The whole point of this problem is to come up with a way of doing this without actually calculating 2^1000.

However, if you *do* want to calculate 2^1000—which may be a good idea, because it's a great way to test whether your other algorithm is correct—you're going to want some kind of "bignum" library, such as `gmp`

:

```
mpz_t two_to_1000;
mpz_ui_pow_ui(two_to_1000, 2, 1000);
```

Or you can use the C++ interface to `gmp`

. It doesn't do exponentiation, so the first part gets slightly more complicated instead of less, but it makes the digit-summing simpler:

```
mpz_class two_to_1000;
mpz_ui_pow_ui(two_to_1000.get_mpz_t(), 2, 1000);
mpz_class digitsum(0);
while (two_to_1000) {
digitsum += two_to_1000 % 10;
two_to_1000 /= 10;
}
```

(There's actually no reason to make `digitsum`

an `mpz`

there, so you may want to figure out how to prove that the result will fit into 32 bits, add that as a comment, and just use a `long`

for `digitsum`

.)

All that being said, I probably wouldn't have written this `gmp`

code to test it, when the whole thing is a one-liner in Python:

```
print(sum(map(int, str(2**1000))))
```

And, even though converting the bignum to a string to convert each digit to an int to sum them up is possibly the least efficient way to solve it, it still takes under 200us on the slowest machine I have here. And there's really no reason the double-check needs to be in the same language as the actual solution.

`bcpow`

in PHP will let you do that dead easy. – zneak Jan 19 '13 at 0:15