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
```

and

```
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`

].

`^`

is power ? made`<sup>`

– Grijesh Chauhan May 11 '13 at 5:29