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I have two arrays (dividend, divisor):

dividend[] = {1,2,0,9,8,7,5,6,6};
divisor[] = {9,8};

I need the result (dividend/divisor) as:

quotient[] = {1,2,3,4,5,6,7};

I did this using array subtraction:

  • subtract divisor from dividend until dividend becomes 0 or less than divisor, each time incrementing quotient by 1,

but it takes a huge time. Is there a better way to do this?

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I'm not entirely sure I understand - how do you get the quotient array from the dividend and divisor example you provided? Will your dividend arrays and divisor arrays be of varying lengths? If so, how do you map up which array element from your divisor array matches up with your dividend array? – Adam McKee Jul 23 '10 at 20:42
@Adam: apparently he's dividing 120987566 by 98 which gives 1234567. The issue is that the individual decimal digits are stored in arrays. As James suggests below, he can just implement long division, as taught in elementary school. – Paul R Jul 23 '10 at 20:53
up vote 1 down vote accepted

Is there a better way to do this?

You can use long division.

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Do long division.

Have a temporary storage of size equal to the divisor plus one, and initialized to zero:

accumulator[] = {0,0,0};

Now run a loop:

  1. Shift each digit of the quotient one space to the left.
  2. Shift each digit of the accumulator one space to the right.
  3. Take the next digit of the dividend, starting from the most-significant end, and store it to the least-significant place of the accumulator.
  4. Figure out accumulator / divisor and set the least-significant place of the quotient to the result. Set the accumulator to the remainder.

Used to use this same algorithm a lot in assembly language for CPUs what didn't have division instructions.

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Which brings up the related question, "how do you compute accumulator / divisor?" – Drew Hall Jul 23 '10 at 21:01
Use repeated subtractions, but with this method you'd do about 40 instead of 1,234,567 of them. – Nietzche-jou Jul 23 '10 at 21:17
I don't remember the trick, exactly, but Knuth shows a way to do it with no more than two subtractions (rather than the 40 here) per digit of quotient. TAOCP vol. 2 I think. – Drew Hall Jul 23 '10 at 22:30

Other than that, have you considered using BigInt class (or the equivalent thing in your language) which will already does this for you?

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BigInt class is applicable to only Java i guess and in C++ i'm not aware of anything that serves the purpose. – joshi Jul 23 '10 at 21:55
What about the GNU MP Bignum library - GMP is a free library for arbitrary precision arithmetic, operating on signed integers, rational numbers, and floating point numbers – dsolimano Jul 23 '10 at 23:44
Aye, and there's also OpenSSL's BigNum library. – caf Jul 24 '10 at 5:27

You can use long division

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You can use Long division algorithm or the more general Polynomial Long Division.

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Why not convert them to integers and then use regular division?

in pseudocode:

int dividend_number
foreach i in dividend
    dividend_number *= 10
    dividend_number += i

int divisor_number
foreach i in divisor
    divisor_number *= 10
    divisor_number += i

int answer = dividend_number / divisor_number;
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This can easily cause overflow. If the OP could do this, he probably wouldn't be using arrays in the first place. – IVlad Jul 23 '10 at 20:49
ya that is true, i am working with numbers having 100 digits. – joshi Jul 23 '10 at 20:52
I think the point is that the numbers in the array represent BigInts, that is, they have the potential to be much larger than can fit in an integer. – Drew Hall Jul 23 '10 at 20:53
Ah, thought this was an academic exercise. Looks like he should be using something like GMP then, no? – dsolimano Jul 23 '10 at 23:44

There you go! A is the divident. B is the divisor. C is the integer quotinent R is the rest. Each "huge" number is a vector retaining a big number. In huge[0] we retain the number of digits the number has and thren the number is memorized backwards. Let's say we had the number 1234, then the corespoding vector would be:

v[0]=4; //number of digits


SHL(H,1) does: H=H*10;
SGN(A,B) Compares the A and B numbers
DIVIDHUGE: makes the division using the mentioned procedures...

void Shl(Huge H, int Count)
/* H <- H*10ACount */
    int Sgn(Huge H1, Huge H2) {
      while (H1[0] && !H1[H1[0]]) H1[0]--;
      while (H2[0] && !H2[H2[0]]) H2[0]--;

      if (H1[0] < H2[0]) {
        return -1;
      } else if (H1[0] > H2[0]) {
        return +1;

      for (int i = H1[0]; i > 0; --i) {
        if (H1[i] < H2[i]) {
          return -1;
        } else if (H1[i] > H2[i]) {
          return +1;
      return 0;

        void Subtract(Huge A, Huge B)
        /* A <- A-B */
        { int i, T=0;

          for (i=B[0]+1;i<=A[0];) B[i++]=0;
          for (i=1;i<=A[0];i++)
            A[i]+= (T=(A[i]-=B[i]+T)<0) ? 10 : 0;
          while (!A[A[0]]) A[0]--;

            void DivideHuge(Huge A, Huge B, Huge C, Huge R)
            /* A/B = C rest R */
            { int i;

              for (i=A[0];i;i--)
                { Shl(R,1);R[1]=A[i];
                  while (Sgn(B,R)!=1)
                    { C[i]++;
              while (!C[C[0]] && C[0]>1) C[0]--;
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