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I want to calculate am mod n, where n is a prime number, and m is very large. Rather doing this with binary power calculation, I'd like to find such x that ax = a (mod n) and then calculate a(m mod x) mod n.

Obviously such x exists for any a, because powers mod n loop at some point, but I didn't find out how to calculate it with modular arithmetics. I wonder if I missed something or maybe there exists some numerical method for that?

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^ is power ? made <sup> – Grijesh Chauhan May 11 '13 at 5:29
@GrijeshChauhan: thanks ) – Grigor Gevorgyan May 11 '13 at 5:30
up vote 6 down vote accepted

Your modulus is prime, that makes it easy to get a start, as by Fermat's (inappropriately dubbed "little") theorem, then

a^n ≡ a (mod n)

for all a. Equivalent is the formulation

a^(n-1) ≡ 1 (mod n),  if n doesn't divide a.

Then you have

a^m ≡ 0 (mod n) if a ≡ 0 (mod n) and m > 0


a^m ≡ a^(m % (n-1)) (mod n) otherwise

(note that your suggested a^(m % x) is in general not correct, if m = q*x + r, you'd have

a^m ≡ (a^x)^q * a^r ≡ a^q * a^r ≡ a^(q+r) (mod n)

and you'd need to repeat that reduction for q+r until you obtain an exponent smaller than x).

If you are really interested in the smallest x > 1 such that a^x ≡ a (mod n), again the case of a ≡ 0 (mod n) is trivial [x = 2], and for the other cases, let y = min { k > 0 : a^k ≡ 1 (mod n) }, then the desired x = y+1, and, since the units in the ring Z/(n) form a (cyclic) group of order n-1, we know that y is a divisor of n-1.

If you have the factorisation of n-1, the divisors and hence candidates for y are easily found and checked, so it isn't too much work to find y then - but it usually is still far more work than computing a^r (mod n) for one single 0 <= r < n-1.

Finding the factorisation of n-1 can be trivial (e.g. for Fermat primes), but it can also be very hard. In addition to the fact that finding the exact period of a modulo n is usually far more work than just computing a^r (mod n) for some 0 <= r < n-1, that makes it very doubtful whether it's worth even attempting to reduce the exponent further.

Generally, when the modulus is not a prime, the case when gcd(a,n) = 1 is analogous, with n-1 replaced by λ(n) [where λ is the Carmichael function, which yields the smallest exponent of the group of units of Z/(n); for primes n, we have λ(n) = n-1].

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The standard approach for computing am mod n is using the typical binary exponentiation you mentioned, along with Montgomery reduction to keep the problem tractable. Note the section on "Use in cryptography", which explains the utility in computing am mod n.

Solving the problem in your title requires finding the discrete logarithm, for which there is no known efficient solution. The difficulty in solving the discrete logarithm problem is the basis for many cryptosystems!

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I think the comment about discrete logarithms is misleading: in this special case (finding x > 1 such that a^x = a (mod n)), this isn't really about finding discrete logarithms; for the interesting case (where a is relatively prime to n), the hard part is finding the order of the group of units modulo n, and (if you want to find all solutions x) also finding the prime factorization of that order. Finding discrete logs modulo a prime p is still hard even when the factorization of p-1 is known. – Mark Dickinson May 11 '13 at 20:14

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