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:

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

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.

`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