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Fast modulo 3 or division algorithm?

Everyone knows that modulo arithmetic can be a huge drawback on performance. Does anyone know of a good alternative for x%3 operations? I know that one exists for x%2, but I really need one for modulo 3 since I want to alternate between three buffers in a for loop.


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marked as duplicate by Bart, Mike Samuel, Bo Persson, EJP, Toon Krijthe Nov 15 '11 at 21:30

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Unless your code bottlenecks at the modulo, it's going to be a case of premature optimization. –  moshbear Nov 15 '11 at 19:16
I suggest you to first check where the bottleneck lies. I highly doubt it's the modulo... –  m0skit0 Nov 15 '11 at 19:18
Everyone knows that attempting to out-optimize the compiler's modulo optimizations can be a huge drawback on developer efficiency. –  recursive Nov 15 '11 at 19:25
"Everyone knows ..." Do they? –  EJP Nov 15 '11 at 21:08
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3 Answers

up vote 9 down vote accepted

Well instead of the usual "measure it" stuff an actual answer - because that stuff is actually real fun math. Although the compiler could and probably does this as well (at least modern optimizing c++ compilers, javac certainly won't and I've got no idea if the JVM does this) - so better check if it isn't already doing the work for you.

But still fun to know the theory behind the optimization: I'll use assembly because we need the higher 32bit word of a multiplication. The following is from Warren's book on bit twiddling:

n is the input integer we want the modulo from:

li M, 0x55555556   ; load magical number (2^32 + 2) / 3
mulhs q, M, n      ; q = higher word of M * n; i.e. q = floor(M*n / 2^32)
shri t, n, 31      ; add 1 to q if it is negative
add q, q, t

Here q contains the divisor of n / 3 so we just compute the remainder as usual: r = n - q*3

The math is the interesting part - latex would be rather cool here:

q = Floor( (2^32+2)/ 3 * (n / 2^32) ) = Floor( n/3 + 2*n/(3*2^32) )

Now for n = 2^31-1 (largest n possible for signed 32bit integers) the error term is less than 1/3 (and non negative) which makes it quite easy to show that the result is indeed correct. For n = -2^31 we have the correction by 1 above and if you simplify that you'll see that the error term is always larger than -1/3 which means it holds for negative numbers as well.

I leave the proof with the error term bounds for the interested - it's not that hard.

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The gcc genrate almost the same as you wrote: int f(int n) { return n / 3; 0: 89 f8 mov %edi,%eax 2: ba 56 55 55 55 mov $0x55555556,%edx 7: c1 ff 1f sar $0x1f,%edi a: f7 ea imul %edx c: 29 fa sub %edi,%edx } e: 89 d0 mov %edx,%eax 10: c3 retq –  user1034749 Nov 15 '11 at 20:15
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If 3 is known at compile time, then the compiler will generate the 'tricks' to do it as efficiently as possible. Modulo takes much longer when the divisor is unknown until run-time.

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If it's in a straight loop, no need to calculate a modulo. Hold a second int var that you reset every 3 steps.

int i, bn = 0;

for(i=0; i<whatever; i++) {
  if(++bn == 3) bn = 0;

And that is not a premature optimisation, it's avoiding unecessary calculation.

EDIT: It was stated in OP that he was using a loop to switch between buffers, so my solution looks quite appropriate. As for the downvote, if it was a mistake, no problem.

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@Stefan If it's really a loop this is almost certainly faster than ANY other possible solution on a modern x86 cpu. Why? Because the branch predictior in modern CPUs (that is for high performance CPUs.. x86, Power and so on - quite certainly not ARM) WILL get such a simple recurring pattern. Hence we replace my above calculation which still includes two imuls, shifts, an add, (or the other possibility with lots of adds, shifts,..) with a branch and a mov reg, 0 instruction. Why do you think this would be slower? –  Voo Nov 15 '11 at 20:10
Sorry my mistake. Shouldnt downvote while waiting for a deployment. I really thought he was calculating modulo through a loop. Can you edit answer a space orsomething so i can undo the downvote? It doesnt answer the exact question for efficient modulo but is probably the best answer for the actual need. –  Stefan Nov 15 '11 at 20:17
You mean if it is in a loop and you need the modulo 3 of the loop index. Either way this is most definately premature optimization since it reduces code clarity and more importantly it isn't even guranteed to be an optimization, since the compiler might be able to understand the modulo better then the if and therefore make better code. Or it might not, who knows. If neither the modulo nor the if is optimized and you work on a platform with bad/no branchprdiction the modulo might even be faster due to not incurring pipeline stalls. –  Grizzly Nov 15 '11 at 20:21
@Stefan I fear only if he edited the answer in a significant way (no idea what exactly SO defines as significant). But I'm sure a heartfelt sorry is all he will need :) The -2 points aren't that problematic –  Voo Nov 15 '11 at 20:23
@Grizzly Even if the mod 3 IS optimized as in my answer it will be significantly (well significantly for a handful instructions - we're talking <30 cycles difference here) faster still to do it this way around. –  Voo Nov 15 '11 at 20:24
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