I saw the chosen answer to this post.

I was suprised that (x & 255) == (x % 256) if x is an unsigned integer, I wondered if it makes sense to always replace % with & in x % n for n = 2^a (a = [1, ...]) and x being a positive integer.

Since this is a special case in which I as a human can decide because I know with which values the program will deal with and the compiler does not. Can I gain a significant performance boost if my program uses a lot of modulo operations?

Sure, I could just compile and look at the dissassembly. But this would only answer my question for one compiler/architecture. I would like to know if this is in principle faster.

  • 12
    You mean x & 255 == x % 256. And for unsigned arithmetic any compiler worth its salt will produce the same code for both. – StoryTeller Nov 23 '16 at 8:56
  • 31
    Never write "optimized" code. Write code that reflect what you want to do and compiler optimization will do their job. Writing such code decreases readability, portability and often breaks optimization of compiler – Garf365 Nov 23 '16 at 8:59
  • 13
    Your Phd friend sounds like someone who never had to write code in a group and maintain it for long – StoryTeller Nov 23 '16 at 9:03
  • 11
    @Felk, another rule of thumb is to get correct code first, and do benchmarks with optimizations later. It's harder when the code isn't clear. – StoryTeller Nov 23 '16 at 9:05
  • 4
    As you saw, this should make no difference for performance. Personally I usually prefer the bitwise AND, for me it's easier to immediately visualize bitstring being truncated than thinking about modular arithmetic and remembering that remainder by a power of two is the special nice case that I can then again visualize as a bitstring being truncated. – harold Nov 23 '16 at 10:37

If your integral type is unsigned, the compiler will optimize it, and the result will be the same. If it's signed, something is different...

This program:

int mod_signed(int i) {
  return i % 256;
int and_signed(int i) {
  return i & 255;
unsigned mod_unsigned(unsigned int i) {
  return i % 256;
unsigned and_unsigned(unsigned int i) {
  return i & 255;

will be compiled (by GCC 6.2 with -O3; Clang 3.9 produces very similar code) into:

        mov     edx, edi
        sar     edx, 31
        shr     edx, 24
        lea     eax, [rdi+rdx]
        movzx   eax, al
        sub     eax, edx
        movzx   eax, dil
mod_unsigned(unsigned int):
        movzx   eax, dil
and_unsigned(unsigned int):
        movzx   eax, dil

The result assembly of mod_signed is different because

If both operands to a multiplication, division, or modulus expression have the same sign, the result is positive. Otherwise, the result is negative. The result of a modulus operation's sign is implementation-defined.

and AFAICT, most of implementation decided that the result of a modulus expression is always the same as the sign of the first operand. See this documentation.

Hence, mod_signed is optimized to (from nwellnhof's comment):

int d = i < 0 ? 255 : 0;
return ((i + d) & 255) - d;

Logically, we can prove that i % 256 == i & 255 for all unsigned integers, hence, we can trust the compiler to do its job.

  • 3
    If it's signed, something is difference. – Jonas Nov 23 '16 at 9:01
  • 2
    The compiler can't optimize it with n not being static though – Felk Nov 23 '16 at 9:02
  • 2
    @Jonas Fixed that typo – Danh Nov 23 '16 at 9:03
  • 1
    @Felk If we don't know it statically, we can't change it to bitwise and though! If we choose to compare and branching, I don't think it's good – Danh Nov 23 '16 at 9:03
  • 2
    For anyone who's curious, the code generated for mod_signed is equivalent to: int d = i < 0 ? 255 : 0; return ((i + d) & 255) - d; – nwellnhof Nov 23 '16 at 14:49

I did some measurements with gcc, and if the argument of a / or % is a compiled time constant that's a power of 2, gcc can turn it into the corresponding bit operation.

Here are some of my benchmarks for divisions What has a better performance: multiplication or division? and as you can see, the running times with divisors that are statically known powers of two are noticably lower than with other statically known divisors.

So if / and % with statically known power-of-two arguments describe your algorithm better than bit ops, feel free to prefer / and %. You shouldn't lose any performance with a decent compiler.

  • 3
    For / and %, this is only true with unsigned. You won't lose much performance, but implementing signed division by a constant power of 2 takes more than just an arithmetic right shift (to handle the difference in rounding for negative numbers). Similarly, it takes extra work to use a modular multiplicative inverse for div or mod by a non-power-of-2 on a signed integer. – Peter Cordes Nov 23 '16 at 12:57
  • @PeterCordes Thanks. That's good to know. – PSkocik Nov 23 '16 at 13:04
  • @PeterCordes however the compiler is clever enough to know that "(a % b + b) % b" and can be turned into a bit operation. I haven't found an optimizable expression that can turn division into shifting though. – Random832 Nov 23 '16 at 14:14
  • @Random832: I meant for division by a compile-time constant. – Peter Cordes Nov 23 '16 at 22:06

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