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module nqcpu (
input clk,
output [15:0] debugPC,
output [3:0] debugAluOp,
output [2:0] debugAluReg1,
output [2:0] debugAluReg2,
output [1:0] debugAluOpSource1, // ALU first operand: 0 = reg, 1 = memory read, 2 = imm8, 3 = PC
output [1:0] debugAluOpSource2, // ALU second operand: 0 = reg, 1 = ~reg, 2 = PC, 3 = ???
output debugAluDest, // 0 = reg, 1 = PC
output [2:0] debugRegDest,
output debugRegSetH,
output debugRegSetL,
output [2:0] debugRegAddr,
output debugMemReadB,
output debugMemReadW,
output debugMemWriteB,
output debugMemWriteW,
output [4:0] debugSetRegCond, // {should set when condition is true, Z doesn't matter, S doesn't matter, Z must be this, S must be this}
output [15:0] dbg_r0,
output [15:0] dbg_r1,
output [15:0] dbg_r2,
output [15:0] dbg_r3,
output [15:0] dbg_r4,
output [15:0] dbg_r5,
output [15:0] dbg_r6,
output [15:0] dbg_r7
);
reg [15:0] pc;
initial begin
pc = 16'h0;
end
wire fetch_ready;
wire [15:0] fetched_instr;
wire [15:0] pc_from_fetch;
fetch_stage fetch_inst (
.clk(clk),
.en(1'b1),
.addr_in(pc),
.ready(fetch_ready),
.instr_out(fetched_instr),
.pc_out(pc_from_fetch)
);
always @(posedge clk) begin
if(fetch_ready) begin
pc <= pc + 16'h2;
end
end
wire [31:0] ctrl_from_decoder;
wire [15:0] imm_from_decoder;
wire [15:0] pc_from_decoder;
decoder_stage decoder_inst (
.clk(clk),
.en(fetch_ready),
.instr_in(fetched_instr),
.pc_in(pc_from_fetch),
.control_signals_out(ctrl_from_decoder),
.imm_out(imm_from_decoder),
.pc_out(pc_from_decoder)
);
wire [2:0] rf_regA;
wire [2:0] rf_regB;
wire [2:0] rf_regDest;
wire [15:0] rf_dataIn;
wire rf_we;
wire rf_hb;
wire rf_lb;
wire [15:0] rf_dataA;
wire [15:0] rf_dataB;
regFile regFile_inst (
.clk(clk),
.regA(rf_regA),
.regB(rf_regB),
.regDest(rf_regDest),
.dataIn(rf_dataIn),
.we(rf_we),
.hb(rf_hb),
.lb(rf_lb),
.dataA(rf_dataA),
.dataB(rf_dataB),
.dbg_r0(dbg_r0),
.dbg_r1(dbg_r1),
.dbg_r2(dbg_r2),
.dbg_r3(dbg_r3),
.dbg_r4(dbg_r4),
.dbg_r5(dbg_r5),
.dbg_r6(dbg_r6),
.dbg_r7(dbg_r7)
);
wire [31:0] ctrl_from_alu;
wire [15:0] imm_from_alu;
wire [15:0] pc_from_alu;
alu_stage alu_inst (
.clk(clk),
.en(1'b1),
.pc_in(pc_from_decoder),
.control_signals_in(ctrl_from_decoder),
.imm_in(imm_from_decoder),
// register file
.rf_regA(rf_regA),
.rf_regB(rf_regB),
.rf_regDest(rf_regDest),
.rf_dataIn(rf_dataIn),
.rf_we(rf_we),
.rf_hb(rf_hb),
.rf_lb(rf_lb),
.rf_dataA(rf_dataA),
.rf_dataB(rf_dataB),
// memory interface
.memData_in(16'hDEAD), // read in from memory
//.memData_out(??), // to write out to memory
.control_signals_out(ctrl_from_alu),
.imm_out(imm_from_alu),
.pc_out(pc_from_alu)
);
ctrl_decode debug_decode (
.control_signals(ctrl_from_alu),
.aluOp(debugAluOp),
.aluReg1(debugAluReg1),
.aluReg2(debugAluReg2),
.aluOpSource1(debugAluOpSource1),
.aluOpSource2(debugAluOpSource2),
.aluDest(debugAluDest),
.regDest(debugRegDest),
.regSetH(debugRegSetH),
.regSetL(debugRegSetL),
.regAddr(debugRegAddr),
.memReadB(debugMemReadB),
.memReadW(debugMemReadW),
.memWriteB(debugMemWriteB),
.memWriteW(debugMemWriteW),
.setRegCond(debugSetRegCond)
);
assign debugPC = pc_from_alu;
endmodule
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