verilog实现的16位CPU单周期设计

verilog实现的16位CPU单周期设计

这个工程完成了16位CPU的单周期设计,模块化设计,包含对于关键指令的仿真与设计,有包含必要的分析说明。

单周期CPU结构图

verilog实现的16位CPU单周期设计_第1张图片

单周期CPU设计真值表与结构图

verilog实现的16位CPU单周期设计_第2张图片

该CPU用到的指令集,16位8个通用寄存器

verilog实现的16位CPU单周期设计_第3张图片

设计思路

  1. Instruction Memory:
    输入8位的PC指令,输出对应内存的16位指令
    verilog实现的16位CPU单周期设计_第4张图片

  2. Control Unit
    输入16位的指令,根据真值表,输出对应结果
    verilog实现的16位CPU单周期设计_第5张图片

  3. Register File
    输入三个地址和写入内容,写入信号,输出两个地址对应的内容
    由于单周期内不能一边读一边写,故有一个时钟信号,通过一级缓存,在下一个时钟信号来临时立即写入内存
    verilog实现的16位CPU单周期设计_第6张图片

  4. ALU
    输入运算数和指令,输出运算结果以及标志位
    由于单周期内,标志位并不在当前周期而在下一周期使用,故增加时钟信号,通过一级缓存,在下一个周期时判断使用
    verilog实现的16位CPU单周期设计_第7张图片

  5. Data Memory
    输入一个地址,写入内容和写入信号,输出读取内容
    由于单周期内不能一边读一边写,故有一个时钟信号,通过一级缓存,在下一个时钟信号来临时立即写入内存
    verilog实现的16位CPU单周期设计_第8张图片

  6. PC-NextPC
    根据分支指令,跳转指令和标志位的组合逻辑,决定PC是+1还是到某目标位置
    verilog实现的16位CPU单周期设计_第9张图片

实验结果

RTL图
verilog实现的16位CPU单周期设计_第10张图片

Testbench内容
verilog实现的16位CPU单周期设计_第11张图片

在test中,通过每隔50个ns,时钟取反一次,CPU通过一次时钟的上升沿计算一个周期,通过输出用到的通用寄存器和用到的datamemory里面的变量来观察整个CPU的流程结果,测试CPU是否正确工作

Instruction Memory:
verilog实现的16位CPU单周期设计_第12张图片

指令0:gr1原本初始化时为0,把gr1加上一个立即数18,gr1为18(0012)
指令1:gr2原本初始化时为0,把gr2加上一个高八位1,gr2为256(0100)
指令2:从gr1和gr2中取值相加,结果保存在gr3中,gr3应为274(0112)
指令3:把gr3的值保存到datamemory中的dm0,dm0为274(0112)
指令4:gr1的值为18,减去一个立即数2,gr1为16(0010)
指令5:gr2的值为256,加上一个高八位立即数0,结果不变为256(0100)
指令6:从gr1和gr2中取值相加,结果保存在gr3中,gr3应为272(0110)
指令7:把gr3的值保存到datamemory中的dm1,dm1为272(0110)
指令8:从dm0中取值到gr1中,gr1为274(0112)
指令9:从dm1中取值到gr2中,gr2为272(0110)
指令10:从gr1和gr2中取值相减,结果保存在gr3中,gr3应为2(0002)
指令11:把gr3的值保存到datamemory中的dm2,dm2为2(0002)
指令12:跳转指令,PC跳转到第14条指令
指令13:该指令不被执行,如gr1中出现274+171=445(01BD)则出错
指令14:从gr1和gr2中取值与操作,结果保存在gr3中,gr3应为272(0110)
指令15:把gr3的值保存到datamemory中的dm3,dm3为272(0110)
指令16:把gr1的值置为0
指令17:把gr1的值置为1
指令18:把gr1的值算术左移两位保存在gr3中,gr3为4
指令19:把gr3的值保存到datamemory中的dm4,dm4为4(0004)
指令20:把gr3和gr3相减让ZF标志位为1
指令21:因为ZF标志位为1,所以跳转到指令12,循环执行,如PC的值大于21,则出错

实验结果:
verilog实现的16位CPU单周期设计_第13张图片

结果分析:
1) 指令0~3,测试立即数加法和加法,计算18(0012)+256(0100)=274(0112),得到0112存储在dm0上。√
2) 指令4~7,测试立即数减法和加法,计算18-2(0010)+256(0110)=272(0110),得到0110存储在dm1上。√
3) 指令8~11,测试减法和读取写入,计算274(0112)-272(0110)=2(0002),得到0002存储在dm2上。√
4) 指令12~15,测试跳转指令和位操作指令,PC值从0c跳转到0e把274(100010010)和272(100010000)与操作得到272(1000100010)[0110]存储在dm3上。√
5) 指令16~19,测试移位指令,将1(0001)左移2位得到4(0004)存储在dm4上。√
6) 指令20~21,测试分支指令,cmp指令让两个相同的数相减,bz指令跳转,PC在15->0c->…->15->0c之间循环执行。√

各类指令均取很具有代表性的指令,也测试了较难的指令,结果和预期结果相符。

完整代码

CPU_top.v

`timescale 1ns / 1ps

module CPU_top(
	input CLK,
	input reset,
	output [7:0] OPT_PC
    );
	reg [7:0] PC;
	wire [15:0] Instr;
	wire [2:0] rs;
	wire [2:0] rt;
	wire [2:0] rd;
	wire [15:0] SignImm16;
	wire MemtoReg, MemWrite, Branch, ALUSrc, RegWrite, Jump;
	wire [4:0] ALUControl;
	wire JorB, PCSrc, Flag;
	wire [15:0] RD1_out;
	wire [15:0] RD2_out;
	wire [15:0] SrcA;
	wire [15:0] SrcB;
	wire [15:0] ALUResult;
	wire [15:0] WriteData;
	wire [15:0] ReadData;
	wire [15:0] Result;
	wire [7:0] NextPC;
	wire enable;
	
	initial begin
		PC = 8'b00000000;
	end
	
	InstructionMemory IM(
		.A(PC),
		.RD(Instr)
	);
	
	ControlUnit CU(
		.Instr(Instr),
		.MemtoReg(MemtoReg),
		.MemWrite(MemWrite),
		.Branch(Branch),
		.ALUControl(ALUControl),
		.ALUSrc(ALUSrc),
		.RegWrite(RegWrite),
		.Jump(Jump),
		.enable(enable),
		.rs(rs),
		.rt(rt),
		.rd(rd),
		.SignImm16(SignImm16)
   );
	 
	RegisterFile RF(
		.CLK(CLK),
		.A1(rs),
		.A2(rt),
		.A3(rd),
		.WD3(Result),
		.WE3(RegWrite),
		.RD1(RD1_out),
		.RD2(RD2_out)
   );
	
	assign SrcA = RD1_out;
	assign SrcB = (ALUSrc) ? SignImm16 : RD2_out;
	ALU alu(
		.CLK(CLK),
		.ALUControl(ALUControl),
		.SrcA(SrcA),
		.SrcB(SrcB),
		.ALUResult(ALUResult),
		.Flag(Flag)
   );
	
	assign WriteData = RD2_out;
	DataMemory DM(
		.CLK(CLK),
		.WE(MemWrite),
		.A(ALUResult),
		.WD(WriteData),
		.RD(ReadData)
   );
	assign Result = (MemtoReg) ? ReadData : ALUResult;
	
	assign JorB = ( Jump | Branch );//Jump or Branch,判断当前指令是否需要跳转
	assign PCSrc = ( JorB & Flag );//加上Flag判断跳转是否成立
	assign NextPC = (PCSrc) ? ALUResult[7:0] : (PC + 1'b1);//跳转成立则NextPC为新值,否则加1
	
	always@(posedge CLK)//时序,每个周期PC值变化一次
	begin
		if(reset)
			PC <= 0;
		else
		begin
			if(enable)
				PC <= NextPC;
			else
				PC <= PC;
		end
	end

	assign OPT_PC = PC;
	
endmodule

ControlUnit.v

`timescale 1ns / 1ps
`include"headfile.v"

module ControlUnit(
	input [15:0] Instr,
	output MemtoReg,
	output MemWrite,
	output reg Branch,
	output [4:0] ALUControl,
	output reg ALUSrc,
	output reg RegWrite,
	output Jump,
	output enable,
	output reg [2:0] rs,
	output reg [2:0] rt,
	output [2:0] rd,
	output reg [15:0] SignImm16
    );
	
	wire [4:0] Op;
	assign Op = Instr[15:11];//指令高5位是Op
	
	//Set A1(rs) 根据真值表设置A1的取值位置
	always@(*)
	begin
		if((Op == `BZ)				
		 ||(Op == `BN)				
		 ||(Op == `JMPR)			
		 ||(Op == `BC)				
		 ||(Op == `BNZ)			
		 ||(Op == `BNN)			
		 ||(Op == `BNC)			
		 ||(Op == `ADDI)			
		 ||(Op == `SUBI)			
		 ||(Op == `LDIH))			
			rs <= Instr[10:8];
		else							
			rs <= Instr[6:4];
	end
	
	//Set A2(rt) 根据真值表设置A2的取值位置
	always@(*)
	begin
		if(Op == `STORE)
			rt <= Instr[10:8];
		else
			rt <= Instr[2:0];
	end
	
	//Set A3(rd) 根据真值表设置A3的取值位置
	assign rd = Instr[10:8];

	//Set SignImm16 根据真值表设置立即数的取值位置
	always@(*)	//只要立即数存在,ALUSrc的选择即为立即数1
	begin
		if((Op == `LOAD)
		 ||(Op == `STORE)
		 ||(Op == `SLL)
		 ||(Op == `SRL)
		 ||(Op == `SLA)
		 ||(Op == `SRA))
			begin
				SignImm16 <= { {12{1'b0}}, Instr[3:0]};
				ALUSrc <= 1'b1;
			end
		else if((Op == `ADDI)
		      ||(Op == `SUBI)
				||(Op == `JUMP)
				||(Op == `JMPR)
				||(Op == `BZ)
				||(Op == `BNZ)
				||(Op == `BN)
				||(Op == `BNN)
				||(Op == `BC)
				||(Op == `BNC))
			begin
				SignImm16 <= { {8{1'b0}}, Instr[7:0]};
				ALUSrc <= 1'b1;
			end
		else if(Op == `LDIH)
			begin
				SignImm16 <= {Instr[7:0], {8{1'b0}}};
				ALUSrc <= 1'b1;
			end
		else//其余情况,立即数为空值x,ALUSrc选择不为立即数
			begin
				SignImm16 <= { {16{1'bx}} }; 
				ALUSrc <= 1'b0;
			end
	end
	//ALUControl与Op一致
	assign ALUControl = Op;
	//MemtoReg当且仅当LOAD指令时为1
	assign MemtoReg = (Op == `LOAD);
	//MemWrite当且仅当STORE指令时为1
	assign MemWrite = (Op == `STORE);
	//Jump当指令为跳转类型时为1
	assign Jump = ( (Op == `JUMP) || (Op == `JMPR));
	
	//Set Branch 仅当分支指令时为1
	always@(*)
	begin
		if((Op == `BZ)
		 ||(Op == `BNZ)
		 ||(Op == `BN)
		 ||(Op == `BNN)
		 ||(Op == `BC)
		 ||(Op == `BNC))
			Branch <= 1'b1;
		else
			Branch <= 1'b0;
	end
	
	//Set RegWrite 根据真值表设置RegWrite的取值
	always@(*)
	begin
		if((Op == `LOAD)
		 ||(Op == `LDIH)
		 ||(Op == `ADD)
		 ||(Op == `SUB)
		 ||(Op == `ADDI)
		 ||(Op == `SUBI)
		 ||(Op == `ADDC)
		 ||(Op == `SUBC)
		 ||(Op == `AND)
		 ||(Op == `OR)
		 ||(Op == `XOR)
		 ||(Op == `SLL)
		 ||(Op == `SRL)
		 ||(Op == `SLA)
		 ||(Op == `SRA))
			RegWrite <= 1'b1;
		else
			RegWrite <= 1'b0;
	end
	//遇到终止指令时,关闭CPU
	assign enable = ~(Op == `HALT);
	
endmodule

InstructionMemory.v

`timescale 1ns / 1ps
`include"headfile.v"

module InstructionMemory(
	input [7:0] A,
	output [15:0] RD
    );
	
	reg [15:0] IMmem [29:0];
	assign RD = IMmem[A];//立即根据地址取出内容
	
	initial begin
		IMmem[0] = {`ADDI, `gr1, 4'b0001, 4'b0010};//g1 = 10010 = 18
		IMmem[1] = {`LDIH, `gr2, 4'b0000, 4'b0001};//g2 = 100000000 = 256
		IMmem[2] = {`ADD, `gr3, 1'b0, `gr1, 1'b0, `gr2};//g3 = 100010010 = 274
		IMmem[3] = {`STORE, `gr3, 1'b0, `gr0, 4'b0000};// m0 = 100010010 = 274
		IMmem[4] = {`SUBI, `gr1, 4'b0000, 4'b0010};//g1 = 18 - 2 = 16
		IMmem[5] = {`LDIH, `gr2, 4'b0000, 4'b0000};//g2 = 256
		IMmem[6] = {`ADD, `gr3, 1'b0, `gr1, 1'b0, `gr2};//g3 = 272
		IMmem[7] = {`STORE, `gr3, 1'b0, `gr0, 4'b0001}; // m1 = 272
		IMmem[8] = {`LOAD, `gr1, 1'b0, `gr0, 4'b0000};//g1 = 274
		IMmem[9] = {`LOAD, `gr2, 1'b0, `gr0, 4'b0001};//g2 = 272
		IMmem[10] = {`SUB, `gr3, 1'b0, `gr1, 1'b0, `gr2};//g3 = 2
		IMmem[11] = {`STORE, `gr3, 1'b0, `gr0, 4'b0010};// m2 = 2
		IMmem[12] = {`JUMP, 3'b000, 4'b0000, 4'b1110};// To 14
		IMmem[13] = {`ADDI, `gr1, 4'b1010, 4'b1011};// Not Use
		IMmem[14] = {`AND, `gr3, 1'b0, `gr1, 1'b0, `gr2};//g3 =272 
		IMmem[15] = {`STORE, `gr3, 1'b0, `gr0, 4'b0011};// m3 = 272
		IMmem[16] = {`ADD, `gr1, 1'b0, `gr0, 1'b0, `gr0};//g1 = 0
		IMmem[17] = {`ADDI, `gr1, 4'b0000, 4'b0001};//g1 = 1
		IMmem[18] = {`SLL, `gr3, 1'b0, `gr1, 4'b0010};//g3 = 4
		IMmem[19] = {`STORE, `gr3, 1'b0, `gr0, 4'b0100};// m4 = 4
		IMmem[20] = {`CMP, 3'b000, 1'b0, `gr3, 1'b0, `gr3};//ZF = 1
		IMmem[21] = {`BZ, `gr1, 4'b0000, 4'b1011};// To 12
		IMmem[22] = 16'b0000000000000000;
		IMmem[23] = 16'b0000000000000000;
		IMmem[24] = 16'b0000000000000000;
		IMmem[25] = 16'b0000000000000000;
		IMmem[26] = 16'b0000000000000000;
		IMmem[27] = 16'b0000000000000000;
		IMmem[28] = 16'b0000000000000000;
		IMmem[29] = 16'b0000000000000000;
	end

endmodule

RegisterFile.v

`timescale 1ns / 1ps

module RegisterFile(
	input CLK,
	input [2:0] A1,
	input [2:0] A2,
	input [2:0] A3,
	input [15:0] WD3,
	input WE3,
	output [15:0] RD1,
	output [15:0] RD2
    );
	reg [15:0] RFmem [7:0];
	reg reallWE3; reg [2:0] reallA3; reg [15:0] reallWD3;
	initial begin//初始化8个通用寄存器为0
		reallWE3 = 1'b0;
		RFmem[0] = 16'h0000000000000000;
		RFmem[1] = 16'h0000000000000000;
		RFmem[2] = 16'h0000000000000000;
		RFmem[3] = 16'h0000000000000000;
		RFmem[4] = 16'h0000000000000000;
		RFmem[5] = 16'h0000000000000000;
		RFmem[6] = 16'h0000000000000000;
		RFmem[7] = 16'h0000000000000000;
	end
	//避免对一个寄存器同时读写,一级缓存处理
	always@(posedge CLK)
	begin
		reallWE3 <= WE3;
		reallA3 <= A3;
		reallWD3 <= WD3;
	end
	//有写入内容时直接写入到指定位置
	always@(*)
	begin
		if(reallWE3)
			RFmem[reallA3] <= reallWD3;
	end
	//根据地址直接从寄存器取值
	assign RD1 = RFmem[A1];
	assign RD2 = RFmem[A2];

endmodule

SignExtend.v

`timescale 1ns / 1ps

module SignExtend(
	input [7:0] SignImm8,
	output [15:0] SignImm16
    );

	assign SignImm16 = {{8{SignImm8[7]}}, SignImm8};

endmodule

ALU.v

`timescale 1ns / 1ps
`include"headfile.v"

module ALU(
	input CLK,
	input [4:0] ALUControl,
	input [15:0] SrcA,
	input [15:0] SrcB,
	output reg [15:0] ALUResult,
	output reg Flag
    );
	
	reg CF_temp;
	wire ZF_temp, NF_temp;
	reg ZF, CF, NF;
	
	always@(*)//根据指令内容,对操作数进行不同的运算
	begin
		case(ALUControl)
			`NOP:		ALUResult <= ALUResult;
			`HALT:	ALUResult <= ALUResult;
			`AND:		ALUResult <= ( SrcA & SrcB );
			`OR:		ALUResult <= ( SrcA | SrcB );
			`XOR:		ALUResult <= ( SrcA ^ SrcB );
			`SLL:		ALUResult <= ( SrcA << SrcB );
			`SRL:		ALUResult <= ( SrcA >> SrcB );
			`SLA:		ALUResult <= ( SrcA <<< SrcB );
			`SRA:		ALUResult <= ( SrcA >>> SrcB );
			`JUMP:	ALUResult <= SrcB;//增加一位处理是否溢出设置CF
			`LDIH:	{CF_temp, ALUResult} <= {1'b0, SrcA} + {1'b0, SrcB};
			`ADD:		{CF_temp, ALUResult} <= {1'b0, SrcA} + {1'b0, SrcB};
			`ADDI:	{CF_temp, ALUResult} <= {1'b0, SrcA} + {1'b0, SrcB};
			`ADDC:	ALUResult <= ( SrcA + SrcB + CF_temp);
			`SUB:		ALUResult <= ( SrcA - SrcB );
			`SUBI:	ALUResult <= ( SrcA - SrcB );
			`SUBC:	ALUResult <= ( SrcA - SrcB - CF_temp);
			`CMP:		ALUResult <= ( SrcA - SrcB );
			`LOAD:	ALUResult <= ( SrcA + SrcB );
			`STORE:	ALUResult <= ( SrcA + SrcB );
			`JMPR:	ALUResult <= ( SrcA + SrcB );
			`BZ:		ALUResult <= ( SrcA + SrcB );
			`BNZ:		ALUResult <= ( SrcA + SrcB );
			`BN:		ALUResult <= ( SrcA + SrcB );
			`BNN:		ALUResult <= ( SrcA + SrcB );
			`BC:		ALUResult <= ( SrcA + SrcB );
			`BNC:		ALUResult <= ( SrcA + SrcB );
			default:	ALUResult <= ALUResult;
		endcase
	end
	//结果为0时ZF标志位为1
	assign ZF_temp = (ALUResult == 0);
	//结果高位为1时ZF标志位为1
	assign NF_temp = (ALUResult[15] == 1'b1);
	//CF在运算时已处理
	//assign CF_temp = CF_temp;
	//增加一级缓存,为CMP的下一个周期使用
	always@(posedge CLK)
	begin
		ZF <= ZF_temp;
		CF <= CF_temp;
		NF <= NF_temp;
	end
	
	//Set Flag 根据真值表设置
	always@(*)
	begin
		case(ALUControl)
			`JUMP:	Flag <= 1'b1;//跳转指令恒为1
			`JMPR:	Flag <= 1'b1;
			`BZ:		Flag <= ZF;//根据ZF标志位
			`BNZ:		Flag <= ~ZF;
			`BN:		Flag <= NF;//根据NF标志位
			`BNN:		Flag <= ~NF;
			`BC:		Flag <= CF;//根据CF标志位
			`BNC:		Flag <= ~CF;
			default:	Flag <= 1'b0;//其余为0
		endcase
	end

endmodule

DataMemory.v

`timescale 1ns / 1ps

module DataMemory(
	input CLK,
	input WE,
	input [7:0] A,
	input [15:0] WD,
	output [15:0] RD
    );

	reg [15:0] DMmem [29:0];
	reg reallWE; reg [7:0] reallA; reg [15:0] reallWD;
	initial begin//初始化时全为0
		reallWE = 1'b0;
		DMmem[0] = 16'b0000000000000000;
		DMmem[1] = 16'b0000000000000000;
		DMmem[2] = 16'b0000000000000000;
		DMmem[3] = 16'b0000000000000000;
		DMmem[4] = 16'b0000000000000000;
		DMmem[5] = 16'b0000000000000000;
		DMmem[6] = 16'b0000000000000000;
		DMmem[7] = 16'b0000000000000000;
		DMmem[8] = 16'b0000000000000000;
		DMmem[9] = 16'b0000000000000000;
		DMmem[10] = 16'b0000000000000000;
		DMmem[11] = 16'b0000000000000000;
		DMmem[12] = 16'b0000000000000000;
		DMmem[13] = 16'b0000000000000000;
		DMmem[14] = 16'b0000000000000000;
		DMmem[15] = 16'b0000000000000000;
		DMmem[16] = 16'b0000000000000000;
		DMmem[17] = 16'b0000000000000000;
		DMmem[18] = 16'b0000000000000000;
		DMmem[19] = 16'b0000000000000000;
		DMmem[20] = 16'b0000000000000000;
		DMmem[21] = 16'b0000000000000000;
		DMmem[22] = 16'b0000000000000000;
		DMmem[23] = 16'b0000000000000000;
		DMmem[24] = 16'b0000000000000000;
		DMmem[25] = 16'b0000000000000000;
		DMmem[26] = 16'b0000000000000000;
		DMmem[27] = 16'b0000000000000000;
		DMmem[28] = 16'b0000000000000000;
		DMmem[29] = 16'b0000000000000000;
	end
	//增加一级缓存对应RegisterFile的读写处理
	always@(posedge CLK)
	begin
		reallWE <= WE;
		reallA <= A;
		reallWD <= WD;
	end
	//根据写入地址直接写入
	always@(*)
	begin
		if(reallWE)
			DMmem[reallA] <= reallWD;
	end
	//根据地址直接读取
	assign RD = DMmem[A];

endmodule

headfile.v

`ifndef HEADFILE_H_

//State for CPU
`define	idle		1'b0
`define	exec		1'b1

//Data transfer & Arithmetic
`define  NOP		5'b00000
`define  HALT		5'b00001
`define  LOAD		5'b00010
`define  STORE		5'b00011
`define  LDIH		5'b10000
`define  ADD		5'b01000
`define	ADDI		5'b01001
`define	ADDC		5'b10001
`define	CMP		5'b01100

//Logical / shift
`define	AND		5'b01101
`define	SLL		5'b00100
`define	SLA		5'b00101

//Control
`define	JUMP		5'b11000
`define	JMPR		5'b11001
`define	BZ			5'b11010
`define	BNZ		5'b11011
`define	BN			5'b11100
`define	BC			5'b11110

//Add by myself
`define	SUB   	5'b01010
`define 	SUBI  	5'b01011
`define 	SUBC  	5'b10010
`define 	OR    	5'b01110
`define 	XOR   	5'b01111
`define 	SRL   	5'b00110
`define 	SRA   	5'b00111
`define 	BNN   	5'b11101
`define 	BNC   	5'b11111

//gr
`define gr0 3'b000
`define gr1 3'b001
`define gr2 3'b010
`define gr3 3'b011

`endif

VTF_CPUtop.v

`timescale 1ns / 1ps

module VTF_CPUtop;

	// Inputs
	reg CLK;
	reg reset;
	reg [7:0] OPT_PC;

	// Instantiate the Unit Under Test (UUT)
	CPU_top uut (
		.CLK(CLK),
		.reset(reset),
		.OPT_PC(OPT_PC)
	);

	initial begin
		// Initialize Inputs
		CLK = 0;
		reset = 0;

		// Wait 100 ns for global reset to finish
		//#100;
		$display("pc:     instr      :ALUR: gr1: gr2: gr3: dm0: dm1: dm2: dm3: dm4");
		$monitor("%h:%b:%h:%h:%h:%h:%h:%h:%h:%h:%h", 
			uut.PC, uut.Instr, uut.ALUResult, uut.RF.RFmem[1], uut.RF.RFmem[2], uut.RF.RFmem[3], 
			uut.DM.DMmem[0], uut.DM.DMmem[1], uut.DM.DMmem[2], uut.DM.DMmem[3], uut.DM.DMmem[4] );
        
		// Add stimulus here
		
		
	end
	
	always #50 CLK = ~CLK;
      
endmodule

后寄语:只有辛苦过,才有资格吐槽,才知道该如何去改进,才知道架构师与码农之间的区别。

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