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I'm writing a program to estimate the percentage of non-negative integers that are prime. The following code somehow produces an infinite loop, as my output is saying "Timeout" on the online compiler I'm using. However, I can't figure out what part of the code is producing the issue. It looks pretty straight-forward to me.

#include <iostream> 

bool isPrime(unsigned long L) { 
    if (L < 3) { 
        return true; 
    } else { 
        unsigned long i = 2;
        while (i < L)
           if (L % i++ == 0)
                return false;
    }
    return true;
}

int main() { 

    unsigned long k = 0;
    unsigned long N = ~k;
    unsigned long count = 0;
    while (k++ < N)  
        if (isPrime(k)) 
            ++count;

    long double percentPrime = count / N;
    std::cout << "Percentage of prime numbers from 0 to " << N << " = " << percentPrime;

    return 0;
} 
share|improve this question
2  
Or it's running very slowly... – herohuyongtao Jan 21 '14 at 16:51
3  
if (L < 3) return true; – That’s a rather daring redefinition of the term “prime”, you know … – Konrad Rudolph Jan 21 '14 at 16:52
1  
There's no infinite loop. Just one very long one. – R. Martinho Fernandes Jan 21 '14 at 16:52
4  
Be aware that even if your computation somehow did run long enough to complete, count / N; results in 0, because it performs integer division. That is one heck of a debugging cycle. – Steve Jessop Jan 21 '14 at 17:01
3  
Then again, 0 is the percentage of non-negative integers that are prime (that is to say, it is the limit as M tends to infinity of the proportion of non-negative integers less than M that are prime). So just get rid of the loop and you're done ;-) – Steve Jessop Jan 21 '14 at 17:04

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 is_prime function:

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)
            return false;
        ++j;
    }
    return true;
}

And your main code would then be:

// initialize some known primes
std::deque<unsigned int> primes;
primes.push_back(2);
primes.push_back(3);
primes.push_back(5);
primes.push_back(7);

for (unsigned int i = 9; i <= 0xFFFFFFFF; i += 2)
{
    if (is_prime(i, primes))
    {
        primes.push_back(i);
    }
}

// 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.

Side Note

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.

share|improve this answer
unsigned long k = 0;
unsigned long N = ~k;

Here N will be 0xFFFFFFFF which is a really big number so the loop is not infinite but long.

share|improve this answer
1  
Or 0xFFFFFFFFFFFFFFFF on 64 bit Linux systems. – Steve Jessop Jan 21 '14 at 16:57
    
Right, I tend to forgot about the different length on 64 bits since I always typedef them in my code. – Eric Fortin Jan 21 '14 at 17:00

It doesn't seems to be infinite, but since it is very long and time consuming it is timingout.

What I suggest is to improve your primality test with some tricks:

1 - you only need to test the number until its square root (sqrt(L))

2 - you only need to test odd numbers for primality (so you can start to try to divide the number by 3 and increase the test by 2, so you will test against 3,5,7,9,etc...)

Cheers

share|improve this answer
2  
3 - you only need to test against other prime numbers found earlier – paul23 Jan 21 '14 at 16:57
    
@paul23 that is true, I didn't added this because you have to store the other primes somewhere and most of the time that is not reasonable. But you are correct, thanks for the reminder. – prmottajr Jan 21 '14 at 16:58
    
@prmottajr it sure is reasonable if you test more than just a few primes in a sequence. :) – Will Ness Jan 21 '14 at 17:41

Not infinite, just extremely long.

It would have been infinite if you had written while (k++ <= N) instead of while (k++ < N)...

BTW, 1 is generally not considered a prime number, but your code yields that it is.

P.S.: If you want a rough estimation of the percentage of primes in the range 1...N, then you can simply do the following math instead: 100/log(N), where log(N) is the natural logarithm of N.

share|improve this answer
1  
Just a note: the 100/log(N) approximation comes from the Prime Number Theorem – Zac Howland Jan 21 '14 at 17:27

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