# Infinite loop happening somewhere here?

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;
}
``````
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Or it's running very slowly... – herohuyongtao Jan 21 '14 at 16:51
`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
There's no infinite loop. Just one very `long` one. – R. Martinho Fernandes Jan 21 '14 at 16:52
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
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.

-
``````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.

-
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

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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`.

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Just a note: the `100/log(N)` approximation comes from the Prime Number Theorem – Zac Howland Jan 21 '14 at 17:27