verilog/rtl/counter_timer.v - third_party/shuttle/sky130/mpw-001/slot-033 - Git at Google

 /* Simple 32-bit counter-timer for Caravel. */

 module counter_timer_wb # (
     parameter BASE_ADR = 32'h2400_0000,
     parameter CONFIG = 8'h00,
     parameter VALUE  = 8'h04,
     parameter DATA   = 8'h08
 ) (
     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,
     output irq
 );
     wire [31:0] counter_timer_reg_cfg_do;
     wire [31:0] counter_timer_reg_val_do;
     wire [31:0] counter_timer_reg_dat_do;

     wire resetn = ~wb_rst_i;
     wire valid = wb_stb_i && wb_cyc_i;
     wire counter_timer_reg_cfg_sel = valid && (wb_adr_i == (BASE_ADR | CONFIG));
     wire counter_timer_reg_val_sel = valid && (wb_adr_i == (BASE_ADR | VALUE));
     wire counter_timer_reg_dat_sel = valid && (wb_adr_i == (BASE_ADR | DATA));

     wire reg_cfg_we = (counter_timer_reg_cfg_sel) ?
 		(wb_sel_i[0] & {wb_we_i}): 1'b0;
     wire [3:0] reg_val_we = (counter_timer_reg_val_sel) ?
 		(wb_sel_i & {4{wb_we_i}}): 4'b0000;
     wire [3:0] reg_dat_we = (counter_timer_reg_dat_sel) ?
 		(wb_sel_i & {4{wb_we_i}}): 4'b0000;

     wire [31:0] mem_wdata = wb_dat_i;
     wire reg_dat_re = counter_timer_reg_dat_sel && !wb_sel_i && ~wb_we_i;

     assign wb_dat_o = (counter_timer_reg_cfg_sel) ? counter_timer_reg_cfg_do :
 		      (counter_timer_reg_val_sel) ? counter_timer_reg_val_do :
 		      counter_timer_reg_dat_do;
     assign wb_ack_o = counter_timer_reg_cfg_sel || counter_timer_reg_val_sel ||
 			counter_timer_reg_dat_sel;

     counter_timer counter_timer_inst (
         .resetn(resetn),
         .clkin(wb_clk_i),
         .reg_val_we(reg_val_we),
         .reg_val_di(mem_wdata),
         .reg_val_do(counter_timer_reg_val_do),
         .reg_cfg_we(reg_cfg_we),
         .reg_cfg_di(mem_wdata),
         .reg_cfg_do(counter_timer_reg_cfg_do),
         .reg_dat_we(reg_dat_we),
         .reg_dat_di(mem_wdata),
         .reg_dat_do(counter_timer_reg_dat_do),
 	.irq_out(irq)
    );

 endmodule

 module counter_timer (
     input resetn,
     input clkin,

     input  [3:0]  reg_val_we,
     input  [31:0] reg_val_di,
     output [31:0] reg_val_do,

     input 	  reg_cfg_we,
     input  [31:0] reg_cfg_di,
     output [31:0] reg_cfg_do,

     input  [3:0]  reg_dat_we,
     input  [31:0] reg_dat_di,
     output [31:0] reg_dat_do,
     output	  irq_out
 );

 reg [31:0] value_cur;
 reg [31:0] value_reset;
 reg	   irq_out;

 reg enable;	// Enable (start) the counter/timer
 reg lastenable;	// Previous state of enable (catch rising/falling edge)
 reg oneshot;	// Set oneshot (1) mode or continuous (0) mode
 reg updown;	// Count up (1) or down (0)
 reg irq_ena;	// Enable interrupt on timeout

 // Configuration register

 assign reg_cfg_do = {28'd0, irq_ena, updown, oneshot, enable};

 always @(posedge clkin or negedge resetn) begin
     if (resetn == 1'b0) begin
 	enable <= 1'b0;
 	lastenable <= 1'b0;
 	oneshot <= 1'b0;
 	updown <= 1'b0;
 	irq_ena <= 1'b0;
     end else begin
 	lastenable <= enable;
 	if (reg_cfg_we) begin
 	    enable <= reg_cfg_di[0];
 	    oneshot <= reg_cfg_di[1];
 	    updown <= reg_cfg_di[2];
 	    irq_ena <= reg_cfg_di[3];
 	end
     end
 end

 // Counter/timer reset value register

 assign reg_val_do = value_reset;

 always @(posedge clkin or negedge resetn) begin
     if (resetn == 1'b0) begin
 	value_reset <= 32'd0;
     end else begin
 	if (reg_val_we[3]) value_reset[31:24] <= reg_val_di[31:24];
 	if (reg_val_we[2]) value_reset[23:16] <= reg_val_di[23:16];
 	if (reg_val_we[1]) value_reset[15:8] <= reg_val_di[15:8];
 	if (reg_val_we[0]) value_reset[7:0] <= reg_val_di[7:0];
     end
 end

 assign reg_dat_do = value_cur;

 // Counter/timer current value register and timer implementation

 always @(posedge clkin or negedge resetn) begin
     if (resetn == 1'b0) begin
 	value_cur <= 32'd0;
 	irq_out <= 1'b0;
     end else begin
 	if (reg_dat_we != 4'b0000) begin
 	    if (reg_dat_we[3] == 1'b1) value_cur[31:24] <= reg_dat_di[31:24];
 	    if (reg_dat_we[2] == 1'b1) value_cur[23:16] <= reg_dat_di[23:16];
 	    if (reg_dat_we[1] == 1'b1) value_cur[15:8] <= reg_dat_di[15:8];
 	    if (reg_dat_we[0] == 1'b1) value_cur[7:0] <= reg_dat_di[7:0];
 	end else if (enable == 1'b1) begin
 	    if (updown == 1'b1) begin
 		if (lastenable == 1'b0) begin
 		    value_cur <= 32'd0;
 		end else if (value_cur == value_reset) begin
 		    if (oneshot != 1'b1) begin
 			value_cur <= 32'd0;
 		    end
 		    irq_out <= irq_ena;
 		end else begin
 		    value_cur <= value_cur + 1;	// count up
 		    irq_out <= 1'b0;
 		end
 	    end else begin
 		if (lastenable == 1'b0) begin
 		    value_cur <= value_reset;
 		end else if (value_cur == 32'd0) begin
 		    if (oneshot != 1'b1) begin
 			value_cur <= value_reset;
 		    end
 		    irq_out <= irq_ena;
 		end else begin
 		    value_cur <= value_cur - 1;	// count down
 		    irq_out <= 1'b0;
 		end
 	    end
 	end else begin
 	    irq_out <= 1'b0;
 	end
     end
 end

 endmodule
	/* Simple 32-bit counter-timer for Caravel. */

	module counter_timer_wb # (
	parameter BASE_ADR = 32'h2400_0000,
	parameter CONFIG = 8'h00,
	parameter VALUE = 8'h04,
	parameter DATA = 8'h08
	) (
	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,
	output irq
	);
	wire [31:0] counter_timer_reg_cfg_do;
	wire [31:0] counter_timer_reg_val_do;
	wire [31:0] counter_timer_reg_dat_do;

	wire resetn = ~wb_rst_i;
	wire valid = wb_stb_i && wb_cyc_i;
	wire counter_timer_reg_cfg_sel = valid && (wb_adr_i == (BASE_ADR \| CONFIG));
	wire counter_timer_reg_val_sel = valid && (wb_adr_i == (BASE_ADR \| VALUE));
	wire counter_timer_reg_dat_sel = valid && (wb_adr_i == (BASE_ADR \| DATA));

	wire reg_cfg_we = (counter_timer_reg_cfg_sel) ?
	(wb_sel_i[0] & {wb_we_i}): 1'b0;
	wire [3:0] reg_val_we = (counter_timer_reg_val_sel) ?
	(wb_sel_i & {4{wb_we_i}}): 4'b0000;
	wire [3:0] reg_dat_we = (counter_timer_reg_dat_sel) ?
	(wb_sel_i & {4{wb_we_i}}): 4'b0000;

	wire [31:0] mem_wdata = wb_dat_i;
	wire reg_dat_re = counter_timer_reg_dat_sel && !wb_sel_i && ~wb_we_i;

	assign wb_dat_o = (counter_timer_reg_cfg_sel) ? counter_timer_reg_cfg_do :
	(counter_timer_reg_val_sel) ? counter_timer_reg_val_do :
	counter_timer_reg_dat_do;
	assign wb_ack_o = counter_timer_reg_cfg_sel \|\| counter_timer_reg_val_sel \|\|
	counter_timer_reg_dat_sel;

	counter_timer counter_timer_inst (
	.resetn(resetn),
	.clkin(wb_clk_i),
	.reg_val_we(reg_val_we),
	.reg_val_di(mem_wdata),
	.reg_val_do(counter_timer_reg_val_do),
	.reg_cfg_we(reg_cfg_we),
	.reg_cfg_di(mem_wdata),
	.reg_cfg_do(counter_timer_reg_cfg_do),
	.reg_dat_we(reg_dat_we),
	.reg_dat_di(mem_wdata),
	.reg_dat_do(counter_timer_reg_dat_do),
	.irq_out(irq)
	);

	endmodule

	module counter_timer (
	input resetn,
	input clkin,

	input [3:0] reg_val_we,
	input [31:0] reg_val_di,
	output [31:0] reg_val_do,

	input reg_cfg_we,
	input [31:0] reg_cfg_di,
	output [31:0] reg_cfg_do,

	input [3:0] reg_dat_we,
	input [31:0] reg_dat_di,
	output [31:0] reg_dat_do,
	output irq_out
	);

	reg [31:0] value_cur;
	reg [31:0] value_reset;
	reg irq_out;

	reg enable; // Enable (start) the counter/timer
	reg lastenable; // Previous state of enable (catch rising/falling edge)
	reg oneshot; // Set oneshot (1) mode or continuous (0) mode
	reg updown; // Count up (1) or down (0)
	reg irq_ena; // Enable interrupt on timeout

	// Configuration register

	assign reg_cfg_do = {28'd0, irq_ena, updown, oneshot, enable};

	always @(posedge clkin or negedge resetn) begin
	if (resetn == 1'b0) begin
	enable <= 1'b0;
	lastenable <= 1'b0;
	oneshot <= 1'b0;
	updown <= 1'b0;
	irq_ena <= 1'b0;
	end else begin
	lastenable <= enable;
	if (reg_cfg_we) begin
	enable <= reg_cfg_di[0];
	oneshot <= reg_cfg_di[1];
	updown <= reg_cfg_di[2];
	irq_ena <= reg_cfg_di[3];
	end
	end
	end

	// Counter/timer reset value register

	assign reg_val_do = value_reset;

	always @(posedge clkin or negedge resetn) begin
	if (resetn == 1'b0) begin
	value_reset <= 32'd0;
	end else begin
	if (reg_val_we[3]) value_reset[31:24] <= reg_val_di[31:24];
	if (reg_val_we[2]) value_reset[23:16] <= reg_val_di[23:16];
	if (reg_val_we[1]) value_reset[15:8] <= reg_val_di[15:8];
	if (reg_val_we[0]) value_reset[7:0] <= reg_val_di[7:0];
	end
	end

	assign reg_dat_do = value_cur;

	// Counter/timer current value register and timer implementation

	always @(posedge clkin or negedge resetn) begin
	if (resetn == 1'b0) begin
	value_cur <= 32'd0;
	irq_out <= 1'b0;
	end else begin
	if (reg_dat_we != 4'b0000) begin
	if (reg_dat_we[3] == 1'b1) value_cur[31:24] <= reg_dat_di[31:24];
	if (reg_dat_we[2] == 1'b1) value_cur[23:16] <= reg_dat_di[23:16];
	if (reg_dat_we[1] == 1'b1) value_cur[15:8] <= reg_dat_di[15:8];
	if (reg_dat_we[0] == 1'b1) value_cur[7:0] <= reg_dat_di[7:0];
	end else if (enable == 1'b1) begin
	if (updown == 1'b1) begin
	if (lastenable == 1'b0) begin
	value_cur <= 32'd0;
	end else if (value_cur == value_reset) begin
	if (oneshot != 1'b1) begin
	value_cur <= 32'd0;
	end
	irq_out <= irq_ena;
	end else begin
	value_cur <= value_cur + 1; // count up
	irq_out <= 1'b0;
	end
	end else begin
	if (lastenable == 1'b0) begin
	value_cur <= value_reset;
	end else if (value_cur == 32'd0) begin
	if (oneshot != 1'b1) begin
	value_cur <= value_reset;
	end
	irq_out <= irq_ena;
	end else begin
	value_cur <= value_cur - 1; // count down
	irq_out <= 1'b0;
	end
	end
	end else begin
	irq_out <= 1'b0;
	end
	end
	end

	endmodule