// Example code for an AHBLite System-on-Chip // Iain McNally // ECS, University of Soutampton // // This module is a wrapper allowing the system to be used on the Nexsys 4 FPGA board // module nexys4_wrapper( input Clock, nReset, input [15:0] Switches, input [1:0] Buttons, // nexys4 buttons are active high output [15:0] DataOut, output DataValid, DataInvalid, output Status_Green, Status_Red ); timeunit 1ns; timeprecision 100ps; localparam heartbeat_count_msb = 26; localparam heartbeat_dimmer_msb = 5; wire HCLK, HRESETn, LOCKUP; soc soc_inst(.HCLK, .HRESETn, .DataOut, .DataValid, .Switches, .Buttons, .LOCKUP); assign DataInvalid = ! DataValid; // Drive HRESETn directly from active low CPU RESET button assign HRESETn = nReset; // Drive HCLK from 50MHz signal derived from 100MHz Nexys4 board clock logic Clock50; always_ff @(posedge Clock, negedge nReset ) if ( ! nReset ) Clock50 <= 0; else Clock50 <= ! Clock50; assign HCLK = Clock50; // This code gives us a heartbeat signal on the RGB LED // // The LED is: // steady orange - at reset, // steady red - in the event of "lockup" and // pulsing green - under normal operation // logic running, heartbeat; logic [heartbeat_count_msb:0] tick_count; always_ff @(posedge Clock, negedge nReset ) if ( ! nReset ) begin running <= 0; heartbeat <= 0; tick_count <= 0; end else begin running <= 1; heartbeat = tick_count[heartbeat_count_msb] && tick_count[heartbeat_count_msb-2] && (&tick_count[heartbeat_dimmer_msb:0]); tick_count <= tick_count + 1; end // Single LED with two colours to indicate system status assign Status_Green = !running || ( heartbeat && !LOCKUP ); assign Status_Red = !running || LOCKUP; endmodule