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is there a fast algorithm, similar to power of 2, which can be used with 3, i.e. n%3. Perhaps something that uses the fact that if sum of digits is divisible by three, then the number is also divisible.

This leads to a next question. What is the fast way to add digits in a number? I.e. 37 -> 3 +7 -> 10 I am looking for something that does not have conditionals as those tend to inhibit vectorization

thanks

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2  
Adding digits won't work in this case because you'd have to convert the number first to a decimal number which takes much more time than just dividing. –  Georg Schölly Nov 8 '09 at 18:01
    
What are you actually trying to achieve? Unless it is some theoretical curiosity, I doubt this specific problem you have could be the bottleneck of a real world application... –  Bruno Reis Nov 8 '09 at 18:01
2  
it is both, practical and theoretical. the question arises from trying to distribute multiple nested loops over Cartesian centers among threads(Cuda specifically but it is not important).I already solved the problem in another way but still would like to know if there is a way. This is a real bottleneck since integer division and modulo are much more expensive than the actual floating-point operations I am trying to make parallel. –  Anycorn Nov 8 '09 at 18:18
    
@Georg Schölly: Why decimal? You could do a similar thing in binary, e.g., decimal 13 = 0xB = binary "1101" is 1 modulo 3, because of -1+1-0+1=1. This is the base of the accepted answer, although I doubt it's the fastest way. –  maaartinus Jul 28 '12 at 19:38

3 Answers 3

up vote 12 down vote accepted

4 % 3 == 1, so (4^k * a + b) % 3 == (a + b) % 3. You can use this fact to evaluate x%3 for a 32-bit x:

x = (x >> 16) + (x & 0xffff);
x = (x >> 10) + (x & 0x3ff);
x = (x >> 6) + (x & 0x3f);
x = (x >> 4) + (x & 0xf);
x = (x >> 2) + (x & 0x3);
x = (x >> 2) + (x & 0x3);
x = (x >> 2) + (x & 0x3);
if (x == 3) x = 0;

(Untested - you might need a few more reductions.) Is this faster than your hardware can do x%3? If it is, it probably isn't by much.

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This comp.compilers item has a specific recommendation for computing modulo 3.

An alternative, especially if the maximium size of the dividend is modest, is to multiply by the reciprocal of 3 as a fixed-point value, with enough bits of precision to handle the maximum size dividend to compute the quotient, and then subtract 3*quotient from the the dividend to get the remainder. All of these multiplies can be implemented with a fixed sequence of shifts-and-adds. The number of instructions will depend on the bit pattern of the reciprocal. This works pretty well when the dividend max is modest in size.

Regarding adding digits in the number... if you want to add the decimal digits, you're going to end up doing what amounts to a number-conversion-to-decimal, which involves divide by 10 somewhere. If you're willing to settle for adding up the digits in base2, you can do this with an easy shift-right and add loop. Various clever tricks can be used to do this in chunks of N bits to speed it up further.

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Not sure for your first question, but for your second, you can take advantage of the % operator and integer division:

int num = 12345;
int sum = 0;
while (num) {
    sum += num % 10;
    num /= 10;
}

This works because 12345 % 10 = 5, 12345 / 10 = 1234 and keep going until num == 0

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+1 Nice #2. solution. –  Kyle Rozendo Nov 8 '09 at 18:21
2  
yes, it is that obvious solution. However division and modulo a very expensive operations, on the order of hundred of cycles on my platform. I am more interested in something that does not involve those. I have to say that this is a purely curiosity question. –  Anycorn Nov 8 '09 at 18:28

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