module mips_cpu_harvard( /* Standard signals */ input logic clk, input logic reset, output logic active, output logic [31:0] register_v0, /* New clock enable. See below. */ input logic clk_enable, /* Combinatorial read access to instructions */ output logic[31:0] instr_address,//Port from PC out to instruction memory address input. input logic[31:0] instr_readdata,//port from instruction memory out, going to various inputs. /* Combinatorial read and single-cycle write access to instructions */ output logic[31:0] data_address,//Port from ALURes going into Data Memory 'Address' port output logic data_write,//Control line from 'control' CtrlMemWrite enabling/disabling write access for Data Memory. output logic data_read,//Control line from 'control' CtrlMemRead enabling/disabling read access for Data Memory. output logic[31:0] data_writedata,//Data from Register file 'Read data 2' port, aka rt's data, going to 'Write data' port on Data Memory. input logic[31:0] data_readdata//port from data memory out, going to the 'Write Register' port in regfile. ); always_comb begin instr_address = in_pc_in; data_address = out_ALURes; data_write = out_MemWrite; data_read = out_MemRead; data_writedata = out_readdata2; end logic[31:0] in_pc_in, out_pc_out = 32'hBFC00000, out_ALURes, out_readdata1, out_readdata2, in_B, in_writedata; logic[4:0] in_readreg1, in_readreg2, in_writereg, out_shamt, out_ALUOp; logic[5:0] in_opcode; logic out_ALUCond, out_RegWrite, out_ALUSrc, out_MemWrite, out_MemRead; logic[1:0] out_RegDst, out_PC, out_MemtoReg; assign in_readreg1 = instr_readdata[25:21]; assign in_readreg2 = instr_readdata[20:16]; assign in_opcode = instr_readdata[31:26]; always_comb begin //Picking what register should be written to. case(out_RegDst) 2'd0: begin in_writereg = instr_readdata[20:16];//GPR rt end 2'd1: begin in_writereg = instr_readdata[15:11];//GPR rd end 2'd2: begin in_writereg = 5'd31;//Link Register 31. end endcase //Picking which output should be written to regfile. case(out_MemtoReg) 2'd0:begin in_writedata = out_ALURes;//Output from ALU Result. end 2'd1:begin in_writedata = data_readdata;//Output from Data Memory. end 2'd2:begin in_writedata = (out_pc_out + 32'd8);//Output from PC +8. end endcase //Picking which output should be taken as the second operand for ALU. case(out_ALUSrc) 1'b1:begin in_B = {{16{instr_readdata[15]}},instr_readdata[15:0]};//Output from the 16-bit immediate values sign extened to 32bits. end 1'b0:begin in_B = out_readdata2;//Output from 'Read data 2' port of regfile. end endcase end pc pc( //PC inputs .clk(clk),//clk taken from the Standard signals .rst(reset),//clk taken from the Standard signals .pc_ctrl(out_PC), .pc_in(out_pc_out),//what the pc will output on the next clock cycle taken from either: PC itself + 4(Normal/Default Operation); or 16-bit signed valued taken from Instr[15-0] sign extend to 32bit then shifted by 2 then added to PC + 4(Branch Operation); or 26-bit instruction address taken from J-type instr[25-0] shifted left by 2 then concatanated to form Jump Address (PC-region branch); or from the GPR rs. //PC outputs .pc_out(in_pc_in),//What the pc outputs at every clock edge that goes into the 'Read address' port of Instruction Memory. .active(active) ); mips_cpu_control control( //instance of the 'mips_cpu_control' module called 'control' in top level 'harvard' //Inputs to control .Instr(instr_readdata), //Full instruction taken from the Instruction Memory. .ALUCond(out_ALUCond), //Active high condition check from ALU //Outputs from control .CtrlRegDst(out_RegDst), .CtrlPC(out_PC), .CtrlMemRead(out_MemRead), .CtrlMemtoReg(out_MemtoReg), .CtrlALUOp(out_ALUOp), .Ctrlshamt(out_shamt), .CtrlMemWrite(out_MemWrite), .CtrlALUSrc(out_ALUSrc), .CtrlRegWrite(out_RegWrite) ); mips_cpu_regfile regfile( //Inputs to refile .clk(clk), //clock input for triggering write port .readreg1(in_readreg1), //read port 1 selector .readreg2(in_readreg2), //read port 2 selector .writereg(in_writereg), //write port selector .writedata(in_writedata), //write port input data .regwrite(out_RegWrite), //enable line for write port .opcode(in_opcode), //opcode input for controlling partial load weirdness //Outputs from regfile .readdata1(out_readdata1), //read port 1 output .readdata2(out_readdata2), //read port 2 output .regv0(register_v0) //debug output of $v0 or $2 (first register for returning function results ); mips_cpu_alu alu( //Inputs to ALU .A(out_readdata1), //operand 1 taken from 'Read data 1' aka the data stored in GPR rs. .B(in_B), //operand 2 taken either from: 'Read data 2' aka the data stored in rt; or 16-bit immediate sign extended to 32 bits. .ALUOp(out_ALUOp), //Operation selection for ALU decided, and output by control. .shamt(out_shamt), //Shift amount required for shift instruction taken from control. //Outputs from ALU .ALUCond(out_ALUCond), //condition used by control to decide on branch instructions. .ALURes(out_ALURes) //output/result of operation that goes to either: 'Address' port of Data Memory; or 'Write Data' port of the register file. ); endmodule