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/************************************************

The Verilog HDL code example is from the book

Computer Principles and Design in Verilog HDL

by Yamin Li, published by A JOHN WILEY & SONS

************************************************/

module div_restoring (a,b,start,clk,clrn,q,r,busy,ready,count);

module div_nonrestoring (a,b,start,clk,clrn,q,r,busy,ready,count);

input [31:0] a; // dividend

input [15:0] b; // divisor

input start; // start

input clk, clrn; // clk,reset

output [31:0] q; // quotient

output [15:0] r; // remainder

output reg busy; // busy

output reg ready; // ready

output [4:0] count; // counter

output [4:0] count; // count

reg [31:0] reg_q;

reg [15:0] reg_r;

reg [15:0] reg_b;

reg [4:0] count;

wire [16:0] sub_out = {reg_r,reg_q[31]} - {1'b0,reg_b}; // sub

wire [16:0] sub_add = reg_r[15]?

wire [15:0] mux_out = sub_out[16]? // restoring

{reg_r,reg_q[31]} + {1'b0,reg_b} : // + b

{reg_r[14:0],reg_q[31]} : sub_out[15:0]; // or not

{reg_r,reg_q[31]} - {1'b0,reg_b}; // - b

assign q = reg_q;

assign r = reg_r;

assign r = reg_r[15]? reg_r + reg_b : reg_r; // adjust r

always @ (posedge clk or negedge clrn) begin

if (!clrn) begin

busy <= 0;

ready <= 0;

end else begin

if (start) begin

reg_q <= a; // load a

reg_b <= b; // load b

reg_r <= 0;

busy <= 1;

ready <= 0;

count <= 0;

end else if (busy) begin

reg_q <= {reg_q[30:0],~sub_out[16]}; // << 1

reg_q <= {reg_q[30:0],~sub_add[16]}; // << 1

reg_r <= mux_out;

reg_r <= sub_add[15:0];

count <= count + 5'b1; // counter++

count <= count + 5'b1; // count++

if (count == 5'h1f) begin // finished

if (count == 5'h1f) begin // finish

busy <= 0;

ready <= 1; // q,r ready

end

endmodule

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/************************************************
  The Verilog HDL code example is from the book
  Computer Principles and Design in Verilog HDL
  by Yamin Li, published by A JOHN WILEY & SONS
************************************************/
module div_restoring (a,b,start,clk,clrn,q,r,busy,ready,count);
    input  [31:0] a;                                            // dividend
    input  [15:0] b;                                            // divisor
    input         start;                                        // start
    input         clk, clrn;                                    // clk,reset
    output [31:0] q;                                            // quotient
    output [15:0] r;                                            // remainder
    output reg    busy;                                         // busy
    output reg    ready;                                        // ready
    output  [4:0] count;                                        // counter
    reg    [31:0] reg_q;
    reg    [15:0] reg_r;
    reg    [15:0] reg_b;
    reg     [4:0] count;
    wire   [16:0] sub_out = {reg_r,reg_q[31]} - {1'b0,reg_b};   // sub
    wire   [15:0] mux_out = sub_out[16]?                        // restoring
                  {reg_r[14:0],reg_q[31]} : sub_out[15:0];      // or not
    assign q = reg_q;
    assign r = reg_r;
    always @ (posedge clk or negedge clrn) begin
        if (!clrn) begin
            busy  <= 0;
            ready <= 0;
        end else begin 
            if (start) begin
                reg_q <= a;                                     // load a
                reg_b <= b;                                     // load b
                reg_r <= 0;
                busy  <= 1;
                ready <= 0;
                count <= 0;
            end else if (busy) begin
                reg_q <= {reg_q[30:0],~sub_out[16]};            // << 1
                reg_r <= mux_out;
                count <= count + 5'b1;                          // counter++
                if (count == 5'h1f) begin                       // finished
                    busy  <= 0;
                    ready <= 1;                                 // q,r ready
                end
            end
        end
    end
endmodule

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/************************************************
  The Verilog HDL code example is from the book
  Computer Principles and Design in Verilog HDL
  by Yamin Li, published by A JOHN WILEY & SONS
************************************************/
module div_nonrestoring (a,b,start,clk,clrn,q,r,busy,ready,count);
    input  [31:0] a;                                            // dividend
    input  [15:0] b;                                            // divisor
    input         start;                                        // start
    input         clk, clrn;                                    // clk,reset
    output [31:0] q;                                            // quotient
    output [15:0] r;                                            // remainder
    output reg    busy;                                         // busy
    output reg    ready;                                        // ready
    output  [4:0] count;                                        // count
    reg    [31:0] reg_q;
    reg    [15:0] reg_r;
    reg    [15:0] reg_b;
    reg     [4:0] count;
    wire   [16:0] sub_add = reg_r[15]?
                  {reg_r,reg_q[31]} + {1'b0,reg_b} :            // + b
                  {reg_r,reg_q[31]} - {1'b0,reg_b};             // - b
    assign q = reg_q;
    assign r = reg_r[15]? reg_r + reg_b : reg_r;                // adjust r
    always @ (posedge clk or negedge clrn) begin
        if (!clrn) begin
            busy  <= 0;
            ready <= 0;
        end else begin
            if (start) begin
                reg_q <= a;                                     // load a
                reg_b <= b;                                     // load b
                reg_r <= 0;
                busy  <= 1;
                ready <= 0;
                count <= 0;
            end else if (busy) begin
                reg_q <= {reg_q[30:0],~sub_add[16]};            // << 1
                reg_r <= sub_add[15:0];
                count <= count + 5'b1;                          // count++
                if (count == 5'h1f) begin                       // finish
                    busy  <= 0;
                    ready <= 1;                                 // q,r ready
                end
            end
        end
    end
endmodule