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I want to calculate the RSA algorithm by myself . I need to calculate the modulus of a number at a certain power. The thing is that that number at that certain power can get quite big.

Here is what i want :

x = pow(n, p) % q

How can I efficiently determine x?

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so greater than max ulong? –  Roly Mar 25 '11 at 14:46
    
Obligatory remark: this is fine for study etc but never write your own encryption for something real. –  Henk Holterman Mar 25 '11 at 14:52
    
i thing it kind of extends beyond limit of ulong . I'm not sure though .. you could be right . –  Badescu Alexandru Mar 25 '11 at 14:53
    
@Henk .. i'm doing it just for fun .. i'm not going to use it –  Badescu Alexandru Mar 25 '11 at 14:53

7 Answers 7

up vote 7 down vote accepted

If you're using .NET 4, I suggest you look at BigInteger, which even provides the ModPow method to do it all in a single operation :)

BigInteger n = ...;
BigInteger p = ...;
BigInteger q = ...;
BigInteger x = BigInteger.ModPow(n, p, q);
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didnt know about ModPow, pretty cool –  jon_darkstar Mar 25 '11 at 14:56
2  
@jon_darkstar: Neither did I before this question :) –  Jon Skeet Mar 25 '11 at 14:58
    
Is the source code of BigInteger.ModPow() available? I wonder if it is (or there is a version) tuned for when q is prime. –  ypercube Mar 25 '11 at 15:28
    
@Ypercube: The source of the framework is available at referencesource.microsoft.com/netframework.aspx . –  Brian Mar 25 '11 at 17:03

This is known as the powermod function:

function modular_pow(base, exponent, modulus)
    c := 1
    for e_prime = 1 to exponent 
        c := (c * base) mod modulus
    return c

This can be made more efficient by applying exponentiation by squaring:

function modular_pow(base, exponent, modulus)
    result := 1
    while exponent > 0
        if (exponent & 1) equals 1:
           result = (result * base) mod modulus
        exponent := exponent >> 1
        base = (base * base) mod modulus
    return result
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1  
+1. I would only add a base = base mod modulus at the start of the function, to catch the case when base is much larger than modulus. –  ypercube Mar 25 '11 at 15:08

Please check this topic and this article on ways to make the mathematical function more efficient in itself.

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See BigInteger.ModPow (Fx 4+), here is the MSDN.

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Trivially...

x = 1
for(i = 0; i < p; i++)
   x = (x*n) % q

Theres more efficient ways such as binary exponentiation rather than this naive iteration, but this does get past the overflow problem as x is bounded by n*q

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The question specifically says the number will be "quite big" and given that it's to do with crypto, I think it's reasonable to assume it won't fit in an int. What happens when x * n overflows to a negative number, leading to a negative intermediate result? –  Jon Skeet Mar 25 '11 at 14:59
    
ok so call x, and whatever else you deem necessary, a BigInteger. point being that no matter how big the bound is, give a large enough exponent and its going to overflow if think you can just find a huge natural number and mod once at the end, rather than taking mods along the way –  jon_darkstar Mar 25 '11 at 15:04
    
I agree with your previous comment and with that your solution gets past the overflow problem. But only that. "There's more efficient ways" could be stated as "(my program may find the result after the end of the universe (if p is big enough) while other programs would find it in minutes". –  ypercube Mar 25 '11 at 15:25
    
thus i started with the 'trivally' disclaimer, and referred to those other methods. i wasnt sure where OP is at, and you shouldnt tackle the more involved methods until knowing the naive one –  jon_darkstar Mar 25 '11 at 15:31

Although all the answers provided here are correct I mis the obvious square-and-multiply algorithm, which is the "classic" way to implement modular exponentiation.

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If you plan to write your own version of Modpow():


You only need the power modulo q, so your calculations don't need to use any number bigger than q^2, using the fact that:

if a = b (mod q) then a*p = b*p (mod q)

Therefore, when calculating the power n^p, after every multiplication, do a (modulo q) operation on your working variable.


Additionally, if q is prime, you can use Fermat's little theorem, which states that:

a^(q-1) = 1 (mod q)
    (when a is not a multiple of q)

This can be used to shorten the calculations when p is (much) bigger than q

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