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RISC-V CORE

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kaltinsoy
2025-08-23 05:18:49 +03:00
parent a40879f631
commit 989c59ecda
13 changed files with 5245 additions and 477 deletions
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286
FINAL/RISCCore.v Normal file
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module RISCCore (
input rst,
input clk,
output reg [31:0] pc,
output wire [31:0] next_pc, // Changed to wire
output wire [31:0] instr
);
// IMem - reduced size for simplicity
reg [31:0] imem [0:63];
initial begin
$readmemh("program.hex", imem);
end
assign instr = (pc[31:2] < 64) ? imem[pc[31:2]] : 32'h00000013; // Word-aligned access
//Data Mem
reg [31:0] dmem [0:31];
wire [31:0] ld_data;
wire [4:0] word_addr = mem_addr[6:2];
integer j;
initial begin
for(j = 0; j < 32; j = j + 1) begin
dmem[j] = 32'b0;
end
end
assign ld_data = (word_addr < 32) ? dmem[word_addr] : 32'b0;
// Instruction decoder
wire [6:0] opcode = instr[6:0];
wire [4:0] rs1 = instr[19:15];
wire [4:0] rs2 = instr[24:20];
wire [4:0] rd = instr[11:7];
wire [2:0] funct3 = instr[14:12];
wire [6:0] funct7 = instr[31:25];
// Instruction type detection
wire isUType = (opcode == 7'b0110111) || (opcode == 7'b0010111); // LUI, AUIPC
wire isIType = (opcode == 7'b0000011) || (opcode == 7'b0000111) || // LOAD
(opcode == 7'b0010011) || (opcode == 7'b0011011) || // OP-IMM
(opcode == 7'b1100111); // JALR
wire isRType = (opcode == 7'b0110011) || (opcode == 7'b0111011); // OP
wire isSType = (opcode == 7'b0100011) || (opcode == 7'b0100111); // STORE
wire isBType = (opcode == 7'b1100011); // BRANCH
wire isJType = (opcode == 7'b1101111); // JAL
// Immediate generation
wire [31:0] Iimm = {{20{instr[31]}}, instr[31:20]};
wire [31:0] Simm = {{20{instr[31]}}, instr[31:25], instr[11:7]};
wire [31:0] Bimm = {{19{instr[31]}}, instr[31], instr[7], instr[30:25], instr[11:8], 1'b0};
wire [31:0] Uimm = {instr[31:12], 12'b0};
wire [31:0] Jimm = {{11{instr[31]}}, instr[31], instr[19:12], instr[20], instr[30:21], 1'b0};
// Register file
// Initialize register file (x0 always zero)
reg [31:0] rf [0:31]; //Register file
integer i;
initial begin
for (i = 0; i < 32; i = i + 1) begin
rf[i] = 32'b0;
end
end
// Read ports
wire [31:0] rs1_val = (rs1 != 0) ? rf[rs1] : 32'b0;
wire [31:0] rs2_val = (rs2 != 0) ? rf[rs2] : 32'b0;
// Instruction decoding
wire isADDI = (opcode == 7'b0010011) && (funct3 == 3'b000);
wire isADD = (opcode == 7'b0110011) && (funct3 == 3'b000) && (funct7 == 7'b0000000);
// Branch instructions
wire isBEQ = (isBType) && (funct3 == 3'b000);
wire isBNE = (isBType) && (funct3 == 3'b001);
wire isBLT = (isBType) && (funct3 == 3'b100);
wire isBGE = (isBType) && (funct3 == 3'b101);
wire isBLTU = (isBType) && (funct3 == 3'b110);
wire isBGEU = (isBType) && (funct3 == 3'b111);
//store load instructions
wire isLB = (isIType) && (funct3 == 3'b000);
wire isLH = (isIType) && (funct3 == 3'b001);
wire isLW = (opcode == 7'b0000011) && (funct3 == 3'b010);
wire isLBU = (isIType) && (funct3 == 3'b100);
wire isLHU = (isIType) && (funct3 == 3'b101);
wire isSB = (isSType) && (funct3 == 3'b000);
wire isSH = (isSType) && (funct3 == 3'b001);
wire isSW = (opcode == 7'b0100011) && (funct3 == 3'b010);
//sl and sr instructions
wire isSLT = (isRType) && (funct3 == 3'b010) && (funct7[5] == 1'b0);
wire isSLTU = (isRType) && (funct3 == 3'b011) && (funct7[5] == 1'b0);
wire isSLL = (opcode == 7'b0110011) && (funct3 == 3'b001) && (funct7 == 7'b0000000);
wire isSLTI = (isIType) && (funct3 == 3'b010);
wire isSLTIU = (isIType) && (funct3 == 3'b011);
wire isSRL = (opcode == 7'b0110011) && (funct3 == 3'b101) && (funct7 == 7'b0000000);
wire isSRA = (opcode == 7'b0110011) && (funct3 == 3'b101) && (funct7 == 7'b0100000);
wire isSLLI = (opcode == 7'b0010011) && (funct3 == 3'b001) && (funct7[6:1] == 6'b000000);
wire isSRLI = (opcode == 7'b0010011) && (funct3 == 3'b101) && (funct7[6:1] == 6'b000000);
wire isSRAI = (opcode == 7'b0010011) && (funct3 == 3'b101) && (funct7[6:1] == 6'b010000);
//logic imms
wire isANDI = (opcode == 7'b0010011) && (funct3 == 3'b111);
wire isORI = (opcode == 7'b0010011) && (funct3 == 3'b110);
wire isXORI = (opcode == 7'b0010011) && (funct3 == 3'b100);
// logic
wire isAND = (opcode == 7'b0110011) && (funct3 == 3'b111) && (funct7 == 7'b0000000);
wire isOR = (opcode == 7'b0110011) && (funct3 == 3'b110) && (funct7 == 7'b0000000);
wire isXOR = (opcode == 7'b0110011) && (funct3 == 3'b100) && (funct7 == 7'b0000000);
wire isSUB = (opcode == 7'b0110011) && (funct3 == 3'b000) && (funct7 == 7'b0100000);
//lui auipc (opcode use)
wire isLUI = (opcode == 7'b0110111);
wire isAUIPC = (opcode == 7'b0010111);
wire isJAL = (opcode == 7'b1101111);
//jal UType
wire isJALR = (opcode == 7'b1100111) && (funct3 == 3'b000);
//Mem address calculation
wire [31:0] mem_addr = (is_mem_op) ? alu_result : 32'b0;
//Mem address logic
//For simplicity we only implement all loads as word loads (lw)
//byte/halfword ignored
wire is_load = (opcode == 7'b0000011); // All load instructions
wire is_store = (opcode == 7'b0100011); // All store instructions
wire is_mem_op = is_store || is_load;
//Load operations
reg [31:0] load_data;
always @(*) begin
if (mem_addr[1:0] == 2'b00) begin
case (funct3)
3'b000: load_data = {{24{ld_data[7]}}, ld_data[7:0]};
3'b001: load_data = {{16{ld_data[15]}}, ld_data[15:0]};
3'b010: load_data = ld_data;
3'b100: load_data = {24'b0, ld_data[7:0]};
3'b101: load_data = {16'b0, ld_data[15:0]};
default: load_data = 32'b0;
endcase
end else begin
load_data = 32'b0;
if (is_load) begin // Only show error for actual loads
$display("ERROR: Misaligned memory address at addr %h", mem_addr);
end
end
end
//Store operations
always @(*) begin
if (!rst && is_store && (word_addr < 32) && (mem_addr[1:0] == 2'b00)) begin
case (funct3)
3'b000: begin //SB: store byte 0
dmem[word_addr][7:0] = rs2_val[7:0];
end
3'b001: begin //SH: store halfword
dmem[word_addr][15:0] = rs2_val[15:0];
end
3'b010: begin //SW: store word
dmem[word_addr] = rs2_val;
end
endcase
$display("MEM Write: word_addr=%h, data=%h", word_addr, rs2_val);
end
end
// ALU operations
//sltu and slt
wire [31:0] sltu_rslt = {31'b0, (rs1_val < rs2_val)};
wire [31:0] signed_slt = (rs1_val[31] && !rs2_val[31]) ? 1'b1 :
(!rs1_val[31] && rs2_val[31]) ? 1'b0 :
(rs1_val < rs2_val);
wire [31:0] slt_rslt = {31'b0, signed_slt};
wire [31:0] slti_rslt = ((rs1_val[31] == Iimm[31]) ? sltu_rslt : {31'b0, rs1_val[31]});
wire [63:0] SErs1_val = {{32{rs1_val[31]}}, (rs1_val < rs2_val)};
wire [63:0] sra_rslt = {SErs1_val >> rs2_val[4:0]};
wire [63:0] srai_rslt = {SErs1_val >> Iimm[4:0]};
wire [31:0] sltiu_rslt = {31'b0, (rs1_val < Iimm)};
wire [31:0] alu_result = (is_mem_op) ? (rs1_val + Iimm) : // Mem address computation
(isADDI) ? (rs1_val + Iimm) :
(isADD) ? (rs1_val + rs2_val) :
(isSLT) ? slt_rslt :
(isSLTU) ? sltu_rslt :
(isSLTI) ? slti_rslt :
(isANDI) ? (rs1_val & Iimm) :
(isORI) ? (rs1_val | Iimm) :
(isXORI) ? (rs1_val ^ Iimm) :
(isSLLI) ? (rs1_val << Iimm[4:0]) :
(isSRLI) ? (rs1_val >> Iimm[4:0]) :
(isAND) ? (rs1_val & rs2_val) :
(isOR) ? (rs1_val | rs2_val) :
(isXOR) ? (rs1_val ^ rs2_val) :
(isSUB) ? (rs1_val - rs2_val) :
(isSLL) ? (rs1_val << rs2_val[4:0]) :
(isSRL) ? (rs1_val >> rs2_val[4:0]) :
(isSLTIU) ? (sltiu_rslt) :
(isLUI) ? ({Iimm[31:12], 12'b0}) :
(isAUIPC) ? (pc + Iimm) :
(isJAL || isJALR) ? (pc + 32'd4) :
(isSRA) ? (sra_rslt[31:0]) :
(isSRAI) ? (srai_rslt[31:0]) :
32'b0;
wire signed [31:0] signed_rs1 = rs1_val;
wire signed [31:0] signed_rs2 = rs2_val;
wire branch_taken =
isBEQ ? (rs1_val == rs2_val) :
isBNE ? (rs1_val != rs2_val) :
isBLT ? (signed_rs1 < signed_rs2) :
isBGE ? (signed_rs1 >= signed_rs2) :
isBLTU ? (rs1_val < rs2_val) :
isBGEU ? (rs1_val >= rs2_val) :
1'b0;
// Next PC calculation - FIXED: using wire for continuous assignment
wire [31:0] branch_target = pc + Bimm;
wire [31:0] next_pc_base = pc + 32'h4;
wire [31:0] jalr_tgt_pc = rs1_val + Iimm;
assign next_pc = branch_taken ? branch_target :
isJAL ? branch_target :
isJALR ? jalr_tgt_pc :
next_pc_base;
// Register write back
wire rf_write_enable = (rd != 0) && (
isADDI || isADD || isSUB ||
isJAL || isJALR ||
isSLT || isSLTU || isSLTI || isSLTIU ||
isSLL || isSRL || isSRA || isSLLI || isSRLI || isSRAI ||
isLB || isLH || isLW || isLBU || isLHU ||
isXORI || isORI || isANDI ||
isXOR || isOR || isAND ||
is_load || isLUI || isAUIPC
);
wire [31:0] writeback_data = is_load ? load_data : alu_result;
// PC update
always @(posedge clk) begin
if (rst) begin
pc <= 32'h0;
end else begin
pc <= next_pc;
end
end
// Register write back
always @(posedge clk) begin
if (rf_write_enable && !rst) begin
rf[rd] <= writeback_data; // Use writeback_data instead of alu_result
$display("RF Write: x%d = %h", rd, writeback_data);
end
end
// Debug monitoring
always @(posedge clk) begin
if (!rst) begin
$display("PC=%08h, Instr=%08h, rs1=x%d(%h), rs2=x%d(%h), rd=x%d, branch_taken=%b",
pc, instr, rs1, rs1_val, rs2, rs2_val, rd, branch_taken);
if (pc[1:0] != 2'b00) begin
$display("WARNING: PC not word-aligned: %h", pc);
end
end
end
always @(posedge clk) begin
if (!rst && (opcode == 7'b0000011)) begin
$display("LOAD: byte_addr=%h, word_addr=%h, data=%h, funct3=%b",
mem_addr, word_addr, load_data, funct3);
end
end
endmodule

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`timescale 1ns/1ps
module RISCCore_tb;
reg clk;
reg rst;
wire [31:0] pc;
wire [31:0] next_pc;
wire [31:0] instr;
// Instantiate the RISC-V core
RISCCore uut (
.rst(rst),
.clk(clk),
.pc(pc),
.next_pc(next_pc),
.instr(instr)
);
// Clock generation
always #5 clk = ~clk;
// Initialize signals
initial begin
clk = 0;
rst = 1;
// Reset sequence
#10 rst = 0;
// Run for enough clock cycles
#500;
// Display final register values
$display("\n=== FINAL REGISTER STATE ===");
$display("x1 (ra) = %h", uut.rf[1]);
$display("x2 (sp) = %h", uut.rf[2]);
$display("x3 (gp) = %h", uut.rf[3]);
$display("x4 (tp) = %h", uut.rf[4]);
$display("x5 (t0) = %h", uut.rf[5]);
$display("x6 (t1) = %h", uut.rf[6]);
$display("x7 (t2) = %h", uut.rf[7]);
$display("x8 (s0) = %h", uut.rf[8]);
$display("x10 (a0) = %h", uut.rf[10]);
// Display memory contents
$display("\n=== MEMORY STATE ===");
begin : memory_display
integer i;
for (i = 0; i < 10; i = i + 1) begin
$display("mem[%0d] = %h", i, uut.dmem[i]);
end
end
$finish;
end
// Simple monitor
initial begin
$monitor("Time=%0t: PC=%h, Instr=%h", $time, uut.pc, uut.instr);
end
endmodule

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00000093 // addi x1, x0, 0 - x1 = 0
00100113 // addi x2, x0, 1 - x2 = 1
00200193 // addi x3, x0, 2 - x3 = 2
003081b3 // add x3, x1, x3 - x3 = 0 + 2 = 2
00420233 // add x4, x4, x4 - x4 = x4 + x4 (should be 0)
00228463 // beq x5, x2, 8 - branch if x5 == x2 (should not take)
00400463 // beq x0, x4, 8 - branch if 0 == 0 (should take)
00a00513 // addi x10, x0, 10 - x10 = 10 (should be skipped)
fff00513 // addi x10, x0, -1 - x10 = -1 (should execute)
00000013 // nop
00000013 // nop
00000013 // nop

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module RISCCore (
input rst,
input clk,
output reg [31:0] pc,
output wire [31:0] next_pc, // Changed to wire
output wire [31:0] instr
);
// IMem - reduced size for simplicity
reg [31:0] imem [0:63];
initial begin
$readmemh("program.hex", imem);
end
assign instr = (pc[31:2] < 64) ? imem[pc[31:2]] : 32'h00000013; // Word-aligned access
//Data Mem
reg [31:0] dmem [0:31];
wire [31:0] ld_data;
wire [4:0] word_addr = mem_addr[6:2];
integer j;
initial begin
for(j = 0; j < 32; j = j + 1) begin
dmem[j] = 32'b0;
end
end
assign ld_data = (word_addr < 32) ? dmem[word_addr] : 32'b0;
// Instruction decoder
wire [6:0] opcode = instr[6:0];
wire [4:0] rs1 = instr[19:15];
wire [4:0] rs2 = instr[24:20];
wire [4:0] rd = instr[11:7];
wire [2:0] funct3 = instr[14:12];
wire [6:0] funct7 = instr[31:25];
// Instruction type detection
wire isUType = (opcode == 7'b0110111) || (opcode == 7'b0010111); // LUI, AUIPC
wire isIType = (opcode == 7'b0000011) || (opcode == 7'b0000111) || // LOAD
(opcode == 7'b0010011) || (opcode == 7'b0011011) || // OP-IMM
(opcode == 7'b1100111); // JALR
wire isRType = (opcode == 7'b0110011) || (opcode == 7'b0111011); // OP
wire isSType = (opcode == 7'b0100011) || (opcode == 7'b0100111); // STORE
wire isBType = (opcode == 7'b1100011); // BRANCH
wire isJType = (opcode == 7'b1101111); // JAL
// Immediate generation
wire [31:0] Iimm = {{20{instr[31]}}, instr[31:20]};
wire [31:0] Simm = {{20{instr[31]}}, instr[31:25], instr[11:7]};
wire [31:0] Bimm = {{19{instr[31]}}, instr[31], instr[7], instr[30:25], instr[11:8], 1'b0};
wire [31:0] Uimm = {instr[31:12], 12'b0};
wire [31:0] Jimm = {{11{instr[31]}}, instr[31], instr[19:12], instr[20], instr[30:21], 1'b0};
// Register file
// Initialize register file (x0 always zero)
reg [31:0] rf [0:31]; //Register file
integer i;
initial begin
for (i = 0; i < 32; i = i + 1) begin
rf[i] = 32'b0;
end
end
// Read ports
wire [31:0] rs1_val = (rs1 != 0) ? rf[rs1] : 32'b0;
wire [31:0] rs2_val = (rs2 != 0) ? rf[rs2] : 32'b0;
// Instruction decoding
wire isADDI = (opcode == 7'b0010011) && (funct3 == 3'b000);
wire isADD = (opcode == 7'b0110011) && (funct3 == 3'b000) && (funct7 == 7'b0000000);
// Branch instructions
wire isBEQ = (isBType) && (funct3 == 3'b000);
wire isBNE = (isBType) && (funct3 == 3'b001);
wire isBLT = (isBType) && (funct3 == 3'b100);
wire isBGE = (isBType) && (funct3 == 3'b101);
wire isBLTU = (isBType) && (funct3 == 3'b110);
wire isBGEU = (isBType) && (funct3 == 3'b111);
//store load instructions
wire isLB = (isIType) && (funct3 == 3'b000);
wire isLH = (isIType) && (funct3 == 3'b001);
wire isLW = (opcode == 7'b0000011) && (funct3 == 3'b010);
wire isLBU = (isIType) && (funct3 == 3'b100);
wire isLHU = (isIType) && (funct3 == 3'b101);
wire isSB = (isSType) && (funct3 == 3'b000);
wire isSH = (isSType) && (funct3 == 3'b001);
wire isSW = (opcode == 7'b0100011) && (funct3 == 3'b010);
//sl and sr instructions
wire isSLT = (isRType) && (funct3 == 3'b010) && (funct7[5] == 1'b0);
wire isSLTU = (isRType) && (funct3 == 3'b011) && (funct7[5] == 1'b0);
wire isSLL = (opcode == 7'b0110011) && (funct3 == 3'b001) && (funct7 == 7'b0000000);
wire isSLTI = (isIType) && (funct3 == 3'b010);
wire isSLTIU = (isIType) && (funct3 == 3'b011);
wire isSRL = (opcode == 7'b0110011) && (funct3 == 3'b101) && (funct7 == 7'b0000000);
wire isSRA = (opcode == 7'b0110011) && (funct3 == 3'b101) && (funct7 == 7'b0100000);
wire isSLLI = (opcode == 7'b0010011) && (funct3 == 3'b001) && (funct7[6:1] == 6'b000000);
wire isSRLI = (opcode == 7'b0010011) && (funct3 == 3'b101) && (funct7[6:1] == 6'b000000);
wire isSRAI = (opcode == 7'b0010011) && (funct3 == 3'b101) && (funct7[6:1] == 6'b010000);
//logic imms
wire isANDI = (opcode == 7'b0010011) && (funct3 == 3'b111);
wire isORI = (opcode == 7'b0010011) && (funct3 == 3'b110);
wire isXORI = (opcode == 7'b0010011) && (funct3 == 3'b100);
// logic
wire isAND = (opcode == 7'b0110011) && (funct3 == 3'b111) && (funct7 == 7'b0000000);
wire isOR = (opcode == 7'b0110011) && (funct3 == 3'b110) && (funct7 == 7'b0000000);
wire isXOR = (opcode == 7'b0110011) && (funct3 == 3'b100) && (funct7 == 7'b0000000);
wire isSUB = (opcode == 7'b0110011) && (funct3 == 3'b000) && (funct7 == 7'b0100000);
//lui auipc (opcode use)
wire isLUI = (opcode == 7'b0110111);
wire isAUIPC = (opcode == 7'b0010111);
wire isJAL = (opcode == 7'b1101111);
//jal UType
wire isJALR = (opcode == 7'b1100111) && (funct3 == 3'b000);
//Mem address calculation
wire [31:0] mem_addr = (is_mem_op) ? alu_result : 32'b0;
//Mem address logic
//For simplicity we only implement all loads as word loads (lw)
//byte/halfword ignored
wire is_load = (opcode == 7'b0000011); // All load instructions
wire is_store = (opcode == 7'b0100011); // All store instructions
wire is_mem_op = is_store || is_load;
//Load operations
reg [31:0] load_data;
always @(*) begin
if (mem_addr[1:0] == 2'b00) begin
case (funct3)
3'b000: load_data = {{24{ld_data[7]}}, ld_data[7:0]};
3'b001: load_data = {{16{ld_data[15]}}, ld_data[15:0]};
3'b010: load_data = ld_data;
3'b100: load_data = {24'b0, ld_data[7:0]};
3'b101: load_data = {16'b0, ld_data[15:0]};
default: load_data = 32'b0;
endcase
end else begin
load_data = 32'b0;
if (is_load) begin // Only show error for actual loads
$display("ERROR: Misaligned memory address at addr %h", mem_addr);
end
end
end
//Store operations
always @(*) begin
if (!rst && is_store && (word_addr < 32) && (mem_addr[1:0] == 2'b00)) begin
case (funct3)
3'b000: begin //SB: store byte 0
dmem[word_addr][7:0] = rs2_val[7:0];
end
3'b001: begin //SH: store halfword
dmem[word_addr][15:0] = rs2_val[15:0];
end
3'b010: begin //SW: store word
dmem[word_addr] = rs2_val;
end
endcase
$display("MEM Write: word_addr=%h, data=%h", word_addr, rs2_val);
end
end
// ALU operations
//sltu and slt
wire [31:0] sltu_rslt = {31'b0, (rs1_val < rs2_val)};
wire [31:0] signed_slt = (rs1_val[31] && !rs2_val[31]) ? 1'b1 :
(!rs1_val[31] && rs2_val[31]) ? 1'b0 :
(rs1_val < rs2_val);
wire [31:0] slt_rslt = {31'b0, signed_slt};
wire [31:0] slti_rslt = ((rs1_val[31] == Iimm[31]) ? sltu_rslt : {31'b0, rs1_val[31]});
wire [63:0] SErs1_val = {{32{rs1_val[31]}}, (rs1_val < rs2_val)};
wire [63:0] sra_rslt = {SErs1_val >> rs2_val[4:0]};
wire [63:0] srai_rslt = {SErs1_val >> Iimm[4:0]};
wire [31:0] sltiu_rslt = {31'b0, (rs1_val < Iimm)};
wire [31:0] alu_result = (is_mem_op) ? (rs1_val + Iimm) : // Mem address computation
(isADDI) ? (rs1_val + Iimm) :
(isADD) ? (rs1_val + rs2_val) :
(isSLT) ? slt_rslt :
(isSLTU) ? sltu_rslt :
(isSLTI) ? slti_rslt :
(isANDI) ? (rs1_val & Iimm) :
(isORI) ? (rs1_val | Iimm) :
(isXORI) ? (rs1_val ^ Iimm) :
(isSLLI) ? (rs1_val << Iimm[4:0]) :
(isSRLI) ? (rs1_val >> Iimm[4:0]) :
(isAND) ? (rs1_val & rs2_val) :
(isOR) ? (rs1_val | rs2_val) :
(isXOR) ? (rs1_val ^ rs2_val) :
(isSUB) ? (rs1_val - rs2_val) :
(isSLL) ? (rs1_val << rs2_val[4:0]) :
(isSRL) ? (rs1_val >> rs2_val[4:0]) :
(isSLTIU) ? (sltiu_rslt) :
(isLUI) ? ({Iimm[31:12], 12'b0}) :
(isAUIPC) ? (pc + Iimm) :
(isJAL || isJALR) ? (pc + 32'd4) :
(isSRA) ? (sra_rslt[31:0]) :
(isSRAI) ? (srai_rslt[31:0]) :
32'b0;
wire signed [31:0] signed_rs1 = rs1_val;
wire signed [31:0] signed_rs2 = rs2_val;
wire branch_taken =
isBEQ ? (rs1_val == rs2_val) :
isBNE ? (rs1_val != rs2_val) :
isBLT ? (signed_rs1 < signed_rs2) :
isBGE ? (signed_rs1 >= signed_rs2) :
isBLTU ? (rs1_val < rs2_val) :
isBGEU ? (rs1_val >= rs2_val) :
1'b0;
// Next PC calculation - FIXED: using wire for continuous assignment
wire [31:0] branch_target = pc + Bimm;
wire [31:0] next_pc_base = pc + 32'h4;
wire [31:0] jalr_tgt_pc = rs1_val + Iimm;
assign next_pc = branch_taken ? branch_target :
isJAL ? branch_target :
isJALR ? jalr_tgt_pc :
next_pc_base;
// Register write back
wire rf_write_enable = (rd != 0) && (
isADDI || isADD || isSUB ||
isJAL || isJALR ||
isSLT || isSLTU || isSLTI || isSLTIU ||
isSLL || isSRL || isSRA || isSLLI || isSRLI || isSRAI ||
isLB || isLH || isLW || isLBU || isLHU ||
isXORI || isORI || isANDI ||
isXOR || isOR || isAND ||
is_load || isLUI || isAUIPC
);
wire [31:0] writeback_data = is_load ? load_data : alu_result;
// PC update
always @(posedge clk) begin
if (rst) begin
pc <= 32'h0;
end else begin
pc <= next_pc;
end
end
// Register write back
always @(posedge clk) begin
if (rf_write_enable && !rst) begin
rf[rd] <= writeback_data; // Use writeback_data instead of alu_result
$display("RF Write: x%d = %h", rd, writeback_data);
end
end
// Debug monitoring
always @(posedge clk) begin
if (!rst) begin
$display("PC=%08h, Instr=%08h, rs1=x%d(%h), rs2=x%d(%h), rd=x%d, branch_taken=%b",
pc, instr, rs1, rs1_val, rs2, rs2_val, rd, branch_taken);
if (pc[1:0] != 2'b00) begin
$display("WARNING: PC not word-aligned: %h", pc);
end
end
end
always @(posedge clk) begin
if (!rst && (opcode == 7'b0000011)) begin
$display("LOAD: byte_addr=%h, word_addr=%h, data=%h, funct3=%b",
mem_addr, word_addr, load_data, funct3);
end
end
endmodule

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@@ -0,0 +1,55 @@
module RISCCore_tb;
reg clk;
reg rst;
wire [31:0] pc;
wire [31:0] next_pc;
wire [31:0] instr;
// Instantiate the RISC-V core
RISCCore uut (
.rst(rst),
.clk(clk),
.pc(pc),
.next_pc(next_pc),
.instr(instr)
);
// Clock generation
always #5 clk = ~clk;
// Test sequence
initial begin
// Initialize signals
clk = 0;
rst = 1;
// Apply reset
#10 rst = 0;
// Run for 100 clock cycles
#1000;
// Display final register values
$display("\n=== Final Register Values ===");
for (integer i = 0; i < 32; i = i + 1) begin
if (uut.rf[i] != 0) begin
$display("x%d = %h", i, uut.rf[i]);
end
end
// Display final memory contents
$display("\n=== Final Memory Contents ===");
for (integer i = 0; i < 32; i = i + 1) begin
if (uut.dmem[i] != 0) begin
$display("Mem[%d] = %h", i, uut.dmem[i]);
end
end
$finish;
end
// Monitor important signals
initial begin
$monitor("Time=%0t, PC=%h, Instr=%h", $time, pc, instr);
end
endmodule

62
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@@ -0,0 +1,62 @@
`timescale 1ns/1ps
module RISCCore_tb;
reg clk;
reg rst;
wire [31:0] pc;
wire [31:0] next_pc;
wire [31:0] instr;
// Instantiate the RISC-V core
RISCCore uut (
.rst(rst),
.clk(clk),
.pc(pc),
.next_pc(next_pc),
.instr(instr)
);
// Clock generation
always #5 clk = ~clk;
// Initialize signals
initial begin
clk = 0;
rst = 1;
// Reset sequence
#10 rst = 0;
// Run for enough clock cycles
#500;
// Display final register values
$display("\n=== FINAL REGISTER STATE ===");
$display("x1 (ra) = %h", uut.rf[1]);
$display("x2 (sp) = %h", uut.rf[2]);
$display("x3 (gp) = %h", uut.rf[3]);
$display("x4 (tp) = %h", uut.rf[4]);
$display("x5 (t0) = %h", uut.rf[5]);
$display("x6 (t1) = %h", uut.rf[6]);
$display("x7 (t2) = %h", uut.rf[7]);
$display("x8 (s0) = %h", uut.rf[8]);
$display("x10 (a0) = %h", uut.rf[10]);
// Display memory contents
$display("\n=== MEMORY STATE ===");
begin : memory_display
integer i;
for (i = 0; i < 10; i = i + 1) begin
$display("mem[%0d] = %h", i, uut.dmem[i]);
end
end
$finish;
end
// Simple monitor
initial begin
$monitor("Time=%0t: PC=%h, Instr=%h", $time, uut.pc, uut.instr);
end
endmodule

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@@ -0,0 +1,287 @@
module RISCCore (
input rst,
input clk,
output reg [31:0] pc,
output wire [31:0] next_pc, // Changed to wire
output wire [31:0] instr
);
// IMem - reduced size for simplicity
reg [31:0] imem [0:63];
initial begin
$readmemh("program.hex", imem);
end
assign instr = (pc[31:2] < 64) ? imem[pc[31:2]] : 32'h00000013; // Word-aligned access
//Data Mem
reg [31:0] dmem [0:31];
wire [31:0] ld_data;
wire [4:0] word_addr = mem_addr[6:2];
integer j;
initial begin
for(j = 0; j < 32; j = j + 1) begin
dmem[j] = 32'b0;
end
end
assign ld_data = (word_addr < 32) ? dmem[word_addr] : 32'b0;
// Instruction decoder
wire [6:0] opcode = instr[6:0];
wire [4:0] rs1 = instr[19:15];
wire [4:0] rs2 = instr[24:20];
wire [4:0] rd = instr[11:7];
wire [2:0] funct3 = instr[14:12];
wire [6:0] funct7 = instr[31:25];
// Instruction type detection
wire isUType = (opcode == 7'b0110111) || (opcode == 7'b0010111); // LUI, AUIPC
wire isIType = (opcode == 7'b0000011) || (opcode == 7'b0000111) || // LOAD
(opcode == 7'b0010011) || (opcode == 7'b0011011) || // OP-IMM
(opcode == 7'b1100111); // JALR
wire isRType = (opcode == 7'b0110011) || (opcode == 7'b0111011); // OP
wire isSType = (opcode == 7'b0100011) || (opcode == 7'b0100111); // STORE
wire isBType = (opcode == 7'b1100011); // BRANCH
wire isJType = (opcode == 7'b1101111); // JAL
// Immediate generation
wire [31:0] Iimm = {{20{instr[31]}}, instr[31:20]};
wire [31:0] Simm = {{20{instr[31]}}, instr[31:25], instr[11:7]};
wire [31:0] Bimm = {{19{instr[31]}}, instr[31], instr[7], instr[30:25], instr[11:8], 1'b0};
wire [31:0] Uimm = {instr[31:12], 12'b0};
wire [31:0] Jimm = {{11{instr[31]}}, instr[31], instr[19:12], instr[20], instr[30:21], 1'b0};
// Register file
// Initialize register file (x0 always zero)
reg [31:0] rf [0:31]; //Register file
integer i;
initial begin
for (i = 0; i < 32; i = i + 1) begin
rf[i] = 32'b0;
end
end
// Read ports
wire [31:0] rs1_val = (rs1 != 0) ? rf[rs1] : 32'b0;
wire [31:0] rs2_val = (rs2 != 0) ? rf[rs2] : 32'b0;
// Instruction decoding
wire isADDI = (opcode == 7'b0010011) && (funct3 == 3'b000);
wire isADD = (opcode == 7'b0110011) && (funct3 == 3'b000) && (funct7 == 7'b0000000);
// Branch instructions
wire isBEQ = (isBType) && (funct3 == 3'b000);
wire isBNE = (isBType) && (funct3 == 3'b001);
wire isBLT = (isBType) && (funct3 == 3'b100);
wire isBGE = (isBType) && (funct3 == 3'b101);
wire isBLTU = (isBType) && (funct3 == 3'b110);
wire isBGEU = (isBType) && (funct3 == 3'b111);
//store load instructions
wire isLB = (isIType) && (funct3 == 3'b000);
wire isLH = (isIType) && (funct3 == 3'b001);
wire isLW = (opcode == 7'b0000011) && (funct3 == 3'b010);
wire isLBU = (isIType) && (funct3 == 3'b100);
wire isLHU = (isIType) && (funct3 == 3'b101);
wire isSB = (isSType) && (funct3 == 3'b000);
wire isSH = (isSType) && (funct3 == 3'b001);
wire isSW = (opcode == 7'b0100011) && (funct3 == 3'b010);
//sl and sr instructions
wire isSLT = (isRType) && (funct3 == 3'b010) && (funct7[5] == 1'b0);
wire isSLTU = (isRType) && (funct3 == 3'b011) && (funct7[5] == 1'b0);
wire isSLL = (opcode == 7'b0110011) && (funct3 == 3'b001) && (funct7 == 7'b0000000);
wire isSLTI = (isIType) && (funct3 == 3'b010);
wire isSLTIU = (isIType) && (funct3 == 3'b011);
wire isSRL = (opcode == 7'b0110011) && (funct3 == 3'b101) && (funct7 == 7'b0000000);
wire isSRA = (opcode == 7'b0110011) && (funct3 == 3'b101) && (funct7 == 7'b0100000);
wire isSLLI = (opcode == 7'b0010011) && (funct3 == 3'b001) && (funct7[6:1] == 6'b000000);
wire isSRLI = (opcode == 7'b0010011) && (funct3 == 3'b101) && (funct7[6:1] == 6'b000000);
wire isSRAI = (opcode == 7'b0010011) && (funct3 == 3'b101) && (funct7[6:1] == 6'b010000);
//logic imms
wire isANDI = (opcode == 7'b0010011) && (funct3 == 3'b111);
wire isORI = (opcode == 7'b0010011) && (funct3 == 3'b110);
wire isXORI = (opcode == 7'b0010011) && (funct3 == 3'b100);
// logic
wire isAND = (opcode == 7'b0110011) && (funct3 == 3'b111) && (funct7 == 7'b0000000);
wire isOR = (opcode == 7'b0110011) && (funct3 == 3'b110) && (funct7 == 7'b0000000);
wire isXOR = (opcode == 7'b0110011) && (funct3 == 3'b100) && (funct7 == 7'b0000000);
wire isSUB = (opcode == 7'b0110011) && (funct3 == 3'b000) && (funct7 == 7'b0100000);
//lui auipc (opcode use)
wire isLUI = (opcode == 7'b0110111);
wire isAUIPC = (opcode == 7'b0010111);
wire isJAL = (opcode == 7'b1101111);
//jal UType
wire isJALR = (opcode == 7'b1100111) && (funct3 == 3'b000);
//Mem address calculation
wire [31:0] mem_addr = alu_result;
//Mem address logic
//For simplicity we only implement all loads as word loads (lw)
//byte/halfword ignored
wire is_load = (opcode == 7'b0000011); // All load instructions
wire is_store = (opcode == 7'b0100011); // All store instructions
wire is_mem_op = is_store || is_load;
//Load operations
reg [31:0] load_data;
always @(*) begin
if (mem_addr[1:0] == 2'b00) begin
case (funct3)
3'b000: load_data = {{24{ld_data[7]}}, ld_data[7:0]}; //LB sign-extended byte 0
3'b001: load_data = {{16{ld_data[15]}}, ld_data[15:0]}; //LH sign-extended halfword
3'b010: load_data = ld_data; //LW full word
3'b100: load_data = {24'b0, ld_data[7:0]}; //LBU zero-extended byte 0
3'b101: load_data = {16'b0, ld_data[15:0]}; // LHU zero-extended halfword
default: load_data = 32'b0;
endcase
end else begin
load_data = 32'b0; // Misaligned access not supported
$display("ERROR: Misaligned memory address at addr %h", mem_addr);
end
end
//Store operations
always @(posedge clk) begin
if (!rst && (word_addr < 32) && (mem_addr[1:0] == 2'b00)) begin
case (funct3)
3'b000: begin //SB: store byte 0
dmem[word_addr][7:0] <= rs2_val[7:0];
end
3'b001: begin //SH: store halfword
dmem[word_addr][15:0] <= rs2_val[15:0];
end
3'b010: begin //SW: store word
dmem[word_addr] <= rs2_val;
end
endcase
$display("MEM Write: word_addr=%h, data=%h", word_addr, rs2_val);
end
end
// ALU operations
//sltu and slt
wire [31:0] sltu_rslt = {31'b0, (rs1_val < rs2_val)};
wire [31:0] signed_slt = (rs1_val[31] && !rs2_val[31]) ? 1'b1 :
(!rs1_val[31] && rs2_val[31]) ? 1'b0 :
(rs1_val < rs2_val);
wire [31:0] slt_rslt = {31'b0, signed_slt};
wire [31:0] slti_rslt = ((rs1_val[31] == Iimm[31]) ? sltu_rslt : {31'b0, rs1_val[31]});
wire [63:0] SErs1_val = {{32{rs1_val[31]}}, (rs1_val < rs2_val)};
wire [63:0] sra_rslt = {SErs1_val >> rs2_val[4:0]};
wire [63:0] srai_rslt = {SErs1_val >> Iimm[4:0]};
wire [31:0] sltiu_rslt = {31'b0, (rs1_val < Iimm)};
wire [31:0] alu_result = (is_mem_op) ? (rs1_val + Iimm) & 32'hFFFFFFFC : // Mem address computation (force word alignment)
(isADDI) ? (rs1_val + Iimm) :
(isADD) ? (rs1_val + rs2_val) :
(isSLT) ? slt_rslt :
(isSLTU) ? sltu_rslt :
(isSRA) ? sra_rslt :
(isSRAI) ? srai_rslt :
(isSLTI) ? slti_rslt :
(isANDI) ? (rs1_val & Iimm) :
(isORI) ? (rs1_val | Iimm) :
(isXORI) ? (rs1_val ^ Iimm) :
(isSLLI) ? (rs1_val << Iimm[4:0]) :
(isSRLI) ? (rs1_val >> Iimm[4:0]) :
(isAND) ? (rs1_val & rs2_val) :
(isOR) ? (rs1_val | rs2_val) :
(isXOR) ? (rs1_val ^ rs2_val) :
(isSUB) ? (rs1_val - rs2_val) :
(isSLL) ? (rs1_val << rs2_val[4:0]) :
(isSRL) ? (rs1_val >> rs2_val[4:0]) :
(isSLTIU) ? (sltiu_rslt) :
(isLUI) ? ({Iimm[31:12], 12'b0}) :
(isAUIPC) ? (pc + Iimm) :
(isJAL || isJALR) ? (pc + 32'd4) :
(isSRA) ? (sra_rslt[31:0]) :
(isSRAI) ? (srai_rslt[31:0]) :
(is_load) ? (load_data) : //For register writeback
32'b0;
wire signed [31:0] signed_rs1 = rs1_val;
wire signed [31:0] signed_rs2 = rs2_val;
wire branch_taken =
isBEQ ? (rs1_val == rs2_val) :
isBNE ? (rs1_val != rs2_val) :
isBLT ? (signed_rs1 < signed_rs2) :
isBGE ? (signed_rs1 >= signed_rs2) :
isBLTU ? (rs1_val < rs2_val) :
isBGEU ? (rs1_val >= rs2_val) :
1'b0;
// Next PC calculation - FIXED: using wire for continuous assignment
wire [31:0] branch_target = pc + Bimm;
wire [31:0] next_pc_base = pc + 32'h4;
wire [31:0] jalr_tgt_pc = rs1_val + Iimm;
assign next_pc = branch_taken ? branch_target :
isJAL ? branch_target :
isJALR ? jalr_tgt_pc :
next_pc_base;
// Register write back
wire rf_write_enable = (rd != 0) && (
isADDI || isADD || isSUB ||
isJAL || isJALR ||
isSLT || isSLTU || isSLTI || isSLTIU ||
isSLL || isSRL || isSRA || isSLLI || isSRLI || isSRAI ||
isLB || isLH || isLW || isLBU || isLHU ||
isXORI || isORI || isANDI ||
isXOR || isOR || isAND ||
is_load || isLUI || isAUIPC
);
wire [31:0] writeback_data = is_load ? load_data : alu_result;
// PC update
always @(posedge clk) begin
if (rst) begin
pc <= 32'h0;
end else begin
pc <= next_pc;
end
end
// Register write back
always @(posedge clk) begin
if (rf_write_enable && !rst) begin
rf[rd] <= writeback_data; // Use writeback_data instead of alu_result
$display("RF Write: x%d = %h", rd, writeback_data);
end
end
// Debug monitoring
always @(posedge clk) begin
if (!rst) begin
$display("PC=%08h, Instr=%08h, rs1=x%d(%h), rs2=x%d(%h), rd=x%d, branch_taken=%b",
pc, instr, rs1, rs1_val, rs2, rs2_val, rd, branch_taken);
if (pc[1:0] != 2'b00) begin
$display("WARNING: PC not word-aligned: %h", pc);
end
end
end
always @(posedge clk) begin
if (!rst && (opcode == 7'b0000011)) begin
$display("LOAD: byte_addr=%h, word_addr=%h, data=%h, funct3=%b",
mem_addr, word_addr, load_data, funct3);
end
end
endmodule

130
chapter5/RISCcore2.v
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@@ -11,7 +11,16 @@ module RISCcore2 (
initial begin
$readmemh("program.hex", imem);
end
assign instr = imem[pc[31:2]]; // Word-aligned access
assign instr = (pc[31:2] < 64) ? imem[pc[31:2]] : 32'h00000013; // Word-aligned access
//Data Mem
reg [31:0] dmem [0:63];
integer j;
initial begin
for(j = 0; j < 64; j = j + 1) begin
dmem[j] = 32'b0;
end
end
// Instruction decoder
wire [6:0] opcode = instr[6:0];
@@ -39,9 +48,7 @@ module RISCcore2 (
wire [31:0] Jimm = {{11{instr[31]}}, instr[31], instr[19:12], instr[20], instr[30:21], 1'b0};
// Register file
reg [31:0] rf [0:31];
// Initialize register file (x0 always zero)
// Initialize register file (x0 always zero)
integer i;
initial begin
for (i = 0; i < 32; i = i + 1) begin
@@ -109,7 +116,58 @@ module RISCcore2 (
wire isJALR = (opcode == 7'b1100111) && (funct3 == 3'b000);
//Mem address calculation
wire [31:0] mem_addr = alu_result;
wire [31:0] word_addr = mem_addr[31:2];
//Mem address logic
//For simplicity we only implement all loads as word loads (lw)
//byte/halfword ignored
wire is_load = (opcode == 7'b0000011); // All load instructions
wire is_store = (opcode == 7'b0100011); // All store instructions
wire is_mem_op = is_store || is_load;
assign loaded_data = (mem_addr[31:2] < 64) ? dmem[mem_addr[31:2]] : 32'b0;
reg [31:0] load_data;
always @(*) begin
if (mem_addr[1:0] == 2'b00) begin
case (funct3)
3'b000: load_data = {{24{loaded_data[7]}}, loaded_data[7:0]}; //LB sign-extended byte 0
3'b001: load_data = {{16{loaded_data[15]}}, loaded_data[15:0]}; //LH sign-extended halfword
3'b010: load_data = loaded_data; //LW full word
3'b100: load_data = {24'b0, loaded_data[7:0]}; //LBU zero-extended byte 0
3'b101: load_data = {16'b0, loaded_data[15:0]}; // LHU zero-extended halfword
default: load_data = 32'b0;
endcase
end else begin
load_data = 32'b0; // Misaligned access not supported
$display("ERROR: Misaligned memory address at addr %h", mem_addr);
end
end
//Store operations
always @(posedge clk) begin
if (!rst && (word_addr < 64) && (mem_addr[1:0] == 2'b00)) begin
case (funct3)
3'b000: begin //SB: store byte 0
dmem[word_addr][7:0] <= rs2_val[7:0];
end
3'b001: begin //SH: store halfword
dmem[word_addr][15:0] <= rs2_val[15:0];
end
3'b010: begin //SW: store word
dmem[word_addr] <= rs2_val;
end
endcase
$display("MEM Write: word_addr=%h, data=%h", word_addr, rs2_val);
end
end
// ALU operations
//sltu and slt
wire [31:0] sltu_rslt = {31'b0, (rs1_val < rs2_val)};
wire [31:0] signed_slt = (rs1_val[31] && !rs2_val[31]) ? 1'b1 :
@@ -124,7 +182,8 @@ module RISCcore2 (
wire [63:0] srai_rslt = {SErs1_val >> Iimm[4:0]};
wire [31:0] sltiu_rslt = {31'b0, (rs1_val < Iimm)};
wire [31:0] alu_result = (isADDI) ? (rs1_val + Iimm) :
wire [31:0] alu_result = (is_mem_op) ? (rs1_val + Iimm) : //Mem address computation first
(isADDI) ? (rs1_val + Iimm) :
(isADD) ? (rs1_val + rs2_val) :
(isSLT) ? slt_rslt :
(isSLTU) ? sltu_rslt :
@@ -145,13 +204,13 @@ module RISCcore2 (
(isSLTIU) ? (sltiu_rslt) :
(isLUI) ? ({Iimm[31:12], 12'b0}) :
(isAUIPC) ? (pc + Iimm) :
(isJAL) ? (pc + 32'd4) :
(isJALR) ? (pc + 32'd4) :
(isJAL || isJALR) ? (pc + 32'd4) :
(isSRA) ? (sra_rslt[31:0]) :
(isSRAI) ? (srai_rslt[31:0]) :
(isSRAI) ? (srai_rslt[31:0]) :
(is_load) ? (load_data) : //For register writeback
32'b0;
// Branch condition logic
wire signed [31:0] signed_rs1 = rs1_val;
wire signed [31:0] signed_rs2 = rs2_val;
@@ -164,14 +223,42 @@ module RISCcore2 (
isBGEU ? (rs1_val >= rs2_val) :
1'b0;
// Store operations
always @(posedge clk) begin
if(!rst) begin
if (is_store && (mem_addr[31:2] < 64)) begin
dmem[mem_addr[31:2]] <= rs2_val;
$display("MEM Write: address = %h, data=%h", mem_addr, rs2_val);
end
end
end
// Next PC calculation - FIXED: using wire for continuous assignment
wire [31:0] branch_target = pc + Bimm;
wire [31:0] next_pc_base = pc + 32'h4;
assign next_pc = branch_taken ? branch_target : next_pc_base;
wire [31:0] jalr_tgt_pc = rs1_val + Iimm;
assign next_pc = branch_taken ? branch_target :
isJAL ? branch_target :
isJALR ? jalr_tgt_pc :
next_pc_base;
// Register write back
wire rf_write_enable = (rd != 0) && (isADDI || isADD);
wire [31:0] writeback_data = alu_result;
wire rf_write_enable = (rd != 0) && (
isADDI || isADD || isSUB ||
isJAL || isJALR ||
isSLT || isSLTU || isSLTI || isSLTIU ||
isSLL || isSRL || isSRA || isSLLI || isSRLI || isSRAI ||
isLB || isLH || isLW || isLBU || isLHU ||
isXORI || isORI || isANDI ||
isXOR || isOR || isAND ||
is_load || isLUI || isAUIPC
);
wire [31:0] writeback_data = is_load ? load_data : alu_result;
// PC update
always @(posedge clk) begin
@@ -183,14 +270,14 @@ module RISCcore2 (
end
// Register write back
always @(posedge clk) begin
if (rf_write_enable && !rst) begin
rf[rd] <= writeback_data;
$display("RF Write: x%d = %h", rd, writeback_data);
end
always @(posedge clk) begin
if (rf_write_enable && !rst) begin
rf[rd] <= writeback_data; // Use writeback_data instead of alu_result
$display("RF Write: x%d = %h", rd, writeback_data);
end
end
// Debug monitoring
// Debug monitoring
always @(posedge clk) begin
if (!rst) begin
$display("PC=%08h, Instr=%08h, rs1=x%d(%h), rs2=x%d(%h), rd=x%d, branch_taken=%b",
@@ -200,5 +287,12 @@ module RISCcore2 (
end
end
end
always @(posedge clk) begin
if (!rst && (opcode == 7'b0000011)) begin
$display("LOAD: byte_addr=%h, word_addr=%h, data=%h, funct3=%b",
mem_addr, word_addr, load_data, funct3);
end
end
endmodule

27
chapter5/program.hex
View File

@@ -1,15 +1,12 @@
00100093 // addi x1, x0, 1 (x1 = 1)
00200113 // addi x2, x0, 2 (x2 = 2)
00300193 // addi x3, x0, 3 (x3 = 3)
00400213 // addi x4, x0, 4 (x4 = 4)
00500293 // addi x5, x0, 5 (x5 = 5)
00600313 // addi x6, x0, 6 (x6 = 6)
00700393 // addi x7, x0, 7 (x7 = 7)
00800413 // addi x8, x0, 8 (x8 = 8)
00900493 // addi x9, x0, 9 (x9 = 9)
00510233 // add x4, x2, x5 (x4 = 2+3=5)
00620333 // add x6, x4, x6 (x6 = 5+6=11)
007303b3 // add x7, x6, x7 (x7 = 11+7=18)
00840433 // add x8, x8, x8 (x8 = 8+8=16)
009484b3 // add x9, x9, x9 (x9 = 9+9=18)
0000006f // jal x0, 0 (infinite loop)
00000093 // addi x1, x0, 0 - x1 = 0
00100113 // addi x2, x0, 1 - x2 = 1
00200193 // addi x3, x0, 2 - x3 = 2
003081b3 // add x3, x1, x3 - x3 = 0 + 2 = 2
00420233 // add x4, x4, x4 - x4 = x4 + x4 (should be 0)
00228463 // beq x5, x2, 8 - branch if x5 == x2 (should not take)
00400463 // beq x0, x4, 8 - branch if 0 == 0 (should take)
00a00513 // addi x10, x0, 10 - x10 = 10 (should be skipped)
fff00513 // addi x10, x0, -1 - x10 = -1 (should execute)
00000013 // nop
00000013 // nop
00000013 // nop

64
chapter5/program0.1.hex Normal file
View File

@@ -0,0 +1,64 @@
00000093 // addi x1, x0, 0 | x1 = 0
00100113 // addi x2, x0, 1 | x2 = 1
002081B3 // add x3, x1, x2 | x3 = x1 + x2 = 1
00400293 // addi x5, x0, 4 | x5 = 4 (memory address)
0051A023 // sw x5, 0(x3) | Store x5 at address x3 (1)
0001A303 // lw x6, 0(x3) | Load from address x3 to x6
00600393 // addi x7, x0, 6 | x7 = 6
40738433 // sub x8, x7, x7 | x8 = x7 - x7 = 0
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop
00000013 // nop

1318
chapter5/risc_tb Executable file
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File diff suppressed because it is too large Load Diff

1815
chapter5/riscv
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File diff suppressed because it is too large Load Diff