Often in my inner loops I need to index an array in a "wrap-around" way, so that (for example) if the array size is 100 and my code asks for element -2, it should be given element 98. In many high level languages such as Python, one can do this simply with `my_array[index % array_size]`

, but for some reason C's integer arithmetic (usually) rounds toward zero instead of consistently rounding down, and consequently its modulo operator returns a negative result when given a negative first argument.

Often I know that `index`

will not be less than `-array_size`

, and in these cases I just do `my_array[(index + array_size) % array_size]`

. However, sometimes this can't be guaranteed, and for those cases I would like to know the fastest way to implement an always-positive modulo function. There are several "clever" ways to do it without branching, such as

```
inline int positive_modulo(int i, int n) {
return (n + (i % n)) % n;
}
```

or

```
inline int positive_modulo(int i, int n) {
return (i % n) + (n * (i < 0));
}
```

Of course I can profile these to find out which is the fastest on my system, but I can't help worrying that I might have missed a better one, or that what's fast on my machine might be slow on a different one.

So is there a standard way to do this, or some clever trick that I've missed that's likely to be the fastest possible way?

Also, I know it's probably wishful thinking, but if there's a way of doing this that can be auto-vectorised, that would be amazing.

`& (n-1)`

regardless of sign.`(i % n) + (n * (i < 0))`

I'm seeing result`n`

instead of`0`

on negative exact multiples, e.g (-3, 3) -> 3.16more comments