# Modular Exponentiation

In C/C++ how can I calculate `(a^b)%m` where `b` does not fit into 64 bits? In other words, is there a way of calculating the above value using `b%m` instead of `b`?

And is there any algorithm that can compute the above result in `O(log(b))` time or `O(log(b%m))` time?

-
This seems more like a math question. – Luchian Grigore Jul 12 '12 at 9:19
– Luchian Grigore Jul 12 '12 at 9:19
Do you mean where b doesn't fit into 64 bits? The usual exponentiation algorithm has you accumulating a result by multiplying by a if the next bit of b is set and then squaring. This seems pretty easy for large b, it's large a and m that is hard. – tbroberg Jul 12 '12 at 9:35
Yes, and let us say b is a Fibonacci number, and a & m< 10^9. How can I find the (a^b)%m. Given that I am using log(n) matrix exponentiation algorithm for finding b. How should I used the intermediate b values? – sabari Jul 12 '12 at 9:39

According to Euler's theorem, if `a` and `m` are coprime:

` ab mod m = ab mod phi(m) mod m`

so if `b` is large, you can use the value `b % phi(m)` instead of `b`. `phi(m)` is Euler's totient function, which can be easily calculated if you know the prime factorization of `m`.

Once you've reduced the value of `b` in this way, use Exponentiation by squaring to compute the modular exponentiation in `O(log (b % phi(m)))`.

-
to nit-pick: this is only true if a and m are coprime. – Henrik Jul 12 '12 at 10:02
@Henrik: That means it will work even if m is prime and a < m. Correct me if I am wrong. – sabari Jul 12 '12 at 10:06
@Henrik: Right, I forgot about that, thanks. sabari: Yes, it will work in that case. – interjay Jul 12 '12 at 10:07
@interjay: Thanks! It works! – sabari Jul 12 '12 at 10:10
Carmichael's function is a generalization of Totient for non-coprime numbers. See my answer to the exact same question here stackoverflow.com/questions/11272437/calculating-abmod/… – Viktor Latypov Jul 12 '12 at 18:16