verilog/rtl/mem_synth_wb.v - third_party/shuttle/sky130/mpw-001/slot-016 - Git at Google

 module mem_synth_wb #(
    parameter integer MEM_WORDS = 1024
 )(
     input wb_clk_i,
     input wb_rst_i,

     input [31:0] wb_adr_i,
     input [31:0] wb_dat_i,
     input [3:0] wb_sel_i,
     input wb_we_i,
     input wb_cyc_i,
     input wb_stb_i,

     output wb_ack_o,
     output [31:0] wb_dat_o
 );

     wire valid;
     wire ram_wen;
     wire [3:0] wen; // write enable

     assign valid = wb_cyc_i & wb_stb_i;
     assign ram_wen = wb_we_i && valid;

     assign wen = wb_sel_i & {4{ram_wen}} ;

     reg wb_ack_read;
     reg wb_ack_o;

     always @(posedge wb_clk_i) begin
         if (wb_rst_i == 1'b 1) begin
             wb_ack_read <= 1'b0;
             wb_ack_o <= 1'b0;
         end else begin
             wb_ack_o    <= wb_we_i? (valid & !wb_ack_o): wb_ack_read;
             wb_ack_read <= (valid & !wb_ack_o) & !wb_ack_read;
         end
     end

     soc_mem_synth # (
         .MEM_WORDS(MEM_WORDS)
     ) mem (
         .clk(wb_clk_i),
         .ena(valid),
         .wen(wen),
         .addr(wb_adr_i[12:2]),
         .wdata(wb_dat_i),
         .rdata(wb_dat_o)
     );

 endmodule

 module soc_mem_synth #(
     parameter integer MEM_WORDS = 2048
 )(
     input clk,
     input ena,
     input [3:0] wen,
     input [10:0] addr,
     input [31:0] wdata,
     output[31:0] rdata
 );

     reg [31:0] rdata;
     reg [31:0] mem [0:MEM_WORDS-1];

     always @(posedge clk) begin
         if (ena == 1'b1) begin
             rdata <= mem[addr];
             if (wen[0]) mem[addr][ 7: 0] <= wdata[ 7: 0];
             if (wen[1]) mem[addr][15: 8] <= wdata[15: 8];
             if (wen[2]) mem[addr][23:16] <= wdata[23:16];
             if (wen[3]) mem[addr][31:24] <= wdata[31:24];
         end
     end

 endmodule
	module mem_synth_wb #(
	parameter integer MEM_WORDS = 1024
	)(
	input wb_clk_i,
	input wb_rst_i,

	input [31:0] wb_adr_i,
	input [31:0] wb_dat_i,
	input [3:0] wb_sel_i,
	input wb_we_i,
	input wb_cyc_i,
	input wb_stb_i,

	output wb_ack_o,
	output [31:0] wb_dat_o
	);

	wire valid;
	wire ram_wen;
	wire [3:0] wen; // write enable

	assign valid = wb_cyc_i & wb_stb_i;
	assign ram_wen = wb_we_i && valid;

	assign wen = wb_sel_i & {4{ram_wen}} ;

	reg wb_ack_read;
	reg wb_ack_o;

	always @(posedge wb_clk_i) begin
	if (wb_rst_i == 1'b 1) begin
	wb_ack_read <= 1'b0;
	wb_ack_o <= 1'b0;
	end else begin
	wb_ack_o <= wb_we_i? (valid & !wb_ack_o): wb_ack_read;
	wb_ack_read <= (valid & !wb_ack_o) & !wb_ack_read;
	end
	end

	soc_mem_synth # (
	.MEM_WORDS(MEM_WORDS)
	) mem (
	.clk(wb_clk_i),
	.ena(valid),
	.wen(wen),
	.addr(wb_adr_i[12:2]),
	.wdata(wb_dat_i),
	.rdata(wb_dat_o)
	);

	endmodule

	module soc_mem_synth #(
	parameter integer MEM_WORDS = 2048
	)(
	input clk,
	input ena,
	input [3:0] wen,
	input [10:0] addr,
	input [31:0] wdata,
	output[31:0] rdata
	);

	reg [31:0] rdata;
	reg [31:0] mem [0:MEM_WORDS-1];

	always @(posedge clk) begin
	if (ena == 1'b1) begin
	rdata <= mem[addr];
	if (wen[0]) mem[addr][ 7: 0] <= wdata[ 7: 0];
	if (wen[1]) mem[addr][15: 8] <= wdata[15: 8];
	if (wen[2]) mem[addr][23:16] <= wdata[23:16];
	if (wen[3]) mem[addr][31:24] <= wdata[31:24];
	end
	end

	endmodule