_rd_wr + 2'h2;
end
end // always @ (posedge WR_CLK or posedge WR_CLK)
end // rdc_fwft_ext
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3) begin
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr_1;
// assign diff_rd_wr_1 = diff_rd_wr +2'h2;
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= #`TCQ 0;
end else begin
//if (fab_read_data_valid_i == 1'b0 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b0;
//else if (fab_read_data_valid_i == 1'b1 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b1;
//else
rdc_fwft_ext_as <= diff_rd_wr + 2'h2 ;
end
end
end
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = C_USE_FWFT_DATA_COUNT ?
rdc_fwft_ext_as[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH] :
rd_data_count_int[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = (C_USE_FWFT_DATA_COUNT == 1) ?
wdc_fwft_ext_as[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] :
wr_data_count_int[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate
if (C_HAS_VALID==1) begin : blockVL2
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_d2 <= 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
valid_d2 <= #`TCQ valid_d1;
end
// if (C_USE_EMBEDDED_REG == 3 && (C_EN_SAFETY_CKT == 0 || C_EN_SAFETY_CKT == 1 ) begin
// valid_d2 <= #`TCQ valid_d1;
// end
end
end
endgenerate
//Capture delayed version of dout
/**************************************************************************
*embedded/fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG < 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0)
err_type_d1 <= #`TCQ 0;
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
endgenerate
/**************************************************************************
*embedded + fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG == 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate
if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge WR_CLK) begin
ideal_overflow <= #`TCQ WR_EN & FULL;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge WR_CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (FULL | wr_rst_i);
ideal_overflow <= #`TCQ WR_EN & (FULL );
end
end
endgenerate
generate
if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ EMPTY & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ (EMPTY) & RD_EN;
//ideal_underflow <= #`TCQ (rd_rst_i | EMPTY) & RD_EN;
end
end
endgenerate
/**************************************************************************
* Write/Read Pointer Synchronization
**************************************************************************/
localparam NO_OF_SYNC_STAGE_INC_G2B = C_SYNCHRONIZER_STAGE + 1;
wire [C_WR_PNTR_WIDTH-1:0] wr_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
genvar gss;
generate for (gss = 1; gss <= NO_OF_SYNC_STAGE_INC_G2B; gss = gss + 1) begin : Sync_stage_inst
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_WR_PNTR_WIDTH)
)
rd_stg_inst
(
.RST (rd_rst_i),
.CLK (RD_CLK),
.DIN (wr_pntr_sync_stgs[gss-1]),
.DOUT (wr_pntr_sync_stgs[gss])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_RD_PNTR_WIDTH)
)
wr_stg_inst
(
.RST (wr_rst_i),
.CLK (WR_CLK),
.DIN (rd_pntr_sync_stgs[gss-1]),
.DOUT (rd_pntr_sync_stgs[gss])
);
end endgenerate // Sync_stage_inst
assign wr_pntr_sync_stgs[0] = wr_pntr_rd1;
assign rd_pntr_sync_stgs[0] = rd_pntr_wr1;
always@* begin
wr_pntr_rd <= wr_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
rd_pntr_wr <= rd_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
end
/**************************************************************************
* Write Domain Logic
**************************************************************************/
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_wp
if (wr_rst_i == 1'b1 && C_EN_SAFETY_CKT == 0)
wr_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_WR_RST == 1'b1)
wr_pntr <= #`TCQ 0;
end
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (wr_rst_i == 1'b1) begin
num_wr_bits <= 0;
next_num_wr_bits = 0;
wr_ptr <= C_WR_DEPTH - 1;
rd_ptr_wrclk <= C_RD_DEPTH - 1;
ideal_wr_ack <= 0;
ideal_wr_count <= 0;
tmp_wr_listsize = 0;
rd_ptr_wrclk_next <= 0;
wr_pntr_rd1 <= 0;
end else begin //wr_rst_i==0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
//If this is a write, handle the write by adding the value
// to the linked list, and updating all outputs appropriately
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD
>= C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full, but reporting full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//With DEPTH-1 words in the FIFO, it is almost_full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is completely empty, but it is
// reporting FULL for some reason (like reset)
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <=
C_FIFO_WR_DEPTH-2) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//FIFO is really not close to full, so change flag status.
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end //(tmp_wr_listsize == 0)
end else begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD >=
C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//This write is CAUSING the FIFO to go full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is 2 from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Still 2 from full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is not close to being full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //wr_rst_i==0
end // gen_fifo_w
/***************************************************************************
* Programmable FULL flags
***************************************************************************/
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_assert_val;
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_negate_val;
generate if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin : FWFT
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_DC;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_DC;
end else begin // STD
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL;
end endgenerate
always @(posedge WR_CLK or posedge wr_rst_i) begin
if (wr_rst_i == 1'b1) begin
diff_pntr <= 0;
end else begin
if (ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr + 2'h1);
else if (!ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr);
end
end
always @(posedge WR_CLK or posedge RST_FULL_FF) begin : gen_pf
if (RST_FULL_FF == 1'b1) begin
ideal_prog_full <= C_FULL_FLAGS_RST_VAL;
end else begin
if (RST_FULL_GEN)
ideal_prog_full <= #`TCQ 0;
//Single Programmable Full Constant Threshold
else if (C_PROG_FULL_TYPE == 1) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Constant Thresholds
end else if (C_PROG_FULL_TYPE == 2) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < pf_thr_negate_val)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Single Programmable Full Threshold Input
end else if (C_PROG_FULL_TYPE == 3) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Threshold Inputs
end else if (C_PROG_FULL_TYPE == 4) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH_ASSERT - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < (PROG_FULL_THRESH_NEGATE - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH_ASSERT)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < PROG_FULL_THRESH_NEGATE)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
end // C_PROG_FULL_TYPE
end //wr_rst_i==0
end //
/**************************************************************************
* Read Domain Logic
**************************************************************************/
/*********************************************************
* Programmable EMPTY flags
*********************************************************/
//Determine the Assert and Negate thresholds for Programmable Empty
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_assert_val;
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_negate_val;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_rd = 0;
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_pe
if (rd_rst_i) begin
diff_pntr_rd <= 0;
ideal_prog_empty <= 1'b1;
end else begin
if (ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr) - 1'h1;
else if (!ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr);
else
diff_pntr_rd <= #`TCQ diff_pntr_rd;
if (C_PROG_EMPTY_TYPE == 1) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 2) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 3) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 4) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end //C_PROG_EMPTY_TYPE
end
end // gen_pe
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH - 2'h2 : PROG_EMPTY_THRESH;
end endgenerate // single_pe_thr_input
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_ASSERT - 2'h2 : PROG_EMPTY_THRESH_ASSERT;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_NEGATE - 2'h2 : PROG_EMPTY_THRESH_NEGATE;
end endgenerate // multiple_pe_thr_input
generate if (C_PROG_EMPTY_TYPE < 3) begin : single_multiple_pe_thr_const
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2'h2 : C_PROG_EMPTY_THRESH_ASSERT_VAL;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2'h2 : C_PROG_EMPTY_THRESH_NEGATE_VAL;
end endgenerate // single_multiple_pe_thr_const
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_rp
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
rd_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_RD_RST == 1'b1)
rd_pntr <= #`TCQ 0;
end
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_r_as
/****** Reset fifo (case 1)***************************************/
if (rd_rst_i) begin
num_rd_bits <= 0;
next_num_rd_bits = 0;
rd_ptr <= C_RD_DEPTH -1;
rd_pntr_wr1 <= 0;
wr_ptr_rdclk <= C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_MEMORY_TYPE == 2 && C_USE_DOUT_RST == 1)
ideal_dout <= dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= 1'b0;
ideal_rd_count <= 0;
end else begin //rd_rst_i==0
rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
/*****************************************************************/
// Read Operation - Read Latency 1
/*****************************************************************/
if (C_PRELOAD_LATENCY==1 || C_PRELOAD_LATENCY==2) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
//If the FIFO is one from empty, but it is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is two from empty, and is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH))
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end // else: if(ideal_empty == 1'b1)
else //if (ideal_empty == 1'b0)
begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == C_FIFO_RD_DEPTH)
//If the FIFO is not close to being empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
//If the FIFO is two from empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is one from empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR == 1))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is completely empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end //(RD_EN == 1'b1)
else //if (RD_EN == 1'b0)
begin
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
/*****************************************************************/
// Read Operation - Read Latency 0
/*****************************************************************/
end else if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty, but it is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty, and is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH)) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end else begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to being empty
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH)) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is completely empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end else begin//(RD_EN == 1'b0)
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
end //if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0)
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //rd_rst_i==0
end //always gen_fifo_r_as
endmodule // fifo_generator_v13_1_3_bhv_ver_as
/*******************************************************************************
* Declaration of Low Latency Asynchronous FIFO
******************************************************************************/
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_USE_DOUT_RST = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_FIFO_TYPE = 0
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input [C_DIN_WIDTH-1:0] DIN,
input RD_CLK,
input RD_EN,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
output reg [C_DOUT_WIDTH-1:0] DOUT = 0,
output reg EMPTY = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL
);
//-----------------------------------------------------------------------------
// Low Latency Asynchronous FIFO
//-----------------------------------------------------------------------------
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
integer i;
initial begin
for (i = 0; i < C_WR_DEPTH; i = i + 1)
memory[i] = 0;
end
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_ll_afifo = 0;
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo_q = 0;
reg ll_afifo_full = 1'b0;
reg ll_afifo_empty = 1'b1;
wire write_allow;
wire read_allow;
assign write_allow = WR_EN & ~ll_afifo_full;
assign read_allow = RD_EN & ~ll_afifo_empty;
//-----------------------------------------------------------------------------
// Write Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
wr_pntr_ll_afifo <= 0;
else if (write_allow)
wr_pntr_ll_afifo <= #`TCQ wr_pntr_ll_afifo + 1;
end
//-----------------------------------------------------------------------------
// Read Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
rd_pntr_ll_afifo_q <= 0;
else
rd_pntr_ll_afifo_q <= #`TCQ rd_pntr_ll_afifo;
end
assign rd_pntr_ll_afifo = read_allow ? rd_pntr_ll_afifo_q + 1 : rd_pntr_ll_afifo_q;
//-----------------------------------------------------------------------------
// Fill the Memory
//-----------------------------------------------------------------------------
always @(posedge WR_CLK) begin
if (write_allow)
memory[wr_pntr_ll_afifo] <= #`TCQ DIN;
end
//-----------------------------------------------------------------------------
// Generate DOUT
//-----------------------------------------------------------------------------
always @(posedge RD_CLK) begin
DOUT <= #`TCQ memory[rd_pntr_ll_afifo];
end
//-----------------------------------------------------------------------------
// Generate EMPTY
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
ll_afifo_empty <= 1'b1;
else
ll_afifo_empty <= ((wr_pntr_ll_afifo == rd_pntr_ll_afifo_q) |
(read_allow & (wr_pntr_ll_afifo == (rd_pntr_ll_afifo_q + 2'h1))));
end
//-----------------------------------------------------------------------------
// Generate FULL
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
ll_afifo_full <= 1'b1;
else
ll_afifo_full <= ((rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h1)) |
(write_allow & (rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h2))));
end
always @* begin
FULL <= ll_afifo_full;
EMPTY <= ll_afifo_empty;
end
endmodule // fifo_generator_v13_1_3_beh_ver_ll_afifo
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* Declare user parameters and their defaults
*************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
/**************************************************************************
* Declare Input and Output Ports
*************************************************************************/
(
//Inputs
input SAFETY_CKT_WR_RST,
input CLK,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_EN,
input RD_EN_USER,
input USER_EMPTY_FB,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input SRST,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input WR_RST_BUSY,
input RD_RST_BUSY,
//Outputs
output ALMOST_EMPTY,
output ALMOST_FULL,
output reg [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT = 0,
output [C_DOUT_WIDTH-1:0] DOUT,
output EMPTY,
output reg EMPTY_FB = 1'b1,
output FULL,
output OVERFLOW,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output UNDERFLOW,
output WR_ACK,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
wire [C_RD_PNTR_WIDTH:0] rd_data_count_i_ss;
wire [C_WR_PNTR_WIDTH:0] wr_data_count_i_ss;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
//localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
//localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
localparam C_GRTR_PNTR_WIDTH = (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH ;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
wire [C_WR_PNTR_WIDTH:0] EXTRA_WORDS_PF = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//wire [C_RD_PNTR_WIDTH:0] EXTRA_WORDS_PE = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam EXTRA_WORDS_PF_PARAM = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//localparam EXTRA_WORDS_PE_PARAM = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
//The reset value assignments for FULL, ALMOST_FULL, and PROG_FULL are not
//changed for v3.2(IP2_Im). When the core has Sync Reset, C_HAS_SRST=1 and C_HAS_RST=0.
// Therefore, during SRST, all the FULL flags reset to 0.
localparam C_HAS_FAST_FIFO = 0;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH;
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC && SYMMETRIC_PORT && ERR_INJECTION;
localparam C_DATA_WIDTH = (ENABLE_ERR_INJECTION == 1) ? (C_DIN_WIDTH+2) : C_DIN_WIDTH;
localparam IS_ASYMMETRY = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 0 : 1;
localparam LESSER_WIDTH = (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
localparam [C_RD_PNTR_WIDTH-1 : 0] DIFF_MAX_RD = {C_RD_PNTR_WIDTH{1'b1}};
localparam [C_WR_PNTR_WIDTH-1 : 0] DIFF_MAX_WR = {C_WR_PNTR_WIDTH{1'b1}};
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
/**************************************************************************
* Internal Registers and wires
*************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire underflow_i;
wire valid_i;
wire valid_out;
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_reg = 1'b0;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
wire srst_rrst_busy;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire fwft_enabled;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg full_i = C_FULL_FLAGS_RST_VAL;
reg full_i_temp = 0;
reg empty_i = 1;
reg almost_full_i = 0;
reg almost_empty_i = 1;
reg prog_full_i = 0;
reg prog_empty_i = 1;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] diff_count = 0;
reg write_allow_q = 0;
reg read_allow_q = 0;
reg valid_d1 = 0;
reg valid_both = 0;
reg valid_d2 = 0;
wire rst_i;
wire srst_i;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
/****************************************************************************
* Function Declarations
***************************************************************************/
/****************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***************************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 ) begin
case (def_data[7:0])
8'b00000000 : begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default : begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1) begin
if ((index*4)+j < C_DOUT_WIDTH) begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
//reg valid_d1 = 0;
//user specified value for reseting the size of the fifo
//reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_dout_both = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_both = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_EN;
wire RST;
wire WR_EN;
*/
// Assign ALMOST_EPMTY
generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae
assign ALMOST_EMPTY = almost_empty_i;
end else begin : gnae
assign ALMOST_EMPTY = 0;
end endgenerate // gae
// Assign ALMOST_FULL
generate if (C_HAS_ALMOST_FULL==1) begin : gaf
assign ALMOST_FULL = almost_full_i;
end else begin : gnaf
assign ALMOST_FULL = 0;
end endgenerate // gaf
// Dout may change behavior based on latency
localparam C_FWFT_ENABLED = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign fwft_enabled = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign ideal_dout_out= ((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1))?
ideal_dout_d1: ideal_dout;
assign DOUT = ideal_dout_out;
// Assign SBITERR and DBITERR based on latency
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
assign EMPTY = empty_i;
assign FULL = full_i;
//saftey_ckt with one register
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && (C_USE_EMBEDDED_REG == 1 || C_USE_EMBEDDED_REG == 2 )) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK)
begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK)
begin
if( rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end
else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
valid_d1 <= #`TCQ valid_i;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end //if
endgenerate
//safety ckt with both registers
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK) begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end //if
endgenerate
//Overflow may be active-low
generate if (C_HAS_OVERFLOW==1) begin : gof
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end else begin : gnof
assign OVERFLOW = 0;
end endgenerate // gof
assign PROG_EMPTY = prog_empty_i;
assign PROG_FULL = prog_full_i;
//Valid may change behavior based on latency or active-low
generate if (C_HAS_VALID==1) begin : gvalid
assign valid_i = (C_PRELOAD_LATENCY == 0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out = (C_PRELOAD_LATENCY == 2 && C_MEMORY_TYPE < 2) ?
valid_d1 : valid_i;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end else begin : gnvalid
assign VALID = 0;
end endgenerate // gvalid
//Trim data count differently depending on set widths
generate if (C_HAS_DATA_COUNT == 1) begin : gdc
always @* begin
diff_count <= wr_pntr - rd_pntr;
if (C_DATA_COUNT_WIDTH > C_RD_PNTR_WIDTH) begin
DATA_COUNT[C_RD_PNTR_WIDTH-1:0] <= diff_count;
DATA_COUNT[C_DATA_COUNT_WIDTH-1] <= 1'b0 ;
end else begin
DATA_COUNT <= diff_count[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH];
end
end
// end else begin : gndc
// always @* DATA_COUNT <= 0;
end endgenerate // gdc
//Underflow may change behavior based on latency or active-low
generate if (C_HAS_UNDERFLOW==1) begin : guf
assign underflow_i = ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end else begin : gnuf
assign UNDERFLOW = 0;
end endgenerate // guf
//Write acknowledge may be active low
generate if (C_HAS_WR_ACK==1) begin : gwr_ack
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end else begin : gnwr_ack
assign WR_ACK = 0;
end endgenerate // gwr_ack
/*****************************************************************************
* Internal reset logic
****************************************************************************/
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_WR_RST : C_HAS_SRST ? (SRST | WR_RST_BUSY) : 0;
assign rst_i = C_HAS_RST ? RST : 0;
assign srst_wrst_busy = srst_i;
assign srst_rrst_busy = srst_i;
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG <3)) begin : blockVL20
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG == 3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_both <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
valid_both <= #`TCQ 1'b0;
end else begin
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge CLK or posedge rst_i) begin
if (rst_i) begin
stage1_valid <= #`TCQ 0;
stage2_valid <= #`TCQ 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT ==1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = rd_data_count_i_ss[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = wr_data_count_i_ss[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] ;
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//reg ram_rd_en_d1 = 1'b0;
//Capture delayed version of dout
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG<3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
ram_rd_en_d1 <= #`TCQ 1'b0;
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
end // always
end
endgenerate
//no safety ckt with both registers
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG==3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
fab_rd_en_d1 <= #`TCQ (ram_rd_en_d1);
if (ram_rd_en_d1 ) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end // always
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge CLK) begin
ideal_overflow <= #`TCQ WR_EN & full_i;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (rst_i | full_i);
ideal_overflow <= #`TCQ WR_EN & (WR_RST_BUSY | full_i);
end
end endgenerate // blockOF20
generate if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge CLK) begin
ideal_underflow <= #`TCQ empty_i & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge CLK) begin
//ideal_underflow <= #`TCQ (rst_i | empty_i) & RD_EN;
ideal_underflow <= #`TCQ (RD_RST_BUSY | empty_i) & RD_EN;
end
end endgenerate // blockUF20
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/*************************************************************************
* Write and Read Logic
************************************************************************/
wire write_allow;
wire read_allow;
wire read_allow_dc;
wire write_only;
wire read_only;
//wire write_only_q;
reg write_only_q;
//wire read_only_q;
reg read_only_q;
reg full_reg;
reg rst_full_ff_reg1;
reg rst_full_ff_reg2;
wire ram_full_comb;
wire carry;
assign write_allow = WR_EN & ~full_i;
assign read_allow = RD_EN & ~empty_i;
assign read_allow_dc = RD_EN_USER & ~USER_EMPTY_FB;
//assign write_only = write_allow & ~read_allow;
//assign write_only_q = write_allow_q;
//assign read_only = read_allow & ~write_allow;
//assign read_only_q = read_allow_q ;
wire [C_WR_PNTR_WIDTH-1:0] diff_pntr;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_reg1 = 0;
reg [C_RD_PNTR_WIDTH:0] diff_pntr_pe_asym = 0;
wire [C_RD_PNTR_WIDTH:0] adj_wr_pntr_rd_asym ;
wire [C_RD_PNTR_WIDTH:0] rd_pntr_asym;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_pe_reg2 = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_max;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_max;
assign diff_pntr_pe_max = DIFF_MAX_RD;
assign diff_pntr_max = DIFF_MAX_WR;
generate if (IS_ASYMMETRY == 0) begin : diff_pntr_sym
assign write_only = write_allow & ~read_allow;
assign read_only = read_allow & ~write_allow;
end endgenerate
generate if ( IS_ASYMMETRY == 1 && C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : wr_grt_rd
assign read_only = read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]) & ~write_allow;
assign write_only = write_allow & ~(read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (IS_ASYMMETRY ==1 && C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : rd_grt_wr
assign read_only = read_allow & ~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
assign write_only = write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]) & ~read_allow;
end endgenerate
//-----------------------------------------------------------------------------
// Write and Read pointer generation
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
wr_pntr <= 0;
rd_pntr <= 0;
end else begin
if (srst_i) begin
wr_pntr <= #`TCQ 0;
rd_pntr <= #`TCQ 0;
end else begin
if (write_allow) wr_pntr <= #`TCQ wr_pntr + 1;
if (read_allow) rd_pntr <= #`TCQ rd_pntr + 1;
end
end
end
generate if (C_FIFO_TYPE == 2) begin : gll_dm_dout
always @(posedge CLK) begin
if (write_allow) begin
if (ENABLE_ERR_INJECTION == 1)
memory[wr_pntr] <= #`TCQ {INJECTDBITERR,INJECTSBITERR,DIN};
else
memory[wr_pntr] <= #`TCQ DIN;
end
end
reg [C_DATA_WIDTH-1:0] dout_tmp_q;
reg [C_DATA_WIDTH-1:0] dout_tmp = 0;
reg [C_DATA_WIDTH-1:0] dout_tmp1 = 0;
always @(posedge CLK) begin
dout_tmp_q <= #`TCQ ideal_dout;
end
always @* begin
if (read_allow)
ideal_dout <= memory[rd_pntr];
else
ideal_dout <= dout_tmp_q;
end
end endgenerate // gll_dm_dout
/**************************************************************************
* Write Domain Logic
**************************************************************************/
assign ram_rd_en = RD_EN & !EMPTY;
//reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
generate if (C_FIFO_TYPE != 2) begin : gnll_din
always @(posedge CLK or posedge rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (rst_i == 1'b1) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin //rst_i==0
if (srst_wrst_busy) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin//srst_i=0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end else begin
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
//end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //srst_i==0
end //wr_rst_i==0
end // gen_fifo_w
end endgenerate
generate if (C_FIFO_TYPE < 2 && C_MEMORY_TYPE < 2) begin : gnll_dm_dout
always @(posedge CLK) begin
if (rst_i || srst_rrst_busy) begin
if (C_USE_DOUT_RST == 1) begin
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end
end
end endgenerate
generate if (C_FIFO_TYPE != 2) begin : gnll_dout
always @(posedge CLK or posedge rst_i) begin : gen_fifo_r
/****** Reset fifo (case 1)***************************************/
if (rst_i) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end else begin //rd_rst_i==0
if (srst_rrst_busy) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets synchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end //srst_i
else begin
//rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
if (RD_EN == 1'b1) begin
if (EMPTY == 1'b1) begin
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end
else
begin
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
end
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //s_rst_i==0
end //rd_rst_i==0
end //always
end endgenerate
//-----------------------------------------------------------------------------
// Generate diff_pntr for PROG_FULL generation
// Generate diff_pntr_pe for PROG_EMPTY generation
//-----------------------------------------------------------------------------
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 0) begin : reg_write_allow
always @(posedge CLK ) begin
if (rst_i) begin
write_only_q <= 1'b0;
read_only_q <= 1'b0;
diff_pntr_reg1 <= 0;
diff_pntr_pe_reg1 <= 0;
diff_pntr_reg2 <= 0;
diff_pntr_pe_reg2 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_rrst_busy) begin
read_only_q <= #`TCQ 1'b0;
diff_pntr_pe_reg1 <= #`TCQ 0;
diff_pntr_pe_reg2 <= #`TCQ 0;
end
if (srst_wrst_busy) begin
write_only_q <= #`TCQ 1'b0;
diff_pntr_reg1 <= #`TCQ 0;
diff_pntr_reg2 <= #`TCQ 0;
end
end else begin
write_only_q <= #`TCQ write_only;
read_only_q <= #`TCQ read_only;
diff_pntr_reg2 <= #`TCQ diff_pntr_reg1;
diff_pntr_pe_reg2 <= #`TCQ diff_pntr_pe_reg1;
// Add 1 to the difference pointer value when only write happens.
if (write_only)
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr + 1;
else
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
// Add 1 to the difference pointer value when write or both write & read or no write & read happen.
if (read_only)
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr - 1;
else
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr;
end
end
end
assign diff_pntr_pe = diff_pntr_pe_reg1;
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 1) begin : reg_write_allow_asym
assign adj_wr_pntr_rd_asym[C_RD_PNTR_WIDTH:0] = {adj_wr_pntr_rd,1'b1};
assign rd_pntr_asym[C_RD_PNTR_WIDTH:0] = {~rd_pntr,1'b1};
always @(posedge CLK ) begin
if (rst_i) begin
diff_pntr_pe_asym <= 0;
diff_pntr_reg1 <= 0;
full_reg <= 0;
rst_full_ff_reg1 <= 1;
rst_full_ff_reg2 <= 1;
diff_pntr_pe_reg1 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_wrst_busy)
diff_pntr_reg1 <= #`TCQ 0;
if (srst_rrst_busy)
full_reg <= #`TCQ 0;
rst_full_ff_reg1 <= #`TCQ 1;
rst_full_ff_reg2 <= #`TCQ 1;
diff_pntr_pe_asym <= #`TCQ 0;
diff_pntr_pe_reg1 <= #`TCQ 0;
end else begin
diff_pntr_pe_asym <= #`TCQ adj_wr_pntr_rd_asym + rd_pntr_asym;
full_reg <= #`TCQ full_i;
rst_full_ff_reg1 <= #`TCQ RST_FULL_FF;
rst_full_ff_reg2 <= #`TCQ rst_full_ff_reg1;
if (~full_i) begin
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
end
end
end
end
assign carry = (~(|(diff_pntr_pe_asym [C_RD_PNTR_WIDTH : 1])));
assign diff_pntr_pe = (full_reg && ~rst_full_ff_reg2 && carry ) ? diff_pntr_pe_max : diff_pntr_pe_asym[C_RD_PNTR_WIDTH:1];
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow_asym
//-----------------------------------------------------------------------------
// Generate FULL flag
//-----------------------------------------------------------------------------
wire comp0;
wire comp1;
wire going_full;
wire leaving_full;
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gpad
assign adj_rd_pntr_wr [C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_WR_PNTR_WIDTH <= C_RD_PNTR_WIDTH) begin : gtrim
assign adj_rd_pntr_wr = rd_pntr[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
assign comp1 = (adj_rd_pntr_wr == (wr_pntr + 1'b1));
assign comp0 = (adj_rd_pntr_wr == wr_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gf_wp_eq_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full = (comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gf_asym
assign going_full = (comp1 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_full = (comp0 & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gf_wp_gt_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full =(comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_full_comb = going_full | (~leaving_full & full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
full_i <= #`TCQ ram_full_comb;
end
//-----------------------------------------------------------------------------
// Generate EMPTY flag
//-----------------------------------------------------------------------------
wire ecomp0;
wire ecomp1;
wire going_empty;
wire leaving_empty;
wire ram_empty_comb;
generate if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : pad
assign adj_wr_pntr_rd [C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_RD_PNTR_WIDTH <= C_WR_PNTR_WIDTH) begin : trim
assign adj_wr_pntr_rd = wr_pntr[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
assign ecomp1 = (adj_wr_pntr_rd == (rd_pntr + 1'b1));
assign ecomp0 = (adj_wr_pntr_rd == rd_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : ge_wp_eq_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty = (ecomp0 & write_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : ge_wp_gt_rp
assign going_empty = (ecomp1 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_empty = (ecomp0 & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : ge_wp_lt_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty =(ecomp0 & write_allow);
end endgenerate
assign ram_empty_comb = going_empty | (~leaving_empty & empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
empty_i <= 1'b1;
else if (srst_rrst_busy)
empty_i <= #`TCQ 1'b1;
else
empty_i <= #`TCQ ram_empty_comb;
end
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (srst_rrst_busy || (SAFETY_CKT_WR_RST && C_EN_SAFETY_CKT))
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ ram_empty_comb;
end
end // always
//-----------------------------------------------------------------------------
// Generate Read and write data counts for asymmetic common clock
//-----------------------------------------------------------------------------
reg [C_GRTR_PNTR_WIDTH :0] count_dc = 0;
wire [C_GRTR_PNTR_WIDTH :0] ratio;
wire decr_by_one;
wire incr_by_ratio;
wire incr_by_one;
wire decr_by_ratio;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : rd_depth_gt_wr
assign ratio = C_DEPTH_RATIO_RD;
assign decr_by_one = (IS_FWFT == 1)? read_allow_dc : read_allow;
assign incr_by_ratio = write_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (decr_by_one) begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc - 1;
else
count_dc <= #`TCQ count_dc - 1 + ratio ;
end
else begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc + ratio ;
end
end
end
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc;
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wr_depth_gt_rd
assign ratio = C_DEPTH_RATIO_WR;
assign incr_by_one = write_allow;
assign decr_by_ratio = (IS_FWFT == 1)? read_allow_dc : read_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (incr_by_one) begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc + 1;
else
count_dc <= #`TCQ count_dc + 1 - ratio ;
end
else begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc - ratio ;
end
end
end
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc;
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
//-----------------------------------------------------------------------------
// Generate WR_ACK flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_wr_ack <= 1'b0;
else if (srst_wrst_busy)
ideal_wr_ack <= #`TCQ 1'b0;
else if (WR_EN & ~full_i)
ideal_wr_ack <= #`TCQ 1'b1;
else
ideal_wr_ack <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate VALID flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_valid <= 1'b0;
else if (srst_rrst_busy)
ideal_valid <= #`TCQ 1'b0;
else if (RD_EN & ~empty_i)
ideal_valid <= #`TCQ 1'b1;
else
ideal_valid <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate ALMOST_FULL flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_FULL == 1 || C_PROG_FULL_TYPE > 2 || C_PROG_EMPTY_TYPE > 2) begin : gaf_ss
wire fcomp2;
wire going_afull;
wire leaving_afull;
wire ram_afull_comb;
assign fcomp2 = (adj_rd_pntr_wr == (wr_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gaf_wp_eq_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull = (comp1 & read_allow & ~write_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gaf_asym
assign going_afull = (fcomp2 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_afull = (comp1 & (~write_allow) & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gaf_wp_gt_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull =((comp0 | comp1 | fcomp2) & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_afull_comb = going_afull | (~leaving_afull & almost_full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
almost_full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
almost_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
almost_full_i <= #`TCQ ram_afull_comb;
end
// end endgenerate // gaf_ss
//-----------------------------------------------------------------------------
// Generate ALMOST_EMPTY flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae_ss
wire ecomp2;
wire going_aempty;
wire leaving_aempty;
wire ram_aempty_comb;
assign ecomp2 = (adj_wr_pntr_rd == (rd_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gae_wp_eq_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty = (ecomp1 & write_allow & ~read_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gae_wp_gt_rp
assign going_aempty = (ecomp2 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_aempty = (ecomp1 & ~read_allow & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gae_wp_lt_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty =((ecomp2 | ecomp1 |ecomp0) & write_allow);
end endgenerate
assign ram_aempty_comb = going_aempty | (~leaving_aempty & almost_empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
almost_empty_i <= 1'b1;
else if (srst_rrst_busy)
almost_empty_i <= #`TCQ 1'b1;
else
almost_empty_i <= #`TCQ ram_aempty_comb;
end
// end endgenerate // gae_ss
//-----------------------------------------------------------------------------
// Generate PROG_FULL
//-----------------------------------------------------------------------------
localparam C_PF_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_PF_PARAM : // FWFT
C_PROG_FULL_THRESH_ASSERT_VAL; // STD
localparam C_PF_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_PF_PARAM: // FWFT
C_PROG_FULL_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold constant
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] temp = C_PF_ASSERT_VAL;
generate if (C_PROG_FULL_TYPE == 1) begin : single_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_ASSERT_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr>= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr) < C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b0;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate // single_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_FULL_TYPE == 2) begin : multiple_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_NEGATE_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr >= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < C_PF_NEGATE_VAL)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf3_assert_val = (C_PRELOAD_LATENCY == 0) ?
PROG_FULL_THRESH - EXTRA_WORDS_PF: // FWFT
PROG_FULL_THRESH; // STD
generate if (C_PROG_FULL_TYPE == 3) begin : single_pf_input
always @(posedge CLK or posedge RST_FULL_FF) begin//0
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin //1
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin//2
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin//3
if (diff_pntr > pf3_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == pf3_assert_val) begin//4
if (read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b1;
end else//4
prog_full_i <= #`TCQ 1'b0;
end else//3
prog_full_i <= #`TCQ prog_full_i;
end //2
else begin//5
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin//6
if (diff_pntr >= pf3_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf3_assert_val) begin//7
prog_full_i <= #`TCQ 1'b0;
end//7
end//6
else
prog_full_i <= #`TCQ prog_full_i;
end//5
end//1
end//0
end endgenerate //single_pf_input
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_ASSERT -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_ASSERT; // STD
wire [C_WR_PNTR_WIDTH-1:0] pf_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_NEGATE -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_NEGATE; // STD
generate if (C_PROG_FULL_TYPE == 4) begin : multiple_pf_inputs
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin
if (diff_pntr >= pf_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr == pf_negate_val && read_only_q) ||
diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin
if (diff_pntr >= pf_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_inputs
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY
//-----------------------------------------------------------------------------
localparam C_PE_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_ASSERT_VAL; // STD
localparam C_PE_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold constant
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 1) begin : single_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_ASSERT_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b0;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 2) begin : multiple_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_NEGATE_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_NEGATE_VAL)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate //multiple_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe3_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH -2) : // FWFT
PROG_EMPTY_THRESH; // STD
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_input
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe < pe3_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == pe3_assert_val) begin
if (write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ 1'b1;
end else
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe3_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe3_assert_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_input
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe4_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_ASSERT - 2) : // FWFT
PROG_EMPTY_THRESH_ASSERT; // STD
wire [C_RD_PNTR_WIDTH-1:0] pe4_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_NEGATE - 2) : // FWFT
PROG_EMPTY_THRESH_NEGATE; // STD
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_inputs
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe <= pe4_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (((diff_pntr_pe == pe4_negate_val) && write_only_q) ||
(diff_pntr_pe > pe4_negate_val)) begin
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe4_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe4_negate_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // multiple_pe_inputs
endmodule // fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* First-Word Fall-Through module (preload 0)
**************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USERVALID_LOW = 0,
parameter C_USERUNDERFLOW_LOW = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
(
//Inputs
input SAFETY_CKT_RD_RST,
input RD_CLK,
input RD_RST,
input SRST,
input WR_RST_BUSY,
input RD_RST_BUSY,
input RD_EN,
input FIFOEMPTY,
input [C_DOUT_WIDTH-1:0] FIFODATA,
input FIFOSBITERR,
input FIFODBITERR,
//Outputs
output reg [C_DOUT_WIDTH-1:0] USERDATA,
output USERVALID,
output USERUNDERFLOW,
output USEREMPTY,
output USERALMOSTEMPTY,
output RAMVALID,
output FIFORDEN,
output reg USERSBITERR,
output reg USERDBITERR,
output reg STAGE2_REG_EN,
output fab_read_data_valid_i_o,
output read_data_valid_i_o,
output ram_valid_i_o,
output [1:0] VALID_STAGES
);
//Internal signals
wire preloadstage1;
wire preloadstage2;
reg ram_valid_i;
reg fab_valid;
reg read_data_valid_i;
reg fab_read_data_valid_i;
reg fab_read_data_valid_i_1;
reg ram_valid_i_d;
reg read_data_valid_i_d;
reg fab_read_data_valid_i_d;
wire ram_regout_en;
reg ram_regout_en_d1;
reg ram_regout_en_d2;
wire fab_regout_en;
wire ram_rd_en;
reg empty_i = 1'b1;
reg empty_sckt = 1'b1;
reg sckt_rrst_q = 1'b0;
reg sckt_rrst_done = 1'b0;
reg empty_q = 1'b1;
reg rd_en_q = 1'b0;
reg almost_empty_i = 1'b1;
reg almost_empty_q = 1'b1;
wire rd_rst_i;
wire srst_i;
reg [C_DOUT_WIDTH-1:0] userdata_both;
wire uservalid_both;
wire uservalid_one;
reg user_sbiterr_both = 1'b0;
reg user_dbiterr_both = 1'b0;
assign ram_valid_i_o = ram_valid_i;
assign read_data_valid_i_o = read_data_valid_i;
assign fab_read_data_valid_i_o = fab_read_data_valid_i;
/*************************************************************************
* FUNCTIONS
*************************************************************************/
/*************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
//*************************************************************************
// Set power-on states for regs
//*************************************************************************
initial begin
ram_valid_i = 1'b0;
fab_valid = 1'b0;
read_data_valid_i = 1'b0;
fab_read_data_valid_i = 1'b0;
fab_read_data_valid_i_1 = 1'b0;
USERDATA = hexstr_conv(C_DOUT_RST_VAL);
userdata_both = hexstr_conv(C_DOUT_RST_VAL);
USERSBITERR = 1'b0;
USERDBITERR = 1'b0;
user_sbiterr_both = 1'b0;
user_dbiterr_both = 1'b0;
end //initial
//***************************************************************************
// connect up optional reset
//***************************************************************************
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? RD_RST : 0;
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_RD_RST : C_HAS_SRST ? SRST : 0;
reg sckt_rd_rst_fwft = 1'b0;
reg fwft_rst_done_i = 1'b0;
wire fwft_rst_done;
assign fwft_rst_done = C_EN_SAFETY_CKT ? fwft_rst_done_i : 1'b1;
always @ (posedge RD_CLK) begin
sckt_rd_rst_fwft <= #`TCQ SAFETY_CKT_RD_RST;
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i)
fwft_rst_done_i <= 1'b0;
else if (sckt_rd_rst_fwft & ~SAFETY_CKT_RD_RST)
fwft_rst_done_i <= #`TCQ 1'b1;
end
localparam INVALID = 0;
localparam STAGE1_VALID = 2;
localparam STAGE2_VALID = 1;
localparam BOTH_STAGES_VALID = 3;
reg [1:0] curr_fwft_state = INVALID;
reg [1:0] next_fwft_state = INVALID;
generate if (C_USE_EMBEDDED_REG < 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = preloadstage2;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = (RD_EN & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
reg curr_state = 0;
reg next_state = 0;
reg leaving_empty_fwft = 0;
reg going_empty_fwft = 0;
reg empty_i_q = 0;
reg ram_rd_en_fwft = 0;
generate if (C_FIFO_TYPE == 2) begin : gll_fifo
always @* begin // FSM fo FWFT
case (curr_state)
1'b0: begin
if (~FIFOEMPTY)
next_state <= 1'b1;
else
next_state <= 1'b0;
end
1'b1: begin
if (FIFOEMPTY && RD_EN)
next_state <= 1'b0;
else
next_state <= 1'b1;
end
default: next_state <= 1'b0;
endcase
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_i <= 1'b1;
empty_i_q <= 1'b1;
ram_valid_i <= 1'b0;
end else if (srst_i) begin
empty_i <= #`TCQ 1'b1;
empty_i_q <= #`TCQ 1'b1;
ram_valid_i <= #`TCQ 1'b0;
end else begin
empty_i <= #`TCQ going_empty_fwft | (~leaving_empty_fwft & empty_i);
empty_i_q <= #`TCQ FIFOEMPTY;
ram_valid_i <= #`TCQ next_state;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
curr_state <= 1'b0;
end else if (srst_i) begin
curr_state <= #`TCQ 1'b0;
end else begin
curr_state <= #`TCQ next_state;
end
end //always
wire fe_of_empty;
assign fe_of_empty = empty_i_q & ~FIFOEMPTY;
always @* begin // Finding leaving empty
case (curr_state)
1'b0: leaving_empty_fwft <= fe_of_empty;
1'b1: leaving_empty_fwft <= 1'b1;
default: leaving_empty_fwft <= 1'b0;
endcase
end
always @* begin // Finding going empty
case (curr_state)
1'b1: going_empty_fwft <= FIFOEMPTY & RD_EN;
default: going_empty_fwft <= 1'b0;
endcase
end
always @* begin // Generating FWFT rd_en
case (curr_state)
1'b0: ram_rd_en_fwft <= ~FIFOEMPTY;
1'b1: ram_rd_en_fwft <= ~FIFOEMPTY & RD_EN;
default: ram_rd_en_fwft <= 1'b0;
endcase
end
assign ram_regout_en = ram_rd_en_fwft;
//assign ram_regout_en_d1 = ram_rd_en_fwft;
//assign ram_regout_en_d2 = ram_rd_en_fwft;
assign ram_rd_en = ram_rd_en_fwft;
end endgenerate // gll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false.
// Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2) begin : gnll_fifo_ram_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (ram_rd_en == 1'b1) begin
ram_valid_i <= #`TCQ 1'b1;
end else begin
if (ram_regout_en == 1'b1)
ram_valid_i <= #`TCQ 1'b0;
else
ram_valid_i <= #`TCQ ram_valid_i;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_ram_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ ram_valid_i | (read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG < 3) begin : gnll_fifo_empty
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~ram_valid_i & ~read_data_valid_i) | (~ram_valid_i & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
generate if ( C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((ram_regout_en) | (~FIFOEMPTY & read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ FIFOEMPTY;
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
// BRAM resets synchronously
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG < 3) begin
always @ ( posedge rd_rst_i)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
//safety ckt with one register
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
//@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay
if (rd_rst_i == 1) begin
ram_regout_en_d1 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d1 <= #`TCQ 1'b0;
else
ram_regout_en_d1 <= #`TCQ ram_regout_en;
end
end //always
// assign fab_regout_en = ((ram_regout_en_d1 & ~(ram_regout_en_d2) & empty_i) | (RD_EN & !empty_i));
assign fab_regout_en = ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b0 )? 1'b1: ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1) ? RD_EN : 1'b0;
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay1
if (rd_rst_i == 1) begin
ram_regout_en_d2 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d2 <= #`TCQ 1'b0;
else
ram_regout_en_d2 <= #`TCQ ram_regout_en_d1;
end
end //always
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
always @ (posedge RD_CLK) begin
ram_valid_i_d <= #`TCQ ram_valid_i;
read_data_valid_i_d <= #`TCQ read_data_valid_i;
fab_read_data_valid_i_d <= #`TCQ fab_read_data_valid_i;
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = (ram_valid_i == 1'b1 && (read_data_valid_i == 1'b0 || fab_read_data_valid_i == 1'b0)) ? 1'b1 : (read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1 && ram_valid_i == 1'b1) ? RD_EN : 1'b0;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = ((RD_EN | ~ fab_read_data_valid_i) & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false // Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3) begin : gnll_fifo_fab_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (ram_regout_en == 1'b1) begin
fab_valid <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
fab_valid <= #`TCQ 1'b0;
else
fab_valid <= #`TCQ fab_valid;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_fab_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG == 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else begin
if (ram_regout_en == 1'b1) begin
read_data_valid_i <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ read_data_valid_i;
end
end
end //always
end
endgenerate
//generate if(C_USE_EMBEDDED_REG == 3) begin
// always @ (posedge RD_CLK or posedge rd_rst_i) begin
// if (rd_rst_i)
// read_data_valid_i <= #`TCQ 1'b0;
// else if (srst_i)
// read_data_valid_i <= #`TCQ 1'b0;
//
// if (ram_regout_en == 1'b1) begin
// fab_read_data_valid_i <= #`TCQ 1'b0;
// end else begin
// if (fab_regout_en == 1'b1)
// fab_read_data_valid_i <= #`TCQ 1'b1;
// else
// fab_read_data_valid_i <= #`TCQ fab_read_data_valid_i;
// end
// end //always
//end
//endgenerate
generate if(C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin :fabout_dvalid
if (rd_rst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else
fab_read_data_valid_i <= #`TCQ fab_valid | (fab_read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
always @ (posedge RD_CLK ) begin : proc_del1
begin
fab_read_data_valid_i_1 <= #`TCQ fab_read_data_valid_i;
end
end //always
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3 ) begin : gnll_fifo_empty_both
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~fab_valid & ~fab_read_data_valid_i) | (~fab_valid & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty_both
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
reg FIFOEMPTY_1;
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @(posedge RD_CLK) begin
FIFOEMPTY_1 <= #`TCQ FIFOEMPTY;
end
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((fab_regout_en) | (ram_valid_i & fab_read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ (~ram_valid_i);
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_sckt <= #`TCQ 1'b1;
sckt_rrst_q <= #`TCQ 1'b0;
sckt_rrst_done <= #`TCQ 1'b0;
end else begin
sckt_rrst_q <= #`TCQ SAFETY_CKT_RD_RST;
if (sckt_rrst_q && ~SAFETY_CKT_RD_RST) begin
sckt_rrst_done <= #`TCQ 1'b1;
end else if (sckt_rrst_done) begin
// rising clock edge
empty_sckt <= #`TCQ 1'b0;
end
end
end //always
// assign USEREMPTY = C_EN_SAFETY_CKT ? (sckt_rrst_done ? empty_i : empty_sckt) : empty_i;
assign USEREMPTY = empty_i;
assign USERALMOSTEMPTY = almost_empty_i;
assign FIFORDEN = ram_rd_en;
assign RAMVALID = (C_USE_EMBEDDED_REG == 3)? fab_valid : ram_valid_i;
assign uservalid_both = (C_USERVALID_LOW && C_USE_EMBEDDED_REG == 3) ? ~fab_read_data_valid_i : ((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG == 3) ? fab_read_data_valid_i : 1'b0);
assign uservalid_one = (C_USERVALID_LOW && C_USE_EMBEDDED_REG < 3) ? ~read_data_valid_i :((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG < 3) ? read_data_valid_i : 1'b0);
assign USERVALID = (C_USE_EMBEDDED_REG == 3) ? uservalid_both : uservalid_one;
assign USERUNDERFLOW = C_USERUNDERFLOW_LOW ? ~(empty_q & rd_en_q) : empty_q & rd_en_q;
//no safety ckt with both reg
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin
if (fwft_rst_done) begin
if (ram_regout_en) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end
end //always
end //if
endgenerate
//safety_ckt with both registers
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK) begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end //always
end //if
endgenerate
endmodule //fifo_generator_v13_1_3_bhv_ver_preload0
//-----------------------------------------------------------------------------
//
// Register Slice
// Register one AXI channel on forward and/or reverse signal path
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// reg_slice
//
//--------------------------------------------------------------------------
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
input wire S_VALID,
output wire S_READY,
// Master side
output wire [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA,
output wire M_VALID,
input wire M_READY
);
generate
////////////////////////////////////////////////////////////////////
//
// Both FWD and REV mode
//
////////////////////////////////////////////////////////////////////
if (C_REG_CONFIG == 32'h00000000)
begin
reg [1:0] state;
localparam [1:0]
ZERO = 2'b10,
ONE = 2'b11,
TWO = 2'b01;
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg [C_DATA_WIDTH-1:0] storage_data2 = 0;
reg load_s1;
wire load_s2;
wire load_s1_from_s2;
reg s_ready_i; //local signal of output
wire m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with either slave side data or from storage2
always @(posedge ACLK)
begin
if (load_s1)
if (load_s1_from_s2)
storage_data1 <= storage_data2;
else
storage_data1 <= S_PAYLOAD_DATA;
end
// Load storage2 with slave side data
always @(posedge ACLK)
begin
if (load_s2)
storage_data2 <= S_PAYLOAD_DATA;
end
assign M_PAYLOAD_DATA = storage_data1;
// Always load s2 on a valid transaction even if it's unnecessary
assign load_s2 = S_VALID & s_ready_i;
// Loading s1
always @ *
begin
if ( ((state == ZERO) && (S_VALID == 1)) || // Load when empty on slave transaction
// Load when ONE if we both have read and write at the same time
((state == ONE) && (S_VALID == 1) && (M_READY == 1)) ||
// Load when TWO and we have a transaction on Master side
((state == TWO) && (M_READY == 1)))
load_s1 = 1'b1;
else
load_s1 = 1'b0;
end // always @ *
assign load_s1_from_s2 = (state == TWO);
// State Machine for handling output signals
always @(posedge ACLK) begin
if (ARESET) begin
s_ready_i <= 1'b0;
state <= ZERO;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else begin
case (state)
// No transaction stored locally
ZERO: if (S_VALID) state <= ONE; // Got one so move to ONE
// One transaction stored locally
ONE: begin
if (M_READY & ~S_VALID) state <= ZERO; // Read out one so move to ZERO
if (~M_READY & S_VALID) begin
state <= TWO; // Got another one so move to TWO
s_ready_i <= 1'b0;
end
end
// TWO transaction stored locally
TWO: if (M_READY) begin
state <= ONE; // Read out one so move to ONE
s_ready_i <= 1'b1;
end
endcase // case (state)
end
end // always @ (posedge ACLK)
assign m_valid_i = state[0];
end // if (C_REG_CONFIG == 1)
////////////////////////////////////////////////////////////////////
//
// 1-stage pipeline register with bubble cycle, both FWD and REV pipelining
// Operates same as 1-deep FIFO
//
////////////////////////////////////////////////////////////////////
else if (C_REG_CONFIG == 32'h00000001)
begin
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg s_ready_i; //local signal of output
reg m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with slave side data
always @(posedge ACLK)
begin
if (ARESET) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b0;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else if (m_valid_i & M_READY) begin
s_ready_i <= 1'b1;
m_valid_i <= 1'b0;
end else if (S_VALID & s_ready_i) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b1;
end
if (~m_valid_i) begin
storage_data1 <= S_PAYLOAD_DATA;
end
end
assign M_PAYLOAD_DATA = storage_data1;
end // if (C_REG_CONFIG == 7)
else begin : default_case
// Passthrough
assign M_PAYLOAD_DATA = S_PAYLOAD_DATA;
assign M_VALID = S_VALID;
assign S_READY = M_READY;
end
endgenerate
endmodule // reg_slice
|
/*
*******************************************************************************
*
* FIFO Generator - Verilog Behavioral Model
*
*******************************************************************************
*
* (c) Copyright 1995 - 2009 Xilinx, Inc. All rights reserved.
*
* This file contains confidential and proprietary information
* of Xilinx, Inc. and is protected under U.S. and
* international copyright and other intellectual property
* laws.
*
* DISCLAIMER
* This disclaimer is not a license and does not grant any
* rights to the materials distributed herewith. Except as
* otherwise provided in a valid license issued to you by
* Xilinx, and to the maximum extent permitted by applicable
* law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
* WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
* AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
* BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
* INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
* (2) Xilinx shall not be liable (whether in contract or tort,
* including negligence, or under any other theory of
* liability) for any loss or damage of any kind or nature
* related to, arising under or in connection with these
* materials, including for any direct, or any indirect,
* special, incidental, or consequential loss or damage
* (including loss of data, profits, goodwill, or any type of
* loss or damage suffered as a result of any action brought
* by a third party) even if such damage or loss was
* reasonably foreseeable or Xilinx had been advised of the
* possibility of the same.
*
* CRITICAL APPLICATIONS
* Xilinx products are not designed or intended to be fail-
* safe, or for use in any application requiring fail-safe
* performance, such as life-support or safety devices or
* systems, Class III medical devices, nuclear facilities,
* applications related to the deployment of airbags, or any
* other applications that could lead to death, personal
* injury, or severe property or environmental damage
* (individually and collectively, "Critical
* Applications"). Customer assumes the sole risk and
* liability of any use of Xilinx products in Critical
* Applications, subject only to applicable laws and
* regulations governing limitations on product liability.
*
* THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
* PART OF THIS FILE AT ALL TIMES.
*
*******************************************************************************
*******************************************************************************
*
* Filename: fifo_generator_vlog_beh.v
*
* Author : Xilinx
*
*******************************************************************************
* Structure:
*
* fifo_generator_vlog_beh.v
* |
* +-fifo_generator_v13_1_3_bhv_ver_as
* |
* +-fifo_generator_v13_1_3_bhv_ver_ss
* |
* +-fifo_generator_v13_1_3_bhv_ver_preload0
*
*******************************************************************************
* Description:
*
* The Verilog behavioral model for the FIFO Generator.
*
* The behavioral model has three parts:
* - The behavioral model for independent clocks FIFOs (_as)
* - The behavioral model for common clock FIFOs (_ss)
* - The "preload logic" block which implements First-word Fall-through
*
*******************************************************************************
* Description:
* The verilog behavioral model for the FIFO generator core.
*
*******************************************************************************
*/
`timescale 1ps/1ps
`ifndef TCQ
`define TCQ 100
`endif
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "",
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 1,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "4kx4",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_PIPELINE_REG = 0,
parameter C_POWER_SAVING_MODE = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
// AXI Interface related parameters start here
parameter C_INTERFACE_TYPE = 0, // 0: Native Interface, 1: AXI4 Stream, 2: AXI4/AXI3
parameter C_AXI_TYPE = 0, // 1: AXI4, 2: AXI4 Lite, 3: AXI3
parameter C_HAS_AXI_WR_CHANNEL = 0,
parameter C_HAS_AXI_RD_CHANNEL = 0,
parameter C_HAS_SLAVE_CE = 0,
parameter C_HAS_MASTER_CE = 0,
parameter C_ADD_NGC_CONSTRAINT = 0,
parameter C_USE_COMMON_UNDERFLOW = 0,
parameter C_USE_COMMON_OVERFLOW = 0,
parameter C_USE_DEFAULT_SETTINGS = 0,
// AXI Full/Lite
parameter C_AXI_ID_WIDTH = 0,
parameter C_AXI_ADDR_WIDTH = 0,
parameter C_AXI_DATA_WIDTH = 0,
parameter C_AXI_LEN_WIDTH = 8,
parameter C_AXI_LOCK_WIDTH = 2,
parameter C_HAS_AXI_ID = 0,
parameter C_HAS_AXI_AWUSER = 0,
parameter C_HAS_AXI_WUSER = 0,
parameter C_HAS_AXI_BUSER = 0,
parameter C_HAS_AXI_ARUSER = 0,
parameter C_HAS_AXI_RUSER = 0,
parameter C_AXI_ARUSER_WIDTH = 0,
parameter C_AXI_AWUSER_WIDTH = 0,
parameter C_AXI_WUSER_WIDTH = 0,
parameter C_AXI_BUSER_WIDTH = 0,
parameter C_AXI_RUSER_WIDTH = 0,
// AXI Streaming
parameter C_HAS_AXIS_TDATA = 0,
parameter C_HAS_AXIS_TID = 0,
parameter C_HAS_AXIS_TDEST = 0,
parameter C_HAS_AXIS_TUSER = 0,
parameter C_HAS_AXIS_TREADY = 0,
parameter C_HAS_AXIS_TLAST = 0,
parameter C_HAS_AXIS_TSTRB = 0,
parameter C_HAS_AXIS_TKEEP = 0,
parameter C_AXIS_TDATA_WIDTH = 1,
parameter C_AXIS_TID_WIDTH = 1,
parameter C_AXIS_TDEST_WIDTH = 1,
parameter C_AXIS_TUSER_WIDTH = 1,
parameter C_AXIS_TSTRB_WIDTH = 1,
parameter C_AXIS_TKEEP_WIDTH = 1,
// AXI Channel Type
// WACH --> Write Address Channel
// WDCH --> Write Data Channel
// WRCH --> Write Response Channel
// RACH --> Read Address Channel
// RDCH --> Read Data Channel
// AXIS --> AXI Streaming
parameter C_WACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logic
parameter C_WDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_WRCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RACH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_RDCH_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
parameter C_AXIS_TYPE = 0, // 0 = FIFO, 1 = Register Slice, 2 = Pass Through Logie
// AXI Implementation Type
// 1 = Common Clock Block RAM FIFO
// 2 = Common Clock Distributed RAM FIFO
// 11 = Independent Clock Block RAM FIFO
// 12 = Independent Clock Distributed RAM FIFO
parameter C_IMPLEMENTATION_TYPE_WACH = 0,
parameter C_IMPLEMENTATION_TYPE_WDCH = 0,
parameter C_IMPLEMENTATION_TYPE_WRCH = 0,
parameter C_IMPLEMENTATION_TYPE_RACH = 0,
parameter C_IMPLEMENTATION_TYPE_RDCH = 0,
parameter C_IMPLEMENTATION_TYPE_AXIS = 0,
// AXI FIFO Type
// 0 = Data FIFO
// 1 = Packet FIFO
// 2 = Low Latency Sync FIFO
// 3 = Low Latency Async FIFO
parameter C_APPLICATION_TYPE_WACH = 0,
parameter C_APPLICATION_TYPE_WDCH = 0,
parameter C_APPLICATION_TYPE_WRCH = 0,
parameter C_APPLICATION_TYPE_RACH = 0,
parameter C_APPLICATION_TYPE_RDCH = 0,
parameter C_APPLICATION_TYPE_AXIS = 0,
// AXI Built-in FIFO Primitive Type
// 512x36, 1kx18, 2kx9, 4kx4, etc
parameter C_PRIM_FIFO_TYPE_WACH = "512x36",
parameter C_PRIM_FIFO_TYPE_WDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_WRCH = "512x36",
parameter C_PRIM_FIFO_TYPE_RACH = "512x36",
parameter C_PRIM_FIFO_TYPE_RDCH = "512x36",
parameter C_PRIM_FIFO_TYPE_AXIS = "512x36",
// Enable ECC
// 0 = ECC disabled
// 1 = ECC enabled
parameter C_USE_ECC_WACH = 0,
parameter C_USE_ECC_WDCH = 0,
parameter C_USE_ECC_WRCH = 0,
parameter C_USE_ECC_RACH = 0,
parameter C_USE_ECC_RDCH = 0,
parameter C_USE_ECC_AXIS = 0,
// ECC Error Injection Type
// 0 = No Error Injection
// 1 = Single Bit Error Injection
// 2 = Double Bit Error Injection
// 3 = Single Bit and Double Bit Error Injection
parameter C_ERROR_INJECTION_TYPE_WACH = 0,
parameter C_ERROR_INJECTION_TYPE_WDCH = 0,
parameter C_ERROR_INJECTION_TYPE_WRCH = 0,
parameter C_ERROR_INJECTION_TYPE_RACH = 0,
parameter C_ERROR_INJECTION_TYPE_RDCH = 0,
parameter C_ERROR_INJECTION_TYPE_AXIS = 0,
// Input Data Width
// Accumulation of all AXI input signal's width
parameter C_DIN_WIDTH_WACH = 1,
parameter C_DIN_WIDTH_WDCH = 1,
parameter C_DIN_WIDTH_WRCH = 1,
parameter C_DIN_WIDTH_RACH = 1,
parameter C_DIN_WIDTH_RDCH = 1,
parameter C_DIN_WIDTH_AXIS = 1,
parameter C_WR_DEPTH_WACH = 16,
parameter C_WR_DEPTH_WDCH = 16,
parameter C_WR_DEPTH_WRCH = 16,
parameter C_WR_DEPTH_RACH = 16,
parameter C_WR_DEPTH_RDCH = 16,
parameter C_WR_DEPTH_AXIS = 16,
parameter C_WR_PNTR_WIDTH_WACH = 4,
parameter C_WR_PNTR_WIDTH_WDCH = 4,
parameter C_WR_PNTR_WIDTH_WRCH = 4,
parameter C_WR_PNTR_WIDTH_RACH = 4,
parameter C_WR_PNTR_WIDTH_RDCH = 4,
parameter C_WR_PNTR_WIDTH_AXIS = 4,
parameter C_HAS_DATA_COUNTS_WACH = 0,
parameter C_HAS_DATA_COUNTS_WDCH = 0,
parameter C_HAS_DATA_COUNTS_WRCH = 0,
parameter C_HAS_DATA_COUNTS_RACH = 0,
parameter C_HAS_DATA_COUNTS_RDCH = 0,
parameter C_HAS_DATA_COUNTS_AXIS = 0,
parameter C_HAS_PROG_FLAGS_WACH = 0,
parameter C_HAS_PROG_FLAGS_WDCH = 0,
parameter C_HAS_PROG_FLAGS_WRCH = 0,
parameter C_HAS_PROG_FLAGS_RACH = 0,
parameter C_HAS_PROG_FLAGS_RDCH = 0,
parameter C_HAS_PROG_FLAGS_AXIS = 0,
parameter C_PROG_FULL_TYPE_WACH = 0,
parameter C_PROG_FULL_TYPE_WDCH = 0,
parameter C_PROG_FULL_TYPE_WRCH = 0,
parameter C_PROG_FULL_TYPE_RACH = 0,
parameter C_PROG_FULL_TYPE_RDCH = 0,
parameter C_PROG_FULL_TYPE_AXIS = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_PROG_EMPTY_TYPE_WACH = 0,
parameter C_PROG_EMPTY_TYPE_WDCH = 0,
parameter C_PROG_EMPTY_TYPE_WRCH = 0,
parameter C_PROG_EMPTY_TYPE_RACH = 0,
parameter C_PROG_EMPTY_TYPE_RDCH = 0,
parameter C_PROG_EMPTY_TYPE_AXIS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS = 0,
parameter C_REG_SLICE_MODE_WACH = 0,
parameter C_REG_SLICE_MODE_WDCH = 0,
parameter C_REG_SLICE_MODE_WRCH = 0,
parameter C_REG_SLICE_MODE_RACH = 0,
parameter C_REG_SLICE_MODE_RDCH = 0,
parameter C_REG_SLICE_MODE_AXIS = 0
)
(
//------------------------------------------------------------------------------
// Input and Output Declarations
//------------------------------------------------------------------------------
// Conventional FIFO Interface Signals
input backup,
input backup_marker,
input clk,
input rst,
input srst,
input wr_clk,
input wr_rst,
input rd_clk,
input rd_rst,
input [C_DIN_WIDTH-1:0] din,
input wr_en,
input rd_en,
// Optional inputs
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert,
input [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert,
input [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate,
input int_clk,
input injectdbiterr,
input injectsbiterr,
input sleep,
output [C_DOUT_WIDTH-1:0] dout,
output full,
output almost_full,
output wr_ack,
output overflow,
output empty,
output almost_empty,
output valid,
output underflow,
output [C_DATA_COUNT_WIDTH-1:0] data_count,
output [C_RD_DATA_COUNT_WIDTH-1:0] rd_data_count,
output [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count,
output prog_full,
output prog_empty,
output sbiterr,
output dbiterr,
output wr_rst_busy,
output rd_rst_busy,
// AXI Global Signal
input m_aclk,
input s_aclk,
input s_aresetn,
input s_aclk_en,
input m_aclk_en,
// AXI Full/Lite Slave Write Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_awid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_awlen,
input [3-1:0] s_axi_awsize,
input [2-1:0] s_axi_awburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_awlock,
input [4-1:0] s_axi_awcache,
input [3-1:0] s_axi_awprot,
input [4-1:0] s_axi_awqos,
input [4-1:0] s_axi_awregion,
input [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser,
input s_axi_awvalid,
output s_axi_awready,
input [C_AXI_ID_WIDTH-1:0] s_axi_wid,
input [C_AXI_DATA_WIDTH-1:0] s_axi_wdata,
input [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb,
input s_axi_wlast,
input [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser,
input s_axi_wvalid,
output s_axi_wready,
output [C_AXI_ID_WIDTH-1:0] s_axi_bid,
output [2-1:0] s_axi_bresp,
output [C_AXI_BUSER_WIDTH-1:0] s_axi_buser,
output s_axi_bvalid,
input s_axi_bready,
// AXI Full/Lite Master Write Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_awlen,
output [3-1:0] m_axi_awsize,
output [2-1:0] m_axi_awburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_awlock,
output [4-1:0] m_axi_awcache,
output [3-1:0] m_axi_awprot,
output [4-1:0] m_axi_awqos,
output [4-1:0] m_axi_awregion,
output [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
output m_axi_awvalid,
input m_axi_awready,
output [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output m_axi_wlast,
output [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
output m_axi_wvalid,
input m_axi_wready,
input [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input [2-1:0] m_axi_bresp,
input [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
input m_axi_bvalid,
output m_axi_bready,
// AXI Full/Lite Slave Read Channel (write side)
input [C_AXI_ID_WIDTH-1:0] s_axi_arid,
input [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr,
input [C_AXI_LEN_WIDTH-1:0] s_axi_arlen,
input [3-1:0] s_axi_arsize,
input [2-1:0] s_axi_arburst,
input [C_AXI_LOCK_WIDTH-1:0] s_axi_arlock,
input [4-1:0] s_axi_arcache,
input [3-1:0] s_axi_arprot,
input [4-1:0] s_axi_arqos,
input [4-1:0] s_axi_arregion,
input [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser,
input s_axi_arvalid,
output s_axi_arready,
output [C_AXI_ID_WIDTH-1:0] s_axi_rid,
output [C_AXI_DATA_WIDTH-1:0] s_axi_rdata,
output [2-1:0] s_axi_rresp,
output s_axi_rlast,
output [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser,
output s_axi_rvalid,
input s_axi_rready,
// AXI Full/Lite Master Read Channel (read side)
output [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output [C_AXI_LEN_WIDTH-1:0] m_axi_arlen,
output [3-1:0] m_axi_arsize,
output [2-1:0] m_axi_arburst,
output [C_AXI_LOCK_WIDTH-1:0] m_axi_arlock,
output [4-1:0] m_axi_arcache,
output [3-1:0] m_axi_arprot,
output [4-1:0] m_axi_arqos,
output [4-1:0] m_axi_arregion,
output [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
output m_axi_arvalid,
input m_axi_arready,
input [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input [2-1:0] m_axi_rresp,
input m_axi_rlast,
input [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
input m_axi_rvalid,
output m_axi_rready,
// AXI Streaming Slave Signals (Write side)
input s_axis_tvalid,
output s_axis_tready,
input [C_AXIS_TDATA_WIDTH-1:0] s_axis_tdata,
input [C_AXIS_TSTRB_WIDTH-1:0] s_axis_tstrb,
input [C_AXIS_TKEEP_WIDTH-1:0] s_axis_tkeep,
input s_axis_tlast,
input [C_AXIS_TID_WIDTH-1:0] s_axis_tid,
input [C_AXIS_TDEST_WIDTH-1:0] s_axis_tdest,
input [C_AXIS_TUSER_WIDTH-1:0] s_axis_tuser,
// AXI Streaming Master Signals (Read side)
output m_axis_tvalid,
input m_axis_tready,
output [C_AXIS_TDATA_WIDTH-1:0] m_axis_tdata,
output [C_AXIS_TSTRB_WIDTH-1:0] m_axis_tstrb,
output [C_AXIS_TKEEP_WIDTH-1:0] m_axis_tkeep,
output m_axis_tlast,
output [C_AXIS_TID_WIDTH-1:0] m_axis_tid,
output [C_AXIS_TDEST_WIDTH-1:0] m_axis_tdest,
output [C_AXIS_TUSER_WIDTH-1:0] m_axis_tuser,
// AXI Full/Lite Write Address Channel signals
input axi_aw_injectsbiterr,
input axi_aw_injectdbiterr,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WACH-1:0] axi_aw_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_wr_data_count,
output [C_WR_PNTR_WIDTH_WACH:0] axi_aw_rd_data_count,
output axi_aw_sbiterr,
output axi_aw_dbiterr,
output axi_aw_overflow,
output axi_aw_underflow,
output axi_aw_prog_full,
output axi_aw_prog_empty,
// AXI Full/Lite Write Data Channel signals
input axi_w_injectsbiterr,
input axi_w_injectdbiterr,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WDCH-1:0] axi_w_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_wr_data_count,
output [C_WR_PNTR_WIDTH_WDCH:0] axi_w_rd_data_count,
output axi_w_sbiterr,
output axi_w_dbiterr,
output axi_w_overflow,
output axi_w_underflow,
output axi_w_prog_full,
output axi_w_prog_empty,
// AXI Full/Lite Write Response Channel signals
input axi_b_injectsbiterr,
input axi_b_injectdbiterr,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_full_thresh,
input [C_WR_PNTR_WIDTH_WRCH-1:0] axi_b_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_wr_data_count,
output [C_WR_PNTR_WIDTH_WRCH:0] axi_b_rd_data_count,
output axi_b_sbiterr,
output axi_b_dbiterr,
output axi_b_overflow,
output axi_b_underflow,
output axi_b_prog_full,
output axi_b_prog_empty,
// AXI Full/Lite Read Address Channel signals
input axi_ar_injectsbiterr,
input axi_ar_injectdbiterr,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RACH-1:0] axi_ar_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_wr_data_count,
output [C_WR_PNTR_WIDTH_RACH:0] axi_ar_rd_data_count,
output axi_ar_sbiterr,
output axi_ar_dbiterr,
output axi_ar_overflow,
output axi_ar_underflow,
output axi_ar_prog_full,
output axi_ar_prog_empty,
// AXI Full/Lite Read Data Channel Signals
input axi_r_injectsbiterr,
input axi_r_injectdbiterr,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_full_thresh,
input [C_WR_PNTR_WIDTH_RDCH-1:0] axi_r_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_wr_data_count,
output [C_WR_PNTR_WIDTH_RDCH:0] axi_r_rd_data_count,
output axi_r_sbiterr,
output axi_r_dbiterr,
output axi_r_overflow,
output axi_r_underflow,
output axi_r_prog_full,
output axi_r_prog_empty,
// AXI Streaming FIFO Related Signals
input axis_injectsbiterr,
input axis_injectdbiterr,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_full_thresh,
input [C_WR_PNTR_WIDTH_AXIS-1:0] axis_prog_empty_thresh,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_wr_data_count,
output [C_WR_PNTR_WIDTH_AXIS:0] axis_rd_data_count,
output axis_sbiterr,
output axis_dbiterr,
output axis_overflow,
output axis_underflow,
output axis_prog_full,
output axis_prog_empty
);
wire BACKUP;
wire BACKUP_MARKER;
wire CLK;
wire RST;
wire SRST;
wire WR_CLK;
wire WR_RST;
wire RD_CLK;
wire RD_RST;
wire [C_DIN_WIDTH-1:0] DIN;
wire WR_EN;
wire RD_EN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire INT_CLK;
wire INJECTDBITERR;
wire INJECTSBITERR;
wire SLEEP;
wire [C_DOUT_WIDTH-1:0] DOUT;
wire FULL;
wire ALMOST_FULL;
wire WR_ACK;
wire OVERFLOW;
wire EMPTY;
wire ALMOST_EMPTY;
wire VALID;
wire UNDERFLOW;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT;
wire PROG_FULL;
wire PROG_EMPTY;
wire SBITERR;
wire DBITERR;
wire WR_RST_BUSY;
wire RD_RST_BUSY;
wire M_ACLK;
wire S_ACLK;
wire S_ARESETN;
wire S_ACLK_EN;
wire M_ACLK_EN;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_AWLEN;
wire [3-1:0] S_AXI_AWSIZE;
wire [2-1:0] S_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_AWLOCK;
wire [4-1:0] S_AXI_AWCACHE;
wire [3-1:0] S_AXI_AWPROT;
wire [4-1:0] S_AXI_AWQOS;
wire [4-1:0] S_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER;
wire S_AXI_AWVALID;
wire S_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB;
wire S_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER;
wire S_AXI_WVALID;
wire S_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID;
wire [2-1:0] S_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER;
wire S_AXI_BVALID;
wire S_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_AWID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_AWLEN;
wire [3-1:0] M_AXI_AWSIZE;
wire [2-1:0] M_AXI_AWBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_AWLOCK;
wire [4-1:0] M_AXI_AWCACHE;
wire [3-1:0] M_AXI_AWPROT;
wire [4-1:0] M_AXI_AWQOS;
wire [4-1:0] M_AXI_AWREGION;
wire [C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER;
wire M_AXI_AWVALID;
wire M_AXI_AWREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_WID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA;
wire [C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB;
wire M_AXI_WLAST;
wire [C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER;
wire M_AXI_WVALID;
wire M_AXI_WREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID;
wire [2-1:0] M_AXI_BRESP;
wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER;
wire M_AXI_BVALID;
wire M_AXI_BREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] S_AXI_ARLEN;
wire [3-1:0] S_AXI_ARSIZE;
wire [2-1:0] S_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] S_AXI_ARLOCK;
wire [4-1:0] S_AXI_ARCACHE;
wire [3-1:0] S_AXI_ARPROT;
wire [4-1:0] S_AXI_ARQOS;
wire [4-1:0] S_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER;
wire S_AXI_ARVALID;
wire S_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA;
wire [2-1:0] S_AXI_RRESP;
wire S_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER;
wire S_AXI_RVALID;
wire S_AXI_RREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_ARID;
wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR;
wire [C_AXI_LEN_WIDTH-1:0] M_AXI_ARLEN;
wire [3-1:0] M_AXI_ARSIZE;
wire [2-1:0] M_AXI_ARBURST;
wire [C_AXI_LOCK_WIDTH-1:0] M_AXI_ARLOCK;
wire [4-1:0] M_AXI_ARCACHE;
wire [3-1:0] M_AXI_ARPROT;
wire [4-1:0] M_AXI_ARQOS;
wire [4-1:0] M_AXI_ARREGION;
wire [C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER;
wire M_AXI_ARVALID;
wire M_AXI_ARREADY;
wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID;
wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA;
wire [2-1:0] M_AXI_RRESP;
wire M_AXI_RLAST;
wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER;
wire M_AXI_RVALID;
wire M_AXI_RREADY;
wire S_AXIS_TVALID;
wire S_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] S_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] S_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] S_AXIS_TKEEP;
wire S_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] S_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] S_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] S_AXIS_TUSER;
wire M_AXIS_TVALID;
wire M_AXIS_TREADY;
wire [C_AXIS_TDATA_WIDTH-1:0] M_AXIS_TDATA;
wire [C_AXIS_TSTRB_WIDTH-1:0] M_AXIS_TSTRB;
wire [C_AXIS_TKEEP_WIDTH-1:0] M_AXIS_TKEEP;
wire M_AXIS_TLAST;
wire [C_AXIS_TID_WIDTH-1:0] M_AXIS_TID;
wire [C_AXIS_TDEST_WIDTH-1:0] M_AXIS_TDEST;
wire [C_AXIS_TUSER_WIDTH-1:0] M_AXIS_TUSER;
wire AXI_AW_INJECTSBITERR;
wire AXI_AW_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WACH-1:0] AXI_AW_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WACH:0] AXI_AW_RD_DATA_COUNT;
wire AXI_AW_SBITERR;
wire AXI_AW_DBITERR;
wire AXI_AW_OVERFLOW;
wire AXI_AW_UNDERFLOW;
wire AXI_AW_PROG_FULL;
wire AXI_AW_PROG_EMPTY;
wire AXI_W_INJECTSBITERR;
wire AXI_W_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH-1:0] AXI_W_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WDCH:0] AXI_W_RD_DATA_COUNT;
wire AXI_W_SBITERR;
wire AXI_W_DBITERR;
wire AXI_W_OVERFLOW;
wire AXI_W_UNDERFLOW;
wire AXI_W_PROG_FULL;
wire AXI_W_PROG_EMPTY;
wire AXI_B_INJECTSBITERR;
wire AXI_B_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH-1:0] AXI_B_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_WRCH:0] AXI_B_RD_DATA_COUNT;
wire AXI_B_SBITERR;
wire AXI_B_DBITERR;
wire AXI_B_OVERFLOW;
wire AXI_B_UNDERFLOW;
wire AXI_B_PROG_FULL;
wire AXI_B_PROG_EMPTY;
wire AXI_AR_INJECTSBITERR;
wire AXI_AR_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RACH-1:0] AXI_AR_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RACH:0] AXI_AR_RD_DATA_COUNT;
wire AXI_AR_SBITERR;
wire AXI_AR_DBITERR;
wire AXI_AR_OVERFLOW;
wire AXI_AR_UNDERFLOW;
wire AXI_AR_PROG_FULL;
wire AXI_AR_PROG_EMPTY;
wire AXI_R_INJECTSBITERR;
wire AXI_R_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH-1:0] AXI_R_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_RDCH:0] AXI_R_RD_DATA_COUNT;
wire AXI_R_SBITERR;
wire AXI_R_DBITERR;
wire AXI_R_OVERFLOW;
wire AXI_R_UNDERFLOW;
wire AXI_R_PROG_FULL;
wire AXI_R_PROG_EMPTY;
wire AXIS_INJECTSBITERR;
wire AXIS_INJECTDBITERR;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS-1:0] AXIS_PROG_EMPTY_THRESH;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_WR_DATA_COUNT;
wire [C_WR_PNTR_WIDTH_AXIS:0] AXIS_RD_DATA_COUNT;
wire AXIS_SBITERR;
wire AXIS_DBITERR;
wire AXIS_OVERFLOW;
wire AXIS_UNDERFLOW;
wire AXIS_PROG_FULL;
wire AXIS_PROG_EMPTY;
wire [C_WR_DATA_COUNT_WIDTH-1:0] wr_data_count_in;
wire wr_rst_int;
wire rd_rst_int;
wire wr_rst_busy_o;
wire wr_rst_busy_ntve;
wire wr_rst_busy_axis;
wire wr_rst_busy_wach;
wire wr_rst_busy_wdch;
wire wr_rst_busy_wrch;
wire wr_rst_busy_rach;
wire wr_rst_busy_rdch;
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// Conventional FIFO Interface Signals
assign BACKUP = backup;
assign BACKUP_MARKER = backup_marker;
assign CLK = clk;
assign RST = rst;
assign SRST = srst;
assign WR_CLK = wr_clk;
assign WR_RST = wr_rst;
assign RD_CLK = rd_clk;
assign RD_RST = rd_rst;
assign WR_EN = wr_en;
assign RD_EN = rd_en;
assign INT_CLK = int_clk;
assign INJECTDBITERR = injectdbiterr;
assign INJECTSBITERR = injectsbiterr;
assign SLEEP = sleep;
assign full = FULL;
assign almost_full = ALMOST_FULL;
assign wr_ack = WR_ACK;
assign overflow = OVERFLOW;
assign empty = EMPTY;
assign almost_empty = ALMOST_EMPTY;
assign valid = VALID;
assign underflow = UNDERFLOW;
assign prog_full = PROG_FULL;
assign prog_empty = PROG_EMPTY;
assign sbiterr = SBITERR;
assign dbiterr = DBITERR;
// assign wr_rst_busy = WR_RST_BUSY | wr_rst_busy_o;
assign wr_rst_busy = wr_rst_busy_o;
assign rd_rst_busy = RD_RST_BUSY;
assign M_ACLK = m_aclk;
assign S_ACLK = s_aclk;
assign S_ARESETN = s_aresetn;
assign S_ACLK_EN = s_aclk_en;
assign M_ACLK_EN = m_aclk_en;
assign S_AXI_AWVALID = s_axi_awvalid;
assign s_axi_awready = S_AXI_AWREADY;
assign S_AXI_WLAST = s_axi_wlast;
assign S_AXI_WVALID = s_axi_wvalid;
assign s_axi_wready = S_AXI_WREADY;
assign s_axi_bvalid = S_AXI_BVALID;
assign S_AXI_BREADY = s_axi_bready;
assign m_axi_awvalid = M_AXI_AWVALID;
assign M_AXI_AWREADY = m_axi_awready;
assign m_axi_wlast = M_AXI_WLAST;
assign m_axi_wvalid = M_AXI_WVALID;
assign M_AXI_WREADY = m_axi_wready;
assign M_AXI_BVALID = m_axi_bvalid;
assign m_axi_bready = M_AXI_BREADY;
assign S_AXI_ARVALID = s_axi_arvalid;
assign s_axi_arready = S_AXI_ARREADY;
assign s_axi_rlast = S_AXI_RLAST;
assign s_axi_rvalid = S_AXI_RVALID;
assign S_AXI_RREADY = s_axi_rready;
assign m_axi_arvalid = M_AXI_ARVALID;
assign M_AXI_ARREADY = m_axi_arready;
assign M_AXI_RLAST = m_axi_rlast;
assign M_AXI_RVALID = m_axi_rvalid;
assign m_axi_rready = M_AXI_RREADY;
assign S_AXIS_TVALID = s_axis_tvalid;
assign s_axis_tready = S_AXIS_TREADY;
assign S_AXIS_TLAST = s_axis_tlast;
assign m_axis_tvalid = M_AXIS_TVALID;
assign M_AXIS_TREADY = m_axis_tready;
assign m_axis_tlast = M_AXIS_TLAST;
assign AXI_AW_INJECTSBITERR = axi_aw_injectsbiterr;
assign AXI_AW_INJECTDBITERR = axi_aw_injectdbiterr;
assign axi_aw_sbiterr = AXI_AW_SBITERR;
assign axi_aw_dbiterr = AXI_AW_DBITERR;
assign axi_aw_overflow = AXI_AW_OVERFLOW;
assign axi_aw_underflow = AXI_AW_UNDERFLOW;
assign axi_aw_prog_full = AXI_AW_PROG_FULL;
assign axi_aw_prog_empty = AXI_AW_PROG_EMPTY;
assign AXI_W_INJECTSBITERR = axi_w_injectsbiterr;
assign AXI_W_INJECTDBITERR = axi_w_injectdbiterr;
assign axi_w_sbiterr = AXI_W_SBITERR;
assign axi_w_dbiterr = AXI_W_DBITERR;
assign axi_w_overflow = AXI_W_OVERFLOW;
assign axi_w_underflow = AXI_W_UNDERFLOW;
assign axi_w_prog_full = AXI_W_PROG_FULL;
assign axi_w_prog_empty = AXI_W_PROG_EMPTY;
assign AXI_B_INJECTSBITERR = axi_b_injectsbiterr;
assign AXI_B_INJECTDBITERR = axi_b_injectdbiterr;
assign axi_b_sbiterr = AXI_B_SBITERR;
assign axi_b_dbiterr = AXI_B_DBITERR;
assign axi_b_overflow = AXI_B_OVERFLOW;
assign axi_b_underflow = AXI_B_UNDERFLOW;
assign axi_b_prog_full = AXI_B_PROG_FULL;
assign axi_b_prog_empty = AXI_B_PROG_EMPTY;
assign AXI_AR_INJECTSBITERR = axi_ar_injectsbiterr;
assign AXI_AR_INJECTDBITERR = axi_ar_injectdbiterr;
assign axi_ar_sbiterr = AXI_AR_SBITERR;
assign axi_ar_dbiterr = AXI_AR_DBITERR;
assign axi_ar_overflow = AXI_AR_OVERFLOW;
assign axi_ar_underflow = AXI_AR_UNDERFLOW;
assign axi_ar_prog_full = AXI_AR_PROG_FULL;
assign axi_ar_prog_empty = AXI_AR_PROG_EMPTY;
assign AXI_R_INJECTSBITERR = axi_r_injectsbiterr;
assign AXI_R_INJECTDBITERR = axi_r_injectdbiterr;
assign axi_r_sbiterr = AXI_R_SBITERR;
assign axi_r_dbiterr = AXI_R_DBITERR;
assign axi_r_overflow = AXI_R_OVERFLOW;
assign axi_r_underflow = AXI_R_UNDERFLOW;
assign axi_r_prog_full = AXI_R_PROG_FULL;
assign axi_r_prog_empty = AXI_R_PROG_EMPTY;
assign AXIS_INJECTSBITERR = axis_injectsbiterr;
assign AXIS_INJECTDBITERR = axis_injectdbiterr;
assign axis_sbiterr = AXIS_SBITERR;
assign axis_dbiterr = AXIS_DBITERR;
assign axis_overflow = AXIS_OVERFLOW;
assign axis_underflow = AXIS_UNDERFLOW;
assign axis_prog_full = AXIS_PROG_FULL;
assign axis_prog_empty = AXIS_PROG_EMPTY;
assign DIN = din;
assign PROG_EMPTY_THRESH = prog_empty_thresh;
assign PROG_EMPTY_THRESH_ASSERT = prog_empty_thresh_assert;
assign PROG_EMPTY_THRESH_NEGATE = prog_empty_thresh_negate;
assign PROG_FULL_THRESH = prog_full_thresh;
assign PROG_FULL_THRESH_ASSERT = prog_full_thresh_assert;
assign PROG_FULL_THRESH_NEGATE = prog_full_thresh_negate;
assign dout = DOUT;
assign data_count = DATA_COUNT;
assign rd_data_count = RD_DATA_COUNT;
assign wr_data_count = WR_DATA_COUNT;
assign S_AXI_AWID = s_axi_awid;
assign S_AXI_AWADDR = s_axi_awaddr;
assign S_AXI_AWLEN = s_axi_awlen;
assign S_AXI_AWSIZE = s_axi_awsize;
assign S_AXI_AWBURST = s_axi_awburst;
assign S_AXI_AWLOCK = s_axi_awlock;
assign S_AXI_AWCACHE = s_axi_awcache;
assign S_AXI_AWPROT = s_axi_awprot;
assign S_AXI_AWQOS = s_axi_awqos;
assign S_AXI_AWREGION = s_axi_awregion;
assign S_AXI_AWUSER = s_axi_awuser;
assign S_AXI_WID = s_axi_wid;
assign S_AXI_WDATA = s_axi_wdata;
assign S_AXI_WSTRB = s_axi_wstrb;
assign S_AXI_WUSER = s_axi_wuser;
assign s_axi_bid = S_AXI_BID;
assign s_axi_bresp = S_AXI_BRESP;
assign s_axi_buser = S_AXI_BUSER;
assign m_axi_awid = M_AXI_AWID;
assign m_axi_awaddr = M_AXI_AWADDR;
assign m_axi_awlen = M_AXI_AWLEN;
assign m_axi_awsize = M_AXI_AWSIZE;
assign m_axi_awburst = M_AXI_AWBURST;
assign m_axi_awlock = M_AXI_AWLOCK;
assign m_axi_awcache = M_AXI_AWCACHE;
assign m_axi_awprot = M_AXI_AWPROT;
assign m_axi_awqos = M_AXI_AWQOS;
assign m_axi_awregion = M_AXI_AWREGION;
assign m_axi_awuser = M_AXI_AWUSER;
assign m_axi_wid = M_AXI_WID;
assign m_axi_wdata = M_AXI_WDATA;
assign m_axi_wstrb = M_AXI_WSTRB;
assign m_axi_wuser = M_AXI_WUSER;
assign M_AXI_BID = m_axi_bid;
assign M_AXI_BRESP = m_axi_bresp;
assign M_AXI_BUSER = m_axi_buser;
assign S_AXI_ARID = s_axi_arid;
assign S_AXI_ARADDR = s_axi_araddr;
assign S_AXI_ARLEN = s_axi_arlen;
assign S_AXI_ARSIZE = s_axi_arsize;
assign S_AXI_ARBURST = s_axi_arburst;
assign S_AXI_ARLOCK = s_axi_arlock;
assign S_AXI_ARCACHE = s_axi_arcache;
assign S_AXI_ARPROT = s_axi_arprot;
assign S_AXI_ARQOS = s_axi_arqos;
assign S_AXI_ARREGION = s_axi_arregion;
assign S_AXI_ARUSER = s_axi_aruser;
assign s_axi_rid = S_AXI_RID;
assign s_axi_rdata = S_AXI_RDATA;
assign s_axi_rresp = S_AXI_RRESP;
assign s_axi_ruser = S_AXI_RUSER;
assign m_axi_arid = M_AXI_ARID;
assign m_axi_araddr = M_AXI_ARADDR;
assign m_axi_arlen = M_AXI_ARLEN;
assign m_axi_arsize = M_AXI_ARSIZE;
assign m_axi_arburst = M_AXI_ARBURST;
assign m_axi_arlock = M_AXI_ARLOCK;
assign m_axi_arcache = M_AXI_ARCACHE;
assign m_axi_arprot = M_AXI_ARPROT;
assign m_axi_arqos = M_AXI_ARQOS;
assign m_axi_arregion = M_AXI_ARREGION;
assign m_axi_aruser = M_AXI_ARUSER;
assign M_AXI_RID = m_axi_rid;
assign M_AXI_RDATA = m_axi_rdata;
assign M_AXI_RRESP = m_axi_rresp;
assign M_AXI_RUSER = m_axi_ruser;
assign S_AXIS_TDATA = s_axis_tdata;
assign S_AXIS_TSTRB = s_axis_tstrb;
assign S_AXIS_TKEEP = s_axis_tkeep;
assign S_AXIS_TID = s_axis_tid;
assign S_AXIS_TDEST = s_axis_tdest;
assign S_AXIS_TUSER = s_axis_tuser;
assign m_axis_tdata = M_AXIS_TDATA;
assign m_axis_tstrb = M_AXIS_TSTRB;
assign m_axis_tkeep = M_AXIS_TKEEP;
assign m_axis_tid = M_AXIS_TID;
assign m_axis_tdest = M_AXIS_TDEST;
assign m_axis_tuser = M_AXIS_TUSER;
assign AXI_AW_PROG_FULL_THRESH = axi_aw_prog_full_thresh;
assign AXI_AW_PROG_EMPTY_THRESH = axi_aw_prog_empty_thresh;
assign axi_aw_data_count = AXI_AW_DATA_COUNT;
assign axi_aw_wr_data_count = AXI_AW_WR_DATA_COUNT;
assign axi_aw_rd_data_count = AXI_AW_RD_DATA_COUNT;
assign AXI_W_PROG_FULL_THRESH = axi_w_prog_full_thresh;
assign AXI_W_PROG_EMPTY_THRESH = axi_w_prog_empty_thresh;
assign axi_w_data_count = AXI_W_DATA_COUNT;
assign axi_w_wr_data_count = AXI_W_WR_DATA_COUNT;
assign axi_w_rd_data_count = AXI_W_RD_DATA_COUNT;
assign AXI_B_PROG_FULL_THRESH = axi_b_prog_full_thresh;
assign AXI_B_PROG_EMPTY_THRESH = axi_b_prog_empty_thresh;
assign axi_b_data_count = AXI_B_DATA_COUNT;
assign axi_b_wr_data_count = AXI_B_WR_DATA_COUNT;
assign axi_b_rd_data_count = AXI_B_RD_DATA_COUNT;
assign AXI_AR_PROG_FULL_THRESH = axi_ar_prog_full_thresh;
assign AXI_AR_PROG_EMPTY_THRESH = axi_ar_prog_empty_thresh;
assign axi_ar_data_count = AXI_AR_DATA_COUNT;
assign axi_ar_wr_data_count = AXI_AR_WR_DATA_COUNT;
assign axi_ar_rd_data_count = AXI_AR_RD_DATA_COUNT;
assign AXI_R_PROG_FULL_THRESH = axi_r_prog_full_thresh;
assign AXI_R_PROG_EMPTY_THRESH = axi_r_prog_empty_thresh;
assign axi_r_data_count = AXI_R_DATA_COUNT;
assign axi_r_wr_data_count = AXI_R_WR_DATA_COUNT;
assign axi_r_rd_data_count = AXI_R_RD_DATA_COUNT;
assign AXIS_PROG_FULL_THRESH = axis_prog_full_thresh;
assign AXIS_PROG_EMPTY_THRESH = axis_prog_empty_thresh;
assign axis_data_count = AXIS_DATA_COUNT;
assign axis_wr_data_count = AXIS_WR_DATA_COUNT;
assign axis_rd_data_count = AXIS_RD_DATA_COUNT;
generate if (C_INTERFACE_TYPE == 0) begin : conv_fifo
fifo_generator_v13_1_3_CONV_VER
#(
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_USE_DOUT_RST == 1 ? C_DOUT_RST_VAL : 0),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_FAMILY (C_FAMILY),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RD_RST (C_HAS_RD_RST),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_HAS_WR_RST (C_HAS_WR_RST),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_FREQ (C_RD_FREQ),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_AXI_TYPE (C_AXI_TYPE),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE)
)
fifo_generator_v13_1_3_conv_dut
(
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.CLK (CLK),
.RST (RST),
.SRST (SRST),
.WR_CLK (WR_CLK),
.WR_RST (WR_RST),
.RD_CLK (RD_CLK),
.RD_RST (RD_RST),
.DIN (DIN),
.WR_EN (WR_EN),
.RD_EN (RD_EN),
.PROG_EMPTY_THRESH (PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT (PROG_EMPTY_THRESH_ASSERT),
.PROG_EMPTY_THRESH_NEGATE (PROG_EMPTY_THRESH_NEGATE),
.PROG_FULL_THRESH (PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT (PROG_FULL_THRESH_ASSERT),
.PROG_FULL_THRESH_NEGATE (PROG_FULL_THRESH_NEGATE),
.INT_CLK (INT_CLK),
.INJECTDBITERR (INJECTDBITERR),
.INJECTSBITERR (INJECTSBITERR),
.DOUT (DOUT),
.FULL (FULL),
.ALMOST_FULL (ALMOST_FULL),
.WR_ACK (WR_ACK),
.OVERFLOW (OVERFLOW),
.EMPTY (EMPTY),
.ALMOST_EMPTY (ALMOST_EMPTY),
.VALID (VALID),
.UNDERFLOW (UNDERFLOW),
.DATA_COUNT (DATA_COUNT),
.RD_DATA_COUNT (RD_DATA_COUNT),
.WR_DATA_COUNT (wr_data_count_in),
.PROG_FULL (PROG_FULL),
.PROG_EMPTY (PROG_EMPTY),
.SBITERR (SBITERR),
.DBITERR (DBITERR),
.wr_rst_busy_o (wr_rst_busy_o),
.wr_rst_busy (wr_rst_busy_i),
.rd_rst_busy (rd_rst_busy),
.wr_rst_i_out (wr_rst_int),
.rd_rst_i_out (rd_rst_int)
);
end endgenerate
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_AXI_SIZE_WIDTH = 3;
localparam C_AXI_BURST_WIDTH = 2;
localparam C_AXI_CACHE_WIDTH = 4;
localparam C_AXI_PROT_WIDTH = 3;
localparam C_AXI_QOS_WIDTH = 4;
localparam C_AXI_REGION_WIDTH = 4;
localparam C_AXI_BRESP_WIDTH = 2;
localparam C_AXI_RRESP_WIDTH = 2;
localparam IS_AXI_STREAMING = C_INTERFACE_TYPE == 1 ? 1 : 0;
localparam TDATA_OFFSET = C_HAS_AXIS_TDATA == 1 ? C_DIN_WIDTH_AXIS-C_AXIS_TDATA_WIDTH : C_DIN_WIDTH_AXIS;
localparam TSTRB_OFFSET = C_HAS_AXIS_TSTRB == 1 ? TDATA_OFFSET-C_AXIS_TSTRB_WIDTH : TDATA_OFFSET;
localparam TKEEP_OFFSET = C_HAS_AXIS_TKEEP == 1 ? TSTRB_OFFSET-C_AXIS_TKEEP_WIDTH : TSTRB_OFFSET;
localparam TID_OFFSET = C_HAS_AXIS_TID == 1 ? TKEEP_OFFSET-C_AXIS_TID_WIDTH : TKEEP_OFFSET;
localparam TDEST_OFFSET = C_HAS_AXIS_TDEST == 1 ? TID_OFFSET-C_AXIS_TDEST_WIDTH : TID_OFFSET;
localparam TUSER_OFFSET = C_HAS_AXIS_TUSER == 1 ? TDEST_OFFSET-C_AXIS_TUSER_WIDTH : TDEST_OFFSET;
localparam LOG_DEPTH_AXIS = find_log2(C_WR_DEPTH_AXIS);
localparam LOG_WR_DEPTH = find_log2(C_WR_DEPTH);
function [LOG_DEPTH_AXIS-1:0] bin2gray;
input [LOG_DEPTH_AXIS-1:0] x;
begin
bin2gray = x ^ (x>>1);
end
endfunction
function [LOG_DEPTH_AXIS-1:0] gray2bin;
input [LOG_DEPTH_AXIS-1:0] x;
integer i;
begin
gray2bin[LOG_DEPTH_AXIS-1] = x[LOG_DEPTH_AXIS-1];
for(i=LOG_DEPTH_AXIS-2; i>=0; i=i-1) begin
gray2bin[i] = gray2bin[i+1] ^ x[i];
end
end
endfunction
wire [(LOG_WR_DEPTH)-1 : 0] w_cnt_gc_asreg_last;
wire [LOG_WR_DEPTH-1 : 0] w_q [0:C_SYNCHRONIZER_STAGE] ;
wire [LOG_WR_DEPTH-1 : 0] w_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_rd = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt = 0;
reg [LOG_WR_DEPTH-1 : 0] w_cnt_gc = 0;
reg [LOG_WR_DEPTH-1 : 0] r_cnt = 0;
wire [LOG_WR_DEPTH : 0] adj_w_cnt_rd_pad;
wire [LOG_WR_DEPTH : 0] r_inv_pad;
wire [LOG_WR_DEPTH-1 : 0] d_cnt;
reg [LOG_WR_DEPTH : 0] d_cnt_pad = 0;
reg adj_w_cnt_rd_pad_0 = 0;
reg r_inv_pad_0 = 0;
genvar l;
generate for (l = 1; ((l <= C_SYNCHRONIZER_STAGE) && (C_HAS_DATA_COUNTS_AXIS == 3 && C_INTERFACE_TYPE == 0) ); l = l + 1) begin : g_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_WR_DEPTH)
)
rd_stg_inst
(
.RST (rd_rst_int),
.CLK (RD_CLK),
.DIN (w_q[l-1]),
.DOUT (w_q[l])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS == 3) begin : fifo_ic_adapter
assign wr_eop_ad = WR_EN & !(FULL);
assign rd_eop_ad = RD_EN & !(EMPTY);
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt <= 1'b0;
else if (wr_eop_ad)
w_cnt <= w_cnt + 1;
end
always @ (posedge wr_rst_int or posedge WR_CLK)
begin
if (wr_rst_int)
w_cnt_gc <= 1'b0;
else
w_cnt_gc <= bin2gray(w_cnt);
end
assign w_q[0] = w_cnt_gc;
assign w_cnt_gc_asreg_last = w_q[C_SYNCHRONIZER_STAGE];
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
w_cnt_rd <= 1'b0;
else
w_cnt_rd <= gray2bin(w_cnt_gc_asreg_last);
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
r_cnt <= 1'b0;
else if (rd_eop_ad)
r_cnt <= r_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_w_cnt_rd_pad[LOG_WR_DEPTH : 1] = w_cnt_rd;
assign r_inv_pad[LOG_WR_DEPTH : 1] = ~r_cnt;
assign adj_w_cnt_rd_pad[0] = adj_w_cnt_rd_pad_0;
assign r_inv_pad[0] = r_inv_pad_0;
always @ ( rd_eop_ad )
begin
if (!rd_eop_ad) begin
adj_w_cnt_rd_pad_0 <= 1'b1;
r_inv_pad_0 <= 1'b1;
end else begin
adj_w_cnt_rd_pad_0 <= 1'b0;
r_inv_pad_0 <= 1'b0;
end
end
always @ (posedge rd_rst_int or posedge RD_CLK)
begin
if (rd_rst_int)
d_cnt_pad <= 1'b0;
else
d_cnt_pad <= adj_w_cnt_rd_pad + r_inv_pad ;
end
assign d_cnt = d_cnt_pad [LOG_WR_DEPTH : 1] ;
assign WR_DATA_COUNT = d_cnt;
end endgenerate // fifo_ic_adapter
generate if (C_INTERFACE_TYPE == 0 && C_HAS_DATA_COUNTS_AXIS != 3) begin : fifo_icn_adapter
assign WR_DATA_COUNT = wr_data_count_in;
end endgenerate // fifo_icn_adapter
wire inverted_reset = ~S_ARESETN;
wire axi_rs_rst;
wire [C_DIN_WIDTH_AXIS-1:0] axis_din ;
wire [C_DIN_WIDTH_AXIS-1:0] axis_dout ;
wire axis_full ;
wire axis_almost_full ;
wire axis_empty ;
wire axis_s_axis_tready;
wire axis_m_axis_tvalid;
wire axis_wr_en ;
wire axis_rd_en ;
wire axis_we ;
wire axis_re ;
wire [C_WR_PNTR_WIDTH_AXIS:0] axis_dc;
reg axis_pkt_read = 1'b0;
wire axis_rd_rst;
wire axis_wr_rst;
generate if (C_INTERFACE_TYPE > 0 && (C_AXIS_TYPE == 1 || C_WACH_TYPE == 1 ||
C_WDCH_TYPE == 1 || C_WRCH_TYPE == 1 || C_RACH_TYPE == 1 || C_RDCH_TYPE == 1)) begin : gaxi_rs_rst
reg rst_d1 = 0 ;
reg rst_d2 = 0 ;
reg [3:0] axi_rst = 4'h0 ;
always @ (posedge inverted_reset or posedge S_ACLK) begin
if (inverted_reset) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
axi_rst <= 4'hf;
end else begin
rst_d1 <= #`TCQ 1'b0;
rst_d2 <= #`TCQ rst_d1;
axi_rst <= #`TCQ {axi_rst[2:0],1'b0};
end
end
assign axi_rs_rst = axi_rst[3];//rst_d2;
end endgenerate // gaxi_rs_rst
generate if (IS_AXI_STREAMING == 1 && C_AXIS_TYPE == 0) begin : axi_streaming
// Write protection when almost full or prog_full is high
assign axis_we = (C_PROG_FULL_TYPE_AXIS != 0) ? axis_s_axis_tready & S_AXIS_TVALID :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_s_axis_tready & S_AXIS_TVALID : S_AXIS_TVALID;
// Read protection when almost empty or prog_empty is high
assign axis_re = (C_PROG_EMPTY_TYPE_AXIS != 0) ? axis_m_axis_tvalid & M_AXIS_TREADY :
(C_APPLICATION_TYPE_AXIS == 1) ? axis_m_axis_tvalid & M_AXIS_TREADY : M_AXIS_TREADY;
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? axis_we & S_ACLK_EN : axis_we;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? axis_re & M_ACLK_EN : axis_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_AXIS == 2 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_AXIS == 11 || C_IMPLEMENTATION_TYPE_AXIS == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_AXIS),
.C_WR_DEPTH (C_WR_DEPTH_AXIS),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_DOUT_WIDTH (C_DIN_WIDTH_AXIS),
.C_RD_DEPTH (C_WR_DEPTH_AXIS),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_AXIS),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_AXIS),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_AXIS),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_AXIS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS),
.C_USE_ECC (C_USE_ECC_AXIS),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_AXIS),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (C_APPLICATION_TYPE_AXIS == 1 ? 1: 0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_FIFO_TYPE (C_APPLICATION_TYPE_AXIS == 1 ? 0: C_APPLICATION_TYPE_AXIS),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_AXIS == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_AXIS + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_AXIS == 1 || C_IMPLEMENTATION_TYPE_AXIS == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_axis_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (axis_wr_en),
.RD_EN (axis_rd_en),
.PROG_FULL_THRESH (AXIS_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH (AXIS_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_AXIS{1'b0}}),
.INJECTDBITERR (AXIS_INJECTDBITERR),
.INJECTSBITERR (AXIS_INJECTSBITERR),
.DIN (axis_din),
.DOUT (axis_dout),
.FULL (axis_full),
.EMPTY (axis_empty),
.ALMOST_FULL (axis_almost_full),
.PROG_FULL (AXIS_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXIS_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (AXIS_OVERFLOW),
.VALID (),
.UNDERFLOW (AXIS_UNDERFLOW),
.DATA_COUNT (axis_dc),
.RD_DATA_COUNT (AXIS_RD_DATA_COUNT),
.WR_DATA_COUNT (AXIS_WR_DATA_COUNT),
.SBITERR (AXIS_SBITERR),
.DBITERR (AXIS_DBITERR),
.wr_rst_busy (wr_rst_busy_axis),
.rd_rst_busy (rd_rst_busy_axis),
.wr_rst_i_out (axis_wr_rst),
.rd_rst_i_out (axis_rd_rst),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign axis_s_axis_tready = (IS_8SERIES == 0) ? ~axis_full : (C_IMPLEMENTATION_TYPE_AXIS == 5 || C_IMPLEMENTATION_TYPE_AXIS == 13) ? ~(axis_full | wr_rst_busy_axis) : ~axis_full;
assign axis_m_axis_tvalid = (C_APPLICATION_TYPE_AXIS != 1) ? ~axis_empty : ~axis_empty & axis_pkt_read;
assign S_AXIS_TREADY = axis_s_axis_tready;
assign M_AXIS_TVALID = axis_m_axis_tvalid;
end endgenerate // axi_streaming
wire axis_wr_eop;
reg axis_wr_eop_d1 = 1'b0;
wire axis_rd_eop;
integer axis_pkt_cnt;
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 1) begin : gaxis_pkt_fifo_cc
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (axis_pkt_cnt == 1) && ~axis_wr_eop_d1)
axis_pkt_read <= 1'b0;
else if ((axis_pkt_cnt > 0) || (axis_almost_full && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_wr_eop_d1 <= 1'b0;
else
axis_wr_eop_d1 <= axis_wr_eop;
end
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_pkt_cnt <= 0;
else if (axis_wr_eop_d1 && ~axis_rd_eop)
axis_pkt_cnt <= axis_pkt_cnt + 1;
else if (axis_rd_eop && ~axis_wr_eop_d1)
axis_pkt_cnt <= axis_pkt_cnt - 1;
end
end endgenerate // gaxis_pkt_fifo_cc
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_gc = 0;
wire [(LOG_DEPTH_AXIS)-1 : 0] axis_wpkt_cnt_gc_asreg_last;
wire axis_rd_has_rst;
wire [0:C_SYNCHRONIZER_STAGE] axis_af_q ;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q [0:C_SYNCHRONIZER_STAGE] ;
wire [1:C_SYNCHRONIZER_STAGE] axis_af_q_temp = 0;
wire [LOG_DEPTH_AXIS-1 : 0] wpkt_q_temp [1:C_SYNCHRONIZER_STAGE] ;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt_rd = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_wpkt_cnt = 0;
reg [LOG_DEPTH_AXIS-1 : 0] axis_rpkt_cnt = 0;
wire [LOG_DEPTH_AXIS : 0] adj_axis_wpkt_cnt_rd_pad;
wire [LOG_DEPTH_AXIS : 0] rpkt_inv_pad;
wire [LOG_DEPTH_AXIS-1 : 0] diff_pkt_cnt;
reg [LOG_DEPTH_AXIS : 0] diff_pkt_cnt_pad = 0;
reg adj_axis_wpkt_cnt_rd_pad_0 = 0;
reg rpkt_inv_pad_0 = 0;
wire axis_af_rd ;
generate if (C_HAS_RST == 1) begin : rst_blk_has
assign axis_rd_has_rst = axis_rd_rst;
end endgenerate //rst_blk_has
generate if (C_HAS_RST == 0) begin :rst_blk_no
assign axis_rd_has_rst = 1'b0;
end endgenerate //rst_blk_no
genvar i;
generate for (i = 1; ((i <= C_SYNCHRONIZER_STAGE) && (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) ); i = i + 1) begin : gpkt_cnt_sync_stage
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (LOG_DEPTH_AXIS)
)
rd_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (wpkt_q[i-1]),
.DOUT (wpkt_q[i])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (1)
)
wr_stg_inst
(
.RST (axis_rd_has_rst),
.CLK (M_ACLK),
.DIN (axis_af_q[i-1]),
.DOUT (axis_af_q[i])
);
end endgenerate // gpkt_cnt_sync_stage
generate if (C_APPLICATION_TYPE_AXIS == 1 && C_COMMON_CLOCK == 0) begin : gaxis_pkt_fifo_ic
assign axis_wr_eop = axis_wr_en & S_AXIS_TLAST;
assign axis_rd_eop = axis_rd_en & axis_dout[0];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_pkt_read <= 1'b0;
else if (axis_rd_eop && (diff_pkt_cnt == 1))
axis_pkt_read <= 1'b0;
else if ((diff_pkt_cnt > 0) || (axis_af_rd && ~axis_empty))
axis_pkt_read <= 1'b1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt <= 1'b0;
else if (axis_wr_eop)
axis_wpkt_cnt <= axis_wpkt_cnt + 1;
end
always @ (posedge axis_wr_rst or posedge S_ACLK)
begin
if (axis_wr_rst)
axis_wpkt_cnt_gc <= 1'b0;
else
axis_wpkt_cnt_gc <= bin2gray(axis_wpkt_cnt);
end
assign wpkt_q[0] = axis_wpkt_cnt_gc;
assign axis_wpkt_cnt_gc_asreg_last = wpkt_q[C_SYNCHRONIZER_STAGE];
assign axis_af_q[0] = axis_almost_full;
//assign axis_af_q[1:C_SYNCHRONIZER_STAGE] = axis_af_q_temp[1:C_SYNCHRONIZER_STAGE];
assign axis_af_rd = axis_af_q[C_SYNCHRONIZER_STAGE];
always @ (posedge axis_rd_has_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_wpkt_cnt_rd <= 1'b0;
else
axis_wpkt_cnt_rd <= gray2bin(axis_wpkt_cnt_gc_asreg_last);
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
axis_rpkt_cnt <= 1'b0;
else if (axis_rd_eop)
axis_rpkt_cnt <= axis_rpkt_cnt + 1;
end
// Take the difference of write and read packet count
// Logic is similar to rd_pe_as
assign adj_axis_wpkt_cnt_rd_pad[LOG_DEPTH_AXIS : 1] = axis_wpkt_cnt_rd;
assign rpkt_inv_pad[LOG_DEPTH_AXIS : 1] = ~axis_rpkt_cnt;
assign adj_axis_wpkt_cnt_rd_pad[0] = adj_axis_wpkt_cnt_rd_pad_0;
assign rpkt_inv_pad[0] = rpkt_inv_pad_0;
always @ ( axis_rd_eop )
begin
if (!axis_rd_eop) begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b1;
rpkt_inv_pad_0 <= 1'b1;
end else begin
adj_axis_wpkt_cnt_rd_pad_0 <= 1'b0;
rpkt_inv_pad_0 <= 1'b0;
end
end
always @ (posedge axis_rd_rst or posedge M_ACLK)
begin
if (axis_rd_has_rst)
diff_pkt_cnt_pad <= 1'b0;
else
diff_pkt_cnt_pad <= adj_axis_wpkt_cnt_rd_pad + rpkt_inv_pad ;
end
assign diff_pkt_cnt = diff_pkt_cnt_pad [LOG_DEPTH_AXIS : 1] ;
end endgenerate // gaxis_pkt_fifo_ic
// Generate the accurate data count for axi stream packet fifo configuration
reg [C_WR_PNTR_WIDTH_AXIS:0] axis_dc_pkt_fifo = 0;
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 1 && C_APPLICATION_TYPE_AXIS == 1) begin : gdc_pkt
always @ (posedge inverted_reset or posedge S_ACLK)
begin
if (inverted_reset)
axis_dc_pkt_fifo <= 0;
else if (axis_wr_en && (~axis_rd_en))
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo + 1;
else if (~axis_wr_en && axis_rd_en)
axis_dc_pkt_fifo <= #`TCQ axis_dc_pkt_fifo - 1;
end
assign AXIS_DATA_COUNT = axis_dc_pkt_fifo;
end endgenerate // gdc_pkt
generate if (IS_AXI_STREAMING == 1 && C_HAS_DATA_COUNTS_AXIS == 0 && C_APPLICATION_TYPE_AXIS == 1) begin : gndc_pkt
assign AXIS_DATA_COUNT = 0;
end endgenerate // gndc_pkt
generate if (IS_AXI_STREAMING == 1 && C_APPLICATION_TYPE_AXIS != 1) begin : gdc
assign AXIS_DATA_COUNT = axis_dc;
end endgenerate // gdc
// Register Slice for Write Address Channel
generate if (C_AXIS_TYPE == 1) begin : gaxis_reg_slice
assign axis_wr_en = (C_HAS_SLAVE_CE == 1) ? S_AXIS_TVALID & S_ACLK_EN : S_AXIS_TVALID;
assign axis_rd_en = (C_HAS_MASTER_CE == 1) ? M_AXIS_TREADY & M_ACLK_EN : M_AXIS_TREADY;
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_AXIS),
.C_REG_CONFIG (C_REG_SLICE_MODE_AXIS)
)
axis_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (axis_din),
.S_VALID (axis_wr_en),
.S_READY (S_AXIS_TREADY),
// Master side
.M_PAYLOAD_DATA (axis_dout),
.M_VALID (M_AXIS_TVALID),
.M_READY (axis_rd_en)
);
end endgenerate // gaxis_reg_slice
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDATA == 1) begin : tdata
assign axis_din[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET] = S_AXIS_TDATA;
assign M_AXIS_TDATA = axis_dout[C_DIN_WIDTH_AXIS-1:TDATA_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TSTRB == 1) begin : tstrb
assign axis_din[TDATA_OFFSET-1:TSTRB_OFFSET] = S_AXIS_TSTRB;
assign M_AXIS_TSTRB = axis_dout[TDATA_OFFSET-1:TSTRB_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TKEEP == 1) begin : tkeep
assign axis_din[TSTRB_OFFSET-1:TKEEP_OFFSET] = S_AXIS_TKEEP;
assign M_AXIS_TKEEP = axis_dout[TSTRB_OFFSET-1:TKEEP_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TID == 1) begin : tid
assign axis_din[TKEEP_OFFSET-1:TID_OFFSET] = S_AXIS_TID;
assign M_AXIS_TID = axis_dout[TKEEP_OFFSET-1:TID_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TDEST == 1) begin : tdest
assign axis_din[TID_OFFSET-1:TDEST_OFFSET] = S_AXIS_TDEST;
assign M_AXIS_TDEST = axis_dout[TID_OFFSET-1:TDEST_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TUSER == 1) begin : tuser
assign axis_din[TDEST_OFFSET-1:TUSER_OFFSET] = S_AXIS_TUSER;
assign M_AXIS_TUSER = axis_dout[TDEST_OFFSET-1:TUSER_OFFSET];
end endgenerate
generate if ((IS_AXI_STREAMING == 1 || C_AXIS_TYPE == 1) && C_HAS_AXIS_TLAST == 1) begin : tlast
assign axis_din[0] = S_AXIS_TLAST;
assign M_AXIS_TLAST = axis_dout[0];
end endgenerate
//###########################################################################
// AXI FULL Write Channel (axi_write_channel)
//###########################################################################
localparam IS_AXI_FULL = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE != 2)) ? 1 : 0;
localparam IS_AXI_LITE = ((C_INTERFACE_TYPE == 2) && (C_AXI_TYPE == 2)) ? 1 : 0;
localparam IS_AXI_FULL_WACH = ((IS_AXI_FULL == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WDCH = ((IS_AXI_FULL == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_WRCH = ((IS_AXI_FULL == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RACH = ((IS_AXI_FULL == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_FULL_RDCH = ((IS_AXI_FULL == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WACH = ((IS_AXI_LITE == 1) && (C_WACH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WDCH = ((IS_AXI_LITE == 1) && (C_WDCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_WRCH = ((IS_AXI_LITE == 1) && (C_WRCH_TYPE == 0) && C_HAS_AXI_WR_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RACH = ((IS_AXI_LITE == 1) && (C_RACH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_AXI_LITE_RDCH = ((IS_AXI_LITE == 1) && (C_RDCH_TYPE == 0) && C_HAS_AXI_RD_CHANNEL == 1) ? 1 : 0;
localparam IS_WR_ADDR_CH = ((IS_AXI_FULL_WACH == 1) || (IS_AXI_LITE_WACH == 1)) ? 1 : 0;
localparam IS_WR_DATA_CH = ((IS_AXI_FULL_WDCH == 1) || (IS_AXI_LITE_WDCH == 1)) ? 1 : 0;
localparam IS_WR_RESP_CH = ((IS_AXI_FULL_WRCH == 1) || (IS_AXI_LITE_WRCH == 1)) ? 1 : 0;
localparam IS_RD_ADDR_CH = ((IS_AXI_FULL_RACH == 1) || (IS_AXI_LITE_RACH == 1)) ? 1 : 0;
localparam IS_RD_DATA_CH = ((IS_AXI_FULL_RDCH == 1) || (IS_AXI_LITE_RDCH == 1)) ? 1 : 0;
localparam AWID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WACH;
localparam AWADDR_OFFSET = AWID_OFFSET - C_AXI_ADDR_WIDTH;
localparam AWLEN_OFFSET = C_AXI_TYPE != 2 ? AWADDR_OFFSET - C_AXI_LEN_WIDTH : AWADDR_OFFSET;
localparam AWSIZE_OFFSET = C_AXI_TYPE != 2 ? AWLEN_OFFSET - C_AXI_SIZE_WIDTH : AWLEN_OFFSET;
localparam AWBURST_OFFSET = C_AXI_TYPE != 2 ? AWSIZE_OFFSET - C_AXI_BURST_WIDTH : AWSIZE_OFFSET;
localparam AWLOCK_OFFSET = C_AXI_TYPE != 2 ? AWBURST_OFFSET - C_AXI_LOCK_WIDTH : AWBURST_OFFSET;
localparam AWCACHE_OFFSET = C_AXI_TYPE != 2 ? AWLOCK_OFFSET - C_AXI_CACHE_WIDTH : AWLOCK_OFFSET;
localparam AWPROT_OFFSET = AWCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam AWQOS_OFFSET = AWPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam AWREGION_OFFSET = C_AXI_TYPE == 1 ? AWQOS_OFFSET - C_AXI_REGION_WIDTH : AWQOS_OFFSET;
localparam AWUSER_OFFSET = C_HAS_AXI_AWUSER == 1 ? AWREGION_OFFSET-C_AXI_AWUSER_WIDTH : AWREGION_OFFSET;
localparam WID_OFFSET = (C_AXI_TYPE == 3 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WDCH;
localparam WDATA_OFFSET = WID_OFFSET - C_AXI_DATA_WIDTH;
localparam WSTRB_OFFSET = WDATA_OFFSET - C_AXI_DATA_WIDTH/8;
localparam WUSER_OFFSET = C_HAS_AXI_WUSER == 1 ? WSTRB_OFFSET-C_AXI_WUSER_WIDTH : WSTRB_OFFSET;
localparam BID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_WRCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_WRCH;
localparam BRESP_OFFSET = BID_OFFSET - C_AXI_BRESP_WIDTH;
localparam BUSER_OFFSET = C_HAS_AXI_BUSER == 1 ? BRESP_OFFSET-C_AXI_BUSER_WIDTH : BRESP_OFFSET;
wire [C_DIN_WIDTH_WACH-1:0] wach_din ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout ;
wire [C_DIN_WIDTH_WACH-1:0] wach_dout_pkt ;
wire wach_full ;
wire wach_almost_full ;
wire wach_prog_full ;
wire wach_empty ;
wire wach_almost_empty ;
wire wach_prog_empty ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_din ;
wire [C_DIN_WIDTH_WDCH-1:0] wdch_dout ;
wire wdch_full ;
wire wdch_almost_full ;
wire wdch_prog_full ;
wire wdch_empty ;
wire wdch_almost_empty ;
wire wdch_prog_empty ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_din ;
wire [C_DIN_WIDTH_WRCH-1:0] wrch_dout ;
wire wrch_full ;
wire wrch_almost_full ;
wire wrch_prog_full ;
wire wrch_empty ;
wire wrch_almost_empty ;
wire wrch_prog_empty ;
wire axi_aw_underflow_i;
wire axi_w_underflow_i ;
wire axi_b_underflow_i ;
wire axi_aw_overflow_i ;
wire axi_w_overflow_i ;
wire axi_b_overflow_i ;
wire axi_wr_underflow_i;
wire axi_wr_overflow_i ;
wire wach_s_axi_awready;
wire wach_m_axi_awvalid;
wire wach_wr_en ;
wire wach_rd_en ;
wire wdch_s_axi_wready ;
wire wdch_m_axi_wvalid ;
wire wdch_wr_en ;
wire wdch_rd_en ;
wire wrch_s_axi_bvalid ;
wire wrch_m_axi_bready ;
wire wrch_wr_en ;
wire wrch_rd_en ;
wire txn_count_up ;
wire txn_count_down ;
wire awvalid_en ;
wire awvalid_pkt ;
wire awready_pkt ;
integer wr_pkt_count ;
wire wach_we ;
wire wach_re ;
wire wdch_we ;
wire wdch_re ;
wire wrch_we ;
wire wrch_re ;
generate if (IS_WR_ADDR_CH == 1) begin : axi_write_address_channel
// Write protection when almost full or prog_full is high
assign wach_we = (C_PROG_FULL_TYPE_WACH != 0) ? wach_s_axi_awready & S_AXI_AWVALID : S_AXI_AWVALID;
// Read protection when almost empty or prog_empty is high
assign wach_re = (C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH == 1) ?
wach_m_axi_awvalid & awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH != 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY && wach_m_axi_awvalid :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH == 1) ?
awready_pkt & awvalid_en :
(C_PROG_EMPTY_TYPE_WACH == 0 && C_APPLICATION_TYPE_WACH != 1) ?
M_AXI_AWREADY : 1'b0;
assign wach_wr_en = (C_HAS_SLAVE_CE == 1) ? wach_we & S_ACLK_EN : wach_we;
assign wach_rd_en = (C_HAS_MASTER_CE == 1) ? wach_re & M_ACLK_EN : wach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WACH == 2 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WACH == 11 || C_IMPLEMENTATION_TYPE_WACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_DEPTH (C_WR_DEPTH_WACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WACH),
.C_RD_DEPTH (C_WR_DEPTH_WACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH),
.C_USE_ECC (C_USE_ECC_WACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_WACH == 1)?0:C_APPLICATION_TYPE_WACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WACH == 1 || C_IMPLEMENTATION_TYPE_WACH == 11) ? 1 : 0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wach_wr_en),
.RD_EN (wach_rd_en),
.PROG_FULL_THRESH (AXI_AW_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AW_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WACH{1'b0}}),
.INJECTDBITERR (AXI_AW_INJECTDBITERR),
.INJECTSBITERR (AXI_AW_INJECTSBITERR),
.DIN (wach_din),
.DOUT (wach_dout_pkt),
.FULL (wach_full),
.EMPTY (wach_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_AW_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_AW_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_aw_overflow_i),
.VALID (),
.UNDERFLOW (axi_aw_underflow_i),
.DATA_COUNT (AXI_AW_DATA_COUNT),
.RD_DATA_COUNT (AXI_AW_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AW_WR_DATA_COUNT),
.SBITERR (AXI_AW_SBITERR),
.DBITERR (AXI_AW_DBITERR),
.wr_rst_busy (wr_rst_busy_wach),
.rd_rst_busy (rd_rst_busy_wach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wach_s_axi_awready = (IS_8SERIES == 0) ? ~wach_full : (C_IMPLEMENTATION_TYPE_WACH == 5 || C_IMPLEMENTATION_TYPE_WACH == 13) ? ~(wach_full | wr_rst_busy_wach) : ~wach_full;
assign wach_m_axi_awvalid = ~wach_empty;
assign S_AXI_AWREADY = wach_s_axi_awready;
assign AXI_AW_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_aw_underflow_i : 0;
assign AXI_AW_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_aw_overflow_i : 0;
end endgenerate // axi_write_address_channel
// Register Slice for Write Address Channel
generate if (C_WACH_TYPE == 1) begin : gwach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WACH)
)
wach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wach_din),
.S_VALID (S_AXI_AWVALID),
.S_READY (S_AXI_AWREADY),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
end endgenerate // gwach_reg_slice
generate if (C_APPLICATION_TYPE_WACH == 1 && C_HAS_AXI_WR_CHANNEL == 1) begin : axi_mm_pkt_fifo_wr
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WACH),
.C_REG_CONFIG (1)
)
wach_pkt_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (wach_dout_pkt),
.S_VALID (awvalid_pkt),
.S_READY (awready_pkt),
// Master side
.M_PAYLOAD_DATA (wach_dout),
.M_VALID (M_AXI_AWVALID),
.M_READY (M_AXI_AWREADY)
);
assign awvalid_pkt = wach_m_axi_awvalid && awvalid_en;
assign txn_count_up = wdch_s_axi_wready && wdch_wr_en && wdch_din[0];
assign txn_count_down = wach_m_axi_awvalid && awready_pkt && awvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset == 1) begin
wr_pkt_count <= 0;
end else begin
if(txn_count_up == 1 && txn_count_down == 0) begin
wr_pkt_count <= wr_pkt_count + 1;
end else if(txn_count_up == 0 && txn_count_down == 1) begin
wr_pkt_count <= wr_pkt_count - 1;
end
end
end //Always end
assign awvalid_en = (wr_pkt_count > 0)?1:0;
end endgenerate
generate if (C_APPLICATION_TYPE_WACH != 1) begin : axi_mm_fifo_wr
assign awvalid_en = 1;
assign wach_dout = wach_dout_pkt;
assign M_AXI_AWVALID = wach_m_axi_awvalid;
end
endgenerate
generate if (IS_WR_DATA_CH == 1) begin : axi_write_data_channel
// Write protection when almost full or prog_full is high
assign wdch_we = (C_PROG_FULL_TYPE_WDCH != 0) ? wdch_s_axi_wready & S_AXI_WVALID : S_AXI_WVALID;
// Read protection when almost empty or prog_empty is high
assign wdch_re = (C_PROG_EMPTY_TYPE_WDCH != 0) ? wdch_m_axi_wvalid & M_AXI_WREADY : M_AXI_WREADY;
assign wdch_wr_en = (C_HAS_SLAVE_CE == 1) ? wdch_we & S_ACLK_EN : wdch_we;
assign wdch_rd_en = (C_HAS_MASTER_CE == 1) ? wdch_re & M_ACLK_EN : wdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WDCH == 2 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WDCH == 11 || C_IMPLEMENTATION_TYPE_WDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WDCH),
.C_WR_DEPTH (C_WR_DEPTH_WDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WDCH),
.C_RD_DEPTH (C_WR_DEPTH_WDCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH),
.C_USE_ECC (C_USE_ECC_WDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WDCH == 1 || C_IMPLEMENTATION_TYPE_WDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wdch_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wdch_wr_en),
.RD_EN (wdch_rd_en),
.PROG_FULL_THRESH (AXI_W_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_W_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WDCH{1'b0}}),
.INJECTDBITERR (AXI_W_INJECTDBITERR),
.INJECTSBITERR (AXI_W_INJECTSBITERR),
.DIN (wdch_din),
.DOUT (wdch_dout),
.FULL (wdch_full),
.EMPTY (wdch_empty),
.ALMOST_FULL (),
.PROG_FULL (AXI_W_PROG_FULL),
.ALMOST_EMPTY (),
.PROG_EMPTY (AXI_W_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_w_overflow_i),
.VALID (),
.UNDERFLOW (axi_w_underflow_i),
.DATA_COUNT (AXI_W_DATA_COUNT),
.RD_DATA_COUNT (AXI_W_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_W_WR_DATA_COUNT),
.SBITERR (AXI_W_SBITERR),
.DBITERR (AXI_W_DBITERR),
.wr_rst_busy (wr_rst_busy_wdch),
.rd_rst_busy (rd_rst_busy_wdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wdch_s_axi_wready = (IS_8SERIES == 0) ? ~wdch_full : (C_IMPLEMENTATION_TYPE_WDCH == 5 || C_IMPLEMENTATION_TYPE_WDCH == 13) ? ~(wdch_full | wr_rst_busy_wdch) : ~wdch_full;
assign wdch_m_axi_wvalid = ~wdch_empty;
assign S_AXI_WREADY = wdch_s_axi_wready;
assign M_AXI_WVALID = wdch_m_axi_wvalid;
assign AXI_W_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_w_underflow_i : 0;
assign AXI_W_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_w_overflow_i : 0;
end endgenerate // axi_write_data_channel
// Register Slice for Write Data Channel
generate if (C_WDCH_TYPE == 1) begin : gwdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WDCH)
)
wdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wdch_din),
.S_VALID (S_AXI_WVALID),
.S_READY (S_AXI_WREADY),
// Master side
.M_PAYLOAD_DATA (wdch_dout),
.M_VALID (M_AXI_WVALID),
.M_READY (M_AXI_WREADY)
);
end endgenerate // gwdch_reg_slice
generate if (IS_WR_RESP_CH == 1) begin : axi_write_resp_channel
// Write protection when almost full or prog_full is high
assign wrch_we = (C_PROG_FULL_TYPE_WRCH != 0) ? wrch_m_axi_bready & M_AXI_BVALID : M_AXI_BVALID;
// Read protection when almost empty or prog_empty is high
assign wrch_re = (C_PROG_EMPTY_TYPE_WRCH != 0) ? wrch_s_axi_bvalid & S_AXI_BREADY : S_AXI_BREADY;
assign wrch_wr_en = (C_HAS_MASTER_CE == 1) ? wrch_we & M_ACLK_EN : wrch_we;
assign wrch_rd_en = (C_HAS_SLAVE_CE == 1) ? wrch_re & S_ACLK_EN : wrch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_WRCH == 2 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_WRCH == 11 || C_IMPLEMENTATION_TYPE_WRCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_WRCH),
.C_WR_DEPTH (C_WR_DEPTH_WRCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_WRCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_DEPTH (C_WR_DEPTH_WRCH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_WRCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_WRCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_WRCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_WRCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH),
.C_USE_ECC (C_USE_ECC_WRCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_WRCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_WRCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_WRCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_WRCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_WRCH == 1 || C_IMPLEMENTATION_TYPE_WRCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_wrch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (wrch_wr_en),
.RD_EN (wrch_rd_en),
.PROG_FULL_THRESH (AXI_B_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_B_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_WRCH{1'b0}}),
.INJECTDBITERR (AXI_B_INJECTDBITERR),
.INJECTSBITERR (AXI_B_INJECTSBITERR),
.DIN (wrch_din),
.DOUT (wrch_dout),
.FULL (wrch_full),
.EMPTY (wrch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_B_PROG_FULL),
.PROG_EMPTY (AXI_B_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_b_overflow_i),
.VALID (),
.UNDERFLOW (axi_b_underflow_i),
.DATA_COUNT (AXI_B_DATA_COUNT),
.RD_DATA_COUNT (AXI_B_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_B_WR_DATA_COUNT),
.SBITERR (AXI_B_SBITERR),
.DBITERR (AXI_B_DBITERR),
.wr_rst_busy (wr_rst_busy_wrch),
.rd_rst_busy (rd_rst_busy_wrch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign wrch_s_axi_bvalid = ~wrch_empty;
assign wrch_m_axi_bready = (IS_8SERIES == 0) ? ~wrch_full : (C_IMPLEMENTATION_TYPE_WRCH == 5 || C_IMPLEMENTATION_TYPE_WRCH == 13) ? ~(wrch_full | wr_rst_busy_wrch) : ~wrch_full;
assign S_AXI_BVALID = wrch_s_axi_bvalid;
assign M_AXI_BREADY = wrch_m_axi_bready;
assign AXI_B_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_b_underflow_i : 0;
assign AXI_B_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_b_overflow_i : 0;
end endgenerate // axi_write_resp_channel
// Register Slice for Write Response Channel
generate if (C_WRCH_TYPE == 1) begin : gwrch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_WRCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_WRCH)
)
wrch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (wrch_din),
.S_VALID (M_AXI_BVALID),
.S_READY (M_AXI_BREADY),
// Master side
.M_PAYLOAD_DATA (wrch_dout),
.M_VALID (S_AXI_BVALID),
.M_READY (S_AXI_BREADY)
);
end endgenerate // gwrch_reg_slice
assign axi_wr_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_aw_underflow_i || axi_w_underflow_i || axi_b_underflow_i) : 0;
assign axi_wr_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_aw_overflow_i || axi_w_overflow_i || axi_b_overflow_i) : 0;
generate if (IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output
assign M_AXI_AWADDR = wach_dout[AWID_OFFSET-1:AWADDR_OFFSET];
assign M_AXI_AWLEN = wach_dout[AWADDR_OFFSET-1:AWLEN_OFFSET];
assign M_AXI_AWSIZE = wach_dout[AWLEN_OFFSET-1:AWSIZE_OFFSET];
assign M_AXI_AWBURST = wach_dout[AWSIZE_OFFSET-1:AWBURST_OFFSET];
assign M_AXI_AWLOCK = wach_dout[AWBURST_OFFSET-1:AWLOCK_OFFSET];
assign M_AXI_AWCACHE = wach_dout[AWLOCK_OFFSET-1:AWCACHE_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWCACHE_OFFSET-1:AWPROT_OFFSET];
assign M_AXI_AWQOS = wach_dout[AWPROT_OFFSET-1:AWQOS_OFFSET];
assign wach_din[AWID_OFFSET-1:AWADDR_OFFSET] = S_AXI_AWADDR;
assign wach_din[AWADDR_OFFSET-1:AWLEN_OFFSET] = S_AXI_AWLEN;
assign wach_din[AWLEN_OFFSET-1:AWSIZE_OFFSET] = S_AXI_AWSIZE;
assign wach_din[AWSIZE_OFFSET-1:AWBURST_OFFSET] = S_AXI_AWBURST;
assign wach_din[AWBURST_OFFSET-1:AWLOCK_OFFSET] = S_AXI_AWLOCK;
assign wach_din[AWLOCK_OFFSET-1:AWCACHE_OFFSET] = S_AXI_AWCACHE;
assign wach_din[AWCACHE_OFFSET-1:AWPROT_OFFSET] = S_AXI_AWPROT;
assign wach_din[AWPROT_OFFSET-1:AWQOS_OFFSET] = S_AXI_AWQOS;
end endgenerate // axi_wach_output
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_awregion
assign M_AXI_AWREGION = wach_dout[AWQOS_OFFSET-1:AWREGION_OFFSET];
end endgenerate // axi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_awregion
assign M_AXI_AWREGION = 0;
end endgenerate // naxi_awregion
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : axi_awuser
assign M_AXI_AWUSER = wach_dout[AWREGION_OFFSET-1:AWUSER_OFFSET];
end endgenerate // axi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 0) begin : naxi_awuser
assign M_AXI_AWUSER = 0;
end endgenerate // naxi_awuser
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_awid
assign M_AXI_AWID = wach_dout[C_DIN_WIDTH_WACH-1:AWID_OFFSET];
end endgenerate //axi_awid
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_awid
assign M_AXI_AWID = 0;
end endgenerate //naxi_awid
generate if (IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output
assign M_AXI_WDATA = wdch_dout[WID_OFFSET-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
assign M_AXI_WLAST = wdch_dout[0];
assign wdch_din[WID_OFFSET-1:WDATA_OFFSET] = S_AXI_WDATA;
assign wdch_din[WDATA_OFFSET-1:WSTRB_OFFSET] = S_AXI_WSTRB;
assign wdch_din[0] = S_AXI_WLAST;
end endgenerate // axi_wdch_output
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin
assign M_AXI_WID = wdch_dout[C_DIN_WIDTH_WDCH-1:WID_OFFSET];
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && (C_HAS_AXI_ID == 0 || C_AXI_TYPE != 3)) begin
assign M_AXI_WID = 0;
end endgenerate
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1 ) begin
assign M_AXI_WUSER = wdch_dout[WSTRB_OFFSET-1:WUSER_OFFSET];
end endgenerate
generate if (C_HAS_AXI_WUSER == 0) begin
assign M_AXI_WUSER = 0;
end endgenerate
generate if (IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output
assign S_AXI_BRESP = wrch_dout[BID_OFFSET-1:BRESP_OFFSET];
assign wrch_din[BID_OFFSET-1:BRESP_OFFSET] = M_AXI_BRESP;
end endgenerate // axi_wrch_output
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : axi_buser
assign S_AXI_BUSER = wrch_dout[BRESP_OFFSET-1:BUSER_OFFSET];
end endgenerate // axi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 0) begin : naxi_buser
assign S_AXI_BUSER = 0;
end endgenerate // naxi_buser
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_bid
assign S_AXI_BID = wrch_dout[C_DIN_WIDTH_WRCH-1:BID_OFFSET];
end endgenerate // axi_bid
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_bid
assign S_AXI_BID = 0 ;
end endgenerate // naxi_bid
generate if (IS_AXI_LITE_WACH == 1 || (IS_AXI_LITE == 1 && C_WACH_TYPE == 1)) begin : axi_wach_output1
assign wach_din = {S_AXI_AWADDR, S_AXI_AWPROT};
assign M_AXI_AWADDR = wach_dout[C_DIN_WIDTH_WACH-1:AWADDR_OFFSET];
assign M_AXI_AWPROT = wach_dout[AWADDR_OFFSET-1:AWPROT_OFFSET];
end endgenerate // axi_wach_output1
generate if (IS_AXI_LITE_WDCH == 1 || (IS_AXI_LITE == 1 && C_WDCH_TYPE == 1)) begin : axi_wdch_output1
assign wdch_din = {S_AXI_WDATA, S_AXI_WSTRB};
assign M_AXI_WDATA = wdch_dout[C_DIN_WIDTH_WDCH-1:WDATA_OFFSET];
assign M_AXI_WSTRB = wdch_dout[WDATA_OFFSET-1:WSTRB_OFFSET];
end endgenerate // axi_wdch_output1
generate if (IS_AXI_LITE_WRCH == 1 || (IS_AXI_LITE == 1 && C_WRCH_TYPE == 1)) begin : axi_wrch_output1
assign wrch_din = M_AXI_BRESP;
assign S_AXI_BRESP = wrch_dout[C_DIN_WIDTH_WRCH-1:BRESP_OFFSET];
end endgenerate // axi_wrch_output1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_AWUSER == 1) begin : gwach_din1
assign wach_din[AWREGION_OFFSET-1:AWUSER_OFFSET] = S_AXI_AWUSER;
end endgenerate // gwach_din1
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwach_din2
assign wach_din[C_DIN_WIDTH_WACH-1:AWID_OFFSET] = S_AXI_AWID;
end endgenerate // gwach_din2
generate if ((IS_AXI_FULL_WACH == 1 || (IS_AXI_FULL == 1 && C_WACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : gwach_din3
assign wach_din[AWQOS_OFFSET-1:AWREGION_OFFSET] = S_AXI_AWREGION;
end endgenerate // gwach_din3
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_WUSER == 1) begin : gwdch_din1
assign wdch_din[WSTRB_OFFSET-1:WUSER_OFFSET] = S_AXI_WUSER;
end endgenerate // gwdch_din1
generate if ((IS_AXI_FULL_WDCH == 1 || (IS_AXI_FULL == 1 && C_WDCH_TYPE == 1)) && C_HAS_AXI_ID == 1 && C_AXI_TYPE == 3) begin : gwdch_din2
assign wdch_din[C_DIN_WIDTH_WDCH-1:WID_OFFSET] = S_AXI_WID;
end endgenerate // gwdch_din2
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_BUSER == 1) begin : gwrch_din1
assign wrch_din[BRESP_OFFSET-1:BUSER_OFFSET] = M_AXI_BUSER;
end endgenerate // gwrch_din1
generate if ((IS_AXI_FULL_WRCH == 1 || (IS_AXI_FULL == 1 && C_WRCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : gwrch_din2
assign wrch_din[C_DIN_WIDTH_WRCH-1:BID_OFFSET] = M_AXI_BID;
end endgenerate // gwrch_din2
//end of axi_write_channel
//###########################################################################
// AXI FULL Read Channel (axi_read_channel)
//###########################################################################
wire [C_DIN_WIDTH_RACH-1:0] rach_din ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout ;
wire [C_DIN_WIDTH_RACH-1:0] rach_dout_pkt ;
wire rach_full ;
wire rach_almost_full ;
wire rach_prog_full ;
wire rach_empty ;
wire rach_almost_empty ;
wire rach_prog_empty ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_din ;
wire [C_DIN_WIDTH_RDCH-1:0] rdch_dout ;
wire rdch_full ;
wire rdch_almost_full ;
wire rdch_prog_full ;
wire rdch_empty ;
wire rdch_almost_empty ;
wire rdch_prog_empty ;
wire axi_ar_underflow_i ;
wire axi_r_underflow_i ;
wire axi_ar_overflow_i ;
wire axi_r_overflow_i ;
wire axi_rd_underflow_i ;
wire axi_rd_overflow_i ;
wire rach_s_axi_arready ;
wire rach_m_axi_arvalid ;
wire rach_wr_en ;
wire rach_rd_en ;
wire rdch_m_axi_rready ;
wire rdch_s_axi_rvalid ;
wire rdch_wr_en ;
wire rdch_rd_en ;
wire arvalid_pkt ;
wire arready_pkt ;
wire arvalid_en ;
wire rdch_rd_ok ;
wire accept_next_pkt ;
integer rdch_free_space ;
integer rdch_commited_space ;
wire rach_we ;
wire rach_re ;
wire rdch_we ;
wire rdch_re ;
localparam ARID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RACH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RACH;
localparam ARADDR_OFFSET = ARID_OFFSET - C_AXI_ADDR_WIDTH;
localparam ARLEN_OFFSET = C_AXI_TYPE != 2 ? ARADDR_OFFSET - C_AXI_LEN_WIDTH : ARADDR_OFFSET;
localparam ARSIZE_OFFSET = C_AXI_TYPE != 2 ? ARLEN_OFFSET - C_AXI_SIZE_WIDTH : ARLEN_OFFSET;
localparam ARBURST_OFFSET = C_AXI_TYPE != 2 ? ARSIZE_OFFSET - C_AXI_BURST_WIDTH : ARSIZE_OFFSET;
localparam ARLOCK_OFFSET = C_AXI_TYPE != 2 ? ARBURST_OFFSET - C_AXI_LOCK_WIDTH : ARBURST_OFFSET;
localparam ARCACHE_OFFSET = C_AXI_TYPE != 2 ? ARLOCK_OFFSET - C_AXI_CACHE_WIDTH : ARLOCK_OFFSET;
localparam ARPROT_OFFSET = ARCACHE_OFFSET - C_AXI_PROT_WIDTH;
localparam ARQOS_OFFSET = ARPROT_OFFSET - C_AXI_QOS_WIDTH;
localparam ARREGION_OFFSET = C_AXI_TYPE == 1 ? ARQOS_OFFSET - C_AXI_REGION_WIDTH : ARQOS_OFFSET;
localparam ARUSER_OFFSET = C_HAS_AXI_ARUSER == 1 ? ARREGION_OFFSET-C_AXI_ARUSER_WIDTH : ARREGION_OFFSET;
localparam RID_OFFSET = (C_AXI_TYPE != 2 && C_HAS_AXI_ID == 1) ? C_DIN_WIDTH_RDCH - C_AXI_ID_WIDTH : C_DIN_WIDTH_RDCH;
localparam RDATA_OFFSET = RID_OFFSET - C_AXI_DATA_WIDTH;
localparam RRESP_OFFSET = RDATA_OFFSET - C_AXI_RRESP_WIDTH;
localparam RUSER_OFFSET = C_HAS_AXI_RUSER == 1 ? RRESP_OFFSET-C_AXI_RUSER_WIDTH : RRESP_OFFSET;
generate if (IS_RD_ADDR_CH == 1) begin : axi_read_addr_channel
// Write protection when almost full or prog_full is high
assign rach_we = (C_PROG_FULL_TYPE_RACH != 0) ? rach_s_axi_arready & S_AXI_ARVALID : S_AXI_ARVALID;
// Read protection when almost empty or prog_empty is high
// assign rach_rd_en = (C_PROG_EMPTY_TYPE_RACH != 5) ? rach_m_axi_arvalid & M_AXI_ARREADY : M_AXI_ARREADY && arvalid_en;
assign rach_re = (C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH == 1) ?
rach_m_axi_arvalid & arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH != 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY && rach_m_axi_arvalid :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH == 1) ?
arready_pkt & arvalid_en :
(C_PROG_EMPTY_TYPE_RACH == 0 && C_APPLICATION_TYPE_RACH != 1) ?
M_AXI_ARREADY : 1'b0;
assign rach_wr_en = (C_HAS_SLAVE_CE == 1) ? rach_we & S_ACLK_EN : rach_we;
assign rach_rd_en = (C_HAS_MASTER_CE == 1) ? rach_re & M_ACLK_EN : rach_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RACH == 2 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RACH == 11 || C_IMPLEMENTATION_TYPE_RACH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RACH),
.C_WR_DEPTH (C_WR_DEPTH_RACH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_DOUT_WIDTH (C_DIN_WIDTH_RACH),
.C_RD_DEPTH (C_WR_DEPTH_RACH),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RACH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RACH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RACH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RACH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH),
.C_USE_ECC (C_USE_ECC_RACH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RACH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE ((C_APPLICATION_TYPE_RACH == 1)?0:C_APPLICATION_TYPE_RACH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RACH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RACH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RACH == 1 || C_IMPLEMENTATION_TYPE_RACH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rach_dut
(
.CLK (S_ACLK),
.WR_CLK (S_ACLK),
.RD_CLK (M_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rach_wr_en),
.RD_EN (rach_rd_en),
.PROG_FULL_THRESH (AXI_AR_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_AR_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RACH{1'b0}}),
.INJECTDBITERR (AXI_AR_INJECTDBITERR),
.INJECTSBITERR (AXI_AR_INJECTSBITERR),
.DIN (rach_din),
.DOUT (rach_dout_pkt),
.FULL (rach_full),
.EMPTY (rach_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_AR_PROG_FULL),
.PROG_EMPTY (AXI_AR_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_ar_overflow_i),
.VALID (),
.UNDERFLOW (axi_ar_underflow_i),
.DATA_COUNT (AXI_AR_DATA_COUNT),
.RD_DATA_COUNT (AXI_AR_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_AR_WR_DATA_COUNT),
.SBITERR (AXI_AR_SBITERR),
.DBITERR (AXI_AR_DBITERR),
.wr_rst_busy (wr_rst_busy_rach),
.rd_rst_busy (rd_rst_busy_rach),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rach_s_axi_arready = (IS_8SERIES == 0) ? ~rach_full : (C_IMPLEMENTATION_TYPE_RACH == 5 || C_IMPLEMENTATION_TYPE_RACH == 13) ? ~(rach_full | wr_rst_busy_rach) : ~rach_full;
assign rach_m_axi_arvalid = ~rach_empty;
assign S_AXI_ARREADY = rach_s_axi_arready;
assign AXI_AR_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_ar_underflow_i : 0;
assign AXI_AR_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_ar_overflow_i : 0;
end endgenerate // axi_read_addr_channel
// Register Slice for Read Address Channel
generate if (C_RACH_TYPE == 1) begin : grach_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RACH)
)
rach_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rach_din),
.S_VALID (S_AXI_ARVALID),
.S_READY (S_AXI_ARREADY),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice
// Register Slice for Read Address Channel for MM Packet FIFO
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH == 1) begin : grach_reg_slice_mm_pkt_fifo
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RACH),
.C_REG_CONFIG (1)
)
reg_slice_mm_pkt_fifo_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (inverted_reset),
// Slave side
.S_PAYLOAD_DATA (rach_dout_pkt),
.S_VALID (arvalid_pkt),
.S_READY (arready_pkt),
// Master side
.M_PAYLOAD_DATA (rach_dout),
.M_VALID (M_AXI_ARVALID),
.M_READY (M_AXI_ARREADY)
);
end endgenerate // grach_reg_slice_mm_pkt_fifo
generate if (C_RACH_TYPE == 0 && C_APPLICATION_TYPE_RACH != 1) begin : grach_m_axi_arvalid
assign M_AXI_ARVALID = rach_m_axi_arvalid;
assign rach_dout = rach_dout_pkt;
end endgenerate // grach_m_axi_arvalid
generate if (C_APPLICATION_TYPE_RACH == 1 && C_HAS_AXI_RD_CHANNEL == 1) begin : axi_mm_pkt_fifo_rd
assign rdch_rd_ok = rdch_s_axi_rvalid && rdch_rd_en;
assign arvalid_pkt = rach_m_axi_arvalid && arvalid_en;
assign accept_next_pkt = rach_m_axi_arvalid && arready_pkt && arvalid_en;
always@(posedge S_ACLK or posedge inverted_reset) begin
if(inverted_reset) begin
rdch_commited_space <= 0;
end else begin
if(rdch_rd_ok && !accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space-1;
end else if(!rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1);
end else if(rdch_rd_ok && accept_next_pkt) begin
rdch_commited_space <= rdch_commited_space+(rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]);
end
end
end //Always end
always@(*) begin
rdch_free_space <= (C_WR_DEPTH_RDCH-(rdch_commited_space+rach_dout_pkt[ARADDR_OFFSET-1:ARLEN_OFFSET]+1));
end
assign arvalid_en = (rdch_free_space >= 0)?1:0;
end
endgenerate
generate if (C_APPLICATION_TYPE_RACH != 1) begin : axi_mm_fifo_rd
assign arvalid_en = 1;
end
endgenerate
generate if (IS_RD_DATA_CH == 1) begin : axi_read_data_channel
// Write protection when almost full or prog_full is high
assign rdch_we = (C_PROG_FULL_TYPE_RDCH != 0) ? rdch_m_axi_rready & M_AXI_RVALID : M_AXI_RVALID;
// Read protection when almost empty or prog_empty is high
assign rdch_re = (C_PROG_EMPTY_TYPE_RDCH != 0) ? rdch_s_axi_rvalid & S_AXI_RREADY : S_AXI_RREADY;
assign rdch_wr_en = (C_HAS_MASTER_CE == 1) ? rdch_we & M_ACLK_EN : rdch_we;
assign rdch_rd_en = (C_HAS_SLAVE_CE == 1) ? rdch_re & S_ACLK_EN : rdch_re;
fifo_generator_v13_1_3_CONV_VER
#(
.C_FAMILY (C_FAMILY),
.C_COMMON_CLOCK (C_COMMON_CLOCK),
.C_MEMORY_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 :
(C_IMPLEMENTATION_TYPE_RDCH == 2 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 4),
.C_IMPLEMENTATION_TYPE ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 2) ? 0 :
(C_IMPLEMENTATION_TYPE_RDCH == 11 || C_IMPLEMENTATION_TYPE_RDCH == 12) ? 2 : 6),
.C_PRELOAD_REGS (1), // always FWFT for AXI
.C_PRELOAD_LATENCY (0), // always FWFT for AXI
.C_DIN_WIDTH (C_DIN_WIDTH_RDCH),
.C_WR_DEPTH (C_WR_DEPTH_RDCH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_DOUT_WIDTH (C_DIN_WIDTH_RDCH),
.C_RD_DEPTH (C_WR_DEPTH_RDCH),
.C_INTERFACE_TYPE (C_INTERFACE_TYPE),
.C_RD_PNTR_WIDTH (C_WR_PNTR_WIDTH_RDCH),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE_RDCH),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL_RDCH),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE_RDCH),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH),
.C_USE_ECC (C_USE_ECC_RDCH),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE_RDCH),
.C_HAS_ALMOST_EMPTY (0),
.C_HAS_ALMOST_FULL (0),
.C_AXI_TYPE (C_INTERFACE_TYPE == 1 ? 0 : C_AXI_TYPE),
.C_FIFO_TYPE (C_APPLICATION_TYPE_RDCH),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_HAS_WR_RST (0),
.C_HAS_RD_RST (0),
.C_HAS_RST (1),
.C_HAS_SRST (0),
.C_DOUT_RST_VAL (0),
.C_HAS_VALID (0),
.C_VALID_LOW (C_VALID_LOW),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_HAS_WR_ACK (0),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_HAS_DATA_COUNT ((C_COMMON_CLOCK == 1 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_HAS_RD_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_RD_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_USE_FWFT_DATA_COUNT (1), // use extra logic is always true
.C_HAS_WR_DATA_COUNT ((C_COMMON_CLOCK == 0 && C_HAS_DATA_COUNTS_RDCH == 1) ? 1 : 0),
.C_WR_DATA_COUNT_WIDTH (C_WR_PNTR_WIDTH_RDCH + 1),
.C_FULL_FLAGS_RST_VAL (1),
.C_USE_EMBEDDED_REG (0),
.C_USE_DOUT_RST (0),
.C_MSGON_VAL (C_MSGON_VAL),
.C_ENABLE_RST_SYNC (1),
.C_EN_SAFETY_CKT ((C_IMPLEMENTATION_TYPE_RDCH == 1 || C_IMPLEMENTATION_TYPE_RDCH == 11) ? 1 : 0),
.C_COUNT_TYPE (C_COUNT_TYPE),
.C_DEFAULT_VALUE (C_DEFAULT_VALUE),
.C_ENABLE_RLOCS (C_ENABLE_RLOCS),
.C_HAS_BACKUP (C_HAS_BACKUP),
.C_HAS_INT_CLK (C_HAS_INT_CLK),
.C_MIF_FILE_NAME (C_MIF_FILE_NAME),
.C_HAS_MEMINIT_FILE (C_HAS_MEMINIT_FILE),
.C_INIT_WR_PNTR_VAL (C_INIT_WR_PNTR_VAL),
.C_OPTIMIZATION_MODE (C_OPTIMIZATION_MODE),
.C_PRIM_FIFO_TYPE (C_PRIM_FIFO_TYPE),
.C_RD_FREQ (C_RD_FREQ),
.C_USE_FIFO16_FLAGS (C_USE_FIFO16_FLAGS),
.C_WR_FREQ (C_WR_FREQ),
.C_WR_RESPONSE_LATENCY (C_WR_RESPONSE_LATENCY)
)
fifo_generator_v13_1_3_rdch_dut
(
.CLK (S_ACLK),
.WR_CLK (M_ACLK),
.RD_CLK (S_ACLK),
.RST (inverted_reset),
.SRST (1'b0),
.WR_RST (inverted_reset),
.RD_RST (inverted_reset),
.WR_EN (rdch_wr_en),
.RD_EN (rdch_rd_en),
.PROG_FULL_THRESH (AXI_R_PROG_FULL_THRESH),
.PROG_FULL_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_FULL_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH (AXI_R_PROG_EMPTY_THRESH),
.PROG_EMPTY_THRESH_ASSERT ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.PROG_EMPTY_THRESH_NEGATE ({C_WR_PNTR_WIDTH_RDCH{1'b0}}),
.INJECTDBITERR (AXI_R_INJECTDBITERR),
.INJECTSBITERR (AXI_R_INJECTSBITERR),
.DIN (rdch_din),
.DOUT (rdch_dout),
.FULL (rdch_full),
.EMPTY (rdch_empty),
.ALMOST_FULL (),
.ALMOST_EMPTY (),
.PROG_FULL (AXI_R_PROG_FULL),
.PROG_EMPTY (AXI_R_PROG_EMPTY),
.WR_ACK (),
.OVERFLOW (axi_r_overflow_i),
.VALID (),
.UNDERFLOW (axi_r_underflow_i),
.DATA_COUNT (AXI_R_DATA_COUNT),
.RD_DATA_COUNT (AXI_R_RD_DATA_COUNT),
.WR_DATA_COUNT (AXI_R_WR_DATA_COUNT),
.SBITERR (AXI_R_SBITERR),
.DBITERR (AXI_R_DBITERR),
.wr_rst_busy (wr_rst_busy_rdch),
.rd_rst_busy (rd_rst_busy_rdch),
.wr_rst_i_out (),
.rd_rst_i_out (),
.BACKUP (BACKUP),
.BACKUP_MARKER (BACKUP_MARKER),
.INT_CLK (INT_CLK)
);
assign rdch_s_axi_rvalid = ~rdch_empty;
assign rdch_m_axi_rready = (IS_8SERIES == 0) ? ~rdch_full : (C_IMPLEMENTATION_TYPE_RDCH == 5 || C_IMPLEMENTATION_TYPE_RDCH == 13) ? ~(rdch_full | wr_rst_busy_rdch) : ~rdch_full;
assign S_AXI_RVALID = rdch_s_axi_rvalid;
assign M_AXI_RREADY = rdch_m_axi_rready;
assign AXI_R_UNDERFLOW = C_USE_COMMON_UNDERFLOW == 0 ? axi_r_underflow_i : 0;
assign AXI_R_OVERFLOW = C_USE_COMMON_OVERFLOW == 0 ? axi_r_overflow_i : 0;
end endgenerate //axi_read_data_channel
// Register Slice for read Data Channel
generate if (C_RDCH_TYPE == 1) begin : grdch_reg_slice
fifo_generator_v13_1_3_axic_reg_slice
#(
.C_FAMILY (C_FAMILY),
.C_DATA_WIDTH (C_DIN_WIDTH_RDCH),
.C_REG_CONFIG (C_REG_SLICE_MODE_RDCH)
)
rdch_reg_slice_inst
(
// System Signals
.ACLK (S_ACLK),
.ARESET (axi_rs_rst),
// Slave side
.S_PAYLOAD_DATA (rdch_din),
.S_VALID (M_AXI_RVALID),
.S_READY (M_AXI_RREADY),
// Master side
.M_PAYLOAD_DATA (rdch_dout),
.M_VALID (S_AXI_RVALID),
.M_READY (S_AXI_RREADY)
);
end endgenerate // grdch_reg_slice
assign axi_rd_underflow_i = C_USE_COMMON_UNDERFLOW == 1 ? (axi_ar_underflow_i || axi_r_underflow_i) : 0;
assign axi_rd_overflow_i = C_USE_COMMON_OVERFLOW == 1 ? (axi_ar_overflow_i || axi_r_overflow_i) : 0;
generate if (IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) begin : axi_full_rach_output
assign M_AXI_ARADDR = rach_dout[ARID_OFFSET-1:ARADDR_OFFSET];
assign M_AXI_ARLEN = rach_dout[ARADDR_OFFSET-1:ARLEN_OFFSET];
assign M_AXI_ARSIZE = rach_dout[ARLEN_OFFSET-1:ARSIZE_OFFSET];
assign M_AXI_ARBURST = rach_dout[ARSIZE_OFFSET-1:ARBURST_OFFSET];
assign M_AXI_ARLOCK = rach_dout[ARBURST_OFFSET-1:ARLOCK_OFFSET];
assign M_AXI_ARCACHE = rach_dout[ARLOCK_OFFSET-1:ARCACHE_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARCACHE_OFFSET-1:ARPROT_OFFSET];
assign M_AXI_ARQOS = rach_dout[ARPROT_OFFSET-1:ARQOS_OFFSET];
assign rach_din[ARID_OFFSET-1:ARADDR_OFFSET] = S_AXI_ARADDR;
assign rach_din[ARADDR_OFFSET-1:ARLEN_OFFSET] = S_AXI_ARLEN;
assign rach_din[ARLEN_OFFSET-1:ARSIZE_OFFSET] = S_AXI_ARSIZE;
assign rach_din[ARSIZE_OFFSET-1:ARBURST_OFFSET] = S_AXI_ARBURST;
assign rach_din[ARBURST_OFFSET-1:ARLOCK_OFFSET] = S_AXI_ARLOCK;
assign rach_din[ARLOCK_OFFSET-1:ARCACHE_OFFSET] = S_AXI_ARCACHE;
assign rach_din[ARCACHE_OFFSET-1:ARPROT_OFFSET] = S_AXI_ARPROT;
assign rach_din[ARPROT_OFFSET-1:ARQOS_OFFSET] = S_AXI_ARQOS;
end endgenerate // axi_full_rach_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin : axi_arregion
assign M_AXI_ARREGION = rach_dout[ARQOS_OFFSET-1:ARREGION_OFFSET];
end endgenerate // axi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE != 1) begin : naxi_arregion
assign M_AXI_ARREGION = 0;
end endgenerate // naxi_arregion
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : axi_aruser
assign M_AXI_ARUSER = rach_dout[ARREGION_OFFSET-1:ARUSER_OFFSET];
end endgenerate // axi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 0) begin : naxi_aruser
assign M_AXI_ARUSER = 0;
end endgenerate // naxi_aruser
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_arid
assign M_AXI_ARID = rach_dout[C_DIN_WIDTH_RACH-1:ARID_OFFSET];
end endgenerate // axi_arid
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_arid
assign M_AXI_ARID = 0;
end endgenerate // naxi_arid
generate if (IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) begin : axi_full_rdch_output
assign S_AXI_RDATA = rdch_dout[RID_OFFSET-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
assign S_AXI_RLAST = rdch_dout[0];
assign rdch_din[RID_OFFSET-1:RDATA_OFFSET] = M_AXI_RDATA;
assign rdch_din[RDATA_OFFSET-1:RRESP_OFFSET] = M_AXI_RRESP;
assign rdch_din[0] = M_AXI_RLAST;
end endgenerate // axi_full_rdch_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : axi_full_ruser_output
assign S_AXI_RUSER = rdch_dout[RRESP_OFFSET-1:RUSER_OFFSET];
end endgenerate // axi_full_ruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 0) begin : axi_full_nruser_output
assign S_AXI_RUSER = 0;
end endgenerate // axi_full_nruser_output
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : axi_rid
assign S_AXI_RID = rdch_dout[C_DIN_WIDTH_RDCH-1:RID_OFFSET];
end endgenerate // axi_rid
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 0) begin : naxi_rid
assign S_AXI_RID = 0;
end endgenerate // naxi_rid
generate if (IS_AXI_LITE_RACH == 1 || (IS_AXI_LITE == 1 && C_RACH_TYPE == 1)) begin : axi_lite_rach_output1
assign rach_din = {S_AXI_ARADDR, S_AXI_ARPROT};
assign M_AXI_ARADDR = rach_dout[C_DIN_WIDTH_RACH-1:ARADDR_OFFSET];
assign M_AXI_ARPROT = rach_dout[ARADDR_OFFSET-1:ARPROT_OFFSET];
end endgenerate // axi_lite_rach_output
generate if (IS_AXI_LITE_RDCH == 1 || (IS_AXI_LITE == 1 && C_RDCH_TYPE == 1)) begin : axi_lite_rdch_output1
assign rdch_din = {M_AXI_RDATA, M_AXI_RRESP};
assign S_AXI_RDATA = rdch_dout[C_DIN_WIDTH_RDCH-1:RDATA_OFFSET];
assign S_AXI_RRESP = rdch_dout[RDATA_OFFSET-1:RRESP_OFFSET];
end endgenerate // axi_lite_rdch_output
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ARUSER == 1) begin : grach_din1
assign rach_din[ARREGION_OFFSET-1:ARUSER_OFFSET] = S_AXI_ARUSER;
end endgenerate // grach_din1
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grach_din2
assign rach_din[C_DIN_WIDTH_RACH-1:ARID_OFFSET] = S_AXI_ARID;
end endgenerate // grach_din2
generate if ((IS_AXI_FULL_RACH == 1 || (IS_AXI_FULL == 1 && C_RACH_TYPE == 1)) && C_AXI_TYPE == 1) begin
assign rach_din[ARQOS_OFFSET-1:ARREGION_OFFSET] = S_AXI_ARREGION;
end endgenerate
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_RUSER == 1) begin : grdch_din1
assign rdch_din[RRESP_OFFSET-1:RUSER_OFFSET] = M_AXI_RUSER;
end endgenerate // grdch_din1
generate if ((IS_AXI_FULL_RDCH == 1 || (IS_AXI_FULL == 1 && C_RDCH_TYPE == 1)) && C_HAS_AXI_ID == 1) begin : grdch_din2
assign rdch_din[C_DIN_WIDTH_RDCH-1:RID_OFFSET] = M_AXI_RID;
end endgenerate // grdch_din2
//end of axi_read_channel
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_UNDERFLOW == 1) begin : gaxi_comm_uf
assign UNDERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_underflow_i || axi_rd_underflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_underflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_underflow_i : 0;
end endgenerate // gaxi_comm_uf
generate if (C_INTERFACE_TYPE == 1 && C_USE_COMMON_OVERFLOW == 1) begin : gaxi_comm_of
assign OVERFLOW = (C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 1) ? (axi_wr_overflow_i || axi_rd_overflow_i) :
(C_HAS_AXI_WR_CHANNEL == 1 && C_HAS_AXI_RD_CHANNEL == 0) ? axi_wr_overflow_i :
(C_HAS_AXI_WR_CHANNEL == 0 && C_HAS_AXI_RD_CHANNEL == 1) ? axi_rd_overflow_i : 0;
end endgenerate // gaxi_comm_of
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic or Wiring Logic
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Write Address Channel
generate if (C_WACH_TYPE == 2) begin : gwach_pass_through
assign M_AXI_AWID = S_AXI_AWID;
assign M_AXI_AWADDR = S_AXI_AWADDR;
assign M_AXI_AWLEN = S_AXI_AWLEN;
assign M_AXI_AWSIZE = S_AXI_AWSIZE;
assign M_AXI_AWBURST = S_AXI_AWBURST;
assign M_AXI_AWLOCK = S_AXI_AWLOCK;
assign M_AXI_AWCACHE = S_AXI_AWCACHE;
assign M_AXI_AWPROT = S_AXI_AWPROT;
assign M_AXI_AWQOS = S_AXI_AWQOS;
assign M_AXI_AWREGION = S_AXI_AWREGION;
assign M_AXI_AWUSER = S_AXI_AWUSER;
assign S_AXI_AWREADY = M_AXI_AWREADY;
assign M_AXI_AWVALID = S_AXI_AWVALID;
end endgenerate // gwach_pass_through;
// Wiring logic for Write Data Channel
generate if (C_WDCH_TYPE == 2) begin : gwdch_pass_through
assign M_AXI_WID = S_AXI_WID;
assign M_AXI_WDATA = S_AXI_WDATA;
assign M_AXI_WSTRB = S_AXI_WSTRB;
assign M_AXI_WLAST = S_AXI_WLAST;
assign M_AXI_WUSER = S_AXI_WUSER;
assign S_AXI_WREADY = M_AXI_WREADY;
assign M_AXI_WVALID = S_AXI_WVALID;
end endgenerate // gwdch_pass_through;
// Wiring logic for Write Response Channel
generate if (C_WRCH_TYPE == 2) begin : gwrch_pass_through
assign S_AXI_BID = M_AXI_BID;
assign S_AXI_BRESP = M_AXI_BRESP;
assign S_AXI_BUSER = M_AXI_BUSER;
assign M_AXI_BREADY = S_AXI_BREADY;
assign S_AXI_BVALID = M_AXI_BVALID;
end endgenerate // gwrch_pass_through;
//-------------------------------------------------------------------------
// Pass Through Logic for Read Channel
//-------------------------------------------------------------------------
// Wiring logic for Read Address Channel
generate if (C_RACH_TYPE == 2) begin : grach_pass_through
assign M_AXI_ARID = S_AXI_ARID;
assign M_AXI_ARADDR = S_AXI_ARADDR;
assign M_AXI_ARLEN = S_AXI_ARLEN;
assign M_AXI_ARSIZE = S_AXI_ARSIZE;
assign M_AXI_ARBURST = S_AXI_ARBURST;
assign M_AXI_ARLOCK = S_AXI_ARLOCK;
assign M_AXI_ARCACHE = S_AXI_ARCACHE;
assign M_AXI_ARPROT = S_AXI_ARPROT;
assign M_AXI_ARQOS = S_AXI_ARQOS;
assign M_AXI_ARREGION = S_AXI_ARREGION;
assign M_AXI_ARUSER = S_AXI_ARUSER;
assign S_AXI_ARREADY = M_AXI_ARREADY;
assign M_AXI_ARVALID = S_AXI_ARVALID;
end endgenerate // grach_pass_through;
// Wiring logic for Read Data Channel
generate if (C_RDCH_TYPE == 2) begin : grdch_pass_through
assign S_AXI_RID = M_AXI_RID;
assign S_AXI_RLAST = M_AXI_RLAST;
assign S_AXI_RUSER = M_AXI_RUSER;
assign S_AXI_RDATA = M_AXI_RDATA;
assign S_AXI_RRESP = M_AXI_RRESP;
assign S_AXI_RVALID = M_AXI_RVALID;
assign M_AXI_RREADY = S_AXI_RREADY;
end endgenerate // grdch_pass_through;
// Wiring logic for AXI Streaming
generate if (C_AXIS_TYPE == 2) begin : gaxis_pass_through
assign M_AXIS_TDATA = S_AXIS_TDATA;
assign M_AXIS_TSTRB = S_AXIS_TSTRB;
assign M_AXIS_TKEEP = S_AXIS_TKEEP;
assign M_AXIS_TID = S_AXIS_TID;
assign M_AXIS_TDEST = S_AXIS_TDEST;
assign M_AXIS_TUSER = S_AXIS_TUSER;
assign M_AXIS_TLAST = S_AXIS_TLAST;
assign S_AXIS_TREADY = M_AXIS_TREADY;
assign M_AXIS_TVALID = S_AXIS_TVALID;
end endgenerate // gaxis_pass_through;
endmodule //fifo_generator_v13_1_3
/*******************************************************************************
* Declaration of top-level module for Conventional FIFO
******************************************************************************/
module fifo_generator_v13_1_3_CONV_VER
#(
parameter C_COMMON_CLOCK = 0,
parameter C_INTERFACE_TYPE = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_COUNT_TYPE = 0,
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DEFAULT_VALUE = "",
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_ENABLE_RLOCS = 0,
parameter C_FAMILY = "virtex7", //Not allowed in Verilog model
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_BACKUP = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_INT_CLK = 0,
parameter C_HAS_MEMINIT_FILE = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RD_RST = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_HAS_WR_RST = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_INIT_WR_PNTR_VAL = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_MIF_FILE_NAME = "",
parameter C_OPTIMIZATION_MODE = 0,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PRIM_FIFO_TYPE = "",
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_FREQ = 1,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_USE_FIFO16_FLAGS = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_FREQ = 1,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_WR_RESPONSE_LATENCY = 1,
parameter C_MSGON_VAL = 1,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2,
parameter C_AXI_TYPE = 0
)
(
input BACKUP,
input BACKUP_MARKER,
input CLK,
input RST,
input SRST,
input WR_CLK,
input WR_RST,
input RD_CLK,
input RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input WR_EN,
input RD_EN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input INT_CLK,
input INJECTDBITERR,
input INJECTSBITERR,
output [C_DOUT_WIDTH-1:0] DOUT,
output FULL,
output ALMOST_FULL,
output WR_ACK,
output OVERFLOW,
output EMPTY,
output ALMOST_EMPTY,
output VALID,
output UNDERFLOW,
output [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_FULL,
output PROG_EMPTY,
output SBITERR,
output DBITERR,
output wr_rst_busy_o,
output wr_rst_busy,
output rd_rst_busy,
output wr_rst_i_out,
output rd_rst_i_out
);
/*
******************************************************************************
* Definition of Parameters
******************************************************************************
* C_COMMON_CLOCK : Common Clock (1), Independent Clocks (0)
* C_COUNT_TYPE : *not used
* C_DATA_COUNT_WIDTH : Width of DATA_COUNT bus
* C_DEFAULT_VALUE : *not used
* C_DIN_WIDTH : Width of DIN bus
* C_DOUT_RST_VAL : Reset value of DOUT
* C_DOUT_WIDTH : Width of DOUT bus
* C_ENABLE_RLOCS : *not used
* C_FAMILY : not used in bhv model
* C_FULL_FLAGS_RST_VAL : Full flags rst val (0 or 1)
* C_HAS_ALMOST_EMPTY : 1=Core has ALMOST_EMPTY flag
* C_HAS_ALMOST_FULL : 1=Core has ALMOST_FULL flag
* C_HAS_BACKUP : *not used
* C_HAS_DATA_COUNT : 1=Core has DATA_COUNT bus
* C_HAS_INT_CLK : not used in bhv model
* C_HAS_MEMINIT_FILE : *not used
* C_HAS_OVERFLOW : 1=Core has OVERFLOW flag
* C_HAS_RD_DATA_COUNT : 1=Core has RD_DATA_COUNT bus
* C_HAS_RD_RST : *not used
* C_HAS_RST : 1=Core has Async Rst
* C_HAS_SRST : 1=Core has Sync Rst
* C_HAS_UNDERFLOW : 1=Core has UNDERFLOW flag
* C_HAS_VALID : 1=Core has VALID flag
* C_HAS_WR_ACK : 1=Core has WR_ACK flag
* C_HAS_WR_DATA_COUNT : 1=Core has WR_DATA_COUNT bus
* C_HAS_WR_RST : *not used
* C_IMPLEMENTATION_TYPE : 0=Common-Clock Bram/Dram
* 1=Common-Clock ShiftRam
* 2=Indep. Clocks Bram/Dram
* 3=Virtex-4 Built-in
* 4=Virtex-5 Built-in
* C_INIT_WR_PNTR_VAL : *not used
* C_MEMORY_TYPE : 1=Block RAM
* 2=Distributed RAM
* 3=Shift RAM
* 4=Built-in FIFO
* C_MIF_FILE_NAME : *not used
* C_OPTIMIZATION_MODE : *not used
* C_OVERFLOW_LOW : 1=OVERFLOW active low
* C_PRELOAD_LATENCY : Latency of read: 0, 1, 2
* C_PRELOAD_REGS : 1=Use output registers
* C_PRIM_FIFO_TYPE : not used in bhv model
* C_PROG_EMPTY_THRESH_ASSERT_VAL: PROG_EMPTY assert threshold
* C_PROG_EMPTY_THRESH_NEGATE_VAL: PROG_EMPTY negate threshold
* C_PROG_EMPTY_TYPE : 0=No programmable empty
* 1=Single prog empty thresh constant
* 2=Multiple prog empty thresh constants
* 3=Single prog empty thresh input
* 4=Multiple prog empty thresh inputs
* C_PROG_FULL_THRESH_ASSERT_VAL : PROG_FULL assert threshold
* C_PROG_FULL_THRESH_NEGATE_VAL : PROG_FULL negate threshold
* C_PROG_FULL_TYPE : 0=No prog full
* 1=Single prog full thresh constant
* 2=Multiple prog full thresh constants
* 3=Single prog full thresh input
* 4=Multiple prog full thresh inputs
* C_RD_DATA_COUNT_WIDTH : Width of RD_DATA_COUNT bus
* C_RD_DEPTH : Depth of read interface (2^N)
* C_RD_FREQ : not used in bhv model
* C_RD_PNTR_WIDTH : always log2(C_RD_DEPTH)
* C_UNDERFLOW_LOW : 1=UNDERFLOW active low
* C_USE_DOUT_RST : 1=Resets DOUT on RST
* C_USE_ECC : Used for error injection purpose
* C_USE_EMBEDDED_REG : 1=Use BRAM embedded output register
* C_USE_FIFO16_FLAGS : not used in bhv model
* C_USE_FWFT_DATA_COUNT : 1=Use extra logic for FWFT data count
* C_VALID_LOW : 1=VALID active low
* C_WR_ACK_LOW : 1=WR_ACK active low
* C_WR_DATA_COUNT_WIDTH : Width of WR_DATA_COUNT bus
* C_WR_DEPTH : Depth of write interface (2^N)
* C_WR_FREQ : not used in bhv model
* C_WR_PNTR_WIDTH : always log2(C_WR_DEPTH)
* C_WR_RESPONSE_LATENCY : *not used
* C_MSGON_VAL : *not used by bhv model
* C_ENABLE_RST_SYNC : 0 = Use WR_RST & RD_RST
* 1 = Use RST
* C_ERROR_INJECTION_TYPE : 0 = No error injection
* 1 = Single bit error injection only
* 2 = Double bit error injection only
* 3 = Single and double bit error injection
******************************************************************************
* Definition of Ports
******************************************************************************
* BACKUP : Not used
* BACKUP_MARKER: Not used
* CLK : Clock
* DIN : Input data bus
* PROG_EMPTY_THRESH : Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_ASSERT: Threshold for Programmable Empty Flag
* PROG_EMPTY_THRESH_NEGATE: Threshold for Programmable Empty Flag
* PROG_FULL_THRESH : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_ASSERT : Threshold for Programmable Full Flag
* PROG_FULL_THRESH_NEGATE : Threshold for Programmable Full Flag
* RD_CLK : Read Domain Clock
* RD_EN : Read enable
* RD_RST : Read Reset
* RST : Asynchronous Reset
* SRST : Synchronous Reset
* WR_CLK : Write Domain Clock
* WR_EN : Write enable
* WR_RST : Write Reset
* INT_CLK : Internal Clock
* INJECTSBITERR: Inject Signle bit error
* INJECTDBITERR: Inject Double bit error
* ALMOST_EMPTY : One word remaining in FIFO
* ALMOST_FULL : One empty space remaining in FIFO
* DATA_COUNT : Number of data words in fifo( synchronous to CLK)
* DOUT : Output data bus
* EMPTY : Empty flag
* FULL : Full flag
* OVERFLOW : Last write rejected
* PROG_EMPTY : Programmable Empty Flag
* PROG_FULL : Programmable Full Flag
* RD_DATA_COUNT: Number of data words in fifo (synchronous to RD_CLK)
* UNDERFLOW : Last read rejected
* VALID : Last read acknowledged, DOUT bus VALID
* WR_ACK : Last write acknowledged
* WR_DATA_COUNT: Number of data words in fifo (synchronous to WR_CLK)
* SBITERR : Single Bit ECC Error Detected
* DBITERR : Double Bit ECC Error Detected
******************************************************************************
*/
//----------------------------------------------------------------------------
//- Internal Signals for delayed input signals
//- All the input signals except Clock are delayed by 100 ps and then given to
//- the models.
//----------------------------------------------------------------------------
reg rst_delayed ;
reg empty_fb ;
reg srst_delayed ;
reg wr_rst_delayed ;
reg rd_rst_delayed ;
reg wr_en_delayed ;
reg rd_en_delayed ;
reg [C_DIN_WIDTH-1:0] din_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_assert_delayed ;
reg [C_RD_PNTR_WIDTH-1:0] prog_empty_thresh_negate_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_assert_delayed ;
reg [C_WR_PNTR_WIDTH-1:0] prog_full_thresh_negate_delayed ;
reg injectdbiterr_delayed ;
reg injectsbiterr_delayed ;
wire empty_p0_out;
always @* rst_delayed <= #`TCQ RST ;
always @* empty_fb <= #`TCQ empty_p0_out ;
always @* srst_delayed <= #`TCQ SRST ;
always @* wr_rst_delayed <= #`TCQ WR_RST ;
always @* rd_rst_delayed <= #`TCQ RD_RST ;
always @* din_delayed <= #`TCQ DIN ;
always @* wr_en_delayed <= #`TCQ WR_EN ;
always @* rd_en_delayed <= #`TCQ RD_EN ;
always @* prog_empty_thresh_delayed <= #`TCQ PROG_EMPTY_THRESH ;
always @* prog_empty_thresh_assert_delayed <= #`TCQ PROG_EMPTY_THRESH_ASSERT ;
always @* prog_empty_thresh_negate_delayed <= #`TCQ PROG_EMPTY_THRESH_NEGATE ;
always @* prog_full_thresh_delayed <= #`TCQ PROG_FULL_THRESH ;
always @* prog_full_thresh_assert_delayed <= #`TCQ PROG_FULL_THRESH_ASSERT ;
always @* prog_full_thresh_negate_delayed <= #`TCQ PROG_FULL_THRESH_NEGATE ;
always @* injectdbiterr_delayed <= #`TCQ INJECTDBITERR ;
always @* injectsbiterr_delayed <= #`TCQ INJECTSBITERR ;
/*****************************************************************************
* Derived parameters
****************************************************************************/
//There are 2 Verilog behavioral models
// 0 = Common-Clock FIFO/ShiftRam FIFO
// 1 = Independent Clocks FIFO
// 2 = Low Latency Synchronous FIFO
// 3 = Low Latency Asynchronous FIFO
localparam C_VERILOG_IMPL = (C_FIFO_TYPE == 3) ? 2 :
(C_IMPLEMENTATION_TYPE == 2) ? 1 : 0;
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//Internal reset signals
reg rd_rst_asreg = 0;
wire rd_rst_asreg_d1;
wire rd_rst_asreg_d2;
reg rd_rst_asreg_d3 = 0;
reg rd_rst_reg = 0;
wire rd_rst_comb;
reg wr_rst_d0 = 0;
reg wr_rst_d1 = 0;
reg wr_rst_d2 = 0;
reg rd_rst_d0 = 0;
reg rd_rst_d1 = 0;
reg rd_rst_d2 = 0;
reg rd_rst_d3 = 0;
reg wrrst_done = 0;
reg rdrst_done = 0;
reg wr_rst_asreg = 0;
wire wr_rst_asreg_d1;
wire wr_rst_asreg_d2;
reg wr_rst_asreg_d3 = 0;
reg rd_rst_wr_d0 = 0;
reg rd_rst_wr_d1 = 0;
reg rd_rst_wr_d2 = 0;
reg wr_rst_reg = 0;
reg rst_active_i = 1'b1;
reg rst_delayed_d1 = 1'b1;
reg rst_delayed_d2 = 1'b1;
wire wr_rst_comb;
wire wr_rst_i;
wire rd_rst_i;
wire rst_i;
//Internal reset signals
reg rst_asreg = 0;
reg srst_asreg = 0;
wire rst_asreg_d1;
wire rst_asreg_d2;
reg srst_asreg_d1 = 0;
reg srst_asreg_d2 = 0;
reg rst_reg = 0;
reg srst_reg = 0;
wire rst_comb;
wire srst_comb;
reg rst_full_gen_i = 0;
reg rst_full_ff_i = 0;
reg [2:0] sckt_ff0_bsy_o_i = {3{1'b0}};
wire RD_CLK_P0_IN;
wire RST_P0_IN;
wire RD_EN_FIFO_IN;
wire RD_EN_P0_IN;
wire ALMOST_EMPTY_FIFO_OUT;
wire ALMOST_FULL_FIFO_OUT;
wire [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT_FIFO_OUT;
wire [C_DOUT_WIDTH-1:0] DOUT_FIFO_OUT;
wire EMPTY_FIFO_OUT;
wire fifo_empty_fb;
wire FULL_FIFO_OUT;
wire OVERFLOW_FIFO_OUT;
wire PROG_EMPTY_FIFO_OUT;
wire PROG_FULL_FIFO_OUT;
wire VALID_FIFO_OUT;
wire [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT_FIFO_OUT;
wire UNDERFLOW_FIFO_OUT;
wire WR_ACK_FIFO_OUT;
wire [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT_FIFO_OUT;
//***************************************************************************
// Internal Signals
// The core uses either the internal_ wires or the preload0_ wires depending
// on whether the core uses Preload0 or not.
// When using preload0, the internal signals connect the internal core to
// the preload logic, and the external core's interfaces are tied to the
// preload0 signals from the preload logic.
//***************************************************************************
wire [C_DOUT_WIDTH-1:0] DATA_P0_OUT;
wire VALID_P0_OUT;
wire EMPTY_P0_OUT;
wire ALMOSTEMPTY_P0_OUT;
reg EMPTY_P0_OUT_Q;
reg ALMOSTEMPTY_P0_OUT_Q;
wire UNDERFLOW_P0_OUT;
wire RDEN_P0_OUT;
wire [C_DOUT_WIDTH-1:0] DATA_P0_IN;
wire EMPTY_P0_IN;
reg [31:0] DATA_COUNT_FWFT;
reg SS_FWFT_WR ;
reg SS_FWFT_RD ;
wire sbiterr_fifo_out;
wire dbiterr_fifo_out;
wire inject_sbit_err;
wire inject_dbit_err;
wire safety_ckt_wr_rst;
wire safety_ckt_rd_rst;
reg sckt_wr_rst_i_q = 1'b0;
wire w_fab_read_data_valid_i;
wire w_read_data_valid_i;
wire w_ram_valid_i;
// Assign 0 if not selected to avoid 'X' propogation to S/DBITERR.
assign inject_sbit_err = ((C_ERROR_INJECTION_TYPE == 1) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectsbiterr_delayed : 0;
assign inject_dbit_err = ((C_ERROR_INJECTION_TYPE == 2) || (C_ERROR_INJECTION_TYPE == 3)) ?
injectdbiterr_delayed : 0;
assign wr_rst_i_out = wr_rst_i;
assign rd_rst_i_out = rd_rst_i;
assign wr_rst_busy_o = wr_rst_busy | rst_full_gen_i | sckt_ff0_bsy_o_i[2];
generate if (C_FULL_FLAGS_RST_VAL == 0 && C_EN_SAFETY_CKT == 1) begin : gsckt_bsy_o
wire clk_i = C_COMMON_CLOCK ? CLK : WR_CLK;
always @ (posedge clk_i)
sckt_ff0_bsy_o_i <= {sckt_ff0_bsy_o_i[1:0],wr_rst_busy};
end endgenerate
// Choose the behavioral model to instantiate based on the C_VERILOG_IMPL
// parameter (1=Independent Clocks, 0=Common Clock)
localparam FULL_FLAGS_RST_VAL = (C_HAS_SRST == 1) ? 0 : C_FULL_FLAGS_RST_VAL;
generate
case (C_VERILOG_IMPL)
0 : begin : block1
//Common Clock Behavioral Model
fifo_generator_v13_1_3_bhv_ver_ss
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL ((C_AXI_TYPE == 0 && C_FIFO_TYPE == 1) ? 1 : C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ss
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.CLK (CLK),
.RST (rst_i),
.SRST (srst_delayed),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.USER_EMPTY_FB (empty_fb),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.DATA_COUNT (DATA_COUNT_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
1 : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.fab_read_data_valid_i (w_fab_read_data_valid_i),
.read_data_valid_i (w_read_data_valid_i),
.ram_valid_i (w_ram_valid_i),
.DBITERR (dbiterr_fifo_out)
);
end
2 : begin : ll_afifo_inst
fifo_generator_v13_1_3_beh_ver_ll_afifo
#(
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
gen_ll_afifo
(
.DIN (din_delayed),
.RD_CLK (RD_CLK),
.RD_EN (rd_en_delayed),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.WR_CLK (WR_CLK),
.WR_EN (wr_en_delayed),
.DOUT (DOUT),
.EMPTY (EMPTY),
.FULL (FULL)
);
end
default : begin : block1
//Independent Clocks Behavioral Model
fifo_generator_v13_1_3_bhv_ver_as
#(
.C_FAMILY (C_FAMILY),
.C_DATA_COUNT_WIDTH (C_DATA_COUNT_WIDTH),
.C_DIN_WIDTH (C_DIN_WIDTH),
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_FULL_FLAGS_RST_VAL (C_FULL_FLAGS_RST_VAL),
.C_HAS_ALMOST_EMPTY (C_HAS_ALMOST_EMPTY),
.C_HAS_ALMOST_FULL (C_HAS_ALMOST_FULL),
.C_HAS_DATA_COUNT (C_HAS_DATA_COUNT),
.C_HAS_OVERFLOW (C_HAS_OVERFLOW),
.C_HAS_RD_DATA_COUNT (C_HAS_RD_DATA_COUNT),
.C_HAS_RST (C_HAS_RST),
.C_HAS_UNDERFLOW (C_HAS_UNDERFLOW),
.C_HAS_VALID (C_HAS_VALID),
.C_HAS_WR_ACK (C_HAS_WR_ACK),
.C_HAS_WR_DATA_COUNT (C_HAS_WR_DATA_COUNT),
.C_IMPLEMENTATION_TYPE (C_IMPLEMENTATION_TYPE),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_OVERFLOW_LOW (C_OVERFLOW_LOW),
.C_PRELOAD_LATENCY (C_PRELOAD_LATENCY),
.C_PRELOAD_REGS (C_PRELOAD_REGS),
.C_PROG_EMPTY_THRESH_ASSERT_VAL (C_PROG_EMPTY_THRESH_ASSERT_VAL),
.C_PROG_EMPTY_THRESH_NEGATE_VAL (C_PROG_EMPTY_THRESH_NEGATE_VAL),
.C_PROG_EMPTY_TYPE (C_PROG_EMPTY_TYPE),
.C_PROG_FULL_THRESH_ASSERT_VAL (C_PROG_FULL_THRESH_ASSERT_VAL),
.C_PROG_FULL_THRESH_NEGATE_VAL (C_PROG_FULL_THRESH_NEGATE_VAL),
.C_PROG_FULL_TYPE (C_PROG_FULL_TYPE),
.C_RD_DATA_COUNT_WIDTH (C_RD_DATA_COUNT_WIDTH),
.C_RD_DEPTH (C_RD_DEPTH),
.C_RD_PNTR_WIDTH (C_RD_PNTR_WIDTH),
.C_UNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USE_FWFT_DATA_COUNT (C_USE_FWFT_DATA_COUNT),
.C_VALID_LOW (C_VALID_LOW),
.C_WR_ACK_LOW (C_WR_ACK_LOW),
.C_WR_DATA_COUNT_WIDTH (C_WR_DATA_COUNT_WIDTH),
.C_WR_DEPTH (C_WR_DEPTH),
.C_WR_PNTR_WIDTH (C_WR_PNTR_WIDTH),
.C_USE_ECC (C_USE_ECC),
.C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_ERROR_INJECTION_TYPE (C_ERROR_INJECTION_TYPE)
)
gen_as
(
.SAFETY_CKT_WR_RST (safety_ckt_wr_rst),
.SAFETY_CKT_RD_RST (safety_ckt_rd_rst),
.WR_CLK (WR_CLK),
.RD_CLK (RD_CLK),
.RST (rst_i),
.RST_FULL_GEN (rst_full_gen_i),
.RST_FULL_FF (rst_full_ff_i),
.WR_RST (wr_rst_i),
.RD_RST (rd_rst_i),
.DIN (din_delayed),
.WR_EN (wr_en_delayed),
.RD_EN (RD_EN_FIFO_IN),
.RD_EN_USER (rd_en_delayed),
.PROG_EMPTY_THRESH (prog_empty_thresh_delayed),
.PROG_EMPTY_THRESH_ASSERT (prog_empty_thresh_assert_delayed),
.PROG_EMPTY_THRESH_NEGATE (prog_empty_thresh_negate_delayed),
.PROG_FULL_THRESH (prog_full_thresh_delayed),
.PROG_FULL_THRESH_ASSERT (prog_full_thresh_assert_delayed),
.PROG_FULL_THRESH_NEGATE (prog_full_thresh_negate_delayed),
.INJECTSBITERR (inject_sbit_err),
.INJECTDBITERR (inject_dbit_err),
.USER_EMPTY_FB (EMPTY_P0_OUT),
.DOUT (DOUT_FIFO_OUT),
.FULL (FULL_FIFO_OUT),
.ALMOST_FULL (ALMOST_FULL_FIFO_OUT),
.WR_ACK (WR_ACK_FIFO_OUT),
.OVERFLOW (OVERFLOW_FIFO_OUT),
.EMPTY (EMPTY_FIFO_OUT),
.EMPTY_FB (fifo_empty_fb),
.ALMOST_EMPTY (ALMOST_EMPTY_FIFO_OUT),
.VALID (VALID_FIFO_OUT),
.UNDERFLOW (UNDERFLOW_FIFO_OUT),
.RD_DATA_COUNT (RD_DATA_COUNT_FIFO_OUT),
.WR_DATA_COUNT (WR_DATA_COUNT_FIFO_OUT),
.PROG_FULL (PROG_FULL_FIFO_OUT),
.PROG_EMPTY (PROG_EMPTY_FIFO_OUT),
.SBITERR (sbiterr_fifo_out),
.DBITERR (dbiterr_fifo_out)
);
end
endcase
endgenerate
//**************************************************************************
// Connect Internal Signals
// (Signals labeled internal_*)
// In the normal case, these signals tie directly to the FIFO's inputs and
// outputs.
// In the case of Preload Latency 0 or 1, there are intermediate
// signals between the internal FIFO and the preload logic.
//**************************************************************************
//***********************************************
// If First-Word Fall-Through, instantiate
// the preload0 (FWFT) module
//***********************************************
wire rd_en_to_fwft_fifo;
wire sbiterr_fwft;
wire dbiterr_fwft;
wire [C_DOUT_WIDTH-1:0] dout_fwft;
wire empty_fwft;
wire rd_en_fifo_in;
wire stage2_reg_en_i;
wire [1:0] valid_stages_i;
wire rst_fwft;
//wire empty_p0_out;
reg [C_SYNCHRONIZER_STAGE-1:0] pkt_empty_sync = 'b1;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
localparam IS_PKT_FIFO = (C_FIFO_TYPE == 1) ? 1 : 0;
localparam IS_AXIS_PKT_FIFO = (C_FIFO_TYPE == 1 && C_AXI_TYPE == 0) ? 1 : 0;
assign rst_fwft = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 1'b0;
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 3) begin : block2
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_EMBEDDED_REG (C_USE_EMBEDDED_REG),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (C_FIFO_TYPE)
)
fgpl0
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (RST_P0_IN),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (RD_EN_P0_IN),
.FIFOEMPTY (EMPTY_P0_IN),
.FIFODATA (DATA_P0_IN),
.FIFOSBITERR (sbiterr_fifo_out),
.FIFODBITERR (dbiterr_fifo_out),
// Output
.USERDATA (dout_fwft),
.USERVALID (VALID_P0_OUT),
.USEREMPTY (empty_fwft),
.USERALMOSTEMPTY (ALMOSTEMPTY_P0_OUT),
.USERUNDERFLOW (UNDERFLOW_P0_OUT),
.RAMVALID (),
.FIFORDEN (rd_en_fifo_in),
.USERSBITERR (sbiterr_fwft),
.USERDBITERR (dbiterr_fwft),
.STAGE2_REG_EN (stage2_reg_en_i),
.fab_read_data_valid_i_o (w_fab_read_data_valid_i),
.read_data_valid_i_o (w_read_data_valid_i),
.ram_valid_i_o (w_ram_valid_i),
.VALID_STAGES (valid_stages_i)
);
//***********************************************
// Connect inputs to preload (FWFT) module
//***********************************************
//Connect the RD_CLK of the Preload (FWFT) module to CLK if we
// have a common-clock FIFO, or RD_CLK if we have an
// independent clock FIFO
assign RD_CLK_P0_IN = ((C_VERILOG_IMPL == 0) ? CLK : RD_CLK);
assign RST_P0_IN = (C_COMMON_CLOCK == 0) ? rd_rst_i : (C_HAS_RST == 1) ? rst_i : 0;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
assign EMPTY_P0_IN = C_EN_SAFETY_CKT ? fifo_empty_fb : EMPTY_FIFO_OUT;
assign DATA_P0_IN = DOUT_FIFO_OUT;
//***********************************************
// Connect outputs from preload (FWFT) module
//***********************************************
assign VALID = VALID_P0_OUT ;
assign ALMOST_EMPTY = ALMOSTEMPTY_P0_OUT;
assign UNDERFLOW = UNDERFLOW_P0_OUT ;
assign RD_EN_FIFO_IN = rd_en_fifo_in;
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
assign DATA_COUNT = (C_USE_FWFT_DATA_COUNT == 0)? DATA_COUNT_FIFO_OUT:
(C_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) ? DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:0] :
DATA_COUNT_FWFT[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH+1];
//***********************************************
// Create DATA_COUNT from First-Word Fall-Through
// data count
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
EMPTY_P0_OUT_Q <= 1;
ALMOSTEMPTY_P0_OUT_Q <= 1;
end else begin
EMPTY_P0_OUT_Q <= #`TCQ empty_p0_out;
// EMPTY_P0_OUT_Q <= #`TCQ EMPTY_FIFO_OUT;
ALMOSTEMPTY_P0_OUT_Q <= #`TCQ ALMOSTEMPTY_P0_OUT;
end
end //always
//***********************************************
// logic for common-clock data count when FWFT is selected
//***********************************************
initial begin
SS_FWFT_RD = 1'b0;
DATA_COUNT_FWFT = 0 ;
SS_FWFT_WR = 1'b0 ;
end //initial
//***********************************************
// common-clock data count is implemented as an
// up-down counter. SS_FWFT_WR and SS_FWFT_RD
// are the up/down enables for the counter.
//***********************************************
always @ (RD_EN or VALID_P0_OUT or WR_EN or FULL_FIFO_OUT or empty_p0_out) begin
if (C_VALID_LOW == 1) begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && ~VALID_P0_OUT) : (~empty_p0_out && RD_EN && ~VALID_P0_OUT) ;
end else begin
SS_FWFT_RD = (C_FIFO_TYPE != 1) ? (RD_EN && VALID_P0_OUT) : (~empty_p0_out && RD_EN && VALID_P0_OUT) ;
end
SS_FWFT_WR = (WR_EN && (~FULL_FIFO_OUT)) ;
end
//***********************************************
// common-clock data count is implemented as an
// up-down counter for FWFT. This always block
// calculates the counter.
//***********************************************
always @ (posedge RD_CLK_P0_IN or posedge RST_P0_IN) begin
if (RST_P0_IN) begin
DATA_COUNT_FWFT <= 0;
end else begin
//if (srst_delayed && (C_HAS_SRST == 1) ) begin
if ((srst_delayed | wr_rst_busy | rd_rst_busy) && (C_HAS_SRST == 1) ) begin
DATA_COUNT_FWFT <= #`TCQ 0;
end else begin
case ( {SS_FWFT_WR, SS_FWFT_RD})
2'b00: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
2'b01: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT - 1 ;
2'b10: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT + 1 ;
2'b11: DATA_COUNT_FWFT <= #`TCQ DATA_COUNT_FWFT ;
endcase
end //if SRST
end //IF RST
end //always
end endgenerate // : block2
// AXI Streaming Packet FIFO
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_plus1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pkt_count_reg = 0;
reg partial_packet = 0;
reg stage1_eop_d1 = 0;
reg rd_en_fifo_in_d1 = 0;
reg eop_at_stage2 = 0;
reg ram_pkt_empty = 0;
reg ram_pkt_empty_d1 = 0;
wire [C_DOUT_WIDTH-1:0] dout_p0_out;
wire packet_empty_wr;
wire wr_rst_fwft_pkt_fifo;
wire dummy_wr_eop;
wire ram_wr_en_pkt_fifo;
wire wr_eop;
wire ram_rd_en_compare;
wire stage1_eop;
wire pkt_ready_to_read;
wire rd_en_2_stage2;
// Generate Dummy WR_EOP for partial packet (Only for AXI Streaming)
// When Packet EMPTY is high, and FIFO is full, then generate the dummy WR_EOP
// When dummy WR_EOP is high, mask the actual EOP to avoid double increment of
// write packet count
generate if (IS_FWFT == 1 && IS_AXIS_PKT_FIFO == 1) begin // gdummy_wr_eop
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
partial_packet <= 1'b0;
else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy)
partial_packet <= #`TCQ 1'b0;
else if (ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]))
partial_packet <= #`TCQ 1'b1;
else if (partial_packet && din_delayed[0] && ram_wr_en_pkt_fifo)
partial_packet <= #`TCQ 1'b0;
end
end
end endgenerate // gdummy_wr_eop
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1) begin // gpkt_fifo_fwft
assign wr_rst_fwft_pkt_fifo = (C_COMMON_CLOCK == 0) ? wr_rst_i : (C_HAS_RST == 1) ? rst_i:1'b0;
assign dummy_wr_eop = ALMOST_FULL_FIFO_OUT && ram_wr_en_pkt_fifo && packet_empty_wr && (~din_delayed[0]) && (~partial_packet);
assign packet_empty_wr = (C_COMMON_CLOCK == 1) ? empty_p0_out : pkt_empty_sync[C_SYNCHRONIZER_STAGE-1];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
stage1_eop_d1 <= 1'b0;
rd_en_fifo_in_d1 <= 1'b0;
end else begin
if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
stage1_eop_d1 <= #`TCQ 1'b0;
rd_en_fifo_in_d1 <= #`TCQ 1'b0;
end else begin
stage1_eop_d1 <= #`TCQ stage1_eop;
rd_en_fifo_in_d1 <= #`TCQ rd_en_fifo_in;
end
end
end
assign stage1_eop = (rd_en_fifo_in_d1) ? DOUT_FIFO_OUT[0] : stage1_eop_d1;
assign ram_wr_en_pkt_fifo = wr_en_delayed && (~FULL_FIFO_OUT);
assign wr_eop = ram_wr_en_pkt_fifo && ((din_delayed[0] && (~partial_packet)) || dummy_wr_eop);
assign ram_rd_en_compare = stage2_reg_en_i && stage1_eop;
fifo_generator_v13_1_3_bhv_ver_preload0
#(
.C_DOUT_RST_VAL (C_DOUT_RST_VAL),
.C_DOUT_WIDTH (C_DOUT_WIDTH),
.C_HAS_RST (C_HAS_RST),
.C_HAS_SRST (C_HAS_SRST),
.C_USE_DOUT_RST (C_USE_DOUT_RST),
.C_USE_ECC (C_USE_ECC),
.C_USERVALID_LOW (C_VALID_LOW),
.C_EN_SAFETY_CKT (C_EN_SAFETY_CKT),
.C_USERUNDERFLOW_LOW (C_UNDERFLOW_LOW),
.C_ENABLE_RST_SYNC (C_ENABLE_RST_SYNC),
.C_MEMORY_TYPE (C_MEMORY_TYPE),
.C_FIFO_TYPE (2) // Enable low latency fwft logic
)
pkt_fifo_fwft
(
.SAFETY_CKT_RD_RST(safety_ckt_rd_rst),
.RD_CLK (RD_CLK_P0_IN),
.RD_RST (rst_fwft),
.SRST (srst_delayed),
.WR_RST_BUSY (wr_rst_busy),
.RD_RST_BUSY (rd_rst_busy),
.RD_EN (rd_en_delayed),
.FIFOEMPTY (pkt_ready_to_read),
.FIFODATA (dout_fwft),
.FIFOSBITERR (sbiterr_fwft),
.FIFODBITERR (dbiterr_fwft),
// Output
.USERDATA (dout_p0_out),
.USERVALID (),
.USEREMPTY (empty_p0_out),
.USERALMOSTEMPTY (),
.USERUNDERFLOW (),
.RAMVALID (),
.FIFORDEN (rd_en_2_stage2),
.USERSBITERR (SBITERR),
.USERDBITERR (DBITERR),
.STAGE2_REG_EN (),
.VALID_STAGES ()
);
assign pkt_ready_to_read = ~(!(ram_pkt_empty || empty_fwft) && ((valid_stages_i[0] && valid_stages_i[1]) || eop_at_stage2));
assign rd_en_to_fwft_fifo = ~empty_fwft && rd_en_2_stage2;
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
eop_at_stage2 <= 1'b0;
else if (stage2_reg_en_i)
eop_at_stage2 <= #`TCQ stage1_eop;
end
//---------------------------------------------------------------------------
// Write and Read Packet Count
//---------------------------------------------------------------------------
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count <= 0;
else if (srst_delayed | wr_rst_busy | rd_rst_busy)
wr_pkt_count <= #`TCQ 0;
else if (wr_eop)
wr_pkt_count <= #`TCQ wr_pkt_count + 1;
end
end endgenerate // gpkt_fifo_fwft
assign DOUT = (C_FIFO_TYPE != 1) ? dout_fwft : dout_p0_out;
assign EMPTY = (C_FIFO_TYPE != 1) ? empty_fwft : empty_p0_out;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 1) begin // grss_pkt_cnt
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
rd_pkt_count <= 0;
rd_pkt_count_plus1 <= 1;
end else if (srst_delayed | wr_rst_busy | rd_rst_busy) begin
rd_pkt_count <= #`TCQ 0;
rd_pkt_count_plus1 <= #`TCQ 1;
end else if (stage2_reg_en_i && stage1_eop) begin
rd_pkt_count <= #`TCQ rd_pkt_count + 1;
rd_pkt_count_plus1 <= #`TCQ rd_pkt_count_plus1 + 1;
end
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (SRST | wr_rst_busy | rd_rst_busy) begin
ram_pkt_empty <= #`TCQ 1'b1;
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count) && wr_eop) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count_plus1 == wr_pkt_count) && ~wr_eop && ~ALMOST_FULL_FIFO_OUT && ram_rd_en_compare) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
end endgenerate //grss_pkt_cnt
localparam SYNC_STAGE_WIDTH = (C_SYNCHRONIZER_STAGE+1)*C_WR_PNTR_WIDTH;
reg [SYNC_STAGE_WIDTH-1:0] wr_pkt_count_q = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_b2g = 0;
wire [C_WR_PNTR_WIDTH-1:0] wr_pkt_count_rd;
generate if (IS_FWFT == 1 && IS_PKT_FIFO == 1 && C_COMMON_CLOCK == 0) begin // gras_pkt_cnt
// Delay the write packet count in write clock domain to accomodate the binary to gray conversion delay
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
wr_pkt_count_b2g <= 0;
else
wr_pkt_count_b2g <= #`TCQ wr_pkt_count;
end
// Synchronize the delayed write packet count in read domain, and also compensate the gray to binay conversion delay
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
wr_pkt_count_q <= 0;
else
wr_pkt_count_q <= #`TCQ {wr_pkt_count_q[SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH-1:0],wr_pkt_count_b2g};
end
always @* begin
if (stage1_eop)
rd_pkt_count <= rd_pkt_count_reg + 1;
else
rd_pkt_count <= rd_pkt_count_reg;
end
assign wr_pkt_count_rd = wr_pkt_count_q[SYNC_STAGE_WIDTH-1:SYNC_STAGE_WIDTH-C_WR_PNTR_WIDTH];
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft)
rd_pkt_count_reg <= 0;
else if (rd_en_fifo_in)
rd_pkt_count_reg <= #`TCQ rd_pkt_count;
end
always @ (posedge rst_fwft or posedge RD_CLK_P0_IN) begin
if (rst_fwft) begin
ram_pkt_empty <= 1'b1;
ram_pkt_empty_d1 <= 1'b1;
end else if (rd_pkt_count != wr_pkt_count_rd) begin
ram_pkt_empty <= #`TCQ 1'b0;
ram_pkt_empty_d1 <= #`TCQ 1'b0;
end else if (ram_pkt_empty_d1 && rd_en_to_fwft_fifo) begin
ram_pkt_empty <= #`TCQ 1'b1;
end else if ((rd_pkt_count == wr_pkt_count_rd) && stage2_reg_en_i) begin
ram_pkt_empty_d1 <= #`TCQ 1'b1;
end
end
// Synchronize the empty in write domain
always @ (posedge wr_rst_fwft_pkt_fifo or posedge WR_CLK) begin
if (wr_rst_fwft_pkt_fifo)
pkt_empty_sync <= 'b1;
else
pkt_empty_sync <= #`TCQ {pkt_empty_sync[C_SYNCHRONIZER_STAGE-2:0], empty_p0_out};
end
end endgenerate //gras_pkt_cnt
generate if (IS_FWFT == 0 || C_FIFO_TYPE == 3) begin : STD_FIFO
//***********************************************
// If NOT First-Word Fall-Through, wire the outputs
// of the internal _ss or _as FIFO directly to the
// output, and do not instantiate the preload0
// module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VALID = VALID_FIFO_OUT;
assign EMPTY = EMPTY_FIFO_OUT;
assign ALMOST_EMPTY = ALMOST_EMPTY_FIFO_OUT;
assign EMPTY_P0_IN = 0;
assign UNDERFLOW = UNDERFLOW_FIFO_OUT;
assign DATA_COUNT = DATA_COUNT_FIFO_OUT;
assign SBITERR = sbiterr_fifo_out;
assign DBITERR = dbiterr_fifo_out;
end endgenerate // STD_FIFO
generate if (IS_FWFT == 1 && C_FIFO_TYPE != 1) begin : NO_PKT_FIFO
assign empty_p0_out = empty_fwft;
assign SBITERR = sbiterr_fwft;
assign DBITERR = dbiterr_fwft;
assign DOUT = dout_fwft;
assign RD_EN_P0_IN = (C_FIFO_TYPE != 1) ? rd_en_delayed : rd_en_to_fwft_fifo;
end endgenerate // NO_PKT_FIFO
//***********************************************
// Connect user flags to internal signals
//***********************************************
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//RD_DATA_COUNT is 0 when EMPTY and 1 when ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block3
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : RD_DATA_COUNT_FIFO_OUT);
end //block_ic
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG < 3) ) begin : block30
if (C_COMMON_CLOCK == 0) begin : block_ic
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : RD_DATA_COUNT_FIFO_OUT);
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30
endgenerate
//If we are using extra logic for the FWFT data count, then override the
//RD_DATA_COUNT output when we are EMPTY or ALMOST_EMPTY.
//Due to asymmetric ports, RD_DATA_COUNT is 0 when EMPTY or ALMOST_EMPTY.
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH <=C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block30_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 0 : (RD_DATA_COUNT_FIFO_OUT));
end
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block30_both
endgenerate
generate
if (C_USE_FWFT_DATA_COUNT==1 && (C_RD_DATA_COUNT_WIDTH>C_RD_PNTR_WIDTH) && (C_USE_EMBEDDED_REG == 3) ) begin : block3_both
if (C_COMMON_CLOCK == 0) begin : block_ic_both
assign RD_DATA_COUNT = (EMPTY_P0_OUT_Q | RST_P0_IN) ? 0 : (ALMOSTEMPTY_P0_OUT_Q ? 1 : (RD_DATA_COUNT_FIFO_OUT));
end //block_ic_both
else begin
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
end //block3_both
endgenerate
//If we are not using extra logic for the FWFT data count,
//then connect RD_DATA_COUNT to the RD_DATA_COUNT from the
//internal FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==0 ) begin : block31
assign RD_DATA_COUNT = RD_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Always connect WR_DATA_COUNT to the WR_DATA_COUNT from the internal
//FIFO instance
generate
if (C_USE_FWFT_DATA_COUNT==1) begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
else begin : block4
assign WR_DATA_COUNT = WR_DATA_COUNT_FIFO_OUT;
end
endgenerate
//Connect other flags to the internal FIFO instance
assign FULL = FULL_FIFO_OUT;
assign ALMOST_FULL = ALMOST_FULL_FIFO_OUT;
assign WR_ACK = WR_ACK_FIFO_OUT;
assign OVERFLOW = OVERFLOW_FIFO_OUT;
assign PROG_FULL = PROG_FULL_FIFO_OUT;
assign PROG_EMPTY = PROG_EMPTY_FIFO_OUT;
/**************************************************************************
* find_log2
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function integer find_log2;
input integer int_val;
integer i,j;
begin
i = 1;
j = 0;
for (i = 1; i < int_val; i = i*2) begin
j = j + 1;
end
find_log2 = j;
end
endfunction
// if an asynchronous FIFO has been selected, display a message that the FIFO
// will not be cycle-accurate in simulation
initial begin
if (C_IMPLEMENTATION_TYPE == 2) begin
$display("WARNING: Behavioral models for independent clock FIFO configurations do not model synchronization delays. The behavioral models are functionally correct, and will represent the behavior of the configured FIFO. See the FIFO Generator User Guide for more information.");
end else if (C_MEMORY_TYPE == 4) begin
$display("FAILURE : Behavioral models do not support built-in FIFO configurations. Please use post-synthesis or post-implement simulation in Vivado.");
$finish;
end
if (C_WR_PNTR_WIDTH != find_log2(C_WR_DEPTH)) begin
$display("FAILURE : C_WR_PNTR_WIDTH is not log2 of C_WR_DEPTH.");
$finish;
end
if (C_RD_PNTR_WIDTH != find_log2(C_RD_DEPTH)) begin
$display("FAILURE : C_RD_PNTR_WIDTH is not log2 of C_RD_DEPTH.");
$finish;
end
if (C_USE_ECC == 1) begin
if (C_DIN_WIDTH != C_DOUT_WIDTH) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be equal for ECC configuration.");
$finish;
end
if (C_DIN_WIDTH == 1 && C_ERROR_INJECTION_TYPE > 1) begin
$display("FAILURE : C_DIN_WIDTH and C_DOUT_WIDTH must be > 1 for double bit error injection.");
$finish;
end
end
end //initial
/**************************************************************************
* Internal reset logic
**************************************************************************/
assign wr_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? wr_rst_reg : 0;
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? rd_rst_reg : 0;
assign rst_i = C_HAS_RST ? rst_reg : 0;
wire rst_2_sync;
wire rst_2_sync_safety = (C_ENABLE_RST_SYNC == 1) ? rst_delayed : RD_RST;
wire clk_2_sync = (C_COMMON_CLOCK == 1) ? CLK : WR_CLK;
wire clk_2_sync_safety = (C_COMMON_CLOCK == 1) ? CLK : RD_CLK;
localparam RST_SYNC_STAGES = (C_EN_SAFETY_CKT == 0) ? C_SYNCHRONIZER_STAGE :
(C_COMMON_CLOCK == 1) ? 3 : C_SYNCHRONIZER_STAGE+2;
reg [RST_SYNC_STAGES-1:0] wrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_reg = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] arst_sync_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_q = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] rrst_wr = {RST_SYNC_STAGES{1'b0}};
reg [RST_SYNC_STAGES-1:0] wrst_ext = {RST_SYNC_STAGES{1'b0}};
reg [1:0] wrst_cc = {2{1'b0}};
reg [1:0] rrst_cc = {2{1'b0}};
generate
if (C_EN_SAFETY_CKT == 1 && C_INTERFACE_TYPE == 0) begin : grst_safety_ckt
reg[1:0] rst_d1_safety =1;
reg[1:0] rst_d2_safety =1;
reg[1:0] rst_d3_safety =1;
reg[1:0] rst_d4_safety =1;
reg[1:0] rst_d5_safety =1;
reg[1:0] rst_d6_safety =1;
reg[1:0] rst_d7_safety =1;
always@(posedge rst_2_sync_safety or posedge clk_2_sync_safety) begin : prst
if (rst_2_sync_safety == 1'b1) begin
rst_d1_safety <= 1'b1;
rst_d2_safety <= 1'b1;
rst_d3_safety <= 1'b1;
rst_d4_safety <= 1'b1;
rst_d5_safety <= 1'b1;
rst_d6_safety <= 1'b1;
rst_d7_safety <= 1'b1;
end
else begin
rst_d1_safety <= #`TCQ 1'b0;
rst_d2_safety <= #`TCQ rst_d1_safety;
rst_d3_safety <= #`TCQ rst_d2_safety;
rst_d4_safety <= #`TCQ rst_d3_safety;
rst_d5_safety <= #`TCQ rst_d4_safety;
rst_d6_safety <= #`TCQ rst_d5_safety;
rst_d7_safety <= #`TCQ rst_d6_safety;
end //if
end //prst
always@(posedge rst_d7_safety or posedge WR_EN) begin : assert_safety
if(rst_d7_safety == 1 && WR_EN == 1) begin
$display("WARNING:A write attempt has been made within the 7 clock cycles of reset de-assertion. This can lead to data discrepancy when safety circuit is enabled.");
end //if
end //always
end // grst_safety_ckt
endgenerate
// if (C_EN_SAFET_CKT == 1)
// assertion:the reset shud be atleast 3 cycles wide.
generate
reg safety_ckt_wr_rst_i = 1'b0;
if (C_ENABLE_RST_SYNC == 0) begin : gnrst_sync
always @* begin
wr_rst_reg <= wr_rst_delayed;
rd_rst_reg <= rd_rst_delayed;
rst_reg <= 1'b0;
srst_reg <= 1'b0;
end
assign rst_2_sync = wr_rst_delayed;
assign wr_rst_busy = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? wr_rst_delayed : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rd_rst_delayed : 1'b0;
// end : gnrst_sync
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 0) begin : g7s_ic_rst
reg fifo_wrst_done = 1'b0;
reg fifo_rrst_done = 1'b0;
reg sckt_wrst_i = 1'b0;
reg sckt_wrst_i_q = 1'b0;
reg rd_rst_active = 1'b0;
reg rd_rst_middle = 1'b0;
reg sckt_rd_rst_d1 = 1'b0;
reg [1:0] rst_delayed_ic_w = 2'h0;
wire rst_delayed_ic_w_i;
reg [1:0] rst_delayed_ic_r = 2'h0;
wire rst_delayed_ic_r_i;
wire arst_sync_rst;
wire fifo_rst_done;
wire fifo_rst_active;
assign wr_rst_comb = !wr_rst_asreg_d2 && wr_rst_asreg;
assign rd_rst_comb = C_EN_SAFETY_CKT ? (!rd_rst_asreg_d2 && rd_rst_asreg) || rd_rst_active : !rd_rst_asreg_d2 && rd_rst_asreg;
assign rst_2_sync = rst_delayed_ic_w_i;
assign arst_sync_rst = arst_sync_q[RST_SYNC_STAGES-1];
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | fifo_rst_active : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? safety_ckt_rd_rst : 1'b0;
assign fifo_rst_done = fifo_wrst_done & fifo_rrst_done;
assign fifo_rst_active = sckt_wrst_i | wrst_ext[RST_SYNC_STAGES-1] | rrst_wr[RST_SYNC_STAGES-1];
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_w <= 2'b11;
else
rst_delayed_ic_w <= #`TCQ {rst_delayed_ic_w[0],1'b0};
end
assign rst_delayed_ic_w_i = rst_delayed_ic_w[1];
always @(posedge RD_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1 && C_HAS_RST)
rst_delayed_ic_r <= 2'b11;
else
rst_delayed_ic_r <= #`TCQ {rst_delayed_ic_r[0],1'b0};
end
assign rst_delayed_ic_r_i = rst_delayed_ic_r[1];
always @(posedge WR_CLK) begin
sckt_wrst_i_q <= #`TCQ sckt_wrst_i;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ sckt_wrst_i | wr_rst_busy | sckt_wr_rst_i_q;
if (arst_sync_rst && ~fifo_rst_active)
sckt_wrst_i <= #`TCQ 1'b1;
else if (sckt_wrst_i && fifo_rst_done)
sckt_wrst_i <= #`TCQ 1'b0;
else
sckt_wrst_i <= #`TCQ sckt_wrst_i;
if (rrst_wr[RST_SYNC_STAGES-2] & ~rrst_wr[RST_SYNC_STAGES-1])
fifo_rrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_rrst_done <= #`TCQ 1'b0;
else
fifo_rrst_done <= #`TCQ fifo_rrst_done;
if (wrst_ext[RST_SYNC_STAGES-2] & ~wrst_ext[RST_SYNC_STAGES-1])
fifo_wrst_done <= #`TCQ 1'b1;
else if (fifo_rst_done)
fifo_wrst_done <= #`TCQ 1'b0;
else
fifo_wrst_done <= #`TCQ fifo_wrst_done;
end
always @(posedge WR_CLK or posedge rst_delayed_ic_w_i) begin
if (rst_delayed_ic_w_i == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1) begin
wr_rst_asreg <= 1'b1;
end else begin
if (wr_rst_asreg_d1 == 1'b1) begin
wr_rst_asreg <= #`TCQ 1'b0;
end else begin
wr_rst_asreg <= #`TCQ wr_rst_asreg;
end
end
end
always @(posedge WR_CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],wr_rst_asreg};
wrst_ext <= #`TCQ {wrst_ext[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_wr <= #`TCQ {rrst_wr[RST_SYNC_STAGES-2:0],safety_ckt_rd_rst};
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_ic_w_i};
end
assign wr_rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign wr_rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge WR_CLK or posedge wr_rst_comb) begin
if (wr_rst_comb == 1'b1) begin
wr_rst_reg <= 1'b1;
end else begin
wr_rst_reg <= #`TCQ 1'b0;
end
end
always @(posedge RD_CLK or posedge rst_delayed_ic_r_i) begin
if (rst_delayed_ic_r_i == 1'b1) begin
rd_rst_asreg <= 1'b1;
end else begin
if (rd_rst_asreg_d1 == 1'b1) begin
rd_rst_asreg <= #`TCQ 1'b0;
end else begin
rd_rst_asreg <= #`TCQ rd_rst_asreg;
end
end
end
always @(posedge RD_CLK) begin
rrst_reg <= #`TCQ {rrst_reg[RST_SYNC_STAGES-2:0],rd_rst_asreg};
rrst_q <= #`TCQ {rrst_q[RST_SYNC_STAGES-2:0],sckt_wrst_i};
rrst_cc <= #`TCQ {rrst_cc[0],rd_rst_asreg_d2};
sckt_rd_rst_d1 <= #`TCQ safety_ckt_rd_rst;
if (!rd_rst_middle && rrst_reg[1] && !rrst_reg[2]) begin
rd_rst_active <= #`TCQ 1'b1;
rd_rst_middle <= #`TCQ 1'b1;
end else if (safety_ckt_rd_rst)
rd_rst_active <= #`TCQ 1'b0;
else if (sckt_rd_rst_d1 && !safety_ckt_rd_rst)
rd_rst_middle <= #`TCQ 1'b0;
end
assign rd_rst_asreg_d1 = rrst_reg[RST_SYNC_STAGES-2];
assign rd_rst_asreg_d2 = C_EN_SAFETY_CKT ? rrst_reg[RST_SYNC_STAGES-1] : rrst_reg[1];
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rrst_q[2] : 1'b0;
always @(posedge RD_CLK or posedge rd_rst_comb) begin
if (rd_rst_comb == 1'b1) begin
rd_rst_reg <= 1'b1;
end else begin
rd_rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_ic_rst
end else if (C_HAS_RST == 1 && C_COMMON_CLOCK == 1) begin : g7s_cc_rst
reg [1:0] rst_delayed_cc = 2'h0;
wire rst_delayed_cc_i;
assign rst_comb = !rst_asreg_d2 && rst_asreg;
assign rst_2_sync = rst_delayed_cc_i;
assign wr_rst_busy = C_EN_SAFETY_CKT ? |arst_sync_q[RST_SYNC_STAGES-1:1] | wrst_cc[1] : 1'b0;
assign rd_rst_busy = C_EN_SAFETY_CKT ? arst_sync_q[1] | arst_sync_q[RST_SYNC_STAGES-1] | wrst_cc[1] : 1'b0;
always @(posedge CLK or posedge rst_delayed) begin
if (rst_delayed == 1'b1)
rst_delayed_cc <= 2'b11;
else
rst_delayed_cc <= #`TCQ {rst_delayed_cc,1'b0};
end
assign rst_delayed_cc_i = rst_delayed_cc[1];
always @(posedge CLK or posedge rst_delayed_cc_i) begin
if (rst_delayed_cc_i == 1'b1) begin
rst_asreg <= 1'b1;
end else begin
if (rst_asreg_d1 == 1'b1) begin
rst_asreg <= #`TCQ 1'b0;
end else begin
rst_asreg <= #`TCQ rst_asreg;
end
end
end
always @(posedge CLK) begin
wrst_reg <= #`TCQ {wrst_reg[RST_SYNC_STAGES-2:0],rst_asreg};
wrst_cc <= #`TCQ {wrst_cc[0],arst_sync_q[RST_SYNC_STAGES-1]};
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
safety_ckt_wr_rst_i <= #`TCQ wrst_cc[1] | wr_rst_busy | sckt_wr_rst_i_q;
arst_sync_q <= #`TCQ {arst_sync_q[RST_SYNC_STAGES-2:0],rst_delayed_cc_i};
end
assign rst_asreg_d1 = wrst_reg[RST_SYNC_STAGES-2];
assign rst_asreg_d2 = C_EN_SAFETY_CKT ? wrst_reg[RST_SYNC_STAGES-1] : wrst_reg[1];
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? safety_ckt_wr_rst_i : 1'b0;
always @(posedge CLK or posedge rst_comb) begin
if (rst_comb == 1'b1) begin
rst_reg <= 1'b1;
end else begin
rst_reg <= #`TCQ 1'b0;
end
end
// end : g7s_cc_rst
end else if (IS_8SERIES == 1 && C_HAS_SRST == 1 && C_COMMON_CLOCK == 1) begin : g8s_cc_rst
assign wr_rst_busy = (C_MEMORY_TYPE != 4) ? rst_reg : rst_active_i;
assign rd_rst_busy = rst_reg;
assign rst_2_sync = srst_delayed;
always @* rst_full_ff_i <= rst_reg;
always @* rst_full_gen_i <= C_FULL_FLAGS_RST_VAL == 1 ? rst_active_i : 0;
assign safety_ckt_wr_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
assign safety_ckt_rd_rst = C_EN_SAFETY_CKT ? rst_reg | wr_rst_busy | sckt_wr_rst_i_q : 1'b0;
always @(posedge CLK) begin
rst_delayed_d1 <= #`TCQ srst_delayed;
rst_delayed_d2 <= #`TCQ rst_delayed_d1;
sckt_wr_rst_i_q <= #`TCQ wr_rst_busy;
if (rst_reg || rst_delayed_d2) begin
rst_active_i <= #`TCQ 1'b1;
end else begin
rst_active_i <= #`TCQ rst_reg;
end
end
always @(posedge CLK) begin
if (~rst_reg && srst_delayed) begin
rst_reg <= #`TCQ 1'b1;
end else if (rst_reg) begin
rst_reg <= #`TCQ 1'b0;
end else begin
rst_reg <= #`TCQ rst_reg;
end
end
// end : g8s_cc_rst
end else begin
assign wr_rst_busy = 1'b0;
assign rd_rst_busy = 1'b0;
assign safety_ckt_wr_rst = 1'b0;
assign safety_ckt_rd_rst = 1'b0;
end
endgenerate
generate
if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 1) begin : grstd1
// RST_FULL_GEN replaces the reset falling edge detection used to de-assert
// FULL, ALMOST_FULL & PROG_FULL flags if C_FULL_FLAGS_RST_VAL = 1.
// RST_FULL_FF goes to the reset pin of the final flop of FULL, ALMOST_FULL &
// PROG_FULL
reg rst_d1 = 1'b0;
reg rst_d2 = 1'b0;
reg rst_d3 = 1'b0;
reg rst_d4 = 1'b0;
reg rst_d5 = 1'b0;
always @ (posedge rst_2_sync or posedge clk_2_sync) begin
if (rst_2_sync) begin
rst_d1 <= 1'b1;
rst_d2 <= 1'b1;
rst_d3 <= 1'b1;
rst_d4 <= 1'b1;
end else begin
if (srst_delayed) begin
rst_d1 <= #`TCQ 1'b1;
rst_d2 <= #`TCQ 1'b1;
rst_d3 <= #`TCQ 1'b1;
rst_d4 <= #`TCQ 1'b1;
end else begin
rst_d1 <= #`TCQ wr_rst_busy;
rst_d2 <= #`TCQ rst_d1;
rst_d3 <= #`TCQ rst_d2 | safety_ckt_wr_rst;
rst_d4 <= #`TCQ rst_d3;
end
end
end
always @* rst_full_ff_i <= (C_HAS_SRST == 0) ? rst_d2 : 1'b0 ;
always @* rst_full_gen_i <= rst_d3;
end else if ((C_HAS_RST == 1 || C_HAS_SRST == 1 || C_ENABLE_RST_SYNC == 0) && C_FULL_FLAGS_RST_VAL == 0) begin : gnrst_full
always @* rst_full_ff_i <= (C_COMMON_CLOCK == 0) ? wr_rst_i : rst_i;
end
endgenerate // grstd1
endmodule //fifo_generator_v13_1_3_conv_ver
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0;
else
DOUT <= #`TCQ DIN;
end
endmodule // fifo_generator_v13_1_3_sync_stage
/*******************************************************************************
* Declaration of Independent-Clocks FIFO Module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_as
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_SYNCHRONIZER_STAGE = 2
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input SAFETY_CKT_WR_RST,
input SAFETY_CKT_RD_RST,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_CLK,
input RD_EN,
input RD_EN_USER,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input USER_EMPTY_FB,
input fab_read_data_valid_i,
input read_data_valid_i,
input ram_valid_i,
output reg ALMOST_EMPTY = 1'b1,
output reg ALMOST_FULL = C_FULL_FLAGS_RST_VAL,
output [C_DOUT_WIDTH-1:0] DOUT,
output reg EMPTY = 1'b1,
output reg EMPTY_FB = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL,
output OVERFLOW,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output UNDERFLOW,
output WR_ACK,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC_1 && SYMMETRIC_PORT && ERR_INJECTION;
// Array that holds the error injection type (single/double bit error) on
// a specific write operation, which is returned on read to corrupt the
// output data.
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
//The amount of data stored in the FIFO at any time is given
// by num_wr_bits (in the WR_CLK domain) and num_rd_bits (in the RD_CLK
// domain.
//num_wr_bits is calculated by considering the total words in the FIFO,
// and the state of the read pointer (which may not have yet crossed clock
// domains.)
//num_rd_bits is calculated by considering the total words in the FIFO,
// and the state of the write pointer (which may not have yet crossed clock
// domains.)
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
wire wr_rst_i = WR_RST;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0; // UP counter: Rolls back to 0 when reaches to max value.
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire rd_rst_i = RD_RST;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
// Delayed ram_rd_en is needed only for STD Embedded register option
generate
if (C_PRELOAD_LATENCY == 2) begin : grd_d
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
end
endgenerate
generate
if (C_PRELOAD_LATENCY == 2 && C_USE_EMBEDDED_REG == 3) begin : grd_d1
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
ram_rd_en_d1 <= 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
endgenerate
// Write pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : rdg // Read depth greater than write depth
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1:0] = 0;
end else begin : rdl // Read depth lesser than or equal to write depth
assign adj_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
endgenerate
// Generate Empty and Almost Empty
// ram_rd_en used to determine EMPTY should depend on the EMPTY.
assign ram_rd_en = RD_EN & !EMPTY;
assign empty_int = ((adj_wr_pntr_rd == rd_pntr) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+1'h1))));
assign almost_empty_int = ((adj_wr_pntr_rd == (rd_pntr+1'h1)) || (ram_rd_en && (adj_wr_pntr_rd == (rd_pntr+2'h2))));
// Register Empty and Almost Empty
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin
EMPTY <= 1'b1;
ALMOST_EMPTY <= 1'b1;
rd_data_count_int <= {C_RD_PNTR_WIDTH{1'b0}};
end else begin
rd_data_count_int <= #`TCQ {(adj_wr_pntr_rd[C_RD_PNTR_WIDTH-1:0] - rd_pntr[C_RD_PNTR_WIDTH-1:0]), 1'b0};
if (empty_int)
EMPTY <= #`TCQ 1'b1;
else
EMPTY <= #`TCQ 1'b0;
if (!EMPTY) begin
if (almost_empty_int)
ALMOST_EMPTY <= #`TCQ 1'b1;
else
ALMOST_EMPTY <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (SAFETY_CKT_RD_RST && C_EN_SAFETY_CKT)
EMPTY_FB <= #`TCQ 1'b1;
else if (empty_int)
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ 1'b0;
end // rd_rst_i
end // always
// Read pointer adjustment based on pointers width for EMPTY/ALMOST_EMPTY generation
generate
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wdg // Write depth greater than read depth
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1:0] = 0;
end else begin : wdl // Write depth lesser than or equal to read depth
assign adj_rd_pntr_wr = rd_pntr_wr[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end
endgenerate
// Generate FULL and ALMOST_FULL
// ram_wr_en used to determine FULL should depend on the FULL.
assign ram_wr_en = WR_EN & !FULL;
assign full_int = ((adj_rd_pntr_wr == (wr_pntr+1'h1)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+2'h2))));
assign almost_full_int = ((adj_rd_pntr_wr == (wr_pntr+2'h2)) || (ram_wr_en && (adj_rd_pntr_wr == (wr_pntr+3'h3))));
// Register FULL and ALMOST_FULL Empty
always @ (posedge WR_CLK or posedge RST_FULL_FF)
begin
if (RST_FULL_FF) begin
FULL <= C_FULL_FLAGS_RST_VAL;
ALMOST_FULL <= C_FULL_FLAGS_RST_VAL;
end else begin
if (full_int) begin
FULL <= #`TCQ 1'b1;
end else begin
FULL <= #`TCQ 1'b0;
end
if (RST_FULL_GEN) begin
ALMOST_FULL <= #`TCQ 1'b0;
end else if (!FULL) begin
if (almost_full_int)
ALMOST_FULL <= #`TCQ 1'b1;
else
ALMOST_FULL <= #`TCQ 1'b0;
end
end // wr_rst_i
end // always
always @ (posedge WR_CLK or posedge wr_rst_i)
begin
if (wr_rst_i) begin
wr_data_count_int <= {C_WR_DATA_COUNT_WIDTH{1'b0}};
end else begin
wr_data_count_int <= #`TCQ {(wr_pntr[C_WR_PNTR_WIDTH-1:0] - adj_rd_pntr_wr[C_WR_PNTR_WIDTH-1:0]), 1'b0};
end // wr_rst_i
end // always
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
stage1_valid <= 0;
stage2_valid <= 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN_USER) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//Pointers passed into opposite clock domain
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_EMPTY.
wire [31:0] num_read_words_pe =
num_rd_bits/(C_DOUT_WIDTH/C_DEPTH_RATIO_WR);
//Amount of data stored in the FIFO scaled to the narrowest (deepest) port
// (Do not include data in FWFT stages)
//Used to calculate PROG_FULL.
wire [31:0] num_write_words_pf =
num_wr_bits/(C_DIN_WIDTH/C_DEPTH_RATIO_RD);
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/***************************************************************************
* Internal registers and wires
**************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire valid_i;
wire valid_out1;
wire valid_out2;
wire valid_out;
wire underflow_i;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
reg valid_d1 = 0;
reg valid_d2 = 0;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/****************************************************************************
* Function Declarations
***************************************************************************/
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
/***********************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_d2 = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_CLK;
wire RD_EN;
wire RST;
wire WR_CLK;
wire WR_EN;
*/
//***************************************************************************
// Dout may change behavior based on latency
//***************************************************************************
assign ideal_dout_out[C_DOUT_WIDTH-1:0] = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) )?
ideal_dout_d1: ideal_dout;
assign DOUT[C_DOUT_WIDTH-1:0] = ideal_dout_out;
//***************************************************************************
// Assign SBITERR and DBITERR based on latency
//***************************************************************************
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY == 2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) ) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
(C_PRELOAD_LATENCY==2 && (C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
//***************************************************************************
// Safety-ckt logic with embedded reg/fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
// if (C_HAS_VALID == 1) begin
// assign valid_out = valid_d1;
// end
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK)
begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else
ram_rd_en_d1 <= #`TCQ ram_rd_en;
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else begin
if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end
end
endgenerate
//***************************************************************************
// Safety-ckt logic with embedded reg + fabric reg
//***************************************************************************
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft4 or posedge rd_rst_i or posedge RD_CLK) begin
if( rst_delayed_sft4 == 1'b1 || rd_rst_i == 1'b1)
ram_rd_en_d1 <= #`TCQ 1'b0;
else begin
ram_rd_en_d1 <= #`TCQ ram_rd_en;
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
end
end
always@(posedge rst_delayed_sft2 or posedge RD_CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end
endgenerate
//***************************************************************************
// Overflow may be active-low
//***************************************************************************
generate
if (C_HAS_OVERFLOW==1) begin : blockOF1
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end
endgenerate
assign PROG_EMPTY = ideal_prog_empty;
assign PROG_FULL = ideal_prog_full;
//***************************************************************************
// Valid may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_VALID==1) begin : blockVL1
assign valid_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out1 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG < 3)?
valid_d1: valid_i;
assign valid_out2 = (C_PRELOAD_LATENCY==2 &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_USE_EMBEDDED_REG == 3)?
valid_d2: valid_i;
assign valid_out = (C_USE_EMBEDDED_REG == 3) ? valid_out2 : valid_out1;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end
endgenerate
//***************************************************************************
// Underflow may change behavior based on latency or active-low
//***************************************************************************
generate
if (C_HAS_UNDERFLOW==1) begin : blockUF1
assign underflow_i = (C_PRELOAD_LATENCY==0) ? (RD_EN & EMPTY) : ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end
endgenerate
//***************************************************************************
// Write acknowledge may be active low
//***************************************************************************
generate
if (C_HAS_WR_ACK==1) begin : blockWK1
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : wdc_fwft_ext
reg [C_PNTR_WIDTH-1:0] adjusted_wr_pntr = 0;
reg [C_PNTR_WIDTH-1:0] adjusted_rd_pntr = 0;
wire [C_PNTR_WIDTH-1:0] diff_wr_rd_tmp;
wire [C_PNTR_WIDTH:0] diff_wr_rd;
reg [C_PNTR_WIDTH:0] wr_data_count_i = 0;
always @* begin
if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = 0;
adjusted_rd_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr_wr;
end else if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin
adjusted_rd_pntr = rd_pntr_wr;
adjusted_wr_pntr = 0;
adjusted_wr_pntr[C_PNTR_WIDTH-1:C_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
end else begin
adjusted_wr_pntr = wr_pntr;
adjusted_rd_pntr = rd_pntr_wr;
end
end // always @*
assign diff_wr_rd_tmp = adjusted_wr_pntr - adjusted_rd_pntr;
assign diff_wr_rd = {1'b0,diff_wr_rd_tmp};
always @ (posedge wr_rst_i or posedge WR_CLK)
begin
if (wr_rst_i)
wr_data_count_i <= 0;
else
wr_data_count_i <= #`TCQ diff_wr_rd + EXTRA_WORDS_DC;
end // always @ (posedge WR_CLK or posedge WR_CLK)
always @* begin
if (C_WR_PNTR_WIDTH >= C_RD_PNTR_WIDTH)
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:0];
else
wdc_fwft_ext_as = wr_data_count_i[C_PNTR_WIDTH:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end // always @*
end // wdc_fwft_ext
endgenerate
//***************************************************************************
// Generate RD_DATA_COUNT if Use Extra Logic option is selected
//***************************************************************************
reg [C_RD_PNTR_WIDTH:0] rdc_fwft_ext_as = 0;
generate if (C_USE_EMBEDDED_REG < 3) begin: rdc_fwft_ext_both
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= 0;
end else begin
if (!stage2_valid)
rdc_fwft_ext_as <= #`TCQ 0;
else if (!stage1_valid && stage2_valid)
rdc_fwft_ext_as <= #`TCQ 1;
else
rdc_fwft_ext_as <= #`TCQ diff_rd_wr + 2'h2;
end
end // always @ (posedge WR_CLK or posedge WR_CLK)
end // rdc_fwft_ext
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3) begin
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : rdc_fwft_ext
reg [C_RD_PNTR_WIDTH-1:0] adjusted_wr_pntr_rd = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_rd_wr_tmp;
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr;
always @* begin
if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin
adjusted_wr_pntr_rd = 0;
adjusted_wr_pntr_rd[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr_rd;
end else begin
adjusted_wr_pntr_rd = wr_pntr_rd[C_WR_PNTR_WIDTH-1:C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end
end // always @*
assign diff_rd_wr_tmp = adjusted_wr_pntr_rd - rd_pntr;
assign diff_rd_wr = {1'b0,diff_rd_wr_tmp};
wire [C_RD_PNTR_WIDTH:0] diff_rd_wr_1;
// assign diff_rd_wr_1 = diff_rd_wr +2'h2;
always @ (posedge rd_rst_i or posedge RD_CLK)
begin
if (rd_rst_i) begin
rdc_fwft_ext_as <= #`TCQ 0;
end else begin
//if (fab_read_data_valid_i == 1'b0 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b1 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b0;
//else if (fab_read_data_valid_i == 1'b1 && ((ram_valid_i == 1'b0 && read_data_valid_i ==1'b0) || (ram_valid_i == 1'b0 && read_data_valid_i ==1'b1)))
// rdc_fwft_ext_as <= 1'b1;
//else
rdc_fwft_ext_as <= diff_rd_wr + 2'h2 ;
end
end
end
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = C_USE_FWFT_DATA_COUNT ?
rdc_fwft_ext_as[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH] :
rd_data_count_int[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = (C_USE_FWFT_DATA_COUNT == 1) ?
wdc_fwft_ext_as[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] :
wr_data_count_int[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate
if (C_HAS_VALID==1) begin : blockVL2
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_d2 <= 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
valid_d2 <= #`TCQ valid_d1;
end
// if (C_USE_EMBEDDED_REG == 3 && (C_EN_SAFETY_CKT == 0 || C_EN_SAFETY_CKT == 1 ) begin
// valid_d2 <= #`TCQ valid_d1;
// end
end
end
endgenerate
//Capture delayed version of dout
/**************************************************************************
*embedded/fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG < 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0)
err_type_d1 <= #`TCQ 0;
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
endgenerate
/**************************************************************************
*embedded + fabric reg with no safety ckt
**************************************************************************/
generate
if (C_USE_EMBEDDED_REG == 3) begin
always @(posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge RD_CLK)
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate
if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge WR_CLK) begin
ideal_overflow <= #`TCQ WR_EN & FULL;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge WR_CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (FULL | wr_rst_i);
ideal_overflow <= #`TCQ WR_EN & (FULL );
end
end
endgenerate
generate
if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ EMPTY & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge RD_CLK) begin
ideal_underflow <= #`TCQ (EMPTY) & RD_EN;
//ideal_underflow <= #`TCQ (rd_rst_i | EMPTY) & RD_EN;
end
end
endgenerate
/**************************************************************************
* Write/Read Pointer Synchronization
**************************************************************************/
localparam NO_OF_SYNC_STAGE_INC_G2B = C_SYNCHRONIZER_STAGE + 1;
wire [C_WR_PNTR_WIDTH-1:0] wr_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_sync_stgs [0:NO_OF_SYNC_STAGE_INC_G2B];
genvar gss;
generate for (gss = 1; gss <= NO_OF_SYNC_STAGE_INC_G2B; gss = gss + 1) begin : Sync_stage_inst
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_WR_PNTR_WIDTH)
)
rd_stg_inst
(
.RST (rd_rst_i),
.CLK (RD_CLK),
.DIN (wr_pntr_sync_stgs[gss-1]),
.DOUT (wr_pntr_sync_stgs[gss])
);
fifo_generator_v13_1_3_sync_stage
#(
.C_WIDTH (C_RD_PNTR_WIDTH)
)
wr_stg_inst
(
.RST (wr_rst_i),
.CLK (WR_CLK),
.DIN (rd_pntr_sync_stgs[gss-1]),
.DOUT (rd_pntr_sync_stgs[gss])
);
end endgenerate // Sync_stage_inst
assign wr_pntr_sync_stgs[0] = wr_pntr_rd1;
assign rd_pntr_sync_stgs[0] = rd_pntr_wr1;
always@* begin
wr_pntr_rd <= wr_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
rd_pntr_wr <= rd_pntr_sync_stgs[NO_OF_SYNC_STAGE_INC_G2B];
end
/**************************************************************************
* Write Domain Logic
**************************************************************************/
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_wp
if (wr_rst_i == 1'b1 && C_EN_SAFETY_CKT == 0)
wr_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_WR_RST == 1'b1)
wr_pntr <= #`TCQ 0;
end
always @(posedge WR_CLK or posedge wr_rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (wr_rst_i == 1'b1) begin
num_wr_bits <= 0;
next_num_wr_bits = 0;
wr_ptr <= C_WR_DEPTH - 1;
rd_ptr_wrclk <= C_RD_DEPTH - 1;
ideal_wr_ack <= 0;
ideal_wr_count <= 0;
tmp_wr_listsize = 0;
rd_ptr_wrclk_next <= 0;
wr_pntr_rd1 <= 0;
end else begin //wr_rst_i==0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
//If this is a write, handle the write by adding the value
// to the linked list, and updating all outputs appropriately
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD
>= C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full, but reporting full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//With DEPTH-1 words in the FIFO, it is almost_full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is completely empty, but it is
// reporting FULL for some reason (like reset)
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <=
C_FIFO_WR_DEPTH-2) begin
//No change to FIFO
//Write not successful
ideal_wr_ack <= #`TCQ 0;
//FIFO is really not close to full, so change flag status.
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end //(tmp_wr_listsize == 0)
end else begin
//If the FIFO is full, do NOT perform the write,
// update flags accordingly
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD >=
C_FIFO_WR_DEPTH) begin
//write unsuccessful - do not change contents
//Do not acknowledge the write
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is one from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-1) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//This write is CAUSING the FIFO to go full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is 2 from full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD ==
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Still 2 from full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
//If the FIFO is not close to being full
end else
if ((tmp_wr_listsize + C_DEPTH_RATIO_RD - 1)/C_DEPTH_RATIO_RD <
C_FIFO_WR_DEPTH-2) begin
//Add value on DIN port to FIFO
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //wr_rst_i==0
end // gen_fifo_w
/***************************************************************************
* Programmable FULL flags
***************************************************************************/
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_assert_val;
wire [C_WR_PNTR_WIDTH-1:0] pf_thr_negate_val;
generate if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin : FWFT
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_DC;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_DC;
end else begin // STD
assign pf_thr_assert_val = C_PROG_FULL_THRESH_ASSERT_VAL;
assign pf_thr_negate_val = C_PROG_FULL_THRESH_NEGATE_VAL;
end endgenerate
always @(posedge WR_CLK or posedge wr_rst_i) begin
if (wr_rst_i == 1'b1) begin
diff_pntr <= 0;
end else begin
if (ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr + 2'h1);
else if (!ram_wr_en)
diff_pntr <= #`TCQ (wr_pntr - adj_rd_pntr_wr);
end
end
always @(posedge WR_CLK or posedge RST_FULL_FF) begin : gen_pf
if (RST_FULL_FF == 1'b1) begin
ideal_prog_full <= C_FULL_FLAGS_RST_VAL;
end else begin
if (RST_FULL_GEN)
ideal_prog_full <= #`TCQ 0;
//Single Programmable Full Constant Threshold
else if (C_PROG_FULL_TYPE == 1) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Constant Thresholds
end else if (C_PROG_FULL_TYPE == 2) begin
if (FULL == 0) begin
if (diff_pntr >= pf_thr_assert_val)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < pf_thr_negate_val)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Single Programmable Full Threshold Input
end else if (C_PROG_FULL_TYPE == 3) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH)
ideal_prog_full <= #`TCQ 1;
else
ideal_prog_full <= #`TCQ 0;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
//Two Programmable Full Threshold Inputs
end else if (C_PROG_FULL_TYPE == 4) begin
if (FULL == 0) begin
if (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) begin // FWFT
if (diff_pntr >= (PROG_FULL_THRESH_ASSERT - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < (PROG_FULL_THRESH_NEGATE - EXTRA_WORDS_DC))
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end else begin // STD
if (diff_pntr >= PROG_FULL_THRESH_ASSERT)
ideal_prog_full <= #`TCQ 1;
else if (diff_pntr < PROG_FULL_THRESH_NEGATE)
ideal_prog_full <= #`TCQ 0;
else
ideal_prog_full <= #`TCQ ideal_prog_full;
end
end else
ideal_prog_full <= #`TCQ ideal_prog_full;
end // C_PROG_FULL_TYPE
end //wr_rst_i==0
end //
/**************************************************************************
* Read Domain Logic
**************************************************************************/
/*********************************************************
* Programmable EMPTY flags
*********************************************************/
//Determine the Assert and Negate thresholds for Programmable Empty
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_assert_val;
wire [C_RD_PNTR_WIDTH-1:0] pe_thr_negate_val;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_rd = 0;
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_pe
if (rd_rst_i) begin
diff_pntr_rd <= 0;
ideal_prog_empty <= 1'b1;
end else begin
if (ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr) - 1'h1;
else if (!ram_rd_en)
diff_pntr_rd <= #`TCQ (adj_wr_pntr_rd - rd_pntr);
else
diff_pntr_rd <= #`TCQ diff_pntr_rd;
if (C_PROG_EMPTY_TYPE == 1) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 2) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 3) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else
ideal_prog_empty <= #`TCQ 0;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else if (C_PROG_EMPTY_TYPE == 4) begin
if (EMPTY == 0) begin
if (diff_pntr_rd <= pe_thr_assert_val)
ideal_prog_empty <= #`TCQ 1;
else if (diff_pntr_rd > pe_thr_negate_val)
ideal_prog_empty <= #`TCQ 0;
else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end else
ideal_prog_empty <= #`TCQ ideal_prog_empty;
end //C_PROG_EMPTY_TYPE
end
end // gen_pe
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH - 2'h2 : PROG_EMPTY_THRESH;
end endgenerate // single_pe_thr_input
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_thr_input
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_ASSERT - 2'h2 : PROG_EMPTY_THRESH_ASSERT;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
PROG_EMPTY_THRESH_NEGATE - 2'h2 : PROG_EMPTY_THRESH_NEGATE;
end endgenerate // multiple_pe_thr_input
generate if (C_PROG_EMPTY_TYPE < 3) begin : single_multiple_pe_thr_const
assign pe_thr_assert_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2'h2 : C_PROG_EMPTY_THRESH_ASSERT_VAL;
assign pe_thr_negate_val = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2'h2 : C_PROG_EMPTY_THRESH_NEGATE_VAL;
end endgenerate // single_multiple_pe_thr_const
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_rp
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
rd_pntr <= 0;
else if (C_EN_SAFETY_CKT == 1 && SAFETY_CKT_RD_RST == 1'b1)
rd_pntr <= #`TCQ 0;
end
always @(posedge RD_CLK or posedge rd_rst_i) begin : gen_fifo_r_as
/****** Reset fifo (case 1)***************************************/
if (rd_rst_i) begin
num_rd_bits <= 0;
next_num_rd_bits = 0;
rd_ptr <= C_RD_DEPTH -1;
rd_pntr_wr1 <= 0;
wr_ptr_rdclk <= C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_MEMORY_TYPE == 2 && C_USE_DOUT_RST == 1)
ideal_dout <= dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= 1'b0;
ideal_rd_count <= 0;
end else begin //rd_rst_i==0
rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
/*****************************************************************/
// Read Operation - Read Latency 1
/*****************************************************************/
if (C_PRELOAD_LATENCY==1 || C_PRELOAD_LATENCY==2) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
//If the FIFO is one from empty, but it is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is two from empty, and is reporting empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH))
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end // else: if(ideal_empty == 1'b1)
else //if (ideal_empty == 1'b0)
begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == C_FIFO_RD_DEPTH)
//If the FIFO is not close to being empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) && (tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
//If the FIFO is two from empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2)
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
//If the FIFO is one from empty
else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR == 1))
begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 1)
//If the FIFO is completely empty
else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0)
begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end //(RD_EN == 1'b1)
else //if (RD_EN == 1'b0)
begin
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
/*****************************************************************/
// Read Operation - Read Latency 0
/*****************************************************************/
end else if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0) begin
ideal_valid <= #`TCQ 1'b0;
if (ram_rd_en == 1'b1) begin
if (EMPTY == 1'b1) begin
//If the FIFO is completely empty, and is reporting empty
if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty, but it is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that FIFO is no longer empty, but is almost empty (has one word left)
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty, and is reporting empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Fifo has two words, so is neither empty or almost empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to empty, but is reporting that it is
// Treat the FIFO as empty this time, but unset EMPTY flags.
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<C_FIFO_RD_DEPTH)) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Note that the FIFO is No Longer Empty or Almost Empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if ((tmp_rd_listsize > 2) && (tmp_rd_listsize<=C_FIFO_RD_DEPTH-1))
end else begin
//If the FIFO is completely full, and we are successfully reading from it
if (tmp_rd_listsize/C_DEPTH_RATIO_WR >= C_FIFO_RD_DEPTH) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is not close to being empty
end else if ((tmp_rd_listsize/C_DEPTH_RATIO_WR > 2) &&
(tmp_rd_listsize/C_DEPTH_RATIO_WR<=C_FIFO_RD_DEPTH)) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Not close to empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is two from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 2) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Fifo is not yet empty. It is going almost_empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is one from empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR == 1) begin
//Read the value from the FIFO
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
//Note that FIFO is GOING empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
//If the FIFO is completely empty
end else if (tmp_rd_listsize/C_DEPTH_RATIO_WR <= 0) begin
//Do not change the contents of the FIFO
//Do not acknowledge the read from empty FIFO
ideal_valid <= #`TCQ 1'b0;
//Reminder that FIFO is still empty
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize <= 0)
end // if (ideal_empty == 1'b0)
end else begin//(RD_EN == 1'b0)
//If user did not attempt a read, do not give an ack or err
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // else: !if(RD_EN == 1'b1)
end //if (C_PRELOAD_REGS==1 && C_PRELOAD_LATENCY==0)
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //rd_rst_i==0
end //always gen_fifo_r_as
endmodule // fifo_generator_v13_1_3_bhv_ver_as
/*******************************************************************************
* Declaration of Low Latency Asynchronous FIFO
******************************************************************************/
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_USE_DOUT_RST = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_FIFO_TYPE = 0
)
/***************************************************************************
* Declare Input and Output Ports
***************************************************************************/
(
input [C_DIN_WIDTH-1:0] DIN,
input RD_CLK,
input RD_EN,
input WR_RST,
input RD_RST,
input WR_CLK,
input WR_EN,
output reg [C_DOUT_WIDTH-1:0] DOUT = 0,
output reg EMPTY = 1'b1,
output reg FULL = C_FULL_FLAGS_RST_VAL
);
//-----------------------------------------------------------------------------
// Low Latency Asynchronous FIFO
//-----------------------------------------------------------------------------
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
integer i;
initial begin
for (i = 0; i < C_WR_DEPTH; i = i + 1)
memory[i] = 0;
end
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_ll_afifo = 0;
wire [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_ll_afifo_q = 0;
reg ll_afifo_full = 1'b0;
reg ll_afifo_empty = 1'b1;
wire write_allow;
wire read_allow;
assign write_allow = WR_EN & ~ll_afifo_full;
assign read_allow = RD_EN & ~ll_afifo_empty;
//-----------------------------------------------------------------------------
// Write Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
wr_pntr_ll_afifo <= 0;
else if (write_allow)
wr_pntr_ll_afifo <= #`TCQ wr_pntr_ll_afifo + 1;
end
//-----------------------------------------------------------------------------
// Read Pointer Generation
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
rd_pntr_ll_afifo_q <= 0;
else
rd_pntr_ll_afifo_q <= #`TCQ rd_pntr_ll_afifo;
end
assign rd_pntr_ll_afifo = read_allow ? rd_pntr_ll_afifo_q + 1 : rd_pntr_ll_afifo_q;
//-----------------------------------------------------------------------------
// Fill the Memory
//-----------------------------------------------------------------------------
always @(posedge WR_CLK) begin
if (write_allow)
memory[wr_pntr_ll_afifo] <= #`TCQ DIN;
end
//-----------------------------------------------------------------------------
// Generate DOUT
//-----------------------------------------------------------------------------
always @(posedge RD_CLK) begin
DOUT <= #`TCQ memory[rd_pntr_ll_afifo];
end
//-----------------------------------------------------------------------------
// Generate EMPTY
//-----------------------------------------------------------------------------
always @(posedge RD_CLK or posedge RD_RST) begin
if (RD_RST)
ll_afifo_empty <= 1'b1;
else
ll_afifo_empty <= ((wr_pntr_ll_afifo == rd_pntr_ll_afifo_q) |
(read_allow & (wr_pntr_ll_afifo == (rd_pntr_ll_afifo_q + 2'h1))));
end
//-----------------------------------------------------------------------------
// Generate FULL
//-----------------------------------------------------------------------------
always @(posedge WR_CLK or posedge WR_RST) begin
if (WR_RST)
ll_afifo_full <= 1'b1;
else
ll_afifo_full <= ((rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h1)) |
(write_allow & (rd_pntr_ll_afifo_q == (wr_pntr_ll_afifo + 2'h2))));
end
always @* begin
FULL <= ll_afifo_full;
EMPTY <= ll_afifo_empty;
end
endmodule // fifo_generator_v13_1_3_beh_ver_ll_afifo
/*******************************************************************************
* Declaration of top-level module
******************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* Declare user parameters and their defaults
*************************************************************************/
#(
parameter C_FAMILY = "virtex7",
parameter C_DATA_COUNT_WIDTH = 2,
parameter C_DIN_WIDTH = 8,
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_FULL_FLAGS_RST_VAL = 1,
parameter C_HAS_ALMOST_EMPTY = 0,
parameter C_HAS_ALMOST_FULL = 0,
parameter C_HAS_DATA_COUNT = 0,
parameter C_HAS_OVERFLOW = 0,
parameter C_HAS_RD_DATA_COUNT = 0,
parameter C_HAS_RST = 0,
parameter C_HAS_SRST = 0,
parameter C_HAS_UNDERFLOW = 0,
parameter C_HAS_VALID = 0,
parameter C_HAS_WR_ACK = 0,
parameter C_HAS_WR_DATA_COUNT = 0,
parameter C_IMPLEMENTATION_TYPE = 0,
parameter C_MEMORY_TYPE = 1,
parameter C_OVERFLOW_LOW = 0,
parameter C_PRELOAD_LATENCY = 1,
parameter C_PRELOAD_REGS = 0,
parameter C_PROG_EMPTY_THRESH_ASSERT_VAL = 0,
parameter C_PROG_EMPTY_THRESH_NEGATE_VAL = 0,
parameter C_PROG_EMPTY_TYPE = 0,
parameter C_PROG_FULL_THRESH_ASSERT_VAL = 0,
parameter C_PROG_FULL_THRESH_NEGATE_VAL = 0,
parameter C_PROG_FULL_TYPE = 0,
parameter C_RD_DATA_COUNT_WIDTH = 2,
parameter C_RD_DEPTH = 256,
parameter C_RD_PNTR_WIDTH = 8,
parameter C_UNDERFLOW_LOW = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_FWFT_DATA_COUNT = 0,
parameter C_VALID_LOW = 0,
parameter C_WR_ACK_LOW = 0,
parameter C_WR_DATA_COUNT_WIDTH = 2,
parameter C_WR_DEPTH = 256,
parameter C_WR_PNTR_WIDTH = 8,
parameter C_USE_ECC = 0,
parameter C_ENABLE_RST_SYNC = 1,
parameter C_ERROR_INJECTION_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
/**************************************************************************
* Declare Input and Output Ports
*************************************************************************/
(
//Inputs
input SAFETY_CKT_WR_RST,
input CLK,
input [C_DIN_WIDTH-1:0] DIN,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT,
input [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT,
input [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE,
input RD_EN,
input RD_EN_USER,
input USER_EMPTY_FB,
input RST,
input RST_FULL_GEN,
input RST_FULL_FF,
input SRST,
input WR_EN,
input INJECTDBITERR,
input INJECTSBITERR,
input WR_RST_BUSY,
input RD_RST_BUSY,
//Outputs
output ALMOST_EMPTY,
output ALMOST_FULL,
output reg [C_DATA_COUNT_WIDTH-1:0] DATA_COUNT = 0,
output [C_DOUT_WIDTH-1:0] DOUT,
output EMPTY,
output reg EMPTY_FB = 1'b1,
output FULL,
output OVERFLOW,
output [C_RD_DATA_COUNT_WIDTH-1:0] RD_DATA_COUNT,
output [C_WR_DATA_COUNT_WIDTH-1:0] WR_DATA_COUNT,
output PROG_EMPTY,
output PROG_FULL,
output VALID,
output UNDERFLOW,
output WR_ACK,
output SBITERR,
output DBITERR
);
reg [C_RD_PNTR_WIDTH:0] rd_data_count_int = 0;
reg [C_WR_PNTR_WIDTH:0] wr_data_count_int = 0;
wire [C_RD_PNTR_WIDTH:0] rd_data_count_i_ss;
wire [C_WR_PNTR_WIDTH:0] wr_data_count_i_ss;
reg [C_WR_PNTR_WIDTH:0] wdc_fwft_ext_as = 0;
/***************************************************************************
* Parameters used as constants
**************************************************************************/
localparam IS_8SERIES = (C_FAMILY == "virtexu" || C_FAMILY == "kintexu" || C_FAMILY == "artixu" || C_FAMILY == "virtexuplus" || C_FAMILY == "zynquplus" || C_FAMILY == "kintexuplus") ? 1 : 0;
localparam C_DEPTH_RATIO_WR =
(C_WR_DEPTH>C_RD_DEPTH) ? (C_WR_DEPTH/C_RD_DEPTH) : 1;
localparam C_DEPTH_RATIO_RD =
(C_RD_DEPTH>C_WR_DEPTH) ? (C_RD_DEPTH/C_WR_DEPTH) : 1;
//localparam C_FIFO_WR_DEPTH = C_WR_DEPTH - 1;
//localparam C_FIFO_RD_DEPTH = C_RD_DEPTH - 1;
localparam C_GRTR_PNTR_WIDTH = (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH ;
// C_DEPTH_RATIO_WR | C_DEPTH_RATIO_RD | C_PNTR_WIDTH | EXTRA_WORDS_DC
// -----------------|------------------|-----------------|---------------
// 1 | 8 | C_RD_PNTR_WIDTH | 2
// 1 | 4 | C_RD_PNTR_WIDTH | 2
// 1 | 2 | C_RD_PNTR_WIDTH | 2
// 1 | 1 | C_WR_PNTR_WIDTH | 2
// 2 | 1 | C_WR_PNTR_WIDTH | 4
// 4 | 1 | C_WR_PNTR_WIDTH | 8
// 8 | 1 | C_WR_PNTR_WIDTH | 16
localparam C_PNTR_WIDTH = (C_WR_PNTR_WIDTH>=C_RD_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
wire [C_PNTR_WIDTH:0] EXTRA_WORDS_DC = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
wire [C_WR_PNTR_WIDTH:0] EXTRA_WORDS_PF = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//wire [C_RD_PNTR_WIDTH:0] EXTRA_WORDS_PE = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam EXTRA_WORDS_PF_PARAM = (C_DEPTH_RATIO_WR == 1) ? 2 : (2 * C_DEPTH_RATIO_WR/C_DEPTH_RATIO_RD);
//localparam EXTRA_WORDS_PE_PARAM = (C_DEPTH_RATIO_RD == 1) ? 2 : (2 * C_DEPTH_RATIO_RD/C_DEPTH_RATIO_WR);
localparam [31:0] reads_per_write = C_DIN_WIDTH/C_DOUT_WIDTH;
localparam [31:0] log2_reads_per_write = log2_val(reads_per_write);
localparam [31:0] writes_per_read = C_DOUT_WIDTH/C_DIN_WIDTH;
localparam [31:0] log2_writes_per_read = log2_val(writes_per_read);
//When RST is present, set FULL reset value to '1'.
//If core has no RST, make sure FULL powers-on as '0'.
//The reset value assignments for FULL, ALMOST_FULL, and PROG_FULL are not
//changed for v3.2(IP2_Im). When the core has Sync Reset, C_HAS_SRST=1 and C_HAS_RST=0.
// Therefore, during SRST, all the FULL flags reset to 0.
localparam C_HAS_FAST_FIFO = 0;
localparam C_FIFO_WR_DEPTH = C_WR_DEPTH;
localparam C_FIFO_RD_DEPTH = C_RD_DEPTH;
// Local parameters used to determine whether to inject ECC error or not
localparam SYMMETRIC_PORT = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 1 : 0;
localparam ERR_INJECTION = (C_ERROR_INJECTION_TYPE != 0) ? 1 : 0;
localparam C_USE_ECC_1 = (C_USE_ECC == 1 || C_USE_ECC ==2) ? 1:0;
localparam ENABLE_ERR_INJECTION = C_USE_ECC && SYMMETRIC_PORT && ERR_INJECTION;
localparam C_DATA_WIDTH = (ENABLE_ERR_INJECTION == 1) ? (C_DIN_WIDTH+2) : C_DIN_WIDTH;
localparam IS_ASYMMETRY = (C_DIN_WIDTH == C_DOUT_WIDTH) ? 0 : 1;
localparam LESSER_WIDTH = (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) ? C_WR_PNTR_WIDTH : C_RD_PNTR_WIDTH;
localparam [C_RD_PNTR_WIDTH-1 : 0] DIFF_MAX_RD = {C_RD_PNTR_WIDTH{1'b1}};
localparam [C_WR_PNTR_WIDTH-1 : 0] DIFF_MAX_WR = {C_WR_PNTR_WIDTH{1'b1}};
/**************************************************************************
* FIFO Contents Tracking and Data Count Calculations
*************************************************************************/
// Memory which will be used to simulate a FIFO
reg [C_DIN_WIDTH-1:0] memory[C_WR_DEPTH-1:0];
reg [1:0] ecc_err[C_WR_DEPTH-1:0];
/**************************************************************************
* Internal Registers and wires
*************************************************************************/
//Temporary signals used for calculating the model's outputs. These
//are only used in the assign statements immediately following wire,
//parameter, and function declarations.
wire underflow_i;
wire valid_i;
wire valid_out;
reg [31:0] num_wr_bits;
reg [31:0] num_rd_bits;
reg [31:0] next_num_wr_bits;
reg [31:0] next_num_rd_bits;
//The write pointer - tracks write operations
// (Works opposite to core: wr_ptr is a DOWN counter)
reg [31:0] wr_ptr;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd1 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd3 = 0;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr_rd = 0;
reg wr_rst_d1 =0;
//The read pointer - tracks read operations
// (rd_ptr Works opposite to core: rd_ptr is a DOWN counter)
reg [31:0] rd_ptr;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr2 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr3 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr4 = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr_wr = 0;
wire ram_rd_en;
wire empty_int;
wire almost_empty_int;
wire ram_wr_en;
wire full_int;
wire almost_full_int;
reg ram_rd_en_reg = 1'b0;
reg ram_rd_en_d1 = 1'b0;
reg fab_rd_en_d1 = 1'b0;
wire srst_rrst_busy;
//Ideal FIFO signals. These are the raw output of the behavioral model,
//which behaves like an ideal FIFO.
reg [1:0] err_type = 0;
reg [1:0] err_type_d1 = 0;
reg [1:0] err_type_both = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_d1 = 0;
reg [C_DOUT_WIDTH-1:0] ideal_dout_both = 0;
wire [C_DOUT_WIDTH-1:0] ideal_dout_out;
wire fwft_enabled;
reg ideal_wr_ack = 0;
reg ideal_valid = 0;
reg ideal_overflow = C_OVERFLOW_LOW;
reg ideal_underflow = C_UNDERFLOW_LOW;
reg full_i = C_FULL_FLAGS_RST_VAL;
reg full_i_temp = 0;
reg empty_i = 1;
reg almost_full_i = 0;
reg almost_empty_i = 1;
reg prog_full_i = 0;
reg prog_empty_i = 1;
reg [C_WR_PNTR_WIDTH-1:0] wr_pntr = 0;
reg [C_RD_PNTR_WIDTH-1:0] rd_pntr = 0;
wire [C_RD_PNTR_WIDTH-1:0] adj_wr_pntr_rd;
wire [C_WR_PNTR_WIDTH-1:0] adj_rd_pntr_wr;
reg [C_RD_PNTR_WIDTH-1:0] diff_count = 0;
reg write_allow_q = 0;
reg read_allow_q = 0;
reg valid_d1 = 0;
reg valid_both = 0;
reg valid_d2 = 0;
wire rst_i;
wire srst_i;
//user specified value for reseting the size of the fifo
reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
reg [31:0] wr_ptr_rdclk;
reg [31:0] wr_ptr_rdclk_next;
reg [31:0] rd_ptr_wrclk;
reg [31:0] rd_ptr_wrclk_next;
/****************************************************************************
* Function Declarations
***************************************************************************/
/****************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***************************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 ) begin
case (def_data[7:0])
8'b00000000 : begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default : begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1) begin
if ((index*4)+j < C_DOUT_WIDTH) begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
/**************************************************************************
* log2_val
* Returns the 'log2' value for the input value for the supported ratios
***************************************************************************/
function [31:0] log2_val;
input [31:0] binary_val;
begin
if (binary_val == 8) begin
log2_val = 3;
end else if (binary_val == 4) begin
log2_val = 2;
end else begin
log2_val = 1;
end
end
endfunction
reg ideal_prog_full = 0;
reg ideal_prog_empty = 1;
reg [C_WR_DATA_COUNT_WIDTH-1 : 0] ideal_wr_count = 0;
reg [C_RD_DATA_COUNT_WIDTH-1 : 0] ideal_rd_count = 0;
//Assorted reg values for delayed versions of signals
//reg valid_d1 = 0;
//user specified value for reseting the size of the fifo
//reg [C_DOUT_WIDTH-1:0] dout_reset_val = 0;
//temporary registers for WR_RESPONSE_LATENCY feature
integer tmp_wr_listsize;
integer tmp_rd_listsize;
//Signal for registered version of prog full and empty
//Threshold values for Programmable Flags
integer prog_empty_actual_thresh_assert;
integer prog_empty_actual_thresh_negate;
integer prog_full_actual_thresh_assert;
integer prog_full_actual_thresh_negate;
/**************************************************************************
* write_fifo
* This task writes a word to the FIFO memory and updates the
* write pointer.
* FIFO size is relative to write domain.
***************************************************************************/
task write_fifo;
begin
memory[wr_ptr] <= DIN;
wr_pntr <= #`TCQ wr_pntr + 1;
// Store the type of error injection (double/single) on write
case (C_ERROR_INJECTION_TYPE)
3: ecc_err[wr_ptr] <= {INJECTDBITERR,INJECTSBITERR};
2: ecc_err[wr_ptr] <= {INJECTDBITERR,1'b0};
1: ecc_err[wr_ptr] <= {1'b0,INJECTSBITERR};
default: ecc_err[wr_ptr] <= 0;
endcase
// (Works opposite to core: wr_ptr is a DOWN counter)
if (wr_ptr == 0) begin
wr_ptr <= C_WR_DEPTH - 1;
end else begin
wr_ptr <= wr_ptr - 1;
end
end
endtask // write_fifo
/**************************************************************************
* read_fifo
* This task reads a word from the FIFO memory and updates the read
* pointer. It's output is the ideal_dout bus.
* FIFO size is relative to write domain.
***************************************************************************/
task read_fifo;
integer i;
reg [C_DOUT_WIDTH-1:0] tmp_dout;
reg [C_DIN_WIDTH-1:0] memory_read;
reg [31:0] tmp_rd_ptr;
reg [31:0] rd_ptr_high;
reg [31:0] rd_ptr_low;
reg [1:0] tmp_ecc_err;
begin
rd_pntr <= #`TCQ rd_pntr + 1;
// output is wider than input
if (reads_per_write == 0) begin
tmp_dout = 0;
tmp_rd_ptr = (rd_ptr << log2_writes_per_read)+(writes_per_read-1);
for (i = writes_per_read - 1; i >= 0; i = i - 1) begin
tmp_dout = tmp_dout << C_DIN_WIDTH;
tmp_dout = tmp_dout | memory[tmp_rd_ptr];
// (Works opposite to core: rd_ptr is a DOWN counter)
if (tmp_rd_ptr == 0) begin
tmp_rd_ptr = C_WR_DEPTH - 1;
end else begin
tmp_rd_ptr = tmp_rd_ptr - 1;
end
end
// output is symmetric
end else if (reads_per_write == 1) begin
tmp_dout = memory[rd_ptr][C_DIN_WIDTH-1:0];
// Retreive the error injection type. Based on the error injection type
// corrupt the output data.
tmp_ecc_err = ecc_err[rd_ptr];
if (ENABLE_ERR_INJECTION && C_DIN_WIDTH == C_DOUT_WIDTH) begin
if (tmp_ecc_err[1]) begin // Corrupt the output data only for double bit error
if (C_DOUT_WIDTH == 1) begin
$display("FAILURE : Data width must be >= 2 for double bit error injection.");
$finish;
end else if (C_DOUT_WIDTH == 2)
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2]};
else
tmp_dout = {~tmp_dout[C_DOUT_WIDTH-1],~tmp_dout[C_DOUT_WIDTH-2],(tmp_dout << 2)};
end else begin
tmp_dout = tmp_dout[C_DOUT_WIDTH-1:0];
end
err_type <= {tmp_ecc_err[1], tmp_ecc_err[0] & !tmp_ecc_err[1]};
end else begin
err_type <= 0;
end
// input is wider than output
end else begin
rd_ptr_high = rd_ptr >> log2_reads_per_write;
rd_ptr_low = rd_ptr & (reads_per_write - 1);
memory_read = memory[rd_ptr_high];
tmp_dout = memory_read >> (rd_ptr_low*C_DOUT_WIDTH);
end
ideal_dout <= tmp_dout;
// (Works opposite to core: rd_ptr is a DOWN counter)
if (rd_ptr == 0) begin
rd_ptr <= C_RD_DEPTH - 1;
end else begin
rd_ptr <= rd_ptr - 1;
end
end
endtask
/*************************************************************************
* Initialize Signals for clean power-on simulation
*************************************************************************/
initial begin
num_wr_bits = 0;
num_rd_bits = 0;
next_num_wr_bits = 0;
next_num_rd_bits = 0;
rd_ptr = C_RD_DEPTH - 1;
wr_ptr = C_WR_DEPTH - 1;
wr_pntr = 0;
rd_pntr = 0;
rd_ptr_wrclk = rd_ptr;
wr_ptr_rdclk = wr_ptr;
dout_reset_val = hexstr_conv(C_DOUT_RST_VAL);
ideal_dout = dout_reset_val;
err_type = 0;
err_type_d1 = 0;
err_type_both = 0;
ideal_dout_d1 = dout_reset_val;
ideal_dout_both = dout_reset_val;
ideal_wr_ack = 1'b0;
ideal_valid = 1'b0;
valid_d1 = 1'b0;
valid_both = 1'b0;
ideal_overflow = C_OVERFLOW_LOW;
ideal_underflow = C_UNDERFLOW_LOW;
ideal_wr_count = 0;
ideal_rd_count = 0;
ideal_prog_full = 1'b0;
ideal_prog_empty = 1'b1;
end
/*************************************************************************
* Connect the module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_NEGATE;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_ASSERT;
wire [C_WR_PNTR_WIDTH-1:0] PROG_FULL_THRESH_NEGATE;
wire RD_EN;
wire RST;
wire WR_EN;
*/
// Assign ALMOST_EPMTY
generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae
assign ALMOST_EMPTY = almost_empty_i;
end else begin : gnae
assign ALMOST_EMPTY = 0;
end endgenerate // gae
// Assign ALMOST_FULL
generate if (C_HAS_ALMOST_FULL==1) begin : gaf
assign ALMOST_FULL = almost_full_i;
end else begin : gnaf
assign ALMOST_FULL = 0;
end endgenerate // gaf
// Dout may change behavior based on latency
localparam C_FWFT_ENABLED = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign fwft_enabled = (C_PRELOAD_LATENCY == 0 && C_PRELOAD_REGS == 1)?
1: 0;
assign ideal_dout_out= ((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1))?
ideal_dout_d1: ideal_dout;
assign DOUT = ideal_dout_out;
// Assign SBITERR and DBITERR based on latency
assign SBITERR = (C_ERROR_INJECTION_TYPE == 1 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[0]: err_type[0];
assign DBITERR = (C_ERROR_INJECTION_TYPE == 2 || C_ERROR_INJECTION_TYPE == 3) &&
((C_USE_EMBEDDED_REG>0 && (fwft_enabled == 0)) &&
(C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1)) ?
err_type_d1[1]: err_type[1];
assign EMPTY = empty_i;
assign FULL = full_i;
//saftey_ckt with one register
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && (C_USE_EMBEDDED_REG == 1 || C_USE_EMBEDDED_REG == 2 )) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK)
begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK)
begin
if( rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end
else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
valid_d1 <= #`TCQ valid_i;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK)
begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end
else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (ram_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1[0] <= #`TCQ err_type[0];
err_type_d1[1] <= #`TCQ err_type[1];
end
end
end //if
endgenerate
//safety ckt with both registers
generate
if ((C_MEMORY_TYPE==0 || C_MEMORY_TYPE==1) && C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge CLK) begin
rst_delayed_sft1 <= #`TCQ rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always@(posedge rst_delayed_sft2 or posedge rst_i or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1 || rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
valid_d1 <= #`TCQ 1'b0;
end else begin
ram_rd_en_d1 <= #`TCQ (RD_EN && ~(empty_i));
fab_rd_en_d1 <= #`TCQ ram_rd_en_d1;
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
always@(posedge rst_delayed_sft2 or posedge CLK) begin
if (rst_delayed_sft2 == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else if (srst_rrst_busy == 1'b1) begin
if (C_USE_DOUT_RST == 1'b1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both[0] <= #`TCQ err_type[0];
err_type_both[1] <= #`TCQ err_type[1];
end
if (fab_rd_en_d1) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1[0] <= #`TCQ err_type_both[0];
err_type_d1[1] <= #`TCQ err_type_both[1];
end
end
end
end //if
endgenerate
//Overflow may be active-low
generate if (C_HAS_OVERFLOW==1) begin : gof
assign OVERFLOW = ideal_overflow ? !C_OVERFLOW_LOW : C_OVERFLOW_LOW;
end else begin : gnof
assign OVERFLOW = 0;
end endgenerate // gof
assign PROG_EMPTY = prog_empty_i;
assign PROG_FULL = prog_full_i;
//Valid may change behavior based on latency or active-low
generate if (C_HAS_VALID==1) begin : gvalid
assign valid_i = (C_PRELOAD_LATENCY == 0) ? (RD_EN & ~EMPTY) : ideal_valid;
assign valid_out = (C_PRELOAD_LATENCY == 2 && C_MEMORY_TYPE < 2) ?
valid_d1 : valid_i;
assign VALID = valid_out ? !C_VALID_LOW : C_VALID_LOW;
end else begin : gnvalid
assign VALID = 0;
end endgenerate // gvalid
//Trim data count differently depending on set widths
generate if (C_HAS_DATA_COUNT == 1) begin : gdc
always @* begin
diff_count <= wr_pntr - rd_pntr;
if (C_DATA_COUNT_WIDTH > C_RD_PNTR_WIDTH) begin
DATA_COUNT[C_RD_PNTR_WIDTH-1:0] <= diff_count;
DATA_COUNT[C_DATA_COUNT_WIDTH-1] <= 1'b0 ;
end else begin
DATA_COUNT <= diff_count[C_RD_PNTR_WIDTH-1:C_RD_PNTR_WIDTH-C_DATA_COUNT_WIDTH];
end
end
// end else begin : gndc
// always @* DATA_COUNT <= 0;
end endgenerate // gdc
//Underflow may change behavior based on latency or active-low
generate if (C_HAS_UNDERFLOW==1) begin : guf
assign underflow_i = ideal_underflow;
assign UNDERFLOW = underflow_i ? !C_UNDERFLOW_LOW : C_UNDERFLOW_LOW;
end else begin : gnuf
assign UNDERFLOW = 0;
end endgenerate // guf
//Write acknowledge may be active low
generate if (C_HAS_WR_ACK==1) begin : gwr_ack
assign WR_ACK = ideal_wr_ack ? !C_WR_ACK_LOW : C_WR_ACK_LOW;
end else begin : gnwr_ack
assign WR_ACK = 0;
end endgenerate // gwr_ack
/*****************************************************************************
* Internal reset logic
****************************************************************************/
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_WR_RST : C_HAS_SRST ? (SRST | WR_RST_BUSY) : 0;
assign rst_i = C_HAS_RST ? RST : 0;
assign srst_wrst_busy = srst_i;
assign srst_rrst_busy = srst_i;
/**************************************************************************
* Assorted registers for delayed versions of signals
**************************************************************************/
//Capture delayed version of valid
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG <3)) begin : blockVL20
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
end else begin
valid_d1 <= #`TCQ valid_i;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
generate if (C_HAS_VALID == 1 && (C_USE_EMBEDDED_REG == 3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
valid_d1 <= 1'b0;
valid_both <= 1'b0;
end else begin
if (srst_rrst_busy) begin
valid_d1 <= #`TCQ 1'b0;
valid_both <= #`TCQ 1'b0;
end else begin
valid_both <= #`TCQ valid_i;
valid_d1 <= #`TCQ valid_both;
end
end
end // always @ (posedge CLK or posedge rst_i)
end
endgenerate // blockVL20
// Determine which stage in FWFT registers are valid
reg stage1_valid = 0;
reg stage2_valid = 0;
generate
if (C_PRELOAD_LATENCY == 0) begin : grd_fwft_proc
always @ (posedge CLK or posedge rst_i) begin
if (rst_i) begin
stage1_valid <= #`TCQ 0;
stage2_valid <= #`TCQ 0;
end else begin
if (!stage1_valid && !stage2_valid) begin
if (!EMPTY)
stage1_valid <= #`TCQ 1'b1;
else
stage1_valid <= #`TCQ 1'b0;
end else if (stage1_valid && !stage2_valid) begin
if (EMPTY) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else if (!stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b0;
end else if (!EMPTY && !RD_EN) begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end
end else if (stage1_valid && stage2_valid) begin
if (EMPTY && RD_EN) begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b1;
end else begin
stage1_valid <= #`TCQ 1'b1;
stage2_valid <= #`TCQ 1'b1;
end
end else begin
stage1_valid <= #`TCQ 1'b0;
stage2_valid <= #`TCQ 1'b0;
end
end // rd_rst_i
end // always
end
endgenerate
//***************************************************************************
// Assign the read data count value only if it is selected,
// otherwise output zeros.
//***************************************************************************
generate
if (C_HAS_RD_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT ==1) begin : grdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = rd_data_count_i_ss[C_RD_PNTR_WIDTH:C_RD_PNTR_WIDTH+1-C_RD_DATA_COUNT_WIDTH];
end
endgenerate
generate
if (C_HAS_RD_DATA_COUNT == 0) begin : gnrdc
assign RD_DATA_COUNT[C_RD_DATA_COUNT_WIDTH-1:0] = {C_RD_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//***************************************************************************
// Assign the write data count value only if it is selected,
// otherwise output zeros
//***************************************************************************
generate
if (C_HAS_WR_DATA_COUNT == 1 && C_USE_FWFT_DATA_COUNT == 1) begin : gwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = wr_data_count_i_ss[C_WR_PNTR_WIDTH:C_WR_PNTR_WIDTH+1-C_WR_DATA_COUNT_WIDTH] ;
end
endgenerate
generate
if (C_HAS_WR_DATA_COUNT == 0) begin : gnwdc
assign WR_DATA_COUNT[C_WR_DATA_COUNT_WIDTH-1:0] = {C_WR_DATA_COUNT_WIDTH{1'b0}};
end
endgenerate
//reg ram_rd_en_d1 = 1'b0;
//Capture delayed version of dout
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG<3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
ram_rd_en_d1 <= #`TCQ 1'b0;
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
if (ram_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout;
err_type_d1 <= #`TCQ err_type;
end
end
end
end // always
end
endgenerate
//no safety ckt with both registers
generate if (C_EN_SAFETY_CKT == 0 && (C_USE_EMBEDDED_REG==3)) begin
always @(posedge CLK or posedge rst_i) begin
if (rst_i == 1'b1) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// DRAM and SRAM reset asynchronously
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
@(posedge CLK)
ideal_dout_d1 <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end else begin
if (srst_rrst_busy) begin
ram_rd_en_d1 <= #`TCQ 1'b0;
fab_rd_en_d1 <= #`TCQ 1'b0;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
// Reset DRAM and SRAM based FIFO, BRAM based FIFO is reset above
if ((C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3) && C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
if (C_USE_DOUT_RST == 1) begin
ideal_dout_d1 <= #`TCQ dout_reset_val;
end
end else begin
ram_rd_en_d1 <= #`TCQ RD_EN & ~EMPTY;
fab_rd_en_d1 <= #`TCQ (ram_rd_en_d1);
if (ram_rd_en_d1 ) begin
ideal_dout_both <= #`TCQ ideal_dout;
err_type_both <= #`TCQ err_type;
end
if (fab_rd_en_d1 ) begin
ideal_dout_d1 <= #`TCQ ideal_dout_both;
err_type_d1 <= #`TCQ err_type_both;
end
end
end
end // always
end
endgenerate
/**************************************************************************
* Overflow and Underflow Flag calculation
* (handled separately because they don't support rst)
**************************************************************************/
generate if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 0) begin : g7s_ovflw
always @(posedge CLK) begin
ideal_overflow <= #`TCQ WR_EN & full_i;
end
end else if (C_HAS_OVERFLOW == 1 && IS_8SERIES == 1) begin : g8s_ovflw
always @(posedge CLK) begin
//ideal_overflow <= #`TCQ WR_EN & (rst_i | full_i);
ideal_overflow <= #`TCQ WR_EN & (WR_RST_BUSY | full_i);
end
end endgenerate // blockOF20
generate if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 0) begin : g7s_unflw
always @(posedge CLK) begin
ideal_underflow <= #`TCQ empty_i & RD_EN;
end
end else if (C_HAS_UNDERFLOW == 1 && IS_8SERIES == 1) begin : g8s_unflw
always @(posedge CLK) begin
//ideal_underflow <= #`TCQ (rst_i | empty_i) & RD_EN;
ideal_underflow <= #`TCQ (RD_RST_BUSY | empty_i) & RD_EN;
end
end endgenerate // blockUF20
/**************************
* Read Data Count
*************************/
reg [31:0] num_read_words_dc;
reg [C_RD_DATA_COUNT_WIDTH-1:0] num_read_words_sized_i;
always @(num_rd_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//If using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain,
// and add two read words for FWFT stages
//This value is only a temporary value and not used in the code.
num_read_words_dc = (num_rd_bits/C_DOUT_WIDTH+2);
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH+1];
end else begin
//If not using extra logic for FWFT Data Counts,
// then scale FIFO contents to read domain.
//This value is only a temporary value and not used in the code.
num_read_words_dc = num_rd_bits/C_DOUT_WIDTH;
//Trim the read words for use with RD_DATA_COUNT
num_read_words_sized_i =
num_read_words_dc[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_RD_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/**************************
* Write Data Count
*************************/
reg [31:0] num_write_words_dc;
reg [C_WR_DATA_COUNT_WIDTH-1:0] num_write_words_sized_i;
always @(num_wr_bits) begin
if (C_USE_FWFT_DATA_COUNT) begin
//Calculate the Data Count value for the number of write words,
// when using First-Word Fall-Through with extra logic for Data
// Counts. This takes into consideration the number of words that
// are expected to be stored in the FWFT register stages (it always
// assumes they are filled).
//This value is scaled to the Write Domain.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//EXTRA_WORDS_DC is the number of words added to write_words
// due to FWFT.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? EXTRA_WORDS_DC : (((num_wr_bits-1)/C_DIN_WIDTH)+1) + EXTRA_WORDS_DC ;
//Trim the write words for use with WR_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH+1];
end else begin
//Calculate the Data Count value for the number of write words, when NOT
// using First-Word Fall-Through with extra logic for Data Counts. This
// calculates only the number of words in the internal FIFO.
//The expression (((A-1)/B))+1 divides A/B, but takes the
// ceiling of the result.
//This value is scaled to the Write Domain.
//When num_wr_bits==0, set the result manually to prevent
// division errors.
//This value is only a temporary value and not used in the code.
num_write_words_dc = (num_wr_bits==0) ? 0 : ((num_wr_bits-1)/C_DIN_WIDTH)+1;
//Trim the read words for use with RD_DATA_COUNT
num_write_words_sized_i =
num_write_words_dc[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_WR_DATA_COUNT_WIDTH];
end //if (C_USE_FWFT_DATA_COUNT)
end //always
/*************************************************************************
* Write and Read Logic
************************************************************************/
wire write_allow;
wire read_allow;
wire read_allow_dc;
wire write_only;
wire read_only;
//wire write_only_q;
reg write_only_q;
//wire read_only_q;
reg read_only_q;
reg full_reg;
reg rst_full_ff_reg1;
reg rst_full_ff_reg2;
wire ram_full_comb;
wire carry;
assign write_allow = WR_EN & ~full_i;
assign read_allow = RD_EN & ~empty_i;
assign read_allow_dc = RD_EN_USER & ~USER_EMPTY_FB;
//assign write_only = write_allow & ~read_allow;
//assign write_only_q = write_allow_q;
//assign read_only = read_allow & ~write_allow;
//assign read_only_q = read_allow_q ;
wire [C_WR_PNTR_WIDTH-1:0] diff_pntr;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg1 = 0;
reg [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_reg1 = 0;
reg [C_RD_PNTR_WIDTH:0] diff_pntr_pe_asym = 0;
wire [C_RD_PNTR_WIDTH:0] adj_wr_pntr_rd_asym ;
wire [C_RD_PNTR_WIDTH:0] rd_pntr_asym;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_reg2 = 0;
reg [C_WR_PNTR_WIDTH-1:0] diff_pntr_pe_reg2 = 0;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_pe_max;
wire [C_RD_PNTR_WIDTH-1:0] diff_pntr_max;
assign diff_pntr_pe_max = DIFF_MAX_RD;
assign diff_pntr_max = DIFF_MAX_WR;
generate if (IS_ASYMMETRY == 0) begin : diff_pntr_sym
assign write_only = write_allow & ~read_allow;
assign read_only = read_allow & ~write_allow;
end endgenerate
generate if ( IS_ASYMMETRY == 1 && C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : wr_grt_rd
assign read_only = read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]) & ~write_allow;
assign write_only = write_allow & ~(read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (IS_ASYMMETRY ==1 && C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : rd_grt_wr
assign read_only = read_allow & ~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
assign write_only = write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]) & ~read_allow;
end endgenerate
//-----------------------------------------------------------------------------
// Write and Read pointer generation
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
wr_pntr <= 0;
rd_pntr <= 0;
end else begin
if (srst_i) begin
wr_pntr <= #`TCQ 0;
rd_pntr <= #`TCQ 0;
end else begin
if (write_allow) wr_pntr <= #`TCQ wr_pntr + 1;
if (read_allow) rd_pntr <= #`TCQ rd_pntr + 1;
end
end
end
generate if (C_FIFO_TYPE == 2) begin : gll_dm_dout
always @(posedge CLK) begin
if (write_allow) begin
if (ENABLE_ERR_INJECTION == 1)
memory[wr_pntr] <= #`TCQ {INJECTDBITERR,INJECTSBITERR,DIN};
else
memory[wr_pntr] <= #`TCQ DIN;
end
end
reg [C_DATA_WIDTH-1:0] dout_tmp_q;
reg [C_DATA_WIDTH-1:0] dout_tmp = 0;
reg [C_DATA_WIDTH-1:0] dout_tmp1 = 0;
always @(posedge CLK) begin
dout_tmp_q <= #`TCQ ideal_dout;
end
always @* begin
if (read_allow)
ideal_dout <= memory[rd_pntr];
else
ideal_dout <= dout_tmp_q;
end
end endgenerate // gll_dm_dout
/**************************************************************************
* Write Domain Logic
**************************************************************************/
assign ram_rd_en = RD_EN & !EMPTY;
//reg [C_WR_PNTR_WIDTH-1:0] diff_pntr = 0;
generate if (C_FIFO_TYPE != 2) begin : gnll_din
always @(posedge CLK or posedge rst_i) begin : gen_fifo_w
/****** Reset fifo (case 1)***************************************/
if (rst_i == 1'b1) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin //rst_i==0
if (srst_wrst_busy) begin
num_wr_bits <= #`TCQ 0;
next_num_wr_bits = #`TCQ 0;
wr_ptr <= #`TCQ C_WR_DEPTH - 1;
rd_ptr_wrclk <= #`TCQ C_RD_DEPTH - 1;
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ 0;
tmp_wr_listsize = #`TCQ 0;
rd_ptr_wrclk_next <= #`TCQ 0;
wr_pntr <= #`TCQ 0;
wr_pntr_rd1 <= #`TCQ 0;
end else begin//srst_i=0
wr_pntr_rd1 <= #`TCQ wr_pntr;
//Determine the current number of words in the FIFO
tmp_wr_listsize = (C_DEPTH_RATIO_RD > 1) ? num_wr_bits/C_DOUT_WIDTH :
num_wr_bits/C_DIN_WIDTH;
rd_ptr_wrclk_next = rd_ptr;
if (rd_ptr_wrclk < rd_ptr_wrclk_next) begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk + C_RD_DEPTH
- rd_ptr_wrclk_next);
end else begin
next_num_wr_bits = num_wr_bits -
C_DOUT_WIDTH*(rd_ptr_wrclk - rd_ptr_wrclk_next);
end
if (WR_EN == 1'b1) begin
if (FULL == 1'b1) begin
ideal_wr_ack <= #`TCQ 0;
//Reminder that FIFO is still full
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end else begin
write_fifo;
next_num_wr_bits = next_num_wr_bits + C_DIN_WIDTH;
//Write successful, so issue acknowledge
// and no error
ideal_wr_ack <= #`TCQ 1;
//Not even close to full.
ideal_wr_count <= num_write_words_sized_i;
//end
end
end else begin //(WR_EN == 1'b1)
//If user did not attempt a write, then do not
// give ack or err
ideal_wr_ack <= #`TCQ 0;
ideal_wr_count <= #`TCQ num_write_words_sized_i;
end
num_wr_bits <= #`TCQ next_num_wr_bits;
rd_ptr_wrclk <= #`TCQ rd_ptr;
end //srst_i==0
end //wr_rst_i==0
end // gen_fifo_w
end endgenerate
generate if (C_FIFO_TYPE < 2 && C_MEMORY_TYPE < 2) begin : gnll_dm_dout
always @(posedge CLK) begin
if (rst_i || srst_rrst_busy) begin
if (C_USE_DOUT_RST == 1) begin
ideal_dout <= #`TCQ dout_reset_val;
ideal_dout_both <= #`TCQ dout_reset_val;
end
end
end
end endgenerate
generate if (C_FIFO_TYPE != 2) begin : gnll_dout
always @(posedge CLK or posedge rst_i) begin : gen_fifo_r
/****** Reset fifo (case 1)***************************************/
if (rst_i) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets asynchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= 0;
err_type_both <= 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end else begin //rd_rst_i==0
if (srst_rrst_busy) begin
num_rd_bits <= #`TCQ 0;
next_num_rd_bits = #`TCQ 0;
rd_ptr <= #`TCQ C_RD_DEPTH -1;
rd_pntr <= #`TCQ 0;
//rd_pntr_wr1 <= #`TCQ 0;
wr_ptr_rdclk <= #`TCQ C_WR_DEPTH -1;
// DRAM resets synchronously
if (C_FIFO_TYPE < 2 && (C_MEMORY_TYPE == 2 || C_MEMORY_TYPE == 3 )&& C_USE_DOUT_RST == 1)
ideal_dout <= #`TCQ dout_reset_val;
// Reset err_type only if ECC is not selected
if (C_USE_ECC == 0) begin
err_type <= #`TCQ 0;
err_type_d1 <= #`TCQ 0;
err_type_both <= #`TCQ 0;
end
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ 0;
end //srst_i
else begin
//rd_pntr_wr1 <= #`TCQ rd_pntr;
//Determine the current number of words in the FIFO
tmp_rd_listsize = (C_DEPTH_RATIO_WR > 1) ? num_rd_bits/C_DIN_WIDTH :
num_rd_bits/C_DOUT_WIDTH;
wr_ptr_rdclk_next = wr_ptr;
if (wr_ptr_rdclk < wr_ptr_rdclk_next) begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk +C_WR_DEPTH
- wr_ptr_rdclk_next);
end else begin
next_num_rd_bits = num_rd_bits +
C_DIN_WIDTH*(wr_ptr_rdclk - wr_ptr_rdclk_next);
end
if (RD_EN == 1'b1) begin
if (EMPTY == 1'b1) begin
ideal_valid <= #`TCQ 1'b0;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end
else
begin
read_fifo;
next_num_rd_bits = next_num_rd_bits - C_DOUT_WIDTH;
//Acknowledge the read from the FIFO, no error
ideal_valid <= #`TCQ 1'b1;
ideal_rd_count <= #`TCQ num_read_words_sized_i;
end // if (tmp_rd_listsize == 2)
end
num_rd_bits <= #`TCQ next_num_rd_bits;
wr_ptr_rdclk <= #`TCQ wr_ptr;
end //s_rst_i==0
end //rd_rst_i==0
end //always
end endgenerate
//-----------------------------------------------------------------------------
// Generate diff_pntr for PROG_FULL generation
// Generate diff_pntr_pe for PROG_EMPTY generation
//-----------------------------------------------------------------------------
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 0) begin : reg_write_allow
always @(posedge CLK ) begin
if (rst_i) begin
write_only_q <= 1'b0;
read_only_q <= 1'b0;
diff_pntr_reg1 <= 0;
diff_pntr_pe_reg1 <= 0;
diff_pntr_reg2 <= 0;
diff_pntr_pe_reg2 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_rrst_busy) begin
read_only_q <= #`TCQ 1'b0;
diff_pntr_pe_reg1 <= #`TCQ 0;
diff_pntr_pe_reg2 <= #`TCQ 0;
end
if (srst_wrst_busy) begin
write_only_q <= #`TCQ 1'b0;
diff_pntr_reg1 <= #`TCQ 0;
diff_pntr_reg2 <= #`TCQ 0;
end
end else begin
write_only_q <= #`TCQ write_only;
read_only_q <= #`TCQ read_only;
diff_pntr_reg2 <= #`TCQ diff_pntr_reg1;
diff_pntr_pe_reg2 <= #`TCQ diff_pntr_pe_reg1;
// Add 1 to the difference pointer value when only write happens.
if (write_only)
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr + 1;
else
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
// Add 1 to the difference pointer value when write or both write & read or no write & read happen.
if (read_only)
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr - 1;
else
diff_pntr_pe_reg1 <= #`TCQ adj_wr_pntr_rd - rd_pntr;
end
end
end
assign diff_pntr_pe = diff_pntr_pe_reg1;
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow
generate if ((C_PROG_FULL_TYPE != 0 || C_PROG_EMPTY_TYPE != 0) && IS_ASYMMETRY == 1) begin : reg_write_allow_asym
assign adj_wr_pntr_rd_asym[C_RD_PNTR_WIDTH:0] = {adj_wr_pntr_rd,1'b1};
assign rd_pntr_asym[C_RD_PNTR_WIDTH:0] = {~rd_pntr,1'b1};
always @(posedge CLK ) begin
if (rst_i) begin
diff_pntr_pe_asym <= 0;
diff_pntr_reg1 <= 0;
full_reg <= 0;
rst_full_ff_reg1 <= 1;
rst_full_ff_reg2 <= 1;
diff_pntr_pe_reg1 <= 0;
end else begin
if (srst_i || srst_wrst_busy || srst_rrst_busy) begin
if (srst_wrst_busy)
diff_pntr_reg1 <= #`TCQ 0;
if (srst_rrst_busy)
full_reg <= #`TCQ 0;
rst_full_ff_reg1 <= #`TCQ 1;
rst_full_ff_reg2 <= #`TCQ 1;
diff_pntr_pe_asym <= #`TCQ 0;
diff_pntr_pe_reg1 <= #`TCQ 0;
end else begin
diff_pntr_pe_asym <= #`TCQ adj_wr_pntr_rd_asym + rd_pntr_asym;
full_reg <= #`TCQ full_i;
rst_full_ff_reg1 <= #`TCQ RST_FULL_FF;
rst_full_ff_reg2 <= #`TCQ rst_full_ff_reg1;
if (~full_i) begin
diff_pntr_reg1 <= #`TCQ wr_pntr - adj_rd_pntr_wr;
end
end
end
end
assign carry = (~(|(diff_pntr_pe_asym [C_RD_PNTR_WIDTH : 1])));
assign diff_pntr_pe = (full_reg && ~rst_full_ff_reg2 && carry ) ? diff_pntr_pe_max : diff_pntr_pe_asym[C_RD_PNTR_WIDTH:1];
assign diff_pntr = diff_pntr_reg1;
end endgenerate // reg_write_allow_asym
//-----------------------------------------------------------------------------
// Generate FULL flag
//-----------------------------------------------------------------------------
wire comp0;
wire comp1;
wire going_full;
wire leaving_full;
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gpad
assign adj_rd_pntr_wr [C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH] = rd_pntr;
assign adj_rd_pntr_wr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_WR_PNTR_WIDTH <= C_RD_PNTR_WIDTH) begin : gtrim
assign adj_rd_pntr_wr = rd_pntr[C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
assign comp1 = (adj_rd_pntr_wr == (wr_pntr + 1'b1));
assign comp0 = (adj_rd_pntr_wr == wr_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gf_wp_eq_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full = (comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gf_asym
assign going_full = (comp1 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_full = (comp0 & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gf_wp_gt_rp
assign going_full = (comp1 & write_allow & ~read_allow);
assign leaving_full =(comp0 & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_full_comb = going_full | (~leaving_full & full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
full_i <= #`TCQ ram_full_comb;
end
//-----------------------------------------------------------------------------
// Generate EMPTY flag
//-----------------------------------------------------------------------------
wire ecomp0;
wire ecomp1;
wire going_empty;
wire leaving_empty;
wire ram_empty_comb;
generate if (C_RD_PNTR_WIDTH > C_WR_PNTR_WIDTH) begin : pad
assign adj_wr_pntr_rd [C_RD_PNTR_WIDTH-1 : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH] = wr_pntr;
assign adj_wr_pntr_rd[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0] = 0;
end endgenerate
generate if (C_RD_PNTR_WIDTH <= C_WR_PNTR_WIDTH) begin : trim
assign adj_wr_pntr_rd = wr_pntr[C_WR_PNTR_WIDTH-1 : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
assign ecomp1 = (adj_wr_pntr_rd == (rd_pntr + 1'b1));
assign ecomp0 = (adj_wr_pntr_rd == rd_pntr);
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : ge_wp_eq_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty = (ecomp0 & write_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : ge_wp_gt_rp
assign going_empty = (ecomp1 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_empty = (ecomp0 & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : ge_wp_lt_rp
assign going_empty = (ecomp1 & ~write_allow & read_allow);
assign leaving_empty =(ecomp0 & write_allow);
end endgenerate
assign ram_empty_comb = going_empty | (~leaving_empty & empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
empty_i <= 1'b1;
else if (srst_rrst_busy)
empty_i <= #`TCQ 1'b1;
else
empty_i <= #`TCQ ram_empty_comb;
end
always @(posedge CLK or posedge rst_i) begin
if (rst_i && C_EN_SAFETY_CKT == 0) begin
EMPTY_FB <= 1'b1;
end else begin
if (srst_rrst_busy || (SAFETY_CKT_WR_RST && C_EN_SAFETY_CKT))
EMPTY_FB <= #`TCQ 1'b1;
else
EMPTY_FB <= #`TCQ ram_empty_comb;
end
end // always
//-----------------------------------------------------------------------------
// Generate Read and write data counts for asymmetic common clock
//-----------------------------------------------------------------------------
reg [C_GRTR_PNTR_WIDTH :0] count_dc = 0;
wire [C_GRTR_PNTR_WIDTH :0] ratio;
wire decr_by_one;
wire incr_by_ratio;
wire incr_by_one;
wire decr_by_ratio;
localparam IS_FWFT = (C_PRELOAD_REGS == 1 && C_PRELOAD_LATENCY == 0) ? 1 : 0;
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : rd_depth_gt_wr
assign ratio = C_DEPTH_RATIO_RD;
assign decr_by_one = (IS_FWFT == 1)? read_allow_dc : read_allow;
assign incr_by_ratio = write_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (decr_by_one) begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc - 1;
else
count_dc <= #`TCQ count_dc - 1 + ratio ;
end
else begin
if (!incr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc + ratio ;
end
end
end
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc;
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc[C_RD_PNTR_WIDTH : C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH];
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : wr_depth_gt_rd
assign ratio = C_DEPTH_RATIO_WR;
assign incr_by_one = write_allow;
assign decr_by_ratio = (IS_FWFT == 1)? read_allow_dc : read_allow;
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
count_dc <= #`TCQ 0;
else if (srst_wrst_busy)
count_dc <= #`TCQ 0;
else begin
if (incr_by_one) begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc + 1;
else
count_dc <= #`TCQ count_dc + 1 - ratio ;
end
else begin
if (!decr_by_ratio)
count_dc <= #`TCQ count_dc ;
else
count_dc <= #`TCQ count_dc - ratio ;
end
end
end
assign wr_data_count_i_ss[C_WR_PNTR_WIDTH : 0] = count_dc;
assign rd_data_count_i_ss[C_RD_PNTR_WIDTH : 0] = count_dc[C_WR_PNTR_WIDTH : C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH];
end endgenerate
//-----------------------------------------------------------------------------
// Generate WR_ACK flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_wr_ack <= 1'b0;
else if (srst_wrst_busy)
ideal_wr_ack <= #`TCQ 1'b0;
else if (WR_EN & ~full_i)
ideal_wr_ack <= #`TCQ 1'b1;
else
ideal_wr_ack <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate VALID flag
//-----------------------------------------------------------------------------
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
ideal_valid <= 1'b0;
else if (srst_rrst_busy)
ideal_valid <= #`TCQ 1'b0;
else if (RD_EN & ~empty_i)
ideal_valid <= #`TCQ 1'b1;
else
ideal_valid <= #`TCQ 1'b0;
end
//-----------------------------------------------------------------------------
// Generate ALMOST_FULL flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_FULL == 1 || C_PROG_FULL_TYPE > 2 || C_PROG_EMPTY_TYPE > 2) begin : gaf_ss
wire fcomp2;
wire going_afull;
wire leaving_afull;
wire ram_afull_comb;
assign fcomp2 = (adj_rd_pntr_wr == (wr_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gaf_wp_eq_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull = (comp1 & read_allow & ~write_allow) | RST_FULL_GEN;
end endgenerate
// Write data width is bigger than read data width
// Write depth is smaller than read depth
// One write could be equal to 2 or 4 or 8 reads
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gaf_asym
assign going_afull = (fcomp2 & write_allow & (~ (read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0]))));
assign leaving_afull = (comp1 & (~write_allow) & read_allow & &(rd_pntr[C_RD_PNTR_WIDTH-C_WR_PNTR_WIDTH-1 : 0])) | RST_FULL_GEN;
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gaf_wp_gt_rp
assign going_afull = (fcomp2 & write_allow & ~read_allow);
assign leaving_afull =((comp0 | comp1 | fcomp2) & read_allow) | RST_FULL_GEN;
end endgenerate
assign ram_afull_comb = going_afull | (~leaving_afull & almost_full_i);
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF)
almost_full_i <= C_FULL_FLAGS_RST_VAL;
else if (srst_wrst_busy)
almost_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else
almost_full_i <= #`TCQ ram_afull_comb;
end
// end endgenerate // gaf_ss
//-----------------------------------------------------------------------------
// Generate ALMOST_EMPTY flag
//-----------------------------------------------------------------------------
//generate if (C_HAS_ALMOST_EMPTY == 1) begin : gae_ss
wire ecomp2;
wire going_aempty;
wire leaving_aempty;
wire ram_aempty_comb;
assign ecomp2 = (adj_wr_pntr_rd == (rd_pntr + 2'h2));
generate if (C_WR_PNTR_WIDTH == C_RD_PNTR_WIDTH) begin : gae_wp_eq_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty = (ecomp1 & write_allow & ~read_allow);
end endgenerate
generate if (C_WR_PNTR_WIDTH > C_RD_PNTR_WIDTH) begin : gae_wp_gt_rp
assign going_aempty = (ecomp2 & read_allow & (~(write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]))));
assign leaving_aempty = (ecomp1 & ~read_allow & write_allow & &(wr_pntr[C_WR_PNTR_WIDTH-C_RD_PNTR_WIDTH-1 : 0]));
end endgenerate
generate if (C_WR_PNTR_WIDTH < C_RD_PNTR_WIDTH) begin : gae_wp_lt_rp
assign going_aempty = (ecomp2 & ~write_allow & read_allow);
assign leaving_aempty =((ecomp2 | ecomp1 |ecomp0) & write_allow);
end endgenerate
assign ram_aempty_comb = going_aempty | (~leaving_aempty & almost_empty_i);
always @(posedge CLK or posedge rst_i) begin
if (rst_i)
almost_empty_i <= 1'b1;
else if (srst_rrst_busy)
almost_empty_i <= #`TCQ 1'b1;
else
almost_empty_i <= #`TCQ ram_aempty_comb;
end
// end endgenerate // gae_ss
//-----------------------------------------------------------------------------
// Generate PROG_FULL
//-----------------------------------------------------------------------------
localparam C_PF_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_ASSERT_VAL - EXTRA_WORDS_PF_PARAM : // FWFT
C_PROG_FULL_THRESH_ASSERT_VAL; // STD
localparam C_PF_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_FULL_THRESH_NEGATE_VAL - EXTRA_WORDS_PF_PARAM: // FWFT
C_PROG_FULL_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold constant
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] temp = C_PF_ASSERT_VAL;
generate if (C_PROG_FULL_TYPE == 1) begin : single_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_ASSERT_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr>= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr) < C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b0;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate // single_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_FULL_TYPE == 2) begin : multiple_pf_const
always @(posedge CLK or posedge RST_FULL_FF) begin
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (diff_pntr == C_PF_ASSERT_VAL && write_only_q)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == C_PF_NEGATE_VAL && read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~RST_FULL_GEN ) begin
if (diff_pntr >= C_PF_ASSERT_VAL )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < C_PF_NEGATE_VAL)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_const
//-----------------------------------------------------------------------------
// Generate PROG_FULL for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf3_assert_val = (C_PRELOAD_LATENCY == 0) ?
PROG_FULL_THRESH - EXTRA_WORDS_PF: // FWFT
PROG_FULL_THRESH; // STD
generate if (C_PROG_FULL_TYPE == 3) begin : single_pf_input
always @(posedge CLK or posedge RST_FULL_FF) begin//0
//if (RST_FULL_FF)
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin //1
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin//2
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin//3
if (diff_pntr > pf3_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr == pf3_assert_val) begin//4
if (read_only_q)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ 1'b1;
end else//4
prog_full_i <= #`TCQ 1'b0;
end else//3
prog_full_i <= #`TCQ prog_full_i;
end //2
else begin//5
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin//6
if (diff_pntr >= pf3_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf3_assert_val) begin//7
prog_full_i <= #`TCQ 1'b0;
end//7
end//6
else
prog_full_i <= #`TCQ prog_full_i;
end//5
end//1
end//0
end endgenerate //single_pf_input
//-----------------------------------------------------------------------------
// Generate PROG_FULL for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_WR_PNTR_WIDTH-1:0] pf_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_ASSERT -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_ASSERT; // STD
wire [C_WR_PNTR_WIDTH-1:0] pf_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_FULL_THRESH_NEGATE -EXTRA_WORDS_PF) : // FWFT
PROG_FULL_THRESH_NEGATE; // STD
generate if (C_PROG_FULL_TYPE == 4) begin : multiple_pf_inputs
always @(posedge CLK or posedge RST_FULL_FF) begin
if (RST_FULL_FF && C_HAS_RST)
prog_full_i <= C_FULL_FLAGS_RST_VAL;
else begin
if (srst_wrst_busy)
prog_full_i <= #`TCQ C_FULL_FLAGS_RST_VAL;
else if (IS_ASYMMETRY == 0) begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~almost_full_i) begin
if (diff_pntr >= pf_assert_val)
prog_full_i <= #`TCQ 1'b1;
else if ((diff_pntr == pf_negate_val && read_only_q) ||
diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end else
prog_full_i <= #`TCQ prog_full_i;
end
else begin
if (RST_FULL_GEN)
prog_full_i <= #`TCQ 1'b0;
else if (~full_i ) begin
if (diff_pntr >= pf_assert_val )
prog_full_i <= #`TCQ 1'b1;
else if (diff_pntr < pf_negate_val)
prog_full_i <= #`TCQ 1'b0;
else
prog_full_i <= #`TCQ prog_full_i;
end
else
prog_full_i <= #`TCQ prog_full_i;
end
end
end
end endgenerate //multiple_pf_inputs
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY
//-----------------------------------------------------------------------------
localparam C_PE_ASSERT_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_ASSERT_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_ASSERT_VAL; // STD
localparam C_PE_NEGATE_VAL = (C_PRELOAD_LATENCY == 0) ?
C_PROG_EMPTY_THRESH_NEGATE_VAL - 2: // FWFT
C_PROG_EMPTY_THRESH_NEGATE_VAL; // STD
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold constant
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 1) begin : single_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_ASSERT_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_ASSERT_VAL)
prog_empty_i <= #`TCQ 1'b0;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold constants
//-----------------------------------------------------------------------------
generate if (C_PROG_EMPTY_TYPE == 2) begin : multiple_pe_const
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (diff_pntr_pe == C_PE_ASSERT_VAL && read_only_q)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == C_PE_NEGATE_VAL && write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (~rst_i ) begin
if (diff_pntr_pe <= C_PE_ASSERT_VAL )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > C_PE_NEGATE_VAL)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate //multiple_pe_const
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for single programmable threshold input port
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe3_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH -2) : // FWFT
PROG_EMPTY_THRESH; // STD
generate if (C_PROG_EMPTY_TYPE == 3) begin : single_pe_input
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe < pe3_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe == pe3_assert_val) begin
if (write_only_q)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ 1'b1;
end else
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe3_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe3_assert_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // single_pe_input
//-----------------------------------------------------------------------------
// Generate PROG_EMPTY for multiple programmable threshold input ports
//-----------------------------------------------------------------------------
wire [C_RD_PNTR_WIDTH-1:0] pe4_assert_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_ASSERT - 2) : // FWFT
PROG_EMPTY_THRESH_ASSERT; // STD
wire [C_RD_PNTR_WIDTH-1:0] pe4_negate_val = (C_PRELOAD_LATENCY == 0) ?
(PROG_EMPTY_THRESH_NEGATE - 2) : // FWFT
PROG_EMPTY_THRESH_NEGATE; // STD
generate if (C_PROG_EMPTY_TYPE == 4) begin : multiple_pe_inputs
always @(posedge CLK or posedge rst_i) begin
//if (rst_i)
if (rst_i && C_HAS_RST)
prog_empty_i <= 1'b1;
else begin
if (srst_rrst_busy)
prog_empty_i <= #`TCQ 1'b1;
else if (IS_ASYMMETRY == 0) begin
if (~almost_full_i) begin
if (diff_pntr_pe <= pe4_assert_val)
prog_empty_i <= #`TCQ 1'b1;
else if (((diff_pntr_pe == pe4_negate_val) && write_only_q) ||
(diff_pntr_pe > pe4_negate_val)) begin
prog_empty_i <= #`TCQ 1'b0;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end else
prog_empty_i <= #`TCQ prog_empty_i;
end
else begin
if (diff_pntr_pe <= pe4_assert_val )
prog_empty_i <= #`TCQ 1'b1;
else if (diff_pntr_pe > pe4_negate_val)
prog_empty_i <= #`TCQ 1'b0;
else
prog_empty_i <= #`TCQ prog_empty_i;
end
end
end
end endgenerate // multiple_pe_inputs
endmodule // fifo_generator_v13_1_3_bhv_ver_ss
/**************************************************************************
* First-Word Fall-Through module (preload 0)
**************************************************************************/
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG = 0,
parameter C_EN_SAFETY_CKT = 0,
parameter C_USE_DOUT_RST = 0,
parameter C_USE_ECC = 0,
parameter C_USERVALID_LOW = 0,
parameter C_USERUNDERFLOW_LOW = 0,
parameter C_MEMORY_TYPE = 0,
parameter C_FIFO_TYPE = 0
)
(
//Inputs
input SAFETY_CKT_RD_RST,
input RD_CLK,
input RD_RST,
input SRST,
input WR_RST_BUSY,
input RD_RST_BUSY,
input RD_EN,
input FIFOEMPTY,
input [C_DOUT_WIDTH-1:0] FIFODATA,
input FIFOSBITERR,
input FIFODBITERR,
//Outputs
output reg [C_DOUT_WIDTH-1:0] USERDATA,
output USERVALID,
output USERUNDERFLOW,
output USEREMPTY,
output USERALMOSTEMPTY,
output RAMVALID,
output FIFORDEN,
output reg USERSBITERR,
output reg USERDBITERR,
output reg STAGE2_REG_EN,
output fab_read_data_valid_i_o,
output read_data_valid_i_o,
output ram_valid_i_o,
output [1:0] VALID_STAGES
);
//Internal signals
wire preloadstage1;
wire preloadstage2;
reg ram_valid_i;
reg fab_valid;
reg read_data_valid_i;
reg fab_read_data_valid_i;
reg fab_read_data_valid_i_1;
reg ram_valid_i_d;
reg read_data_valid_i_d;
reg fab_read_data_valid_i_d;
wire ram_regout_en;
reg ram_regout_en_d1;
reg ram_regout_en_d2;
wire fab_regout_en;
wire ram_rd_en;
reg empty_i = 1'b1;
reg empty_sckt = 1'b1;
reg sckt_rrst_q = 1'b0;
reg sckt_rrst_done = 1'b0;
reg empty_q = 1'b1;
reg rd_en_q = 1'b0;
reg almost_empty_i = 1'b1;
reg almost_empty_q = 1'b1;
wire rd_rst_i;
wire srst_i;
reg [C_DOUT_WIDTH-1:0] userdata_both;
wire uservalid_both;
wire uservalid_one;
reg user_sbiterr_both = 1'b0;
reg user_dbiterr_both = 1'b0;
assign ram_valid_i_o = ram_valid_i;
assign read_data_valid_i_o = read_data_valid_i;
assign fab_read_data_valid_i_o = fab_read_data_valid_i;
/*************************************************************************
* FUNCTIONS
*************************************************************************/
/*************************************************************************
* hexstr_conv
* Converts a string of type hex to a binary value (for C_DOUT_RST_VAL)
***********************************************************************/
function [C_DOUT_WIDTH-1:0] hexstr_conv;
input [(C_DOUT_WIDTH*8)-1:0] def_data;
integer index,i,j;
reg [3:0] bin;
begin
index = 0;
hexstr_conv = 'b0;
for( i=C_DOUT_WIDTH-1; i>=0; i=i-1 )
begin
case (def_data[7:0])
8'b00000000 :
begin
bin = 4'b0000;
i = -1;
end
8'b00110000 : bin = 4'b0000;
8'b00110001 : bin = 4'b0001;
8'b00110010 : bin = 4'b0010;
8'b00110011 : bin = 4'b0011;
8'b00110100 : bin = 4'b0100;
8'b00110101 : bin = 4'b0101;
8'b00110110 : bin = 4'b0110;
8'b00110111 : bin = 4'b0111;
8'b00111000 : bin = 4'b1000;
8'b00111001 : bin = 4'b1001;
8'b01000001 : bin = 4'b1010;
8'b01000010 : bin = 4'b1011;
8'b01000011 : bin = 4'b1100;
8'b01000100 : bin = 4'b1101;
8'b01000101 : bin = 4'b1110;
8'b01000110 : bin = 4'b1111;
8'b01100001 : bin = 4'b1010;
8'b01100010 : bin = 4'b1011;
8'b01100011 : bin = 4'b1100;
8'b01100100 : bin = 4'b1101;
8'b01100101 : bin = 4'b1110;
8'b01100110 : bin = 4'b1111;
default :
begin
bin = 4'bx;
end
endcase
for( j=0; j<4; j=j+1)
begin
if ((index*4)+j < C_DOUT_WIDTH)
begin
hexstr_conv[(index*4)+j] = bin[j];
end
end
index = index + 1;
def_data = def_data >> 8;
end
end
endfunction
//*************************************************************************
// Set power-on states for regs
//*************************************************************************
initial begin
ram_valid_i = 1'b0;
fab_valid = 1'b0;
read_data_valid_i = 1'b0;
fab_read_data_valid_i = 1'b0;
fab_read_data_valid_i_1 = 1'b0;
USERDATA = hexstr_conv(C_DOUT_RST_VAL);
userdata_both = hexstr_conv(C_DOUT_RST_VAL);
USERSBITERR = 1'b0;
USERDBITERR = 1'b0;
user_sbiterr_both = 1'b0;
user_dbiterr_both = 1'b0;
end //initial
//***************************************************************************
// connect up optional reset
//***************************************************************************
assign rd_rst_i = (C_HAS_RST == 1 || C_ENABLE_RST_SYNC == 0) ? RD_RST : 0;
assign srst_i = C_EN_SAFETY_CKT ? SAFETY_CKT_RD_RST : C_HAS_SRST ? SRST : 0;
reg sckt_rd_rst_fwft = 1'b0;
reg fwft_rst_done_i = 1'b0;
wire fwft_rst_done;
assign fwft_rst_done = C_EN_SAFETY_CKT ? fwft_rst_done_i : 1'b1;
always @ (posedge RD_CLK) begin
sckt_rd_rst_fwft <= #`TCQ SAFETY_CKT_RD_RST;
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i)
fwft_rst_done_i <= 1'b0;
else if (sckt_rd_rst_fwft & ~SAFETY_CKT_RD_RST)
fwft_rst_done_i <= #`TCQ 1'b1;
end
localparam INVALID = 0;
localparam STAGE1_VALID = 2;
localparam STAGE2_VALID = 1;
localparam BOTH_STAGES_VALID = 3;
reg [1:0] curr_fwft_state = INVALID;
reg [1:0] next_fwft_state = INVALID;
generate if (C_USE_EMBEDDED_REG < 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = preloadstage2;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = (RD_EN & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
reg curr_state = 0;
reg next_state = 0;
reg leaving_empty_fwft = 0;
reg going_empty_fwft = 0;
reg empty_i_q = 0;
reg ram_rd_en_fwft = 0;
generate if (C_FIFO_TYPE == 2) begin : gll_fifo
always @* begin // FSM fo FWFT
case (curr_state)
1'b0: begin
if (~FIFOEMPTY)
next_state <= 1'b1;
else
next_state <= 1'b0;
end
1'b1: begin
if (FIFOEMPTY && RD_EN)
next_state <= 1'b0;
else
next_state <= 1'b1;
end
default: next_state <= 1'b0;
endcase
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_i <= 1'b1;
empty_i_q <= 1'b1;
ram_valid_i <= 1'b0;
end else if (srst_i) begin
empty_i <= #`TCQ 1'b1;
empty_i_q <= #`TCQ 1'b1;
ram_valid_i <= #`TCQ 1'b0;
end else begin
empty_i <= #`TCQ going_empty_fwft | (~leaving_empty_fwft & empty_i);
empty_i_q <= #`TCQ FIFOEMPTY;
ram_valid_i <= #`TCQ next_state;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0) begin
curr_state <= 1'b0;
end else if (srst_i) begin
curr_state <= #`TCQ 1'b0;
end else begin
curr_state <= #`TCQ next_state;
end
end //always
wire fe_of_empty;
assign fe_of_empty = empty_i_q & ~FIFOEMPTY;
always @* begin // Finding leaving empty
case (curr_state)
1'b0: leaving_empty_fwft <= fe_of_empty;
1'b1: leaving_empty_fwft <= 1'b1;
default: leaving_empty_fwft <= 1'b0;
endcase
end
always @* begin // Finding going empty
case (curr_state)
1'b1: going_empty_fwft <= FIFOEMPTY & RD_EN;
default: going_empty_fwft <= 1'b0;
endcase
end
always @* begin // Generating FWFT rd_en
case (curr_state)
1'b0: ram_rd_en_fwft <= ~FIFOEMPTY;
1'b1: ram_rd_en_fwft <= ~FIFOEMPTY & RD_EN;
default: ram_rd_en_fwft <= 1'b0;
endcase
end
assign ram_regout_en = ram_rd_en_fwft;
//assign ram_regout_en_d1 = ram_rd_en_fwft;
//assign ram_regout_en_d2 = ram_rd_en_fwft;
assign ram_rd_en = ram_rd_en_fwft;
end endgenerate // gll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false.
// Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2) begin : gnll_fifo_ram_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
ram_valid_i <= #`TCQ 1'b0;
end else begin
if (ram_rd_en == 1'b1) begin
ram_valid_i <= #`TCQ 1'b1;
end else begin
if (ram_regout_en == 1'b1)
ram_valid_i <= #`TCQ 1'b0;
else
ram_valid_i <= #`TCQ ram_valid_i;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_ram_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ ram_valid_i | (read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG < 3) begin : gnll_fifo_empty
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~ram_valid_i & ~read_data_valid_i) | (~ram_valid_i & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
generate if ( C_USE_EMBEDDED_REG < 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((ram_regout_en) | (~FIFOEMPTY & read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ FIFOEMPTY;
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
// BRAM resets synchronously
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG < 3) begin
always @ ( posedge rd_rst_i)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
//safety ckt with one register
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG < 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK)
begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
//@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end
else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1) begin
// @(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ FIFODATA;
USERSBITERR <= #`TCQ FIFOSBITERR;
USERDBITERR <= #`TCQ FIFODBITERR;
end
end
end
end //always
end //if
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 && C_FIFO_TYPE != 2) begin
always @* begin
case (curr_fwft_state)
INVALID: begin
if (~FIFOEMPTY)
next_fwft_state <= STAGE1_VALID;
else
next_fwft_state <= INVALID;
end
STAGE1_VALID: begin
if (FIFOEMPTY)
next_fwft_state <= STAGE2_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
STAGE2_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= INVALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE1_VALID;
else if (~FIFOEMPTY && ~RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= STAGE2_VALID;
end
BOTH_STAGES_VALID: begin
if (FIFOEMPTY && RD_EN)
next_fwft_state <= STAGE2_VALID;
else if (~FIFOEMPTY && RD_EN)
next_fwft_state <= BOTH_STAGES_VALID;
else
next_fwft_state <= BOTH_STAGES_VALID;
end
default: next_fwft_state <= INVALID;
endcase
end
always @ (posedge rd_rst_i or posedge RD_CLK) begin
if (rd_rst_i && C_EN_SAFETY_CKT == 0)
curr_fwft_state <= INVALID;
else if (srst_i)
curr_fwft_state <= #`TCQ INVALID;
else
curr_fwft_state <= #`TCQ next_fwft_state;
end
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay
if (rd_rst_i == 1) begin
ram_regout_en_d1 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d1 <= #`TCQ 1'b0;
else
ram_regout_en_d1 <= #`TCQ ram_regout_en;
end
end //always
// assign fab_regout_en = ((ram_regout_en_d1 & ~(ram_regout_en_d2) & empty_i) | (RD_EN & !empty_i));
assign fab_regout_en = ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b0 )? 1'b1: ((ram_valid_i == 1'b0 || ram_valid_i == 1'b1) && read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1) ? RD_EN : 1'b0;
always @ (posedge RD_CLK or posedge rd_rst_i) begin : proc_delay1
if (rd_rst_i == 1) begin
ram_regout_en_d2 <= #`TCQ 1'b0;
end
else begin
if (srst_i == 1'b1)
ram_regout_en_d2 <= #`TCQ 1'b0;
else
ram_regout_en_d2 <= #`TCQ ram_regout_en_d1;
end
end //always
always @* begin
case (curr_fwft_state)
INVALID: STAGE2_REG_EN <= 1'b0;
STAGE1_VALID: STAGE2_REG_EN <= 1'b1;
STAGE2_VALID: STAGE2_REG_EN <= 1'b0;
BOTH_STAGES_VALID: STAGE2_REG_EN <= RD_EN;
default: STAGE2_REG_EN <= 1'b0;
endcase
end
always @ (posedge RD_CLK) begin
ram_valid_i_d <= #`TCQ ram_valid_i;
read_data_valid_i_d <= #`TCQ read_data_valid_i;
fab_read_data_valid_i_d <= #`TCQ fab_read_data_valid_i;
end
assign VALID_STAGES = curr_fwft_state;
//***************************************************************************
// preloadstage2 indicates that stage2 needs to be updated. This is true
// whenever read_data_valid is false, and RAM_valid is true.
//***************************************************************************
assign preloadstage2 = ram_valid_i & (~read_data_valid_i | RD_EN );
//***************************************************************************
// preloadstage1 indicates that stage1 needs to be updated. This is true
// whenever the RAM has data (RAM_EMPTY is false), and either RAM_Valid is
// false (indicating that Stage1 needs updating), or preloadstage2 is active
// (indicating that Stage2 is going to update, so Stage1, therefore, must
// also be updated to keep it valid.
//***************************************************************************
assign preloadstage1 = ((~ram_valid_i | preloadstage2) & ~FIFOEMPTY);
//***************************************************************************
// Calculate RAM_REGOUT_EN
// The output registers are controlled by the ram_regout_en signal.
// These registers should be updated either when the output in Stage2 is
// invalid (preloadstage2), OR when the user is reading, in which case the
// Stage2 value will go invalid unless it is replenished.
//***************************************************************************
assign ram_regout_en = (ram_valid_i == 1'b1 && (read_data_valid_i == 1'b0 || fab_read_data_valid_i == 1'b0)) ? 1'b1 : (read_data_valid_i == 1'b1 && fab_read_data_valid_i == 1'b1 && ram_valid_i == 1'b1) ? RD_EN : 1'b0;
//***************************************************************************
// Calculate RAM_RD_EN
// RAM_RD_EN will be asserted whenever the RAM needs to be read in order to
// update the value in Stage1.
// One case when this happens is when preloadstage1=true, which indicates
// that the data in Stage1 or Stage2 is invalid, and needs to automatically
// be updated.
// The other case is when the user is reading from the FIFO, which
// guarantees that Stage1 or Stage2 will be invalid on the next clock
// cycle, unless it is replinished by data from the memory. So, as long
// as the RAM has data in it, a read of the RAM should occur.
//***************************************************************************
assign ram_rd_en = ((RD_EN | ~ fab_read_data_valid_i) & ~FIFOEMPTY) | preloadstage1;
end
endgenerate // gnll_fifo
//***************************************************************************
// Calculate RAMVALID_P0_OUT
// RAMVALID_P0_OUT indicates that the data in Stage1 is valid.
//
// If the RAM is being read from on this clock cycle (ram_rd_en=1), then
// RAMVALID_P0_OUT is certainly going to be true.
// If the RAM is not being read from, but the output registers are being
// updated to fill Stage2 (ram_regout_en=1), then Stage1 will be emptying,
// therefore causing RAMVALID_P0_OUT to be false // Otherwise, RAMVALID_P0_OUT will remain unchanged.
//***************************************************************************
// PROCESS regout_valid
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3) begin : gnll_fifo_fab_valid
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (srst_i) begin
// synchronous reset (active high)
fab_valid <= #`TCQ 1'b0;
end else begin
if (ram_regout_en == 1'b1) begin
fab_valid <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
fab_valid <= #`TCQ 1'b0;
else
fab_valid <= #`TCQ fab_valid;
end
end //srst_i
end //rd_rst_i
end //always
end endgenerate // gnll_fifo_fab_valid
//***************************************************************************
// Calculate READ_DATA_VALID
// READ_DATA_VALID indicates whether the value in Stage2 is valid or not.
// Stage2 has valid data whenever Stage1 had valid data and
// ram_regout_en_i=1, such that the data in Stage1 is propogated
// into Stage2.
//***************************************************************************
generate if(C_USE_EMBEDDED_REG == 3) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i)
read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
read_data_valid_i <= #`TCQ 1'b0;
else begin
if (ram_regout_en == 1'b1) begin
read_data_valid_i <= #`TCQ 1'b1;
end else begin
if (fab_regout_en == 1'b1)
read_data_valid_i <= #`TCQ 1'b0;
else
read_data_valid_i <= #`TCQ read_data_valid_i;
end
end
end //always
end
endgenerate
//generate if(C_USE_EMBEDDED_REG == 3) begin
// always @ (posedge RD_CLK or posedge rd_rst_i) begin
// if (rd_rst_i)
// read_data_valid_i <= #`TCQ 1'b0;
// else if (srst_i)
// read_data_valid_i <= #`TCQ 1'b0;
//
// if (ram_regout_en == 1'b1) begin
// fab_read_data_valid_i <= #`TCQ 1'b0;
// end else begin
// if (fab_regout_en == 1'b1)
// fab_read_data_valid_i <= #`TCQ 1'b1;
// else
// fab_read_data_valid_i <= #`TCQ fab_read_data_valid_i;
// end
// end //always
//end
//endgenerate
generate if(C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i) begin :fabout_dvalid
if (rd_rst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else if (srst_i)
fab_read_data_valid_i <= #`TCQ 1'b0;
else
fab_read_data_valid_i <= #`TCQ fab_valid | (fab_read_data_valid_i & ~RD_EN);
end //always
end
endgenerate
always @ (posedge RD_CLK ) begin : proc_del1
begin
fab_read_data_valid_i_1 <= #`TCQ fab_read_data_valid_i;
end
end //always
//**************************************************************************
// Calculate EMPTY
// Defined as the inverse of READ_DATA_VALID
//
// Description:
//
// If read_data_valid_i indicates that the output is not valid,
// and there is no valid data on the output of the ram to preload it
// with, then we will report empty.
//
// If there is no valid data on the output of the ram and we are
// reading, then the FIFO will go empty.
//
//**************************************************************************
generate if (C_FIFO_TYPE < 2 && C_USE_EMBEDDED_REG == 3 ) begin : gnll_fifo_empty_both
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
// asynchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
if (srst_i) begin
// synchronous reset (active high)
empty_i <= #`TCQ 1'b1;
end else begin
// rising clock edge
empty_i <= #`TCQ (~fab_valid & ~fab_read_data_valid_i) | (~fab_valid & RD_EN);
end
end
end //always
end endgenerate // gnll_fifo_empty_both
// Register RD_EN from user to calculate USERUNDERFLOW.
// Register empty_i to calculate USERUNDERFLOW.
always @ (posedge RD_CLK) begin
rd_en_q <= #`TCQ RD_EN;
empty_q <= #`TCQ empty_i;
end //always
//***************************************************************************
// Calculate user_almost_empty
// user_almost_empty is defined such that, unless more words are written
// to the FIFO, the next read will cause the FIFO to go EMPTY.
//
// In most cases, whenever the output registers are updated (due to a user
// read or a preload condition), then user_almost_empty will update to
// whatever RAM_EMPTY is.
//
// The exception is when the output is valid, the user is not reading, and
// Stage1 is not empty. In this condition, Stage1 will be preloaded from the
// memory, so we need to make sure user_almost_empty deasserts properly under
// this condition.
//***************************************************************************
reg FIFOEMPTY_1;
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @(posedge RD_CLK) begin
FIFOEMPTY_1 <= #`TCQ FIFOEMPTY;
end
end
endgenerate
generate if (C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin // asynchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin // rising clock edge
if (srst_i) begin // synchronous reset (active high)
almost_empty_i <= #`TCQ 1'b1;
almost_empty_q <= #`TCQ 1'b1;
end else begin
if ((fab_regout_en) | (ram_valid_i & fab_read_data_valid_i & ~RD_EN)) begin
almost_empty_i <= #`TCQ (~ram_valid_i);
end
almost_empty_q <= #`TCQ empty_i;
end
end
end //always
end
endgenerate
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin
empty_sckt <= #`TCQ 1'b1;
sckt_rrst_q <= #`TCQ 1'b0;
sckt_rrst_done <= #`TCQ 1'b0;
end else begin
sckt_rrst_q <= #`TCQ SAFETY_CKT_RD_RST;
if (sckt_rrst_q && ~SAFETY_CKT_RD_RST) begin
sckt_rrst_done <= #`TCQ 1'b1;
end else if (sckt_rrst_done) begin
// rising clock edge
empty_sckt <= #`TCQ 1'b0;
end
end
end //always
// assign USEREMPTY = C_EN_SAFETY_CKT ? (sckt_rrst_done ? empty_i : empty_sckt) : empty_i;
assign USEREMPTY = empty_i;
assign USERALMOSTEMPTY = almost_empty_i;
assign FIFORDEN = ram_rd_en;
assign RAMVALID = (C_USE_EMBEDDED_REG == 3)? fab_valid : ram_valid_i;
assign uservalid_both = (C_USERVALID_LOW && C_USE_EMBEDDED_REG == 3) ? ~fab_read_data_valid_i : ((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG == 3) ? fab_read_data_valid_i : 1'b0);
assign uservalid_one = (C_USERVALID_LOW && C_USE_EMBEDDED_REG < 3) ? ~read_data_valid_i :((C_USERVALID_LOW == 0 && C_USE_EMBEDDED_REG < 3) ? read_data_valid_i : 1'b0);
assign USERVALID = (C_USE_EMBEDDED_REG == 3) ? uservalid_both : uservalid_one;
assign USERUNDERFLOW = C_USERUNDERFLOW_LOW ? ~(empty_q & rd_en_q) : empty_q & rd_en_q;
//no safety ckt with both reg
generate
if (C_EN_SAFETY_CKT==0 && C_USE_EMBEDDED_REG == 3 ) begin
always @ (posedge RD_CLK)
begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i)
begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin
if (fwft_rst_done) begin
if (ram_regout_en) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end
end //always
end //if
endgenerate
//safety_ckt with both registers
generate
if (C_EN_SAFETY_CKT==1 && C_USE_EMBEDDED_REG == 3) begin
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d1;
reg [C_DOUT_WIDTH-1:0] dout_rst_val_d2;
reg [1:0] rst_delayed_sft1 =1;
reg [1:0] rst_delayed_sft2 =1;
reg [1:0] rst_delayed_sft3 =1;
reg [1:0] rst_delayed_sft4 =1;
always@(posedge RD_CLK) begin
rst_delayed_sft1 <= #`TCQ rd_rst_i;
rst_delayed_sft2 <= #`TCQ rst_delayed_sft1;
rst_delayed_sft3 <= #`TCQ rst_delayed_sft2;
rst_delayed_sft4 <= #`TCQ rst_delayed_sft3;
end
always @ (posedge RD_CLK) begin
if (rd_rst_i || srst_i) begin
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE < 2 && rst_delayed_sft1 == 1'b1) begin
@(posedge RD_CLK)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end
end //always
always @ (posedge RD_CLK or posedge rd_rst_i) begin
if (rd_rst_i) begin //asynchronous reset (active high)
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
// DRAM resets asynchronously
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2)begin //asynchronous reset (active high)
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
userdata_both <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
end else begin // rising clock edge
if (srst_i) begin
if (C_USE_ECC == 0) begin // Reset S/DBITERR only if ECC is OFF
USERSBITERR <= #`TCQ 0;
USERDBITERR <= #`TCQ 0;
user_sbiterr_both <= #`TCQ 0;
user_dbiterr_both <= #`TCQ 0;
end
if (C_USE_DOUT_RST == 1 && C_MEMORY_TYPE == 2) begin
USERDATA <= #`TCQ hexstr_conv(C_DOUT_RST_VAL);
end
end else if (fwft_rst_done) begin
if (ram_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
userdata_both <= #`TCQ FIFODATA;
user_dbiterr_both <= #`TCQ FIFODBITERR;
user_sbiterr_both <= #`TCQ FIFOSBITERR;
end
if (fab_regout_en == 1'b1 && rd_rst_i == 1'b0) begin
USERDATA <= #`TCQ userdata_both;
USERDBITERR <= #`TCQ user_dbiterr_both;
USERSBITERR <= #`TCQ user_sbiterr_both;
end
end
end
end //always
end //if
endgenerate
endmodule //fifo_generator_v13_1_3_bhv_ver_preload0
//-----------------------------------------------------------------------------
//
// Register Slice
// Register one AXI channel on forward and/or reverse signal path
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// reg_slice
//
//--------------------------------------------------------------------------
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_WIDTH-1:0] S_PAYLOAD_DATA,
input wire S_VALID,
output wire S_READY,
// Master side
output wire [C_DATA_WIDTH-1:0] M_PAYLOAD_DATA,
output wire M_VALID,
input wire M_READY
);
generate
////////////////////////////////////////////////////////////////////
//
// Both FWD and REV mode
//
////////////////////////////////////////////////////////////////////
if (C_REG_CONFIG == 32'h00000000)
begin
reg [1:0] state;
localparam [1:0]
ZERO = 2'b10,
ONE = 2'b11,
TWO = 2'b01;
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg [C_DATA_WIDTH-1:0] storage_data2 = 0;
reg load_s1;
wire load_s2;
wire load_s1_from_s2;
reg s_ready_i; //local signal of output
wire m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with either slave side data or from storage2
always @(posedge ACLK)
begin
if (load_s1)
if (load_s1_from_s2)
storage_data1 <= storage_data2;
else
storage_data1 <= S_PAYLOAD_DATA;
end
// Load storage2 with slave side data
always @(posedge ACLK)
begin
if (load_s2)
storage_data2 <= S_PAYLOAD_DATA;
end
assign M_PAYLOAD_DATA = storage_data1;
// Always load s2 on a valid transaction even if it's unnecessary
assign load_s2 = S_VALID & s_ready_i;
// Loading s1
always @ *
begin
if ( ((state == ZERO) && (S_VALID == 1)) || // Load when empty on slave transaction
// Load when ONE if we both have read and write at the same time
((state == ONE) && (S_VALID == 1) && (M_READY == 1)) ||
// Load when TWO and we have a transaction on Master side
((state == TWO) && (M_READY == 1)))
load_s1 = 1'b1;
else
load_s1 = 1'b0;
end // always @ *
assign load_s1_from_s2 = (state == TWO);
// State Machine for handling output signals
always @(posedge ACLK) begin
if (ARESET) begin
s_ready_i <= 1'b0;
state <= ZERO;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else begin
case (state)
// No transaction stored locally
ZERO: if (S_VALID) state <= ONE; // Got one so move to ONE
// One transaction stored locally
ONE: begin
if (M_READY & ~S_VALID) state <= ZERO; // Read out one so move to ZERO
if (~M_READY & S_VALID) begin
state <= TWO; // Got another one so move to TWO
s_ready_i <= 1'b0;
end
end
// TWO transaction stored locally
TWO: if (M_READY) begin
state <= ONE; // Read out one so move to ONE
s_ready_i <= 1'b1;
end
endcase // case (state)
end
end // always @ (posedge ACLK)
assign m_valid_i = state[0];
end // if (C_REG_CONFIG == 1)
////////////////////////////////////////////////////////////////////
//
// 1-stage pipeline register with bubble cycle, both FWD and REV pipelining
// Operates same as 1-deep FIFO
//
////////////////////////////////////////////////////////////////////
else if (C_REG_CONFIG == 32'h00000001)
begin
reg [C_DATA_WIDTH-1:0] storage_data1 = 0;
reg s_ready_i; //local signal of output
reg m_valid_i; //local signal of output
// assign local signal to its output signal
assign S_READY = s_ready_i;
assign M_VALID = m_valid_i;
reg areset_d1; // Reset delay register
always @(posedge ACLK) begin
areset_d1 <= ARESET;
end
// Load storage1 with slave side data
always @(posedge ACLK)
begin
if (ARESET) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b0;
end else if (areset_d1) begin
s_ready_i <= 1'b1;
end else if (m_valid_i & M_READY) begin
s_ready_i <= 1'b1;
m_valid_i <= 1'b0;
end else if (S_VALID & s_ready_i) begin
s_ready_i <= 1'b0;
m_valid_i <= 1'b1;
end
if (~m_valid_i) begin
storage_data1 <= S_PAYLOAD_DATA;
end
end
assign M_PAYLOAD_DATA = storage_data1;
end // if (C_REG_CONFIG == 7)
else begin : default_case
// Passthrough
assign M_PAYLOAD_DATA = S_PAYLOAD_DATA;
assign M_VALID = S_VALID;
assign S_READY = M_READY;
end
endgenerate
endmodule // reg_slice
|
//-----------------------------------------------------------------------------
//-- Divisor de reloj
//-- Señal de periodo igual al indicado
//-- El ancho del pulso positivo es de 1 ciclo de reloj
//--
//-- (c) BQ. September 2015. written by Juan Gonzalez (obijuan)
//-----------------------------------------------------------------------------
//-- GPL license
//-----------------------------------------------------------------------------
`include "divider.vh"
//-- ENTRADAS:
//-- -clk: Senal de reloj del sistema (12 MHZ en la iceStick)
//
//-- SALIDAS:
//-- - clk_out. Señal de salida para lograr la velocidad en baudios indicada
//-- Anchura de 1 periodo de clk. SALIDA NO REGISTRADA
module dividerp1(input wire clk,
output wire clk_out);
//-- Valor por defecto de la velocidad en baudios
parameter M = `T_100ms;
//-- Numero de bits para almacenar el divisor de baudios
localparam N = $clog2(M);
//-- Registro para implementar el contador modulo M
reg [N-1:0] divcounter = 0;
//-- Contador módulo M
always @(posedge clk)
divcounter <= (divcounter == M - 1) ? 0 : divcounter + 1;
//-- Sacar un pulso de anchura 1 ciclo de reloj si el generador
assign clk_out = (divcounter == 0) ? 1 : 0;
endmodule
|
// -*- verilog -*-
//
// USRP - Universal Software Radio Peripheral
//
// Copyright (C) 2003 Matt Ettus
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA
//
// DUC block
module duc(input clock,
input reset,
input enable,
input [3:0] rate1,
input [3:0] rate2,
output strobe,
input [31:0] freq,
input [15:0] i_in,
input [15:0] q_in,
output [15:0] i_out,
output [15:0] q_out
);
parameter bw = 16;
parameter zw = 16;
wire [15:0] i_interp_out, q_interp_out;
wire [31:0] phase;
wire strobe1, strobe2;
reg [3:0] strobe_ctr1,strobe_ctr2;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr2 <= #1 4'd0;
else if(strobe2)
strobe_ctr2 <= #1 4'd0;
else
strobe_ctr2 <= #1 strobe_ctr2 + 4'd1;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr1 <= #1 4'd0;
else if(strobe1)
strobe_ctr1 <= #1 4'd0;
else if(strobe2)
strobe_ctr1 <= #1 strobe_ctr1 + 4'd1;
assign strobe2 = enable & ( strobe_ctr2 == rate2 );
assign strobe1 = strobe2 & ( strobe_ctr1 == rate1 );
assign strobe = strobe1;
function [2:0] log_ceil;
input [3:0] val;
log_ceil = val[3] ? 3'd4 : val[2] ? 3'd3 : val[1] ? 3'd2 : 3'd1;
endfunction
wire [2:0] shift1 = log_ceil(rate1);
wire [2:0] shift2 = log_ceil(rate2);
cordic #(.bitwidth(bw),.zwidth(zw),.stages(16))
cordic(.clock(clock), .reset(reset), .enable(enable),
.xi(i_interp_out), .yi(q_interp_out), .zi(phase[31:32-zw]),
.xo(i_out), .yo(q_out), .zo() );
cic_interp_2stage #(.bw(bw),.N(4))
interp_i(.clock(clock),.reset(reset),.enable(enable),
.strobe1(strobe1),.strobe2(strobe2),.strobe3(1'b1),.shift1(shift1),.shift2(shift2),
.signal_in(i_in),.signal_out(i_interp_out));
cic_interp_2stage #(.bw(bw),.N(4))
interp_q(.clock(clock),.reset(reset),.enable(enable),
.strobe1(strobe1),.strobe2(strobe2),.strobe3(1'b1),.shift1(shift1),.shift2(shift2),
.signal_in(q_in),.signal_out(q_interp_out));
phase_acc #(.resolution(32))
nco (.clk(clock),.reset(reset),.enable(enable),
.freq(freq),.phase(phase));
endmodule
|
// -*- verilog -*-
//
// USRP - Universal Software Radio Peripheral
//
// Copyright (C) 2003 Matt Ettus
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA
//
// DUC block
module duc(input clock,
input reset,
input enable,
input [3:0] rate1,
input [3:0] rate2,
output strobe,
input [31:0] freq,
input [15:0] i_in,
input [15:0] q_in,
output [15:0] i_out,
output [15:0] q_out
);
parameter bw = 16;
parameter zw = 16;
wire [15:0] i_interp_out, q_interp_out;
wire [31:0] phase;
wire strobe1, strobe2;
reg [3:0] strobe_ctr1,strobe_ctr2;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr2 <= #1 4'd0;
else if(strobe2)
strobe_ctr2 <= #1 4'd0;
else
strobe_ctr2 <= #1 strobe_ctr2 + 4'd1;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr1 <= #1 4'd0;
else if(strobe1)
strobe_ctr1 <= #1 4'd0;
else if(strobe2)
strobe_ctr1 <= #1 strobe_ctr1 + 4'd1;
assign strobe2 = enable & ( strobe_ctr2 == rate2 );
assign strobe1 = strobe2 & ( strobe_ctr1 == rate1 );
assign strobe = strobe1;
function [2:0] log_ceil;
input [3:0] val;
log_ceil = val[3] ? 3'd4 : val[2] ? 3'd3 : val[1] ? 3'd2 : 3'd1;
endfunction
wire [2:0] shift1 = log_ceil(rate1);
wire [2:0] shift2 = log_ceil(rate2);
cordic #(.bitwidth(bw),.zwidth(zw),.stages(16))
cordic(.clock(clock), .reset(reset), .enable(enable),
.xi(i_interp_out), .yi(q_interp_out), .zi(phase[31:32-zw]),
.xo(i_out), .yo(q_out), .zo() );
cic_interp_2stage #(.bw(bw),.N(4))
interp_i(.clock(clock),.reset(reset),.enable(enable),
.strobe1(strobe1),.strobe2(strobe2),.strobe3(1'b1),.shift1(shift1),.shift2(shift2),
.signal_in(i_in),.signal_out(i_interp_out));
cic_interp_2stage #(.bw(bw),.N(4))
interp_q(.clock(clock),.reset(reset),.enable(enable),
.strobe1(strobe1),.strobe2(strobe2),.strobe3(1'b1),.shift1(shift1),.shift2(shift2),
.signal_in(q_in),.signal_out(q_interp_out));
phase_acc #(.resolution(32))
nco (.clk(clock),.reset(reset),.enable(enable),
.freq(freq),.phase(phase));
endmodule
|
// -*- verilog -*-
//
// USRP - Universal Software Radio Peripheral
//
// Copyright (C) 2003 Matt Ettus
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA
//
// DUC block
module duc(input clock,
input reset,
input enable,
input [3:0] rate1,
input [3:0] rate2,
output strobe,
input [31:0] freq,
input [15:0] i_in,
input [15:0] q_in,
output [15:0] i_out,
output [15:0] q_out
);
parameter bw = 16;
parameter zw = 16;
wire [15:0] i_interp_out, q_interp_out;
wire [31:0] phase;
wire strobe1, strobe2;
reg [3:0] strobe_ctr1,strobe_ctr2;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr2 <= #1 4'd0;
else if(strobe2)
strobe_ctr2 <= #1 4'd0;
else
strobe_ctr2 <= #1 strobe_ctr2 + 4'd1;
always @(posedge clock)
if(reset | ~enable)
strobe_ctr1 <= #1 4'd0;
else if(strobe1)
strobe_ctr1 <= #1 4'd0;
else if(strobe2)
strobe_ctr1 <= #1 strobe_ctr1 + 4'd1;
assign strobe2 = enable & ( strobe_ctr2 == rate2 );
assign strobe1 = strobe2 & ( strobe_ctr1 == rate1 );
assign strobe = strobe1;
function [2:0] log_ceil;
input [3:0] val;
log_ceil = val[3] ? 3'd4 : val[2] ? 3'd3 : val[1] ? 3'd2 : 3'd1;
endfunction
wire [2:0] shift1 = log_ceil(rate1);
wire [2:0] shift2 = log_ceil(rate2);
cordic #(.bitwidth(bw),.zwidth(zw),.stages(16))
cordic(.clock(clock), .reset(reset), .enable(enable),
.xi(i_interp_out), .yi(q_interp_out), .zi(phase[31:32-zw]),
.xo(i_out), .yo(q_out), .zo() );
cic_interp_2stage #(.bw(bw),.N(4))
interp_i(.clock(clock),.reset(reset),.enable(enable),
.strobe1(strobe1),.strobe2(strobe2),.strobe3(1'b1),.shift1(shift1),.shift2(shift2),
.signal_in(i_in),.signal_out(i_interp_out));
cic_interp_2stage #(.bw(bw),.N(4))
interp_q(.clock(clock),.reset(reset),.enable(enable),
.strobe1(strobe1),.strobe2(strobe2),.strobe3(1'b1),.shift1(shift1),.shift2(shift2),
.signal_in(q_in),.signal_out(q_interp_out));
phase_acc #(.resolution(32))
nco (.clk(clock),.reset(reset),.enable(enable),
.freq(freq),.phase(phase));
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Addr Decoder
// Each received address is compared to base and high address pairs for each
// of a set of decode targets.
// The matching target's index (if any) is output combinatorially.
// If the decode is successful (matches any target), the MATCH output is asserted.
// For each target, a set of alternative address ranges may be specified.
// The base and high address pairs are formatted as a pair of 2-dimensional arrays,
// alternative address ranges iterate within each target.
// The alternative range which matches the address is also output as REGION.
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// addr_decoder
// comparator_static
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
(* DowngradeIPIdentifiedWarnings="yes" *)
module axi_crossbar_v2_1_addr_decoder #
(
parameter C_FAMILY = "none",
parameter integer C_NUM_TARGETS = 2, // Number of decode targets = [1:16]
parameter integer C_NUM_TARGETS_LOG = 1, // Log2(C_NUM_TARGETS)
parameter integer C_NUM_RANGES = 1, // Number of alternative ranges that
// can match each target [1:16]
parameter integer C_ADDR_WIDTH = 32, // Width of decoder operand and of
// each base and high address [2:64]
parameter integer C_TARGET_ENC = 0, // Enable encoded target output
parameter integer C_TARGET_HOT = 1, // Enable 1-hot target output
parameter integer C_REGION_ENC = 0, // Enable REGION output
parameter [C_NUM_TARGETS*C_NUM_RANGES*64-1:0] C_BASE_ADDR = {C_NUM_TARGETS*C_NUM_RANGES*64{1'b1}},
parameter [C_NUM_TARGETS*C_NUM_RANGES*64-1:0] C_HIGH_ADDR = {C_NUM_TARGETS*C_NUM_RANGES*64{1'b0}},
parameter [C_NUM_TARGETS:0] C_TARGET_QUAL = {C_NUM_TARGETS{1'b1}},
// Indicates whether each target has connectivity.
// Format: C_NUM_TARGETS{Bit1}.
parameter integer C_RESOLUTION = 0,
// Number of low-order ADDR bits that can be ignored when decoding.
parameter integer C_COMPARATOR_THRESHOLD = 6
// Number of decoded ADDR bits above which will implement comparator_static.
)
(
input wire [C_ADDR_WIDTH-1:0] ADDR, // Decoder input operand
output wire [C_NUM_TARGETS-1:0] TARGET_HOT, // Target matching address (1-hot)
output wire [C_NUM_TARGETS_LOG-1:0] TARGET_ENC, // Target matching address (encoded)
output wire MATCH, // Decode successful
output wire [3:0] REGION // Range within target matching address (encoded)
);
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
genvar target_cnt;
genvar region_cnt;
/////////////////////////////////////////////////////////////////////////////
// Function to detect addrs is in the addressable range.
// Only compare 4KB page address (ignore low-order 12 bits)
function decode_address;
input [C_ADDR_WIDTH-1:0] base, high, addr;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] mask;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] addr_page;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] base_page;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] high_page;
begin
addr_page = addr[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
base_page = base[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
high_page = high[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
if (base[C_ADDR_WIDTH-1] & ~high[C_ADDR_WIDTH-1]) begin
decode_address = 1'b0;
end else begin
mask = base_page ^ high_page;
if ( (base_page & ~mask) == (addr_page & ~mask) ) begin
decode_address = 1'b1;
end else begin
decode_address = 1'b0;
end
end
end
endfunction
// Generates a binary coded from onehotone encoded
function [3:0] f_hot2enc
(
input [15:0] one_hot
);
begin
f_hot2enc[0] = |(one_hot & 16'b1010101010101010);
f_hot2enc[1] = |(one_hot & 16'b1100110011001100);
f_hot2enc[2] = |(one_hot & 16'b1111000011110000);
f_hot2enc[3] = |(one_hot & 16'b1111111100000000);
end
endfunction
/////////////////////////////////////////////////////////////////////////////
// Internal signals
wire [C_NUM_TARGETS-1:0] TARGET_HOT_I; // Target matching address (1-hot).
wire [C_NUM_TARGETS*C_NUM_RANGES-1:0] ADDRESS_HIT; // For address hit (1-hot).
wire [C_NUM_TARGETS*C_NUM_RANGES-1:0] ADDRESS_HIT_REG; // For address hit (1-hot).
wire [C_NUM_RANGES-1:0] REGION_HOT; // Reginon matching address (1-hot).
wire [3:0] TARGET_ENC_I; // Internal version of encoded hit.
/////////////////////////////////////////////////////////////////////////////
// Generate detection per region per target.
generate
for (target_cnt = 0; target_cnt < C_NUM_TARGETS; target_cnt = target_cnt + 1) begin : gen_target
for (region_cnt = 0; region_cnt < C_NUM_RANGES; region_cnt = region_cnt + 1) begin : gen_region
// Detect if this is an address hit (including used region decoding).
if ((C_ADDR_WIDTH - C_RESOLUTION) > C_COMPARATOR_THRESHOLD) begin : gen_comparator_static
if (C_TARGET_QUAL[target_cnt] &&
((C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH] == 0) ||
(C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH] != 0))) begin : gen_addr_range
generic_baseblocks_v2_1_comparator_static #
(
.C_FAMILY("rtl"),
.C_VALUE(C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION]),
.C_DATA_WIDTH(C_ADDR_WIDTH-C_RESOLUTION)
) addr_decode_comparator
(
.CIN(1'b1),
.A(ADDR[C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION] &
~(C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION] ^
C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION])),
.COUT(ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt])
);
end else begin : gen_null_range
assign ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt] = 1'b0;
end
end else begin : gen_no_comparator_static
assign ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt] = C_TARGET_QUAL[target_cnt] ?
decode_address(
C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH],
C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH],
ADDR)
: 1'b0;
end // gen_comparator_static
assign ADDRESS_HIT_REG[region_cnt*C_NUM_TARGETS+target_cnt] = ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt];
assign REGION_HOT[region_cnt] = | ADDRESS_HIT_REG[region_cnt*C_NUM_TARGETS +: C_NUM_TARGETS];
end // gen_region
// All regions are non-overlapping
// => Or all the region detections for this target to determine if it is a hit.
assign TARGET_HOT_I[target_cnt] = | ADDRESS_HIT[target_cnt*C_NUM_RANGES +: C_NUM_RANGES];
end // gen_target
endgenerate
/////////////////////////////////////////////////////////////////////////////
// All regions are non-overlapping
// => Or all the target hit detections if it is a match.
assign MATCH = | TARGET_HOT_I;
/////////////////////////////////////////////////////////////////////////////
// Assign conditional onehot target output signal.
generate
if (C_TARGET_HOT == 1) begin : USE_TARGET_ONEHOT
assign TARGET_HOT = MATCH ? TARGET_HOT_I : 1;
end else begin : NO_TARGET_ONEHOT
assign TARGET_HOT = {C_NUM_TARGETS{1'b0}};
end
endgenerate
/////////////////////////////////////////////////////////////////////////////
// Assign conditional encoded target output signal.
generate
if (C_TARGET_ENC == 1) begin : USE_TARGET_ENCODED
assign TARGET_ENC_I = f_hot2enc(TARGET_HOT_I);
assign TARGET_ENC = TARGET_ENC_I[C_NUM_TARGETS_LOG-1:0];
end else begin : NO_TARGET_ENCODED
assign TARGET_ENC = {C_NUM_TARGETS_LOG{1'b0}};
end
endgenerate
/////////////////////////////////////////////////////////////////////////////
// Assign conditional encoded region output signal.
generate
if (C_TARGET_ENC == 1) begin : USE_REGION_ENCODED
assign REGION = f_hot2enc(REGION_HOT);
end else begin : NO_REGION_ENCODED
assign REGION = 4'b0;
end
endgenerate
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Addr Decoder
// Each received address is compared to base and high address pairs for each
// of a set of decode targets.
// The matching target's index (if any) is output combinatorially.
// If the decode is successful (matches any target), the MATCH output is asserted.
// For each target, a set of alternative address ranges may be specified.
// The base and high address pairs are formatted as a pair of 2-dimensional arrays,
// alternative address ranges iterate within each target.
// The alternative range which matches the address is also output as REGION.
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// addr_decoder
// comparator_static
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
(* DowngradeIPIdentifiedWarnings="yes" *)
module axi_crossbar_v2_1_addr_decoder #
(
parameter C_FAMILY = "none",
parameter integer C_NUM_TARGETS = 2, // Number of decode targets = [1:16]
parameter integer C_NUM_TARGETS_LOG = 1, // Log2(C_NUM_TARGETS)
parameter integer C_NUM_RANGES = 1, // Number of alternative ranges that
// can match each target [1:16]
parameter integer C_ADDR_WIDTH = 32, // Width of decoder operand and of
// each base and high address [2:64]
parameter integer C_TARGET_ENC = 0, // Enable encoded target output
parameter integer C_TARGET_HOT = 1, // Enable 1-hot target output
parameter integer C_REGION_ENC = 0, // Enable REGION output
parameter [C_NUM_TARGETS*C_NUM_RANGES*64-1:0] C_BASE_ADDR = {C_NUM_TARGETS*C_NUM_RANGES*64{1'b1}},
parameter [C_NUM_TARGETS*C_NUM_RANGES*64-1:0] C_HIGH_ADDR = {C_NUM_TARGETS*C_NUM_RANGES*64{1'b0}},
parameter [C_NUM_TARGETS:0] C_TARGET_QUAL = {C_NUM_TARGETS{1'b1}},
// Indicates whether each target has connectivity.
// Format: C_NUM_TARGETS{Bit1}.
parameter integer C_RESOLUTION = 0,
// Number of low-order ADDR bits that can be ignored when decoding.
parameter integer C_COMPARATOR_THRESHOLD = 6
// Number of decoded ADDR bits above which will implement comparator_static.
)
(
input wire [C_ADDR_WIDTH-1:0] ADDR, // Decoder input operand
output wire [C_NUM_TARGETS-1:0] TARGET_HOT, // Target matching address (1-hot)
output wire [C_NUM_TARGETS_LOG-1:0] TARGET_ENC, // Target matching address (encoded)
output wire MATCH, // Decode successful
output wire [3:0] REGION // Range within target matching address (encoded)
);
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
genvar target_cnt;
genvar region_cnt;
/////////////////////////////////////////////////////////////////////////////
// Function to detect addrs is in the addressable range.
// Only compare 4KB page address (ignore low-order 12 bits)
function decode_address;
input [C_ADDR_WIDTH-1:0] base, high, addr;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] mask;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] addr_page;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] base_page;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] high_page;
begin
addr_page = addr[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
base_page = base[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
high_page = high[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
if (base[C_ADDR_WIDTH-1] & ~high[C_ADDR_WIDTH-1]) begin
decode_address = 1'b0;
end else begin
mask = base_page ^ high_page;
if ( (base_page & ~mask) == (addr_page & ~mask) ) begin
decode_address = 1'b1;
end else begin
decode_address = 1'b0;
end
end
end
endfunction
// Generates a binary coded from onehotone encoded
function [3:0] f_hot2enc
(
input [15:0] one_hot
);
begin
f_hot2enc[0] = |(one_hot & 16'b1010101010101010);
f_hot2enc[1] = |(one_hot & 16'b1100110011001100);
f_hot2enc[2] = |(one_hot & 16'b1111000011110000);
f_hot2enc[3] = |(one_hot & 16'b1111111100000000);
end
endfunction
/////////////////////////////////////////////////////////////////////////////
// Internal signals
wire [C_NUM_TARGETS-1:0] TARGET_HOT_I; // Target matching address (1-hot).
wire [C_NUM_TARGETS*C_NUM_RANGES-1:0] ADDRESS_HIT; // For address hit (1-hot).
wire [C_NUM_TARGETS*C_NUM_RANGES-1:0] ADDRESS_HIT_REG; // For address hit (1-hot).
wire [C_NUM_RANGES-1:0] REGION_HOT; // Reginon matching address (1-hot).
wire [3:0] TARGET_ENC_I; // Internal version of encoded hit.
/////////////////////////////////////////////////////////////////////////////
// Generate detection per region per target.
generate
for (target_cnt = 0; target_cnt < C_NUM_TARGETS; target_cnt = target_cnt + 1) begin : gen_target
for (region_cnt = 0; region_cnt < C_NUM_RANGES; region_cnt = region_cnt + 1) begin : gen_region
// Detect if this is an address hit (including used region decoding).
if ((C_ADDR_WIDTH - C_RESOLUTION) > C_COMPARATOR_THRESHOLD) begin : gen_comparator_static
if (C_TARGET_QUAL[target_cnt] &&
((C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH] == 0) ||
(C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH] != 0))) begin : gen_addr_range
generic_baseblocks_v2_1_comparator_static #
(
.C_FAMILY("rtl"),
.C_VALUE(C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION]),
.C_DATA_WIDTH(C_ADDR_WIDTH-C_RESOLUTION)
) addr_decode_comparator
(
.CIN(1'b1),
.A(ADDR[C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION] &
~(C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION] ^
C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION])),
.COUT(ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt])
);
end else begin : gen_null_range
assign ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt] = 1'b0;
end
end else begin : gen_no_comparator_static
assign ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt] = C_TARGET_QUAL[target_cnt] ?
decode_address(
C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH],
C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH],
ADDR)
: 1'b0;
end // gen_comparator_static
assign ADDRESS_HIT_REG[region_cnt*C_NUM_TARGETS+target_cnt] = ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt];
assign REGION_HOT[region_cnt] = | ADDRESS_HIT_REG[region_cnt*C_NUM_TARGETS +: C_NUM_TARGETS];
end // gen_region
// All regions are non-overlapping
// => Or all the region detections for this target to determine if it is a hit.
assign TARGET_HOT_I[target_cnt] = | ADDRESS_HIT[target_cnt*C_NUM_RANGES +: C_NUM_RANGES];
end // gen_target
endgenerate
/////////////////////////////////////////////////////////////////////////////
// All regions are non-overlapping
// => Or all the target hit detections if it is a match.
assign MATCH = | TARGET_HOT_I;
/////////////////////////////////////////////////////////////////////////////
// Assign conditional onehot target output signal.
generate
if (C_TARGET_HOT == 1) begin : USE_TARGET_ONEHOT
assign TARGET_HOT = MATCH ? TARGET_HOT_I : 1;
end else begin : NO_TARGET_ONEHOT
assign TARGET_HOT = {C_NUM_TARGETS{1'b0}};
end
endgenerate
/////////////////////////////////////////////////////////////////////////////
// Assign conditional encoded target output signal.
generate
if (C_TARGET_ENC == 1) begin : USE_TARGET_ENCODED
assign TARGET_ENC_I = f_hot2enc(TARGET_HOT_I);
assign TARGET_ENC = TARGET_ENC_I[C_NUM_TARGETS_LOG-1:0];
end else begin : NO_TARGET_ENCODED
assign TARGET_ENC = {C_NUM_TARGETS_LOG{1'b0}};
end
endgenerate
/////////////////////////////////////////////////////////////////////////////
// Assign conditional encoded region output signal.
generate
if (C_TARGET_ENC == 1) begin : USE_REGION_ENCODED
assign REGION = f_hot2enc(REGION_HOT);
end else begin : NO_REGION_ENCODED
assign REGION = 4'b0;
end
endgenerate
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Addr Decoder
// Each received address is compared to base and high address pairs for each
// of a set of decode targets.
// The matching target's index (if any) is output combinatorially.
// If the decode is successful (matches any target), the MATCH output is asserted.
// For each target, a set of alternative address ranges may be specified.
// The base and high address pairs are formatted as a pair of 2-dimensional arrays,
// alternative address ranges iterate within each target.
// The alternative range which matches the address is also output as REGION.
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// addr_decoder
// comparator_static
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
(* DowngradeIPIdentifiedWarnings="yes" *)
module axi_crossbar_v2_1_addr_decoder #
(
parameter C_FAMILY = "none",
parameter integer C_NUM_TARGETS = 2, // Number of decode targets = [1:16]
parameter integer C_NUM_TARGETS_LOG = 1, // Log2(C_NUM_TARGETS)
parameter integer C_NUM_RANGES = 1, // Number of alternative ranges that
// can match each target [1:16]
parameter integer C_ADDR_WIDTH = 32, // Width of decoder operand and of
// each base and high address [2:64]
parameter integer C_TARGET_ENC = 0, // Enable encoded target output
parameter integer C_TARGET_HOT = 1, // Enable 1-hot target output
parameter integer C_REGION_ENC = 0, // Enable REGION output
parameter [C_NUM_TARGETS*C_NUM_RANGES*64-1:0] C_BASE_ADDR = {C_NUM_TARGETS*C_NUM_RANGES*64{1'b1}},
parameter [C_NUM_TARGETS*C_NUM_RANGES*64-1:0] C_HIGH_ADDR = {C_NUM_TARGETS*C_NUM_RANGES*64{1'b0}},
parameter [C_NUM_TARGETS:0] C_TARGET_QUAL = {C_NUM_TARGETS{1'b1}},
// Indicates whether each target has connectivity.
// Format: C_NUM_TARGETS{Bit1}.
parameter integer C_RESOLUTION = 0,
// Number of low-order ADDR bits that can be ignored when decoding.
parameter integer C_COMPARATOR_THRESHOLD = 6
// Number of decoded ADDR bits above which will implement comparator_static.
)
(
input wire [C_ADDR_WIDTH-1:0] ADDR, // Decoder input operand
output wire [C_NUM_TARGETS-1:0] TARGET_HOT, // Target matching address (1-hot)
output wire [C_NUM_TARGETS_LOG-1:0] TARGET_ENC, // Target matching address (encoded)
output wire MATCH, // Decode successful
output wire [3:0] REGION // Range within target matching address (encoded)
);
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
genvar target_cnt;
genvar region_cnt;
/////////////////////////////////////////////////////////////////////////////
// Function to detect addrs is in the addressable range.
// Only compare 4KB page address (ignore low-order 12 bits)
function decode_address;
input [C_ADDR_WIDTH-1:0] base, high, addr;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] mask;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] addr_page;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] base_page;
reg [C_ADDR_WIDTH-C_RESOLUTION-1:0] high_page;
begin
addr_page = addr[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
base_page = base[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
high_page = high[C_RESOLUTION+:C_ADDR_WIDTH-C_RESOLUTION];
if (base[C_ADDR_WIDTH-1] & ~high[C_ADDR_WIDTH-1]) begin
decode_address = 1'b0;
end else begin
mask = base_page ^ high_page;
if ( (base_page & ~mask) == (addr_page & ~mask) ) begin
decode_address = 1'b1;
end else begin
decode_address = 1'b0;
end
end
end
endfunction
// Generates a binary coded from onehotone encoded
function [3:0] f_hot2enc
(
input [15:0] one_hot
);
begin
f_hot2enc[0] = |(one_hot & 16'b1010101010101010);
f_hot2enc[1] = |(one_hot & 16'b1100110011001100);
f_hot2enc[2] = |(one_hot & 16'b1111000011110000);
f_hot2enc[3] = |(one_hot & 16'b1111111100000000);
end
endfunction
/////////////////////////////////////////////////////////////////////////////
// Internal signals
wire [C_NUM_TARGETS-1:0] TARGET_HOT_I; // Target matching address (1-hot).
wire [C_NUM_TARGETS*C_NUM_RANGES-1:0] ADDRESS_HIT; // For address hit (1-hot).
wire [C_NUM_TARGETS*C_NUM_RANGES-1:0] ADDRESS_HIT_REG; // For address hit (1-hot).
wire [C_NUM_RANGES-1:0] REGION_HOT; // Reginon matching address (1-hot).
wire [3:0] TARGET_ENC_I; // Internal version of encoded hit.
/////////////////////////////////////////////////////////////////////////////
// Generate detection per region per target.
generate
for (target_cnt = 0; target_cnt < C_NUM_TARGETS; target_cnt = target_cnt + 1) begin : gen_target
for (region_cnt = 0; region_cnt < C_NUM_RANGES; region_cnt = region_cnt + 1) begin : gen_region
// Detect if this is an address hit (including used region decoding).
if ((C_ADDR_WIDTH - C_RESOLUTION) > C_COMPARATOR_THRESHOLD) begin : gen_comparator_static
if (C_TARGET_QUAL[target_cnt] &&
((C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH] == 0) ||
(C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH] != 0))) begin : gen_addr_range
generic_baseblocks_v2_1_comparator_static #
(
.C_FAMILY("rtl"),
.C_VALUE(C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION]),
.C_DATA_WIDTH(C_ADDR_WIDTH-C_RESOLUTION)
) addr_decode_comparator
(
.CIN(1'b1),
.A(ADDR[C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION] &
~(C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION] ^
C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64+C_RESOLUTION +: C_ADDR_WIDTH-C_RESOLUTION])),
.COUT(ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt])
);
end else begin : gen_null_range
assign ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt] = 1'b0;
end
end else begin : gen_no_comparator_static
assign ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt] = C_TARGET_QUAL[target_cnt] ?
decode_address(
C_BASE_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH],
C_HIGH_ADDR[(target_cnt*C_NUM_RANGES+region_cnt)*64 +: C_ADDR_WIDTH],
ADDR)
: 1'b0;
end // gen_comparator_static
assign ADDRESS_HIT_REG[region_cnt*C_NUM_TARGETS+target_cnt] = ADDRESS_HIT[target_cnt*C_NUM_RANGES + region_cnt];
assign REGION_HOT[region_cnt] = | ADDRESS_HIT_REG[region_cnt*C_NUM_TARGETS +: C_NUM_TARGETS];
end // gen_region
// All regions are non-overlapping
// => Or all the region detections for this target to determine if it is a hit.
assign TARGET_HOT_I[target_cnt] = | ADDRESS_HIT[target_cnt*C_NUM_RANGES +: C_NUM_RANGES];
end // gen_target
endgenerate
/////////////////////////////////////////////////////////////////////////////
// All regions are non-overlapping
// => Or all the target hit detections if it is a match.
assign MATCH = | TARGET_HOT_I;
/////////////////////////////////////////////////////////////////////////////
// Assign conditional onehot target output signal.
generate
if (C_TARGET_HOT == 1) begin : USE_TARGET_ONEHOT
assign TARGET_HOT = MATCH ? TARGET_HOT_I : 1;
end else begin : NO_TARGET_ONEHOT
assign TARGET_HOT = {C_NUM_TARGETS{1'b0}};
end
endgenerate
/////////////////////////////////////////////////////////////////////////////
// Assign conditional encoded target output signal.
generate
if (C_TARGET_ENC == 1) begin : USE_TARGET_ENCODED
assign TARGET_ENC_I = f_hot2enc(TARGET_HOT_I);
assign TARGET_ENC = TARGET_ENC_I[C_NUM_TARGETS_LOG-1:0];
end else begin : NO_TARGET_ENCODED
assign TARGET_ENC = {C_NUM_TARGETS_LOG{1'b0}};
end
endgenerate
/////////////////////////////////////////////////////////////////////////////
// Assign conditional encoded region output signal.
generate
if (C_TARGET_ENC == 1) begin : USE_REGION_ENCODED
assign REGION = f_hot2enc(REGION_HOT);
end else begin : NO_REGION_ENCODED
assign REGION = 4'b0;
end
endgenerate
endmodule
|
//IEEE Floating Point Adder (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module adder(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
align = 4'd4,
add_0 = 4'd5,
add_1 = 4'd6,
normalise_1 = 4'd7,
normalise_2 = 4'd8,
round = 4'd9,
pack = 4'd10,
put_z = 4'd11;
reg [31:0] a, b, z;
reg [26:0] a_m, b_m;
reg [23:0] z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [27:0] sum;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= {a[22 : 0], 3'd0};
b_m <= {b[22 : 0], 3'd0};
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is inf return inf
end else if (b_e == 128) begin
z[31] <= b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if a is zero return b
end else if ((($signed(a_e) == -127) && (a_m == 0)) && (($signed(b_e) == -127) && (b_m == 0))) begin
z[31] <= a_s & b_s;
z[30:23] <= b_e[7:0] + 127;
z[22:0] <= b_m[26:3];
state <= put_z;
//if a is zero return b
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= b_s;
z[30:23] <= b_e[7:0] + 127;
z[22:0] <= b_m[26:3];
state <= put_z;
//if b is zero return a
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s;
z[30:23] <= a_e[7:0] + 127;
z[22:0] <= a_m[26:3];
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[26] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[26] <= 1;
end
state <= align;
end
end
align:
begin
if ($signed(a_e) > $signed(b_e)) begin
b_e <= b_e + 1;
b_m <= b_m >> 1;
b_m[0] <= b_m[0] | b_m[1];
end else if ($signed(a_e) < $signed(b_e)) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
a_m[0] <= a_m[0] | a_m[1];
end else begin
state <= add_0;
end
end
add_0:
begin
z_e <= a_e;
if (a_s == b_s) begin
sum <= a_m + b_m;
z_s <= a_s;
end else begin
if (a_m >= b_m) begin
sum <= a_m - b_m;
z_s <= a_s;
end else begin
sum <= b_m - a_m;
z_s <= b_s;
end
end
state <= add_1;
end
add_1:
begin
if (sum[27]) begin
z_m <= sum[27:4];
guard <= sum[3];
round_bit <= sum[2];
sticky <= sum[1] | sum[0];
z_e <= z_e + 1;
end else begin
z_m <= sum[26:3];
guard <= sum[2];
round_bit <= sum[1];
sticky <= sum[0];
end
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0 && $signed(z_e) > -126) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Divider (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
//
module divider(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
divide_0 = 4'd6,
divide_1 = 4'd7,
divide_2 = 4'd8,
divide_3 = 4'd9,
normalise_1 = 4'd10,
normalise_2 = 4'd11,
round = 4'd12,
pack = 4'd13,
put_z = 4'd14;
reg [31:0] a, b, z;
reg [23:0] a_m, b_m, z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [50:0] quotient, divisor, dividend, remainder;
reg [5:0] count;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[22 : 0];
b_m <= b[22 : 0];
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf and b is inf return NaN
end else if ((a_e == 128) && (b_e == 128)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is inf return zero
end else if (b_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is zero return inf
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[23] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[23] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[23]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[23]) begin
state <= divide_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
divide_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e - b_e;
quotient <= 0;
remainder <= 0;
count <= 0;
dividend <= a_m << 27;
divisor <= b_m;
state <= divide_1;
end
divide_1:
begin
quotient <= quotient << 1;
remainder <= remainder << 1;
remainder[0] <= dividend[50];
dividend <= dividend << 1;
state <= divide_2;
end
divide_2:
begin
if (remainder >= divisor) begin
quotient[0] <= 1;
remainder <= remainder - divisor;
end
if (count == 49) begin
state <= divide_3;
end else begin
count <= count + 1;
state <= divide_1;
end
end
divide_3:
begin
z_m <= quotient[26:3];
guard <= quotient[2];
round_bit <= quotient[1];
sticky <= quotient[0] | (remainder != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0 && $signed(z_e) > -126) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Multiplier (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module multiplier(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
multiply_0 = 4'd6,
multiply_1 = 4'd7,
normalise_1 = 4'd8,
normalise_2 = 4'd9,
round = 4'd10,
pack = 4'd11,
put_z = 4'd12;
reg [31:0] a, b, z;
reg [23:0] a_m, b_m, z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [49:0] product;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[22 : 0];
b_m <= b[22 : 0];
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is inf return inf
end else if (b_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if b is zero return zero
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[23] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[23] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[23]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[23]) begin
state <= multiply_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
multiply_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e + b_e + 1;
product <= a_m * b_m * 4;
state <= multiply_1;
end
multiply_1:
begin
z_m <= product[49:26];
guard <= product[25];
round_bit <= product[24];
sticky <= (product[23:0] != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Divider (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
//
module double_divider(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
divide_0 = 4'd6,
divide_1 = 4'd7,
divide_2 = 4'd8,
divide_3 = 4'd9,
normalise_1 = 4'd10,
normalise_2 = 4'd11,
round = 4'd12,
pack = 4'd13,
put_z = 4'd14;
reg [63:0] a, b, z;
reg [52:0] a_m, b_m, z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [108:0] quotient, divisor, dividend, remainder;
reg [6:0] count;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[51 : 0];
b_m <= b[51 : 0];
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf and b is inf return NaN
end else if ((a_e == 1024) && (b_e == 1024)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is inf return zero
end else if (b_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is zero return inf
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[52] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[52] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[52]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[52]) begin
state <= divide_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
divide_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e - b_e;
quotient <= 0;
remainder <= 0;
count <= 0;
dividend <= a_m << 56;
divisor <= b_m;
state <= divide_1;
end
divide_1:
begin
quotient <= quotient << 1;
remainder <= remainder << 1;
remainder[0] <= dividend[108];
dividend <= dividend << 1;
state <= divide_2;
end
divide_2:
begin
if (remainder >= divisor) begin
quotient[0] <= 1;
remainder <= remainder - divisor;
end
if (count == 107) begin
state <= divide_3;
end else begin
count <= count + 1;
state <= divide_1;
end
end
divide_3:
begin
z_m <= quotient[55:3];
guard <= quotient[2];
round_bit <= quotient[1];
sticky <= quotient[0] | (remainder != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0 && $signed(z_e) > -1022) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[10:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Multiplier (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-10
module double_multiplier(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
multiply_0 = 4'd6,
multiply_1 = 4'd7,
normalise_1 = 4'd8,
normalise_2 = 4'd9,
round = 4'd10,
pack = 4'd11,
put_z = 4'd12;
reg [63:0] a, b, z;
reg [52:0] a_m, b_m, z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [107:0] product;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[51 : 0];
b_m <= b[51 : 0];
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is inf return inf
end else if (b_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if b is zero return zero
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[52] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[52] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[52]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[52]) begin
state <= multiply_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
multiply_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e + b_e + 1;
product <= a_m * b_m * 4;
state <= multiply_1;
end
multiply_1:
begin
z_m <= product[107:55];
guard <= product[54];
round_bit <= product[53];
sticky <= (product[52:0] != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[11:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Adder (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module double_adder(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
align = 4'd4,
add_0 = 4'd5,
add_1 = 4'd6,
normalise_1 = 4'd7,
normalise_2 = 4'd8,
round = 4'd9,
pack = 4'd10,
put_z = 4'd11;
reg [63:0] a, b, z;
reg [55:0] a_m, b_m;
reg [52:0] z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [56:0] sum;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= {a[51 : 0], 3'd0};
b_m <= {b[51 : 0], 3'd0};
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is inf return inf
end else if (b_e == 1024) begin
z[63] <= b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if a is zero return b
end else if ((($signed(a_e) == -1023) && (a_m == 0)) && (($signed(b_e) == -1023) && (b_m == 0))) begin
z[63] <= a_s & b_s;
z[62:52] <= b_e[10:0] + 1023;
z[51:0] <= b_m[55:3];
state <= put_z;
//if a is zero return b
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= b_s;
z[62:52] <= b_e[10:0] + 1023;
z[51:0] <= b_m[55:3];
state <= put_z;
//if b is zero return a
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s;
z[62:52] <= a_e[10:0] + 1023;
z[51:0] <= a_m[55:3];
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[55] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[55] <= 1;
end
state <= align;
end
end
align:
begin
if ($signed(a_e) > $signed(b_e)) begin
b_e <= b_e + 1;
b_m <= b_m >> 1;
b_m[0] <= b_m[0] | b_m[1];
end else if ($signed(a_e) < $signed(b_e)) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
a_m[0] <= a_m[0] | a_m[1];
end else begin
state <= add_0;
end
end
add_0:
begin
z_e <= a_e;
if (a_s == b_s) begin
sum <= {1'd0, a_m} + b_m;
z_s <= a_s;
end else begin
if (a_m > b_m) begin
sum <= {1'd0, a_m} - b_m;
z_s <= a_s;
end else begin
sum <= {1'd0, b_m} - a_m;
z_s <= b_s;
end
end
state <= add_1;
end
add_1:
begin
if (sum[56]) begin
z_m <= sum[56:4];
guard <= sum[3];
round_bit <= sum[2];
sticky <= sum[1] | sum[0];
z_e <= z_e + 1;
end else begin
z_m <= sum[55:3];
guard <= sum[2];
round_bit <= sum[1];
sticky <= sum[0];
end
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0 && $signed(z_e) > -1022) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'h1fffffffffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[10:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module int_to_float(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [2:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
convert_1 = 3'd2,
convert_2 = 3'd3,
round = 3'd4,
pack = 3'd5,
put_z = 3'd6;
reg [31:0] a, z, value;
reg [23:0] z_m;
reg [7:0] z_r;
reg [7:0] z_e;
reg z_s;
reg guard, round_bit, sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
if ( a == 0 ) begin
z_s <= 0;
z_m <= 0;
z_e <= -127;
state <= pack;
end else begin
value <= a[31] ? -a : a;
z_s <= a[31];
state <= convert_1;
end
end
convert_1:
begin
z_e <= 31;
z_m <= value[31:8];
z_r <= value[7:0];
state <= convert_2;
end
convert_2:
begin
if (!z_m[23]) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= z_r[7];
z_r <= z_r << 1;
end else begin
guard <= z_r[7];
round_bit <= z_r[6];
sticky <= z_r[5:0] != 0;
state <= round;
end
end
round:
begin
if (guard && (round_bit || sticky || z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e + 127;
z[31] <= z_s;
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module float_to_int(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg [2:0] state;
parameter get_a = 3'd0,
special_cases = 3'd1,
unpack = 3'd2,
convert = 3'd3,
put_z = 3'd4;
reg [31:0] a_m, a, z;
reg [8:0] a_e;
reg a_s;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m[31:8] <= {1'b1, a[22 : 0]};
a_m[7:0] <= 0;
a_e <= a[30 : 23] - 127;
a_s <= a[31];
state <= special_cases;
end
special_cases:
begin
if ($signed(a_e) == -127) begin
z <= 0;
state <= put_z;
end else if ($signed(a_e) > 31) begin
z <= 32'h80000000;
state <= put_z;
end else begin
state <= convert;
end
end
convert:
begin
if ($signed(a_e) < 31 && a_m) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
end else begin
if (a_m[31]) begin
z <= 32'h80000000;
end else begin
z <= a_s ? -a_m : a_m;
end
state <= put_z;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module long_to_double(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [2:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
convert_1 = 3'd2,
convert_2 = 3'd3,
round = 3'd4,
pack = 3'd5,
put_z = 3'd6;
reg [63:0] a, z, value;
reg [52:0] z_m;
reg [10:0] z_r;
reg [10:0] z_e;
reg z_s;
reg guard, round_bit, sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
if ( a == 0 ) begin
z_s <= 0;
z_m <= 0;
z_e <= -1023;
state <= pack;
end else begin
value <= a[63] ? -a : a;
z_s <= a[63];
state <= convert_1;
end
end
convert_1:
begin
z_e <= 63;
z_m <= value[63:11];
z_r <= value[10:0];
state <= convert_2;
end
convert_2:
begin
if (!z_m[52]) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= z_r[10];
z_r <= z_r << 1;
end else begin
guard <= z_r[10];
round_bit <= z_r[9];
sticky <= z_r[8:0] != 0;
state <= round;
end
end
round:
begin
if (guard && (round_bit || sticky || z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'h1fffffffffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e + 1023;
z[63] <= z_s;
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
module double_to_long(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg [2:0] state;
parameter get_a = 3'd0,
special_cases = 3'd1,
unpack = 3'd2,
convert = 3'd3,
put_z = 3'd4;
reg [63:0] a_m, a, z;
reg [11:0] a_e;
reg a_s;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m[63:11] <= {1'b1, a[51 : 0]};
a_m[10:0] <= 0;
a_e <= a[62 : 52] - 1023;
a_s <= a[63];
state <= special_cases;
end
special_cases:
begin
if ($signed(a_e) == -1023) begin
//zero
z <= 0;
state <= put_z;
end else if ($signed(a_e) == 1024 && a[51:0] != 0) begin
//nan
z <= 64'h8000000000000000;
state <= put_z;
end else if ($signed(a_e) > 63) begin
//too big
if (a_s) begin
z <= 64'h8000000000000000;
end else begin
z <= 64'h0000000000000000;
end
state <= put_z;
end else begin
state <= convert;
end
end
convert:
begin
if ($signed(a_e) < 63 && a_m) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
end else begin
if (a_m[63] && a_s) begin
z <= 64'h8000000000000000;
end else begin
z <= a_s ? -a_m : a_m;
end
state <= put_z;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module float_to_double(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [1:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
normalise_0 = 3'd2,
put_z = 3'd3;
reg [63:0] z;
reg [10:0] z_e;
reg [52:0] z_m;
reg [31:0] a;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
z[63] <= a[31];
z[62:52] <= (a[30:23] - 127) + 1023;
z[51:0] <= {a[22:0], 29'd0};
if (a[30:23] == 255) begin
z[62:52] <= 2047;
end
state <= put_z;
if (a[30:23] == 0) begin
if (a[23:0]) begin
state <= normalise_0;
z_e <= 897;
z_m <= {1'd0, a[22:0], 29'd0};
end
z[62:52] <= 0;
end
end
normalise_0:
begin
if (z_m[52]) begin
z[62:52] <= z_e;
z[51:0] <= z_m[51:0];
state <= put_z;
end else begin
z_m <= {z_m[51:0], 1'd0};
z_e <= z_e - 1;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
module double_to_float(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg [1:0] state;
parameter get_a = 3'd0,
unpack = 3'd1,
denormalise = 3'd2,
put_z = 3'd3;
reg [63:0] a;
reg [31:0] z;
reg [10:0] z_e;
reg [23:0] z_m;
reg guard;
reg round;
reg sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
z[31] <= a[63];
state <= put_z;
if (a[62:52] == 0) begin
z[30:23] <= 0;
z[22:0] <= 0;
end else if (a[62:52] < 897) begin
z[30:23] <= 0;
z_m <= {1'd1, a[51:29]};
z_e <= a[62:52];
guard <= a[28];
round <= a[27];
sticky <= a[26:0] != 0;
state <= denormalise;
end else if (a[62:52] == 2047) begin
z[30:23] <= 255;
z[22:0] <= 0;
if (a[51:0]) begin
z[22] <= 1;
end
end else if (a[62:52] > 1150) begin
z[30:23] <= 255;
z[22:0] <= 0;
end else begin
z[30:23] <= (a[62:52] - 1023) + 127;
if (a[28] && (a[27] || a[26:0])) begin
z[22:0] <= a[51:29] + 1;
end else begin
z[22:0] <= a[51:29];
end
end
end
denormalise:
begin
if (z_e == 897 || (z_m == 0 && guard == 0)) begin
state <= put_z;
z[22:0] <= z_m;
if (guard && (round || sticky)) begin
z[22:0] <= z_m + 1;
end
end else begin
z_e <= z_e + 1;
z_m <= {1'd0, z_m[23:1]};
guard <= z_m[0];
round <= guard;
sticky <= sticky | round;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
|
//IEEE Floating Point Adder (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module adder(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
align = 4'd4,
add_0 = 4'd5,
add_1 = 4'd6,
normalise_1 = 4'd7,
normalise_2 = 4'd8,
round = 4'd9,
pack = 4'd10,
put_z = 4'd11;
reg [31:0] a, b, z;
reg [26:0] a_m, b_m;
reg [23:0] z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [27:0] sum;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= {a[22 : 0], 3'd0};
b_m <= {b[22 : 0], 3'd0};
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is inf return inf
end else if (b_e == 128) begin
z[31] <= b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if a is zero return b
end else if ((($signed(a_e) == -127) && (a_m == 0)) && (($signed(b_e) == -127) && (b_m == 0))) begin
z[31] <= a_s & b_s;
z[30:23] <= b_e[7:0] + 127;
z[22:0] <= b_m[26:3];
state <= put_z;
//if a is zero return b
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= b_s;
z[30:23] <= b_e[7:0] + 127;
z[22:0] <= b_m[26:3];
state <= put_z;
//if b is zero return a
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s;
z[30:23] <= a_e[7:0] + 127;
z[22:0] <= a_m[26:3];
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[26] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[26] <= 1;
end
state <= align;
end
end
align:
begin
if ($signed(a_e) > $signed(b_e)) begin
b_e <= b_e + 1;
b_m <= b_m >> 1;
b_m[0] <= b_m[0] | b_m[1];
end else if ($signed(a_e) < $signed(b_e)) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
a_m[0] <= a_m[0] | a_m[1];
end else begin
state <= add_0;
end
end
add_0:
begin
z_e <= a_e;
if (a_s == b_s) begin
sum <= a_m + b_m;
z_s <= a_s;
end else begin
if (a_m >= b_m) begin
sum <= a_m - b_m;
z_s <= a_s;
end else begin
sum <= b_m - a_m;
z_s <= b_s;
end
end
state <= add_1;
end
add_1:
begin
if (sum[27]) begin
z_m <= sum[27:4];
guard <= sum[3];
round_bit <= sum[2];
sticky <= sum[1] | sum[0];
z_e <= z_e + 1;
end else begin
z_m <= sum[26:3];
guard <= sum[2];
round_bit <= sum[1];
sticky <= sum[0];
end
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0 && $signed(z_e) > -126) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Divider (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
//
module divider(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
divide_0 = 4'd6,
divide_1 = 4'd7,
divide_2 = 4'd8,
divide_3 = 4'd9,
normalise_1 = 4'd10,
normalise_2 = 4'd11,
round = 4'd12,
pack = 4'd13,
put_z = 4'd14;
reg [31:0] a, b, z;
reg [23:0] a_m, b_m, z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [50:0] quotient, divisor, dividend, remainder;
reg [5:0] count;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[22 : 0];
b_m <= b[22 : 0];
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf and b is inf return NaN
end else if ((a_e == 128) && (b_e == 128)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is inf return zero
end else if (b_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is zero return inf
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[23] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[23] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[23]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[23]) begin
state <= divide_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
divide_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e - b_e;
quotient <= 0;
remainder <= 0;
count <= 0;
dividend <= a_m << 27;
divisor <= b_m;
state <= divide_1;
end
divide_1:
begin
quotient <= quotient << 1;
remainder <= remainder << 1;
remainder[0] <= dividend[50];
dividend <= dividend << 1;
state <= divide_2;
end
divide_2:
begin
if (remainder >= divisor) begin
quotient[0] <= 1;
remainder <= remainder - divisor;
end
if (count == 49) begin
state <= divide_3;
end else begin
count <= count + 1;
state <= divide_1;
end
end
divide_3:
begin
z_m <= quotient[26:3];
guard <= quotient[2];
round_bit <= quotient[1];
sticky <= quotient[0] | (remainder != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0 && $signed(z_e) > -126) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Multiplier (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module multiplier(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
multiply_0 = 4'd6,
multiply_1 = 4'd7,
normalise_1 = 4'd8,
normalise_2 = 4'd9,
round = 4'd10,
pack = 4'd11,
put_z = 4'd12;
reg [31:0] a, b, z;
reg [23:0] a_m, b_m, z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [49:0] product;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[22 : 0];
b_m <= b[22 : 0];
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is inf return inf
end else if (b_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if b is zero return zero
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[23] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[23] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[23]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[23]) begin
state <= multiply_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
multiply_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e + b_e + 1;
product <= a_m * b_m * 4;
state <= multiply_1;
end
multiply_1:
begin
z_m <= product[49:26];
guard <= product[25];
round_bit <= product[24];
sticky <= (product[23:0] != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Divider (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
//
module double_divider(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
divide_0 = 4'd6,
divide_1 = 4'd7,
divide_2 = 4'd8,
divide_3 = 4'd9,
normalise_1 = 4'd10,
normalise_2 = 4'd11,
round = 4'd12,
pack = 4'd13,
put_z = 4'd14;
reg [63:0] a, b, z;
reg [52:0] a_m, b_m, z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [108:0] quotient, divisor, dividend, remainder;
reg [6:0] count;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[51 : 0];
b_m <= b[51 : 0];
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf and b is inf return NaN
end else if ((a_e == 1024) && (b_e == 1024)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is inf return zero
end else if (b_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is zero return inf
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[52] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[52] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[52]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[52]) begin
state <= divide_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
divide_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e - b_e;
quotient <= 0;
remainder <= 0;
count <= 0;
dividend <= a_m << 56;
divisor <= b_m;
state <= divide_1;
end
divide_1:
begin
quotient <= quotient << 1;
remainder <= remainder << 1;
remainder[0] <= dividend[108];
dividend <= dividend << 1;
state <= divide_2;
end
divide_2:
begin
if (remainder >= divisor) begin
quotient[0] <= 1;
remainder <= remainder - divisor;
end
if (count == 107) begin
state <= divide_3;
end else begin
count <= count + 1;
state <= divide_1;
end
end
divide_3:
begin
z_m <= quotient[55:3];
guard <= quotient[2];
round_bit <= quotient[1];
sticky <= quotient[0] | (remainder != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0 && $signed(z_e) > -1022) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[10:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Multiplier (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-10
module double_multiplier(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
multiply_0 = 4'd6,
multiply_1 = 4'd7,
normalise_1 = 4'd8,
normalise_2 = 4'd9,
round = 4'd10,
pack = 4'd11,
put_z = 4'd12;
reg [63:0] a, b, z;
reg [52:0] a_m, b_m, z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [107:0] product;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[51 : 0];
b_m <= b[51 : 0];
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is inf return inf
end else if (b_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if b is zero return zero
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[52] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[52] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[52]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[52]) begin
state <= multiply_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
multiply_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e + b_e + 1;
product <= a_m * b_m * 4;
state <= multiply_1;
end
multiply_1:
begin
z_m <= product[107:55];
guard <= product[54];
round_bit <= product[53];
sticky <= (product[52:0] != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[11:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Adder (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module double_adder(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
align = 4'd4,
add_0 = 4'd5,
add_1 = 4'd6,
normalise_1 = 4'd7,
normalise_2 = 4'd8,
round = 4'd9,
pack = 4'd10,
put_z = 4'd11;
reg [63:0] a, b, z;
reg [55:0] a_m, b_m;
reg [52:0] z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [56:0] sum;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= {a[51 : 0], 3'd0};
b_m <= {b[51 : 0], 3'd0};
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is inf return inf
end else if (b_e == 1024) begin
z[63] <= b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if a is zero return b
end else if ((($signed(a_e) == -1023) && (a_m == 0)) && (($signed(b_e) == -1023) && (b_m == 0))) begin
z[63] <= a_s & b_s;
z[62:52] <= b_e[10:0] + 1023;
z[51:0] <= b_m[55:3];
state <= put_z;
//if a is zero return b
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= b_s;
z[62:52] <= b_e[10:0] + 1023;
z[51:0] <= b_m[55:3];
state <= put_z;
//if b is zero return a
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s;
z[62:52] <= a_e[10:0] + 1023;
z[51:0] <= a_m[55:3];
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[55] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[55] <= 1;
end
state <= align;
end
end
align:
begin
if ($signed(a_e) > $signed(b_e)) begin
b_e <= b_e + 1;
b_m <= b_m >> 1;
b_m[0] <= b_m[0] | b_m[1];
end else if ($signed(a_e) < $signed(b_e)) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
a_m[0] <= a_m[0] | a_m[1];
end else begin
state <= add_0;
end
end
add_0:
begin
z_e <= a_e;
if (a_s == b_s) begin
sum <= {1'd0, a_m} + b_m;
z_s <= a_s;
end else begin
if (a_m > b_m) begin
sum <= {1'd0, a_m} - b_m;
z_s <= a_s;
end else begin
sum <= {1'd0, b_m} - a_m;
z_s <= b_s;
end
end
state <= add_1;
end
add_1:
begin
if (sum[56]) begin
z_m <= sum[56:4];
guard <= sum[3];
round_bit <= sum[2];
sticky <= sum[1] | sum[0];
z_e <= z_e + 1;
end else begin
z_m <= sum[55:3];
guard <= sum[2];
round_bit <= sum[1];
sticky <= sum[0];
end
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0 && $signed(z_e) > -1022) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'h1fffffffffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[10:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module int_to_float(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [2:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
convert_1 = 3'd2,
convert_2 = 3'd3,
round = 3'd4,
pack = 3'd5,
put_z = 3'd6;
reg [31:0] a, z, value;
reg [23:0] z_m;
reg [7:0] z_r;
reg [7:0] z_e;
reg z_s;
reg guard, round_bit, sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
if ( a == 0 ) begin
z_s <= 0;
z_m <= 0;
z_e <= -127;
state <= pack;
end else begin
value <= a[31] ? -a : a;
z_s <= a[31];
state <= convert_1;
end
end
convert_1:
begin
z_e <= 31;
z_m <= value[31:8];
z_r <= value[7:0];
state <= convert_2;
end
convert_2:
begin
if (!z_m[23]) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= z_r[7];
z_r <= z_r << 1;
end else begin
guard <= z_r[7];
round_bit <= z_r[6];
sticky <= z_r[5:0] != 0;
state <= round;
end
end
round:
begin
if (guard && (round_bit || sticky || z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e + 127;
z[31] <= z_s;
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module float_to_int(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg [2:0] state;
parameter get_a = 3'd0,
special_cases = 3'd1,
unpack = 3'd2,
convert = 3'd3,
put_z = 3'd4;
reg [31:0] a_m, a, z;
reg [8:0] a_e;
reg a_s;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m[31:8] <= {1'b1, a[22 : 0]};
a_m[7:0] <= 0;
a_e <= a[30 : 23] - 127;
a_s <= a[31];
state <= special_cases;
end
special_cases:
begin
if ($signed(a_e) == -127) begin
z <= 0;
state <= put_z;
end else if ($signed(a_e) > 31) begin
z <= 32'h80000000;
state <= put_z;
end else begin
state <= convert;
end
end
convert:
begin
if ($signed(a_e) < 31 && a_m) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
end else begin
if (a_m[31]) begin
z <= 32'h80000000;
end else begin
z <= a_s ? -a_m : a_m;
end
state <= put_z;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module long_to_double(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [2:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
convert_1 = 3'd2,
convert_2 = 3'd3,
round = 3'd4,
pack = 3'd5,
put_z = 3'd6;
reg [63:0] a, z, value;
reg [52:0] z_m;
reg [10:0] z_r;
reg [10:0] z_e;
reg z_s;
reg guard, round_bit, sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
if ( a == 0 ) begin
z_s <= 0;
z_m <= 0;
z_e <= -1023;
state <= pack;
end else begin
value <= a[63] ? -a : a;
z_s <= a[63];
state <= convert_1;
end
end
convert_1:
begin
z_e <= 63;
z_m <= value[63:11];
z_r <= value[10:0];
state <= convert_2;
end
convert_2:
begin
if (!z_m[52]) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= z_r[10];
z_r <= z_r << 1;
end else begin
guard <= z_r[10];
round_bit <= z_r[9];
sticky <= z_r[8:0] != 0;
state <= round;
end
end
round:
begin
if (guard && (round_bit || sticky || z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'h1fffffffffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e + 1023;
z[63] <= z_s;
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
module double_to_long(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg [2:0] state;
parameter get_a = 3'd0,
special_cases = 3'd1,
unpack = 3'd2,
convert = 3'd3,
put_z = 3'd4;
reg [63:0] a_m, a, z;
reg [11:0] a_e;
reg a_s;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m[63:11] <= {1'b1, a[51 : 0]};
a_m[10:0] <= 0;
a_e <= a[62 : 52] - 1023;
a_s <= a[63];
state <= special_cases;
end
special_cases:
begin
if ($signed(a_e) == -1023) begin
//zero
z <= 0;
state <= put_z;
end else if ($signed(a_e) == 1024 && a[51:0] != 0) begin
//nan
z <= 64'h8000000000000000;
state <= put_z;
end else if ($signed(a_e) > 63) begin
//too big
if (a_s) begin
z <= 64'h8000000000000000;
end else begin
z <= 64'h0000000000000000;
end
state <= put_z;
end else begin
state <= convert;
end
end
convert:
begin
if ($signed(a_e) < 63 && a_m) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
end else begin
if (a_m[63] && a_s) begin
z <= 64'h8000000000000000;
end else begin
z <= a_s ? -a_m : a_m;
end
state <= put_z;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module float_to_double(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [1:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
normalise_0 = 3'd2,
put_z = 3'd3;
reg [63:0] z;
reg [10:0] z_e;
reg [52:0] z_m;
reg [31:0] a;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
z[63] <= a[31];
z[62:52] <= (a[30:23] - 127) + 1023;
z[51:0] <= {a[22:0], 29'd0};
if (a[30:23] == 255) begin
z[62:52] <= 2047;
end
state <= put_z;
if (a[30:23] == 0) begin
if (a[23:0]) begin
state <= normalise_0;
z_e <= 897;
z_m <= {1'd0, a[22:0], 29'd0};
end
z[62:52] <= 0;
end
end
normalise_0:
begin
if (z_m[52]) begin
z[62:52] <= z_e;
z[51:0] <= z_m[51:0];
state <= put_z;
end else begin
z_m <= {z_m[51:0], 1'd0};
z_e <= z_e - 1;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
module double_to_float(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg [1:0] state;
parameter get_a = 3'd0,
unpack = 3'd1,
denormalise = 3'd2,
put_z = 3'd3;
reg [63:0] a;
reg [31:0] z;
reg [10:0] z_e;
reg [23:0] z_m;
reg guard;
reg round;
reg sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
z[31] <= a[63];
state <= put_z;
if (a[62:52] == 0) begin
z[30:23] <= 0;
z[22:0] <= 0;
end else if (a[62:52] < 897) begin
z[30:23] <= 0;
z_m <= {1'd1, a[51:29]};
z_e <= a[62:52];
guard <= a[28];
round <= a[27];
sticky <= a[26:0] != 0;
state <= denormalise;
end else if (a[62:52] == 2047) begin
z[30:23] <= 255;
z[22:0] <= 0;
if (a[51:0]) begin
z[22] <= 1;
end
end else if (a[62:52] > 1150) begin
z[30:23] <= 255;
z[22:0] <= 0;
end else begin
z[30:23] <= (a[62:52] - 1023) + 127;
if (a[28] && (a[27] || a[26:0])) begin
z[22:0] <= a[51:29] + 1;
end else begin
z[22:0] <= a[51:29];
end
end
end
denormalise:
begin
if (z_e == 897 || (z_m == 0 && guard == 0)) begin
state <= put_z;
z[22:0] <= z_m;
if (guard && (round || sticky)) begin
z[22:0] <= z_m + 1;
end
end else begin
z_e <= z_e + 1;
z_m <= {1'd0, z_m[23:1]};
guard <= z_m[0];
round <= guard;
sticky <= sticky | round;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
|
//IEEE Floating Point Adder (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module adder(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
align = 4'd4,
add_0 = 4'd5,
add_1 = 4'd6,
normalise_1 = 4'd7,
normalise_2 = 4'd8,
round = 4'd9,
pack = 4'd10,
put_z = 4'd11;
reg [31:0] a, b, z;
reg [26:0] a_m, b_m;
reg [23:0] z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [27:0] sum;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= {a[22 : 0], 3'd0};
b_m <= {b[22 : 0], 3'd0};
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is inf return inf
end else if (b_e == 128) begin
z[31] <= b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if a is zero return b
end else if ((($signed(a_e) == -127) && (a_m == 0)) && (($signed(b_e) == -127) && (b_m == 0))) begin
z[31] <= a_s & b_s;
z[30:23] <= b_e[7:0] + 127;
z[22:0] <= b_m[26:3];
state <= put_z;
//if a is zero return b
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= b_s;
z[30:23] <= b_e[7:0] + 127;
z[22:0] <= b_m[26:3];
state <= put_z;
//if b is zero return a
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s;
z[30:23] <= a_e[7:0] + 127;
z[22:0] <= a_m[26:3];
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[26] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[26] <= 1;
end
state <= align;
end
end
align:
begin
if ($signed(a_e) > $signed(b_e)) begin
b_e <= b_e + 1;
b_m <= b_m >> 1;
b_m[0] <= b_m[0] | b_m[1];
end else if ($signed(a_e) < $signed(b_e)) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
a_m[0] <= a_m[0] | a_m[1];
end else begin
state <= add_0;
end
end
add_0:
begin
z_e <= a_e;
if (a_s == b_s) begin
sum <= a_m + b_m;
z_s <= a_s;
end else begin
if (a_m >= b_m) begin
sum <= a_m - b_m;
z_s <= a_s;
end else begin
sum <= b_m - a_m;
z_s <= b_s;
end
end
state <= add_1;
end
add_1:
begin
if (sum[27]) begin
z_m <= sum[27:4];
guard <= sum[3];
round_bit <= sum[2];
sticky <= sum[1] | sum[0];
z_e <= z_e + 1;
end else begin
z_m <= sum[26:3];
guard <= sum[2];
round_bit <= sum[1];
sticky <= sum[0];
end
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0 && $signed(z_e) > -126) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Divider (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
//
module divider(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
divide_0 = 4'd6,
divide_1 = 4'd7,
divide_2 = 4'd8,
divide_3 = 4'd9,
normalise_1 = 4'd10,
normalise_2 = 4'd11,
round = 4'd12,
pack = 4'd13,
put_z = 4'd14;
reg [31:0] a, b, z;
reg [23:0] a_m, b_m, z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [50:0] quotient, divisor, dividend, remainder;
reg [5:0] count;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[22 : 0];
b_m <= b[22 : 0];
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf and b is inf return NaN
end else if ((a_e == 128) && (b_e == 128)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is inf return zero
end else if (b_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is zero return inf
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[23] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[23] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[23]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[23]) begin
state <= divide_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
divide_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e - b_e;
quotient <= 0;
remainder <= 0;
count <= 0;
dividend <= a_m << 27;
divisor <= b_m;
state <= divide_1;
end
divide_1:
begin
quotient <= quotient << 1;
remainder <= remainder << 1;
remainder[0] <= dividend[50];
dividend <= dividend << 1;
state <= divide_2;
end
divide_2:
begin
if (remainder >= divisor) begin
quotient[0] <= 1;
remainder <= remainder - divisor;
end
if (count == 49) begin
state <= divide_3;
end else begin
count <= count + 1;
state <= divide_1;
end
end
divide_3:
begin
z_m <= quotient[26:3];
guard <= quotient[2];
round_bit <= quotient[1];
sticky <= quotient[0] | (remainder != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0 && $signed(z_e) > -126) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Multiplier (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module multiplier(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
input [31:0] input_b;
input input_b_stb;
output input_b_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
multiply_0 = 4'd6,
multiply_1 = 4'd7,
normalise_1 = 4'd8,
normalise_2 = 4'd9,
round = 4'd10,
pack = 4'd11,
put_z = 4'd12;
reg [31:0] a, b, z;
reg [23:0] a_m, b_m, z_m;
reg [9:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [49:0] product;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[22 : 0];
b_m <= b[22 : 0];
a_e <= a[30 : 23] - 127;
b_e <= b[30 : 23] - 127;
a_s <= a[31];
b_s <= b[31];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -127) && (b_m == 0)) begin
z[31] <= 1;
z[30:23] <= 255;
z[22] <= 1;
z[21:0] <= 0;
state <= put_z;
end
//if b is inf return inf
end else if (b_e == 128) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 255;
z[22:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -127) && (a_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
//if b is zero return zero
end else if (($signed(b_e) == -127) && (b_m == 0)) begin
z[31] <= a_s ^ b_s;
z[30:23] <= 0;
z[22:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -127) begin
a_e <= -126;
end else begin
a_m[23] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -127) begin
b_e <= -126;
end else begin
b_m[23] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[23]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[23]) begin
state <= multiply_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
multiply_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e + b_e + 1;
product <= a_m * b_m * 4;
state <= multiply_1;
end
multiply_1:
begin
z_m <= product[49:26];
guard <= product[25];
round_bit <= product[24];
sticky <= (product[23:0] != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[23] == 0) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -126) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e[7:0] + 127;
z[31] <= z_s;
if ($signed(z_e) == -126 && z_m[23] == 0) begin
z[30 : 23] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 127) begin
z[22 : 0] <= 0;
z[30 : 23] <= 255;
z[31] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Divider (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
//
module double_divider(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
divide_0 = 4'd6,
divide_1 = 4'd7,
divide_2 = 4'd8,
divide_3 = 4'd9,
normalise_1 = 4'd10,
normalise_2 = 4'd11,
round = 4'd12,
pack = 4'd13,
put_z = 4'd14;
reg [63:0] a, b, z;
reg [52:0] a_m, b_m, z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [108:0] quotient, divisor, dividend, remainder;
reg [6:0] count;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[51 : 0];
b_m <= b[51 : 0];
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf and b is inf return NaN
end else if ((a_e == 1024) && (b_e == 1024)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is inf return zero
end else if (b_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is zero return inf
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[52] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[52] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[52]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[52]) begin
state <= divide_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
divide_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e - b_e;
quotient <= 0;
remainder <= 0;
count <= 0;
dividend <= a_m << 56;
divisor <= b_m;
state <= divide_1;
end
divide_1:
begin
quotient <= quotient << 1;
remainder <= remainder << 1;
remainder[0] <= dividend[108];
dividend <= dividend << 1;
state <= divide_2;
end
divide_2:
begin
if (remainder >= divisor) begin
quotient[0] <= 1;
remainder <= remainder - divisor;
end
if (count == 107) begin
state <= divide_3;
end else begin
count <= count + 1;
state <= divide_1;
end
end
divide_3:
begin
z_m <= quotient[55:3];
guard <= quotient[2];
round_bit <= quotient[1];
sticky <= quotient[0] | (remainder != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0 && $signed(z_e) > -1022) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[10:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Multiplier (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-10
module double_multiplier(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
normalise_a = 4'd4,
normalise_b = 4'd5,
multiply_0 = 4'd6,
multiply_1 = 4'd7,
normalise_1 = 4'd8,
normalise_2 = 4'd9,
round = 4'd10,
pack = 4'd11,
put_z = 4'd12;
reg [63:0] a, b, z;
reg [52:0] a_m, b_m, z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [107:0] product;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= a[51 : 0];
b_m <= b[51 : 0];
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is zero return NaN
if ($signed(b_e == -1023) && (b_m == 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
end
//if b is inf return inf
end else if (b_e == 1024) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if a is zero return zero
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
//if b is zero return zero
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s ^ b_s;
z[62:52] <= 0;
z[51:0] <= 0;
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[52] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[52] <= 1;
end
state <= normalise_a;
end
end
normalise_a:
begin
if (a_m[52]) begin
state <= normalise_b;
end else begin
a_m <= a_m << 1;
a_e <= a_e - 1;
end
end
normalise_b:
begin
if (b_m[52]) begin
state <= multiply_0;
end else begin
b_m <= b_m << 1;
b_e <= b_e - 1;
end
end
multiply_0:
begin
z_s <= a_s ^ b_s;
z_e <= a_e + b_e + 1;
product <= a_m * b_m * 4;
state <= multiply_1;
end
multiply_1:
begin
z_m <= product[107:55];
guard <= product[54];
round_bit <= product[53];
sticky <= (product[52:0] != 0);
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[11:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point Adder (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module double_adder(
input_a,
input_b,
input_a_stb,
input_b_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack,
input_b_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
input [63:0] input_b;
input input_b_stb;
output input_b_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [3:0] state;
parameter get_a = 4'd0,
get_b = 4'd1,
unpack = 4'd2,
special_cases = 4'd3,
align = 4'd4,
add_0 = 4'd5,
add_1 = 4'd6,
normalise_1 = 4'd7,
normalise_2 = 4'd8,
round = 4'd9,
pack = 4'd10,
put_z = 4'd11;
reg [63:0] a, b, z;
reg [55:0] a_m, b_m;
reg [52:0] z_m;
reg [12:0] a_e, b_e, z_e;
reg a_s, b_s, z_s;
reg guard, round_bit, sticky;
reg [56:0] sum;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= get_b;
end
end
get_b:
begin
s_input_b_ack <= 1;
if (s_input_b_ack && input_b_stb) begin
b <= input_b;
s_input_b_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m <= {a[51 : 0], 3'd0};
b_m <= {b[51 : 0], 3'd0};
a_e <= a[62 : 52] - 1023;
b_e <= b[62 : 52] - 1023;
a_s <= a[63];
b_s <= b[63];
state <= special_cases;
end
special_cases:
begin
//if a is NaN or b is NaN return NaN
if ((a_e == 1024 && a_m != 0) || (b_e == 1024 && b_m != 0)) begin
z[63] <= 1;
z[62:52] <= 2047;
z[51] <= 1;
z[50:0] <= 0;
state <= put_z;
//if a is inf return inf
end else if (a_e == 1024) begin
z[63] <= a_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if b is inf return inf
end else if (b_e == 1024) begin
z[63] <= b_s;
z[62:52] <= 2047;
z[51:0] <= 0;
state <= put_z;
//if a is zero return b
end else if ((($signed(a_e) == -1023) && (a_m == 0)) && (($signed(b_e) == -1023) && (b_m == 0))) begin
z[63] <= a_s & b_s;
z[62:52] <= b_e[10:0] + 1023;
z[51:0] <= b_m[55:3];
state <= put_z;
//if a is zero return b
end else if (($signed(a_e) == -1023) && (a_m == 0)) begin
z[63] <= b_s;
z[62:52] <= b_e[10:0] + 1023;
z[51:0] <= b_m[55:3];
state <= put_z;
//if b is zero return a
end else if (($signed(b_e) == -1023) && (b_m == 0)) begin
z[63] <= a_s;
z[62:52] <= a_e[10:0] + 1023;
z[51:0] <= a_m[55:3];
state <= put_z;
end else begin
//Denormalised Number
if ($signed(a_e) == -1023) begin
a_e <= -1022;
end else begin
a_m[55] <= 1;
end
//Denormalised Number
if ($signed(b_e) == -1023) begin
b_e <= -1022;
end else begin
b_m[55] <= 1;
end
state <= align;
end
end
align:
begin
if ($signed(a_e) > $signed(b_e)) begin
b_e <= b_e + 1;
b_m <= b_m >> 1;
b_m[0] <= b_m[0] | b_m[1];
end else if ($signed(a_e) < $signed(b_e)) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
a_m[0] <= a_m[0] | a_m[1];
end else begin
state <= add_0;
end
end
add_0:
begin
z_e <= a_e;
if (a_s == b_s) begin
sum <= {1'd0, a_m} + b_m;
z_s <= a_s;
end else begin
if (a_m > b_m) begin
sum <= {1'd0, a_m} - b_m;
z_s <= a_s;
end else begin
sum <= {1'd0, b_m} - a_m;
z_s <= b_s;
end
end
state <= add_1;
end
add_1:
begin
if (sum[56]) begin
z_m <= sum[56:4];
guard <= sum[3];
round_bit <= sum[2];
sticky <= sum[1] | sum[0];
z_e <= z_e + 1;
end else begin
z_m <= sum[55:3];
guard <= sum[2];
round_bit <= sum[1];
sticky <= sum[0];
end
state <= normalise_1;
end
normalise_1:
begin
if (z_m[52] == 0 && $signed(z_e) > -1022) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= guard;
guard <= round_bit;
round_bit <= 0;
end else begin
state <= normalise_2;
end
end
normalise_2:
begin
if ($signed(z_e) < -1022) begin
z_e <= z_e + 1;
z_m <= z_m >> 1;
guard <= z_m[0];
round_bit <= guard;
sticky <= sticky | round_bit;
end else begin
state <= round;
end
end
round:
begin
if (guard && (round_bit | sticky | z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'h1fffffffffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e[10:0] + 1023;
z[63] <= z_s;
if ($signed(z_e) == -1022 && z_m[52] == 0) begin
z[62 : 52] <= 0;
end
//if overflow occurs, return inf
if ($signed(z_e) > 1023) begin
z[51 : 0] <= 0;
z[62 : 52] <= 2047;
z[63] <= z_s;
end
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_input_b_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign input_b_ack = s_input_b_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module int_to_float(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [2:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
convert_1 = 3'd2,
convert_2 = 3'd3,
round = 3'd4,
pack = 3'd5,
put_z = 3'd6;
reg [31:0] a, z, value;
reg [23:0] z_m;
reg [7:0] z_r;
reg [7:0] z_e;
reg z_s;
reg guard, round_bit, sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
if ( a == 0 ) begin
z_s <= 0;
z_m <= 0;
z_e <= -127;
state <= pack;
end else begin
value <= a[31] ? -a : a;
z_s <= a[31];
state <= convert_1;
end
end
convert_1:
begin
z_e <= 31;
z_m <= value[31:8];
z_r <= value[7:0];
state <= convert_2;
end
convert_2:
begin
if (!z_m[23]) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= z_r[7];
z_r <= z_r << 1;
end else begin
guard <= z_r[7];
round_bit <= z_r[6];
sticky <= z_r[5:0] != 0;
state <= round;
end
end
round:
begin
if (guard && (round_bit || sticky || z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 24'hffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[22 : 0] <= z_m[22:0];
z[30 : 23] <= z_e + 127;
z[31] <= z_s;
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Single Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module float_to_int(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg [2:0] state;
parameter get_a = 3'd0,
special_cases = 3'd1,
unpack = 3'd2,
convert = 3'd3,
put_z = 3'd4;
reg [31:0] a_m, a, z;
reg [8:0] a_e;
reg a_s;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m[31:8] <= {1'b1, a[22 : 0]};
a_m[7:0] <= 0;
a_e <= a[30 : 23] - 127;
a_s <= a[31];
state <= special_cases;
end
special_cases:
begin
if ($signed(a_e) == -127) begin
z <= 0;
state <= put_z;
end else if ($signed(a_e) > 31) begin
z <= 32'h80000000;
state <= put_z;
end else begin
state <= convert;
end
end
convert:
begin
if ($signed(a_e) < 31 && a_m) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
end else begin
if (a_m[31]) begin
z <= 32'h80000000;
end else begin
z <= a_s ? -a_m : a_m;
end
state <= put_z;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module long_to_double(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [2:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
convert_1 = 3'd2,
convert_2 = 3'd3,
round = 3'd4,
pack = 3'd5,
put_z = 3'd6;
reg [63:0] a, z, value;
reg [52:0] z_m;
reg [10:0] z_r;
reg [10:0] z_e;
reg z_s;
reg guard, round_bit, sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
if ( a == 0 ) begin
z_s <= 0;
z_m <= 0;
z_e <= -1023;
state <= pack;
end else begin
value <= a[63] ? -a : a;
z_s <= a[63];
state <= convert_1;
end
end
convert_1:
begin
z_e <= 63;
z_m <= value[63:11];
z_r <= value[10:0];
state <= convert_2;
end
convert_2:
begin
if (!z_m[52]) begin
z_e <= z_e - 1;
z_m <= z_m << 1;
z_m[0] <= z_r[10];
z_r <= z_r << 1;
end else begin
guard <= z_r[10];
round_bit <= z_r[9];
sticky <= z_r[8:0] != 0;
state <= round;
end
end
round:
begin
if (guard && (round_bit || sticky || z_m[0])) begin
z_m <= z_m + 1;
if (z_m == 53'h1fffffffffffff) begin
z_e <=z_e + 1;
end
end
state <= pack;
end
pack:
begin
z[51 : 0] <= z_m[51:0];
z[62 : 52] <= z_e + 1023;
z[63] <= z_s;
state <= put_z;
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
module double_to_long(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg [2:0] state;
parameter get_a = 3'd0,
special_cases = 3'd1,
unpack = 3'd2,
convert = 3'd3,
put_z = 3'd4;
reg [63:0] a_m, a, z;
reg [11:0] a_e;
reg a_s;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
a_m[63:11] <= {1'b1, a[51 : 0]};
a_m[10:0] <= 0;
a_e <= a[62 : 52] - 1023;
a_s <= a[63];
state <= special_cases;
end
special_cases:
begin
if ($signed(a_e) == -1023) begin
//zero
z <= 0;
state <= put_z;
end else if ($signed(a_e) == 1024 && a[51:0] != 0) begin
//nan
z <= 64'h8000000000000000;
state <= put_z;
end else if ($signed(a_e) > 63) begin
//too big
if (a_s) begin
z <= 64'h8000000000000000;
end else begin
z <= 64'h0000000000000000;
end
state <= put_z;
end else begin
state <= convert;
end
end
convert:
begin
if ($signed(a_e) < 63 && a_m) begin
a_e <= a_e + 1;
a_m <= a_m >> 1;
end else begin
if (a_m[63] && a_s) begin
z <= 64'h8000000000000000;
end else begin
z <= a_s ? -a_m : a_m;
end
state <= put_z;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//Integer to IEEE Floating Point Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2013
//2013-12-12
module float_to_double(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [31:0] input_a;
input input_a_stb;
output input_a_ack;
output [63:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [63:0] s_output_z;
reg s_input_a_ack;
reg s_input_b_ack;
reg [1:0] state;
parameter get_a = 3'd0,
convert_0 = 3'd1,
normalise_0 = 3'd2,
put_z = 3'd3;
reg [63:0] z;
reg [10:0] z_e;
reg [52:0] z_m;
reg [31:0] a;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= convert_0;
end
end
convert_0:
begin
z[63] <= a[31];
z[62:52] <= (a[30:23] - 127) + 1023;
z[51:0] <= {a[22:0], 29'd0};
if (a[30:23] == 255) begin
z[62:52] <= 2047;
end
state <= put_z;
if (a[30:23] == 0) begin
if (a[23:0]) begin
state <= normalise_0;
z_e <= 897;
z_m <= {1'd0, a[22:0], 29'd0};
end
z[62:52] <= 0;
end
end
normalise_0:
begin
if (z_m[52]) begin
z[62:52] <= z_e;
z[51:0] <= z_m[51:0];
state <= put_z;
end else begin
z_m <= {z_m[51:0], 1'd0};
z_e <= z_e - 1;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
//IEEE Floating Point to Integer Converter (Double Precision)
//Copyright (C) Jonathan P Dawson 2014
//2014-01-11
module double_to_float(
input_a,
input_a_stb,
output_z_ack,
clk,
rst,
output_z,
output_z_stb,
input_a_ack);
input clk;
input rst;
input [63:0] input_a;
input input_a_stb;
output input_a_ack;
output [31:0] output_z;
output output_z_stb;
input output_z_ack;
reg s_output_z_stb;
reg [31:0] s_output_z;
reg s_input_a_ack;
reg [1:0] state;
parameter get_a = 3'd0,
unpack = 3'd1,
denormalise = 3'd2,
put_z = 3'd3;
reg [63:0] a;
reg [31:0] z;
reg [10:0] z_e;
reg [23:0] z_m;
reg guard;
reg round;
reg sticky;
always @(posedge clk)
begin
case(state)
get_a:
begin
s_input_a_ack <= 1;
if (s_input_a_ack && input_a_stb) begin
a <= input_a;
s_input_a_ack <= 0;
state <= unpack;
end
end
unpack:
begin
z[31] <= a[63];
state <= put_z;
if (a[62:52] == 0) begin
z[30:23] <= 0;
z[22:0] <= 0;
end else if (a[62:52] < 897) begin
z[30:23] <= 0;
z_m <= {1'd1, a[51:29]};
z_e <= a[62:52];
guard <= a[28];
round <= a[27];
sticky <= a[26:0] != 0;
state <= denormalise;
end else if (a[62:52] == 2047) begin
z[30:23] <= 255;
z[22:0] <= 0;
if (a[51:0]) begin
z[22] <= 1;
end
end else if (a[62:52] > 1150) begin
z[30:23] <= 255;
z[22:0] <= 0;
end else begin
z[30:23] <= (a[62:52] - 1023) + 127;
if (a[28] && (a[27] || a[26:0])) begin
z[22:0] <= a[51:29] + 1;
end else begin
z[22:0] <= a[51:29];
end
end
end
denormalise:
begin
if (z_e == 897 || (z_m == 0 && guard == 0)) begin
state <= put_z;
z[22:0] <= z_m;
if (guard && (round || sticky)) begin
z[22:0] <= z_m + 1;
end
end else begin
z_e <= z_e + 1;
z_m <= {1'd0, z_m[23:1]};
guard <= z_m[0];
round <= guard;
sticky <= sticky | round;
end
end
put_z:
begin
s_output_z_stb <= 1;
s_output_z <= z;
if (s_output_z_stb && output_z_ack) begin
s_output_z_stb <= 0;
state <= get_a;
end
end
endcase
if (rst == 1) begin
state <= get_a;
s_input_a_ack <= 0;
s_output_z_stb <= 0;
end
end
assign input_a_ack = s_input_a_ack;
assign output_z_stb = s_output_z_stb;
assign output_z = s_output_z;
endmodule
|
`include "lo_read.v"
/*
pck0 - input main 24Mhz clock (PLL / 4)
[7:0] adc_d - input data from A/D converter
lo_is_125khz - input freq selector (1=125Khz, 0=136Khz)
pwr_lo - output to coil drivers (ssp_clk / 8)
adc_clk - output A/D clock signal
ssp_frame - output SSS frame indicator (goes high while the 8 bits are shifted)
ssp_din - output SSP data to ARM (shifts 8 bit A/D value serially to ARM MSB first)
ssp_clk - output SSP clock signal 1Mhz/1.09Mhz (pck0 / 2*(11+lo_is_125khz) )
ck_1356meg - input unused
ck_1356megb - input unused
ssp_dout - input unused
cross_hi - input unused
cross_lo - input unused
pwr_hi - output unused, tied low
pwr_oe1 - output unused, undefined
pwr_oe2 - output unused, undefined
pwr_oe3 - output unused, undefined
pwr_oe4 - output unused, undefined
dbg - output alias for adc_clk
*/
module testbed_lo_read;
reg pck0;
reg [7:0] adc_d;
reg lo_is_125khz;
reg [15:0] divisor;
wire pwr_lo;
wire adc_clk;
wire ck_1356meg;
wire ck_1356megb;
wire ssp_frame;
wire ssp_din;
wire ssp_clk;
reg ssp_dout;
wire pwr_hi;
wire pwr_oe1;
wire pwr_oe2;
wire pwr_oe3;
wire pwr_oe4;
wire cross_lo;
wire cross_hi;
wire dbg;
lo_read #(5,10) dut(
.pck0(pck0),
.ck_1356meg(ck_1356meg),
.ck_1356megb(ck_1356megb),
.pwr_lo(pwr_lo),
.pwr_hi(pwr_hi),
.pwr_oe1(pwr_oe1),
.pwr_oe2(pwr_oe2),
.pwr_oe3(pwr_oe3),
.pwr_oe4(pwr_oe4),
.adc_d(adc_d),
.adc_clk(adc_clk),
.ssp_frame(ssp_frame),
.ssp_din(ssp_din),
.ssp_dout(ssp_dout),
.ssp_clk(ssp_clk),
.cross_hi(cross_hi),
.cross_lo(cross_lo),
.dbg(dbg),
.lo_is_125khz(lo_is_125khz),
.divisor(divisor)
);
integer idx, i, adc_val=8;
// main clock
always #5 pck0 = !pck0;
task crank_dut;
begin
@(posedge adc_clk) ;
adc_d = adc_val;
adc_val = (adc_val *2) + 53;
end
endtask
initial begin
// init inputs
pck0 = 0;
adc_d = 0;
ssp_dout = 0;
lo_is_125khz = 1;
divisor = 255; //min 16, 95=125Khz, max 255
// simulate 4 A/D cycles at 125Khz
for (i = 0 ; i < 8 ; i = i + 1) begin
crank_dut;
end
$finish;
end
endmodule // main
|
`include "lo_read.v"
/*
pck0 - input main 24Mhz clock (PLL / 4)
[7:0] adc_d - input data from A/D converter
lo_is_125khz - input freq selector (1=125Khz, 0=136Khz)
pwr_lo - output to coil drivers (ssp_clk / 8)
adc_clk - output A/D clock signal
ssp_frame - output SSS frame indicator (goes high while the 8 bits are shifted)
ssp_din - output SSP data to ARM (shifts 8 bit A/D value serially to ARM MSB first)
ssp_clk - output SSP clock signal 1Mhz/1.09Mhz (pck0 / 2*(11+lo_is_125khz) )
ck_1356meg - input unused
ck_1356megb - input unused
ssp_dout - input unused
cross_hi - input unused
cross_lo - input unused
pwr_hi - output unused, tied low
pwr_oe1 - output unused, undefined
pwr_oe2 - output unused, undefined
pwr_oe3 - output unused, undefined
pwr_oe4 - output unused, undefined
dbg - output alias for adc_clk
*/
module testbed_lo_read;
reg pck0;
reg [7:0] adc_d;
reg lo_is_125khz;
reg [15:0] divisor;
wire pwr_lo;
wire adc_clk;
wire ck_1356meg;
wire ck_1356megb;
wire ssp_frame;
wire ssp_din;
wire ssp_clk;
reg ssp_dout;
wire pwr_hi;
wire pwr_oe1;
wire pwr_oe2;
wire pwr_oe3;
wire pwr_oe4;
wire cross_lo;
wire cross_hi;
wire dbg;
lo_read #(5,10) dut(
.pck0(pck0),
.ck_1356meg(ck_1356meg),
.ck_1356megb(ck_1356megb),
.pwr_lo(pwr_lo),
.pwr_hi(pwr_hi),
.pwr_oe1(pwr_oe1),
.pwr_oe2(pwr_oe2),
.pwr_oe3(pwr_oe3),
.pwr_oe4(pwr_oe4),
.adc_d(adc_d),
.adc_clk(adc_clk),
.ssp_frame(ssp_frame),
.ssp_din(ssp_din),
.ssp_dout(ssp_dout),
.ssp_clk(ssp_clk),
.cross_hi(cross_hi),
.cross_lo(cross_lo),
.dbg(dbg),
.lo_is_125khz(lo_is_125khz),
.divisor(divisor)
);
integer idx, i, adc_val=8;
// main clock
always #5 pck0 = !pck0;
task crank_dut;
begin
@(posedge adc_clk) ;
adc_d = adc_val;
adc_val = (adc_val *2) + 53;
end
endtask
initial begin
// init inputs
pck0 = 0;
adc_d = 0;
ssp_dout = 0;
lo_is_125khz = 1;
divisor = 255; //min 16, 95=125Khz, max 255
// simulate 4 A/D cycles at 125Khz
for (i = 0 ; i < 8 ; i = i + 1) begin
crank_dut;
end
$finish;
end
endmodule // main
|
//Legal Notice: (C)2017 Altera Corporation. All rights reserved. Your
//use of Altera Corporation's design tools, logic functions and other
//software and tools, and its AMPP partner logic functions, and any
//output files any of the foregoing (including device programming or
//simulation files), and any associated documentation or information are
//expressly subject to the terms and conditions of the Altera Program
//License Subscription Agreement or other applicable license agreement,
//including, without limitation, that your use is for the sole purpose
//of programming logic devices manufactured by Altera and sold by Altera
//or its authorized distributors. Please refer to the applicable
//agreement for further details.
// synthesis translate_off
`timescale 1ns / 1ps
// synthesis translate_on
// turn off superfluous verilog processor warnings
// altera message_level Level1
// altera message_off 10034 10035 10036 10037 10230 10240 10030
module soc_design_niosII_core_cpu_debug_slave_tck (
// inputs:
MonDReg,
break_readreg,
dbrk_hit0_latch,
dbrk_hit1_latch,
dbrk_hit2_latch,
dbrk_hit3_latch,
debugack,
ir_in,
jtag_state_rti,
monitor_error,
monitor_ready,
reset_n,
resetlatch,
tck,
tdi,
tracemem_on,
tracemem_trcdata,
tracemem_tw,
trc_im_addr,
trc_on,
trc_wrap,
trigbrktype,
trigger_state_1,
vs_cdr,
vs_sdr,
vs_uir,
// outputs:
ir_out,
jrst_n,
sr,
st_ready_test_idle,
tdo
)
;
output [ 1: 0] ir_out;
output jrst_n;
output [ 37: 0] sr;
output st_ready_test_idle;
output tdo;
input [ 31: 0] MonDReg;
input [ 31: 0] break_readreg;
input dbrk_hit0_latch;
input dbrk_hit1_latch;
input dbrk_hit2_latch;
input dbrk_hit3_latch;
input debugack;
input [ 1: 0] ir_in;
input jtag_state_rti;
input monitor_error;
input monitor_ready;
input reset_n;
input resetlatch;
input tck;
input tdi;
input tracemem_on;
input [ 35: 0] tracemem_trcdata;
input tracemem_tw;
input [ 6: 0] trc_im_addr;
input trc_on;
input trc_wrap;
input trigbrktype;
input trigger_state_1;
input vs_cdr;
input vs_sdr;
input vs_uir;
reg [ 2: 0] DRsize /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103,R101\"" */;
wire debugack_sync;
reg [ 1: 0] ir_out;
wire jrst_n;
wire monitor_ready_sync;
reg [ 37: 0] sr /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103,R101\"" */;
wire st_ready_test_idle;
wire tdo;
wire unxcomplemented_resetxx1;
wire unxcomplemented_resetxx2;
always @(posedge tck)
begin
if (vs_cdr)
case (ir_in)
2'b00: begin
sr[35] <= debugack_sync;
sr[34] <= monitor_error;
sr[33] <= resetlatch;
sr[32 : 1] <= MonDReg;
sr[0] <= monitor_ready_sync;
end // 2'b00
2'b01: begin
sr[35 : 0] <= tracemem_trcdata;
sr[37] <= tracemem_tw;
sr[36] <= tracemem_on;
end // 2'b01
2'b10: begin
sr[37] <= trigger_state_1;
sr[36] <= dbrk_hit3_latch;
sr[35] <= dbrk_hit2_latch;
sr[34] <= dbrk_hit1_latch;
sr[33] <= dbrk_hit0_latch;
sr[32 : 1] <= break_readreg;
sr[0] <= trigbrktype;
end // 2'b10
2'b11: begin
sr[15 : 2] <= trc_im_addr;
sr[1] <= trc_wrap;
sr[0] <= trc_on;
end // 2'b11
endcase // ir_in
if (vs_sdr)
case (DRsize)
3'b000: begin
sr <= {tdi, sr[37 : 2], tdi};
end // 3'b000
3'b001: begin
sr <= {tdi, sr[37 : 9], tdi, sr[7 : 1]};
end // 3'b001
3'b010: begin
sr <= {tdi, sr[37 : 17], tdi, sr[15 : 1]};
end // 3'b010
3'b011: begin
sr <= {tdi, sr[37 : 33], tdi, sr[31 : 1]};
end // 3'b011
3'b100: begin
sr <= {tdi, sr[37], tdi, sr[35 : 1]};
end // 3'b100
3'b101: begin
sr <= {tdi, sr[37 : 1]};
end // 3'b101
default: begin
sr <= {tdi, sr[37 : 2], tdi};
end // default
endcase // DRsize
if (vs_uir)
case (ir_in)
2'b00: begin
DRsize <= 3'b100;
end // 2'b00
2'b01: begin
DRsize <= 3'b101;
end // 2'b01
2'b10: begin
DRsize <= 3'b101;
end // 2'b10
2'b11: begin
DRsize <= 3'b010;
end // 2'b11
endcase // ir_in
end
assign tdo = sr[0];
assign st_ready_test_idle = jtag_state_rti;
assign unxcomplemented_resetxx1 = jrst_n;
altera_std_synchronizer the_altera_std_synchronizer1
(
.clk (tck),
.din (debugack),
.dout (debugack_sync),
.reset_n (unxcomplemented_resetxx1)
);
defparam the_altera_std_synchronizer1.depth = 2;
assign unxcomplemented_resetxx2 = jrst_n;
altera_std_synchronizer the_altera_std_synchronizer2
(
.clk (tck),
.din (monitor_ready),
.dout (monitor_ready_sync),
.reset_n (unxcomplemented_resetxx2)
);
defparam the_altera_std_synchronizer2.depth = 2;
always @(posedge tck or negedge jrst_n)
begin
if (jrst_n == 0)
ir_out <= 2'b0;
else
ir_out <= {debugack_sync, monitor_ready_sync};
end
//synthesis translate_off
//////////////// SIMULATION-ONLY CONTENTS
assign jrst_n = reset_n;
//////////////// END SIMULATION-ONLY CONTENTS
//synthesis translate_on
//synthesis read_comments_as_HDL on
// assign jrst_n = 1;
//synthesis read_comments_as_HDL off
endmodule
|
//Legal Notice: (C)2017 Altera Corporation. All rights reserved. Your
//use of Altera Corporation's design tools, logic functions and other
//software and tools, and its AMPP partner logic functions, and any
//output files any of the foregoing (including device programming or
//simulation files), and any associated documentation or information are
//expressly subject to the terms and conditions of the Altera Program
//License Subscription Agreement or other applicable license agreement,
//including, without limitation, that your use is for the sole purpose
//of programming logic devices manufactured by Altera and sold by Altera
//or its authorized distributors. Please refer to the applicable
//agreement for further details.
// synthesis translate_off
`timescale 1ns / 1ps
// synthesis translate_on
// turn off superfluous verilog processor warnings
// altera message_level Level1
// altera message_off 10034 10035 10036 10037 10230 10240 10030
module soc_design_niosII_core_cpu_debug_slave_tck (
// inputs:
MonDReg,
break_readreg,
dbrk_hit0_latch,
dbrk_hit1_latch,
dbrk_hit2_latch,
dbrk_hit3_latch,
debugack,
ir_in,
jtag_state_rti,
monitor_error,
monitor_ready,
reset_n,
resetlatch,
tck,
tdi,
tracemem_on,
tracemem_trcdata,
tracemem_tw,
trc_im_addr,
trc_on,
trc_wrap,
trigbrktype,
trigger_state_1,
vs_cdr,
vs_sdr,
vs_uir,
// outputs:
ir_out,
jrst_n,
sr,
st_ready_test_idle,
tdo
)
;
output [ 1: 0] ir_out;
output jrst_n;
output [ 37: 0] sr;
output st_ready_test_idle;
output tdo;
input [ 31: 0] MonDReg;
input [ 31: 0] break_readreg;
input dbrk_hit0_latch;
input dbrk_hit1_latch;
input dbrk_hit2_latch;
input dbrk_hit3_latch;
input debugack;
input [ 1: 0] ir_in;
input jtag_state_rti;
input monitor_error;
input monitor_ready;
input reset_n;
input resetlatch;
input tck;
input tdi;
input tracemem_on;
input [ 35: 0] tracemem_trcdata;
input tracemem_tw;
input [ 6: 0] trc_im_addr;
input trc_on;
input trc_wrap;
input trigbrktype;
input trigger_state_1;
input vs_cdr;
input vs_sdr;
input vs_uir;
reg [ 2: 0] DRsize /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103,R101\"" */;
wire debugack_sync;
reg [ 1: 0] ir_out;
wire jrst_n;
wire monitor_ready_sync;
reg [ 37: 0] sr /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103,R101\"" */;
wire st_ready_test_idle;
wire tdo;
wire unxcomplemented_resetxx1;
wire unxcomplemented_resetxx2;
always @(posedge tck)
begin
if (vs_cdr)
case (ir_in)
2'b00: begin
sr[35] <= debugack_sync;
sr[34] <= monitor_error;
sr[33] <= resetlatch;
sr[32 : 1] <= MonDReg;
sr[0] <= monitor_ready_sync;
end // 2'b00
2'b01: begin
sr[35 : 0] <= tracemem_trcdata;
sr[37] <= tracemem_tw;
sr[36] <= tracemem_on;
end // 2'b01
2'b10: begin
sr[37] <= trigger_state_1;
sr[36] <= dbrk_hit3_latch;
sr[35] <= dbrk_hit2_latch;
sr[34] <= dbrk_hit1_latch;
sr[33] <= dbrk_hit0_latch;
sr[32 : 1] <= break_readreg;
sr[0] <= trigbrktype;
end // 2'b10
2'b11: begin
sr[15 : 2] <= trc_im_addr;
sr[1] <= trc_wrap;
sr[0] <= trc_on;
end // 2'b11
endcase // ir_in
if (vs_sdr)
case (DRsize)
3'b000: begin
sr <= {tdi, sr[37 : 2], tdi};
end // 3'b000
3'b001: begin
sr <= {tdi, sr[37 : 9], tdi, sr[7 : 1]};
end // 3'b001
3'b010: begin
sr <= {tdi, sr[37 : 17], tdi, sr[15 : 1]};
end // 3'b010
3'b011: begin
sr <= {tdi, sr[37 : 33], tdi, sr[31 : 1]};
end // 3'b011
3'b100: begin
sr <= {tdi, sr[37], tdi, sr[35 : 1]};
end // 3'b100
3'b101: begin
sr <= {tdi, sr[37 : 1]};
end // 3'b101
default: begin
sr <= {tdi, sr[37 : 2], tdi};
end // default
endcase // DRsize
if (vs_uir)
case (ir_in)
2'b00: begin
DRsize <= 3'b100;
end // 2'b00
2'b01: begin
DRsize <= 3'b101;
end // 2'b01
2'b10: begin
DRsize <= 3'b101;
end // 2'b10
2'b11: begin
DRsize <= 3'b010;
end // 2'b11
endcase // ir_in
end
assign tdo = sr[0];
assign st_ready_test_idle = jtag_state_rti;
assign unxcomplemented_resetxx1 = jrst_n;
altera_std_synchronizer the_altera_std_synchronizer1
(
.clk (tck),
.din (debugack),
.dout (debugack_sync),
.reset_n (unxcomplemented_resetxx1)
);
defparam the_altera_std_synchronizer1.depth = 2;
assign unxcomplemented_resetxx2 = jrst_n;
altera_std_synchronizer the_altera_std_synchronizer2
(
.clk (tck),
.din (monitor_ready),
.dout (monitor_ready_sync),
.reset_n (unxcomplemented_resetxx2)
);
defparam the_altera_std_synchronizer2.depth = 2;
always @(posedge tck or negedge jrst_n)
begin
if (jrst_n == 0)
ir_out <= 2'b0;
else
ir_out <= {debugack_sync, monitor_ready_sync};
end
//synthesis translate_off
//////////////// SIMULATION-ONLY CONTENTS
assign jrst_n = reset_n;
//////////////// END SIMULATION-ONLY CONTENTS
//synthesis translate_on
//synthesis read_comments_as_HDL on
// assign jrst_n = 1;
//synthesis read_comments_as_HDL off
endmodule
|
//Legal Notice: (C)2017 Altera Corporation. All rights reserved. Your
//use of Altera Corporation's design tools, logic functions and other
//software and tools, and its AMPP partner logic functions, and any
//output files any of the foregoing (including device programming or
//simulation files), and any associated documentation or information are
//expressly subject to the terms and conditions of the Altera Program
//License Subscription Agreement or other applicable license agreement,
//including, without limitation, that your use is for the sole purpose
//of programming logic devices manufactured by Altera and sold by Altera
//or its authorized distributors. Please refer to the applicable
//agreement for further details.
// synthesis translate_off
`timescale 1ns / 1ps
// synthesis translate_on
// turn off superfluous verilog processor warnings
// altera message_level Level1
// altera message_off 10034 10035 10036 10037 10230 10240 10030
module soc_design_niosII_core_cpu_debug_slave_sysclk (
// inputs:
clk,
ir_in,
sr,
vs_udr,
vs_uir,
// outputs:
jdo,
take_action_break_a,
take_action_break_b,
take_action_break_c,
take_action_ocimem_a,
take_action_ocimem_b,
take_action_tracectrl,
take_no_action_break_a,
take_no_action_break_b,
take_no_action_break_c,
take_no_action_ocimem_a
)
;
output [ 37: 0] jdo;
output take_action_break_a;
output take_action_break_b;
output take_action_break_c;
output take_action_ocimem_a;
output take_action_ocimem_b;
output take_action_tracectrl;
output take_no_action_break_a;
output take_no_action_break_b;
output take_no_action_break_c;
output take_no_action_ocimem_a;
input clk;
input [ 1: 0] ir_in;
input [ 37: 0] sr;
input vs_udr;
input vs_uir;
reg enable_action_strobe /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
reg [ 1: 0] ir /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,R101\"" */;
reg [ 37: 0] jdo /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,R101\"" */;
reg jxuir /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
reg sync2_udr /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
reg sync2_uir /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
wire sync_udr;
wire sync_uir;
wire take_action_break_a;
wire take_action_break_b;
wire take_action_break_c;
wire take_action_ocimem_a;
wire take_action_ocimem_b;
wire take_action_tracectrl;
wire take_no_action_break_a;
wire take_no_action_break_b;
wire take_no_action_break_c;
wire take_no_action_ocimem_a;
wire unxunused_resetxx3;
wire unxunused_resetxx4;
reg update_jdo_strobe /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
assign unxunused_resetxx3 = 1'b1;
altera_std_synchronizer the_altera_std_synchronizer3
(
.clk (clk),
.din (vs_udr),
.dout (sync_udr),
.reset_n (unxunused_resetxx3)
);
defparam the_altera_std_synchronizer3.depth = 2;
assign unxunused_resetxx4 = 1'b1;
altera_std_synchronizer the_altera_std_synchronizer4
(
.clk (clk),
.din (vs_uir),
.dout (sync_uir),
.reset_n (unxunused_resetxx4)
);
defparam the_altera_std_synchronizer4.depth = 2;
always @(posedge clk)
begin
sync2_udr <= sync_udr;
update_jdo_strobe <= sync_udr & ~sync2_udr;
enable_action_strobe <= update_jdo_strobe;
sync2_uir <= sync_uir;
jxuir <= sync_uir & ~sync2_uir;
end
assign take_action_ocimem_a = enable_action_strobe && (ir == 2'b00) &&
~jdo[35] && jdo[34];
assign take_no_action_ocimem_a = enable_action_strobe && (ir == 2'b00) &&
~jdo[35] && ~jdo[34];
assign take_action_ocimem_b = enable_action_strobe && (ir == 2'b00) &&
jdo[35];
assign take_action_break_a = enable_action_strobe && (ir == 2'b10) &&
~jdo[36] &&
jdo[37];
assign take_no_action_break_a = enable_action_strobe && (ir == 2'b10) &&
~jdo[36] &&
~jdo[37];
assign take_action_break_b = enable_action_strobe && (ir == 2'b10) &&
jdo[36] && ~jdo[35] &&
jdo[37];
assign take_no_action_break_b = enable_action_strobe && (ir == 2'b10) &&
jdo[36] && ~jdo[35] &&
~jdo[37];
assign take_action_break_c = enable_action_strobe && (ir == 2'b10) &&
jdo[36] && jdo[35] &&
jdo[37];
assign take_no_action_break_c = enable_action_strobe && (ir == 2'b10) &&
jdo[36] && jdo[35] &&
~jdo[37];
assign take_action_tracectrl = enable_action_strobe && (ir == 2'b11) &&
jdo[15];
always @(posedge clk)
begin
if (jxuir)
ir <= ir_in;
if (update_jdo_strobe)
jdo <= sr;
end
endmodule
|
//Legal Notice: (C)2017 Altera Corporation. All rights reserved. Your
//use of Altera Corporation's design tools, logic functions and other
//software and tools, and its AMPP partner logic functions, and any
//output files any of the foregoing (including device programming or
//simulation files), and any associated documentation or information are
//expressly subject to the terms and conditions of the Altera Program
//License Subscription Agreement or other applicable license agreement,
//including, without limitation, that your use is for the sole purpose
//of programming logic devices manufactured by Altera and sold by Altera
//or its authorized distributors. Please refer to the applicable
//agreement for further details.
// synthesis translate_off
`timescale 1ns / 1ps
// synthesis translate_on
// turn off superfluous verilog processor warnings
// altera message_level Level1
// altera message_off 10034 10035 10036 10037 10230 10240 10030
module soc_design_niosII_core_cpu_debug_slave_sysclk (
// inputs:
clk,
ir_in,
sr,
vs_udr,
vs_uir,
// outputs:
jdo,
take_action_break_a,
take_action_break_b,
take_action_break_c,
take_action_ocimem_a,
take_action_ocimem_b,
take_action_tracectrl,
take_no_action_break_a,
take_no_action_break_b,
take_no_action_break_c,
take_no_action_ocimem_a
)
;
output [ 37: 0] jdo;
output take_action_break_a;
output take_action_break_b;
output take_action_break_c;
output take_action_ocimem_a;
output take_action_ocimem_b;
output take_action_tracectrl;
output take_no_action_break_a;
output take_no_action_break_b;
output take_no_action_break_c;
output take_no_action_ocimem_a;
input clk;
input [ 1: 0] ir_in;
input [ 37: 0] sr;
input vs_udr;
input vs_uir;
reg enable_action_strobe /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
reg [ 1: 0] ir /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,R101\"" */;
reg [ 37: 0] jdo /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,R101\"" */;
reg jxuir /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
reg sync2_udr /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
reg sync2_uir /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
wire sync_udr;
wire sync_uir;
wire take_action_break_a;
wire take_action_break_b;
wire take_action_break_c;
wire take_action_ocimem_a;
wire take_action_ocimem_b;
wire take_action_tracectrl;
wire take_no_action_break_a;
wire take_no_action_break_b;
wire take_no_action_break_c;
wire take_no_action_ocimem_a;
wire unxunused_resetxx3;
wire unxunused_resetxx4;
reg update_jdo_strobe /* synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=\"D101,D103\"" */;
assign unxunused_resetxx3 = 1'b1;
altera_std_synchronizer the_altera_std_synchronizer3
(
.clk (clk),
.din (vs_udr),
.dout (sync_udr),
.reset_n (unxunused_resetxx3)
);
defparam the_altera_std_synchronizer3.depth = 2;
assign unxunused_resetxx4 = 1'b1;
altera_std_synchronizer the_altera_std_synchronizer4
(
.clk (clk),
.din (vs_uir),
.dout (sync_uir),
.reset_n (unxunused_resetxx4)
);
defparam the_altera_std_synchronizer4.depth = 2;
always @(posedge clk)
begin
sync2_udr <= sync_udr;
update_jdo_strobe <= sync_udr & ~sync2_udr;
enable_action_strobe <= update_jdo_strobe;
sync2_uir <= sync_uir;
jxuir <= sync_uir & ~sync2_uir;
end
assign take_action_ocimem_a = enable_action_strobe && (ir == 2'b00) &&
~jdo[35] && jdo[34];
assign take_no_action_ocimem_a = enable_action_strobe && (ir == 2'b00) &&
~jdo[35] && ~jdo[34];
assign take_action_ocimem_b = enable_action_strobe && (ir == 2'b00) &&
jdo[35];
assign take_action_break_a = enable_action_strobe && (ir == 2'b10) &&
~jdo[36] &&
jdo[37];
assign take_no_action_break_a = enable_action_strobe && (ir == 2'b10) &&
~jdo[36] &&
~jdo[37];
assign take_action_break_b = enable_action_strobe && (ir == 2'b10) &&
jdo[36] && ~jdo[35] &&
jdo[37];
assign take_no_action_break_b = enable_action_strobe && (ir == 2'b10) &&
jdo[36] && ~jdo[35] &&
~jdo[37];
assign take_action_break_c = enable_action_strobe && (ir == 2'b10) &&
jdo[36] && jdo[35] &&
jdo[37];
assign take_no_action_break_c = enable_action_strobe && (ir == 2'b10) &&
jdo[36] && jdo[35] &&
~jdo[37];
assign take_action_tracectrl = enable_action_strobe && (ir == 2'b11) &&
jdo[15];
always @(posedge clk)
begin
if (jxuir)
ir <= ir_in;
if (update_jdo_strobe)
jdo <= sr;
end
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved.
// --
// -- This file contains confidential and proprietary information
// -- of Xilinx, Inc. and is protected under U.S. and
// -- international copyright and other intellectual property
// -- laws.
// --
// -- DISCLAIMER
// -- This disclaimer is not a license and does not grant any
// -- rights to the materials distributed herewith. Except as
// -- otherwise provided in a valid license issued to you by
// -- Xilinx, and to the maximum extent permitted by applicable
// -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// -- (2) Xilinx shall not be liable (whether in contract or tort,
// -- including negligence, or under any other theory of
// -- liability) for any loss or damage of any kind or nature
// -- related to, arising under or in connection with these
// -- materials, including for any direct, or any indirect,
// -- special, incidental, or consequential loss or damage
// -- (including loss of data, profits, goodwill, or any type of
// -- loss or damage suffered as a result of any action brought
// -- by a third party) even if such damage or loss was
// -- reasonably foreseeable or Xilinx had been advised of the
// -- possibility of the same.
// --
// -- CRITICAL APPLICATIONS
// -- Xilinx products are not designed or intended to be fail-
// -- safe, or for use in any application requiring fail-safe
// -- performance, such as life-support or safety devices or
// -- systems, Class III medical devices, nuclear facilities,
// -- applications related to the deployment of airbags, or any
// -- other applications that could lead to death, personal
// -- injury, or severe property or environmental damage
// -- (individually and collectively, "Critical
// -- Applications"). Customer assumes the sole risk and
// -- liability of any use of Xilinx products in Critical
// -- Applications, subject only to applicable laws and
// -- regulations governing limitations on product liability.
// --
// -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// -- PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// Description: Write Response Channel for ATC
//
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
// Structure:
// b_atc
//
//--------------------------------------------------------------------------
`timescale 1ps/1ps
module processing_system7_v5_5_b_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of checker.
// Range: >= 1.
parameter integer C_AXI_BUSER_WIDTH = 1,
// Width of AWUSER signals.
// Range: >= 1.
parameter integer C_FIFO_DEPTH_LOG = 4
)
(
// Global Signals
input wire ARESET,
input wire ACLK,
// Command Interface
input wire cmd_b_push,
input wire cmd_b_error,
input wire [C_AXI_ID_WIDTH-1:0] cmd_b_id,
output wire cmd_b_ready,
output wire [C_FIFO_DEPTH_LOG-1:0] cmd_b_addr,
output reg cmd_b_full,
// Slave Interface Write Response Ports
output wire [C_AXI_ID_WIDTH-1:0] S_AXI_BID,
output reg [2-1:0] S_AXI_BRESP,
output wire [C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
// Master Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] M_AXI_BID,
input wire [2-1:0] M_AXI_BRESP,
input wire [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER,
input wire M_AXI_BVALID,
output wire M_AXI_BREADY,
// Trigger detection
output reg ERROR_TRIGGER,
output reg [C_AXI_ID_WIDTH-1:0] ERROR_TRANSACTION_ID
);
/////////////////////////////////////////////////////////////////////////////
// Local params
/////////////////////////////////////////////////////////////////////////////
// Constants for packing levels.
localparam [2-1:0] C_RESP_OKAY = 2'b00;
localparam [2-1:0] C_RESP_EXOKAY = 2'b01;
localparam [2-1:0] C_RESP_SLVERROR = 2'b10;
localparam [2-1:0] C_RESP_DECERR = 2'b11;
// Command FIFO settings
localparam C_FIFO_WIDTH = C_AXI_ID_WIDTH + 1;
localparam C_FIFO_DEPTH = 2 ** C_FIFO_DEPTH_LOG;
/////////////////////////////////////////////////////////////////////////////
// Variables for generating parameter controlled instances.
/////////////////////////////////////////////////////////////////////////////
integer index;
/////////////////////////////////////////////////////////////////////////////
// Functions
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////
// Internal signals
/////////////////////////////////////////////////////////////////////////////
// Command Queue.
reg [C_FIFO_DEPTH_LOG-1:0] addr_ptr;
reg [C_FIFO_WIDTH-1:0] data_srl[C_FIFO_DEPTH-1:0];
reg cmd_b_valid;
wire cmd_b_ready_i;
wire inject_error;
wire [C_AXI_ID_WIDTH-1:0] current_id;
// Search command.
wire found_match;
wire use_match;
wire matching_id;
// Manage valid command.
wire write_valid_cmd;
reg [C_FIFO_DEPTH-2:0] valid_cmd;
reg [C_FIFO_DEPTH-2:0] updated_valid_cmd;
reg [C_FIFO_DEPTH-2:0] next_valid_cmd;
reg [C_FIFO_DEPTH_LOG-1:0] search_addr_ptr;
reg [C_FIFO_DEPTH_LOG-1:0] collapsed_addr_ptr;
// Pipelined data
reg [C_AXI_ID_WIDTH-1:0] M_AXI_BID_I;
reg [2-1:0] M_AXI_BRESP_I;
reg [C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER_I;
reg M_AXI_BVALID_I;
wire M_AXI_BREADY_I;
/////////////////////////////////////////////////////////////////////////////
// Command Queue:
//
// Keep track of depth of Queue to generate full flag.
//
// Also generate valid to mark pressence of commands in Queue.
//
// Maintain Queue and extract data from currently searched entry.
//
/////////////////////////////////////////////////////////////////////////////
// SRL FIFO Pointer.
always @ (posedge ACLK) begin
if (ARESET) begin
addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
// Pushing data increase length/addr.
addr_ptr <= addr_ptr + 1;
end else if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
addr_ptr <= collapsed_addr_ptr;
end
end
end
// FIFO Flags.
always @ (posedge ACLK) begin
if (ARESET) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= 1'b0;
end else begin
if ( cmd_b_push & ~cmd_b_ready_i ) begin
cmd_b_full <= ( addr_ptr == C_FIFO_DEPTH-3 );
cmd_b_valid <= 1'b1;
end else if ( ~cmd_b_push & cmd_b_ready_i ) begin
cmd_b_full <= 1'b0;
cmd_b_valid <= ( collapsed_addr_ptr != C_FIFO_DEPTH-1 );
end
end
end
// Infere SRL for storage.
always @ (posedge ACLK) begin
if ( cmd_b_push ) begin
for (index = 0; index < C_FIFO_DEPTH-1 ; index = index + 1) begin
data_srl[index+1] <= data_srl[index];
end
data_srl[0] <= {cmd_b_error, cmd_b_id};
end
end
// Get current transaction info.
assign {inject_error, current_id} = data_srl[search_addr_ptr];
// Assign outputs.
assign cmd_b_addr = collapsed_addr_ptr;
/////////////////////////////////////////////////////////////////////////////
// Search Command Queue:
//
// Search for matching valid command in queue.
//
// A command is found when an valid entry with correct ID is found. The queue
// is search from the oldest entry, i.e. from a high value.
// When new commands are pushed the search address has to be updated to always
// start the search from the oldest available.
//
/////////////////////////////////////////////////////////////////////////////
// Handle search addr.
always @ (posedge ACLK) begin
if (ARESET) begin
search_addr_ptr <= {C_FIFO_DEPTH_LOG{1'b1}};
end else begin
if ( cmd_b_ready_i ) begin
// Collapse addr when data is popped.
search_addr_ptr <= collapsed_addr_ptr;
end else if ( M_AXI_BVALID_I & cmd_b_valid & ~found_match & ~cmd_b_push ) begin
// Skip non valid command.
search_addr_ptr <= search_addr_ptr - 1;
end else if ( cmd_b_push ) begin
search_addr_ptr <= search_addr_ptr + 1;
end
end
end
// Check if searched command is valid and match ID (for existing response on MI side).
assign matching_id = ( M_AXI_BID_I == current_id );
assign found_match = valid_cmd[search_addr_ptr] & matching_id & M_AXI_BVALID_I;
assign use_match = found_match & S_AXI_BREADY;
/////////////////////////////////////////////////////////////////////////////
// Track Used Commands:
//
// Actions that affect Valid Command:
// * When a new command is pushed
// => Shift valid vector one step
// * When a command is used
// => Clear corresponding valid bit
//
/////////////////////////////////////////////////////////////////////////////
// Valid command status is updated when a command is used or a new one is pushed.
assign write_valid_cmd = cmd_b_push | cmd_b_ready_i;
// Update the used command valid bit.
always @ *
begin
updated_valid_cmd = valid_cmd;
updated_valid_cmd[search_addr_ptr] = ~use_match;
end
// Shift valid vector when command is pushed.
always @ *
begin
if ( cmd_b_push ) begin
next_valid_cmd = {updated_valid_cmd[C_FIFO_DEPTH-3:0], 1'b1};
end else begin
next_valid_cmd = updated_valid_cmd;
end
end
// Valid signals for next cycle.
always @ (posedge ACLK) begin
if (ARESET) begin
valid_cmd <= {C_FIFO_WIDTH{1'b0}};
end else if ( write_valid_cmd ) begin
valid_cmd <= next_valid_cmd;
end
end
// Detect oldest available command in Queue.
always @ *
begin
// Default to empty.
collapsed_addr_ptr = {C_FIFO_DEPTH_LOG{1'b1}};
for (index = 0; index < C_FIFO_DEPTH-2 ; index = index + 1) begin
if ( next_valid_cmd[index] ) begin
collapsed_addr_ptr = index;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Pipe incoming data:
//
// The B channel is piped to improve timing and avoid impact in search
// mechanism due to late arriving signals.
//
/////////////////////////////////////////////////////////////////////////////
// Clock data.
always @ (posedge ACLK) begin
if (ARESET) begin
M_AXI_BID_I <= {C_AXI_ID_WIDTH{1'b0}};
M_AXI_BRESP_I <= 2'b00;
M_AXI_BUSER_I <= {C_AXI_BUSER_WIDTH{1'b0}};
M_AXI_BVALID_I <= 1'b0;
end else begin
if ( M_AXI_BREADY_I | ~M_AXI_BVALID_I ) begin
M_AXI_BVALID_I <= 1'b0;
end
if (M_AXI_BVALID & ( M_AXI_BREADY_I | ~M_AXI_BVALID_I) ) begin
M_AXI_BID_I <= M_AXI_BID;
M_AXI_BRESP_I <= M_AXI_BRESP;
M_AXI_BUSER_I <= M_AXI_BUSER;
M_AXI_BVALID_I <= 1'b1;
end
end
end
// Generate ready to get new transaction.
assign M_AXI_BREADY = M_AXI_BREADY_I | ~M_AXI_BVALID_I;
/////////////////////////////////////////////////////////////////////////////
// Inject Error:
//
// BRESP is modified according to command information.
//
/////////////////////////////////////////////////////////////////////////////
// Inject error in response.
always @ *
begin
if ( inject_error ) begin
S_AXI_BRESP = C_RESP_SLVERROR;
end else begin
S_AXI_BRESP = M_AXI_BRESP_I;
end
end
// Handle interrupt generation.
always @ (posedge ACLK) begin
if (ARESET) begin
ERROR_TRIGGER <= 1'b0;
ERROR_TRANSACTION_ID <= {C_AXI_ID_WIDTH{1'b0}};
end else begin
if ( inject_error & cmd_b_ready_i ) begin
ERROR_TRIGGER <= 1'b1;
ERROR_TRANSACTION_ID <= M_AXI_BID_I;
end else begin
ERROR_TRIGGER <= 1'b0;
end
end
end
/////////////////////////////////////////////////////////////////////////////
// Transaction Throttling:
//
// Response is passed forward when a matching entry has been found in queue.
// Both ready and valid are set when the command is completed.
//
/////////////////////////////////////////////////////////////////////////////
// Propagate masked valid.
assign S_AXI_BVALID = M_AXI_BVALID_I & cmd_b_valid & found_match;
// Return ready with push back.
assign M_AXI_BREADY_I = cmd_b_valid & use_match;
// Command has been handled.
assign cmd_b_ready_i = M_AXI_BVALID_I & cmd_b_valid & use_match;
assign cmd_b_ready = cmd_b_ready_i;
/////////////////////////////////////////////////////////////////////////////
// Write Response Propagation:
//
// All information is simply forwarded on from MI- to SI-Side untouched.
//
/////////////////////////////////////////////////////////////////////////////
// 1:1 mapping.
assign S_AXI_BID = M_AXI_BID_I;
assign S_AXI_BUSER = M_AXI_BUSER_I;
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 03/17/2016 05:20:59 PM
// Design Name:
// Module Name: Priority_Codec_32
// Project Name:
// Target Devices:
// Tool Versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module Priority_Codec_32(
input wire [25:0] Data_Dec_i,
output reg [4:0] Data_Bin_o
);
always @(Data_Dec_i)
begin
if(~Data_Dec_i[25]) begin Data_Bin_o = 5'b00000;//0
end else if(~Data_Dec_i[24]) begin Data_Bin_o = 5'b00001;//1
end else if(~Data_Dec_i[23]) begin Data_Bin_o = 5'b00010;//2
end else if(~Data_Dec_i[22]) begin Data_Bin_o = 5'b00011;//3
end else if(~Data_Dec_i[21]) begin Data_Bin_o = 5'b00100;//4
end else if(~Data_Dec_i[20]) begin Data_Bin_o = 5'b00101;//5
end else if(~Data_Dec_i[19]) begin Data_Bin_o = 5'b00110;//6
end else if(~Data_Dec_i[18]) begin Data_Bin_o = 5'b00111;//7
end else if(~Data_Dec_i[17]) begin Data_Bin_o = 5'b01000;//8
end else if(~Data_Dec_i[16]) begin Data_Bin_o = 5'b01001;//9
end else if(~Data_Dec_i[15]) begin Data_Bin_o = 5'b01010;//10
end else if(~Data_Dec_i[14]) begin Data_Bin_o = 5'b01011;//11
end else if(~Data_Dec_i[13]) begin Data_Bin_o = 5'b01100;//12
end else if(~Data_Dec_i[12]) begin Data_Bin_o = 5'b01101;//13
end else if(~Data_Dec_i[11]) begin Data_Bin_o = 5'b01110;//14
end else if(~Data_Dec_i[10]) begin Data_Bin_o = 5'b01111;//15
end else if(~Data_Dec_i[9]) begin Data_Bin_o = 5'b10000;//16
end else if(~Data_Dec_i[8]) begin Data_Bin_o = 5'b10001;//17
end else if(~Data_Dec_i[7]) begin Data_Bin_o = 5'b10010;//18
end else if(~Data_Dec_i[6]) begin Data_Bin_o = 5'b10011;//19
end else if(~Data_Dec_i[5]) begin Data_Bin_o = 5'b10100;//20
end else if(~Data_Dec_i[4]) begin Data_Bin_o = 5'b10101;//21
end else if(~Data_Dec_i[3]) begin Data_Bin_o = 5'b10110;//22
end else if(~Data_Dec_i[2]) begin Data_Bin_o = 5'b10111;//23
end else if(~Data_Dec_i[1]) begin Data_Bin_o = 5'b11000;//24
end else if(~Data_Dec_i[0]) begin Data_Bin_o = 5'b10101;//25
end
else Data_Bin_o = 5'b00000;//zero value
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 03/17/2016 05:20:59 PM
// Design Name:
// Module Name: Priority_Codec_32
// Project Name:
// Target Devices:
// Tool Versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module Priority_Codec_32(
input wire [25:0] Data_Dec_i,
output reg [4:0] Data_Bin_o
);
always @(Data_Dec_i)
begin
if(~Data_Dec_i[25]) begin Data_Bin_o = 5'b00000;//0
end else if(~Data_Dec_i[24]) begin Data_Bin_o = 5'b00001;//1
end else if(~Data_Dec_i[23]) begin Data_Bin_o = 5'b00010;//2
end else if(~Data_Dec_i[22]) begin Data_Bin_o = 5'b00011;//3
end else if(~Data_Dec_i[21]) begin Data_Bin_o = 5'b00100;//4
end else if(~Data_Dec_i[20]) begin Data_Bin_o = 5'b00101;//5
end else if(~Data_Dec_i[19]) begin Data_Bin_o = 5'b00110;//6
end else if(~Data_Dec_i[18]) begin Data_Bin_o = 5'b00111;//7
end else if(~Data_Dec_i[17]) begin Data_Bin_o = 5'b01000;//8
end else if(~Data_Dec_i[16]) begin Data_Bin_o = 5'b01001;//9
end else if(~Data_Dec_i[15]) begin Data_Bin_o = 5'b01010;//10
end else if(~Data_Dec_i[14]) begin Data_Bin_o = 5'b01011;//11
end else if(~Data_Dec_i[13]) begin Data_Bin_o = 5'b01100;//12
end else if(~Data_Dec_i[12]) begin Data_Bin_o = 5'b01101;//13
end else if(~Data_Dec_i[11]) begin Data_Bin_o = 5'b01110;//14
end else if(~Data_Dec_i[10]) begin Data_Bin_o = 5'b01111;//15
end else if(~Data_Dec_i[9]) begin Data_Bin_o = 5'b10000;//16
end else if(~Data_Dec_i[8]) begin Data_Bin_o = 5'b10001;//17
end else if(~Data_Dec_i[7]) begin Data_Bin_o = 5'b10010;//18
end else if(~Data_Dec_i[6]) begin Data_Bin_o = 5'b10011;//19
end else if(~Data_Dec_i[5]) begin Data_Bin_o = 5'b10100;//20
end else if(~Data_Dec_i[4]) begin Data_Bin_o = 5'b10101;//21
end else if(~Data_Dec_i[3]) begin Data_Bin_o = 5'b10110;//22
end else if(~Data_Dec_i[2]) begin Data_Bin_o = 5'b10111;//23
end else if(~Data_Dec_i[1]) begin Data_Bin_o = 5'b11000;//24
end else if(~Data_Dec_i[0]) begin Data_Bin_o = 5'b10101;//25
end
else Data_Bin_o = 5'b00000;//zero value
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 03/17/2016 05:20:59 PM
// Design Name:
// Module Name: Priority_Codec_32
// Project Name:
// Target Devices:
// Tool Versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module Priority_Codec_32(
input wire [25:0] Data_Dec_i,
output reg [4:0] Data_Bin_o
);
always @(Data_Dec_i)
begin
if(~Data_Dec_i[25]) begin Data_Bin_o = 5'b00000;//0
end else if(~Data_Dec_i[24]) begin Data_Bin_o = 5'b00001;//1
end else if(~Data_Dec_i[23]) begin Data_Bin_o = 5'b00010;//2
end else if(~Data_Dec_i[22]) begin Data_Bin_o = 5'b00011;//3
end else if(~Data_Dec_i[21]) begin Data_Bin_o = 5'b00100;//4
end else if(~Data_Dec_i[20]) begin Data_Bin_o = 5'b00101;//5
end else if(~Data_Dec_i[19]) begin Data_Bin_o = 5'b00110;//6
end else if(~Data_Dec_i[18]) begin Data_Bin_o = 5'b00111;//7
end else if(~Data_Dec_i[17]) begin Data_Bin_o = 5'b01000;//8
end else if(~Data_Dec_i[16]) begin Data_Bin_o = 5'b01001;//9
end else if(~Data_Dec_i[15]) begin Data_Bin_o = 5'b01010;//10
end else if(~Data_Dec_i[14]) begin Data_Bin_o = 5'b01011;//11
end else if(~Data_Dec_i[13]) begin Data_Bin_o = 5'b01100;//12
end else if(~Data_Dec_i[12]) begin Data_Bin_o = 5'b01101;//13
end else if(~Data_Dec_i[11]) begin Data_Bin_o = 5'b01110;//14
end else if(~Data_Dec_i[10]) begin Data_Bin_o = 5'b01111;//15
end else if(~Data_Dec_i[9]) begin Data_Bin_o = 5'b10000;//16
end else if(~Data_Dec_i[8]) begin Data_Bin_o = 5'b10001;//17
end else if(~Data_Dec_i[7]) begin Data_Bin_o = 5'b10010;//18
end else if(~Data_Dec_i[6]) begin Data_Bin_o = 5'b10011;//19
end else if(~Data_Dec_i[5]) begin Data_Bin_o = 5'b10100;//20
end else if(~Data_Dec_i[4]) begin Data_Bin_o = 5'b10101;//21
end else if(~Data_Dec_i[3]) begin Data_Bin_o = 5'b10110;//22
end else if(~Data_Dec_i[2]) begin Data_Bin_o = 5'b10111;//23
end else if(~Data_Dec_i[1]) begin Data_Bin_o = 5'b11000;//24
end else if(~Data_Dec_i[0]) begin Data_Bin_o = 5'b10101;//25
end
else Data_Bin_o = 5'b00000;//zero value
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 03/17/2016 05:20:59 PM
// Design Name:
// Module Name: Priority_Codec_32
// Project Name:
// Target Devices:
// Tool Versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module Priority_Codec_32(
input wire [25:0] Data_Dec_i,
output reg [4:0] Data_Bin_o
);
always @(Data_Dec_i)
begin
if(~Data_Dec_i[25]) begin Data_Bin_o = 5'b00000;//0
end else if(~Data_Dec_i[24]) begin Data_Bin_o = 5'b00001;//1
end else if(~Data_Dec_i[23]) begin Data_Bin_o = 5'b00010;//2
end else if(~Data_Dec_i[22]) begin Data_Bin_o = 5'b00011;//3
end else if(~Data_Dec_i[21]) begin Data_Bin_o = 5'b00100;//4
end else if(~Data_Dec_i[20]) begin Data_Bin_o = 5'b00101;//5
end else if(~Data_Dec_i[19]) begin Data_Bin_o = 5'b00110;//6
end else if(~Data_Dec_i[18]) begin Data_Bin_o = 5'b00111;//7
end else if(~Data_Dec_i[17]) begin Data_Bin_o = 5'b01000;//8
end else if(~Data_Dec_i[16]) begin Data_Bin_o = 5'b01001;//9
end else if(~Data_Dec_i[15]) begin Data_Bin_o = 5'b01010;//10
end else if(~Data_Dec_i[14]) begin Data_Bin_o = 5'b01011;//11
end else if(~Data_Dec_i[13]) begin Data_Bin_o = 5'b01100;//12
end else if(~Data_Dec_i[12]) begin Data_Bin_o = 5'b01101;//13
end else if(~Data_Dec_i[11]) begin Data_Bin_o = 5'b01110;//14
end else if(~Data_Dec_i[10]) begin Data_Bin_o = 5'b01111;//15
end else if(~Data_Dec_i[9]) begin Data_Bin_o = 5'b10000;//16
end else if(~Data_Dec_i[8]) begin Data_Bin_o = 5'b10001;//17
end else if(~Data_Dec_i[7]) begin Data_Bin_o = 5'b10010;//18
end else if(~Data_Dec_i[6]) begin Data_Bin_o = 5'b10011;//19
end else if(~Data_Dec_i[5]) begin Data_Bin_o = 5'b10100;//20
end else if(~Data_Dec_i[4]) begin Data_Bin_o = 5'b10101;//21
end else if(~Data_Dec_i[3]) begin Data_Bin_o = 5'b10110;//22
end else if(~Data_Dec_i[2]) begin Data_Bin_o = 5'b10111;//23
end else if(~Data_Dec_i[1]) begin Data_Bin_o = 5'b11000;//24
end else if(~Data_Dec_i[0]) begin Data_Bin_o = 5'b10101;//25
end
else Data_Bin_o = 5'b00000;//zero value
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 22:40:46 12/20/2010
// Design Name:
// Module Name: clk_test
// Project Name:
// Target Devices:
// Tool versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module clk_test(
input clk,
input sysclk,
output [31:0] snes_sysclk_freq
);
reg [31:0] snes_sysclk_freq_r;
assign snes_sysclk_freq = snes_sysclk_freq_r;
reg [31:0] sysclk_counter;
reg [31:0] sysclk_value;
initial snes_sysclk_freq_r = 32'hFFFFFFFF;
initial sysclk_counter = 0;
initial sysclk_value = 0;
reg [1:0] sysclk_sreg;
always @(posedge clk) sysclk_sreg <= {sysclk_sreg[0], sysclk};
wire sysclk_rising = (sysclk_sreg == 2'b01);
always @(posedge clk) begin
if(sysclk_counter < 96000000) begin
sysclk_counter <= sysclk_counter + 1;
if(sysclk_rising) sysclk_value <= sysclk_value + 1;
end else begin
snes_sysclk_freq_r <= sysclk_value;
sysclk_counter <= 0;
sysclk_value <= 0;
end
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 22:40:46 12/20/2010
// Design Name:
// Module Name: clk_test
// Project Name:
// Target Devices:
// Tool versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module clk_test(
input clk,
input sysclk,
output [31:0] snes_sysclk_freq
);
reg [31:0] snes_sysclk_freq_r;
assign snes_sysclk_freq = snes_sysclk_freq_r;
reg [31:0] sysclk_counter;
reg [31:0] sysclk_value;
initial snes_sysclk_freq_r = 32'hFFFFFFFF;
initial sysclk_counter = 0;
initial sysclk_value = 0;
reg [1:0] sysclk_sreg;
always @(posedge clk) sysclk_sreg <= {sysclk_sreg[0], sysclk};
wire sysclk_rising = (sysclk_sreg == 2'b01);
always @(posedge clk) begin
if(sysclk_counter < 96000000) begin
sysclk_counter <= sysclk_counter + 1;
if(sysclk_rising) sysclk_value <= sysclk_value + 1;
end else begin
snes_sysclk_freq_r <= sysclk_value;
sysclk_counter <= 0;
sysclk_value <= 0;
end
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 22:40:46 12/20/2010
// Design Name:
// Module Name: clk_test
// Project Name:
// Target Devices:
// Tool versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module clk_test(
input clk,
input sysclk,
output [31:0] snes_sysclk_freq
);
reg [31:0] snes_sysclk_freq_r;
assign snes_sysclk_freq = snes_sysclk_freq_r;
reg [31:0] sysclk_counter;
reg [31:0] sysclk_value;
initial snes_sysclk_freq_r = 32'hFFFFFFFF;
initial sysclk_counter = 0;
initial sysclk_value = 0;
reg [1:0] sysclk_sreg;
always @(posedge clk) sysclk_sreg <= {sysclk_sreg[0], sysclk};
wire sysclk_rising = (sysclk_sreg == 2'b01);
always @(posedge clk) begin
if(sysclk_counter < 96000000) begin
sysclk_counter <= sysclk_counter + 1;
if(sysclk_rising) sysclk_value <= sysclk_value + 1;
end else begin
snes_sysclk_freq_r <= sysclk_value;
sysclk_counter <= 0;
sysclk_value <= 0;
end
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 22:40:46 12/20/2010
// Design Name:
// Module Name: clk_test
// Project Name:
// Target Devices:
// Tool versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module clk_test(
input clk,
input sysclk,
output [31:0] snes_sysclk_freq
);
reg [31:0] snes_sysclk_freq_r;
assign snes_sysclk_freq = snes_sysclk_freq_r;
reg [31:0] sysclk_counter;
reg [31:0] sysclk_value;
initial snes_sysclk_freq_r = 32'hFFFFFFFF;
initial sysclk_counter = 0;
initial sysclk_value = 0;
reg [1:0] sysclk_sreg;
always @(posedge clk) sysclk_sreg <= {sysclk_sreg[0], sysclk};
wire sysclk_rising = (sysclk_sreg == 2'b01);
always @(posedge clk) begin
if(sysclk_counter < 96000000) begin
sysclk_counter <= sysclk_counter + 1;
if(sysclk_rising) sysclk_value <= sysclk_value + 1;
end else begin
snes_sysclk_freq_r <= sysclk_value;
sysclk_counter <= 0;
sysclk_value <= 0;
end
end
endmodule
|
// (c) Copyright 2012 Xilinx, Inc. All rights reserved.
//
// This file contains confidential and proprietary information
// of Xilinx, Inc. and is protected under U.S. and
// international copyright and other intellectual property
// laws.
//
// DISCLAIMER
// This disclaimer is not a license and does not grant any
// rights to the materials distributed herewith. Except as
// otherwise provided in a valid license issued to you by
// Xilinx, and to the maximum extent permitted by applicable
// law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// (2) Xilinx shall not be liable (whether in contract or tort,
// including negligence, or under any other theory of
// liability) for any loss or damage of any kind or nature
// related to, arising under or in connection with these
// materials, including for any direct, or any indirect,
// special, incidental, or consequential loss or damage
// (including loss of data, profits, goodwill, or any type of
// loss or damage suffered as a result of any action brought
// by a third party) even if such damage or loss was
// reasonably foreseeable or Xilinx had been advised of the
// possibility of the same.
//
// CRITICAL APPLICATIONS
// Xilinx products are not designed or intended to be fail-
// safe, or for use in any application requiring fail-safe
// performance, such as life-support or safety devices or
// systems, Class III medical devices, nuclear facilities,
// applications related to the deployment of airbags, or any
// other applications that could lead to death, personal
// injury, or severe property or environmental damage
// (individually and collectively, "Critical
// Applications"). Customer assumes the sole risk and
// liability of any use of Xilinx products in Critical
// Applications, subject only to applicable laws and
// regulations governing limitations on product liability.
//
// THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// axi to vector
// A generic module to merge all axi signals into one signal called payload.
// This is strictly wires, so no clk, reset, aclken, valid/ready are required.
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
`timescale 1ps/1ps
`default_nettype none
(* DowngradeIPIdentifiedWarnings="yes" *)
module axi_infrastructure_v1_1_vector2axi #
(
///////////////////////////////////////////////////////////////////////////////
// Parameter Definitions
///////////////////////////////////////////////////////////////////////////////
parameter integer C_AXI_PROTOCOL = 0,
parameter integer C_AXI_ID_WIDTH = 4,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0,
parameter integer C_AXI_SUPPORTS_REGION_SIGNALS = 0,
parameter integer C_AXI_AWUSER_WIDTH = 1,
parameter integer C_AXI_WUSER_WIDTH = 1,
parameter integer C_AXI_BUSER_WIDTH = 1,
parameter integer C_AXI_ARUSER_WIDTH = 1,
parameter integer C_AXI_RUSER_WIDTH = 1,
parameter integer C_AWPAYLOAD_WIDTH = 61,
parameter integer C_WPAYLOAD_WIDTH = 73,
parameter integer C_BPAYLOAD_WIDTH = 6,
parameter integer C_ARPAYLOAD_WIDTH = 61,
parameter integer C_RPAYLOAD_WIDTH = 69
)
(
///////////////////////////////////////////////////////////////////////////////
// Port Declarations
///////////////////////////////////////////////////////////////////////////////
// Slave Interface Write Address Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_awlen,
output wire [3-1:0] m_axi_awsize,
output wire [2-1:0] m_axi_awburst,
output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_awlock,
output wire [4-1:0] m_axi_awcache,
output wire [3-1:0] m_axi_awprot,
output wire [4-1:0] m_axi_awregion,
output wire [4-1:0] m_axi_awqos,
output wire [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
// Slave Interface Write Data Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output wire [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output wire [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output wire m_axi_wlast,
output wire [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
// Slave Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input wire [2-1:0] m_axi_bresp,
input wire [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
// Slave Interface Read Address Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_arlen,
output wire [3-1:0] m_axi_arsize,
output wire [2-1:0] m_axi_arburst,
output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_arlock,
output wire [4-1:0] m_axi_arcache,
output wire [3-1:0] m_axi_arprot,
output wire [4-1:0] m_axi_arregion,
output wire [4-1:0] m_axi_arqos,
output wire [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
// Slave Interface Read Data Ports
input wire [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input wire [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input wire [2-1:0] m_axi_rresp,
input wire m_axi_rlast,
input wire [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
// payloads
input wire [C_AWPAYLOAD_WIDTH-1:0] m_awpayload,
input wire [C_WPAYLOAD_WIDTH-1:0] m_wpayload,
output wire [C_BPAYLOAD_WIDTH-1:0] m_bpayload,
input wire [C_ARPAYLOAD_WIDTH-1:0] m_arpayload,
output wire [C_RPAYLOAD_WIDTH-1:0] m_rpayload
);
////////////////////////////////////////////////////////////////////////////////
// Functions
////////////////////////////////////////////////////////////////////////////////
`include "axi_infrastructure_v1_1_header.vh"
////////////////////////////////////////////////////////////////////////////////
// Local parameters
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// Wires/Reg declarations
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// BEGIN RTL
////////////////////////////////////////////////////////////////////////////////
// AXI4, AXI4LITE, AXI3 packing
assign m_axi_awaddr = m_awpayload[G_AXI_AWADDR_INDEX+:G_AXI_AWADDR_WIDTH];
assign m_axi_awprot = m_awpayload[G_AXI_AWPROT_INDEX+:G_AXI_AWPROT_WIDTH];
assign m_axi_wdata = m_wpayload[G_AXI_WDATA_INDEX+:G_AXI_WDATA_WIDTH];
assign m_axi_wstrb = m_wpayload[G_AXI_WSTRB_INDEX+:G_AXI_WSTRB_WIDTH];
assign m_bpayload[G_AXI_BRESP_INDEX+:G_AXI_BRESP_WIDTH] = m_axi_bresp;
assign m_axi_araddr = m_arpayload[G_AXI_ARADDR_INDEX+:G_AXI_ARADDR_WIDTH];
assign m_axi_arprot = m_arpayload[G_AXI_ARPROT_INDEX+:G_AXI_ARPROT_WIDTH];
assign m_rpayload[G_AXI_RDATA_INDEX+:G_AXI_RDATA_WIDTH] = m_axi_rdata;
assign m_rpayload[G_AXI_RRESP_INDEX+:G_AXI_RRESP_WIDTH] = m_axi_rresp;
generate
if (C_AXI_PROTOCOL == 0 || C_AXI_PROTOCOL == 1) begin : gen_axi4_or_axi3_packing
assign m_axi_awsize = m_awpayload[G_AXI_AWSIZE_INDEX+:G_AXI_AWSIZE_WIDTH] ;
assign m_axi_awburst = m_awpayload[G_AXI_AWBURST_INDEX+:G_AXI_AWBURST_WIDTH];
assign m_axi_awcache = m_awpayload[G_AXI_AWCACHE_INDEX+:G_AXI_AWCACHE_WIDTH];
assign m_axi_awlen = m_awpayload[G_AXI_AWLEN_INDEX+:G_AXI_AWLEN_WIDTH] ;
assign m_axi_awlock = m_awpayload[G_AXI_AWLOCK_INDEX+:G_AXI_AWLOCK_WIDTH] ;
assign m_axi_awid = m_awpayload[G_AXI_AWID_INDEX+:G_AXI_AWID_WIDTH] ;
assign m_axi_awqos = m_awpayload[G_AXI_AWQOS_INDEX+:G_AXI_AWQOS_WIDTH] ;
assign m_axi_wlast = m_wpayload[G_AXI_WLAST_INDEX+:G_AXI_WLAST_WIDTH] ;
if (C_AXI_PROTOCOL == 1) begin : gen_axi3_wid_packing
assign m_axi_wid = m_wpayload[G_AXI_WID_INDEX+:G_AXI_WID_WIDTH] ;
end
else begin : gen_no_axi3_wid_packing
assign m_axi_wid = 1'b0;
end
assign m_bpayload[G_AXI_BID_INDEX+:G_AXI_BID_WIDTH] = m_axi_bid;
assign m_axi_arsize = m_arpayload[G_AXI_ARSIZE_INDEX+:G_AXI_ARSIZE_WIDTH] ;
assign m_axi_arburst = m_arpayload[G_AXI_ARBURST_INDEX+:G_AXI_ARBURST_WIDTH];
assign m_axi_arcache = m_arpayload[G_AXI_ARCACHE_INDEX+:G_AXI_ARCACHE_WIDTH];
assign m_axi_arlen = m_arpayload[G_AXI_ARLEN_INDEX+:G_AXI_ARLEN_WIDTH] ;
assign m_axi_arlock = m_arpayload[G_AXI_ARLOCK_INDEX+:G_AXI_ARLOCK_WIDTH] ;
assign m_axi_arid = m_arpayload[G_AXI_ARID_INDEX+:G_AXI_ARID_WIDTH] ;
assign m_axi_arqos = m_arpayload[G_AXI_ARQOS_INDEX+:G_AXI_ARQOS_WIDTH] ;
assign m_rpayload[G_AXI_RLAST_INDEX+:G_AXI_RLAST_WIDTH] = m_axi_rlast;
assign m_rpayload[G_AXI_RID_INDEX+:G_AXI_RID_WIDTH] = m_axi_rid ;
if (C_AXI_SUPPORTS_REGION_SIGNALS == 1 && G_AXI_AWREGION_WIDTH > 0) begin : gen_region_signals
assign m_axi_awregion = m_awpayload[G_AXI_AWREGION_INDEX+:G_AXI_AWREGION_WIDTH];
assign m_axi_arregion = m_arpayload[G_AXI_ARREGION_INDEX+:G_AXI_ARREGION_WIDTH];
end
else begin : gen_no_region_signals
assign m_axi_awregion = 'b0;
assign m_axi_arregion = 'b0;
end
if (C_AXI_SUPPORTS_USER_SIGNALS == 1 && C_AXI_PROTOCOL != 2) begin : gen_user_signals
assign m_axi_awuser = m_awpayload[G_AXI_AWUSER_INDEX+:G_AXI_AWUSER_WIDTH];
assign m_axi_wuser = m_wpayload[G_AXI_WUSER_INDEX+:G_AXI_WUSER_WIDTH] ;
assign m_bpayload[G_AXI_BUSER_INDEX+:G_AXI_BUSER_WIDTH] = m_axi_buser ;
assign m_axi_aruser = m_arpayload[G_AXI_ARUSER_INDEX+:G_AXI_ARUSER_WIDTH];
assign m_rpayload[G_AXI_RUSER_INDEX+:G_AXI_RUSER_WIDTH] = m_axi_ruser ;
end
else begin : gen_no_user_signals
assign m_axi_awuser = 'b0;
assign m_axi_wuser = 'b0;
assign m_axi_aruser = 'b0;
end
end
else begin : gen_axi4lite_packing
assign m_axi_awsize = (C_AXI_DATA_WIDTH == 32) ? 3'd2 : 3'd3;
assign m_axi_awburst = 'b0;
assign m_axi_awcache = 'b0;
assign m_axi_awlen = 'b0;
assign m_axi_awlock = 'b0;
assign m_axi_awid = 'b0;
assign m_axi_awqos = 'b0;
assign m_axi_wlast = 1'b1;
assign m_axi_wid = 'b0;
assign m_axi_arsize = (C_AXI_DATA_WIDTH == 32) ? 3'd2 : 3'd3;
assign m_axi_arburst = 'b0;
assign m_axi_arcache = 'b0;
assign m_axi_arlen = 'b0;
assign m_axi_arlock = 'b0;
assign m_axi_arid = 'b0;
assign m_axi_arqos = 'b0;
assign m_axi_awregion = 'b0;
assign m_axi_arregion = 'b0;
assign m_axi_awuser = 'b0;
assign m_axi_wuser = 'b0;
assign m_axi_aruser = 'b0;
end
endgenerate
endmodule
`default_nettype wire
|
// (c) Copyright 2012 Xilinx, Inc. All rights reserved.
//
// This file contains confidential and proprietary information
// of Xilinx, Inc. and is protected under U.S. and
// international copyright and other intellectual property
// laws.
//
// DISCLAIMER
// This disclaimer is not a license and does not grant any
// rights to the materials distributed herewith. Except as
// otherwise provided in a valid license issued to you by
// Xilinx, and to the maximum extent permitted by applicable
// law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// (2) Xilinx shall not be liable (whether in contract or tort,
// including negligence, or under any other theory of
// liability) for any loss or damage of any kind or nature
// related to, arising under or in connection with these
// materials, including for any direct, or any indirect,
// special, incidental, or consequential loss or damage
// (including loss of data, profits, goodwill, or any type of
// loss or damage suffered as a result of any action brought
// by a third party) even if such damage or loss was
// reasonably foreseeable or Xilinx had been advised of the
// possibility of the same.
//
// CRITICAL APPLICATIONS
// Xilinx products are not designed or intended to be fail-
// safe, or for use in any application requiring fail-safe
// performance, such as life-support or safety devices or
// systems, Class III medical devices, nuclear facilities,
// applications related to the deployment of airbags, or any
// other applications that could lead to death, personal
// injury, or severe property or environmental damage
// (individually and collectively, "Critical
// Applications"). Customer assumes the sole risk and
// liability of any use of Xilinx products in Critical
// Applications, subject only to applicable laws and
// regulations governing limitations on product liability.
//
// THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// axi to vector
// A generic module to merge all axi signals into one signal called payload.
// This is strictly wires, so no clk, reset, aclken, valid/ready are required.
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
`timescale 1ps/1ps
`default_nettype none
(* DowngradeIPIdentifiedWarnings="yes" *)
module axi_infrastructure_v1_1_vector2axi #
(
///////////////////////////////////////////////////////////////////////////////
// Parameter Definitions
///////////////////////////////////////////////////////////////////////////////
parameter integer C_AXI_PROTOCOL = 0,
parameter integer C_AXI_ID_WIDTH = 4,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0,
parameter integer C_AXI_SUPPORTS_REGION_SIGNALS = 0,
parameter integer C_AXI_AWUSER_WIDTH = 1,
parameter integer C_AXI_WUSER_WIDTH = 1,
parameter integer C_AXI_BUSER_WIDTH = 1,
parameter integer C_AXI_ARUSER_WIDTH = 1,
parameter integer C_AXI_RUSER_WIDTH = 1,
parameter integer C_AWPAYLOAD_WIDTH = 61,
parameter integer C_WPAYLOAD_WIDTH = 73,
parameter integer C_BPAYLOAD_WIDTH = 6,
parameter integer C_ARPAYLOAD_WIDTH = 61,
parameter integer C_RPAYLOAD_WIDTH = 69
)
(
///////////////////////////////////////////////////////////////////////////////
// Port Declarations
///////////////////////////////////////////////////////////////////////////////
// Slave Interface Write Address Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_awlen,
output wire [3-1:0] m_axi_awsize,
output wire [2-1:0] m_axi_awburst,
output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_awlock,
output wire [4-1:0] m_axi_awcache,
output wire [3-1:0] m_axi_awprot,
output wire [4-1:0] m_axi_awregion,
output wire [4-1:0] m_axi_awqos,
output wire [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
// Slave Interface Write Data Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output wire [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output wire [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output wire m_axi_wlast,
output wire [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
// Slave Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input wire [2-1:0] m_axi_bresp,
input wire [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
// Slave Interface Read Address Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_arlen,
output wire [3-1:0] m_axi_arsize,
output wire [2-1:0] m_axi_arburst,
output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_arlock,
output wire [4-1:0] m_axi_arcache,
output wire [3-1:0] m_axi_arprot,
output wire [4-1:0] m_axi_arregion,
output wire [4-1:0] m_axi_arqos,
output wire [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
// Slave Interface Read Data Ports
input wire [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input wire [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input wire [2-1:0] m_axi_rresp,
input wire m_axi_rlast,
input wire [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
// payloads
input wire [C_AWPAYLOAD_WIDTH-1:0] m_awpayload,
input wire [C_WPAYLOAD_WIDTH-1:0] m_wpayload,
output wire [C_BPAYLOAD_WIDTH-1:0] m_bpayload,
input wire [C_ARPAYLOAD_WIDTH-1:0] m_arpayload,
output wire [C_RPAYLOAD_WIDTH-1:0] m_rpayload
);
////////////////////////////////////////////////////////////////////////////////
// Functions
////////////////////////////////////////////////////////////////////////////////
`include "axi_infrastructure_v1_1_header.vh"
////////////////////////////////////////////////////////////////////////////////
// Local parameters
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// Wires/Reg declarations
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// BEGIN RTL
////////////////////////////////////////////////////////////////////////////////
// AXI4, AXI4LITE, AXI3 packing
assign m_axi_awaddr = m_awpayload[G_AXI_AWADDR_INDEX+:G_AXI_AWADDR_WIDTH];
assign m_axi_awprot = m_awpayload[G_AXI_AWPROT_INDEX+:G_AXI_AWPROT_WIDTH];
assign m_axi_wdata = m_wpayload[G_AXI_WDATA_INDEX+:G_AXI_WDATA_WIDTH];
assign m_axi_wstrb = m_wpayload[G_AXI_WSTRB_INDEX+:G_AXI_WSTRB_WIDTH];
assign m_bpayload[G_AXI_BRESP_INDEX+:G_AXI_BRESP_WIDTH] = m_axi_bresp;
assign m_axi_araddr = m_arpayload[G_AXI_ARADDR_INDEX+:G_AXI_ARADDR_WIDTH];
assign m_axi_arprot = m_arpayload[G_AXI_ARPROT_INDEX+:G_AXI_ARPROT_WIDTH];
assign m_rpayload[G_AXI_RDATA_INDEX+:G_AXI_RDATA_WIDTH] = m_axi_rdata;
assign m_rpayload[G_AXI_RRESP_INDEX+:G_AXI_RRESP_WIDTH] = m_axi_rresp;
generate
if (C_AXI_PROTOCOL == 0 || C_AXI_PROTOCOL == 1) begin : gen_axi4_or_axi3_packing
assign m_axi_awsize = m_awpayload[G_AXI_AWSIZE_INDEX+:G_AXI_AWSIZE_WIDTH] ;
assign m_axi_awburst = m_awpayload[G_AXI_AWBURST_INDEX+:G_AXI_AWBURST_WIDTH];
assign m_axi_awcache = m_awpayload[G_AXI_AWCACHE_INDEX+:G_AXI_AWCACHE_WIDTH];
assign m_axi_awlen = m_awpayload[G_AXI_AWLEN_INDEX+:G_AXI_AWLEN_WIDTH] ;
assign m_axi_awlock = m_awpayload[G_AXI_AWLOCK_INDEX+:G_AXI_AWLOCK_WIDTH] ;
assign m_axi_awid = m_awpayload[G_AXI_AWID_INDEX+:G_AXI_AWID_WIDTH] ;
assign m_axi_awqos = m_awpayload[G_AXI_AWQOS_INDEX+:G_AXI_AWQOS_WIDTH] ;
assign m_axi_wlast = m_wpayload[G_AXI_WLAST_INDEX+:G_AXI_WLAST_WIDTH] ;
if (C_AXI_PROTOCOL == 1) begin : gen_axi3_wid_packing
assign m_axi_wid = m_wpayload[G_AXI_WID_INDEX+:G_AXI_WID_WIDTH] ;
end
else begin : gen_no_axi3_wid_packing
assign m_axi_wid = 1'b0;
end
assign m_bpayload[G_AXI_BID_INDEX+:G_AXI_BID_WIDTH] = m_axi_bid;
assign m_axi_arsize = m_arpayload[G_AXI_ARSIZE_INDEX+:G_AXI_ARSIZE_WIDTH] ;
assign m_axi_arburst = m_arpayload[G_AXI_ARBURST_INDEX+:G_AXI_ARBURST_WIDTH];
assign m_axi_arcache = m_arpayload[G_AXI_ARCACHE_INDEX+:G_AXI_ARCACHE_WIDTH];
assign m_axi_arlen = m_arpayload[G_AXI_ARLEN_INDEX+:G_AXI_ARLEN_WIDTH] ;
assign m_axi_arlock = m_arpayload[G_AXI_ARLOCK_INDEX+:G_AXI_ARLOCK_WIDTH] ;
assign m_axi_arid = m_arpayload[G_AXI_ARID_INDEX+:G_AXI_ARID_WIDTH] ;
assign m_axi_arqos = m_arpayload[G_AXI_ARQOS_INDEX+:G_AXI_ARQOS_WIDTH] ;
assign m_rpayload[G_AXI_RLAST_INDEX+:G_AXI_RLAST_WIDTH] = m_axi_rlast;
assign m_rpayload[G_AXI_RID_INDEX+:G_AXI_RID_WIDTH] = m_axi_rid ;
if (C_AXI_SUPPORTS_REGION_SIGNALS == 1 && G_AXI_AWREGION_WIDTH > 0) begin : gen_region_signals
assign m_axi_awregion = m_awpayload[G_AXI_AWREGION_INDEX+:G_AXI_AWREGION_WIDTH];
assign m_axi_arregion = m_arpayload[G_AXI_ARREGION_INDEX+:G_AXI_ARREGION_WIDTH];
end
else begin : gen_no_region_signals
assign m_axi_awregion = 'b0;
assign m_axi_arregion = 'b0;
end
if (C_AXI_SUPPORTS_USER_SIGNALS == 1 && C_AXI_PROTOCOL != 2) begin : gen_user_signals
assign m_axi_awuser = m_awpayload[G_AXI_AWUSER_INDEX+:G_AXI_AWUSER_WIDTH];
assign m_axi_wuser = m_wpayload[G_AXI_WUSER_INDEX+:G_AXI_WUSER_WIDTH] ;
assign m_bpayload[G_AXI_BUSER_INDEX+:G_AXI_BUSER_WIDTH] = m_axi_buser ;
assign m_axi_aruser = m_arpayload[G_AXI_ARUSER_INDEX+:G_AXI_ARUSER_WIDTH];
assign m_rpayload[G_AXI_RUSER_INDEX+:G_AXI_RUSER_WIDTH] = m_axi_ruser ;
end
else begin : gen_no_user_signals
assign m_axi_awuser = 'b0;
assign m_axi_wuser = 'b0;
assign m_axi_aruser = 'b0;
end
end
else begin : gen_axi4lite_packing
assign m_axi_awsize = (C_AXI_DATA_WIDTH == 32) ? 3'd2 : 3'd3;
assign m_axi_awburst = 'b0;
assign m_axi_awcache = 'b0;
assign m_axi_awlen = 'b0;
assign m_axi_awlock = 'b0;
assign m_axi_awid = 'b0;
assign m_axi_awqos = 'b0;
assign m_axi_wlast = 1'b1;
assign m_axi_wid = 'b0;
assign m_axi_arsize = (C_AXI_DATA_WIDTH == 32) ? 3'd2 : 3'd3;
assign m_axi_arburst = 'b0;
assign m_axi_arcache = 'b0;
assign m_axi_arlen = 'b0;
assign m_axi_arlock = 'b0;
assign m_axi_arid = 'b0;
assign m_axi_arqos = 'b0;
assign m_axi_awregion = 'b0;
assign m_axi_arregion = 'b0;
assign m_axi_awuser = 'b0;
assign m_axi_wuser = 'b0;
assign m_axi_aruser = 'b0;
end
endgenerate
endmodule
`default_nettype wire
|
// (c) Copyright 2012 Xilinx, Inc. All rights reserved.
//
// This file contains confidential and proprietary information
// of Xilinx, Inc. and is protected under U.S. and
// international copyright and other intellectual property
// laws.
//
// DISCLAIMER
// This disclaimer is not a license and does not grant any
// rights to the materials distributed herewith. Except as
// otherwise provided in a valid license issued to you by
// Xilinx, and to the maximum extent permitted by applicable
// law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// (2) Xilinx shall not be liable (whether in contract or tort,
// including negligence, or under any other theory of
// liability) for any loss or damage of any kind or nature
// related to, arising under or in connection with these
// materials, including for any direct, or any indirect,
// special, incidental, or consequential loss or damage
// (including loss of data, profits, goodwill, or any type of
// loss or damage suffered as a result of any action brought
// by a third party) even if such damage or loss was
// reasonably foreseeable or Xilinx had been advised of the
// possibility of the same.
//
// CRITICAL APPLICATIONS
// Xilinx products are not designed or intended to be fail-
// safe, or for use in any application requiring fail-safe
// performance, such as life-support or safety devices or
// systems, Class III medical devices, nuclear facilities,
// applications related to the deployment of airbags, or any
// other applications that could lead to death, personal
// injury, or severe property or environmental damage
// (individually and collectively, "Critical
// Applications"). Customer assumes the sole risk and
// liability of any use of Xilinx products in Critical
// Applications, subject only to applicable laws and
// regulations governing limitations on product liability.
//
// THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// axi to vector
// A generic module to merge all axi signals into one signal called payload.
// This is strictly wires, so no clk, reset, aclken, valid/ready are required.
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
`timescale 1ps/1ps
`default_nettype none
(* DowngradeIPIdentifiedWarnings="yes" *)
module axi_infrastructure_v1_1_vector2axi #
(
///////////////////////////////////////////////////////////////////////////////
// Parameter Definitions
///////////////////////////////////////////////////////////////////////////////
parameter integer C_AXI_PROTOCOL = 0,
parameter integer C_AXI_ID_WIDTH = 4,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0,
parameter integer C_AXI_SUPPORTS_REGION_SIGNALS = 0,
parameter integer C_AXI_AWUSER_WIDTH = 1,
parameter integer C_AXI_WUSER_WIDTH = 1,
parameter integer C_AXI_BUSER_WIDTH = 1,
parameter integer C_AXI_ARUSER_WIDTH = 1,
parameter integer C_AXI_RUSER_WIDTH = 1,
parameter integer C_AWPAYLOAD_WIDTH = 61,
parameter integer C_WPAYLOAD_WIDTH = 73,
parameter integer C_BPAYLOAD_WIDTH = 6,
parameter integer C_ARPAYLOAD_WIDTH = 61,
parameter integer C_RPAYLOAD_WIDTH = 69
)
(
///////////////////////////////////////////////////////////////////////////////
// Port Declarations
///////////////////////////////////////////////////////////////////////////////
// Slave Interface Write Address Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_awlen,
output wire [3-1:0] m_axi_awsize,
output wire [2-1:0] m_axi_awburst,
output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_awlock,
output wire [4-1:0] m_axi_awcache,
output wire [3-1:0] m_axi_awprot,
output wire [4-1:0] m_axi_awregion,
output wire [4-1:0] m_axi_awqos,
output wire [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
// Slave Interface Write Data Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output wire [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output wire [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output wire m_axi_wlast,
output wire [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
// Slave Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input wire [2-1:0] m_axi_bresp,
input wire [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
// Slave Interface Read Address Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_arlen,
output wire [3-1:0] m_axi_arsize,
output wire [2-1:0] m_axi_arburst,
output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_arlock,
output wire [4-1:0] m_axi_arcache,
output wire [3-1:0] m_axi_arprot,
output wire [4-1:0] m_axi_arregion,
output wire [4-1:0] m_axi_arqos,
output wire [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
// Slave Interface Read Data Ports
input wire [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input wire [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input wire [2-1:0] m_axi_rresp,
input wire m_axi_rlast,
input wire [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
// payloads
input wire [C_AWPAYLOAD_WIDTH-1:0] m_awpayload,
input wire [C_WPAYLOAD_WIDTH-1:0] m_wpayload,
output wire [C_BPAYLOAD_WIDTH-1:0] m_bpayload,
input wire [C_ARPAYLOAD_WIDTH-1:0] m_arpayload,
output wire [C_RPAYLOAD_WIDTH-1:0] m_rpayload
);
////////////////////////////////////////////////////////////////////////////////
// Functions
////////////////////////////////////////////////////////////////////////////////
`include "axi_infrastructure_v1_1_header.vh"
////////////////////////////////////////////////////////////////////////////////
// Local parameters
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// Wires/Reg declarations
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// BEGIN RTL
////////////////////////////////////////////////////////////////////////////////
// AXI4, AXI4LITE, AXI3 packing
assign m_axi_awaddr = m_awpayload[G_AXI_AWADDR_INDEX+:G_AXI_AWADDR_WIDTH];
assign m_axi_awprot = m_awpayload[G_AXI_AWPROT_INDEX+:G_AXI_AWPROT_WIDTH];
assign m_axi_wdata = m_wpayload[G_AXI_WDATA_INDEX+:G_AXI_WDATA_WIDTH];
assign m_axi_wstrb = m_wpayload[G_AXI_WSTRB_INDEX+:G_AXI_WSTRB_WIDTH];
assign m_bpayload[G_AXI_BRESP_INDEX+:G_AXI_BRESP_WIDTH] = m_axi_bresp;
assign m_axi_araddr = m_arpayload[G_AXI_ARADDR_INDEX+:G_AXI_ARADDR_WIDTH];
assign m_axi_arprot = m_arpayload[G_AXI_ARPROT_INDEX+:G_AXI_ARPROT_WIDTH];
assign m_rpayload[G_AXI_RDATA_INDEX+:G_AXI_RDATA_WIDTH] = m_axi_rdata;
assign m_rpayload[G_AXI_RRESP_INDEX+:G_AXI_RRESP_WIDTH] = m_axi_rresp;
generate
if (C_AXI_PROTOCOL == 0 || C_AXI_PROTOCOL == 1) begin : gen_axi4_or_axi3_packing
assign m_axi_awsize = m_awpayload[G_AXI_AWSIZE_INDEX+:G_AXI_AWSIZE_WIDTH] ;
assign m_axi_awburst = m_awpayload[G_AXI_AWBURST_INDEX+:G_AXI_AWBURST_WIDTH];
assign m_axi_awcache = m_awpayload[G_AXI_AWCACHE_INDEX+:G_AXI_AWCACHE_WIDTH];
assign m_axi_awlen = m_awpayload[G_AXI_AWLEN_INDEX+:G_AXI_AWLEN_WIDTH] ;
assign m_axi_awlock = m_awpayload[G_AXI_AWLOCK_INDEX+:G_AXI_AWLOCK_WIDTH] ;
assign m_axi_awid = m_awpayload[G_AXI_AWID_INDEX+:G_AXI_AWID_WIDTH] ;
assign m_axi_awqos = m_awpayload[G_AXI_AWQOS_INDEX+:G_AXI_AWQOS_WIDTH] ;
assign m_axi_wlast = m_wpayload[G_AXI_WLAST_INDEX+:G_AXI_WLAST_WIDTH] ;
if (C_AXI_PROTOCOL == 1) begin : gen_axi3_wid_packing
assign m_axi_wid = m_wpayload[G_AXI_WID_INDEX+:G_AXI_WID_WIDTH] ;
end
else begin : gen_no_axi3_wid_packing
assign m_axi_wid = 1'b0;
end
assign m_bpayload[G_AXI_BID_INDEX+:G_AXI_BID_WIDTH] = m_axi_bid;
assign m_axi_arsize = m_arpayload[G_AXI_ARSIZE_INDEX+:G_AXI_ARSIZE_WIDTH] ;
assign m_axi_arburst = m_arpayload[G_AXI_ARBURST_INDEX+:G_AXI_ARBURST_WIDTH];
assign m_axi_arcache = m_arpayload[G_AXI_ARCACHE_INDEX+:G_AXI_ARCACHE_WIDTH];
assign m_axi_arlen = m_arpayload[G_AXI_ARLEN_INDEX+:G_AXI_ARLEN_WIDTH] ;
assign m_axi_arlock = m_arpayload[G_AXI_ARLOCK_INDEX+:G_AXI_ARLOCK_WIDTH] ;
assign m_axi_arid = m_arpayload[G_AXI_ARID_INDEX+:G_AXI_ARID_WIDTH] ;
assign m_axi_arqos = m_arpayload[G_AXI_ARQOS_INDEX+:G_AXI_ARQOS_WIDTH] ;
assign m_rpayload[G_AXI_RLAST_INDEX+:G_AXI_RLAST_WIDTH] = m_axi_rlast;
assign m_rpayload[G_AXI_RID_INDEX+:G_AXI_RID_WIDTH] = m_axi_rid ;
if (C_AXI_SUPPORTS_REGION_SIGNALS == 1 && G_AXI_AWREGION_WIDTH > 0) begin : gen_region_signals
assign m_axi_awregion = m_awpayload[G_AXI_AWREGION_INDEX+:G_AXI_AWREGION_WIDTH];
assign m_axi_arregion = m_arpayload[G_AXI_ARREGION_INDEX+:G_AXI_ARREGION_WIDTH];
end
else begin : gen_no_region_signals
assign m_axi_awregion = 'b0;
assign m_axi_arregion = 'b0;
end
if (C_AXI_SUPPORTS_USER_SIGNALS == 1 && C_AXI_PROTOCOL != 2) begin : gen_user_signals
assign m_axi_awuser = m_awpayload[G_AXI_AWUSER_INDEX+:G_AXI_AWUSER_WIDTH];
assign m_axi_wuser = m_wpayload[G_AXI_WUSER_INDEX+:G_AXI_WUSER_WIDTH] ;
assign m_bpayload[G_AXI_BUSER_INDEX+:G_AXI_BUSER_WIDTH] = m_axi_buser ;
assign m_axi_aruser = m_arpayload[G_AXI_ARUSER_INDEX+:G_AXI_ARUSER_WIDTH];
assign m_rpayload[G_AXI_RUSER_INDEX+:G_AXI_RUSER_WIDTH] = m_axi_ruser ;
end
else begin : gen_no_user_signals
assign m_axi_awuser = 'b0;
assign m_axi_wuser = 'b0;
assign m_axi_aruser = 'b0;
end
end
else begin : gen_axi4lite_packing
assign m_axi_awsize = (C_AXI_DATA_WIDTH == 32) ? 3'd2 : 3'd3;
assign m_axi_awburst = 'b0;
assign m_axi_awcache = 'b0;
assign m_axi_awlen = 'b0;
assign m_axi_awlock = 'b0;
assign m_axi_awid = 'b0;
assign m_axi_awqos = 'b0;
assign m_axi_wlast = 1'b1;
assign m_axi_wid = 'b0;
assign m_axi_arsize = (C_AXI_DATA_WIDTH == 32) ? 3'd2 : 3'd3;
assign m_axi_arburst = 'b0;
assign m_axi_arcache = 'b0;
assign m_axi_arlen = 'b0;
assign m_axi_arlock = 'b0;
assign m_axi_arid = 'b0;
assign m_axi_arqos = 'b0;
assign m_axi_awregion = 'b0;
assign m_axi_arregion = 'b0;
assign m_axi_awuser = 'b0;
assign m_axi_wuser = 'b0;
assign m_axi_aruser = 'b0;
end
endgenerate
endmodule
`default_nettype wire
|
// (c) Copyright 2012 Xilinx, Inc. All rights reserved.
//
// This file contains confidential and proprietary information
// of Xilinx, Inc. and is protected under U.S. and
// international copyright and other intellectual property
// laws.
//
// DISCLAIMER
// This disclaimer is not a license and does not grant any
// rights to the materials distributed herewith. Except as
// otherwise provided in a valid license issued to you by
// Xilinx, and to the maximum extent permitted by applicable
// law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// (2) Xilinx shall not be liable (whether in contract or tort,
// including negligence, or under any other theory of
// liability) for any loss or damage of any kind or nature
// related to, arising under or in connection with these
// materials, including for any direct, or any indirect,
// special, incidental, or consequential loss or damage
// (including loss of data, profits, goodwill, or any type of
// loss or damage suffered as a result of any action brought
// by a third party) even if such damage or loss was
// reasonably foreseeable or Xilinx had been advised of the
// possibility of the same.
//
// CRITICAL APPLICATIONS
// Xilinx products are not designed or intended to be fail-
// safe, or for use in any application requiring fail-safe
// performance, such as life-support or safety devices or
// systems, Class III medical devices, nuclear facilities,
// applications related to the deployment of airbags, or any
// other applications that could lead to death, personal
// injury, or severe property or environmental damage
// (individually and collectively, "Critical
// Applications"). Customer assumes the sole risk and
// liability of any use of Xilinx products in Critical
// Applications, subject only to applicable laws and
// regulations governing limitations on product liability.
//
// THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// PART OF THIS FILE AT ALL TIMES.
//-----------------------------------------------------------------------------
//
// axi to vector
// A generic module to merge all axi signals into one signal called payload.
// This is strictly wires, so no clk, reset, aclken, valid/ready are required.
//
// Verilog-standard: Verilog 2001
//--------------------------------------------------------------------------
//
`timescale 1ps/1ps
`default_nettype none
(* DowngradeIPIdentifiedWarnings="yes" *)
module axi_infrastructure_v1_1_vector2axi #
(
///////////////////////////////////////////////////////////////////////////////
// Parameter Definitions
///////////////////////////////////////////////////////////////////////////////
parameter integer C_AXI_PROTOCOL = 0,
parameter integer C_AXI_ID_WIDTH = 4,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0,
parameter integer C_AXI_SUPPORTS_REGION_SIGNALS = 0,
parameter integer C_AXI_AWUSER_WIDTH = 1,
parameter integer C_AXI_WUSER_WIDTH = 1,
parameter integer C_AXI_BUSER_WIDTH = 1,
parameter integer C_AXI_ARUSER_WIDTH = 1,
parameter integer C_AXI_RUSER_WIDTH = 1,
parameter integer C_AWPAYLOAD_WIDTH = 61,
parameter integer C_WPAYLOAD_WIDTH = 73,
parameter integer C_BPAYLOAD_WIDTH = 6,
parameter integer C_ARPAYLOAD_WIDTH = 61,
parameter integer C_RPAYLOAD_WIDTH = 69
)
(
///////////////////////////////////////////////////////////////////////////////
// Port Declarations
///////////////////////////////////////////////////////////////////////////////
// Slave Interface Write Address Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_awid,
output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_awlen,
output wire [3-1:0] m_axi_awsize,
output wire [2-1:0] m_axi_awburst,
output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_awlock,
output wire [4-1:0] m_axi_awcache,
output wire [3-1:0] m_axi_awprot,
output wire [4-1:0] m_axi_awregion,
output wire [4-1:0] m_axi_awqos,
output wire [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser,
// Slave Interface Write Data Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_wid,
output wire [C_AXI_DATA_WIDTH-1:0] m_axi_wdata,
output wire [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb,
output wire m_axi_wlast,
output wire [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser,
// Slave Interface Write Response Ports
input wire [C_AXI_ID_WIDTH-1:0] m_axi_bid,
input wire [2-1:0] m_axi_bresp,
input wire [C_AXI_BUSER_WIDTH-1:0] m_axi_buser,
// Slave Interface Read Address Ports
output wire [C_AXI_ID_WIDTH-1:0] m_axi_arid,
output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_arlen,
output wire [3-1:0] m_axi_arsize,
output wire [2-1:0] m_axi_arburst,
output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_arlock,
output wire [4-1:0] m_axi_arcache,
output wire [3-1:0] m_axi_arprot,
output wire [4-1:0] m_axi_arregion,
output wire [4-1:0] m_axi_arqos,
output wire [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser,
// Slave Interface Read Data Ports
input wire [C_AXI_ID_WIDTH-1:0] m_axi_rid,
input wire [C_AXI_DATA_WIDTH-1:0] m_axi_rdata,
input wire [2-1:0] m_axi_rresp,
input wire m_axi_rlast,
input wire [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser,
// payloads
input wire [C_AWPAYLOAD_WIDTH-1:0] m_awpayload,
input wire [C_WPAYLOAD_WIDTH-1:0] m_wpayload,
output wire [C_BPAYLOAD_WIDTH-1:0] m_bpayload,
input wire [C_ARPAYLOAD_WIDTH-1:0] m_arpayload,
output wire [C_RPAYLOAD_WIDTH-1:0] m_rpayload
);
////////////////////////////////////////////////////////////////////////////////
// Functions
////////////////////////////////////////////////////////////////////////////////
`include "axi_infrastructure_v1_1_header.vh"
////////////////////////////////////////////////////////////////////////////////
// Local parameters
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// Wires/Reg declarations
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// BEGIN RTL
////////////////////////////////////////////////////////////////////////////////
// AXI4, AXI4LITE, AXI3 packing
assign m_axi_awaddr = m_awpayload[G_AXI_AWADDR_INDEX+:G_AXI_AWADDR_WIDTH];
assign m_axi_awprot = m_awpayload[G_AXI_AWPROT_INDEX+:G_AXI_AWPROT_WIDTH];
assign m_axi_wdata = m_wpayload[G_AXI_WDATA_INDEX+:G_AXI_WDATA_WIDTH];
assign m_axi_wstrb = m_wpayload[G_AXI_WSTRB_INDEX+:G_AXI_WSTRB_WIDTH];
assign m_bpayload[G_AXI_BRESP_INDEX+:G_AXI_BRESP_WIDTH] = m_axi_bresp;
assign m_axi_araddr = m_arpayload[G_AXI_ARADDR_INDEX+:G_AXI_ARADDR_WIDTH];
assign m_axi_arprot = m_arpayload[G_AXI_ARPROT_INDEX+:G_AXI_ARPROT_WIDTH];
assign m_rpayload[G_AXI_RDATA_INDEX+:G_AXI_RDATA_WIDTH] = m_axi_rdata;
assign m_rpayload[G_AXI_RRESP_INDEX+:G_AXI_RRESP_WIDTH] = m_axi_rresp;
generate
if (C_AXI_PROTOCOL == 0 || C_AXI_PROTOCOL == 1) begin : gen_axi4_or_axi3_packing
assign m_axi_awsize = m_awpayload[G_AXI_AWSIZE_INDEX+:G_AXI_AWSIZE_WIDTH] ;
assign m_axi_awburst = m_awpayload[G_AXI_AWBURST_INDEX+:G_AXI_AWBURST_WIDTH];
assign m_axi_awcache = m_awpayload[G_AXI_AWCACHE_INDEX+:G_AXI_AWCACHE_WIDTH];
assign m_axi_awlen = m_awpayload[G_AXI_AWLEN_INDEX+:G_AXI_AWLEN_WIDTH] ;
assign m_axi_awlock = m_awpayload[G_AXI_AWLOCK_INDEX+:G_AXI_AWLOCK_WIDTH] ;
assign m_axi_awid = m_awpayload[G_AXI_AWID_INDEX+:G_AXI_AWID_WIDTH] ;
assign m_axi_awqos = m_awpayload[G_AXI_AWQOS_INDEX+:G_AXI_AWQOS_WIDTH] ;
assign m_axi_wlast = m_wpayload[G_AXI_WLAST_INDEX+:G_AXI_WLAST_WIDTH] ;
if (C_AXI_PROTOCOL == 1) begin : gen_axi3_wid_packing
assign m_axi_wid = m_wpayload[G_AXI_WID_INDEX+:G_AXI_WID_WIDTH] ;
end
else begin : gen_no_axi3_wid_packing
assign m_axi_wid = 1'b0;
end
assign m_bpayload[G_AXI_BID_INDEX+:G_AXI_BID_WIDTH] = m_axi_bid;
assign m_axi_arsize = m_arpayload[G_AXI_ARSIZE_INDEX+:G_AXI_ARSIZE_WIDTH] ;
assign m_axi_arburst = m_arpayload[G_AXI_ARBURST_INDEX+:G_AXI_ARBURST_WIDTH];
assign m_axi_arcache = m_arpayload[G_AXI_ARCACHE_INDEX+:G_AXI_ARCACHE_WIDTH];
assign m_axi_arlen = m_arpayload[G_AXI_ARLEN_INDEX+:G_AXI_ARLEN_WIDTH] ;
assign m_axi_arlock = m_arpayload[G_AXI_ARLOCK_INDEX+:G_AXI_ARLOCK_WIDTH] ;
assign m_axi_arid = m_arpayload[G_AXI_ARID_INDEX+:G_AXI_ARID_WIDTH] ;
assign m_axi_arqos = m_arpayload[G_AXI_ARQOS_INDEX+:G_AXI_ARQOS_WIDTH] ;
assign m_rpayload[G_AXI_RLAST_INDEX+:G_AXI_RLAST_WIDTH] = m_axi_rlast;
assign m_rpayload[G_AXI_RID_INDEX+:G_AXI_RID_WIDTH] = m_axi_rid ;
if (C_AXI_SUPPORTS_REGION_SIGNALS == 1 && G_AXI_AWREGION_WIDTH > 0) begin : gen_region_signals
assign m_axi_awregion = m_awpayload[G_AXI_AWREGION_INDEX+:G_AXI_AWREGION_WIDTH];
assign m_axi_arregion = m_arpayload[G_AXI_ARREGION_INDEX+:G_AXI_ARREGION_WIDTH];
end
else begin : gen_no_region_signals
assign m_axi_awregion = 'b0;
assign m_axi_arregion = 'b0;
end
if (C_AXI_SUPPORTS_USER_SIGNALS == 1 && C_AXI_PROTOCOL != 2) begin : gen_user_signals
assign m_axi_awuser = m_awpayload[G_AXI_AWUSER_INDEX+:G_AXI_AWUSER_WIDTH];
assign m_axi_wuser = m_wpayload[G_AXI_WUSER_INDEX+:G_AXI_WUSER_WIDTH] ;
assign m_bpayload[G_AXI_BUSER_INDEX+:G_AXI_BUSER_WIDTH] = m_axi_buser ;
assign m_axi_aruser = m_arpayload[G_AXI_ARUSER_INDEX+:G_AXI_ARUSER_WIDTH];
assign m_rpayload[G_AXI_RUSER_INDEX+:G_AXI_RUSER_WIDTH] = m_axi_ruser ;
end
else begin : gen_no_user_signals
assign m_axi_awuser = 'b0;
assign m_axi_wuser = 'b0;
assign m_axi_aruser = 'b0;
end
end
else begin : gen_axi4lite_packing
assign m_axi_awsize = (C_AXI_DATA_WIDTH == 32) ? 3'd2 : 3'd3;
assign m_axi_awburst = 'b0;
assign m_axi_awcache = 'b0;
assign m_axi_awlen = 'b0;
assign m_axi_awlock = 'b0;
assign m_axi_awid = 'b0;
assign m_axi_awqos = 'b0;
assign m_axi_wlast = 1'b1;
assign m_axi_wid = 'b0;
assign m_axi_arsize = (C_AXI_DATA_WIDTH == 32) ? 3'd2 : 3'd3;
assign m_axi_arburst = 'b0;
assign m_axi_arcache = 'b0;
assign m_axi_arlen = 'b0;
assign m_axi_arlock = 'b0;
assign m_axi_arid = 'b0;
assign m_axi_arqos = 'b0;
assign m_axi_awregion = 'b0;
assign m_axi_arregion = 'b0;
assign m_axi_awuser = 'b0;
assign m_axi_wuser = 'b0;
assign m_axi_aruser = 'b0;
end
endgenerate
endmodule
`default_nettype wire
|
// $File: //acds/rel/15.1/ip/sopc/components/altera_avalon_dc_fifo/altera_avalon_dc_fifo.v $
// $Revision: #1 $
// $Date: 2015/08/09 $
// $Author: swbranch $
//-------------------------------------------------------------------------------
// Description: Dual clocked single channel FIFO with fill levels and status
// information.
// ---------------------------------------------------------------------
`timescale 1 ns / 100 ps
//altera message_off 10036 10858 10230 10030 10034
module altera_avalon_dc_fifo(
in_clk,
in_reset_n,
out_clk,
out_reset_n,
// sink
in_data,
in_valid,
in_ready,
in_startofpacket,
in_endofpacket,
in_empty,
in_error,
in_channel,
// source
out_data,
out_valid,
out_ready,
out_startofpacket,
out_endofpacket,
out_empty,
out_error,
out_channel,
// in csr
in_csr_address,
in_csr_write,
in_csr_read,
in_csr_readdata,
in_csr_writedata,
// out csr
out_csr_address,
out_csr_write,
out_csr_read,
out_csr_readdata,
out_csr_writedata,
// streaming in status
almost_full_valid,
almost_full_data,
// streaming out status
almost_empty_valid,
almost_empty_data,
// (internal, experimental interface) space available st source
space_avail_data
);
// ---------------------------------------------------------------------
// Parameters
// ---------------------------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1;
parameter BITS_PER_SYMBOL = 8;
parameter FIFO_DEPTH = 16;
parameter CHANNEL_WIDTH = 0;
parameter ERROR_WIDTH = 0;
parameter USE_PACKETS = 0;
parameter USE_IN_FILL_LEVEL = 0;
parameter USE_OUT_FILL_LEVEL = 0;
parameter WR_SYNC_DEPTH = 2;
parameter RD_SYNC_DEPTH = 2;
parameter STREAM_ALMOST_FULL = 0;
parameter STREAM_ALMOST_EMPTY = 0;
parameter BACKPRESSURE_DURING_RESET = 0;
// optimizations
parameter LOOKAHEAD_POINTERS = 0;
parameter PIPELINE_POINTERS = 0;
// experimental, internal parameter
parameter USE_SPACE_AVAIL_IF = 0;
localparam ADDR_WIDTH = log2ceil(FIFO_DEPTH);
localparam DEPTH = 2 ** ADDR_WIDTH;
localparam DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL;
localparam EMPTY_WIDTH = log2ceil(SYMBOLS_PER_BEAT);
localparam PACKET_SIGNALS_WIDTH = 2 + EMPTY_WIDTH;
localparam PAYLOAD_WIDTH = (USE_PACKETS == 1) ?
2 + EMPTY_WIDTH + DATA_WIDTH + ERROR_WIDTH + CHANNEL_WIDTH:
DATA_WIDTH + ERROR_WIDTH + CHANNEL_WIDTH;
// ---------------------------------------------------------------------
// Input/Output Signals
// ---------------------------------------------------------------------
input in_clk;
input in_reset_n;
input out_clk;
input out_reset_n;
input [DATA_WIDTH - 1 : 0] in_data;
input in_valid;
input in_startofpacket;
input in_endofpacket;
input [((EMPTY_WIDTH > 0) ? EMPTY_WIDTH - 1 : 0) : 0] in_empty;
input [((ERROR_WIDTH > 0) ? ERROR_WIDTH - 1 : 0) : 0] in_error;
input [((CHANNEL_WIDTH > 0) ? CHANNEL_WIDTH - 1 : 0) : 0] in_channel;
output in_ready;
output [DATA_WIDTH - 1 : 0] out_data;
output reg out_valid;
output out_startofpacket;
output out_endofpacket;
output [((EMPTY_WIDTH > 0) ? EMPTY_WIDTH - 1 : 0) : 0] out_empty;
output [((ERROR_WIDTH > 0) ? ERROR_WIDTH - 1 : 0) : 0] out_error;
output [((CHANNEL_WIDTH > 0) ? CHANNEL_WIDTH - 1 : 0) : 0] out_channel;
input out_ready;
input in_csr_address;
input in_csr_read;
input in_csr_write;
input [31 : 0] in_csr_writedata;
output reg [31 : 0] in_csr_readdata;
input out_csr_address;
input out_csr_read;
input out_csr_write;
input [31 : 0] out_csr_writedata;
output reg [31 : 0] out_csr_readdata;
output reg almost_full_valid;
output reg almost_full_data;
output reg almost_empty_valid;
output reg almost_empty_data;
output [ADDR_WIDTH : 0] space_avail_data;
// ---------------------------------------------------------------------
// Memory Pointers
// ---------------------------------------------------------------------
(* ramstyle="no_rw_check" *) reg [PAYLOAD_WIDTH - 1 : 0] mem [DEPTH - 1 : 0];
wire [ADDR_WIDTH - 1 : 0] mem_wr_ptr;
wire [ADDR_WIDTH - 1 : 0] mem_rd_ptr;
reg [ADDR_WIDTH : 0] in_wr_ptr;
reg [ADDR_WIDTH : 0] in_wr_ptr_lookahead;
reg [ADDR_WIDTH : 0] out_rd_ptr;
reg [ADDR_WIDTH : 0] out_rd_ptr_lookahead;
// ---------------------------------------------------------------------
// Internal Signals
// ---------------------------------------------------------------------
wire [ADDR_WIDTH : 0] next_out_wr_ptr;
wire [ADDR_WIDTH : 0] next_in_wr_ptr;
wire [ADDR_WIDTH : 0] next_out_rd_ptr;
wire [ADDR_WIDTH : 0] next_in_rd_ptr;
reg [ADDR_WIDTH : 0] in_wr_ptr_gray /*synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=D102" */;
wire [ADDR_WIDTH : 0] out_wr_ptr_gray;
reg [ADDR_WIDTH : 0] out_rd_ptr_gray /*synthesis ALTERA_ATTRIBUTE = "SUPPRESS_DA_RULE_INTERNAL=D102" */;
wire [ADDR_WIDTH : 0] in_rd_ptr_gray;
reg [ADDR_WIDTH : 0] out_wr_ptr_gray_reg;
reg [ADDR_WIDTH : 0] in_rd_ptr_gray_reg;
reg full;
reg empty;
wire [PAYLOAD_WIDTH - 1 : 0] in_payload;
reg [PAYLOAD_WIDTH - 1 : 0] out_payload;
reg [PAYLOAD_WIDTH - 1 : 0] internal_out_payload;
wire [PACKET_SIGNALS_WIDTH - 1 : 0] in_packet_signals;
wire [PACKET_SIGNALS_WIDTH - 1 : 0] out_packet_signals;
wire internal_out_ready;
wire internal_out_valid;
wire [ADDR_WIDTH : 0] out_fill_level;
reg [ADDR_WIDTH : 0] out_fifo_fill_level;
reg [ADDR_WIDTH : 0] in_fill_level;
reg [ADDR_WIDTH : 0] in_space_avail;
reg [23 : 0] almost_empty_threshold;
reg [23 : 0] almost_full_threshold;
reg sink_in_reset;
// --------------------------------------------------
// Define Payload
//
// Icky part where we decide which signals form the
// payload to the FIFO.
// --------------------------------------------------
generate
if (EMPTY_WIDTH > 0) begin
assign in_packet_signals = {in_startofpacket, in_endofpacket, in_empty};
assign {out_startofpacket, out_endofpacket, out_empty} = out_packet_signals;
end
else begin
assign in_packet_signals = {in_startofpacket, in_endofpacket};
assign {out_startofpacket, out_endofpacket} = out_packet_signals;
end
endgenerate
generate
if (USE_PACKETS) begin
if (ERROR_WIDTH > 0) begin
if (CHANNEL_WIDTH > 0) begin
assign in_payload = {in_packet_signals, in_data, in_error, in_channel};
assign {out_packet_signals, out_data, out_error, out_channel} = out_payload;
end
else begin
assign in_payload = {in_packet_signals, in_data, in_error};
assign {out_packet_signals, out_data, out_error} = out_payload;
end
end
else begin
if (CHANNEL_WIDTH > 0) begin
assign in_payload = {in_packet_signals, in_data, in_channel};
assign {out_packet_signals, out_data, out_channel} = out_payload;
end
else begin
assign in_payload = {in_packet_signals, in_data};
assign {out_packet_signals, out_data} = out_payload;
end
end
end
else begin
if (ERROR_WIDTH > 0) begin
if (CHANNEL_WIDTH > 0) begin
assign in_payload = {in_data, in_error, in_channel};
assign {out_data, out_error, out_channel} = out_payload;
end
else begin
assign in_payload = {in_data, in_error};
assign {out_data, out_error} = out_payload;
end
end
else begin
if (CHANNEL_WIDTH > 0) begin
assign in_payload = {in_data, in_channel};
assign {out_data, out_channel} = out_payload;
end
else begin
assign in_payload = in_data;
assign out_data = out_payload;
end
end
assign out_packet_signals = 'b0;
end
endgenerate
// ---------------------------------------------------------------------
// Memory
//
// Infers a simple dual clock memory with unregistered outputs
// ---------------------------------------------------------------------
always @(posedge in_clk) begin
if (in_valid && in_ready)
mem[mem_wr_ptr] <= in_payload;
end
always @(posedge out_clk) begin
internal_out_payload <= mem[mem_rd_ptr];
end
assign mem_rd_ptr = next_out_rd_ptr;
assign mem_wr_ptr = in_wr_ptr;
// ---------------------------------------------------------------------
// Pointer Management
//
// Increment our good old read and write pointers on their native
// clock domains.
// ---------------------------------------------------------------------
always @(posedge in_clk or negedge in_reset_n) begin
if (!in_reset_n) begin
in_wr_ptr <= 0;
in_wr_ptr_lookahead <= 1;
end
else begin
in_wr_ptr <= next_in_wr_ptr;
in_wr_ptr_lookahead <= (in_valid && in_ready) ? in_wr_ptr_lookahead + 1'b1 : in_wr_ptr_lookahead;
end
end
always @(posedge out_clk or negedge out_reset_n) begin
if (!out_reset_n) begin
out_rd_ptr <= 0;
out_rd_ptr_lookahead <= 1;
end
else begin
out_rd_ptr <= next_out_rd_ptr;
out_rd_ptr_lookahead <= (internal_out_valid && internal_out_ready) ? out_rd_ptr_lookahead + 1'b1 : out_rd_ptr_lookahead;
end
end
generate if (LOOKAHEAD_POINTERS) begin : lookahead_pointers
assign next_in_wr_ptr = (in_ready && in_valid) ? in_wr_ptr_lookahead : in_wr_ptr;
assign next_out_rd_ptr = (internal_out_ready && internal_out_valid) ? out_rd_ptr_lookahead : out_rd_ptr;
end
else begin : non_lookahead_pointers
assign next_in_wr_ptr = (in_ready && in_valid) ? in_wr_ptr + 1'b1 : in_wr_ptr;
assign next_out_rd_ptr = (internal_out_ready && internal_out_valid) ? out_rd_ptr + 1'b1 : out_rd_ptr;
end
endgenerate
// ---------------------------------------------------------------------
// Empty/Full Signal Generation
//
// We keep read and write pointers that are one bit wider than
// required, and use that additional bit to figure out if we're
// full or empty.
// ---------------------------------------------------------------------
always @(posedge out_clk or negedge out_reset_n) begin
if(!out_reset_n)
empty <= 1;
else
empty <= (next_out_rd_ptr == next_out_wr_ptr);
end
always @(posedge in_clk or negedge in_reset_n) begin
if (!in_reset_n) begin
full <= 0;
sink_in_reset <= 1'b1;
end
else begin
full <= (next_in_rd_ptr[ADDR_WIDTH - 1 : 0] == next_in_wr_ptr[ADDR_WIDTH - 1 : 0]) && (next_in_rd_ptr[ADDR_WIDTH] != next_in_wr_ptr[ADDR_WIDTH]);
sink_in_reset <= 1'b0;
end
end
// ---------------------------------------------------------------------
// Write Pointer Clock Crossing
//
// Clock crossing is done with gray encoding of the pointers. What? You
// want to know more? We ensure a one bit change at sampling time,
// and then metastable harden the sampled gray pointer.
// ---------------------------------------------------------------------
always @(posedge in_clk or negedge in_reset_n) begin
if (!in_reset_n)
in_wr_ptr_gray <= 0;
else
in_wr_ptr_gray <= bin2gray(in_wr_ptr);
end
altera_dcfifo_synchronizer_bundle #(.WIDTH(ADDR_WIDTH+1), .DEPTH(WR_SYNC_DEPTH))
write_crosser (
.clk(out_clk),
.reset_n(out_reset_n),
.din(in_wr_ptr_gray),
.dout(out_wr_ptr_gray)
);
// ---------------------------------------------------------------------
// Optionally pipeline the gray to binary conversion for the write pointer.
// Doing this will increase the latency of the FIFO, but increase fmax.
// ---------------------------------------------------------------------
generate if (PIPELINE_POINTERS) begin : wr_ptr_pipeline
always @(posedge out_clk or negedge out_reset_n) begin
if (!out_reset_n)
out_wr_ptr_gray_reg <= 0;
else
out_wr_ptr_gray_reg <= gray2bin(out_wr_ptr_gray);
end
assign next_out_wr_ptr = out_wr_ptr_gray_reg;
end
else begin : no_wr_ptr_pipeline
assign next_out_wr_ptr = gray2bin(out_wr_ptr_gray);
end
endgenerate
// ---------------------------------------------------------------------
// Read Pointer Clock Crossing
//
// Go the other way, go the other way...
// ---------------------------------------------------------------------
always @(posedge out_clk or negedge out_reset_n) begin
if (!out_reset_n)
out_rd_ptr_gray <= 0;
else
out_rd_ptr_gray <= bin2gray(out_rd_ptr);
end
altera_dcfifo_synchronizer_bundle #(.WIDTH(ADDR_WIDTH+1), .DEPTH(RD_SYNC_DEPTH))
read_crosser (
.clk(in_clk),
.reset_n(in_reset_n),
.din(out_rd_ptr_gray),
.dout(in_rd_ptr_gray)
);
// ---------------------------------------------------------------------
// Optionally pipeline the gray to binary conversion of the read pointer.
// Doing this will increase the pessimism of the FIFO, but increase fmax.
// ---------------------------------------------------------------------
generate if (PIPELINE_POINTERS) begin : rd_ptr_pipeline
always @(posedge in_clk or negedge in_reset_n) begin
if (!in_reset_n)
in_rd_ptr_gray_reg <= 0;
else
in_rd_ptr_gray_reg <= gray2bin(in_rd_ptr_gray);
end
assign next_in_rd_ptr = in_rd_ptr_gray_reg;
end
else begin : no_rd_ptr_pipeline
assign next_in_rd_ptr = gray2bin(in_rd_ptr_gray);
end
endgenerate
// ---------------------------------------------------------------------
// Avalon ST Signals
// ---------------------------------------------------------------------
assign in_ready = BACKPRESSURE_DURING_RESET ? !(full || sink_in_reset) : !full;
assign internal_out_valid = !empty;
// --------------------------------------------------
// Output Pipeline Stage
//
// We do this on the single clock FIFO to keep fmax
// up because the memory outputs are kind of slow.
// Therefore, this stage is even more critical on a dual clock
// FIFO, wouldn't you say? No one wants a slow dcfifo.
// --------------------------------------------------
assign internal_out_ready = out_ready || !out_valid;
always @(posedge out_clk or negedge out_reset_n) begin
if (!out_reset_n) begin
out_valid <= 0;
out_payload <= 0;
end
else begin
if (internal_out_ready) begin
out_valid <= internal_out_valid;
out_payload <= internal_out_payload;
end
end
end
// ---------------------------------------------------------------------
// Out Fill Level
//
// As in the SCFIFO, we account for the output stage as well in the
// fill level calculations. This means that the out fill level always
// gives the most accurate fill level report.
//
// On a full 16-deep FIFO, the out fill level will read 17. Funny, but
// accurate.
//
// That's essential on the output side, because a downstream component
// might want to know the exact amount of data in the FIFO at any time.
// ---------------------------------------------------------------------
generate
if (USE_OUT_FILL_LEVEL || STREAM_ALMOST_EMPTY) begin
always @(posedge out_clk or negedge out_reset_n) begin
if (!out_reset_n) begin
out_fifo_fill_level <= 0;
end
else begin
out_fifo_fill_level <= next_out_wr_ptr - next_out_rd_ptr;
end
end
assign out_fill_level = out_fifo_fill_level + {{ADDR_WIDTH{1'b0}}, out_valid};
end
endgenerate
// ---------------------------------------------------------------------
// Almost Empty Streaming Status & Out CSR
//
// This is banal by now, but where's the empty signal? The output side.
// Where's the almost empty status? The output side.
//
// The almost empty signal is asserted when the output fill level
// in the FIFO falls below the user-specified threshold.
//
// Output CSR address map:
//
// | Addr | RW | 31 - 24 | 23 - 0 |
// | 0 | R | Reserved | Out fill level |
// | 1 | RW | Reserved | Almost empty threshold |
// ---------------------------------------------------------------------
generate
if (USE_OUT_FILL_LEVEL || STREAM_ALMOST_EMPTY) begin
always @(posedge out_clk or negedge out_reset_n) begin
if (!out_reset_n) begin
out_csr_readdata <= 0;
if (STREAM_ALMOST_EMPTY)
almost_empty_threshold <= 0;
end
else begin
if (out_csr_write) begin
if (STREAM_ALMOST_EMPTY && (out_csr_address == 1))
almost_empty_threshold <= out_csr_writedata[23 : 0];
end
else if (out_csr_read) begin
out_csr_readdata <= 0;
if (out_csr_address == 0)
out_csr_readdata[23 : 0] <= out_fill_level;
else if (STREAM_ALMOST_EMPTY && (out_csr_address == 1))
out_csr_readdata[23 : 0] <= almost_empty_threshold;
end
end
end
end
if (STREAM_ALMOST_EMPTY) begin
always @(posedge out_clk or negedge out_reset_n) begin
if (!out_reset_n) begin
almost_empty_valid <= 0;
almost_empty_data <= 0;
end
else begin
almost_empty_valid <= 1'b1;
almost_empty_data <= (out_fill_level <= almost_empty_threshold);
end
end
end
endgenerate
// ---------------------------------------------------------------------
// In Fill Level & In Status Connection Point
//
// Note that the input fill level does not account for the output
// stage i.e it is only the fifo fill level.
//
// Is this a problem? No, because the input fill is usually used to
// see how much data can still be pushed into this FIFO. The FIFO
// fill level gives exactly this information, and there's no need to
// make our lives more difficult by including the output stage here.
//
// One might ask: why not just report a space available level on the
// input side? Well, I'd like to make this FIFO be as similar as possible
// to its single clock cousin, and that uses fill levels and
// fill thresholds with nary a mention of space available.
// ---------------------------------------------------------------------
generate
if (USE_IN_FILL_LEVEL || STREAM_ALMOST_FULL) begin
always @(posedge in_clk or negedge in_reset_n) begin
if (!in_reset_n) begin
in_fill_level <= 0;
end
else begin
in_fill_level <= next_in_wr_ptr - next_in_rd_ptr;
end
end
end
endgenerate
generate
if (USE_SPACE_AVAIL_IF) begin
always @(posedge in_clk or negedge in_reset_n) begin
if (!in_reset_n) begin
in_space_avail <= FIFO_DEPTH;
end
else begin
// -------------------------------------
// space = DEPTH-fill = DEPTH-(wr-rd) = DEPTH+rd-wr
// Conveniently, DEPTH requires the same number of bits
// as the pointers, e.g. a dcfifo with depth = 8
// requires 4-bit pointers.
//
// Adding 8 to a 4-bit pointer is simply negating the
// first bit... as is done below.
// -------------------------------------
in_space_avail <= {~next_in_rd_ptr[ADDR_WIDTH],
next_in_rd_ptr[ADDR_WIDTH-1:0]} -
next_in_wr_ptr;
end
end
assign space_avail_data = in_space_avail;
end
else begin : gen_blk13_else
assign space_avail_data = 'b0;
end
endgenerate
// ---------------------------------------------------------------------
// Almost Full Streaming Status & In CSR
//
// Where's the full signal? The input side.
// Where's the almost full status? The input side.
//
// The almost full data bit is asserted when the input fill level
// in the FIFO goes above the user-specified threshold.
//
// Input csr port address map:
//
// | Addr | RW | 31 - 24 | 23 - 0 |
// | 0 | R | Reserved | In fill level |
// | 1 | RW | Reserved | Almost full threshold |
// ---------------------------------------------------------------------
generate
if (USE_IN_FILL_LEVEL || STREAM_ALMOST_FULL) begin
always @(posedge in_clk or negedge in_reset_n) begin
if (!in_reset_n) begin
in_csr_readdata <= 0;
if (STREAM_ALMOST_FULL)
almost_full_threshold <= 0;
end
else begin
if (in_csr_write) begin
if (STREAM_ALMOST_FULL && (in_csr_address == 1))
almost_full_threshold <= in_csr_writedata[23 : 0];
end
else if (in_csr_read) begin
in_csr_readdata <= 0;
if (in_csr_address == 0)
in_csr_readdata[23 : 0] <= in_fill_level;
else if (STREAM_ALMOST_FULL && (in_csr_address == 1))
in_csr_readdata[23 : 0] <= almost_full_threshold;
end
end
end
end
if (STREAM_ALMOST_FULL) begin
always @(posedge in_clk or negedge in_reset_n) begin
if (!in_reset_n) begin
almost_full_valid <= 0;
almost_full_data <= 0;
end
else begin
almost_full_valid <= 1'b1;
almost_full_data <= (in_fill_level >= almost_full_threshold);
end
end
end
endgenerate
// ---------------------------------------------------------------------
// Gray Functions
//
// These are real beasts when you look at them. But they'll be
// tested thoroughly.
// ---------------------------------------------------------------------
function [ADDR_WIDTH : 0] bin2gray;
input [ADDR_WIDTH : 0] bin_val;
integer i;
for (i = 0; i <= ADDR_WIDTH; i = i + 1)
begin
if (i == ADDR_WIDTH)
bin2gray[i] = bin_val[i];
else
bin2gray[i] = bin_val[i+1] ^ bin_val[i];
end
endfunction
function [ADDR_WIDTH : 0] gray2bin;
input [ADDR_WIDTH : 0] gray_val;
integer i;
integer j;
for (i = 0; i <= ADDR_WIDTH; i = i + 1) begin
gray2bin[i] = gray_val[i];
for (j = ADDR_WIDTH; j > i; j = j - 1) begin
gray2bin[i] = gray2bin[i] ^ gray_val[j];
end
end
endfunction
// --------------------------------------------------
// Calculates the log2ceil of the input value
// --------------------------------------------------
function integer log2ceil;
input integer val;
integer i;
begin
i = 1;
log2ceil = 0;
while (i < val) begin
log2ceil = log2ceil + 1;
i = i << 1;
end
end
endfunction
endmodule
|
// Copyright 1986-2016 Xilinx, Inc. All Rights Reserved.
// --------------------------------------------------------------------------------
// Tool Version: Vivado v.2016.3 (win64) Build 1682563 Mon Oct 10 19:07:27 MDT 2016
// Date : Thu Sep 14 09:48:07 2017
// Host : PC4719 running 64-bit Service Pack 1 (build 7601)
// Command : write_verilog -force -mode synth_stub -rename_top decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix -prefix
// decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix_ srio_gen2_0_stub.v
// Design : srio_gen2_0
// Purpose : Stub declaration of top-level module interface
// Device : xc7k325tffg676-2
// --------------------------------------------------------------------------------
// This empty module with port declaration file causes synthesis tools to infer a black box for IP.
// The synthesis directives are for Synopsys Synplify support to prevent IO buffer insertion.
// Please paste the declaration into a Verilog source file or add the file as an additional source.
(* X_CORE_INFO = "srio_gen2_v4_0_5,Vivado 2015.1.0" *)
module decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix(sys_clkp, sys_clkn, sys_rst, log_clk_out,
phy_clk_out, gt_clk_out, gt_pcs_clk_out, drpclk_out, refclk_out, clk_lock_out, cfg_rst_out,
log_rst_out, buf_rst_out, phy_rst_out, gt_pcs_rst_out, gt0_qpll_clk_out,
gt0_qpll_out_refclk_out, srio_rxn0, srio_rxp0, srio_txn0, srio_txp0, s_axis_ireq_tvalid,
s_axis_ireq_tready, s_axis_ireq_tlast, s_axis_ireq_tdata, s_axis_ireq_tkeep,
s_axis_ireq_tuser, m_axis_iresp_tvalid, m_axis_iresp_tready, m_axis_iresp_tlast,
m_axis_iresp_tdata, m_axis_iresp_tkeep, m_axis_iresp_tuser, m_axis_treq_tvalid,
m_axis_treq_tready, m_axis_treq_tlast, m_axis_treq_tdata, m_axis_treq_tkeep,
m_axis_treq_tuser, s_axis_tresp_tvalid, s_axis_tresp_tready, s_axis_tresp_tlast,
s_axis_tresp_tdata, s_axis_tresp_tkeep, s_axis_tresp_tuser, s_axi_maintr_rst,
s_axi_maintr_awvalid, s_axi_maintr_awready, s_axi_maintr_awaddr, s_axi_maintr_wvalid,
s_axi_maintr_wready, s_axi_maintr_wdata, s_axi_maintr_bvalid, s_axi_maintr_bready,
s_axi_maintr_bresp, s_axi_maintr_arvalid, s_axi_maintr_arready, s_axi_maintr_araddr,
s_axi_maintr_rvalid, s_axi_maintr_rready, s_axi_maintr_rdata, s_axi_maintr_rresp,
sim_train_en, force_reinit, phy_mce, phy_link_reset, phy_rcvd_mce, phy_rcvd_link_reset,
phy_debug, gtrx_disperr_or, gtrx_notintable_or, port_error, port_timeout, srio_host,
port_decode_error, deviceid, idle2_selected, phy_lcl_master_enable_out,
buf_lcl_response_only_out, buf_lcl_tx_flow_control_out, buf_lcl_phy_buf_stat_out,
phy_lcl_phy_next_fm_out, phy_lcl_phy_last_ack_out, phy_lcl_phy_rewind_out,
phy_lcl_phy_rcvd_buf_stat_out, phy_lcl_maint_only_out, port_initialized,
link_initialized, idle_selected, mode_1x)
/* synthesis syn_black_box black_box_pad_pin="sys_clkp,sys_clkn,sys_rst,log_clk_out,phy_clk_out,gt_clk_out,gt_pcs_clk_out,drpclk_out,refclk_out,clk_lock_out,cfg_rst_out,log_rst_out,buf_rst_out,phy_rst_out,gt_pcs_rst_out,gt0_qpll_clk_out,gt0_qpll_out_refclk_out,srio_rxn0,srio_rxp0,srio_txn0,srio_txp0,s_axis_ireq_tvalid,s_axis_ireq_tready,s_axis_ireq_tlast,s_axis_ireq_tdata[63:0],s_axis_ireq_tkeep[7:0],s_axis_ireq_tuser[31:0],m_axis_iresp_tvalid,m_axis_iresp_tready,m_axis_iresp_tlast,m_axis_iresp_tdata[63:0],m_axis_iresp_tkeep[7:0],m_axis_iresp_tuser[31:0],m_axis_treq_tvalid,m_axis_treq_tready,m_axis_treq_tlast,m_axis_treq_tdata[63:0],m_axis_treq_tkeep[7:0],m_axis_treq_tuser[31:0],s_axis_tresp_tvalid,s_axis_tresp_tready,s_axis_tresp_tlast,s_axis_tresp_tdata[63:0],s_axis_tresp_tkeep[7:0],s_axis_tresp_tuser[31:0],s_axi_maintr_rst,s_axi_maintr_awvalid,s_axi_maintr_awready,s_axi_maintr_awaddr[31:0],s_axi_maintr_wvalid,s_axi_maintr_wready,s_axi_maintr_wdata[31:0],s_axi_maintr_bvalid,s_axi_maintr_bready,s_axi_maintr_bresp[1:0],s_axi_maintr_arvalid,s_axi_maintr_arready,s_axi_maintr_araddr[31:0],s_axi_maintr_rvalid,s_axi_maintr_rready,s_axi_maintr_rdata[31:0],s_axi_maintr_rresp[1:0],sim_train_en,force_reinit,phy_mce,phy_link_reset,phy_rcvd_mce,phy_rcvd_link_reset,phy_debug[223:0],gtrx_disperr_or,gtrx_notintable_or,port_error,port_timeout[23:0],srio_host,port_decode_error,deviceid[15:0],idle2_selected,phy_lcl_master_enable_out,buf_lcl_response_only_out,buf_lcl_tx_flow_control_out,buf_lcl_phy_buf_stat_out[5:0],phy_lcl_phy_next_fm_out[5:0],phy_lcl_phy_last_ack_out[5:0],phy_lcl_phy_rewind_out,phy_lcl_phy_rcvd_buf_stat_out[5:0],phy_lcl_maint_only_out,port_initialized,link_initialized,idle_selected,mode_1x" */;
input sys_clkp;
input sys_clkn;
input sys_rst;
output log_clk_out;
output phy_clk_out;
output gt_clk_out;
output gt_pcs_clk_out;
output drpclk_out;
output refclk_out;
output clk_lock_out;
output cfg_rst_out;
output log_rst_out;
output buf_rst_out;
output phy_rst_out;
output gt_pcs_rst_out;
output gt0_qpll_clk_out;
output gt0_qpll_out_refclk_out;
input srio_rxn0;
input srio_rxp0;
output srio_txn0;
output srio_txp0;
input s_axis_ireq_tvalid;
output s_axis_ireq_tready;
input s_axis_ireq_tlast;
input [63:0]s_axis_ireq_tdata;
input [7:0]s_axis_ireq_tkeep;
input [31:0]s_axis_ireq_tuser;
output m_axis_iresp_tvalid;
input m_axis_iresp_tready;
output m_axis_iresp_tlast;
output [63:0]m_axis_iresp_tdata;
output [7:0]m_axis_iresp_tkeep;
output [31:0]m_axis_iresp_tuser;
output m_axis_treq_tvalid;
input m_axis_treq_tready;
output m_axis_treq_tlast;
output [63:0]m_axis_treq_tdata;
output [7:0]m_axis_treq_tkeep;
output [31:0]m_axis_treq_tuser;
input s_axis_tresp_tvalid;
output s_axis_tresp_tready;
input s_axis_tresp_tlast;
input [63:0]s_axis_tresp_tdata;
input [7:0]s_axis_tresp_tkeep;
input [31:0]s_axis_tresp_tuser;
input s_axi_maintr_rst;
input s_axi_maintr_awvalid;
output s_axi_maintr_awready;
input [31:0]s_axi_maintr_awaddr;
input s_axi_maintr_wvalid;
output s_axi_maintr_wready;
input [31:0]s_axi_maintr_wdata;
output s_axi_maintr_bvalid;
input s_axi_maintr_bready;
output [1:0]s_axi_maintr_bresp;
input s_axi_maintr_arvalid;
output s_axi_maintr_arready;
input [31:0]s_axi_maintr_araddr;
output s_axi_maintr_rvalid;
input s_axi_maintr_rready;
output [31:0]s_axi_maintr_rdata;
output [1:0]s_axi_maintr_rresp;
input sim_train_en;
input force_reinit;
input phy_mce;
input phy_link_reset;
output phy_rcvd_mce;
output phy_rcvd_link_reset;
output [223:0]phy_debug;
output gtrx_disperr_or;
output gtrx_notintable_or;
output port_error;
output [23:0]port_timeout;
output srio_host;
output port_decode_error;
output [15:0]deviceid;
output idle2_selected;
output phy_lcl_master_enable_out;
output buf_lcl_response_only_out;
output buf_lcl_tx_flow_control_out;
output [5:0]buf_lcl_phy_buf_stat_out;
output [5:0]phy_lcl_phy_next_fm_out;
output [5:0]phy_lcl_phy_last_ack_out;
output phy_lcl_phy_rewind_out;
output [5:0]phy_lcl_phy_rcvd_buf_stat_out;
output phy_lcl_maint_only_out;
output port_initialized;
output link_initialized;
output idle_selected;
output mode_1x;
endmodule
|
/*
* Copyright 2020 The SkyWater PDK Authors
*
* 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
*
* https://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.
*
* SPDX-License-Identifier: Apache-2.0
*/
`ifndef SKY130_FD_SC_HD__A2BB2OI_FUNCTIONAL_V
`define SKY130_FD_SC_HD__A2BB2OI_FUNCTIONAL_V
/**
* a2bb2oi: 2-input AND, both inputs inverted, into first input, and
* 2-input AND into 2nd input of 2-input NOR.
*
* Y = !((!A1 & !A2) | (B1 & B2))
*
* Verilog simulation functional model.
*/
`timescale 1ns / 1ps
`default_nettype none
`celldefine
module sky130_fd_sc_hd__a2bb2oi (
Y ,
A1_N,
A2_N,
B1 ,
B2
);
// Module ports
output Y ;
input A1_N;
input A2_N;
input B1 ;
input B2 ;
// Local signals
wire and0_out ;
wire nor0_out ;
wire nor1_out_Y;
// Name Output Other arguments
and and0 (and0_out , B1, B2 );
nor nor0 (nor0_out , A1_N, A2_N );
nor nor1 (nor1_out_Y, nor0_out, and0_out);
buf buf0 (Y , nor1_out_Y );
endmodule
`endcelldefine
`default_nettype wire
`endif // SKY130_FD_SC_HD__A2BB2OI_FUNCTIONAL_V |
/*
* Copyright 2020 The SkyWater PDK Authors
*
* 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
*
* https://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.
*
* SPDX-License-Identifier: Apache-2.0
*/
`ifndef SKY130_FD_SC_HD__SEDFXTP_FUNCTIONAL_V
`define SKY130_FD_SC_HD__SEDFXTP_FUNCTIONAL_V
/**
* sedfxtp: Scan delay flop, data enable, non-inverted clock,
* single output.
*
* Verilog simulation functional model.
*/
`timescale 1ns / 1ps
`default_nettype none
// Import user defined primitives.
`include "../../models/udp_mux_2to1/sky130_fd_sc_hd__udp_mux_2to1.v"
`include "../../models/udp_dff_p/sky130_fd_sc_hd__udp_dff_p.v"
`celldefine
module sky130_fd_sc_hd__sedfxtp (
Q ,
CLK,
D ,
DE ,
SCD,
SCE
);
// Module ports
output Q ;
input CLK;
input D ;
input DE ;
input SCD;
input SCE;
// Local signals
wire buf_Q ;
wire mux_out;
wire de_d ;
// Delay Name Output Other arguments
sky130_fd_sc_hd__udp_mux_2to1 mux_2to10 (mux_out, de_d, SCD, SCE );
sky130_fd_sc_hd__udp_mux_2to1 mux_2to11 (de_d , buf_Q, D, DE );
sky130_fd_sc_hd__udp_dff$P `UNIT_DELAY dff0 (buf_Q , mux_out, CLK );
buf buf0 (Q , buf_Q );
endmodule
`endcelldefine
`default_nettype wire
`endif // SKY130_FD_SC_HD__SEDFXTP_FUNCTIONAL_V |
/*
Copyright (c) 2014-2018 Alex Forencich
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
*/
// Language: Verilog 2001
`timescale 1ns / 1ps
/*
* AXI4-Stream multiplexer
*/
module axis_mux #
(
// Number of AXI stream inputs
parameter S_COUNT = 4,
// Width of AXI stream interfaces in bits
parameter DATA_WIDTH = 8,
// Propagate tkeep signal
parameter KEEP_ENABLE = (DATA_WIDTH>8),
// tkeep signal width (words per cycle)
parameter KEEP_WIDTH = (DATA_WIDTH/8),
// Propagate tid signal
parameter ID_ENABLE = 0,
// tid signal width
parameter ID_WIDTH = 8,
// Propagate tdest signal
parameter DEST_ENABLE = 0,
// tdest signal width
parameter DEST_WIDTH = 8,
// Propagate tuser signal
parameter USER_ENABLE = 1,
// tuser signal width
parameter USER_WIDTH = 1
)
(
input wire clk,
input wire rst,
/*
* AXI inputs
*/
input wire [S_COUNT*DATA_WIDTH-1:0] s_axis_tdata,
input wire [S_COUNT*KEEP_WIDTH-1:0] s_axis_tkeep,
input wire [S_COUNT-1:0] s_axis_tvalid,
output wire [S_COUNT-1:0] s_axis_tready,
input wire [S_COUNT-1:0] s_axis_tlast,
input wire [S_COUNT*ID_WIDTH-1:0] s_axis_tid,
input wire [S_COUNT*DEST_WIDTH-1:0] s_axis_tdest,
input wire [S_COUNT*USER_WIDTH-1:0] s_axis_tuser,
/*
* AXI output
*/
output wire [DATA_WIDTH-1:0] m_axis_tdata,
output wire [KEEP_WIDTH-1:0] m_axis_tkeep,
output wire m_axis_tvalid,
input wire m_axis_tready,
output wire m_axis_tlast,
output wire [ID_WIDTH-1:0] m_axis_tid,
output wire [DEST_WIDTH-1:0] m_axis_tdest,
output wire [USER_WIDTH-1:0] m_axis_tuser,
/*
* Control
*/
input wire enable,
input wire [$clog2(S_COUNT)-1:0] select
);
parameter CL_S_COUNT = $clog2(S_COUNT);
reg [CL_S_COUNT-1:0] select_reg = 2'd0, select_next;
reg frame_reg = 1'b0, frame_next;
reg [S_COUNT-1:0] s_axis_tready_reg = 0, s_axis_tready_next;
// internal datapath
reg [DATA_WIDTH-1:0] m_axis_tdata_int;
reg [KEEP_WIDTH-1:0] m_axis_tkeep_int;
reg m_axis_tvalid_int;
reg m_axis_tready_int_reg = 1'b0;
reg m_axis_tlast_int;
reg [ID_WIDTH-1:0] m_axis_tid_int;
reg [DEST_WIDTH-1:0] m_axis_tdest_int;
reg [USER_WIDTH-1:0] m_axis_tuser_int;
wire m_axis_tready_int_early;
assign s_axis_tready = s_axis_tready_reg;
// mux for incoming packet
wire [DATA_WIDTH-1:0] current_s_tdata = s_axis_tdata[select_reg*DATA_WIDTH +: DATA_WIDTH];
wire [KEEP_WIDTH-1:0] current_s_tkeep = s_axis_tkeep[select_reg*KEEP_WIDTH +: KEEP_WIDTH];
wire current_s_tvalid = s_axis_tvalid[select_reg];
wire current_s_tready = s_axis_tready[select_reg];
wire current_s_tlast = s_axis_tlast[select_reg];
wire [ID_WIDTH-1:0] current_s_tid = s_axis_tid[select_reg*ID_WIDTH +: ID_WIDTH];
wire [DEST_WIDTH-1:0] current_s_tdest = s_axis_tdest[select_reg*DEST_WIDTH +: DEST_WIDTH];
wire [USER_WIDTH-1:0] current_s_tuser = s_axis_tuser[select_reg*USER_WIDTH +: USER_WIDTH];
always @* begin
select_next = select_reg;
frame_next = frame_reg;
s_axis_tready_next = 0;
if (current_s_tvalid & current_s_tready) begin
// end of frame detection
if (current_s_tlast) begin
frame_next = 1'b0;
end
end
if (!frame_reg && enable && (s_axis_tvalid & (1 << select))) begin
// start of frame, grab select value
frame_next = 1'b1;
select_next = select;
end
// generate ready signal on selected port
s_axis_tready_next = (m_axis_tready_int_early && frame_next) << select_next;
// pass through selected packet data
m_axis_tdata_int = current_s_tdata;
m_axis_tkeep_int = current_s_tkeep;
m_axis_tvalid_int = current_s_tvalid && current_s_tready && frame_reg;
m_axis_tlast_int = current_s_tlast;
m_axis_tid_int = current_s_tid;
m_axis_tdest_int = current_s_tdest;
m_axis_tuser_int = current_s_tuser;
end
always @(posedge clk) begin
if (rst) begin
select_reg <= 0;
frame_reg <= 1'b0;
s_axis_tready_reg <= 0;
end else begin
select_reg <= select_next;
frame_reg <= frame_next;
s_axis_tready_reg <= s_axis_tready_next;
end
end
// output datapath logic
reg [DATA_WIDTH-1:0] m_axis_tdata_reg = {DATA_WIDTH{1'b0}};
reg [KEEP_WIDTH-1:0] m_axis_tkeep_reg = {KEEP_WIDTH{1'b0}};
reg m_axis_tvalid_reg = 1'b0, m_axis_tvalid_next;
reg m_axis_tlast_reg = 1'b0;
reg [ID_WIDTH-1:0] m_axis_tid_reg = {ID_WIDTH{1'b0}};
reg [DEST_WIDTH-1:0] m_axis_tdest_reg = {DEST_WIDTH{1'b0}};
reg [USER_WIDTH-1:0] m_axis_tuser_reg = {USER_WIDTH{1'b0}};
reg [DATA_WIDTH-1:0] temp_m_axis_tdata_reg = {DATA_WIDTH{1'b0}};
reg [KEEP_WIDTH-1:0] temp_m_axis_tkeep_reg = {KEEP_WIDTH{1'b0}};
reg temp_m_axis_tvalid_reg = 1'b0, temp_m_axis_tvalid_next;
reg temp_m_axis_tlast_reg = 1'b0;
reg [ID_WIDTH-1:0] temp_m_axis_tid_reg = {ID_WIDTH{1'b0}};
reg [DEST_WIDTH-1:0] temp_m_axis_tdest_reg = {DEST_WIDTH{1'b0}};
reg [USER_WIDTH-1:0] temp_m_axis_tuser_reg = {USER_WIDTH{1'b0}};
// datapath control
reg store_axis_int_to_output;
reg store_axis_int_to_temp;
reg store_axis_temp_to_output;
assign m_axis_tdata = m_axis_tdata_reg;
assign m_axis_tkeep = KEEP_ENABLE ? m_axis_tkeep_reg : {KEEP_WIDTH{1'b1}};
assign m_axis_tvalid = m_axis_tvalid_reg;
assign m_axis_tlast = m_axis_tlast_reg;
assign m_axis_tid = ID_ENABLE ? m_axis_tid_reg : {ID_WIDTH{1'b0}};
assign m_axis_tdest = DEST_ENABLE ? m_axis_tdest_reg : {DEST_WIDTH{1'b0}};
assign m_axis_tuser = USER_ENABLE ? m_axis_tuser_reg : {USER_WIDTH{1'b0}};
// enable ready input next cycle if output is ready or the temp reg will not be filled on the next cycle (output reg empty or no input)
assign m_axis_tready_int_early = m_axis_tready || (!temp_m_axis_tvalid_reg && (!m_axis_tvalid_reg || !m_axis_tvalid_int));
always @* begin
// transfer sink ready state to source
m_axis_tvalid_next = m_axis_tvalid_reg;
temp_m_axis_tvalid_next = temp_m_axis_tvalid_reg;
store_axis_int_to_output = 1'b0;
store_axis_int_to_temp = 1'b0;
store_axis_temp_to_output = 1'b0;
if (m_axis_tready_int_reg) begin
// input is ready
if (m_axis_tready || !m_axis_tvalid_reg) begin
// output is ready or currently not valid, transfer data to output
m_axis_tvalid_next = m_axis_tvalid_int;
store_axis_int_to_output = 1'b1;
end else begin
// output is not ready, store input in temp
temp_m_axis_tvalid_next = m_axis_tvalid_int;
store_axis_int_to_temp = 1'b1;
end
end else if (m_axis_tready) begin
// input is not ready, but output is ready
m_axis_tvalid_next = temp_m_axis_tvalid_reg;
temp_m_axis_tvalid_next = 1'b0;
store_axis_temp_to_output = 1'b1;
end
end
always @(posedge clk) begin
if (rst) begin
m_axis_tvalid_reg <= 1'b0;
m_axis_tready_int_reg <= 1'b0;
temp_m_axis_tvalid_reg <= 1'b0;
end else begin
m_axis_tvalid_reg <= m_axis_tvalid_next;
m_axis_tready_int_reg <= m_axis_tready_int_early;
temp_m_axis_tvalid_reg <= temp_m_axis_tvalid_next;
end
// datapath
if (store_axis_int_to_output) begin
m_axis_tdata_reg <= m_axis_tdata_int;
m_axis_tkeep_reg <= m_axis_tkeep_int;
m_axis_tlast_reg <= m_axis_tlast_int;
m_axis_tid_reg <= m_axis_tid_int;
m_axis_tdest_reg <= m_axis_tdest_int;
m_axis_tuser_reg <= m_axis_tuser_int;
end else if (store_axis_temp_to_output) begin
m_axis_tdata_reg <= temp_m_axis_tdata_reg;
m_axis_tkeep_reg <= temp_m_axis_tkeep_reg;
m_axis_tlast_reg <= temp_m_axis_tlast_reg;
m_axis_tid_reg <= temp_m_axis_tid_reg;
m_axis_tdest_reg <= temp_m_axis_tdest_reg;
m_axis_tuser_reg <= temp_m_axis_tuser_reg;
end
if (store_axis_int_to_temp) begin
temp_m_axis_tdata_reg <= m_axis_tdata_int;
temp_m_axis_tkeep_reg <= m_axis_tkeep_int;
temp_m_axis_tlast_reg <= m_axis_tlast_int;
temp_m_axis_tid_reg <= m_axis_tid_int;
temp_m_axis_tdest_reg <= m_axis_tdest_int;
temp_m_axis_tuser_reg <= m_axis_tuser_int;
end
end
endmodule
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