First, focus on 2^{n} mod p because you can always subtract one at the end.

Consider the powers of two. This is a sequence of numbers produced by repeatedly multiplying by two.

Consider the modulo operation. If the number is written in base p, you're just grabbing the last digit. Higher digits can be thrown away.

So at some point(s) in the sequence, you get a two-digit number (a 1 in the p's place), and your task is really just to get rid of the first digit (subtract p) when that happens.

Stopping here conceptually, the brute-force approach would be something like this:

```
uint64_t exp2modp( uint64_t n, uint64_t p ) {
uint64_t ret = 1;
uint64_t limit = p / 2;
n %= p; // Apply Fermat's Little Theorem.
while ( n -- ) {
if ( ret >= limit ) {
ret *= 2;
ret -= p;
} else {
ret *= 2;
}
}
return ret;
}
```

Unfortunately, this still takes forever for large n and p, and I can't think of any better number theory offhand.

If you have a multiplication facility which can compute (p-1)^2 without overflow, then you can use an analogous algorithm using repeated squaring with a modulo after each square operation, and then take the product of the series of square residuals, again with a modulo after each multiplication.