First off, your loop is not infinite. It will run until it reaches
0xFFFFFFFF, which will take forever.
Part of the reason it will take forever is you are using what amounts to an
O(N^2) algorithm (so it will take
0xFFFFFFFF * 0xFFFFFFFF operations to finish).
You should use a sieve, or at the very least, optimize your
bool is_prime(unsigned int i, const std::deque<unsigned int>& previous_primes)
std::size_t j = 0;
while (previous_primes[j] * previous_primes[j] <= i)
if (i % previous_primes[j] == 0)
And your main code would then be:
// initialize some known primes
std::deque<unsigned int> primes;
for (unsigned int i = 9; i <= 0xFFFFFFFF; i += 2)
if (is_prime(i, primes))
// your percentage of primes would be (mathematically) primes.size() / 0xFFFFFFFF
Note that because of the iterations, this will still take forever to loop through all odd integers from 9 to 0xFFFFFFFF.
Effectively, you are writing a program to show the following simple proof:
- Start with 2, so the percentage of primes must be less than .5, as every other number is divisible by 2.
- Next, 3, so the percentage of primes must be less than .33 as every 3rd number is divisible by 3.
- Next 5 ...
As the primes get larger and larger, the maximum percentage becomes
1/some infinite prime ~= 0. (the limit of
f(x) = 1/x as x approaches infinity is 0).
So here, the mathematical proof is much faster than your attempt at a programmatic proof.