SVIncCompil/Testcases/Verilator/t_inst_dff.v - third_party/Surelog - Git at Google

 // DESCRIPTION: Verilator: Verilog Test module
 //
 // This file ONLY is placed into the Public Domain, for any use,
 // without warranty, 2012 by Wilson Snyder.

 module t (/*AUTOARG*/
    // Inputs
    clk
    );
    input clk;

    integer 	cyc=0;
    reg [63:0] 	crc;
    reg [63:0] 	sum;

    // Take CRC data and apply to testblock inputs
    wire [31:0]  in = crc[31:0];

    localparam WIDTH = 31;

    /*AUTOWIRE*/
    // Beginning of automatic wires (for undeclared instantiated-module outputs)
    wire [WIDTH-1:0]	b;			// From test of Test.v
    wire [WIDTH-1:0]	c;			// From test of Test.v
    // End of automatics
    reg 			rst_l;

    Test #(.WIDTH(WIDTH))
    test (/*AUTOINST*/
 	 // Outputs
 	 .b				(b[WIDTH-1:0]),
 	 .c				(c[WIDTH-1:0]),
 	 // Inputs
 	 .clk				(clk),
 	 .rst_l				(rst_l),
 	 .in				(in[WIDTH-1:0]));

    // Aggregate outputs into a single result vector
    wire [63:0] result = {1'h0, c, 1'b0, b};

    // Test loop
    always @ (posedge clk) begin
 `ifdef TEST_VERBOSE
       $write("[%0t] cyc==%0d crc=%x result=%x\n",$time, cyc, crc, result);
 `endif
       cyc <= cyc + 1;
       crc <= {crc[62:0], crc[63]^crc[2]^crc[0]};
       sum <= result ^ {sum[62:0],sum[63]^sum[2]^sum[0]};
       if (cyc==0) begin
 	 // Setup
 	 crc <= 64'h5aef0c8d_d70a4497;
 	 sum <= 64'h0;
 	 rst_l <= ~1'b1;
       end
       else if (cyc<10) begin
 	 sum <= 64'h0;
 	 rst_l <= ~1'b1;
 	 // Hold reset while summing
       end
       else if (cyc<20) begin
 	 rst_l <= ~1'b0;
       end
       else if (cyc<90) begin
       end
       else if (cyc==99) begin
 	 $write("[%0t] cyc==%0d crc=%x sum=%x\n",$time, cyc, crc, sum);
 	 if (crc !== 64'hc77bb9b3784ea091) $stop;
 	 // What checksum will we end up with (above print should match)
 `define EXPECTED_SUM 64'hbcfcebdb75ec9d32
 	 if (sum !== `EXPECTED_SUM) $stop;
 	 $write("*-* All Finished *-*\n");
 	 $finish;
       end
    end

 endmodule

 module Test (/*AUTOARG*/
    // Outputs
    b, c,
    // Inputs
    clk, rst_l, in
    );

    parameter    WIDTH = 5;

    input                 clk;
    input 		 rst_l;

    input [WIDTH-1:0] 	 in;
    output wire [WIDTH-1:0] 	b;
    output wire [WIDTH-1:0] 	c;

    dff # ( .WIDTH	(WIDTH),
 	   .RESET	('0),   // Although this is a single bit, the parameter must be the specified type
 	   .RESET_WIDTH (1) )
    sub1
      ( .clk(clk), .rst_l(rst_l), .q(b), .d(in) );

    dff # ( .WIDTH	(WIDTH),
 	   .RESET	({ 1'b1, {(WIDTH-1){1'b0}} }),
 	   .RESET_WIDTH (WIDTH))
    sub2
      ( .clk(clk), .rst_l(rst_l), .q(c), .d(in) );

 endmodule

 module dff (/*AUTOARG*/
    // Outputs
    q,
    // Inputs
    clk, rst_l, d
    );

    parameter WIDTH = 1;
    parameter RESET = {WIDTH{1'b0}};
    parameter RESET_WIDTH = WIDTH;

    input   clk;
    input   rst_l;
    input [WIDTH-1:0] d;
    output reg [WIDTH-1:0] q;

    always_ff @(posedge clk or negedge rst_l) begin
       if ($bits(RESET) != RESET_WIDTH) $stop;
       // verilator lint_off WIDTH
       if (~rst_l) q <= RESET;
       // verilator lint_on WIDTH
       else q <= d;
    end
 endmodule
	// DESCRIPTION: Verilator: Verilog Test module
	//
	// This file ONLY is placed into the Public Domain, for any use,
	// without warranty, 2012 by Wilson Snyder.

	module t (/AUTOARG/
	// Inputs
	clk
	);
	input clk;

	integer cyc=0;
	reg [63:0] crc;
	reg [63:0] sum;

	// Take CRC data and apply to testblock inputs
	wire [31:0] in = crc[31:0];

	localparam WIDTH = 31;

	/AUTOWIRE/
	// Beginning of automatic wires (for undeclared instantiated-module outputs)
	wire [WIDTH-1:0] b; // From test of Test.v
	wire [WIDTH-1:0] c; // From test of Test.v
	// End of automatics
	reg rst_l;

	Test #(.WIDTH(WIDTH))
	test (/AUTOINST/
	// Outputs
	.b (b[WIDTH-1:0]),
	.c (c[WIDTH-1:0]),
	// Inputs
	.clk (clk),
	.rst_l (rst_l),
	.in (in[WIDTH-1:0]));

	// Aggregate outputs into a single result vector
	wire [63:0] result = {1'h0, c, 1'b0, b};

	// Test loop
	always @ (posedge clk) begin
	`ifdef TEST_VERBOSE
	$write("[%0t] cyc==%0d crc=%x result=%x\n",$time, cyc, crc, result);
	`endif
	cyc <= cyc + 1;
	crc <= {crc[62:0], crc[63]^crc[2]^crc[0]};
	sum <= result ^ {sum[62:0],sum[63]^sum[2]^sum[0]};
	if (cyc==0) begin
	// Setup
	crc <= 64'h5aef0c8d_d70a4497;
	sum <= 64'h0;
	rst_l <= ~1'b1;
	end
	else if (cyc<10) begin
	sum <= 64'h0;
	rst_l <= ~1'b1;
	// Hold reset while summing
	end
	else if (cyc<20) begin
	rst_l <= ~1'b0;
	end
	else if (cyc<90) begin
	end
	else if (cyc==99) begin
	$write("[%0t] cyc==%0d crc=%x sum=%x\n",$time, cyc, crc, sum);
	if (crc !== 64'hc77bb9b3784ea091) $stop;
	// What checksum will we end up with (above print should match)
	`define EXPECTED_SUM 64'hbcfcebdb75ec9d32
	if (sum !== `EXPECTED_SUM) $stop;
	$write("- All Finished -\n");
	$finish;
	end
	end

	endmodule

	module Test (/AUTOARG/
	// Outputs
	b, c,
	// Inputs
	clk, rst_l, in
	);

	parameter WIDTH = 5;

	input clk;
	input rst_l;

	input [WIDTH-1:0] in;
	output wire [WIDTH-1:0] b;
	output wire [WIDTH-1:0] c;

	dff # ( .WIDTH (WIDTH),
	.RESET ('0), // Although this is a single bit, the parameter must be the specified type
	.RESET_WIDTH (1) )
	sub1
	( .clk(clk), .rst_l(rst_l), .q(b), .d(in) );

	dff # ( .WIDTH (WIDTH),
	.RESET ({ 1'b1, {(WIDTH-1){1'b0}} }),
	.RESET_WIDTH (WIDTH))
	sub2
	( .clk(clk), .rst_l(rst_l), .q(c), .d(in) );

	endmodule

	module dff (/AUTOARG/
	// Outputs
	q,
	// Inputs
	clk, rst_l, d
	);

	parameter WIDTH = 1;
	parameter RESET = {WIDTH{1'b0}};
	parameter RESET_WIDTH = WIDTH;

	input clk;
	input rst_l;
	input [WIDTH-1:0] d;
	output reg [WIDTH-1:0] q;

	always_ff @(posedge clk or negedge rst_l) begin
	if ($bits(RESET) != RESET_WIDTH) $stop;
	// verilator lint_off WIDTH
	if (~rst_l) q <= RESET;
	// verilator lint_on WIDTH
	else q <= d;
	end
	endmodule