//-------------------------------------------------------------------------------- // SimWrapper.v // Konstantin Pavlov, pavlovconst@gmail.com //-------------------------------------------------------------------------------- // INFO -------------------------------------------------------------------------------- // CAUTION ! THIS CODE IS OBSOLETE NOW. PLEASE USE "uart_tx.sv", "uart_rx.sv" BLOCKS AND THEIR TESTBENCHES INSTEAD `timescale 1ns / 1ps module SimWrapper(); reg clk200; initial begin #0 clk200 = 1; forever #2.5 clk200 = ~clk200; end reg rst; initial begin #10.2 rst = 1; #5 rst = 0; //#10000; forever begin #9985 rst = ~rst; #5 rst = ~rst; end end wire nrst = ~rst; reg rst_once; initial begin // initializing non-X data before PLL starts #10.2 rst_once = 1; #5 rst_once = 0; end initial begin #510.2 rst_once = 1; // PLL starts at 500ns, clock appears, so doing the reset for modules #5 rst_once = 0; end wire nrst_once = ~rst_once; wire [31:0] DerivedClocks; ClkDivider CD1 ( .clk(clk200), .nrst(nrst_once), .out(DerivedClocks[31:0])); defparam CD1.WIDTH = 32; wire [31:0] E_DerivedClocks; EdgeDetect ED1 ( .clk(clk200), .nrst(nrst_once), .in(DerivedClocks[31:0]), .rising(E_DerivedClocks[31:0]), .falling(), .both() ); defparam ED1.WIDTH = 32; wire [15:0] RandomNumber1; c_rand RNG1 ( .clk(clk200), .rst(rst_once), .reseed(1'b0), .seed_val(DerivedClocks[31:0]), .out(RandomNumber1[15:0])); reg start; initial begin #100.2 start = 1; #5 start = 0; end wire txd_pin; wire txbusy_pin; UartTx UT1 ( .clk(clk200), .nrst(nrst), .tx_data(RandomNumber1[7:0]), .tx_start(1'b1), // .tx_start(~|RandomNumber1[15:10]), .tx_busy(txbusy_pin), .txd(txd_pin) ); defparam UT1.CLK_HZ = 200_000_000; defparam UT1.BAUD = 100_000_000; UartRx UR1 ( .clk(clk200), .nrst(nrst), .rx_data(), .rx_busy(), .rx_done(), .rxd(txd_pin) ); defparam UR1.CLK_HZ = 200_000_000; defparam UR1.BAUD = 100_000_000; endmodule