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Often in my inner loops I need to index an array in a "wrap-around" way, so that 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.

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Are you consistently modding over the same number? –  Mysticial Feb 21 '13 at 7:59
    
@Mysticial typically, yes. –  Nathaniel Feb 21 '13 at 7:59
    
@Mysticial also if the solution constrains the number I'm modding over to be a power of 2, that's OK. –  Nathaniel Feb 21 '13 at 8:00
1  
Then, you'll want to either hard-code the modulus, or put it in as a compile-time constant. You'll get much better performance that way than whatever tricks you can play with the sign. –  Mysticial Feb 21 '13 at 8:00
1  
Well, modding over a power of two is trivial; you just do & (n-1) regardless of sign. –  nneonneo Feb 21 '13 at 8:01

4 Answers 4

The standard way I learned is

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

This function is essentially your first variant without the abs (which, in fact, makes it return the wrong result). I wouldn't be surprised if an optimizing compiler could recognize this pattern and compile it to machine code that computes an "unsigned modulo".

Edit:

Moving on to your second variant: First of all, it contains a bug, too -- the n < 0 should be i < 0.

This variant may not look as if it branches, but on a lot of architectures, the i < 0 will compile into a conditional jump. In any case, it will be at least as fast to replace (n * (i < 0)) with i < 0? n: 0, which avoids the multiplication; in addition, it's "cleaner" because it avoids reinterpreting the bool as an int.

As to which of these two variants is faster, that probably depends on the compiler and processor architecture -- time the two variants and see. I don't think there's a faster way than either of these two variants, though.

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Nitpick: It actually won't vectorize because there's generally no SIMD support for modulus. –  Mysticial Feb 21 '13 at 8:46
    
@Mysticial: Good point -- I'll remove that note. –  Martin B Feb 21 '13 at 8:50
    
Would it be more efficient to factor the n out into a template? In the case that the function cannot be inlined, the compiler may be able to play some tricks to improve performance. –  Alex Chamberlain Feb 21 '13 at 9:02
    
Oops, you're right about the abs(), I've edited it out of my question. –  Nathaniel Feb 21 '13 at 10:32
    
also corrected the typo in the second example. (I really should have tested them first.) –  Nathaniel Feb 22 '13 at 3:03

Modulo a power of two, the following works (assuming twos complement representation):

return i & (n-1);
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Many thanks! I will leave the question open in case someone has a good answer for the general case, but I will probably end up using this. –  Nathaniel Feb 21 '13 at 8:03
1  
what is n here? n mod i or i mod n? –  ixSci Feb 21 '13 at 8:42
1  
As simple as the answer is, I would be very careful. Remember different architectures generally store negative numbers in different ways. Hence bitwise operators on negative numbers cant differ with different compilers and/or architectures. –  mity Feb 21 '13 at 8:42
1  
i mod n == i & (n-1) when n is a power of two and mod is the aforementioned positive mod. (FYI: modulus is the common mathematical term for the "divisor" when a modulo operation is considered). –  nneonneo Feb 21 '13 at 9:01
6  
@GrijeshChauhan: The limitations are clearly stated: n must be a power of two and numbers must use twos-complement (pretty much every computer produced in the last 20 years). When else will it fail? –  nneonneo Feb 21 '13 at 9:03

An old-school way to get the optional addend using twos-complement sign-bit propagation:

int positive_mod(int i, int n)
{
    /* constexpr */ int shift = CHAR_BIT*sizeof i - 1;
    int m = i%n;
    return m+ (m>>shift & n);
}
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Old-school hard to read hack. I like it. Though I wonder if (i>>shift & n) might be faster as the bitshift operation will otherwise have to wait for the modulo operation to finish. –  eBusiness Feb 22 '13 at 22:47
    
It would be faster but it would give incorrect results for e.g. -2 mod 2. –  jthill Feb 23 '13 at 0:28
    
Shoot, you are right. And now that you mention it, that is true for (i % n) + (n * (i < 0)) as well. –  eBusiness Feb 23 '13 at 10:32

You can as well do array[(i+array_size*N) % array_size], where N is large enough integer to guarantee positive argument, but small enough for not to overflow.

When the array_size is constant, there are techniques to calculate the modulus without division. Besides of power of two approach, one can calculate a weighted sum of bitgroups multiplied by the 2^i % n, where i is the least significant bit in each group:

e.g. 32-bit integer 0xaabbccdd % 100 = dd + cc*[2]56 + bb*[655]36 + aa*[167772]16, having the maximum range of (1+56+36+16)*255 = 27795. With repeated applications and different subdivision one can reduce the operation to few conditional subtractions.

Common practises also include approximation of division with reciprocal of 2^32 / n, which usually can handle reasonably large range of arguments.

 i - ((i * 655)>>16)*100; // (gives 100*n % 100 == 100 requiring adjusting...)
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