verilog/rtl/ren_conv_top.v - third_party/shuttle/sky130/mpw-002/slot-031 - Git at Google

 // SPDX-FileCopyrightText: 2021 renzym.com
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //      http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 // SPDX-License-Identifier: Apache-2.0
 // SPDX-FileContributor: Yasir Javed <info@renzym.com>

 //////////////////////////////////////////////////////////////////////////////////
 // Company: 		Renzym
 // Engineer: 		Yasir Javed
 // Design Name: 	Renzym Convolver Top
 // Module Name:		ren_conv_top
 // Description:
 //
 // Dependencies:	Configs and BRAMs.
 //
 //////////////////////////////////////////////////////////////////////////////////
 module ren_conv_top
 	#(
 	parameter KERN_COL_WIDTH 	= 3,
 	parameter COL_WIDTH 		= 8,
 	parameter KERN_CNT_WIDTH 	= 3,
 	parameter IMG_ADDR_WIDTH 	= 6,
 	parameter RSLT_ADDR_WIDTH 	= 6
 	)
 	(
 `ifdef USE_POWER_PINS
     inout         vccd1,
     inout         vssd1,
 `endif
     // Wishbone Slave ports (WB MI A)
     input 			wb_clk_i,
     input 			wb_rst_i,
     input 			wbs_stb_i,
     input 			wbs_cyc_i,
     input 			wbs_we_i,
     input [3:0] 	wbs_sel_i,
     input [31:0] 	wbs_dat_i,
     input [31:0] 	wbs_adr_i,
     output 			wbs_ack_o,
     output [31:0] 	wbs_dat_o

 	);

 	wire 			we_regs;
 	wire 			we_img_ram;
 	wire 			we_kern_ram;
 	wire 			we_res_ram;
 	wire	[31:0]	data_out_regs;
 	wire	[7:0]	data_out_result;
 	wire			clk;
 	wire			reset;
 	reg				ready;
 	reg		[31:0]	rdata;
 	wire			start;
 	wire 	[2:0]	kern_cols;
 	wire	[7:0]	cols;
 	wire	[2:0]	kerns;
 	wire	[7:0]	stride;
 	wire			kern_addr_mode;
 	wire	[7:0]	result_cols;
 	wire	[3:0]	shift;
 	wire			en_max_pool;
 	wire	[2:0]	mask;
 	wire			done;

 	wire	[23:0]	img_data;
 	wire	[23:0]	kern_data;
 	wire	[KERN_CNT_WIDTH+KERN_COL_WIDTH-1:0]	kern_addr;
 	wire	[IMG_ADDR_WIDTH-1:0]				img_addr;
 	wire	[RSLT_ADDR_WIDTH-1:0]				result_addr;
 	wire	[7:0]	result_data;
 	wire			result_valid;

 	assign clk 		= wb_clk_i;
 	assign reset	= wb_rst_i;


     assign valid 	 = wbs_cyc_i & wbs_stb_i;
 //    assign wstrb 	 = wbs_sel_i & {(DWIDTH/8){wbs_we_i}};
     assign wbs_dat_o = rdata;
 	assign wbs_ack_o = ready;

 	assign we_regs 		= (wbs_adr_i[9:8]==0) & valid & wbs_we_i;
 	assign we_img_ram	= (wbs_adr_i[9:8]==1) & valid & wbs_we_i;
 	assign we_kern_ram	= (wbs_adr_i[9:8]==2) & valid & wbs_we_i;
 	assign we_res_ram	= (wbs_adr_i[9:8]==3) & valid & wbs_we_i;

 	always@(posedge clk)
 		if(reset)					rdata <= 0;
 		else if(wbs_adr_i[9:8]==0)	rdata <= data_out_regs;
 		else if(wbs_adr_i[9:8]==3)	rdata <= data_out_result;

 	always@(posedge clk)
 		if(reset | ready)			ready <= 0;
 		else if(valid & ~ready)		ready <= 1;

 	regs
 	#(
 		.DWIDTH	(32)
 	)
 	cfg_regs_inst
 	(
 	.clk			(clk			),
 	.reset			(reset			),
 	.addr			(wbs_adr_i[3:2]	),
 	.wr_en			(we_regs		),
 	.data_in		(wbs_dat_i		),
 	.data_out		(data_out_regs	),
 	.done			(done			),
 	.start			(start			),
 	.soft_reset		(soft_reset		),
 	.kern_cols		(kern_cols		),
 	.cols			(cols			),
 	.kerns			(kerns			),
 	.stride			(stride			),
 	.kern_addr_mode	(kern_addr_mode	),
 	.result_cols	(result_cols	),
 	.shift			(shift			),
 	.en_max_pool	(en_max_pool	),
 	.mask			(mask			),
 	.accum_ovrflow	(accum_ovrflow	)
 	);


 	ren_conv
 	#(
 	.KERN_COL_WIDTH 	(KERN_COL_WIDTH ),
 	.COL_WIDTH 			(COL_WIDTH 		),
 	.KERN_CNT_WIDTH 	(KERN_CNT_WIDTH ),
 	.IMG_ADDR_WIDTH 	(IMG_ADDR_WIDTH ),
 	.RSLT_ADDR_WIDTH 	(RSLT_ADDR_WIDTH)
 	)
 	ren_conv_inst
 	(
 	.clk			(clk			),
 	.reset			(reset|soft_reset),
 	.start			(start			),
 	.done			(done			),
 	.kern_cols		(kern_cols		),
 	.cols			(cols			),
 	.kerns			(kerns			),
 	.stride			(stride[5:0]	),
 	.kern_addr_mode	(kern_addr_mode	),
 	.result_cols	(result_cols[5:0]),
 	.shift			(shift			),
 	.en_max_pool	(en_max_pool	),
 	.mask			(mask			),
 	.img_data		(img_data		),
 	.kern_data		(kern_data		),
 	.kern_addr		(kern_addr		),
 	.img_addr		(img_addr		),
 	.result_addr	(result_addr	),
 	.result_data	(result_data	),
 	.result_valid	(result_valid	),
 	.accum_ovrflow	(accum_ovrflow	)
 	);

 	dffram
 	#(
 	.DWIDTH (24),
 	.AWIDTH (6 )
 	)
 	img_dffram
 	(
 	.clk		(clk			),
 	.we			(we_img_ram		),
 	.dat_o		(				),
 	.dat_o2		(img_data		),
 	.dat_i		(wbs_dat_i[23:0]),
 	.adr_w		(wbs_adr_i[7:2]	),
 	.adr_r		(img_addr		)
 	);

 	dffram
 	#(
 	.DWIDTH (24),
 	.AWIDTH (6 )
 	)
 	kerns_dffram
 	(
 	.clk		(clk			),
 	.we			(we_kern_ram	),
 	.dat_o		(				),
 	.dat_o2		(kern_data		),
 	.dat_i		(wbs_dat_i[23:0]),
 	.adr_w		(wbs_adr_i[7:2]	),
 	.adr_r		(kern_addr		)
 	);

 	dffram
 	#(
 	.DWIDTH (8),
 	.AWIDTH (6 )
 	)
 	results_dffram
 	(
 	.clk		(clk			),
 	.we			(result_valid & ~done	),
 	.dat_o		(				),
 	.dat_o2		(data_out_result),
 	.dat_i		(result_data	),
 	.adr_w		(result_addr	),
 	.adr_r		(wbs_adr_i[7:2])
 	);

 endmodule
	// SPDX-FileCopyrightText: 2021 renzym.com
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.
	// SPDX-License-Identifier: Apache-2.0
	// SPDX-FileContributor: Yasir Javed <info@renzym.com>

	//////////////////////////////////////////////////////////////////////////////////
	// Company: Renzym
	// Engineer: Yasir Javed
	// Design Name: Renzym Convolver Top
	// Module Name: ren_conv_top
	// Description:
	//
	// Dependencies: Configs and BRAMs.
	//
	//////////////////////////////////////////////////////////////////////////////////
	module ren_conv_top
	#(
	parameter KERN_COL_WIDTH = 3,
	parameter COL_WIDTH = 8,
	parameter KERN_CNT_WIDTH = 3,
	parameter IMG_ADDR_WIDTH = 6,
	parameter RSLT_ADDR_WIDTH = 6
	)
	(
	`ifdef USE_POWER_PINS
	inout vccd1,
	inout vssd1,
	`endif
	// Wishbone Slave ports (WB MI A)
	input wb_clk_i,
	input wb_rst_i,
	input wbs_stb_i,
	input wbs_cyc_i,
	input wbs_we_i,
	input [3:0] wbs_sel_i,
	input [31:0] wbs_dat_i,
	input [31:0] wbs_adr_i,
	output wbs_ack_o,
	output [31:0] wbs_dat_o

	);

	wire we_regs;
	wire we_img_ram;
	wire we_kern_ram;
	wire we_res_ram;
	wire [31:0] data_out_regs;
	wire [7:0] data_out_result;
	wire clk;
	wire reset;
	reg ready;
	reg [31:0] rdata;
	wire start;
	wire [2:0] kern_cols;
	wire [7:0] cols;
	wire [2:0] kerns;
	wire [7:0] stride;
	wire kern_addr_mode;
	wire [7:0] result_cols;
	wire [3:0] shift;
	wire en_max_pool;
	wire [2:0] mask;
	wire done;

	wire [23:0] img_data;
	wire [23:0] kern_data;
	wire [KERN_CNT_WIDTH+KERN_COL_WIDTH-1:0] kern_addr;
	wire [IMG_ADDR_WIDTH-1:0] img_addr;
	wire [RSLT_ADDR_WIDTH-1:0] result_addr;
	wire [7:0] result_data;
	wire result_valid;

	assign clk = wb_clk_i;
	assign reset = wb_rst_i;


	assign valid = wbs_cyc_i & wbs_stb_i;
	// assign wstrb = wbs_sel_i & {(DWIDTH/8){wbs_we_i}};
	assign wbs_dat_o = rdata;
	assign wbs_ack_o = ready;

	assign we_regs = (wbs_adr_i[9:8]==0) & valid & wbs_we_i;
	assign we_img_ram = (wbs_adr_i[9:8]==1) & valid & wbs_we_i;
	assign we_kern_ram = (wbs_adr_i[9:8]==2) & valid & wbs_we_i;
	assign we_res_ram = (wbs_adr_i[9:8]==3) & valid & wbs_we_i;

	always@(posedge clk)
	if(reset) rdata <= 0;
	else if(wbs_adr_i[9:8]==0) rdata <= data_out_regs;
	else if(wbs_adr_i[9:8]==3) rdata <= data_out_result;

	always@(posedge clk)
	if(reset \| ready) ready <= 0;
	else if(valid & ~ready) ready <= 1;

	regs
	#(
	.DWIDTH (32)
	)
	cfg_regs_inst
	(
	.clk (clk ),
	.reset (reset ),
	.addr (wbs_adr_i[3:2] ),
	.wr_en (we_regs ),
	.data_in (wbs_dat_i ),
	.data_out (data_out_regs ),
	.done (done ),
	.start (start ),
	.soft_reset (soft_reset ),
	.kern_cols (kern_cols ),
	.cols (cols ),
	.kerns (kerns ),
	.stride (stride ),
	.kern_addr_mode (kern_addr_mode ),
	.result_cols (result_cols ),
	.shift (shift ),
	.en_max_pool (en_max_pool ),
	.mask (mask ),
	.accum_ovrflow (accum_ovrflow )
	);


	ren_conv
	#(
	.KERN_COL_WIDTH (KERN_COL_WIDTH ),
	.COL_WIDTH (COL_WIDTH ),
	.KERN_CNT_WIDTH (KERN_CNT_WIDTH ),
	.IMG_ADDR_WIDTH (IMG_ADDR_WIDTH ),
	.RSLT_ADDR_WIDTH (RSLT_ADDR_WIDTH)
	)
	ren_conv_inst
	(
	.clk (clk ),
	.reset (reset\|soft_reset),
	.start (start ),
	.done (done ),
	.kern_cols (kern_cols ),
	.cols (cols ),
	.kerns (kerns ),
	.stride (stride[5:0] ),
	.kern_addr_mode (kern_addr_mode ),
	.result_cols (result_cols[5:0]),
	.shift (shift ),
	.en_max_pool (en_max_pool ),
	.mask (mask ),
	.img_data (img_data ),
	.kern_data (kern_data ),
	.kern_addr (kern_addr ),
	.img_addr (img_addr ),
	.result_addr (result_addr ),
	.result_data (result_data ),
	.result_valid (result_valid ),
	.accum_ovrflow (accum_ovrflow )
	);

	dffram
	#(
	.DWIDTH (24),
	.AWIDTH (6 )
	)
	img_dffram
	(
	.clk (clk ),
	.we (we_img_ram ),
	.dat_o ( ),
	.dat_o2 (img_data ),
	.dat_i (wbs_dat_i[23:0]),
	.adr_w (wbs_adr_i[7:2] ),
	.adr_r (img_addr )
	);

	dffram
	#(
	.DWIDTH (24),
	.AWIDTH (6 )
	)
	kerns_dffram
	(
	.clk (clk ),
	.we (we_kern_ram ),
	.dat_o ( ),
	.dat_o2 (kern_data ),
	.dat_i (wbs_dat_i[23:0]),
	.adr_w (wbs_adr_i[7:2] ),
	.adr_r (kern_addr )
	);

	dffram
	#(
	.DWIDTH (8),
	.AWIDTH (6 )
	)
	results_dffram
	(
	.clk (clk ),
	.we (result_valid & ~done ),
	.dat_o ( ),
	.dat_o2 (data_out_result),
	.dat_i (result_data ),
	.adr_w (result_addr ),
	.adr_r (wbs_adr_i[7:2])
	);

	endmodule