// $Id$ // DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed into the Public Domain, for any use, // without warranty, 2003 by Wilson Snyder. module t; reg [2:0] value; reg [31:0] global; initial begin global = 1; value = 2; if (add(value) != 3'd3) $stop; if (global != 2) $stop; if (add(add(3'd1)) != 3'd3) $stop; if (global != 4) $stop; if (munge4(4'b0010) != 4'b1011) $stop; if (global != 5) $stop; setit; incr(global,global,32'h10); if (global != 32'h17) $stop; nop(32'h11); global = 32'h00000001; flipupperbit(global,4'd4); flipupperbit(global,4'd12); if (global !== 32'h10100001) $stop; if (nil_func(32'h12,32'h12) != 32'h24) $stop; nil_task(32'h012,32'h112,global); if (global !== 32'h124) $stop; $write("*-* All Finished *-*\n"); $finish; end function [2:0] add; input [2:0] from; begin add = from + 3'd1; begin : named reg [31:0] flocal; flocal = 1; global = global + flocal; end end endfunction function [3:0] munge4; input [3:0] from; // Different from the 'from' signal above reg one; begin : named reg [1:0] flocal; // Function calling a function one = 1'b1; munge4 = {one, add(from[2:0])}; end endfunction task setit; reg [31:0] temp; begin temp = global + 32'h1; global = temp + 32'h1; end endtask task incr; output [31:0] z; input [31:0] a; input [31:0] inc; z = a + inc; endtask task nop; input [31:0] a; begin end endtask task flipupperbit; inout [31:0] vector; input [3:0] bitnum; reg [4:0] bitnum2; begin bitnum2 = {1'b1, bitnum}; // A little math to test constant propagation vector[bitnum2] = vector[bitnum2] ^ 1'b1; end endtask task nil_task; input [31:0] a; input [31:0] b; output [31:0] q; // verilator no_inline_task q = nil_func(a, b); endtask function [31:0] nil_func; input [31:0] fa; input [31:0] fb; // verilator no_inline_task nil_func = fa + fb; endfunction endmodule