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I want to design a CPU which takes instructions of 8-bits, where the first 4 bits are the opcode, and the last 4 bits are data along with the opcode. There is a 4-bit register accumulator (AC), and these instructions are stored in a 16*4 bit memory. I have to fetch the instructions from the memory. There's also a program counter (PC) register. RESET is a signal which resets AC and PC to 0000.

LOAD encoded with 0000 ADD encoded with 0001 SUB encoded with 0010 AND encoded with 0011 OR encoded with 0100 J encoded with 1000 JR encoded with 1100

Here, each instruction has its usual meaning.

If one says 0000 1111, one has to load 1111 to the accumulator. Similarly you can understand what the other operations do. J is basically unconditional jump to a new location in the instruction memory (change program counter value) JR is PC relative jumping to a new instruction.

NOTE: The instructions in the 16*4 memory block are basically sequentially loaded, i.e., if the first memory location has the value '0000' and the next location has '1111', it means that the first is the opcode and the next is the data along with the opcode.

I am coding this problem in Verilog, and I've done quite a lot of testing, but I'm unable to get the desired output. Can anyone help me? I have several files containing the code. The files and the code are as follows: (P.S. I know the code looks weird, but I am new to using Verilog; this is my first time using Verilog and I'm supposed to be doing the entire code in structural format, so.. yeah)

AC.v

module Accumulator(q,d,clk,reset);  //q is the output, d is the input (4 bits each)

input [3:0] d;
input clk,reset;
output [3:0] q;
                    //Tested and fully functional
dff D0(q[0],notq0,d[0],clk,reset);
dff D1(q[1],notq1,d[1],clk,reset);
dff D2(q[2],notq2,d[2],clk,reset);
dff D3(q[3],notq3,d[3],clk,reset);

endmodule

Adder.v

module onebitadder(x,y,sum,carryout,carryin);
input x,y,carryin;
output sum,carryout;

    //sum = x XOR y XOR z, where z is carry in
    //carryout = x XOR y multiplied by z plus xy

xor XOR1(p,x,y);
xor XOR2(sum,p,carryin);
    //At this stage, we have sum with us

and ANDp(q,p,carryin);
and ANDxy(r,x,y);
or ORing(carryout,q,r);
    //At this stage, we have carryout also with us

endmodule

module fourbitadder(a,b,carryout,s,carryin);

input carryin;
input [3:0] a,b;
output carryout;
output [3:0] s;

onebitadder adder1(a[0],b[0],s[0],c1,carryin);
onebitadder adder2(a[1],b[1],s[1],c2,c1);
onebitadder adder3(a[2],b[2],s[2],c3,c2);
onebitadder adder4(a[3],b[3],s[3],carryout,c3);


endmodule

/* Logic for subtraction: Suppose you want to perform 8 - 4
first take 2's complement of 4 and add it to 8
to take 2's complement of 4, first take 1's complement and add 1 to it
to take 1's complement, perform XOR operation on the bits with the bit '1'
*/

module fourbitsubtractor(a,b,carryout,s,carryin);

//We perform a - b here
input [3:0] a,b;
output [3:0] s;
input carryin;
output carryout;
wire [3:0] m;

xor X1(m[3],b[3],1);
xor X2(m[2],b[2],1);
xor X3(m[1],b[1],1);
xor X4(m[0],b[0],1);

fourbitadder adding(a,m,carryout,s,1);

endmodule

ALU.v

module ALU(reset,out1,out2);        //MUX logic in-built to this ALU
input reset;

wire [3:0] in1;
output [3:0] out1;
wire [3:0] in2;
output [3:0] out2;
wire [3:0] opcode;
wire [3:0] data;
wire [3:0] s1,s2,s3,s4,s5,val;

clkGen CLK(clk);

ProgramCounter PC(out1,in1,clk,reset);
Accumulator AC(out2,in2,clk,reset);

Memory MEM(opcode,data,out1,clk);



or OR1(x,opcode[3],opcode[2]);
not NOT1(y,opcode[1]);          //X = (A+B)C'D'
not NOT2(z,opcode[0]);
and AND1(x1,x,y);
and AND2(X,z,x1);       //Select lines X,Y,Z control logic for future MUX

and AND3(x2,opcode[3],opcode[2]);
and AND4(x3,y,z);
and AND5(x4,x2,x3);     //At this stage, we have ABC'D' in x4

not NOT3(y1,opcode[3]);
not NOT4(y2,opcode[2]);
and AND6(y3,y1,y2);             //y3 = A'B'
and AND7(y4,y3,opcode[1]);      //At this stage, we have A'B'C in y4

or OR2(Y,x4,y4);                //Y = ABC'D' + A'B'C

  and AND8(z1,y3,opcode[0]);      //z1 = A'B'D
  and AND9(z2,x3,opcode[3]);
  and AND10(z3,z2,y2);
  or OR3(Z,z1,z3);

 //At this stage, we have the select lines X,Y,Z for MUX




 fourbitadder add1(out2,data,carryout1,s1,0);       //out2 + data   s1
 fourbitsubtractor sub1(out2,data,carryout2,s2,0);  //out2 - data   s2
 AND andq(out2,data,s3);                    //out2 & data   s3
 OR orq(out2,data,s4);                  //out2 | data   s4
 fourbitadder add2(out1,data,carryout3,s5,0);       //out1 + data   s5

 mux8x1 M1(val,data,s4,s2,s5,s1,data,s3,1'b0,X,Y,Z);

                    //Convert to structural (easily possible)
    if(opcode[3]==0)
    begin
fourbitadder add3(val,4'b0000,carryout4,in2,0);
    fourbitadder add4(out1,4'b0010,carryout5,in1,0);
    end
    else
    begin
    fourbitadder add5(val,4'b0000,carryout6,in1,0);
    end





 endmodule

AND.v

module AND(in1,in2,out);                //this module does a 4-bit AND operation

input [3:0] in1,in2;
output [3:0] out;

and A1(out[0],in1[0],in2[0]);
and A2(out[1],in1[1],in2[1]);
and A3(out[2],in1[2],in2[2]);
and A4(out[3],in1[3],in2[3]);

endmodule

OR.v

module OR(in1,in2,out);                //this module does a 4-bit OR operation

input [3:0] in1,in2;
output [3:0] out;

 or o1(out[0],in1[0],in2[0]);
 or o2(out[1],in1[1],in2[1]);
 or o3(out[2],in1[2],in2[2]);
 or o4(out[3],in1[3],in2[3]);

 endmodule

Clock.v

module clkGen(out);
output out;
reg    out;
        //Tested and fully functional
initial begin
out = 1'b0;
end

always 
begin
out = #1 ~out;
end
endmodule

DFF.v

module dff(q,notq,d,clk,reset);
input d,clk,reset;
output q, notq;             //Tested and fully functional
reg q, notq;


always@(negedge clk)
begin
if(reset == 1'b1)
begin
    q = 1'b0;
    notq = 1'b1;
end
else
begin
    q = d;
    notq = ~q;
end
end
endmodule

Memory.v

 module Memory(opcode,data,addr,clk);
 output [3:0] data;
 output [3:0] opcode;    //The address refers to the opcode; next line is the data
 input  [3:0] addr;
 input clk;
 reg [3:0] data;
 reg [3:0] opcode;
 reg [3:0] memdata [15:0];

 initial
    begin
    memdata[0] = 4'b0000;
    memdata[1] = 4'b1100;
    memdata[2] = 4'b0000;
    memdata[3] = 4'b1111;
    memdata[4] = 4'b0000;
    memdata[5] = 4'b1101;
    memdata[6] = 4'b0000;
    memdata[7] = 4'b1011;
    memdata[8] = 4'b0000;
    memdata[9] = 4'b1100;
    memdata[10] = 4'b0000;
    memdata[11] = 4'b1000;
    memdata[12] = 4'b0000;
    memdata[13] = 4'b0000;
    memdata[14] = 4'b0000;
    memdata[15] = 4'b1101;
    end

 always @(posedge clk)
    begin
            opcode = memdata[addr];
            data = memdata[addr + 1'b1];
    end

 endmodule

MUX.v

module mux2x1(y,a,b,s);     
input [3:0] a,b;        //Tested and fully functional
input s;
output [3:0] y;
wire [3:0] i1,i2;
wire nots;

and G1(i1[0],a[0],nots);
and G2(i2[0],b[0],s);
not G3(nots,s);
or  G4(y[0],i1[0],i2[0]);

and G5(i1[1],a[1],nots);
and G6(i2[1],b[1],s);
or  G8(y[1],i1[1],i2[1]);

and G9(i1[2],a[2],nots);
and G10(i2[2],b[2],s);
or  G12(y[2],i1[2],i2[2]);

and G13(i1[3],a[3],nots);
and G14(i2[3],b[3],s);
or  G16(y[3],i1[3],i2[3]);

endmodule

module mux4x1(y,i1,i2,i3,i4,s0,s1);
input [3:0] i1,i2,i3,i4;
input s0,s1;
output [3:0] y,y01,y02;

mux2x1 MUX2X1_01(y01,i1,i2,s0);
mux2x1 MUX2X1_02(y02,i3,i4,s0);
mux2x1 MUX2X1_03(y,y01,y02,s1);

endmodule

module mux8x1(y,i1,i2,i3,i4,i5,i6,i7,i8,s0,s1,s2);
input [3:0] i1,i2,i3,i4,i5,i6,i7,i8;
input s0,s1,s2;
output [3:0] y,y1,y2,alpha1,alpha2;

mux4x1 MUX4x1_01(y1,i1,i2,i3,i4,s0,s1);
mux4x1 MUX4x1_02(y2,i5,i6,i7,i8,s0,s1);

not NOTa(s2bar, s2);
and ANDa(alpha1[0],y1[0],s2bar);
and ANDb(alpha2[0],y2[0],s2);
or ORa(y[0],alpha1[0],alpha2[0]);

and ANDc(alpha1[1],y1[1],s2bar);
and ANDd(alpha2[1],y2[1],s2);
or ORb(y[1],alpha1[1],alpha2[1]);

and ANDe(alpha1[2],y1[2],s2bar);
and ANDf(alpha2[2],y2[2],s2);
or ORc(y[2],alpha1[2],alpha2[2]);

 and ANDg(alpha1[3],y1[3],s2bar);
 and ANDh(alpha2[3],y2[3],s2);
 or ORd(y[3],alpha1[3],alpha2[3]);

 endmodule

PC.v

module ProgramCounter(out,in,clk,reset);
input [3:0] in;
output [3:0] out;
input reset,clk;
                    //Tested and fully functional
dff ff1(out[0],notq0,in[0],clk,reset);
dff ff2(out[1],notq1,in[1],clk,reset);
dff ff3(out[2],notq2,in[2],clk,reset);
dff ff4(out[3],notq3,in[3],clk,reset);

endmodule

TB.v

module top;

reg reset;
wire [3:0] out1,out2;

ALU alu(reset,out1,out2);

initial begin
$monitor("AC = %b, PC = %b, Reset = %b, Time = %2d",out2,out1,reset,$time);
#2
reset = 1'b1;




$finish;
end

 endmodule

Ok, so basically I've provided my entire code to you for reference, but I don't think there's any error in most of the files (especially the ones which have the comments saying that the code is fully functional), but I figured you might need it since every other file is linked. I am guessing the fault lies in my ALU file, but not sure.

BTW, my test bench is currently under a reset state, as you may have noticed. Try changing the values in it to see the erroneous results.

Thanks for reading through this long post and for your help.

share|improve this question
1  
This is way too large of a question. SO isn't a replacement for learning how to use your simulator. Spend some time viewing the waves, tracing back your output to see where it's diverging from your expected input. Learning to debug is just as important as how to write code. –  Tim Mar 13 '13 at 18:29
    
@Tim Thanks for responding. As I said, I'm new to Verilog. I am currently using the iverilog command to compile the files from a UNIX shell. I don't know what debuggers to use and how to use them. Can you direct me to any good resources? –  user2050932 Mar 14 '13 at 4:22
    
I believe iverilog has a simulator, though I've not used it before, I can't really give you a recommendation other than that as I've only used commercial simulators. Have you reviewed the documentation for it to see if you can figure out how to run the simulator? –  Tim Mar 14 '13 at 4:28
1  
You might also try Xilinx ISE WebPack (free), or anything else in this list: en.wikipedia.org/wiki/List_of_Verilog_simulators –  Tim Mar 14 '13 at 4:31
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