For `n = p^a * q^b`

, the totient is `φ(n) = (p-1)*p^(a-1) * (q-1)*q^(b-1)`

. Without loss of generality, `p < q`

.

So `gcd(n,φ(n)) = p^(a-1) * q^(b-1)`

if `p`

does not divide `q-1`

and `gcd(n,φ(n)) = p^a * q^(b-1)`

if `p`

divides `q-1`

.

In the first case, we have `n/gcd(n,φ(n)) = p*q`

and `φ(n)/gcd(n,φ(n)) = (p-1)*(q-1) = p*q + 1 - (p+q)`

, thus you have `x = p*q = n/gcd(n,φ(n))`

and `y = p+q = n/gcd(n,φ(n)) + 1 - φ(n)/gcd(n,φ(n))`

. Then finding `p`

and `q`

is simple: `y^2 - 4*x = (q-p)^2`

, so `q = (y + sqrt(y^2 - 4*x))/2`

, and `p = y-q`

. Then finding the exponents `a`

and `b`

is trivial.

In the second case, `n/gcd(n,φ(n)) = q`

. Then you can easily find the exponent `b`

, dividing by `q`

until the division leaves a remainder, and thus obtain `p^a`

. Dividing `φ(n)`

by `(q-1)*q^(b-1)`

gives you `z = (p-1)*p^(a-1)`

. Then `p^a - z = p^(a-1)`

and `p = p^a/(p^a-z)`

. Finding the exponent `a`

is again trivial.

So it remains to decide which case you have. You have case 2 if and only if `n/gcd(n,φ(n))`

is a prime.

For that, you need a decent primality test. Or you can first suppose that you have case 1, and if that doesn't work out, conclude that you have case 2.