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I need to be able to calculate (a^b) % c for very large values of a and b (which individually are pushing limit and which cause overflow errors when you try to calculate a^b). For small enough numbers, using the identity (a^b)%c = (a%c)^b%c works, but if c is too large this doesn't really help. I wrote a loop to do the mod operation manually, one a at a time:

private static long no_Overflow_Mod(ulong num_base, ulong num_exponent, ulong mod) 
    {
        long answer = 1;
        for (int x = 0; x < num_exponent; x++)
        {
            answer = (answer * num_base) % mod;
        }
        return answer;
    }

but this takes a very long time. Is there any simple and fast way to do this operation without actually having to take a to the power of b AND without using time-consuming loops? If all else fails, I can make a bool array to represent a huge data type and figure out how to do this with bitwise operators, but there has to be a better way.

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2  
Sounds like an Euler problem... If it is, you should clearly state that in the question instead of trying to cheat... –  Guffa Jun 12 '09 at 17:51
    
Knowing the range of a, b, and c might help us. –  Nosredna Jun 12 '09 at 17:52
2  
Project Euler #188 ? –  Serge - appTranslator Jun 12 '09 at 18:02
1  
I actually wasn't trying to solve that problem at all, I need this algorithm for an encryption program I'm writing. –  Nikolai Mushegian Jun 12 '09 at 22:03
3  
Is this for your own edification, or are you planning on actually relying upon your algorithm to protect your customers from evildoers? If the former, you go. If the latter, I strongly urge you to reconsider. –  Eric Lippert Jun 12 '09 at 23:20
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11 Answers 11

I guess you are looking for : http://en.wikipedia.org/wiki/Montgomery_reduction or the simpler way based on Modular Exponentiation (from wikipedia)

Bignum modpow(Bignum base, Bignum exponent, Bignum modulus) {

    Bignum result = 1;

    while (exponent > 0) {
        if ((exponent & 1) == 1) {
            // multiply in this bit's contribution while using modulus to keep result small
            result = (result * base) % modulus;
        }
        // move to the next bit of the exponent, square (and mod) the base accordingly
        exponent >>= 1;
        base = (base * base) % modulus;
    }

    return result;
}
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If the modulus is smaller than the exponent, I think you could improve this algorithm by taking the modulus of the count of 1 bits of the exponents and only do that many loop iterations. One could actually do even better than that in some cases. See Kai's answer. –  Brian Jun 12 '09 at 18:22
    
i think you can break out whenever result = 0 result = (result * base) % modulus; if (result == 0) break; –  johnnycrash Jun 12 '09 at 19:23
    
The formatting screwed up my comment. Add "if (result == 0) break;" after the calculation of result. –  johnnycrash Jun 12 '09 at 19:24
    
Actually before you mutliply result*base, check base==0 and break then. –  johnnycrash Jun 12 '09 at 19:25
    
You can break out at the bottom after "exponent >>= 1;" if exponent == 0 and avoid having to do the last mulitply and mod. –  johnnycrash Jun 12 '09 at 19:40
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Fast Modular Exponentiation (I think that's what it's called) might work.

Given a, b, c and a^b (mod c):

1. Write b as a sum of powers of 2. (If b=72, this is 2^6 + 2^3 )
2. Do:
    (1) a^2 (mod c) = a*
    (2) (a*)^2 (mod c) = a*
    (3) (a*)^2 (mod c) = a*
    ...
    (n) (a*)^2 (mod c) = a*

3. Using the a* from above, multiply the a* for the powers of 2 you identified. For example:
    b = 72, use a* at 3 and a* at 6.
    a*(3) x a*(6) (mod c)

4. Do the previous step one multiplication at a time and at the end, you'll have a^b % c.

Now, how you're going to do that with data types, I don't know. As long as your datatype can support c^2, i think you'll be fine.

If using strings, just create string versions of add, subtract, and multiply (not too hard). This method should be quick enough doing that. (and you can start step 1 by a mod c so that a is never greater than c).

EDIT: Oh look, a wiki page on Modular Exponentiation.

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Here's an example of Fast Modular Exponentiation (suggested in one of the earlier answers) in java. Shouldn't be too hard to convert that to C#

http://www.math.umn.edu/~garrett/crypto/a01/FastPow.html

and the source...

http://www.math.umn.edu/~garrett/crypto/a01/FastPow.java

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I'd recommend checking over the Decimal documentation and seeing if it meets your requirements since it is a built in type and can use the mod operator. If not then you're going to need an arbitrary precision library like java's Bignum.

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Not using Java. C#. –  Malfist Jun 12 '09 at 17:43
    
no shit, i was saying like, as in he would need to find an equivalent. way to not read. –  Qberticus Jun 12 '09 at 17:48
    
He said like Java's Bignum. Not *use" Java's Bignum. Given that he knows about C#'s decimal type, it's probably a good bet that he knows the question is about C#. –  Tim Lesher Jun 12 '09 at 17:49
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You can try factoring 'a' into sufficiently small numbers.

If the factors of 'a' are 'x', 'y', and 'z', then

a^b = (x^b)(y^b)(z^b).

Then you can use your identity: (a^b)%c = (a%c)^b%c

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Except that factoring is a much more difficult problem than modulus –  Eclipse Jun 12 '09 at 19:27
    
I would just start out dividing a/2 in a loop until it didn't divide evenly.... Then a/3, etc with prime numbers until 'a' was "sufficiently small" for a^b not to overflow. Then complete the operation as outlined by the original poster. –  Robert Cartaino Jun 13 '09 at 0:07
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It seems to me like there's some kind of relation between power and mod. Power is just repeated multiplication and mod is related to division. We know that multiplication and division are inverses, so through that connection I would assume there's a correlation between power and mod.

For example, take powers of 5:

5 % 4 = 1
25 % 4 = 1
125 % 4 = 1
625 % 4 = 1
...

The pattern is clear that 5 ^ b % 4 = 1 for all values of b.

It's less clear in this situation:

5 % 3 = 2
25 % 3 = 1
125 % 3 = 2
625 % 3 = 1
3125 % 3 = 2
15625 % 3 = 1
78125 % 3 = 2
...

But there's still a pattern.

If you could work out the math behind the patterns, I wouldn't be surprised if you could figure out the value of the mod without doing the actual power.

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The pattern is obvious and well-known. It's Fermat's Little Theorem (and the identity is used in the OP). –  Matthew Flaschen Jun 12 '09 at 17:55
    
Ah yes, you're right, thanks for pointing me to it. It's only obvious if you've considered this kind of problem before and I'm grateful to have derived the idea myself :) –  Kai Jun 12 '09 at 17:57
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Where is Fermat's little theorem used in the OP? –  Tobias Jun 12 '09 at 18:19
    
Sorry, I spoke too quick. This isn't Fermat. Both Kai's post and the OP are basic modular multiplicatioon. –  Matthew Flaschen Jun 12 '09 at 18:45
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Python has pow(a,b,c) which returns (a**b)%c (only faster), so there must be some clever way to do this. Maybe they just do the identity you mentioned.

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Why the down vote? This was correct. –  Nick Cox Aug 30 '13 at 12:50
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You could try this:

C#: Doing a modulus (mod) operation on a very large number (> Int64.MaxValue)
http://www.del337ed.com/blog/index.php/2009/02/04/c-doing-a-modulus-mod-operation-on-a-very-large-number-int64maxvalue/

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Short of writing your own fast modular exponentiation, the simplest idea I can come up with, is to use the F# BigInt type: Microsoft.FSharp.Math.Types.BigInt which supports operations with arbitrarily large scale - including exponentiation and modular arithmetic.

It's a built-in type that will be part of the full .NET framework with the next release. You don't need to use F# to use BitInt - you can make use of it directly in C#.

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Can you factor a, b, or c? Does C have a known range?

These are 32 bit integers! Go check this site

For instance, here is how you get the mod of n%d where d 1>>s (1,2,4,8,...)

  int n = 137;     // numerator
  int d = 32;      // denom d will be one of: 1, 2, 4, 8, 16, 32, ...
  int m;           // m will be n % d
  m = n & (d - 1);

There is code for n%d where d is 1>>s - 1 (1, 3, 7, 15, 31, ...)

This is only going to really help if c is small though, like you said.

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do you mean, "where d is 1 << (s-1)"? –  Nathan Fellman Jun 13 '09 at 4:51
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yeah. I can't even copy from another website without making a mistake! –  johnnycrash Jun 13 '09 at 17:08
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Looks like homework in cryptography.

Hint: check out Fermat's little theorem.

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