# Why is (a % 256) different than (a & 0xFF)?

I always assumed that when doing `(a % 256)` the optimizer would naturally use an efficient bitwise operation, as if I wrote `(a & 0xFF)`.

When testing on compiler explorer gcc-6.2 (-O3):

``````// Type your code here, or load an example.
int mod(int num) {
return num % 256;
}

mod(int):
mov     edx, edi
sar     edx, 31
shr     edx, 24
lea     eax, [rdi+rdx]
movzx   eax, al
sub     eax, edx
ret
``````

And when trying the other code:

``````// Type your code here, or load an example.
int mod(int num) {
return num & 0xFF;
}

mod(int):
movzx   eax, dil
ret
``````

Seems like I'm completely missing something out. Any ideas?

• 0xFF is 255 not 256. Commented Nov 8, 2016 at 9:30
• @RishikeshRaje: So? `%` is not `&` either. Commented Nov 8, 2016 at 9:30
• @RishikeshRaje: I am sure the OP is very much aware of that. They're used with different operations. Commented Nov 8, 2016 at 9:31
• Out of interest, do you get better results if `num` is `unsigned`? Commented Nov 8, 2016 at 9:32
• @RishikeshRaje Bitwise and 0xFF is equivalent to modulo 2^8 for unsigned integers.
– 2501
Commented Nov 8, 2016 at 9:50

It's not the same. Try `num = -79`, and you will get different results from both operations. `(-79) % 256 = -79`, while `(-79) & 0xff` is some positive number.

Using `unsigned int`, the operations are the same, and the code will likely be the same.

PS- Someone commented

They shouldn't be the same, `a % b` is defined as `a - b * floor (a / b)`.

That's not how it is defined in C, C++, Objective-C (ie all the languages where the code in the question would compile).

• Comments are not for extended discussion; this conversation has been moved to chat. Commented Nov 11, 2016 at 0:26

`-1 % 256` yields `-1` and not `255` which is `-1 & 0xFF`. Therefore, the optimization would be incorrect.

C++ has the convention that `(a/b)*b + a%b == a`, which seems quite natural. `a/b` always returns the arithmetic result without the fractional part (truncating towards 0). As a consequence, `a%b` has the same sign as `a` or is 0.

The division `-1/256` yields `0` and hence `-1%256` must be `-1` in order to satisfy the above condition (`(-1%256)*256 + -1%256 == -1`). This is obviously different from `-1&0xFF` which is `0xFF`. Therefore, the compiler cannot optimize the way you want.

The relevant section in the C++ standard [expr.mul §4] as of N4606 states:

For integral operands the `/` operator yields the algebraic quotient with any fractional part discarded; if the quotient `a/b` is representable in the type of the result, `(a/b)*b + a%b` is equal to `a` [...].

## Enabling the optimization

However, using `unsigned` types, the optimization would be completely correct, satisfying the above convention:

``````unsigned(-1)%256 == 0xFF
``````

## Other languages

This is handled very different across different programming languages as you can look up on Wikipedia.

Since C++11, `num % 256` has to be non-positive if `num` is negative.

So the bit pattern would depend on the implementation of signed types on your system: for a negative first argument, the result is not the extraction of the least significant 8 bits.

It would be a different matter if `num` in your case was `unsigned`: these days I'd almost expect a compiler to make the optimisation that you cite.

• Almost but not quite. If `num` is negative, then `num % 256` is zero or negative (a.k.a. non-positive). Commented Nov 8, 2016 at 15:16
• Which IMO, is a mistake in the standard: mathematically modulo operation should take the sign of the divisor, 256 in this case. In order to understand why consider that `(-250+256)%256==6`, but `(-250%256)+(256%256)` must be, according to the standard, "non-positive", and therefore not `6`. Breaking associativity like that has real life side effects: for example when computing "zooming out" rendering in integer coordinates one has to shift the image to have all coordinates non-negative. Commented Nov 8, 2016 at 17:13
• @Michael Modulus has never been distributive over addition ("associative" is the wrong name for this property!), even if you follow the math definition to the letter. For example, `(128+128)%256==0` but `(128%256)+(128%256)==256`. Perhaps there's a good objection to the specified behavior, but it isn't clear to me that it's the one you said. Commented Nov 8, 2016 at 17:23
• @DanielWagner, you are right, of course, I misspoke with "associative". However, if one keeps the sign of the divisor and computes everything in modular arithmetic, the distributive property does hold; in your example you would have `256==0`. The key is to have exactly `N` possible values in modulo `N` arithmetic, which is only possible if all the results are in the range `0,...,(N-1)`, not `-(N-1),...,(N-1)`. Commented Nov 8, 2016 at 18:27
• @Michael: Except % is not a modulo operator, it's a remainder operator. Commented Nov 9, 2016 at 12:20

I don't have telepathic insight into the compiler's reasoning, but in the case of `%` there is the necessity of dealing with negative values (and division rounds towards zero), while with `&` the result is always the lower 8 bits.

The `sar` instruction sounds to me like "shift arithmetic right", filling up the vacated bits with the sign bit value.

As others have pointed out:

If you like me want the modulo operation to actually output a positive integer, as in my use case where I convert a hue (hsv color space) double where 1.0 == 360 degrees to a unsigned char by multiplying with 255.0, taking the floor followed by modulo 256. Then &0xff is a correct optimization. Observe that I treat 255 as 360 degrees to fit into unsigned char in my case.

``````hue = [-1.0 , 2.0]
hue = (unsigned char)(floor(hue * 255.0) & 0xff)
``````

But this might not be the right solution for your specific use case.