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For given numbers x,y and n, I would like to calculate x-y mod n in C. Look at this example:

int substract_modulu(int x, int y, int n)
{
    return (x-y) % n;
}

As long as x>y, we are fine. In the other case, however, the modulu operation is undefined.

You can think of x,y,n>0. I would like the result to be positive, so if (x-y)<0, then ((x-y)-substract_modulu(x,y,n))/ n shall be an integer.

What is the fastest algorithm you know for that? Is there one which avoids any calls of if and operator??

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1  
You can use abs(), but that won't be more efficient by any means. –  user529758 Dec 25 '12 at 9:52
    
How do you wish to define the negative result? What is the desirable outcome if y>x? –  John Leidegren Dec 25 '12 at 9:59
    
Out of curiosity, in what situation is an IF to expensive? If it's cryptography, then implementing it by yourself is a very dangerous idea (excepted if it is only for learning, and not production code). If you have lots of calculations, maybe you can speed up thing with SSE –  Tristram Gräbener Dec 25 '12 at 10:00
    
IBM's PowerPC processor (XBOX360) and the PS3 PPU/SPU really don't like branching. It can be really useful in console programming scenarios. It's sometimes more efficient just to do other things even if it results in more instructions. –  John Leidegren Dec 25 '12 at 10:05
    
You tagged with C++. Is it C++ or C? If C++, have a look at my answer. –  Johan Lundberg Dec 25 '12 at 11:11

6 Answers 6

up vote 3 down vote accepted

As many have pointed out, in current C and C++ standards, x % n is no longer ever implementation-defined. It is undefined behaviour in the cases where x / n is undefined [1]. More interestingly, x - y is undefined behaviour in the case of integer overflow, which is possible whenever the signs of x and y differ [1].

So the main problem for a general solution is avoiding integer overflow, either in the division or the subtraction. However, if we know that x and y are non-negative and n is positive, then overflow and division by zero are not possible, and we can confidently say that (x - y) % n is defined. Unfortunately, it might be negative.

It's easy to correct for the result being negative if we know that n is positive; all we have to do is add n and do another modulo operation. That's unlikely to be the best solution, unless you have a computer where division is faster than branching.

If a conditional load instruction is available (pretty common these days), then the compiler will probably do well with the following code, which is portable and well-defined, subject to the constraints that x,y ≥ 0 ∧ n > 0:

((x - y) % n) + ((x > y) ? 0 : n)

For example, gcc produces this code for my core I5 (although it's generic enough to work on any non-Paleozoic intel chip):

    idivq   %rcx
    cmpq    %rsi, %rdi
    movl    $0, %eax
    cmovg   %rax, %rcx
    leaq    (%rdx,%rcx), %rax

which is cheerfully branch-free. (Conditional move is usually a lot faster than branching.)

Another way of doing this would be (except that the function sign needs to be written):

((x - y) % n) + (sign(x > y) & (unsigned long)n)

where sign is all 1s if its argument is negative, and otherwise 0. One possible implementation of sign (adapted from bithacks) is

unsigned long sign(unsigned long x) {
  return x >> (sizeof(long) * CHAR_BIT - 1);
}

This is portable (casting negative integer values to unsigned is defined), but it may be slow on architectures which lack high-speed shift. It's unlikely to be faster than the previous solution, but YMMV. TIAS.

Neither of these produce correct results for the general case where integer overflow is possible. It's very difficult to deal with integer overflow, particularly the annoying case where n == -1. (Also, you need to decide your preference for the result of modulo of negative n. I personally prefer the definition where x%n is either 0 or has the same sign as n -- otherwise why would you bother with a negative divisor -- but applications differ.)

The three-modulo solution proposed by Tom Tanner will work if n is not -1 and n + n does not overflow. n == -1 will fail if either x or y is INT_MIN, and the simple fix of using abs(n) instead of n will fail if n is INT_MIN. The cases where n has a large absolute value could be replaced with comparisons, but there are a lot of corner cases, and made more complicated by the fact that the standard does not require 2's complement arithmetic, so it's not easily predictable what the corner cases are [3].

As a final note, some tempting solutions do not work. You cannot just take the absolute value of (x - y):

(-z) % n == -(z % n) == n - (z % n) ≠ z % n (unless z % n happens to be n / 2)

And, for the same reason, you cannot just take the absolute value of the result of modulo.

Also, you cannot just cast (x - y) to unsigned:

(unsigned)z == z + 2k (for some k) if z < 0
(z + 2k) % n == (z % n) + (2k % n) ≠ z % n unless (2k % n) == 0


[1] x/n and x%n are both undefined if n==0. But x%n is also undefined if x/n is "not representable" (i.e. there was integer overflow), which will happen on twos-complement machines (that is, all the ones you care about) if x is most negative representable number and n == -1. It's clear why x/n should be undefined in this case, but slightly less so in the case of x%n, since that value is (mathematically) 0.

[2] Except for the case where x is negative and y == 0.

[3] Most people who complain about the difficulty of predicting the results of floating-point arithmetic haven't spent much time trying to write truly portable integer arithmetic code :)

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Thanks. Your post spotted some issues in TomTanners post. One thing, though: if x-y < -n , I think your "+n"-solution won't work, since x-y+n<0? –  Johannes Dec 25 '12 at 18:08
    
@Johannes: I'm adding n to (x-y)%n, not to x-y. (x-y)%n > (-n) in all cases where (x-y) doesn't overflow. –  rici Dec 25 '12 at 18:22
    
@Johannes, by the way, you could do the test and add solution in two steps, such as: int tmp = (x - y) % n; return tmp + (tmp < 0) ? n : 0;, which will work even with the pre-C++11 guarantees. In fact, I believe that both C++11 and C++03 use the same division op-code to do the modulo calculation; the improved guarantee in C++11 simply codifies the reality that all modern hardware works that way. C99 has the same guarantee, and that was over a decade ago. –  rici Dec 25 '12 at 18:28
    
Thanks, I see it! –  Johannes Dec 25 '12 at 21:06
    
@Johannes, by the way, I forgot to mention this before. If n is known, you can replace the division by a multiplication. By known, I mean either it's a compile-time constant, or you're going to use it often enough that it's worth doing some computation to figure out what to use as a multiplier. I'm sure you can find the details on the internet somewhere. If n is known at compile-time, both gcc and clang are capable of working it out for you, so you don't really have to know the details. –  rici Dec 25 '12 at 21:50

If you want to avoid undefined behaviour, without an if, the following would work

return (x % n - y % n + n) % n;

The efficiency depends on the implementation of the modulo operation, but I'd suspect algorithms involving if would be rather faster.

Alternatively you could treat x and y as unsigned. In which case there are no negative numbers involved and no undefined behaviour.

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Thanks, the first seems good. But what do you mean with the unsigned method? –  Johannes Dec 25 '12 at 10:08
1  
I think you can drop the modulo op on x. –  KillianDS Dec 25 '12 at 10:29
    
@Johannes - if x and y are unsigned ints, then x - y can never be negative. n should be unsigned in any case, modulo a negative number doesn't make a lot of sense –  Tom Tanner Dec 25 '12 at 10:30
    
@KillianDS - that's true, thanks –  Tom Tanner Dec 25 '12 at 10:31
    
@TomTanner Okay, let's say x-y=-1, then in unsigned (suppose we have char instead of int, for easiness), x-y=255. But if n=3, then -1%3=2!=0=255%3. Are you sure this works? –  Johannes Dec 25 '12 at 10:35

Whether branching is going to matter will depend on the CPU to some degree. According to the documentation abs (on MSDN) has intrinsic behavior and it might not be a bottleneck at all. This you'll have to test.

If you wan't unconditionally compute things there are several nice methods that can be adapted from the Bit Twiddling Hacks site.

int v;           // we want to find the absolute value of v
unsigned int r;  // the result goes here 
int const mask = v >> sizeof(int) * CHAR_BIT - 1;

r = (v + mask) ^ mask;

However, I don't know if this will be helpful to your situation without more information about hardware targets and testing.

Just out of curiosity I had to test this myself and when you look at the assembly generated by the compiler we can see there's no real overhead in the use of abs.

unsigned r = abs(i);
====
00381006  cdq              
00381007  xor         eax,edx 
00381009  sub         eax,edx

The following is just an alternate form of the above example which according to the Bit Twiddling Site is not patented (while the version used by the Visual C++ 2008 compiler is).

Throughout my answer I have been using MSDN and Visual C++ but I would assume that any sane compiler has similar behavior.

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I'm going to guess that it's not really the case here, but I'd like to mention that if the value you are taking modulo with is a power of two, then using the "AND" method is a lot quicker (I'm going to ignore the x-y, and just show how it works for a single x, as x-y is not part of the equation here):

int modpow2(int x, int n)
{
    return x & (n-1);
}

If you want to ensure that your code doesn't do anything daft, you could add ASSERT(!(n & n-1)); - this checks that there is only a single bit set in n (so, n is a power of two).

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With C++11 the undefined behavior was removed. Depending on the the exact behavior you want you can there just stick with

return (x-y) % n;

For a full explanation read this answer:

http://stackoverflow.com/a/13100805/1149664

You still get undefined behavior for n==0 or if x-y can not be stored in the type you are using.

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In my case, however, I can not use C++11. But really interesting! –  Johannes Dec 25 '12 at 18:03

Assuming 0 <= x < n and 0 <= y < n, how about (x + n - y) % n? Then x + n will certainly be larger than y, subtracting y will always result in a positive integer, and the final mod n reduces the result if necessary.

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Good point. In my case, it this is the case indeed. Otherwise, I could just calculate (x+n-(y%n))%n. Which is indeed the same as in TomTanner's post. –  Johannes Dec 25 '12 at 18:02

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