The thing with Project Euler is that there is usually an obvious brute-force method to do the problem, which will take just about forever. As the questions become more difficult, you will need to implement clever solutions.

One way you can solve this problem is to use a loop that always finds the smallest (positive integer) factor of a number. When the smallest factor of a number is that number, then you've found the greatest prime factor!

Detailed Algorithm description:

You can do this by keeping three variables:

The number you are trying to factor (A)
A current divisor store (B)
A largest divisor store (C)

Initially, let (A) be the number you are interested in - in this case, it is 600851475143. Then let (B) be 2. Have a conditional that checks if (A) is divisible by (B). If it is divisible, divide (A) by (B), reset (B) to 2, and go back to checking if (A) is divisible by (B). Else, if (A) is not divisible by (B), increment (B) by +1 and then check if (A) is divisible by (B). Run the loop until (A) is 1. The (3) you return will be the largest prime divisor of 600851475143.

There are numerous ways you could make this more effective - instead of incrementing to the next integer, you could increment to the next necessarily prime integer, and instead of keeping a largest divisor store, you could just return the current number when its only divisor is itself. However, the algorithm I described above will run in seconds regardless.

The implementation in python is as follows:-

```
def lpf(x):
lpf = 2;
while (x > lpf):
if (x%lpf==0):
x = x/lpf
lpf = 2
else:
lpf+=1;
print("Largest Prime Factor: %d" % (lpf));
def main():
x = long(raw_input("Input long int:"))
lpf(x);
return 0;
if __name__ == '__main__':
main()
```

Example: Let's find the largest prime factor of 105 using the method described above.

Let (A) = 105. (B) = 2 (we always start with 2), and we don't have a value for (C) yet.

Is (A) divisible by (B)? No. Increment (B) by +1: (B) = 3. Is Is (A) divisible by (B)? Yes. (105/3 = 35). The largest divisor found so far is 3. Let (C) = 3. Update (A) = 35. Reset (B) = 2.

Now, is (A) divisible by (B)? No. Increment (B) by +1: (B) = 3. Is (A) divisible by (B)? No. Increment (B) by +1: (B) = 4. Is (A) divisible by (B)? No. Increment (B) by +1: (B) = 5. Is (A) divisible by (B)? Yes. (35/5 = 7). The largest divisor we found previously is stored in (C). (C) is currently 3. 5 is larger than 3, so we update (C) = 5. We update (A)=7. We reset (B)=2.

Then we repeat the process for (A), but we will just keep incrementing (B) until (B)=(A), because 7 is prime and has no divisors other than itself and 1. (We could already stop when (B)>((A)/2), as you cannot have integer divisors greater than half of a number - the smallest possible divisor (other than 1) of any number is 2!)

So at that point we return (A) = 7.

Try doing a few of these by hand, and you'll get the hang of the idea

`notPrime()`

function. :) – Greg Hewgill Dec 9 '09 at 22:14