Verilog例子整理(转载)

【例5.6 】用fork-join 并行块产生信号波形

`timescale 10ns/1ns 
module wave2; 
reg wave; 
parameter cycle=5; 
initial

fork

wave=0;
#(cycle) wave=1;
#(2*cycle) wave=0;
#(3*cycle) wave=1;
#(4*cycle) wave=0;
#(5*cycle) wave=1;
#(6*cycle) $finish;


join 
initial $monitor($time,,,"wave=%b",wave); 
endmodule

【例5.7 】持续赋值方式定义的2 选1 多路选择器

module MUX21_1(out,a,b,sel);
input a,b,sel;
output out;
assign out=(sel==0)?a:b;


//持续赋值,如果sel为0,则out=a ;否则out=b

endmodule

【例5.8 】阻塞赋值方式定义的2 选1 多路选择器

module MUX21_2(out,a,b,sel); 
input a,b,sel; 
output out;
reg out;
always@(a or b or sel)


begin 
if(sel==0) out=a; //阻塞赋值
else out=b;


end
endmodule
【例5.2 】同步置数、同步清零的计数器

module count(out,data,load,reset,clk);
output[7:0] out;
input[7:0] data;
input load,clk,reset;
reg[7:0] out;
always @(posedge clk) //clk 上升沿触发


begin
if (!reset) out = 8'h00; //同步清0,低电平有效
else if (load) out = data; //同步预置
else out = out + 1; //计数
end

 

endmodule

【例5.9 】非阻塞赋值

module non_block(c,b,a,clk);
output c,b; 
input clk,a;
reg c,b;
always @(posedge clk)


begin

b<=a;
c<=b;


end
endmodule


【例5.10 】阻塞赋值

module block(c,b,a,clk);
output c,b;
input clk,a;
reg c,b;
always @(posedge clk)


begin

b=a;
c=b;


end
endmodule


【例5.15 】用for 语句描述的七人投票表决器

module voter7(pass,vote);
output pass;
input[6:0] vote;
reg[2:0] sum;
integer i;
reg pass;
always @(vote)


begin

sum=0;

for(i=0;i<=6;i=i+1) //for语句
if(vote[i]) sum=sum+1;
if(sum[2]) pass=1; //若超过4人赞成,则pass=1
else pass=0;


 end 
endmodule

【例6.2 】任务举例

module alutask(code,a,b,c);
input[1:0] code;
input[3:0] a,b;
output[4:0] c;
reg[4:0] c;


task my_and; //任务定义,注意无端口列表
input[3:0] a,b; //a,b,out 名称的作用域范围为task任务内部
output[4:0] out;
integer i;


begin 
for(i=3;i>=0;i=i-1) 
out[i]=a[i]&b[i]; //按位与

end 
endtask

always@(code or a or b) 
begin 
case(code)

2'b00: my_and(a,b,c); 
/*调用任务my_and,需注意端口列表的顺序应与任务定义中的一致,这里的a,b,c

分别对应任务定义中的a,b,out */ 
2'b01: c=a|b; //或
2'b10: c=a-b; //相减
2'b11: c=a+b; //相加

endcase 
end 
endmodule

【例6.3 】测试程序

`include "alutask.v" 
module alu_tp; 
reg[3:0] a,b; 
reg[1:0] code; 
wire[4:0] c; 
parameter DELY = 100;

alutask ADD(code,a,b,c); //调用被测试模块

initial begin

code=4'd0; a= 4'b0000; b= 4'b1111; 
#DELY code=4'd0; a= 4'b0111; b= 4'b1101; 
#DELY code=4'd1; a= 4'b0001; b= 4'b0011; 
#DELY code=4'd2; a= 4'b1001; b= 4'b0011; 
#DELY code=4'd3; a= 4'b0011; b= 4'b0001; 
#DELY code=4'd3; a= 4'b0111; b= 4'b1001; 
#DELY $finish; 
end 
initial $monitor($time,,,"code=%b a=%b b=%b c=%b", code,a,b,c); 
endmodule

【例6.4 】函数

function[7:0] get0; 
input[7:0] x; 
reg[7:0] count; 
integer i;

begin

count=0;

for (i=0;i<=7;i=i+1)

if (x[i]=1'b0) count=count+1;

get0=count;

end 
endfunction
【例6.5 】用函数和case 语句描述的编码器(不含优先顺序)

module code_83(din,dout); 
input[7:0] din; 
output[2:0] dout;


function[2:0] code; //函数定义

input[7:0] din; //函数只有输入,输出为函数名本身

casex (din)
8'b1xxx_xxxx : code = 3'h7;
8'b01xx_xxxx : code = 3'h6;
8'b001x_xxxx : code = 3'h5;
8'b0001_xxxx : code = 3'h4;
8'b0000_1xxx : code = 3'h3;
8'b0000_01xx : code = 3'h2;
8'b0000_001x : code = 3'h1;
8'b0000_000x : code = 3'h0;
default: code = 3'hx;
endcase


endfunction

assign dout = code(din) ; //函数调用

endmodule

【例6.6 】阶乘运算函数

module funct(clk,n,result,reset);
output[31:0] result;
input[3:0] n;
input reset,clk;
reg[31:0] result;
always @(posedge clk) //在clk的上升沿时执行运算


begin
if(!reset) result<=0; //复位
else begin


result <= 2 * factorial(n); // 调用factorial函数

end
end


function[31:0] factorial; //阶乘运算函数定义(注意无端口列表)
input[3:0] opa; //函数只能定义输入端,输出端口为函数名本身
reg[3:0] i;

begin

factorial = opa ? 1 : 0; 
for(i= 2; i <= opa; i = i+1) //该句若要综合通过,opa应赋具体的数值
factorial = i* factorial; //阶乘运算

end


endfunction 
endmodule

【例6.7 】测试程序

`define clk_cycle 50 
`include "funct.v" 
module funct_tp; 
reg[3:0] n; 
reg reset,clk; 
wire[31:0] result;

initial //定义激励向量
begin


n=0; reset=1; clk=0;
for(n=0;n<=15;n=n+1)
#100 n=n;


end

initial $monitor($time,,,"n=%d result=%d",n,result); 
//定义输出显示格式
always # `clk_cycle clk=~clk; //产生时钟信号

funct funct_try(.clk(clk),.n(n),.result(result),.reset(reset)); 
//调用被测试模块

endmodule


【例6.8 】顺序执行模块1

module serial1(q,a,clk);
output q,a;
input clk;
reg q,a;
always @(posedge clk)


begin
q=~q;
a=~q;
end


endmodule

【例6.9 】顺序执行模块2

module serial2(q,a,clk); 
output q,a;

input clk;
reg q,a;
always @(posedge clk)


begin

a=~q;

q=~q;

end 
endmodule

【例6.10 】并行执行模块1

module paral1(q,a,clk);
output q,a;
input clk;
reg q,a;
always @(posedge clk)


begin

q=~q;

end 
always @(posedge clk)

begin

a=~q;

end 
endmodule

【例6.11 】并行执行模块2

module paral2(q,a,clk);
output q,a;
input clk;
reg q,a;
always @(posedge clk)


begin

a=~q;

end 
always @(posedge clk)

begin

q=~q;

end 
endmodule

【例7.3 】行为描述方式实现的4 位计数器

module count4(clk,clr,out);
input clk,clr;
output[3:0] out;
reg[3:0] out;
always @(posedge clk or posedge clr)


begin
if (clr) out<=0;
else out<=out+1;
end


endmodule

【例7.6 】门级结构描述的2 选1MUX

module mux2_1a(out,a,b,sel);
output out;
input a,b,sel;
not (sel_,sel);
and (a1,a,sel_),


(a2,b,sel); 
or (out,a1,a2); 
endmodule

【例7.7 】行为描述的2 选1MUX

module mux2_1b(out,a,b,sel);
output out;
input a,b,sel;
reg out;
always @(a or b or sel)


begin 
if(sel) out = b; 
else out = a; 
end 
endmodule

【例7.8 】数据流描述的2 选1MUX

module MUX2_1c(out,a,b,sel); 
output out;


input a,b,sel; 
assign out = sel ? b : a; 
endmodule

【例7.9 】调用门元件实现的1 位半加器

module half_add1(a,b,sum,cout);
input a,b;
output sum,cout;
and (cout,a,b);
xor (sum,a,b);
endmodule


【例7.10 】数据流方式描述的1 位半加器

module half_add2(a,b,sum,cout);
input a,b;
output sum,cout;
assign sum=a^b;
assign cout=a&b;
endmodule


【例7.11 】采用行为描述的1 位半加器

module half_add3(a,b,sum,cout);
input a,b;
output sum,cout;
reg sum,cout;
always @(a or b)


begin
case ({a,b}) //真值表描述
2'b00: begin sum=0; cout=0; end
2'b01: begin sum=1; cout=0; end
2'b10: begin sum=1; cout=0; end
2'b11: begin sum=0; cout=1; end
endcase


end 
endmodule

【例7.12 】采用行为描述的1 位半加器

module half_add4(a,b,sum,cout);
input a,b;
output sum,cout;


reg sum,cout;
always @(a or b)
begin


sum= a^b;

cout=a&b;

end
endmodule


【例7.13 】调用门元件实现的1 位全加器

module full_add1(a,b,cin,sum,cout);
input a,b,cin;
output sum,cout;
wire s1,m1,m2,m3;
and (m1,a,b),


(m2,b,cin),
(m3,a,cin);
xor (s1,a,b),


(sum,s1,cin);
or (cout,m1,m2,m3);
endmodule


【例7.14 】数据流描述的1 位全加器

module full_add2(a,b,cin,sum,cout);
input a,b,cin;
output sum,cout;
assign sum = a ^ b ^ cin;
assign cout = (a & b)|(b & cin)|(cin & a);
endmodule


【例7.15 】1 位全加器

module full_add3(a,b,cin,sum,cout);
input a,b,cin;
output sum,cout;
assign {cout,sum}=a+b+cin;
endmodule


【例7.16 】行为描述的1 位全加器

module full_add4(a,b,cin,sum,cout);
input a,b,cin;
output sum,cout;


reg sum,cout; //在always块中被赋值的变量应定义为reg型
reg m1,m2,m3;
always @(a or b or cin)


begin

sum = (a ^ b) ^ cin;

m1 = a & b;

m2 = b & cin;

m3 = a & cin;

cout = (m1|m2)|m3;

end
endmodule


【例7.17 】混合描述的1 位全加器

module full_add5(a,b,cin,sum,cout);
input a,b,cin;
output sum,cout;
reg cout,m1,m2,m3; //在always块中被赋值的变量应定义为reg型
wire s1;
xor x1(s1,a,b); //调用门元件
always @(a or b or cin) //always 块语句


begin

m1 = a & b;

m2 = b & cin;

m3 = a & cin;

cout = (m1| m2) | m3;

end

assign sum = s1 ^ cin; //assign 持续赋值语句

endmodule

【例7.18 】结构描述的4 位级连全加器

`include "full_add1.v"
module add4_1(sum,cout,a,b,cin);
output[3:0] sum;
output cout;
input[3:0] a,b;
input cin;


full_add1 f0(a[0],b[0],cin,sum[0],cin1); //级连描述
full_add1 f1(a[1],b[1],cin1,sum[1],cin2);
full_add1 f2(a[2],b[2],cin2,sum[2],cin3);

 

full_add1 f3(a[3],b[3],cin3,sum[3],cout);

endmodule

【例7.19 】数据流描述的4 位全加器

module add4_2(cout,sum,a,b,cin);
output[3:0] sum;
output cout;
input[3:0] a,b;
input cin;
assign {cout,sum}=a+b+cin;
endmodule


【例7.20 】行为描述的4 位全加器

module add4_3(cout,sum,a,b,cin);
output[3:0] sum;
output cout;
input[3:0] a,b;
input cin;
reg[3:0] sum;
reg cout;
always @(a or b or cin)
begin


{cout,sum}=a+b+cin;

end
endmodule


【例8.2】$random 函数的使用

`timescale 10ns/1ns

module random_tp;

integer data;

integer i;

parameter delay=10;

initial $monitor($time,,,"data=%b",data);

initial begin

for(i=0; i<=100; i=i+1)

#delay data=$random; //每次产生一个随机数

end
endmodule

primitive carry_udp(cout,cin,a,b);
input cin,a,b;
output cout;


table

//cin a b : cout //真值表

0 0 0 : 0; 
0 1 0 : 0; 
0 0 1 : 0; 
0 1 1 : 1; 
1 0 0 : 0; 
1 0 1 : 1; 
1 1 0 : 1; 
1 1 1 : 1; 
endtable

endprimitive

【例8.15 】用always 过程块产生两个时钟信号

module test2; 
reg clk1,clk2; 
parameter CYCLE = 100; 
always

begin

{clk1,clk2} = 2'b10;
#(CYCLE/4) {clk1,clk2} = 2'b01;
#(CYCLE/4) {clk1,clk2} = 2'b11;
#(CYCLE/4) {clk1,clk2} = 2'b00;
#(CYCLE/4) {clk1,clk2} = 2'b10;


end 
initial $monitor($time,,,"clk1=%b clk2=%b",clk1,clk2); 
endmodule


【例9.1 】基本门电路的几种描述方法

(1)门级结构描述
module gate1(F,A,B,C,D);
input A,B,C,D;
output F;
nand(F1,A,B); //调用门元件
and(F2,B,C,D);
or(F,F1,F2);
endmodule


(2)数据流描述
module gate2(F,A,B,C,D);
input A,B,C,D;
output F;
assign F=(A&B)|(B&C&D); //assign 持续赋值
endmodule


(3)行为描述
module gate3(F,A,B,C,D); 
input A,B,C,D; 
output F;

reg F;
always @(A or B or C or D) //过程赋值
begin


F=(A&B)|(B&C&D);

end
endmodule
【例9.2 】用bufif1 关键字描述的三态门

module tri_1(in,en,out);
input in,en;
output out;
tri out;
bufif1 b1(out,in,en); //注意三态门端口的排列顺序
endmodule


【例9.3 】用assign 语句描述的三态门

module tri_2(out,in,en);
output out;
input in,en;
assign out = en ? in : 'bz;


//若en=1,则out=in;若en=0,则out为高阻态

endmodule

【例9.4 】三态双向驱动器

module bidir(tri_inout,out,in,en,b);
inout tri_inout;
output out;
input in,en,b;
assign tri_inout = en ? in : 'bz;
assign out = tri_inout ^ b;
endmodule


【例9.5 】三态双向驱动器

module bidir2(bidir,en,clk);
inout[7:0] bidir;
input en,clk;
reg[7:0] temp;
assign bidir= en ? temp : 8'bz;
always @(posedge clk)


begin

if(en) temp=bidir; 
else temp=temp+1; 
end 
endmodule

【例9.6 】3-8 译码器

module decoder_38(out,in);
output[7:0] out;
input[2:0] in;
reg[7:0] out;
always @(in)


begin

case(in)
3'd0: out=8'b11111110;
3'd1: out=8'b11111101;
3'd2: out=8'b11111011;
3'd3: out=8'b11110111;
3'd4: out=8'b11101111;
3'd5: out=8'b11011111;
3'd6: out=8'b10111111;
3'd7: out=8'b01111111;


endcase 
end 
endmodule

【例9.7 】8-3 优先编码器

module encoder8_3(none_on,outcode,a,b,c,d,e,f,g,h);
output none_on;
output[2:0] outcode;
input a,b,c,d,e,f,g,h;
reg[3:0] outtemp;
assign {none_on,outcode}=outtemp;
always @(a or b or c or d or e or f or g or h)


begin
if(h) outtemp=4'b0111;
else if(g) outtemp=4'b0110;
else if(f) outtemp=4'b0101;
else if(e) outtemp=4'b0100;
else if(d) outtemp=4'b0011;
else if(c) outtemp=4'b0010;
else if(b) outtemp=4'b0001;
else if(a) outtemp=4'b0000; 
else outtemp=4'b1000;


end
endmodule


【例9.8 】用函数定义的8-3 优先编码器

module code_83(din, dout);
input[7:0] din;
output[2:0] dout;


function[2:0] code; //函数定义
input[7:0] din; //函数只有输入端口,输出为函数名本身
if (din[7]) code = 3'd7;
else if (din[6]) code = 3'd6;
else if (din[5]) code = 3'd5;
else if (din[4]) code = 3'd4;
else if (din[3]) code = 3'd3;
else if (din[2]) code = 3'd2;
else if (din[1]) code = 3'd1;
else code = 3'd0;
endfunction


assign dout = code(din); //函数调用
endmodule
【例9.10 】奇偶校验位产生器

module parity(even_bit,odd_bit,input_bus);
output even_bit,odd_bit;
input[7:0] input_bus;
assign odd_bit = ^ input_bus; //产生奇校验位
assign even_bit = ~odd_bit; //产生偶校验位
endmodule


【例9.11 】用if-else 语句描述的4 选1 MUX

module mux_if(out,in0,in1,in2,in3,sel);
output out;
input in0,in1,in2,in3;
input[1:0] sel;
reg out;
always @(in0 or in1 or in2 or in3 or sel)


begin
if(sel==2'b00) out=in0;
else if(sel==2'b01) out=in1;
else if(sel==2'b10) out=in2;
else out=in3;


end 
endmodule

【例9.12 】用case 语句描述的4 选1 MUX

module mux_case(out,in0,in1,in2,in3,sel);
output out;
input in0,in1,in2,in3;
input[1:0] sel;
reg out;
always @(in0 or in1 or in2 or in3 or sel)


begin

case(sel) 
2'b00: out=in0; 
2'b01: out=in1; 
2'b10: out=in2; 
default: out=in3;

endcase 
end
endmodule

【例9.13 】用组合电路实现的ROM

module rom(addr,data);
input[3:0] addr;
output[7:0] data;


function[7:0] romout;
input[3:0] addr;
case(addr)


0 : romout = 0; 
1 : romout = 1; 
2 : romout = 4; 
3 : romout = 9; 
4 : romout = 16; 
5 : romout = 25; 
6 : romout = 36; 
7 : romout = 49; 
8 : romout = 64; 
9 : romout = 81; 
10 : romout = 100; 
11 : romout = 121; 
12 : romout = 144; 
13 : romout = 169; 
14 : romout = 196; 
15 : romout = 225; 
default : romout = 8'hxx; 
endcase 
endfunction 
assign data = romout(addr); 
endmodule

【例9.14 】基本D 触发器

module DFF(Q,D,CLK);
output Q;
input D,CLK;
reg Q;
always @(posedge CLK)


begin

Q <= D;

end 
endmodule

【例9.15 】带异步清0、异步置1 的D 触发器

module DFF1(q,qn,d,clk,set,reset);
input d,clk,set,reset;
output q,qn;
reg q,qn;
always @(posedge clk or negedge set or negedge reset)


begin

if (!reset) begin
q <= 0; //异步清0,低电平有效
qn <= 1;


end
else if (!set) begin
q <= 1; //异步置1,低电平有效
qn <= 0;


end
else begin


q <= d;
qn <= ~d;


end 
end 
endmodule

【例9.16 】带同步清0、同步置1 的D 触发器

module DFF2(q,qn,d,clk,set,reset);
input d,clk,set,reset;
output q,qn;
reg q,qn;
always @(posedge clk)


begin
if (reset) begin

q <= 0;qn <= 1; //同步清0,高电平有效

end 
else if (set) begin 
q <=1; qn <=0; //同步置1,高电平有效

end
else begin


q <= d; qn <= ~d;

end
end
endmodule


【例9.17 】带异步清0、异步置1 的JK 触发器

module JK_FF(CLK,J,K,Q,RS,SET);
input CLK,J,K,SET,RS;
output Q;
reg Q;
always @(posedge CLK or negedge RS or negedge SET)


begin
if(!RS) Q <= 1'b0;
else if(!SET) Q <= 1'b1;
else case({J,K})


2'b00 : Q <= Q;
2'b01 : Q <= 1'b0;
2'b10 : Q <= 1'b1;
2'b11 : Q <= ~Q;
default: Q<= 1'bx;
endcase


end

endmodule

【例9.18 】电平敏感的1 位数据锁存器

module latch_1(q,d,clk);
output q;
input d,clk;
assign q = clk ? d : q; //时钟信号为高电平时,将输入端数据锁存
endmodule


【例9.19 】带置位和复位端的1 位数据锁存器

module latch_2(q,d,clk,set,reset);
output q;
input d,clk,set,reset;
assign q = reset ? 0 : (set ? 1 : (clk ? d : q));
endmodule


【例9.20 】8 位数据锁存器

module latch_8(qout,data,clk);
output[7:0] qout;
input[7:0] data;
input clk;
reg[7:0] qout;
always @(clk or data)


begin
if (clk) qout<=data;
end


endmodule

【例9.21 】8 位数据寄存器

module reg8(out_data,in_data,clk,clr);
output[7:0] out_data;
input[7:0] in_data;
input clk,clr;
reg[7:0] out_data;
always @(posedge clk or posedge clr)


begin
if(clr) out_data <=0;
else out_data <=in_data;
end


endmodule

【例9.22 】8 位移位寄存器

module shifter(din,clk,clr,dout);
input din,clk,clr;
output[7:0] dout;
reg[7:0] dout;
always @(posedge clk)


begin
if (clr) dout<= 8'b0; //同步清0,高电平有效
else


begin

dout <= dout << 1; //输出信号左移一位
dout[0] <= din; //输入信号补充到输出信号的最低位

end 
end 
endmodule

【例9.23 】可变模加法/减法计数器

module updown_count(d,clk,clear,load,up_down,qd);

input[7:0] d; 
input clk,clear,load; 
input up_down; 
output[7:0] qd; 
reg[7:0] cnt; 
assign qd = cnt; 
always @(posedge clk) 
begin 
if (!clear) cnt = 8'h00; //同步清0,低电平有效
else if (load) cnt = d; //同步预置
else if (up_down) cnt = cnt + 1; //加法计数
else cnt = cnt - 1; //减法计数
end 
endmodule

【例9.24 】4 位Johnson 计数器(异步复位)

module johnson(clk,clr,out);
input clk,clr;
output[3:0] out;
reg[3:0] out;
always @(posedge clk or posedge clr)


begin 
if (clr) out<= 4'h0; 
else

begin out<= out<< 1; 
out[0]<= ~out[3];

end 
end 
endmodule


【例9.25 】256×8 RAM 模块

module ram256x8(data,address,we,inclock,outclock,q); 
input[7:0] data;
input[7:0] address; 
input we,inclock,outclock; 
output[7:0] q;

lpm_ram_dq myram(.q(q),.data(data),.address(address),

.we(we),.inclock(inclock),.outclock(outclock)); 
defparam myram.lpm_width=8; //定义数据宽度
defparam myram.lpm_widthad=8; //定义地址宽度

endmodule

【例9.26 】256×16 RAM 块

module map_lpm_ram(dataout,datain,addr,we,inclk,outclk);
input[15:0] datain; //端口定义
input[7:0] addr;
input we,inclk,outclk;
output[15:0] dataout;


//lpm_ram_dq元件例化
lpm_ram_dq ram(.data(datain),.address(addr),.we(we),.inclock(inclk),

.outclock(outclk),.q(dataout)); 
defparam ram.lpm_width=16; //参数赋值
defparam ram.lpm_widthad=8; 
defparam ram.lpm_indata="REGISTERED"; 
defparam ram.lpm_outdata="REGISTERED"; 
defparam ram.lpm_file="map_lpm_ram.mif"; //RAM块中的内容取自该文件

endmodule

【例9.27 】4 位串并转换器

module serial_pal(clk,reset,en,in,out);
input clk,reset,en,in;
output[3:0] out;
reg[3:0] out;
always @(posedge clk)


begin
if(reset) out<=4'h0;
else if(en) out<={out,in}; //使用连接运算符


end 
endmodule 
【例10.1 】非流水线方式8 位全加器

module adder8(cout,sum,ina,inb,cin,clk);
output[7:0] sum;
output cout;
input[7:0] ina,inb;
input cin,clk;
reg[7:0] tempa,tempb,sum;
reg cout;
reg tempc;
always @(posedge clk)


begin

tempa=ina; tempb=inb; tempc=cin; //输入数据锁存

end 
always @(posedge clk) 
begin

{cout,sum}=tempa+tempb+tempc;

end 
endmodule

【例10.2 】4 级流水方式的8 位全加器

module pipeline(cout,sum,ina,inb,cin,clk);
output[7:0] sum;
output cout;
input[7:0] ina,inb;
input cin,clk;
reg[7:0] tempa,tempb,sum;
reg tempci,firstco,secondco,thirdco,cout;


reg[1:0] firsts,thirda,thirdb;
reg[3:0] seconda,secondb,seconds;
reg[5:0] firsta,firstb,thirds;


always @(posedge clk)
begin


tempa=ina; tempb=inb; tempci=cin; //输入数据缓存

end
always @(posedge clk)
begin


{firstco,firsts}=tempa[1:0]+tempb[1:0]+tempci; 
//第一级加(低2位)
firsta=tempa[7:2]; //未参加计算的数据缓存
firstb=tempb[7:2];

end
always @(posedge clk)
begin


{secondco,seconds}={firsta[1:0]+firstb[1:0]+firstco,firsts}; 
//第二级加(第2、3位相加)
seconda=firsta[5:2]; //数据缓存
secondb=firstb[5:2];

end
always @(posedge clk)
begin


{thirdco,thirds}={seconda[1:0]+secondb[1:0]+secondco,seconds}; 
//第三级加(第4、5位相加)
thirda=seconda[3:2]; //数据缓存
thirdb=secondb[3:2];

end
always @(posedge clk)
begin


{cout,sum}={thirda[1:0]+thirdb[1:0]+thirdco,thirds}; 
//第四级加(高两位相加)

end
endmodule

【例10.5 】状态机设计的例子

module FSM(clk,clr,out,start,step2,step3);
input clk,clr,start,step2,step3;
output[2:0] out;
reg[2:0] out;
reg[1:0] state,next_state;


parameter state0=2'b00,state1=2'b01, 
state2=2'b11,state3=2'b10; 
/*状态编码,采用格雷(Gray)编码方式*/

always @(posedge clk or posedge clr) /*该进程定义起始状态*/

begin 
if (clr) state <= state0; 
else state <= next_state; 
end

always @(state or start or step2 or step3) /*该进程实现状态的转换*/
begin 
case (state)


state0: begin
if (start) next_state <=state1;
else next_state <=state0;
end


state1: begin
next_state <= state2;


end

state2: begin
if (step2) next_state <=state3;
else next_state <=state0;
end


state3: begin
if (step3) next_state <=state0;
else next_state <=state3;
end


default: next_state <=state0; /*default语句*/
endcase
end


always @(state) /*该进程定义组合逻辑(FSM的输出)*/
begin
case(state)


state0: out=3'b001;
state1: out=3'b010;
state2: out=3'b100;
state3: out=3'b111;
default:out=3'b001; /*default语句,避免锁存器的产生*/


endcase
end


endmodule

【例10.7 】8 位全加器

module add8(sum,cout,b,a,cin);
output[7:0] sum;
output cout;
input[7:0] a,b;
input cin;


assign {cout,sum}=a+b+cin; 
endmodule

【例10.8 】8 位寄存器

module reg8(qout,in,clk,clear);
output[7:0] qout;
input[7:0] in;
input clk,clear;

reg[7:0] qout; 
always @(posedge clk or posedge clear) 
begin 
if(clear) qout=0; //异步清0 
else qout=in; 
end 
endmodule

 

【例10.12 】阻塞赋值方式描述的移位寄存器2

module block2(Q0,Q1,Q2,Q3,din,clk);
output Q0,Q1,Q2,Q3;
input clk,din;
reg Q0,Q1,Q2,Q3;
always @(posedge clk)


begin

Q3=Q2;


Q1=Q0; //该句与下句的顺序与例10.11 颠倒
Q2=Q1;
Q0=din;


end
endmodule


【例10.13 】阻塞赋值方式描述的移位寄存器3

module block3(Q0,Q1,Q2,Q3,din,clk);
output Q0,Q1,Q2,Q3;
input clk,din;
reg Q0,Q1,Q2,Q3;
always @(posedge clk)


begin

Q0=din; //4条赋值语句的顺序与例10.11 完全颠倒

Q1=Q0;
Q2=Q1;
Q3=Q2;


end
endmodule


【例10.14 】非阻塞赋值方式描述的移位寄存器

module block4(Q0,Q1,Q2,Q3,din,clk);

output Q0,Q1,Q2,Q3; 
input clk,din; 
reg Q0,Q1,Q2,Q3; 
always @(posedge clk)

begin

Q3<=Q2;
Q1<=Q0;
Q2<=Q1;
Q0<=din;


end 
endmodule

 

【例10.15 】长帧同步时钟的产生

module longframe1(clk,strb);
parameter delay=8;
input clk;
output strb;
reg strb;
reg[7:0] counter;
always@(posedge clk)


begin
if(counter==255) counter=0;
else counter=counter+1;
end


always@(counter) 
begin 
if(counter<=(delay-1)) strb=1; 
else strb=0; 
end

endmodule

【例10.16 】引入了D 触发器的长帧同步时钟的产生

module longframe2(clk,strb);
parameter delay=8; 
input clk;
output strb;
reg[7:0] counter;
reg temp;
reg strb;
always@(posedge clk)

begin
if(counter==255) counter=0;
else counter=counter+1;
end
always@(posedge clk)
begin


strb=temp; //引入一个触发器

end

always@(counter)
begin 
if(counter<=(delay-1)) temp=1;
else temp=0;
end


endmodule

【例11.1 】数字跑表

/*信号定义:
CLK: CLK为时钟信号;
CLR: 为异步复位信号;
PAUSE: 为暂停信号;
MSH,MSL: 百分秒的高位和低位;
SH,SL: 秒信号的高位和低位;
MH,ML: 分钟信号的高位和低位。 */
module paobiao(CLK,CLR,PAUSE,MSH,MSL,SH,SL,MH,ML);
input CLK,CLR;
input PAUSE;
output[3:0] MSH,MSL,SH,SL,MH,ML;
reg[3:0] MSH,MSL,SH,SL,MH,ML;
reg cn1,cn2; //cn1为百分秒向秒的进位,cn2为秒向分的进位


//百分秒计数进程,每计满100,cn1产生一个进位
always @(posedge CLK or posedge CLR)
begin


if(CLR) begin //异步复位
{MSH,MSL}<=8'h00;
cn1<=0;


end

else if(!PAUSE) //PAUSE为0时正常计数,为1时暂停计数
begin 
if(MSL==9) begin

MSL<=0; 
if(MSH==9) 
begin MSH<=0; cn1<=1; end 
else MSH<=MSH+1; 
end 
else begin

MSL<=MSL+1; cn1<=0;

end 
end 
end

//秒计数进程,每计满60,cn2产生一个进位
always @(posedge cn1 or posedge CLR) 
begin

if(CLR) begin //异步复位
{SH,SL}<=8'h00;
cn2<=0;


end
else if(SL==9) //低位是否为9
begin


SL<=0; 
if(SH==5) begin SH<=0; cn2<=1; end 
else SH<=SH+1; 
end 
else 
begin SL<=SL+1; cn2<=0; end 
end

//分钟计数进程,每计满60,系统自动清零
always @(posedge cn2 or posedge CLR) 
begin

if(CLR)
begin {MH,ML}<=8'h00; end //异步复位


else if(ML==9) begin
ML<=0;
if(MH==5) MH<=0;
else MH<=MH+1;
end


else ML<=ML+1; 
end

endmodule

 

 


/* 信号定义与说明:
CLK: 为同步时钟;
EN: 使能信号,为1的话,则控制器开始工作;
LAMPA: 控制A方向四盏灯的亮灭;其中,LAMPA0~LAMPA3 ,分别控制A方向的


左拐灯、绿灯、黄灯和红灯;
LAMPB: 控制B方向四盏灯的亮灭;其中,LAMPB0 ~ LAMPB3 ,分别控制B方向的

左拐灯、绿灯、黄灯和红灯;
ACOUNT: 用于A方向灯的时间显示,8位,可驱动两个数码管;
BCOUNT: 用于B方向灯的时间显示,8位,可驱动两个数码管。 */

module traffic(CLK,EN,LAMPA,LAMPB,ACOUNT,BCOUNT);
output[7:0] ACOUNT,BCOUNT;
output[3:0] LAMPA,LAMPB;
input CLK,EN;
reg[7:0] numa,numb;
reg tempa,tempb;
reg[2:0] counta,countb;
reg[7:0] ared,ayellow,agreen,aleft,bred,byellow,bgreen,bleft;
reg[3:0] LAMPA,LAMPB;


always @(EN)
if(!EN)


begin //设置各种灯的计数器的预置数
ared <=8'd55; //55秒
ayellow <=8'd5; //5秒
agreen <=8'd40; //40秒
aleft <=8'd15; //15秒
bred <=8'd65; //65秒
byellow <=8'd5; //5秒
bleft <=8'd15; //15秒
bgreen <=8'd30; //30秒


end

assign ACOUNT=numa;
assign BCOUNT=numb;


always @(posedge CLK) //该进程控制A方向的四种灯

begin
if(EN)
begin


if(!tempa)
begin


tempa<=1;
case(counta) //控制亮灯的顺序


0: begin numa<=agreen; LAMPA<=2; counta<=1; end 
1: begin numa<=ayellow; LAMPA<=4; counta<=2; end 
2: begin numa<=aleft; LAMPA<=1; counta<=3; end 
3: begin numa<=ayellow; LAMPA<=4; counta<=4; end 
4: begin numa<=ared; LAMPA<=8; counta<=0; end 
default: LAMPA<=8; 
endcase 
end
else begin //倒计时
if(numa>1)


if(numa[3:0]==0) begin 
numa[3:0]<=4'b1001; 
numa[7:4]<=numa[7:4]-1;

end 
else numa[3:0]<=numa[3:0]-1; 
if (numa==2) tempa<=0;

end
end
else begin


LAMPA<=4'b1000; 
counta<=0; tempa<=0;

end 
end


always @(posedge CLK) //该进程控制B方向的四种灯
begin 
if (EN) 
begin 
if(!tempb) 
begin

 tempb<=1;
case (countb) //控制亮灯的顺序


0: begin numb<=bred; LAMPB<=8; countb<=1; end 
1: begin numb<=bgreen; LAMPB<=2; countb<=2; end 
2: begin numb<=byellow; LAMPB<=4; countb<=3; end 
3: begin numb<=bleft; LAMPB<=1; countb<=4; end 
4: begin numb<=byellow; LAMPB<=4; countb<=0; end 
default: LAMPB<=8;
endcase 
end


 else 
begin //倒计时
if(numb>1)


if(!numb[3:0]) begin
numb[3:0]<=9; 
numb[7:4]<=numb[7:4]-1;


end
else numb[3:0]<=numb[3:0]-1;
if(numb==2) tempb<=0;


end 
end
else begin


LAMPB<=4'b1000;
tempb<=0; countb<=0;


end 
end 
endmodule

【例11.6 】“梁祝”乐曲演奏电路

//信号定义与说明:
//clk_4Hz: 用于控制音长(节拍)的时钟频率;
//clk_6MHz: 用于产生各种音阶频率的基准频率;
//speaker: 用于激励扬声器的输出信号,本例中为方波信号;
//high, med, low:分别用于显示高音、中音和低音音符,各驱动一个数码管来显示。


module song(clk_6MHz,clk_4Hz,speaker,high,med,low);
input clk_6MHz, clk_4Hz;
output speaker;
output[3:0] high,med,low;
reg[3:0] high,med,low;
reg[13:0] divider,origin;
reg[7:0] counter;
reg speaker;
wire carry;


assign carry=(divider==16383);

always @(posedge clk_6MHz)
begin if(carry) divider=origin;
else divider=divider+1;
end


always @(posedge carry)
begin


speaker=~speaker; //2分频产生方波信号

end

always @(posedge clk_4Hz)

begin
case({high,med,low}) //分频比预置
'b000000000011: origin=7281;
'b000000000101: origin=8730;
'b000000000110: origin=9565;
'b000000000111: origin=10310;
'b000000010000: origin=10647;
'b000000100000: origin=11272;
'b000000110000: origin=11831;
'b000001010000: origin=12556;
'b000001100000: origin=12974;
'b000100000000: origin=13516;
'b000000000000: origin=16383;


endcase 
end


always @(posedge clk_4Hz)

begin 
if(counter==63) counter=0; //计时,以实现循环演奏
else counter=counter+1; 
case(counter) //记谱
0: {high,med,low}='b000000000011; //低音“3” 
1: {high,med,low}='b000000000011; //持续4个时钟节拍
2: {high,med,low}='b000000000011; 
3: {high,med,low}='b000000000011; 
4: {high,med,low}='b000000000101; //低音“5” 
5: {high,med,low}='b000000000101; //发3个时钟节拍
6: {high,med,low}='b000000000101; 
7: {high,med,low}='b000000000110; //低音“6” 
8: {high,med,low}='b000000010000; //中音“1” 
9: {high,med,low}='b000000010000; //发3个时钟节拍
10: {high,med,low}='b000000010000; 
11: {high,med,low}='b000000100000; //中音“2” 
12: {high,med,low}='b000000000110; //低音“6” 
13: {high,med,low}='b000000010000; 
14: {high,med,low}='b000000000101; 
15: {high,med,low}='b000000000101; 
16: {high,med,low}='b000001010000; //中音“5” 
17: {high,med,low}='b000001010000; //发3个时钟节拍
18: {high,med,low}='b000001010000; 
19: {high,med,low}='b000100000000; //高音“1” 
20: {high,med,low}='b000001100000; 
21: {high,med,low}='b000001010000; 
22: {high,med,low}='b000000110000; 
23: {high,med,low}='b000001010000; 
24: {high,med,low}='b000000100000; //中音“2” 
25: {high,med,low}='b000000100000; //持续11个时钟节拍
26: {high,med,low}='b000000100000; 
27: {high,med,low}='b000000100000; 
28: {high,med,low}='b000000100000; 
29: {high,med,low}='b000000100000; 
30: {high,med,low}='b000000100000; 
31: {high,med,low}='b000000100000; 
32: {high,med,low}='b000000100000; 
33: {high,med,low}='b000000100000; 
34: {high,med,low}='b000000100000; 
35: {high,med,low}='b000000110000; //中音“3” 
36: {high,med,low}='b000000000111; //低音“7” 
37: {high,med,low}='b000000000111; 
38: {high,med,low}='b000000000110; //低音“6” 
39: {high,med,low}='b000000000110; 
40: {high,med,low}='b000000000101; //低音“5” 
41: {high,med,low}='b000000000101; 
42: {high,med,low}='b000000000101; 
43: {high,med,low}='b000000000110; //低音“6” 
44: {high,med,low}='b000000010000; //中音“1” 
45: {high,med,low}='b000000010000; 
46: {high,med,low}='b000000100000; //中音“2” 
47: {high,med,low}='b000000100000; 
48: {high,med,low}='b000000000011; //低音“3” 
49: {high,med,low}='b000000000011; 
50: {high,med,low}='b000000010000; //中音“1” 
51: {high,med,low}='b000000010000; 
52: {high,med,low}='b000000000110; 
53: {high,med,low}='b000000000101; //低音“5” 
54: {high,med,low}='b000000000110; 
55: {high,med,low}='b000000010000; //中音“1” 
56: {high,med,low}='b000000000101; //低音“5” 
57: {high,med,low}='b000000000101; //持续8个时钟节拍
58: {high,med,low}='b000000000101; 
59: {high,med,low}='b000000000101; 
60: {high,med,low}='b000000000101; 
61: {high,med,low}='b000000000101; 
62: {high,med,low}='b000000000101; 
63: {high,med,low}='b000000000101; 
endcase 
end 
endmodule 
【例11.7 】自动售饮料机
/*信号定义:
clk: 时钟输入;
reset: 为系统复位信号;
half_dollar: 代表投入5角硬币;
one_dollar: 代表投入1元硬币;
half_out: 表示找零信号;
dispense: 表示机器售出一瓶饮料;
collect: 该信号用于提示投币者取走饮料。 */ 
module sell(one_dollar,half_dollar, 
collect,half_out,dispense,reset,clk); 
parameter idle=0,one=2,half=1,two=3,three=4; 
//idle,one,half,two,three 为中间状态变量,代表投入币值的几种情况

input one_dollar,half_dollar,reset,clk; 
output collect,half_out,dispense; 
reg collect,half_out,dispense; 
reg[2:0] D; 
always @(posedge clk)

begin
if(reset)
begin


dispense=0; collect=0; 
half_out=0; D=idle;

end
case(D)


idle: 
if(half_dollar) D=half; 
else if(one_dollar)

D=one;

half: 
if(half_dollar) D=one; 
else if(one_dollar)

D=two;

one: 
if(half_dollar) D=two; 
else if(one_dollar) 
D=three;

two: 
if(half_dollar) D=three; 
else if(one_dollar) 
begin

dispense=1; //售出饮料
collect=1; D=idle;

end

three:
if(half_dollar)
begin


dispense=1; //售出饮料
collect=1; D=idle;

end 
else if(one_dollar) 
begin

dispense=1; //售出饮料
collect=1;
half_out=1; D=idle;


end 
endcase 
end 
endmodule

【例11.8 】多功能数字钟

/* 信号定义:

clk: 标准时钟信号,本例中,其频率为4Hz; 
clk_1k: 产生闹铃音、报时音的时钟信号,本例中其频率为1024Hz; 
mode: 功能控制信号;为0:计时功能;
为1:闹钟功能;
为2:手动校时功能;
turn: 接按键,在手动校时功能时,选择是调整小时,还是分钟;
若长时间按住该键,还可使秒信号清零,用于精确调时;
change: 接按键,手动调整时,每按一次,计数器加1; 
如果长按,则连续快速加1,用于快速调时和定时;

hour,min,sec :此三信号分别输出并显示时、分、秒信号,
皆采用BCD码计数,分别驱动6个数码管显示时间;

alert: 输出到扬声器的信号,用于产生闹铃音和报时音;
闹铃音为持续20秒的急促的“嘀嘀嘀”音,若按住“change”键,
则可屏蔽该音;整点报时音为“嘀嘀嘀嘀—嘟”四短一长音;

LD_alert: 接发光二极管,指示是否设置了闹钟功能;
LD_hour: 接发光二极管,指示当前调整的是小时信号;
LD_min: 接发光二极管,指示当前调整的是分钟信号。

 */ 
module clock(clk,clk_1k,mode,change,turn,alert,hour,min,sec,

LD_alert,LD_hour,LD_min); 
input clk,clk_1k,mode,change,turn; 
output alert,LD_alert,LD_hour,LD_min; 
output[7:0] hour,min,sec; 
reg[7:0] hour,min,sec,hour1,min1,sec1,ahour,amin; 
reg[1:0] m,fm,num1,num2,num3,num4; 
reg[1:0] loop1,loop2,loop3,loop4,sound;

reg LD_hour,LD_min; 
reg clk_1Hz,clk_2Hz,minclk,hclk; 
reg alert1,alert2,ear; 
reg count1,count2,counta,countb; 
wire ct1,ct2,cta,ctb,m_clk,h_clk;

always @(posedge clk) 
begin

clk_2Hz<=~clk_2Hz;
if(sound==3) begin sound<=0; ear<=1; end
//ear信号用于产生或屏蔽声音
else begin sound<=sound+1; ear<=0; end
end


always @(posedge clk_2Hz) //由4Hz 的输入时钟产生1Hz的时基信号
clk_1Hz<=~clk_1Hz;

always @(posedge mode) //mode信号控制系统在三种功能间转换
begin if(m==2) m<=0; else m<=m+1; end 
always @(posedge turn) 
fm<=~fm;

always //该进程产生count1,count2,counta,countb四个信号

begin
case(m) 
2:begin if(fm)


begin count1<=change; {LD_min,LD_hour}<=2; end 
else 
begin counta<=change; {LD_min,LD_hour}<=1; end 
{count2,countb}<=0;

end

 1:begin if(fm) 
begin count2<=change; {LD_min,LD_hour}<=2; end
else
begin countb<=change; {LD_min,LD_hour}<=1; end


{count1,counta}<=2'b00;

end
default: {count1,count2,counta,countb,LD_min,LD_hour}<=0;
endcase


 end

 

always @(negedge clk) 
//如果长时间按下“change”键,则生成“num1”信号用于连续快速加1

if(count2) begin
if(loop1==3) num1<=1;
else
begin loop1<=loop1+1; num1<=0; end
end


else begin loop1<=0; num1<=0; end
always @(negedge clk) //产生num2信号


if(countb) begin 
if(loop2==3) num2<=1; 
else 
begin loop2<=loop2+1; num2<=0; end 
end

else begin loop2<=0; num2<=0; end
always @(negedge clk)


if(count1) begin 
if(loop3==3) num3<=1; 
else 
begin loop3<=loop3+1; num3<=0; end 
end

else begin loop3<=0; num3<=0; end
always @(negedge clk)


if(counta) begin 
if(loop4==3) num4<=1; 
else 
begin loop4<=loop4+1; num4<=0; end 
end

else begin loop4<=0; num4<=0; end

assign ct1=(num3&clk)|(!num3&m_clk); //ct1 用于计时、校时中的分钟计数
assign ct2=(num1&clk)|(!num1&count2); //ct2 用于定时状态下调整分钟信号
assign cta=(num4&clk)|(!num4&h_clk); //cta 用于计时、校时中的小时计数
assign ctb=(num2&clk)|(!num2&countb); //ctb 用于定时状态下调整小时信号

always @(posedge clk_1Hz) //秒计时和秒调整进程

if(!(sec1^8'h59)|turn&(!m)) 
begin
sec1<=0; if(!(turn&(!m))) minclk<=1;

end

//按住“turn”按键一段时间,秒信号可清零,该功能用于手动精确调时

else begin
if(sec1[3:0]==4'b1001) 
begin sec1[3:0]<=4'b0000; sec1[7:4]<=sec1[7:4]+1; end
else sec1[3:0]<=sec1[3:0]+1; minclk<=0;
end


assign m_clk=minclk||count1;

always @(posedge ct1) //分计时和分调整进程

begin
if(min1==8'h59) begin min1<=0; hclk<=1; end
else begin


if(min1[3:0]==9)
begin min1[3:0]<=0; min1[7:4]<=min1[7:4]+1; end
else min1[3:0]<=min1[3:0]+1; hclk<=0;
end


 end 
assign h_clk=hclk||counta;

always @(posedge cta) //小时计时和小时调整进程
if(hour1==8'h23) hour1<=0; 
else if(hour1[3:0]==9)

begin hour1[7:4]<=hour1[7:4]+1; hour1[3:0]<=0; end 
else hour1[3:0]<=hour1[3:0]+1;

always @(posedge ct2) //闹钟定时功能中的分钟调节进程
if(amin==8'h59) amin<=0; 
else if(amin[3:0]==9)

begin amin[3:0]<=0; amin[7:4]<=amin[7:4]+1; end 
else amin[3:0]<=amin[3:0]+1;

always @(posedge ctb) //闹钟定时功能中的小时调节进程
if(ahour==8'h23) ahour<=0; 
else if(ahour[3:0]==9)

begin ahour[3:0]<=0; ahour[7:4]<=ahour[7:4]+1; end 
else ahour[3:0]<=ahour[3:0]+1;

always //闹铃功能
if((min1==amin)&&(hour1==ahour)&&(amin|ahour)&&(!change))

//若按住“change”键不放,可屏蔽闹铃音
if(sec1<8'h20) alert1<=1; //控制闹铃的时间长短
else alert1<=0; 
else alert1<=0;

always //时、分、秒的显示控制
case(m)
3'b00: begin hour<=hour1; min<=min1; sec<=sec1; end


//计时状态下的时、分、秒显示
3'b01: begin hour<=ahour; min<=amin; sec<=8'hzz; end 
//定时状态下的时、分、秒显示
3'b10: begin hour<=hour1; min<=min1; sec<=8'hzz; end 
//校时状态下的时、分、秒显示

endcase

assign LD_alert=(ahour|amin)?1:0; //指示是否进行了闹铃定时
assign alert=((alert1)?clk_1k&clk:0)|alert2; //产生闹铃音或整点报时音

always //产生整点报时信号alert2

 begin 
if((min1==8'h59)&&(sec1>8'h54)||(!(min1|sec1))) 
if(sec1>8'h54) alert2<=ear&clk_1k; // 产生短音
else alert2<=!ear&clk_1k; //产生长音
else alert2<=0;


end
endmodule


【例11.9 】电话计费器程序

/*信号定义:
clk: 时钟信号,本例中其频率值为1Hz;
decide: 电话局反馈回来的信号,代表话务种类,“01”表示市话,“10”表示


长话,“11”表示特话;
dispmoney: 用来显示卡内余额,其单位为角,这里假定能显示的最大数额为50元

(500角);
disptime: 显示本次通话的时长;
write,read:当write信号下降沿到来时写卡,当话卡插入,read信号变高时读卡;
warn: 余额过少时的告警信号。本例中,当打市话时,余额少于3角,打长

话时,余额少于6角,即会产生告警信号;
cut: 当告警时间过长时自动切断通话信号。 */


module account(state,clk,card,decide,disptime,dispmoney,

write,read,warn,cut); 
output write,read,warn,cut; 
input state,clk,card; 
input[2:1] decide; 
output[10:0] dispmoney; 
output[8:0] disptime; 
reg[10:0] money; 
reg[8:0] dtime; 
reg warn,cut,write,t1m; //t1m为分时钟
reg set,reset_ena; 
integer num1,temp;

assign dispmoney=card?money:0; 
assign disptime=dtime; 
assign read=card?1:0;

//产生分时钟
always @(posedge clk)

begin
if (num1==59) begin num1<=0; t1m<=1; end
else begin


if(state) num1<=num1+1;
else num1<=0; t1m<=0; 
end


 end

always @(negedge clk) //该进程完成电话计费功能
begin 
if(!set) 
begin money<=11'h500; set<=1; end

if(card&state)
if(t1m)
case({state,decide})


 3'b101: if(money<3)
begin warn<=1; write<=0; reset_ena<=1; end
else
begin //市话计费


if(money[3:0]<4'b0011)
begin


money[3:0]<=money[3:0]+7;


end

 3'b110:

if(money[7:4]!=0) 
money[7:4]<=money[7:4]-1;

else 
begin money[7:4]<=9; money[10:8]<=money[10:8]-1; end 
end 
else money[3:0]<=money[3:0]-3; write<=1;

//市话通话计时
if(dtime[3:0]==9) 
begin

dtime[3:0]<=0; 
if(dtime[7:4]==9)

begin dtime[7:4]<=0; dtime[8]<=dtime[8]+1; end 
else dtime[7:4]<=dtime[7:4]+1; 
end 
else 
begin

dtime[3:0]<=dtime[3:0]+1; warn<=0; reset_ena<=0;

end

if(money<6) 
begin warn<=1; write<=0; reset_ena<=1; end 
else begin

//通话计时
if(dtime[3:0]==9) 
begin

dtime[3:0]<=0; if(dtime[7:4]==9) 
begin dtime[7:4]<=0; dtime[8]<=dtime[8]+1; end 
else dtime[7:4]<=dtime[7:4]+1; 
end 
else dtime[3:0]<=dtime[3:0]+1; 
//长话计费
if(money[3:0]<4'b0110) 
begin

money[3:0]<=money[3:0]+4;
if(!money[7:4])
begin money[7:4]<=9; money[10:8]<=money[10:8]-1; end
else money[7:4]<=money[7:4]-1;
end
else money[3:0]<=money[3:0]-6;


write<=1; reset_ena<=0; warn<=0;
end 
endcase 
else write<=0; 
else begin dtime<=0; warn<=0; write<=0; reset_ena<=0; end 
//取卡后对一些信号进行复位

end

always @(posedge clk) //该进程在告警时间过长的情况下切断本次通话

begin
if(warn) temp<=temp+1;
else temp<=0;
if(temp==15)


begin cut<=1; temp<=0; end
if(!card||!reset_ena)
begin


cut<=0; //复位cut信号
temp<=0;


end 
end 
endmodule

【例12.1 】8 位级连加法器

module add_jl(sum,cout,a,b,cin);
output[7:0] sum;
output cout;
input[7:0] a,b;
input cin;


full_add1 f0(a[0],b[0],cin,sum[0],cin1); //级连描述
full_add1 f1(a[1],b[1],cin1,sum[1],cin2);
full_add1 f2(a[2],b[2],cin2,sum[2],cin3);


full_add1 f3(a[3],b[3],cin3,sum[3],cin4);
full_add1 f4(a[4],b[4],cin4,sum[4],cin5);
full_add1 f5(a[5],b[5],cin5,sum[5],cin6);
full_add1 f6(a[6],b[6],cin6,sum[6],cin7);
full_add1 f7(a[7],b[7],cin7,sum[7],cout);
endmodule


module full_add1(a,b,cin,sum,cout); //1位全加器
input a,b,cin;
output sum,cout; 
wire s1,m1,m2,m3; 
and (m1,a,b), 
(m2,b,cin), 
(m3,a,cin); 
xor (s1,a,b), 
(sum,s1,cin); 
or (cout,m1,m2,m3); 
endmodule 
【例12.2 】8 位并行加法器
module add_bx(cout,sum,a,b,cin); 
output[7:0] sum; 
output cout; 
input[7:0] a,b; 
input cin; 
assign {cout,sum}=a+b+cin; 
endmodule 
【例12.3 】8 位超前进位加法器
module add_ahead(sum,cout,a,b,cin); 
output[7:0] sum; 
output cout; 
input[7:0] a,b; 
input cin; 
wire[7:0] G,P; 
wire[7:0] C,sum; 
assign G[0]=a[0]&b[0]; //产生第0位本位值和进位值
assign P[0]=a[0]|b[0]; 
assign C[0]=cin; 
assign sum[0]=G[0]^P[0]^C[0]; 
assign G[1]=a[1]&b[1]; //产生第1位本位值和进位值
assign P[1]=a[1]|b[1]; 
assign C[1]=G[0]|(P[0]&cin); 
assign sum[1]=G[1]^P[1]^C[1]; 
assign G[2]=a[2]&b[2]; //产生第2位本位值和进位值
assign P[2]=a[2]|b[2]; 
assign C[2]=G[1]|(P[1]&C[1]); 
assign sum[2]=G[2]^P[2]^C[2]; 
assign G[3]=a[3]&b[3]; //产生第3位本位值和进位值
assign P[3]=a[3]|b[3]; 
assign C[3]=G[2]|(P[2]&C[2]); 
assign sum[3]=G[3]^P[3]^C[3]; 
assign G[4]=a[4]&b[4]; //产生第4位本位值和进位值
assign P[4]=a[4]|b[4]; 
assign C[4]=G[3]|(P[3]&C[3]); 
assign sum[4]=G[2]^P[2]^C[2]; 
assign G[5]=a[5]&b[5]; //产生第5位本位值和进位值
assign P[5]=a[5]|b[5]; 
assign C[5]=G[4]|(P[4]&C[4]); 
assign sum[5]=G[5]^P[5]^C[5]; 
assign G[6]=a[6]&b[6]; //产生第6位本位值和进位值
assign P[6]=a[6]|b[6]; 
assign C[6]=G[5]|(P[5]&C[5]); 
assign sum[6]=G[6]^P[6]^C[6]; 
assign G[7]=a[7]&b[7]; //产生第7位本位值和进位值
assign P[7]=a[7]|b[7]; 
assign C[7]=G[6]|(P[6]&C[6]); 
assign sum[7]=G[7]^P[7]^C[7]; 
assign cout=G[7]|(P[7]&C[7]); //产生最高位进位输出
endmodule 
【例12.4 】8 位并行乘法器
module mult(outcome,a,b); 
parameter size=8; 
input[size:1] a,b; //两个操作数
output[2*size:1] outcome; //结果
assign outcome=a*b; //乘法运算符
endmodule 
【例12.5 】4×4 查找表乘法器

module mult4x4(out,a,b,clk);
output[7:0] out;
input[3:0] a,b;
input clk;
reg[7:0] out;
reg[1:0] firsta,firstb;
reg[1:0] seconda,secondb;
wire[3:0] outa,outb,outc,outd;
always @(posedge clk)
begin


firsta = a[3:2]; seconda = a[1:0];
firstb = b[3:2]; secondb = b[1:0];


end

lookup m1(outa,firsta,firstb,clk),
m2(outb,firsta,secondb,clk),
m3(outc,seconda,firstb,clk),
m4(outd,seconda,secondb,clk); //模块调用


always @(posedge clk)
begin


 out = (outa << 4) + (outb << 2) + (outc << 2) + outd;

end
endmodule


module lookup(out,a,b,clk); //用查找表方式实现2×2乘法
output[3:0] out;
input[1:0] a,b;
input clk;
reg[3:0] out;
reg[3:0] address;
always @(posedge clk)


begin

 address = {a,b};

case(address)
4'h0 : out = 4 'b0000;
4'h1 : out = 4'b0000;
4'h2 : out = 4'b0000;
4'h3 : out = 4'b0000;
4'h4 : out = 4'b0000;
4'h5 : out = 4'b0001;
4'h6 : out = 4'b0010;
4'h7 : out = 4'b0011;
4'h8 : out = 4'b0000;
4'h9 : out = 4'b0010;
4'ha : out = 4'b0100;
4'hb : out = 4'b0110;
4'hc : out = 4'b0000;
4'hd : out = 4'b0011;
4'he : out = 4'b0110;
4'hf : out = 4'b1001;
default : out='bx;


endcase 
end 
endmodule

【例12.6 】8 位加法树乘法器

module add_tree(out,a,b,clk);
output[15:0] out;
input[7:0] a,b;
input clk;
wire[15:0] out;
wire[14:0] out1,c1;
wire[12:0] out2;
wire[10:0] out3,c2;
wire[8:0] out4;
reg[14:0] temp0;
reg[13:0] temp1;
reg[12:0] temp2;
reg[11:0] temp3;
reg[10:0] temp4;
reg[9:0] temp5;
reg[8:0] temp6;
reg[7:0] temp7;


function[7:0] mult8x1; //该函数实现8×1乘法
input[7:0] operand;
input sel;


begin

mult8x1= (sel) ? (operand) : 8'b00000000;


end
endfunction


always @(posedge clk) //调用函数实现操作数b 各位与操作数a的相乘
begin

temp7<=mult8x1(a,b[0]);
temp6<=((mult8x1(a,b[1]))<<1);
temp5<=((mult8x1(a,b[2]))<<2);
temp4<=((mult8x1(a,b[3]))<<3);
temp3<=((mult8x1(a,b[4]))<<4);
temp2<=((mult8x1(a,b[5]))<<5);
temp1<=((mult8x1(a,b[6]))<<6);
temp0<=((mult8x1(a,b[7]))<<7);


end

assign out1 = temp0 + temp1; //加法器树运算
assign out2 = temp2 + temp3; 
assign out3 = temp4 + temp5;
assign out4 = temp6 + temp7;
assign c1 = out1 + out2;
assign c2 = out3 + out4;
assign out = c1 + c2;


endmodule

【例12.7 】11 阶FIR 数字滤波器

module fir(clk,x,y);
input[7:0] x;
input clk;
output[15:0] y;
reg[15:0] y;
reg[7:0] tap0,tap1,tap2,tap3,tap4,tap5,tap6,tap7,tap8,tap9,tap10;
reg[7:0] t0,t1,t2,t3,t4,t5;
reg[15:0] sum;


always@(posedge clk)
begin


t0<=tap5;
t1<=tap4+tap6;
t2<=tap3+tap7;
t3<=tap2+tap8;
t4<=tap1+tap9;
t5<=tap0+tap10; //利用对称性


sum<=(t1<<4)+{t1[7],t1[7:1]}+{t1[7],t1[7],t1[7:2]}+

{t1[7],t1[7],t1[7], 
t1[7:3]}-(t2<<3)-(t2<<2)+t2-{t2[7],t2[7],t2[7:2]} 
+(t3<<2)+t3+{t3[7],t3[7],t3[7:2]}+{t3[7],t3[7],t3[7],t3[7],t3[7:4]} 
+{t3[7],t3[7],t3[7],t3[7],t3[7],t3[7:5]} 
-t4-{t4[7],t4[7:1]}-{t4[7],t4[7],t4[7],t4[7:3]} 
+{t5[7],t5[7:1]}-{t5[7],t5[7],t5[7],t5[7],t5[7],t5[7:5]} 
+(t0<<7)-((t0<<2)<<2)-(t0<<2)+{t0[7],t0[7:1]} 
+{t0[7],t0[7],t0[7:2]}+{t0[7],t0[7],t0[7],t0[7],t0[7:4]};

//16+0.5+0.25+0.125=16.875 
//8+4-1+0.25=11.25 
//4+1+0.25+0.0625+0.03125=5.34375 
//1+0.5+0.125=1.625 
//0.5-0.03125=0.46875 
//128-4*4-4+0.5+0.25+0.0625=108.8125 
/* 0.0036,-0.0127,0.0417,-0.0878,0.1318,0.8500,0.1318,-0.0878, 
0.0417,-0.0127,0.0036,0.4608,-1.6256,5.3376,-11.2384,16.8704, 
108.800,16.8704,-11.238,5.3376,-1.6256,0.4608 */

 tap10<=tap9; 
tap9<=tap8; 
tap8<=tap7; 
tap7<=tap6; 
tap6<=tap5; 
tap5<=tap4; 
tap4<=tap3; 
tap3<=tap2; 
tap2<=tap1; 
tap1<=tap0; 
tap0<=x;


y<={sum[15],sum[15],sum[15],sum[15],sum[15],sum[15],sum[15],sum[15:7]} 
;

end

endmodule

【例12.8 】16 位高速数字相关器

module correlator(out,a,b,clk);
output[4:0] out;
input[15:0] a,b;
input clk;
wire[2:0] sum1,sum2,sum3,sum4;
wire[3:0] temp1,temp2;


detect u1(sum1,a[3:0],b[3:0],clk), //模块调用
u2(sum2,a[7:4],b[7:4],clk), 
u3(sum3,a[11:8],b[11:8],clk), 
u4(sum4,a[15:12],b[15:12],clk); 
add3 u5(temp1,sum1,sum2,clk), 
u6(temp2,sum3,sum4,clk); 
add4 u7(out,temp1,temp2,clk);

endmodule

module detect(sum,a,b,clk); //该模块实现4位相关器
output[2:0] sum;
input clk;
input[3:0] a,b;
wire[3:0] ab;
reg[2:0] sum;


assign ab = a ^ b; 
always @(posedge clk) 
begin

case(ab) 
'd0: sum = 4; 
'd1,'d2,'d4,'d8: sum = 3; 
'd3,'d5,'d6,'d9,'d10,'d12: sum = 2; 
'd7,'d11,'d13,'d14: sum = 1; 
'd15: sum = 0;

endcase 
end 
endmodule

module add3(add,a,b,clk); //3位加法器
output[3:0] add;
input[2:0] a,b;
input clk;
reg[3:0] add; 
always @(posedge clk) 
begin add = a + b; end 
endmodule

module add4(add,a,b,clk); //4位加法器
output[4:0] add;
input[3:0] a,b;
input clk;
reg[4:0] add;
always @(posedge clk)


begin add = a + b; end 
endmodule

【例12.9 】(7,4)线性分组码编码器

module linear(c,u,clk);
output[6:0] c; //c 为编码输出码字
input[3:0] u;
input clk;
reg[6:0] c;
always @(posedge clk)


begin

c[6] = u[3];
c[5] = u[2];
c[4] = u[1];
c[3] = u[0];
c[2] = u[1] ^ u[2] ^ u[3];
c[1] = u[0] ^ u[1] ^ u[2];
c[0] = u[0] ^ u[2] ^ u[3] ;


end 
endmodule

【例12.10 】(7,4)线性分组码译码器

module decoder1(c,y,clk);
output[6:0] c;
input[6:0] y;
input clk;
reg[2:0] s;
reg[6:0] e,c;
always @(posedge clk)

begin

s[0] = y[0] ^ y[3] ^ y[5] ^ y[6];
s[1] = y[1] ^ y[3] ^ y[4] ^ y[5];
s[2] = y[2] ^ y[4] ^ y[5] ^ y[6]; //s[0]~ s[2]为伴随子
e[0] = s[0] & (~s[1]) & (~s[2]);
e[1] = (~s[0]) & s[1] & (~s[2]);
e[2] = (~s[0]) & (~s[1]) & s[2];
e[3] = s[0] & s[1] & (~s[2]);
e[4] = (~s[0]) & s[1] & s[2];
e[5] = s[0] & s[1] & s[2];
e[6] = s[0] & (~s[1]) & s[2]; //e[0]~ e[6]为错误图样
c = e ^ y; //c 为输出码字


end
endmodule


【例12.11 】(7,4)循环码编码器

module cycle(c,u,clk);
output[6:0] c;
input[3:0] u;
input clk;
reg[2:0] i;
reg d0,d1,d2,temp;
reg[6:0] c;


always @(posedge clk)
begin


d0=0;d1=0; d2=0; //初始化
for (i=0;i<4;i=i+1) //该for循环计算码组的前4个码元
begin

temp = d2 ^ c[i];
d2 = d1; d1 = d0 ^ temp;
d0 = temp; c[i] = u[i];


end 
for (i=4;i<7;i=i+1) //该for循环计算码组的后3个码元
begin

temp = d2;
d2 = d1; d1 = d0 ^ temp;
d0 = temp; c[i] = temp;


end
end
endmodule 
【例12.12 】(7,4)循环码纠错译码器
module decoder2(c,y,clk); 
output[6:0] c; //c为输出码字,c[6]为高次项
input[6:0] y; //y为接收码字,y[6]为高次项
input clk; 
reg[6:0] c,c_buf,buffer; 
reg temp; 
reg s0,s1,s2; //伴随式电路寄存器
reg e; //错误检测输出信号
integer i; 
always @(posedge clk) 
begin 
s0=0; s1=0; s2=0; //初始化 
temp=0; 
buffer=y; //接收码字移入缓存
for (i=6;i>=0;i=i-1) //接收码字进入除法电路
begin 
e=s0&(~s1)&temp; 
temp=s2; 
s2=s1; 
s1=s0^temp; 
s0=y[i]^temp^e; 
end 
for (i=6;i>=0;i=i-1) //输出纠错译码后的码字
begin 
e=s0&(~s1)&temp; 
temp=s2; 
s2=s1; 
s1=s0^temp; 
s0=temp^e; 
c_buf[i]=buffer[i]^e; 
if (e==1) //若出错,对缓存进行清零
begin 
s0=0; s1=0; s2=0; 
end
end
end


always @(posedge clk)
begin


c=c_buf;

end
endmodule


【例12.13 】CRC 编码

module crc(crc_reg,crc,d,calc,init,d_valid,clk,reset);
output[15:0] crc_reg;
output[7:0] crc;
input[7:0] d;
input calc;
input init;
input d_valid;
input clk;
input reset;
reg[15:0] crc_reg;
reg[7:0] crc;
wire[15:0] next_crc;


always @(posedge clk or posedge reset)

begin
if (reset)
begin


crc_reg <= 16'h0000;
crc <= 8'h00;


end

else if (init)
begin


crc_reg <= 16'h0000;
crc <= 8'h00;


end

else if (calc & d_valid)
begin

 

 

crc_reg <= next_crc; 
crc <= ~{next_crc[8], next_crc[9], next_crc[10], next_crc[11], 
next_crc[12], next_crc[13], next_crc[14], next_crc[15]};

end

else if (~calc & d_valid)

begin

crc_reg <= {crc_reg[7:0], 8'h00}; 
crc <= ~{crc_reg[0], crc_reg[1], crc_reg[2], crc_reg[3], 
crc_reg[4], crc_reg[5], crc_reg[6], crc_reg[7]};

end
end


assign next_crc[0] = crc_reg[12] ^ d[7] ^ crc_reg[8] ^ d[3]; 
assign next_crc[1] = crc_reg[13] ^ d[6] ^ d[2] ^ crc_reg[9]; 
assign next_crc[2] = d[5] ^ crc_reg[14] ^ d[1] ^ crc_reg[10]; 
assign next_crc[3] = d[4] ^ crc_reg[15] ^ d[0] ^ crc_reg[11]; 
assign next_crc[4] = crc_reg[12] ^ d[3]; 
assign next_crc[5]=crc_reg[12]^crc_reg[13]^d[7]^crc_reg[8]^d[2]^d[3]; 
assign next_crc[6] = crc_reg[13] ^ d[6] ^ crc_reg[14] ^ d[1] ^ d[2] ^

crc_reg[9]; 
assign next_crc[7] = d[5] ^ crc_reg[14] ^ crc_reg[15] ^ d[0] ^ d[1] ^

crc_reg[10]; 
assign next_crc[8] = d[4] ^ crc_reg[15] ^ d[0] ^ crc_reg[0] ^ crc_reg[11]; 
assign next_crc[9] = crc_reg[12] ^ crc_reg[1] ^ d[3]; 
assign next_crc[10] = crc_reg[13] ^ d[2] ^ crc_reg[2]; 
assign next_crc[11] = crc_reg[3] ^ crc_reg[14] ^ d[1]; 
assign next_crc[12] = crc_reg[12] ^ crc_reg[4] ^ d[7] ^ crc_reg[15]

^ d[0] ^ crc_reg[8] ^ d[3]; 
assign next_crc[13] = crc_reg[13] ^ d[6] ^ crc_reg[5] ^ d[2] ^ crc_reg[9]; 
assign next_crc[14] = d[5] ^ crc_reg[14] ^ crc_reg[6] ^ d[1] ^ crc_reg[10];

assign next_crc[15] = d[4] ^ crc_reg[15] ^ d[0] ^ crc_reg[7] ^ crc_reg[11]; 
endmodule

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