# Finding largest prime number out of 600851475143?

I'm trying to solve problem 3 from http://projecteuler.net. However, when I run thing program nothing prints out. What am I doing wrong? Problem: What is the largest prime factor of the number 600851475143 ?

``````public class project_3
{
public boolean prime(long x)   // if x is prime return true
{
boolean bool = false;

for(long count=1L; count<x; count++)
{
if( x%count==0 )
{
bool = false;
break;
}
else { bool = true; }
}
return bool;
}

public static void main(String[] args)
{
long ultprime = 0L;  // largest prime value
project_3 object = new project_3();

for(long x=1L; x <= 600851475143L; x++)
{
if( object.prime(x)==true )
{
ultprime = ((x>ultprime) ? x : ultprime);
}
}
System.out.println(ultprime);
}
}
``````
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`for(long x=1L; x<=600851475143L;x++)` - um... that's gonna take a while... –  Mysticial Mar 7 at 18:50
Start with `count=2L` –  jonhopkins Mar 7 at 18:50
And you should stop the `for-loop` on `sqrt(number)`. –  Luiggi Mendoza Mar 7 at 18:51
If you are looking for the largest then I would start in the opposite direction –  Jason Sperske Mar 7 at 18:53
@JasonSperske no you don't. To count down from 600851475143 is terribly inefficient. –  Will Ness Mar 8 at 11:34

Two things:

1) You are starting `count` at 1 instead of 2. All integers are divisible by 1.

2) You are running an O(n^2) algorithm against a rather large N (or at least you will be once you fix point #1). The runtime will be quite long.

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Scroll down the code to see "System.out.println(ultprime);". But your other points are valid. –  rgettman Mar 7 at 18:54
Actually, the code as written is not O(n^2) because the loop inside `prime()` runs exactly once (since `count` starts at 1). –  Ted Hopp Mar 7 at 18:55
Correction, if the algorithm wasn't broken it would be O(n^2) –  Aurand Mar 7 at 19:01
Consider using Sieve of Eratosthenes to find prime numbers en.wikipedia.org/wiki/Sieve_of_Eratosthenes –  Steve Kuo Mar 7 at 20:38
@SteveKuo That's good to find prime numbers, but it's not a good way to solve this kind of problem. To find the largest prime factor of a number, you have to factorise it (well, okay, you don't have to, there are other ways). Simple factorisation by trial division is plenty good enough for a number of the given size, even if it is itself prime. –  Daniel Fischer Mar 8 at 13:36

Not only does your `prime` checking function always return `false`; even if it were functioning properly, your main loop does not seek the input number's factors at all, but rather just the largest prime smaller or equal to it. In pseudocode, your code is equivalent to:

``````foo(n):
x := 0 ;
foreach d from 1 to n step 1:
if is_prime(d):          // always false
x := d
return x                     // always 0

is_prime(d):
not( d % 1 == 0 )            // always false
``````

But you don't need the prime checking function here at all. The following finds all factors of a number, by trial division:

``````factors(n):
fs := []
d  := 2
while ( d <= n/d ):
if ( n % d == 0 ): { n := n/d ; fs := append(fs,d) }
else:              { d := d+1 }
if ( n > 1 ): { fs := append(fs, n) }
return fs
``````

By construction, all the factors thus found, are guaranteed to be prime. It is crucial to enumerate the possible divisors in ascending order, for this to happen1. Ascending order is also the most efficient, because a randomly picked number is more likely to have smaller prime factor than larger one.

The testing for divisibility is done only upto the square root of the number. Each factor, as it is found, is divided into the number being factorized, thus further reducing the run time. Factorization of the number in question runs instantly, taking just 1473 iterations.

It is trivial to augment the above to find the largest factor: just implement `append` as

``````append(fs,d):
return d
``````

1 Because we try to divide by numbers from 2, in ascending order, and because we divide out every factor we find, for any `d` which divides `n`, if `d` is composite it can be represented as a product of primes, all smaller than `d`. So we'd try them already, and divide them out of the number `n`, so the new number that is being tested at that point has no factors equal to those primes, so let alone their product can not be its divisor.

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It's obvious to you and me why the factors in your trial division are always prime, but it might still be better to explain why. –  Daniel Fischer Mar 8 at 13:41

The whole point of Project Euler is that the most obvious approaches to finding the answer will take so long to compute that they aren't worth running. That way you learn to look for the less obvious, more efficient approaches.

Your approach is technically correct in terms of whether or not it is capable of computing the largest prime of some number. The reason you aren't seeing anything print out is that your algorithm is not capable of solving the problem quickly.

The way you've designed this, it'll take somewhere around 4,000,000 years to finish.

If you replaced the 600851475143 number with say 20 it would be able to finish fairly quickly. But you have the 600 billion number, so it's not that simple.

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