verilog/rtl/jacaranda-8/computer.v - third_party/shuttle/sky130/mpw-003/slot-028 - Git at Google

 `default_nettype none

 // module computer(
 //     input clock,
 //     input rx,
 //     output tx,
 //     output [3:0] led_out_data,
 //     output [6:0] seg_out_1,
 //     output [6:0] seg_out_2,
 //     output [6:0] seg_out_3
 // );


 module computer(
 `ifdef USE_POWER_PINS
     inout vdda1,	// User area 1 3.3V supply
     inout vdda2,	// User area 2 3.3V supply
     inout vssa1,	// User area 1 analog ground
     inout vssa2,	// User area 2 analog ground
     inout vccd1,	// User area 1 1.8V supply
     inout vccd2,	// User area 2 1.8v supply
     inout vssd1,	// User area 1 digital ground
     inout vssd2,	// User area 2 digital ground
 `endif
     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_adr_i,
     input [31:0] wbs_dat_i,
     output wbs_ack_o,
     output [31:0] wbs_dat_o,

     input  [127:0] la_data_in,
     output [127:0] la_data_out,
     input  [127:0] la_oenb,

     input  [`MPRJ_IO_PADS-1:0] io_in,
     output [`MPRJ_IO_PADS-1:0] io_out,
     output [`MPRJ_IO_PADS-1:0] io_oeb,

     output [2:0] irq
 );

 /** temporary **/
     wire rx;
     wire tx;
     wire [3:0] led_out_data;
     wire [6:0] seg_out_1;
     wire [6:0] seg_out_2;
     wire [6:0] seg_out_3;
 /** **/
     // output enable
     assign io_oeb[37:36] = 2'b11;
     // UART - GPIO
     assign io_out[37] = tx;
     assign io_out[36] = rx;

     wire [7:0] instr;
     wire [7:0] pc;
     wire [7:0] rd_data;
     wire [7:0] rs_data;
     wire mem_w_en;
     wire [7:0] mem_r_data;
     wire [7:0] _mem_r_data;
     wire busy_flag;
     wire receive_flag;
     reg tx_en;
     reg rx_en;
     reg begin_flag;
     reg [7:0] tx_data;
     wire [7:0] rx_data;

     reg [7:0] int_vec;
     reg [7:0] int_en;

     wire int_req;

     wire reg_w_en;

     reg [7:0] led_in_data;
     reg led_begin_flag;
     wire [7:0] led_state_reg;

     reg [7:0] nanaseg_in_data;

     wire [7:0] instr_mem_addr;
     wire [7:0] instr_mem_data;

     wire reset;

     assign reset = la_data_in[16];
     assign instr_mem_addr = reset ? la_data_in[15:8] : pc;
     assign instr_mem_data = la_data_in[7:0];


     instr_mem instr_mem(.addr(instr_mem_addr),
                         .w_data(instr_mem_data),
                         .w_en(reset),
                         .r_data(instr),
                         .clock(wb_clk_i),
                         .reset(reset));

     cpu cpu(.raw_clock(wb_clk_i),
             .reset(reset),
             .instr(instr),
             .pc(pc),
             .rd_data(rd_data),
             .rs_data(rs_data),
             .mem_w_en(mem_w_en),
             .mem_r_data(mem_r_data),
             .int_req(int_req),
             .int_en(int_en),
             .int_vec(int_vec),
             .reg_w_en(reg_w_en));

     always @(posedge wb_clk_i) begin
         if(rs_data == 8'd255 && mem_w_en == 1) begin
             tx_en <= rd_data[0];
             rx_en <= rd_data[1];
         end
     end

     always @(posedge wb_clk_i) begin
         if(rs_data == 8'd253 && mem_w_en == 1) begin
             tx_data <= rd_data;
             begin_flag = 1;
         end else begin
             tx_data <= tx_data;
             begin_flag = 0;
         end
     end

     data_mem data_mem(.addr(rs_data),
                       .w_data(rd_data),
                       .w_en(mem_w_en),
                       .r_data(_mem_r_data),
                       .clock(wb_clk_i));

     assign mem_r_data = (rs_data == 8'd254) ? {6'b0, receive_flag, busy_flag}
                       : (rs_data == 8'd252) ? rx_data
                       : (rs_data == 8'd250) ? int_vec
                       : (rs_data == 8'd249) ? led_state_reg
                       : _mem_r_data;

     always @(posedge wb_clk_i) begin
         if(rs_data == 8'd251 && mem_w_en == 1) begin
             led_in_data <= rd_data;
             led_begin_flag <= 1'b1;
         end else begin
             led_in_data <= led_in_data;
             led_begin_flag <= 1'b0;
         end
     end

     always @(posedge wb_clk_i) begin
         if(rs_data == 8'd248 && mem_w_en == 1) begin
             nanaseg_in_data <= rd_data;
         end else begin
             nanaseg_in_data <= nanaseg_in_data;
         end
     end


     //割り込み要求が立っている時は割り込み不許可
     always @(posedge wb_clk_i) begin
         if(int_req == 1'b1) begin
             int_en <= 8'h00;
         end else if(int_req == 1'b0) begin
             int_en <= 8'h01;
         end
     end

     always @(posedge wb_clk_i) begin
         //割り込みベクタの書き込み
         if(rs_data == 8'd250 && mem_w_en == 1'b1) begin
             int_vec <= rd_data;
         end else begin
             int_vec <= int_vec;
         end
     end

     UART UART(.clk(wb_clk_i),
               .reset(reset),
               .tx_en(tx_en),
               .rx_en(rx_en),
               .begin_flag(begin_flag),
               .rx(rx),
               .tx_data(tx_data),
               .tx(tx),
               .rx_data(rx_data),
               .busy_flag(busy_flag),
               .receive_flag(receive_flag),
               .int_req(int_req),
               .access_addr(rs_data),
               .reg_w_en(reg_w_en));
 //
 //    LED4 LED4(.in_data(led_in_data),
 //              .begin_flag(led_begin_flag),
 //              .state_reg(led_state_reg),
 //              .out_data(led_out_data),
 //              .clock(wb_clk_i));
 //
 //    nanaseg nanaseg(.bin_in(nanaseg_in_data),
 //                    .seg_dig1(seg_out_1),
 //                    .seg_dig2(seg_out_2),
 //                    .seg_dig3(seg_out_3));

 endmodule
	`default_nettype none

	// module computer(
	// input clock,
	// input rx,
	// output tx,
	// output [3:0] led_out_data,
	// output [6:0] seg_out_1,
	// output [6:0] seg_out_2,
	// output [6:0] seg_out_3
	// );


	module computer(
	`ifdef USE_POWER_PINS
	inout vdda1, // User area 1 3.3V supply
	inout vdda2, // User area 2 3.3V supply
	inout vssa1, // User area 1 analog ground
	inout vssa2, // User area 2 analog ground
	inout vccd1, // User area 1 1.8V supply
	inout vccd2, // User area 2 1.8v supply
	inout vssd1, // User area 1 digital ground
	inout vssd2, // User area 2 digital ground
	`endif
	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_adr_i,
	input [31:0] wbs_dat_i,
	output wbs_ack_o,
	output [31:0] wbs_dat_o,

	input [127:0] la_data_in,
	output [127:0] la_data_out,
	input [127:0] la_oenb,

	input [`MPRJ_IO_PADS-1:0] io_in,
	output [`MPRJ_IO_PADS-1:0] io_out,
	output [`MPRJ_IO_PADS-1:0] io_oeb,

	output [2:0] irq
	);

	/ temporary /
	wire rx;
	wire tx;
	wire [3:0] led_out_data;
	wire [6:0] seg_out_1;
	wire [6:0] seg_out_2;
	wire [6:0] seg_out_3;
	/ /
	// output enable
	assign io_oeb[37:36] = 2'b11;
	// UART - GPIO
	assign io_out[37] = tx;
	assign io_out[36] = rx;

	wire [7:0] instr;
	wire [7:0] pc;
	wire [7:0] rd_data;
	wire [7:0] rs_data;
	wire mem_w_en;
	wire [7:0] mem_r_data;
	wire [7:0] _mem_r_data;
	wire busy_flag;
	wire receive_flag;
	reg tx_en;
	reg rx_en;
	reg begin_flag;
	reg [7:0] tx_data;
	wire [7:0] rx_data;

	reg [7:0] int_vec;
	reg [7:0] int_en;

	wire int_req;

	wire reg_w_en;

	reg [7:0] led_in_data;
	reg led_begin_flag;
	wire [7:0] led_state_reg;

	reg [7:0] nanaseg_in_data;

	wire [7:0] instr_mem_addr;
	wire [7:0] instr_mem_data;

	wire reset;

	assign reset = la_data_in[16];
	assign instr_mem_addr = reset ? la_data_in[15:8] : pc;
	assign instr_mem_data = la_data_in[7:0];


	instr_mem instr_mem(.addr(instr_mem_addr),
	.w_data(instr_mem_data),
	.w_en(reset),
	.r_data(instr),
	.clock(wb_clk_i),
	.reset(reset));

	cpu cpu(.raw_clock(wb_clk_i),
	.reset(reset),
	.instr(instr),
	.pc(pc),
	.rd_data(rd_data),
	.rs_data(rs_data),
	.mem_w_en(mem_w_en),
	.mem_r_data(mem_r_data),
	.int_req(int_req),
	.int_en(int_en),
	.int_vec(int_vec),
	.reg_w_en(reg_w_en));

	always @(posedge wb_clk_i) begin
	if(rs_data == 8'd255 && mem_w_en == 1) begin
	tx_en <= rd_data[0];
	rx_en <= rd_data[1];
	end
	end

	always @(posedge wb_clk_i) begin
	if(rs_data == 8'd253 && mem_w_en == 1) begin
	tx_data <= rd_data;
	begin_flag = 1;
	end else begin
	tx_data <= tx_data;
	begin_flag = 0;
	end
	end

	data_mem data_mem(.addr(rs_data),
	.w_data(rd_data),
	.w_en(mem_w_en),
	.r_data(_mem_r_data),
	.clock(wb_clk_i));

	assign mem_r_data = (rs_data == 8'd254) ? {6'b0, receive_flag, busy_flag}
	: (rs_data == 8'd252) ? rx_data
	: (rs_data == 8'd250) ? int_vec
	: (rs_data == 8'd249) ? led_state_reg
	: _mem_r_data;

	always @(posedge wb_clk_i) begin
	if(rs_data == 8'd251 && mem_w_en == 1) begin
	led_in_data <= rd_data;
	led_begin_flag <= 1'b1;
	end else begin
	led_in_data <= led_in_data;
	led_begin_flag <= 1'b0;
	end
	end

	always @(posedge wb_clk_i) begin
	if(rs_data == 8'd248 && mem_w_en == 1) begin
	nanaseg_in_data <= rd_data;
	end else begin
	nanaseg_in_data <= nanaseg_in_data;
	end
	end


	//割り込み要求が立っている時は割り込み不許可
	always @(posedge wb_clk_i) begin
	if(int_req == 1'b1) begin
	int_en <= 8'h00;
	end else if(int_req == 1'b0) begin
	int_en <= 8'h01;
	end
	end

	always @(posedge wb_clk_i) begin
	//割り込みベクタの書き込み
	if(rs_data == 8'd250 && mem_w_en == 1'b1) begin
	int_vec <= rd_data;
	end else begin
	int_vec <= int_vec;
	end
	end

	UART UART(.clk(wb_clk_i),
	.reset(reset),
	.tx_en(tx_en),
	.rx_en(rx_en),
	.begin_flag(begin_flag),
	.rx(rx),
	.tx_data(tx_data),
	.tx(tx),
	.rx_data(rx_data),
	.busy_flag(busy_flag),
	.receive_flag(receive_flag),
	.int_req(int_req),
	.access_addr(rs_data),
	.reg_w_en(reg_w_en));
	//
	// LED4 LED4(.in_data(led_in_data),
	// .begin_flag(led_begin_flag),
	// .state_reg(led_state_reg),
	// .out_data(led_out_data),
	// .clock(wb_clk_i));
	//
	// nanaseg nanaseg(.bin_in(nanaseg_in_data),
	// .seg_dig1(seg_out_1),
	// .seg_dig2(seg_out_2),
	// .seg_dig3(seg_out_3));

	endmodule