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You could write something like:

int i = 3;
int k = 2;
int division = i / k;
int remainder = i % k;

It seems as thought this would, on a low level, ask an ALU to perform two vision operations: one returning the quotient, and one returning the remainder. However, I believe an ALU would most likely calculate both in a single operation. If that is the case, this is not optimally efficient.

Is there a more efficient way of doing it, without asking the CPU to calculate twice? In other words, can it be done in a single operation from C++?

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Why do you think "this is not optimally efficient" ? Quite a few reasonable compilers see that i and k don't change, and therefore merge the two calculations. C++ is not assembly; compilers just have to ensure the result is as expected. –  MSalters Sep 15 '11 at 9:12
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5 Answers 5

up vote 8 down vote accepted

Actually, the code you wrote won't generate any division instructions since the compiler can figure out the results at compile time. I wrote a little test program and set the compiler (VC++ 10SP1) to generate an assembly code listing.

#include <iostream>

using namespace std;

struct result {
    long quotient, remainder;
};

result divide(long num, long den) {
    result d = { num / den, num % den };
    return d;
}

int main() {
    result d = divide(3, 2);
    d = divide(10, 3);
    cout << d.quotient << " : " << d.remainder << endl;
    return 0;
}

I had to write it this way and explicitly tell the compiler to not inline any functions. Otherwise the compiler would have happily optimized away most of the code. Here is the resulting assembly code for the divide function.

; 8    : result divide(long num, long den) {

  00000 55       push    ebp
  00001 8b ec        mov     ebp, esp

; 9    :     result d = { num / den, num % den };

  00003 99       cdq
  00004 f7 7d 08     idiv    DWORD PTR _den$[ebp]

; 10   :     return d;
; 11   : }

  00007 5d       pop     ebp
  00008 c3       ret     0

It's smart enough to generate a single IDIV instruction and use the quotient and remainder generated by it. Modern C and C++ compilers have gotten really good at this sort of optimization. Unless you have a performance problem and have profiled you code to determine where the bottleneck is, don't try to second guess the compiler.

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THIS is the sort of answer I was looking for! –  Adam S Sep 27 '11 at 17:53
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Sure:

int i = 3;
int k = 2;
int division = i / k;
int remainder = i - division * k;

Also, if you really want to do this, look at div, I doubt it's faster though, just like my above solution.

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I think you mean: int remainder = i - division * k; –  Mysticial Sep 14 '11 at 22:50
1  
I think you found the one case where this works correctly –  Falmarri Sep 14 '11 at 22:50
    
I think you have a bug. –  Mark Ransom Sep 14 '11 at 22:50
    
@Mysticial: Oh dear, let me edit that in :) EDIT: Oh haha, not it's working perfectly fine ;) –  nightcracker Sep 14 '11 at 22:50
1  
Don't get bent out of shape - I un-downvoted it. I was expecting either an operation that reduces the number of operations done by an ALU, or a "no, that doesn't exist". –  Adam S Sep 14 '11 at 23:28
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ISO C99 has the ldiv function:

#include <stdlib.h>

ldiv_t ldiv(long numer, long denom);

The ldiv() function computes the value numer/denom (numerator/denominator).
It returns the quotient and remainder in a structure named ldiv_t that contains
two long members named quot and rem.

Whether at the FPU level that reduces to a single operation I couldn't say.

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I'm not aware of anything built-in, but you can simulate it with a multiply instead of a divide:

int division = i / k;
int remainder = i - (division * k);
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When you ask yourself, what is fastest, it's usually a good idea to benchmark it (I like to do that). So I took the answers from here and wrote a tiny benchmarking program and threw it at gcc (similar results would be expected for g++ I think) at -O0 (at -O1 he optimises everything away and my benchmark is broken).

I performed 2^28 runs (both i and k running from 1 to 2^14) on my laptop and got the following runtimes:

division = 0;
remainder = 0;
// this test is only there to measure the constant overhead!

1.676s

division = i/k;
remainder = i%k;

24.614s

division = i/k;
remainder = i - division*k;

15.009s

ldiv_t d = ldiv(i,k);
division = d.quot;
remainder = d.rem;

18.845s

As one can see, there is a difference and your best shot is the multiplication approach. The ldiv approach is also okay, but I find it slightly cumbersome compared to the others.

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Well, with more or less no optimization, your results are not really surprising. However, this does not really tell OP what to use in a highly optimized application. –  arne Sep 15 '11 at 5:17
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