As has been said, your first problem in

```
int mod_func(int p, int g, int x) {
return ((int)pow((double)g, (double)x)) % p;
}
```

is that `pow(g,x)`

often exceeds the `int`

range, and then you have undefined behaviour converting that result to `int`

, and whatever the resulting `int`

is, there is no reason to believe it has anything to do with the desired modulus.

The next problem is that the result of `pow(g,x)`

as a `double`

may not be exact. Unless `g`

is a power of 2, the mathematical result cannot be exactly represented as a `double`

for large enough exponents even if it is in range, but it could also happen if the mathematical result is exactly representable (depends on the implementation of `pow`

).

If you do number-theoretic computations - and computing the residue of a power modulo an integer is one - you should only use integer types.

For the case at hand, you can use exponentiation by repeated squaring, computing the residue of all intermediate results. If the modulus `p`

is small enough that `(p-1)*(p-1)`

never overflows,

```
int mod_func(int p, int g, int x) {
int aux = 1;
g %= p;
while(x > 0) {
if (x % 2 == 1) {
aux = (aux * g) % p;
}
g = (g * g) % p;
x /= 2;
}
return aux;
}
```

does it. If `p`

can be larger, you need to use a wider type for the calculations.

`int`

into a negative value. The modulus of a negative number will be negative. – Oded♦ Dec 19 '12 at 21:59