42

I assume that calculating the modulus of a number is a somewhat expensive operation, at least compared to simple arithmetic tests (such as seeing if a number exceeds the length of an array). If this is indeed the case, is it more efficient to replace, for example, the following code:

res = array[(i + 1) % len];

with the following? :

res = array[(i + 1 == len) ? 0 : i + 1];

The first one is easier on the eyes, but I wonder if the second might be more efficient. If so, might I expect an optimizing compiler to replace the first snippet with the second, when a compiled language is used?

Of course this "optimization" (if it is indeed an optimization) doesn't work in all cases (in this case, it only works if i+1 is never more than len).

  • 12
    This might be a case of missing the forest for the trees. – Burhan Khalid Mar 24 '13 at 7:58
  • 1
    if len is a compile-time constant a recent GCC compiler (with -02) is usually doing clever things, often avoiding the modulus machine instruction of the target processor. – Basile Starynkevitch Mar 24 '13 at 7:59
  • 2
    This really is the kind of optimization you should forget about. The optimizing compiler will do better than you could. What matters much more is the readability of your code. – Basile Starynkevitch Mar 24 '13 at 8:04
  • Or you could make the array 1 longer, and copy the first element into the new last element so you can access it normally. Any of these three options may be the fastest, depending on circumstances. – harold Mar 24 '13 at 12:08
  • 1
    This is usually used in circular queues – Muhammad Annaqeeb Dec 13 '13 at 19:29
29

My general advice is as follows. Use whichever version you think is easier on the eye, and then profile your entire system. Only optimize those parts of the code that the profiler flags up as bottlenecks. I'll bet my bottom dollar that the modulo operator isn't going to be among them.

As far as the specific example goes, only benchmarking can tell which is faster on your specific architecture using your specific compiler. You are potentially replacing modulo with branching, and it's anything but obvious which would be faster.

  • 1
    On recent machines integer arithmetic is nearly free; what matter much more is cache misses..... which are much more costly. an L1 cache miss stalls the processor for hundreds of cycles, during which the processor could do dozens of divisions or modulus; so the eventual cost of the modulus is noise – Basile Starynkevitch Mar 24 '13 at 8:00
  • 3
    @BasileStarynkevitch: Well, cache behaviour is going to be identical between the two code snippets. What's going to matter is whether or not version #2 uses branching and, if it does, how good a job the branch predictor is going to do. – NPE Mar 24 '13 at 8:02
  • @Basile Starynkevitch I've seen a factor of about 300 between modulo vs accessing a big table on a laptop. (Adding a test for divisibility by 17 squared to avoid the array access was still beneficial.) – starblue Mar 24 '13 at 9:44
  • @NPE It might be worthwhile to add to this answer that the C language itself doesn't have speed; That's a quality of the implementation (eg. "your specific architecture"). In addition to being dependent upon hardware, "the speed of the modulo operator" is dependent upon the quality of the compiler building code for the hardware; A poor one might use the assembly equivalent of int foo = 54321; int bar = foo / 10000; foo -= bar * 10000; to obtain the modulo, while a good quality compiler might even optimise that code. – autistic Mar 24 '13 at 10:49
25

Some simple measurement:

#include <stdio.h>
#include <stdlib.h>

int main(int argc, char *argv[])
{
    int test = atoi(argv[1]);
    int divisor = atoi(argv[2]);
    int iterations = atoi(argv[3]);

    int a = 0;

    if (test == 0) {
        for (int i = 0; i < iterations; i++)
            a = (a + 1) % divisor;
    } else if (test == 1) {
        for (int i = 0; i < iterations; i++)
            a = a + 1 == divisor ? 0 : a + 1;
    }

    printf("%d\n", a);
}

Compiling with either gcc or clang with -O3, and running time ./a.out 0 42 1000000000 (modulo version) or time ./a.out 1 42 1000000000 (comparison version) results in

  • 6.25 seconds user runtime for the modulo version,
  • 1.03 seconds for the comparison version.

(using gcc 5.2.1 or clang 3.6.2; Intel Core i5-4690K @ 3.50GHz; 64-bit Linux)

This means that it is probably a good idea to use the comparison version.

  • 3
    On more realistic data (for example if number would be a random) then difference would not be that big – user1209304 Oct 24 '16 at 12:23
  • 8
    The comparison version is only faster because the result of the if statement is the same every time, so the branch predictor gets it right every time. If you randomized the input, the comparison version might even be worse than mod – Bigminimus Jun 26 '17 at 10:39
  • 1
    @Bigminimus Hmm but the result of the if clause is the same for both tests all the time? – Baris Demiray Aug 9 '17 at 12:54
3

Well, have a look at 2 ways to get the next value of a "modulo 3" cyclic counter.

int next1(int n) {
    return (n + 1) % 3;
}

int next2(int n) {
    return n == 2 ? 0 : n + 1;
}

I've compiled it with gcc -O3 option (for the common x64 architecture), and -s to get the assembly code.

The code for the first function does some unexplainable magic (*) to avoid a division, using a multiplication anyway:

addl    $1, %edi
movl    $1431655766, %edx
movl    %edi, %eax
imull   %edx
movl    %edi, %eax
sarl    $31, %eax
subl    %eax, %edx
leal    (%rdx,%rdx,2), %eax
subl    %eax, %edi
movl    %edi, %eax
ret

And is much longer (and I bet slower) than the second function:

leal    1(%rdi), %eax
cmpl    $2, %edi
movl    $0, %edx
cmove   %edx, %eax
ret

So it is not always true that "the (modern) compiler does a better job than you anyway".

Interestingly, the same experiment with 4 instead of 3 leads to a and-masking for the first function

addl    $1, %edi
movl    %edi, %edx
sarl    $31, %edx
shrl    $30, %edx
leal    (%rdi,%rdx), %eax
andl    $3, %eax
subl    %edx, %eax
ret

but it is still, and by large, inferior to the second version.

Being more explicit about proper ways to do the things

int next3(int n) {
    return (n + 1) & 3;;
}

yields much better results :

leal    1(%rdi), %eax
andl    $3, %eax
ret

(*) well, not that complicated. Multiplication by reciprocical. Compute the integer constant K = (2^N)/3, for some large enough value of N. Now, when you want the value of X/3, instead of a division by 3, compute X*K, and shift it N positions to the right.

  • The comparison in the second version might make it inferior to the first version; if it doesn't regularly predict the correct branch, that's going to screw up the pipeline. Still, +1 for demonstrating that modern compilers do not always magically find the best possible machine code. – Ray Sep 24 '18 at 16:59
  • @Ray as far as I understand, conditional move have been added to the instruction set (Pentium Pro) so no branch prediction takes place at all "The CMOVcc instructions are useful for optimizing small IF constructions. They also help eliminate branching overhead for IF statements and the possibility of branch mispredictions by the processor. " Pentium-Pro Family Developers Manual, vol 2, p 6.14. phatcode.net/res/231/files/24269101.pdf – Michel Billaud Sep 25 '18 at 10:08
  • Michel Billaud: Looks like you're right. I saw the cmpl and completely overlooked the lack of a jump. – Ray Sep 25 '18 at 15:20
0

If 'len' in your code is big enough, then the conditional will be faster, as the branch predictors will nearly always guess correctly.

If not, then I believe this is closely connected to circular queues, where it is often the case that the length is a power of 2. This will enable the compiler to substitute modulo with a simple AND.

The code is the following:

#include <stdio.h>
#include <stdlib.h>

#define modulo

int main()
{
    int iterations = 1000000000;
    int size = 16;
    int a[size];
    unsigned long long res = 0;
    int i, j;

    for (i=0;i<size;i++)
        a[i] = i;

    for (i=0,j=0;i<iterations;i++)
    {
        j++;
        #ifdef modulo
            j %= size;
        #else
            if (j >= size)
                j = 0;
        #endif
        res += a[j];
    }

    printf("%llu\n", res);
}

size=15:

  • modulo: 4,868s
  • cond: 1,291s

size=16:

  • modulo: 1,067s
  • cond: 1,599s

Compiled in gcc 7.3.0 , with -O3 optimization. The machine is an i7 920.

  • I wonder why the cond version's time is not the same in both cases. – Doug Currie Apr 17 at 14:35
  • I think that, because res is not volatile, gcc can do many optimizations that are less effective as the size is increasing. When I add 'volatile' to res the times for the conditional are always around 2 sec. For modulo around 2 sec when power of 2 and not stable (above 4 sec, increasing with the size) otherwise. – J. Doe Apr 17 at 15:05
  • I also noticed that in the case of non-volatile res, for 1024 size the conditional runs faster, in 1 sec, so I guess it's about 'good' and 'bad' sizes for the optimizations (or branch predictors?). – J. Doe Apr 17 at 15:14
-3

Modulo can be done with a single processor instruction on most architectures (ex. DIV on x86). However it's likely a premature optimization for what you need.

  • 25
    Just becuase there is a single instruction for an operation, doesn't mean it occurs in a single clock cycle. – Chris Desjardins Mar 24 '13 at 8:46
  • 2
    @ChrisDesjardins Agreed, but % if the second operator is power of 2 can be represented as a bit mask. – Alex Mar 24 '13 at 8:49
  • 11
    Sorry had to downvote. I have worked with a lot of architectures (but not x86) and have yet to work with one that accomplishes mod/div in one instruction. And I have seen apps where mod is one of the top 10 CPU consuming function calls because of all of the circular buffering - each "sample" copy followed by a % buffersize. In my case I try to avoid mod if I can - usually by asserting that input buffer sizes are divisible by 2 so the compiler can optimize away the mod. – c.fogelklou Mar 25 '13 at 5:22
  • @c.fogelklou good point. branch prediction works well for ring buffers on iterations. one may think branching is more expensive than modulo and probably missed the opportunity to use it. – M.kazem Akhgary Dec 24 '17 at 18:17
  • div is the slowest integer ALU operation by far. Like 35 to 90 cycle latency on Skylake for div r64, vs. 3 cycle latency for imul r64, r64. Related: C++ code for testing the Collatz conjecture faster than hand-written assembly - why?/ shows just how slow div is, especially vs. a shift for a power of 2. – Peter Cordes Mar 4 at 22:19

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