Standardised indentation

cpu/Makefile

@@ -1,4 +1,4 @@
-SOURCES=processor.v testbench.v
+SOURCES=processor.v testbench.v memory.v
 VVP=processor.vvp
 
 .PHONY: run

cpu/boot_code.txt

@@ -0,0 +1,17 @@
+// 0x00000000
+55AA
+0000
+0000
+0000
+0000
+0000
+0000
+0000
+0000
+0000
+0000
+0000
+0000
+0000
+0000
+0000

cpu/gtkwave_savefile.gtkw

@@ -1,18 +1,18 @@
 [*]
 [*] GTKWave Analyzer v3.3.104 (w)1999-2020 BSI
-[*] Wed Feb  8 09:34:17 2023
+[*] Wed Feb  8 11:44:52 2023
 [*]
 [dumpfile] "/home/user/UNI_DATA/COMS30046_2022_TB-2/projects/9086/cpu/test.lx2"
-[dumpfile_mtime] "Wed Feb  8 09:33:52 2023"
+[dumpfile_mtime] "Wed Feb  8 11:44:20 2023"
-[dumpfile_size] 362
+[dumpfile_size] 430
 [savefile] "/home/user/UNI_DATA/COMS30046_2022_TB-2/projects/9086/cpu/gtkwave_savefile.gtkw"
 [timestart] 0
-[size] 1630 1059
+[size] 1342 1059
 [pos] -1 -1
-*-20.795050 0 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1
+*-20.795050 2883000 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1
 [treeopen] tb.
 [sst_width] 221
-[signals_width] 214
+[signals_width] 293
 [sst_expanded] 1
 [sst_vpaned_height] 313
 @28
@@ -20,7 +20,11 @@ tb.p.clock[0]
 tb.p.reset[0]
 tb.p.start[0]
 tb.p.state[1:0]
-@29
 tb.p.instruction_finished[0]
+@22
+tb.p.external_address_bus[19:0]
+tb.p.external_data_bus[15:0]
+@29
+tb.p.read[0]
 [pattern_trace] 1
 [pattern_trace] 0

cpu/memory.v

@@ -0,0 +1,7 @@
+module rom(input [19:0] address,output wire [15:0] data ,input rd,input cs);
+reg [15:0] memory [15:0];
+initial begin
+	$readmemh("boot_code.txt", memory);
+end
+assign data = !rd & !cs ? memory[address]: 'hz;
+endmodule

cpu/processor.v

@@ -2,42 +2,42 @@
 
 module clock_gen (input enable, output reg clk);
 
-  parameter FREQ = 1000;  // in HZ
+parameter FREQ = 1000;  // in HZ
-  parameter PHASE = 0;    // in degrees
+parameter PHASE = 0;    // in degrees
-  parameter DUTY = 50;    // in percentage 
+parameter DUTY = 50;    // in percentage 
 
-  real clk_pd  		= 1.0/FREQ * 1000000; 	// convert to ms
+real clk_pd	= 1.0/FREQ * 1000000; 	// convert to ms
-  real clk_on  		= DUTY/100.0 * clk_pd;
+real clk_on	= DUTY/100.0 * clk_pd;
-  real clk_off 		= (100.0 - DUTY)/100.0 * clk_pd;
+real clk_off	= (100.0 - DUTY)/100.0 * clk_pd;
-  real quarter 		= clk_pd/4;
+real quarter	= clk_pd/4;
-  real start_dly        = quarter * PHASE/90;
+real start_dly	= quarter * PHASE/90;
 
-  reg start_clk;
+reg start_clk;
 
-  initial begin
+initial begin
-  end
+end
 
-  // Initialize variables to zero
+// Initialize variables to zero
-  initial begin
+initial begin
 	clk <= 0;
 	start_clk <= 0;
-  end
+end
 
-  // When clock is enabled, delay driving the clock to one in order
+// When clock is enabled, delay driving the clock to one in order
-  // to achieve the phase effect. start_dly is configured to the 
+// to achieve the phase effect. start_dly is configured to the 
-  // correct delay for the configured phase. When enable is 0,
+// correct delay for the configured phase. When enable is 0,
-  // allow enough time to complete the current clock period
+// allow enough time to complete the current clock period
-  always @ (posedge enable or negedge enable) begin
+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
+end
 
-  // Achieve duty cycle by a skewed clock on/off time and let this
+// Achieve duty cycle by a skewed clock on/off time and let this
-  // run as long as the clocks are turned on.
+// run as long as the clocks are turned on.
-  always @(posedge start_clk) begin
+always @(posedge start_clk) begin
 	if (start_clk) begin
 		clk = 1;
 
@@ -48,27 +48,33 @@ module clock_gen (input enable, output reg clk);
 
 		clk = 0;
 	end
-  end 
+end 
 endmodule
 
 
-module processor ( input clock, input reset );
+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);
-  reg [1:0] state;
+/* State */
-  reg start=0;
+reg [1:0] state;
-  reg instruction_finished;
+reg start=0;
+reg instruction_finished;
 
-  /* RESET LOGIC */
+/* Registers */
-  always @(negedge reset) begin
+reg [19:0] ProgCount;
+
+
+/* RESET LOGIC */
+always @(negedge reset) begin
 	if (reset==0) begin
 		@(posedge clock);
 		state=0;
+		ProgCount=0;//TODO: Reset Vector
 		#10
 		start=1;
 	end
-  end
+end
 
-  /* CLOCK LOGIC */
+/* CLOCK LOGIC */
-  always @(posedge clock) begin
+always @(posedge clock) begin
 	if(instruction_finished) begin 
 		state =0;
 	end else begin
@@ -76,15 +82,23 @@ module processor ( input clock, input reset );
 			state=state+1;
 		end
 	end
-  end
+end
 
-  always @(state) begin
+always @(state) begin
 	if (state==2) begin
 		instruction_finished=1;
 	end else begin
 		instruction_finished=0;
 	end
-  end
+end
 
+/* Processor stages */
+always @(state) begin
+	if (state==0) begin
+		external_address_bus <= ProgCount;
+		read <= 0;
+		write <= 1;
+	end
+end
 
 endmodule

cpu/testbench.v

@@ -1,13 +1,19 @@
 module tb;
-  wire clock;
+wire clock;
-  reg reset;
+reg reset;
-  reg  clk_enable;
+reg  clk_enable;
+wire [19:0]address_bus;
+wire [15:0]data_bus;
+wire rd,wr,romcs;
 
-  processor p(clock,reset);
+processor p(clock,reset,address_bus,data_bus,rd,wr);
+rom bootrom(address_bus,data_bus,rd,romcs);
 
-  clock_gen #(.FREQ(1000)) u1(clk_enable, clock);
+clock_gen #(.FREQ(1000)) u1(clk_enable, clock);
 
-  initial begin
+assign romcs=0;
+
+initial begin
 	$dumpfile("test.lx2");
 	$dumpvars(0,p);
 	clk_enable <= 1;
@@ -19,5 +25,5 @@ module tb;
 	#(10000)
 
 	#50 $finish;
-  end
+end
 endmodule