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Is booth algorithm for multiplication only for multiplying 2 negative numbers (-3 * -4) or one positive and one negative number (-3 * 4) ? Whenever i multiply 2 positive numbers using booth algorithm i get a wrong result.

example : 5 * 4

A = 101 000 0 // binary of 5 is 101

S = 011 000 0 // 2's complement of 5 is 011

P = 000 100 0 // binary of 4 is 100

x = 3 number of bits in m

y = 3 number of bits in r

m = 5

-m = 2's complement of m

r = 4

  1. After right shift of P by 1 bit 0 000 100

  2. After right shift of P by 1 bit 0 000 010

  3. P+S = 011 001 0

    After right shift by 1 bit 0 011 001

  4. Discarding the LSB 001100

    But that comes out to be the binary of 12 . It should have been 20(010100)

UPDATE after @ ruakh answer

5 * 4 = 20

m = 0101 is 5

r = 0100 is 4

A = 0101 0000 0

S = 1010 0000 0

P = 0000 0100 0

  1. shift P right by 1 bit : 0 0000 0100

  2. shift P right by 1 bit : 0 0000 0010

  3. P+S = 10100010 Shifting rightby 1 bit : 1101 0001

  4. P+A = 1 0010 0001 here 1 is the carry generated shifting right by 1 bit : 110010000

Leave the LSB : 11001000 (not equal to 20)

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5 Answers

up vote 3 down vote accepted

You're not giving enough room for your sign handling. 5 is not 101, but 0101: it has to start with a 0, because values starting with 1 are negative. 101 is actually -3: it's the two's complement of 011, which is 3. Similarly, 4 is not 100, but 0100; 100 is -4. So when you multiply 101 by 100, you're actually multiplying -3 by -4; that's why you get 12.

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please see the update. I still don't get the result . What is wrong ? –  saplingPro Nov 19 '11 at 4:48
    
@grassPro: Now your S is wrong: you inverted the bits, but forgot to add 1. :-) –  ruakh Nov 19 '11 at 4:55
    
yes i made a mistake.After correcting it and computing P+A in the 4th step there is a carry generated in the MSB of P+A . If i omit it i get the correct answer. But why do we have to omit it. Like in the 4th step : P+A = 110110001 + 010100000 = 1 001010001 , see the carry generated (1) in the MSB . If i omit it i will get the right answer in the next step where i have to omit the LSB of the number. –  saplingPro Nov 19 '11 at 5:09
    
@grassPro: Re: "why do we have to omit it": Well, because that's what the algorithm says to do. (The Wikipedia article that you linked to says to "Ignore any overflow.") If you want a deeper reason, remember that 1011 means the same as ...11111011, not ...00001011. So if you performed sign extension, this carried 1 would actually continue to carry leftward indefinitely, changing all the 1s to 0s along the way. –  ruakh Nov 19 '11 at 5:39
    
@ ruakh I am getting a wrong result when i multiply 11*13 using booth algo. I get 0010001111 but i should get 10001111 . Two zeros in the MSB's are missing. Will it make a difference –  saplingPro Nov 19 '11 at 7:23
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Booth's algorithm is for signed integers, that is, each can be either positive or negative or zero.

Here's a sample C program that illustrates both an implementation and intermediate results of multiplying two 8-bit signed (2's complement) integers and getting a 16-bit signed product:

#include <stdio.h>
#include <limits.h>
#include <string.h>

typedef signed char int8;
typedef short int16;

char* Num2BaseStr(unsigned long long num, unsigned base, int maxDigits)
{
  static char s[sizeof(num) * CHAR_BIT + 1];
  char* p = &s[sizeof(s) - 1];

  memset(s, 0, sizeof(s));

  do
  {
    *--p = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"[num % base];
    num /= base;
  } while ((num != 0) || (p > s));

  // Keep at most maxDigits digits if requested
  if ((maxDigits >= 0) && (&s[sizeof(s) - 1] - p > maxDigits))
  {
    p = &s[sizeof(s) - 1] - maxDigits;
  }
  // Skip leading zeroes otherwise
  else
  {
    while (*p == '0') p++;
  }

  return p;
}

int16 BoothMul(int8 a, int8 b)
{
  int16 result = 0;
  int16 bb = b;
  int f0 = 0, f1;
  int i = 8;

  printf("a = %sb (%d)\n", Num2BaseStr(a, 2, 8), a);
  printf("b = %sb (%d)\n", Num2BaseStr(b, 2, 8), b);
  printf("\n");

  while (i--)
  {
    f1 = a & 1;
    a >>= 1;

    printf("        %sb\n", Num2BaseStr(result, 2, 16));
    printf("(%d%d)  ", f1, f0);
    if (!f1 && f0)
    {
      printf("+ %sb\n", Num2BaseStr(bb, 2, 16));
      result += bb;
    }
    else if (f1 && !f0)
    {
      printf("- %sb\n", Num2BaseStr(bb, 2, 16));
      result -= bb;
    }
    else
    {
      printf("no +/-\n");
    }
    printf("\n");

    bb <<= 1;

    f0 = f1;
  }

  printf("a * b = %sb (%d)\n", Num2BaseStr(result, 2, 16), result);

  return result;
}

int main(void)
{
  const int8 testData[][2] =
  {
    {  4,  5 },
    {  4, -5 },
    { -4,  5 },
    { -4, -5 },
    {  5,  4 },
    {  5, -4 },
    { -5,  4 },
    { -5, -4 },
  };
  int i;

  for (i = 0; i < sizeof(testData)/sizeof(testData[0]); i++)
    printf("%d * %d = %d\n\n",
           testData[i][0],
           testData[i][1],
           BoothMul(testData[i][0], testData[i][1]));

  return 0;
}

Output:

a = 00000100b (4)
b = 00000101b (5)

        0000000000000000b
(00)  no +/-

        0000000000000000b
(00)  no +/-

        0000000000000000b
(10)  - 0000000000010100b

        1111111111101100b
(01)  + 0000000000101000b

        0000000000010100b
(00)  no +/-

        0000000000010100b
(00)  no +/-

        0000000000010100b
(00)  no +/-

        0000000000010100b
(00)  no +/-

a * b = 0000000000010100b (20)
4 * 5 = 20

a = 00000100b (4)
b = 11111011b (-5)

        0000000000000000b
(00)  no +/-

        0000000000000000b
(00)  no +/-

        0000000000000000b
(10)  - 1111111111101100b

        0000000000010100b
(01)  + 1111111111011000b

        1111111111101100b
(00)  no +/-

        1111111111101100b
(00)  no +/-

        1111111111101100b
(00)  no +/-

        1111111111101100b
(00)  no +/-

a * b = 1111111111101100b (-20)
4 * -5 = -20

a = 11111100b (-4)
b = 00000101b (5)

        0000000000000000b
(00)  no +/-

        0000000000000000b
(00)  no +/-

        0000000000000000b
(10)  - 0000000000010100b

        1111111111101100b
(11)  no +/-

        1111111111101100b
(11)  no +/-

        1111111111101100b
(11)  no +/-

        1111111111101100b
(11)  no +/-

        1111111111101100b
(11)  no +/-

a * b = 1111111111101100b (-20)
-4 * 5 = -20

a = 11111100b (-4)
b = 11111011b (-5)

        0000000000000000b
(00)  no +/-

        0000000000000000b
(00)  no +/-

        0000000000000000b
(10)  - 1111111111101100b

        0000000000010100b
(11)  no +/-

        0000000000010100b
(11)  no +/-

        0000000000010100b
(11)  no +/-

        0000000000010100b
(11)  no +/-

        0000000000010100b
(11)  no +/-

a * b = 0000000000010100b (20)
-4 * -5 = 20

a = 00000101b (5)
b = 00000100b (4)

        0000000000000000b
(10)  - 0000000000000100b

        1111111111111100b
(01)  + 0000000000001000b

        0000000000000100b
(10)  - 0000000000010000b

        1111111111110100b
(01)  + 0000000000100000b

        0000000000010100b
(00)  no +/-

        0000000000010100b
(00)  no +/-

        0000000000010100b
(00)  no +/-

        0000000000010100b
(00)  no +/-

a * b = 0000000000010100b (20)
5 * 4 = 20

a = 00000101b (5)
b = 11111100b (-4)

        0000000000000000b
(10)  - 1111111111111100b

        0000000000000100b
(01)  + 1111111111111000b

        1111111111111100b
(10)  - 1111111111110000b

        0000000000001100b
(01)  + 1111111111100000b

        1111111111101100b
(00)  no +/-

        1111111111101100b
(00)  no +/-

        1111111111101100b
(00)  no +/-

        1111111111101100b
(00)  no +/-

a * b = 1111111111101100b (-20)
5 * -4 = -20

a = 11111011b (-5)
b = 00000100b (4)

        0000000000000000b
(10)  - 0000000000000100b

        1111111111111100b
(11)  no +/-

        1111111111111100b
(01)  + 0000000000010000b

        0000000000001100b
(10)  - 0000000000100000b

        1111111111101100b
(11)  no +/-

        1111111111101100b
(11)  no +/-

        1111111111101100b
(11)  no +/-

        1111111111101100b
(11)  no +/-

a * b = 1111111111101100b (-20)
-5 * 4 = -20

a = 11111011b (-5)
b = 11111100b (-4)

        0000000000000000b
(10)  - 1111111111111100b

        0000000000000100b
(11)  no +/-

        0000000000000100b
(01)  + 1111111111110000b

        1111111111110100b
(10)  - 1111111111100000b

        0000000000010100b
(11)  no +/-

        0000000000010100b
(11)  no +/-

        0000000000010100b
(11)  no +/-

        0000000000010100b
(11)  no +/-

a * b = 0000000000010100b (20)
-5 * -4 = 20
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I think x should be 2 instead of 3 -- since 3 is 11, only two bits long.

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5*4 =20

m=5,r=4,x=y=4

m=0101 , r=0100 , -m=1011 ,x=y=4

A=0101 0000 0
S=1011 0000 0
P=0000 0100 0

1.  P=0000 0100 0       //last two bits are 00 so simply shift P

    P=0000 0010 0

2.  P=0000 0010 0      //last two bits are 00 so simply shift P

    P=0000 0001 0

3.  P=0000 0001 0      //last two bits are 10 so perform  P = P+S

    P=1011 0001 0

    P=1101 1000 1     // after shifting P

4.  P=1101 1000 1     //last two bits are 01 so perform P = P+A

    P=0010 1000 1

    P=0001 0100 0       // after shifting P


5. now remove LSB 

   the product is P=00010100(20)
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Below, an implementation of Booth's Algorithm according to its flowchart illustrated in chapter 9 in the so called book "Computer Organization and Architecture, eighth edition - William Stallings. This program multiplies two numbers represented in 4 bits. When VERBOSE == 1, the program shows the different steps of the algorithm. PS: The program manipulates numbers as strings.

Good luck!

#include <stdio.h>
#define WORD 4
#define VERBOSE 1 //0

/*
 * CSC 2304 - Al Akhawayn University
 * Implementation of the Booth's Algorithm.
 */

void twosComplementAddition(char[], char[]);
void rightShift(char[], char);
void addition(char[], char[]);

char* twosComplementMultiplication(char M[], char Q[]) {
    char C;
    char *A = (char*) malloc(sizeof(char)*(2 * WORD + 1));
    char processedQ[WORD+ 1];
    char Q0, Q_1 = '0';
    int i, j;
    strcpy(A, "0000");
    if (VERBOSE) {
        printf("\n  A   |   Q   |   M   |");
        printf("\n  %s  |   %s  |   %s  |   Initial", A, Q, M);
        printf("\n-------------------------------------------------------------");
    }
    for (i = 0, j = 1; i < WORD; i++, j++) {
        Q0 = Q[WORD - 1];
        if (VERBOSE) {
            printf("\n  %s  |   %s  |   %s  |   Cycle %d", A, Q, M, j);
        }
        if (Q0 == '0' && Q_1 == '1') {
            addition(A, M);
            if (VERBOSE) {
                printf("\n  %s  |   %s  |   %s  |   Addition", A, Q, M);
            }
        } else {
            if (Q0 == '1' && Q_1 == '0') {
                twosComplementAddition(A, M);
                if (VERBOSE) {
                    printf("\n  %s  |   %s  |   %s  |   Two's Complement", A, Q, M);
                }
            }
        }
        Q_1 = Q[WORD - 1];
        rightShift(Q, A[WORD - 1]);
        rightShift(A, A[0]);
        if (VERBOSE) {
            printf("\n  %s  |   %s  |   %s  |   Right Shift", A, Q, M);
            getch();
        }
        printf("\n-------------------------------------------------------------");
    }
    strcat(A, Q);
    return A;
}
void rightShift(char reg[], char bit) {
    int i;
    for (i = WORD - 1; i > 0; i--) {
        reg[i] = reg[i - 1];
    }
    reg[0] = bit;
}

void addition(char A[], char M[]) {
    int i;
    char c = '0';
    for (i = WORD - 1; i >= 0; i--) {
        if (A[i] == '0' && M[i] == '0') {
            A[i] = c;
            c = '0';
        } else {
            if ((A[i] == '1' && M[i] == '0') || (A[i] == '0' && M[i] == '1')) {
                if (c == '0') {
                    A[i] = '1';
                } else {
                    A[i] = '0';
                }
            } else {
                if (A[i] == '1' && M[i] == '1') {
                    A[i] = c;
                    c = '1';
                }
            }
        }
    }
}
void twosComplementAddition(char A[], char M[]) {
    int i;
    char temp[WORD + 1];
    for (i = 0; i < WORD; i++) {
        if (M[i] == '0') {
            temp[i] = '1';
        } else {
            temp[i] = '0';
        }
    }
    temp[WORD] = '\0';
    addition(temp, "0001");
    addition(A, temp);
}

int main() {
    char QQ[WORD + 1];
    char M[WORD + 1];
    char Q[WORD + 1];
    char *result;

    printf("\nBooth's Algorithm");
    printf("\n*****************");
    printf("\nEnter M: ");
    scanf("%s", M);
    printf("\nEnter Q: ");
    scanf("%s", Q);
    strcpy(QQ, Q);
    result = twosComplementMultiplication(M, Q);
    printf("\n%s * %s = %s", M, QQ, result);

    printf("\n");
    return 0;

}
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