Fix SystemC 2.2 deprecated warnings about sensitive() and sc_start().
This commit is contained in:
Wilson Snyder
parent
5bdb8674ed
commit
ad19d32a66
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#!/usr/bin/perl
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if (!$::Driver) { use FindBin; exec("$FindBin::Bin/bootstrap.pl", @ARGV, $0); die; }
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# DESCRIPTION: Verilator: Verilog Test driver/expect definition
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#
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# Copyright 2003 by Wilson Snyder. This program is free software; you can
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# redistribute it and/or modify it under the terms of either the GNU
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# General Public License or the Perl Artistic License.
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compile (
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);
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execute (
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check_finished=>1,
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);
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ok(1);
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1;
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// DESCRIPTION: Verilator: Verilog Test module
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//
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// This file ONLY is placed into the Public Domain, for any use,
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// without warranty, 2008 by Lane Brooks.
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//
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// This implements a 4096:1 mux via two stages of 64:1 muxing.
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// change these two parameters to see the speed differences
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//`define DATA_WIDTH 12
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//`define MUX2_SIZE 32
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`define DATA_WIDTH 2
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`define MUX2_SIZE 8
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// if you change these, then the testbench will break
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`define ADDR_WIDTH 12
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`define MUX1_SIZE 64
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// Total of DATA_WIDTH*MUX2_SIZE*(MUX1_SIZE+1) instantiations of mux64
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module t (/*AUTOARG*/
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// Inputs
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clk
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);
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input clk;
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/*AUTOWIRE*/
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// Beginning of automatic wires (for undeclared instantiated-module outputs)
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wire [`DATA_WIDTH-1:0] datao; // From mux4096 of mux4096.v
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// End of automatics
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reg [`DATA_WIDTH*`MUX1_SIZE*`MUX2_SIZE-1:0] datai;
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reg [`ADDR_WIDTH-1:0] addr;
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// Mux: takes in addr and datai and outputs datao
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mux4096 mux4096 (/*AUTOINST*/
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// Outputs
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.datao (datao[`DATA_WIDTH-1:0]),
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// Inputs
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.datai (datai[`DATA_WIDTH*`MUX1_SIZE*`MUX2_SIZE-1:0]),
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.addr (addr[`ADDR_WIDTH-1:0]));
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// calculate what the answer should be from datai. This is bit
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// tricky given the way datai gets sliced. datai is in bit
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// planes where all the LSBs are contiguous and then the next bit.
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reg [`DATA_WIDTH-1:0] datao_check;
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integer j;
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always @(datai or addr) begin
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for(j=0;j<`DATA_WIDTH;j=j+1) begin
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/* verilator lint_off WIDTH */
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datao_check[j] = datai >> ((`MUX1_SIZE*`MUX2_SIZE*j)+addr);
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/* verilator lint_on WIDTH */
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end
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end
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// Run the test loop. This just increments the address
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integer i, result;
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always @ (posedge clk) begin
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// initial the input data with random values
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if (addr == 0) begin
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result = 1;
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datai = 0;
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for(i=0; i<`MUX1_SIZE*`MUX2_SIZE; i=i+1) begin
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/* verilator lint_off WIDTH */
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datai = (datai << `DATA_WIDTH) | ($random & {`DATA_WIDTH{1'b1}});
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/* verilator lint_on WIDTH */
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end
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end
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addr <= addr + 1;
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if (datao_check != datao) begin
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result = 0;
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$stop;
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end
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$write("Addr=%d datao_check=%d datao=%d\n", addr, datao_check, datao);
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// only run the first 10 addresses for now
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if (addr > 10) begin
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$write("*-* All Finished *-*\n");
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$finish;
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end
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end
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endmodule
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module mux4096
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(input [`DATA_WIDTH*`MUX1_SIZE*`MUX2_SIZE-1:0] datai,
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input [`ADDR_WIDTH-1:0] addr,
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output [`DATA_WIDTH-1:0] datao
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);
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// DATA_WIDTH instantiations of mux4096_1bit
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mux4096_1bit mux4096_1bit[`DATA_WIDTH-1:0]
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(.addr(addr),
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.datai(datai),
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.datao(datao)
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);
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endmodule
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module mux4096_1bit
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(input [`MUX1_SIZE*`MUX2_SIZE-1:0] datai,
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input [`ADDR_WIDTH-1:0] addr,
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output datao
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);
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// address decoding
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wire [3:0] A = (4'b1) << addr[1:0];
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wire [3:0] B = (4'b1) << addr[3:2];
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wire [3:0] C = (4'b1) << addr[5:4];
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wire [3:0] D = (4'b1) << addr[7:6];
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wire [3:0] E = (4'b1) << addr[9:8];
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wire [3:0] F = (4'b1) << addr[11:10];
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wire [`MUX2_SIZE-1:0] data0;
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// DATA_WIDTH*(MUX2_SIZE)*MUX1_SIZE instantiations of mux64
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// first stage of 64:1 muxing
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mux64 #(.MUX_SIZE(`MUX1_SIZE)) mux1[`MUX2_SIZE-1:0]
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(.A(A),
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.B(B),
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.C(C),
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.datai(datai),
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.datao(data0));
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// DATA_WIDTH*MUX2_SIZE instantiations of mux64
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// second stage of 64:1 muxing
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mux64 #(.MUX_SIZE(`MUX2_SIZE)) mux2
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(.A(D),
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.B(E),
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.C(F),
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.datai(data0),
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.datao(datao));
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endmodule
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module mux64
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#(parameter MUX_SIZE=64)
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(input [3:0] A,
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input [3:0] B,
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input [3:0] C,
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input [MUX_SIZE-1:0] datai,
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output datao
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);
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wire [63:0] colSelA = { 16{ A[3:0] }};
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wire [63:0] colSelB = { 4{ {4{B[3]}}, {4{B[2]}}, {4{B[1]}}, {4{B[0]}}}};
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wire [63:0] colSelC = { {16{C[3]}}, {16{C[2]}}, {16{C[1]}}, {16{C[0]}}};
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wire [MUX_SIZE-1:0] data_bus;
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// Note each of these becomes a separate wire.
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//.colSelA(colSelA[MUX_SIZE-1:0]),
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//.colSelB(colSelB[MUX_SIZE-1:0]),
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//.colSelC(colSelC[MUX_SIZE-1:0]),
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drv drv[MUX_SIZE-1:0]
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(.colSelA(colSelA[MUX_SIZE-1:0]),
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.colSelB(colSelB[MUX_SIZE-1:0]),
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.colSelC(colSelC[MUX_SIZE-1:0]),
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.datai(datai),
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.datao(data_bus)
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);
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assign datao = |data_bus;
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endmodule
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module drv
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(input colSelA,
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input colSelB,
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input colSelC,
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input datai,
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output datao
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);
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assign datao = colSelC & colSelB & colSelA & datai;
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endmodule
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