`timescale 1 ns/10 ps // time-unit = 1 ns, precision = 10 ps // simplified CC_PLL model module CC_PLL #( parameter REF_CLK = "", // e.g. "10.0" parameter OUT_CLK = "", // e.g. "50.0" parameter PERF_MD = "", // LOWPOWER, ECONOMY, SPEED parameter LOW_JITTER = 1, parameter CI_FILTER_CONST = 2, parameter CP_FILTER_CONST = 4 )( input CLK_REF, CLK_FEEDBACK, USR_CLK_REF, input USR_LOCKED_STDY_RST, USR_SET_SEL, output USR_PLL_LOCKED_STDY, USR_PLL_LOCKED, output CLK270, CLK180, CLK90, CLK0, CLK_REF_OUT ); reg r_pll_clk; reg r_user_pll_locked; // OUT_FREQ = 1 MHz integer clk_half_period = 50; initial begin r_pll_clk = 1'b0; r_user_pll_locked = 1'b1; end always #clk_half_period r_pll_clk = ~r_pll_clk; assign CLK0 = r_pll_clk; assign USR_PLL_LOCKED = r_user_pll_locked; endmodule // simplified CC_CFG_END model module CC_CFG_END ( output CFG_END ); assign CFG_END = 1'b1; endmodule module tb_uart_trng; // DUT in/out reg clk = 1'b0; reg rst_n = 1'b1; reg uart_tx; // Testbench variables reg [7:0] tx_data = 8'h0; reg [7:0] rx_data = 8'h0; // Testbench 1/2 clock period localparam clk_half_period = 50; // UART period calculation (9600 baud) localparam uart_bit_period = 1000000000 / 9600; localparam uart_bit_half_period = uart_bit_period/2; uart_trng UUT (.clk_i(clk), .rst_n_i(rst_n), .uart_tx_o(uart_tx)); // set dumpfile initial begin $dumpfile ("tb_uart_trng.fst"); $dumpvars (0, tb_uart_trng); end // Setup simulation initial begin #1 rst_n = 1'b0; #120 rst_n = 1'b1; end // Generate 10 mhz clock always #clk_half_period clk = !clk; // Checker initial begin @(posedge rst_n) for (reg [7:0] rx = 0; rx < 32; rx = rx + 1) begin @(negedge uart_tx) #uart_bit_period; #uart_bit_half_period; for (integer i = 0; i < 7; i = i + 1) begin rx_data[i] = uart_tx; #uart_bit_period; end $display ("UART recv: 0x%h", rx_data); end $display ("UART tests finished"); $finish; end endmodule