Compare commits

..

2 Commits

3 changed files with 56 additions and 54 deletions

View File

@ -1,5 +1,5 @@
module rom(input [19:0] address,output wire [15:0] data ,input rd,input cs); module rom(input [19:0] address,output wire [15:0] data ,input rd,input cs);
reg [15:0] memory [15:0]; reg [15:0] memory [0:15];
initial begin initial begin
$readmemh("boot_code.txt", memory); $readmemh("boot_code.txt", memory);
end end

View File

@ -1,58 +1,5 @@
`timescale 1ns/1ps
`include "proc_state_def.v" `include "proc_state_def.v"
module clock_gen (input enable, output reg clk);
parameter FREQ = 1000; // in HZ
parameter PHASE = 0; // in degrees
parameter DUTY = 50; // in percentage
real clk_pd = 1.0/FREQ * 1000000; // convert to ms
real clk_on = DUTY/100.0 * clk_pd;
real clk_off = (100.0 - DUTY)/100.0 * clk_pd;
real quarter = clk_pd/4;
real start_dly = quarter * PHASE/90;
reg start_clk;
initial begin
end
// Initialize variables to zero
initial begin
clk <= 0;
start_clk <= 0;
end
// When clock is enabled, delay driving the clock to one in order
// to achieve the phase effect. start_dly is configured to the
// correct delay for the configured phase. When enable is 0,
// allow enough time to complete the current clock period
always @ (posedge enable or negedge enable) begin
if (enable) begin
#(start_dly) start_clk = 1;
end else begin
#(start_dly) start_clk = 0;
end
end
// Achieve duty cycle by a skewed clock on/off time and let this
// run as long as the clocks are turned on.
always @(posedge start_clk) begin
if (start_clk) begin
clk = 1;
while (start_clk) begin
#(clk_on) clk = 0;
#(clk_off) clk = 1;
end
clk = 0;
end
end
endmodule
module processor ( input clock, input reset , output reg [19:0] external_address_bus, inout [15:0] external_data_bus,output reg read, output reg write, output reg HALT); module processor ( input clock, input reset , output reg [19:0] external_address_bus, inout [15:0] external_data_bus,output reg read, output reg write, output reg HALT);
/* State */ /* State */
reg [3:0] state; reg [3:0] state;

View File

@ -1,3 +1,5 @@
`timescale 1ns/1ps
module tb; module tb;
wire clock; wire clock;
reg reset; reg reset;
@ -29,3 +31,56 @@ initial begin
#50 $finish; #50 $finish;
end end
endmodule endmodule
/*Clock generator*/
module clock_gen (input enable, output reg clk);
parameter FREQ = 1000; // in HZ
parameter PHASE = 0; // in degrees
parameter DUTY = 50; // in percentage
real clk_pd = 1.0/FREQ * 1000000; // convert to ms
real clk_on = DUTY/100.0 * clk_pd;
real clk_off = (100.0 - DUTY)/100.0 * clk_pd;
real quarter = clk_pd/4;
real start_dly = quarter * PHASE/90;
reg start_clk;
initial begin
end
// Initialize variables to zero
initial begin
clk <= 0;
start_clk <= 0;
end
// When clock is enabled, delay driving the clock to one in order
// to achieve the phase effect. start_dly is configured to the
// correct delay for the configured phase. When enable is 0,
// allow enough time to complete the current clock period
always @ (posedge enable or negedge enable) begin
if (enable) begin
#(start_dly) start_clk = 1;
end else begin
#(start_dly) start_clk = 0;
end
end
// Achieve duty cycle by a skewed clock on/off time and let this
// run as long as the clocks are turned on.
always @(posedge start_clk) begin
if (start_clk) begin
clk = 1;
while (start_clk) begin
#(clk_on) clk = 0;
#(clk_off) clk = 1;
end
clk = 0;
end
end
endmodule