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lifo_tb.sv
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lifo_tb.sv
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//------------------------------------------------------------------------------
// lifo_tb.sv
// Konstantin Pavlov, pavlovconst@gmail.com
//------------------------------------------------------------------------------
// INFO ------------------------------------------------------------------------
// testbench for lifo.sv module
//
`timescale 1ns / 1ps
module lifo_tb();
logic clk200;
initial begin
#0 clk200 = 1'b0;
forever
#2.5 clk200 = ~clk200;
end
// external device "asynchronous" clock
logic clk33;
initial begin
#0 clk33 = 1'b0;
forever
#15.151 clk33 = ~clk33;
end
logic rst;
initial begin
#0 rst = 1'b0;
#10.2 rst = 1'b1;
#5 rst = 1'b0;
//#10000;
forever begin
#9985 rst = ~rst;
#5 rst = ~rst;
end
end
logic nrst;
assign nrst = ~rst;
logic rst_once;
initial begin
#0 rst_once = 1'b0;
#10.2 rst_once = 1'b1;
#5 rst_once = 1'b0;
end
logic nrst_once;
assign nrst_once = ~rst_once;
logic [31:0] DerivedClocks;
clk_divider #(
.WIDTH( 32 )
) cd1 (
.clk( clk200 ),
.nrst( nrst_once ),
.ena( 1'b1 ),
.out( DerivedClocks[31:0] )
);
logic [31:0] E_DerivedClocks;
edge_detect ed1[31:0] (
.clk( {32{clk200}} ),
.nrst( {32{nrst_once}} ),
.in( DerivedClocks[31:0] ),
.rising( E_DerivedClocks[31:0] ),
.falling( ),
.both( )
);
logic [15:0] RandomNumber1;
c_rand rng1 (
.clk(clk200),
.rst(rst_once),
.reseed(1'b0),
.seed_val(DerivedClocks[31:0]),
.out( RandomNumber1[15:0] )
);
logic start;
initial begin
#0 start = 1'b0;
#100 start = 1'b1;
#20 start = 1'b0;
end
// Module under test ==========================================================
// comment or uncomment to test FWFT and normal fifo modes
//`define TEST_FWFT yes
// comment or uncomment to sweep-test or random test
`define TEST_SWEEP yes
logic full1, empty1;
logic full1_d1, empty1_d1;
logic direction1 = 1'b0;
always_ff @(posedge clk200) begin
if( ~nrst ) begin
direction1 <= 1'b0;
end else begin
// sweep logic
if( full1_d1 ) begin
direction1 <= 1'b1;
end else if( empty1_d1 ) begin
direction1 <= 1'b0;
end
// these signals allow "erroring" requests testing:
// - reads from the empty fifo
// - writes to the filled fifo
full1_d1 <= full1;
empty1_d1 <= empty1;
end
end
logic [3:0] cnt1;
logic [15:0] data_out1;
lifo #(
`ifdef TEST_FWFT
.FWFT_MODE( "TRUE" ),
`else
.FWFT_MODE( "FALSE" ),
`endif
.DEPTH( 8 ),
.DATA_W( 16 )
) LF1 (
.clk( clk200 ),
.nrst( nrst_once ),
`ifdef TEST_SWEEP
.w_req( ~direction1 && &RandomNumber1[10] ),
.w_data( RandomNumber1[15:0] ),
.r_req( direction1 && &RandomNumber1[10] ),
.r_data( data_out1[15:0] ),
`else
.w_req( &RandomNumber1[10:9] ),
.w_data( RandomNumber1[15:0] ),
.r_req( &RandomNumber1[8:7] ),
.r_data( data_out1[15:0] ),
`endif
.cnt( cnt1[3:0] ),
.empty( empty1 ),
.full( full1 )
);
endmodule