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I need some easy way to divide 64b unsigned integers in assembler for x86. My number is saved in two 32b registers EDX:EAX and I need to put result back to EDX:EAX. Factor is in 32b integer. Some code, please?

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Just for clarification, do you mean with or without using x64 instructions? That is, is this just a matter of getting the data into 64 bit registers (eg RAX), doing 64 bit division, then splitting them back up into 32 bit registers, or are you trying to emulate 64 bit division on a 32 bit processor? –  WeirdlyCheezy Oct 18 '12 at 23:16
    
Without 64b reg - I'm trying to emulate 64b division on 32b. –  Nick Oct 18 '12 at 23:21
    
If that's the case, it sounds like you're basically implementing binary division from almost-scratch. That seems a little broad for a SO question, imo. What have you tried so far? Is there a more-specific part you're stuck on? –  WeirdlyCheezy Oct 18 '12 at 23:29
    
I need some idea, how to do that. I don't need any check's (owerflows, div by 0, sign control) or something. Just divide and save. I think, this is about 15 lines of code :) –  Nick Oct 18 '12 at 23:41
    
I'll see what I can scratch together tomorrow if no one else has posted a solution by then. –  WeirdlyCheezy Oct 18 '12 at 23:56

3 Answers 3

up vote 1 down vote accepted

If I interpret your question correctly (particularly the part Factor is in 32b integer), you want to divide a 64-bit dividend by a 32-bit divisor and get a 64-bit quotient.

If that interpretation is correct, then it's actually easy to do in 32-bit code.

The idea is that you divide both "halves" of the dividend by the divisor and reuse the remainder from the first division for the second division.

C code illustrating how to do it:

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

#define C_ASSERT(expr) extern char CAssertExtern[(expr)?1:-1]

#if UINT_MAX >= 0xFFFFFFFF
typedef unsigned int uint32;
#else
typedef unsigned long uint32;
#endif
typedef unsigned long long uint64;

typedef unsigned long ulong;

// Make sure uint32=32 bits and uint64=64 bits
C_ASSERT(sizeof(uint32) * CHAR_BIT == 32);
C_ASSERT(sizeof(uint64) * CHAR_BIT == 64);

int div64by32eq64(uint64* dividend, uint32 divisor)
{
  uint32 dividendHi = (uint32)(*dividend >> 32);
  uint32 dividendLo = (uint32)*dividend;
  uint32 quotientHi;
  uint32 quotientLo;

  if (divisor == 0)
    return 0;

  // This can be done as one 32-bit DIV, e.g. "div ecx"
  quotientHi = dividendHi / divisor;
  dividendHi = dividendHi % divisor;

  // This can be done as another 32-bit DIV, e.g. "div ecx"
  quotientLo = (uint32)((((uint64)dividendHi << 32) + dividendLo) / divisor);

  *dividend = ((uint64)quotientHi << 32) + quotientLo;

  return 1;
}

int main(void)
{
  static const struct
  {
    uint64 dividend;
    uint32 divisor;
  } testData[] =
  {
    { 1 , 0 },
    { 0xFFFFFFFFFFFFFFFFULL, 1 },
    { 0xFFFFFFFFFFFFFFFFULL, 2 },
    { 0xFFFFFFFF00000000ULL, 0xFFFFFFFFUL },
    { 0xFFFFFFFFFFFFFFFFULL, 0xFFFFFFFFUL },
  };
  int i;

  for (i = 0; i < sizeof(testData)/sizeof(testData[0]); i++)
  {
    uint64 dividend = testData[i].dividend;
    uint32 divisor = testData[i].divisor;

    printf("0x%016llX / 0x%08lX = ", dividend, (ulong)divisor);

    if (div64by32eq64(&dividend, divisor))
      printf("0x%016llX\n", dividend);
    else
      printf("division by 0 error\n");
  }

  return 0;
}

Output (ideone):

0x0000000000000001 / 0x00000000 = division by 0 error
0xFFFFFFFFFFFFFFFF / 0x00000001 = 0xFFFFFFFFFFFFFFFF
0xFFFFFFFFFFFFFFFF / 0x00000002 = 0x7FFFFFFFFFFFFFFF
0xFFFFFFFF00000000 / 0xFFFFFFFF = 0x0000000100000000
0xFFFFFFFFFFFFFFFF / 0xFFFFFFFF = 0x0000000100000001

And now the equivalent division code in assembly (NASM syntax) without checking for division by 0:

; 64-bit dividend
mov edx, 0xFFFFFFFF
mov eax, 0xFFFFFFFF

; 32-bit divisor
mov ecx, 0xFFFFFFFF

push eax
mov eax, edx
xor edx, edx
div ecx ; get high 32 bits of quotient
xchg eax, [esp] ; store them on stack, get low 32 bits of dividend
div ecx ; get low 32 bits of quotient
pop edx ; 64-bit quotient in edx:eax now
; edx:eax should now be equal 0x0000000100000001
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[SOLVED] .. Wow! Working! Thank you, this is what I need :) ... Thank's all of you! –  Nick Oct 20 '12 at 20:15

What about using the div instruction?

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Of course, but if you have one long number saved in two registers, you can't just use one or two "div". You need some way, how to divide one part of number (EDX), second part of number (EAX), combine results and save final result back into EDX:EAX. I'm looking for this way, how to do that. –  Nick Oct 18 '12 at 23:35
    
Is your divisor also 64-bit? –  Jens Björnhager Oct 19 '12 at 1:03

Quick terminology recap: numerator/divisor = result + remainder/divisor

First check if the divisor is zero (abort if it is).

     test eax,eax
     jne .ok
     test edx,edx
     je .divisionByZero
.ok:

Shift the divisor left until the MSB is set while keeping track of how many shifts you did:

    xor ebp,ebp            ;ebp = bits shifted so far
    test edx,(1 << 31)
    jne .l2
.l1:
    shld edx,eax,1
    shl eax,1
    inc ebp
    test edx,(1 << 31)
    jne .l1
.l2:

Set the current result to zero:

    xor esi,esi
    xor edi,edi

Now shift the divisor back to its original position; while subtracting current divisor from remaining numerator and setting a bit in the result whenever current divisor is less than current numerator:

.nextBit:
    shld edi,esi,1
    shl esi,1

    cmp ecx,edx
    jb .doneBit
    ja .subtract
    cmp ebx,eax
    jb .doneBit

.subtract:
    sub ecx,edx
    sbb ebx,eax
    or esi,1

.doneBit:
    sub ebp,1
    jnc .nextBit

At this point EDX:EAX is the same value it was, EDI:ESI is the result and ECX:EBX is the remainder.

WARNING: All of the above is completely untested. It's just an example/description.

NOTE: If the numbers are signed you need to remove the sign bit from the numerator and divisor first; then set the sign bit in the result and remainder later (sign = numerator_sign XOR divisor_sign).

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