# Project Euler #3

Question:

The prime factors of 13195 are 5, 7, 13 and 29.

What is the largest prime factor of the number 600851475143?

I found this one pretty easy, but running the file took an extremely long time, it's been going on for a while and the highest number I've got to is 716151937.

Here is my code, am I just going to have a wait or is there an error in my code?

``````        //User made class
public class Three
{
public static boolean checkPrime(long p)
{
long i;
boolean prime = false;
for(i = 2;i<p/2;i++)
{
if(p%i==0)
{
prime = true;
break;
}
}
return prime;
}
``````

}

``````    //Note: This is a separate file
public class ThreeMain
{
public static void main(String[] args)
{
long comp = 600851475143L;
boolean prime;
long i;
for(i=2;i<comp/2;i++)
{
if(comp%i==0)
{
prime = Three.checkPrime(i);
if(prime==true)
{
System.out.println(i);
}
}
}
}
}
``````
-
You only have to loop to `sqrt(n)`, not `n/2`. Also, you can check the 2 case, then start at 3 and increment by 2 each time to double the speed. Also, `== true` is pointless. Also also, it is not evil to have multiple exit points to a function, so you can just `return false;`. Also also also note that it's `false`, not `true` - if the number is divisible by `i`, it's composite. – Ryan O'Hara Nov 6 '12 at 5:01
Oh, wait, you're running a separate loop to check if the factors are prime? That's really slow. Just keep dividing the number to get its prime factors. – Ryan O'Hara Nov 6 '12 at 5:03
Like so. Or, since it's obviously not divisible by 2, shave another 0.02 seconds off. – Ryan O'Hara Nov 6 '12 at 5:06

You're headed in the right direction, but you've gone way past where you need to go and have a couple of mistakes along the way. You're currently checking much higher than you need to verify primes (particularly primes >> 2). Your line: `for(i = 2;i<p/2;i++)` could be `for(i = 2;i*i <= p;i++)` (you need only check up to the square root of a number to determine if it's prime or composite).

Your function to check for primes actually returns true for composites, not primes. You're code:

``````    if ((p%i==0) {
prime = true;
break; }
``````

should be

``````    if ((p%i==0) {
prime = false;
break; }
``````

In your main method, you don't actually need the `boolean prime` at all. From the context of the question, we can assume that there will be more than two prime factors, which means the largest prime factor we need to reduce comp to a smaller and more manageable number is the cube root of comp. Therefore, your line `for(i=2;i<comp/2;i++)` could be `for(i=2;i*i*i<comp;i++)`. Instead of continually checking if `i` divides `comp` and then checking if `i` is prime, you can reduce the size of `comp` by dividing by `i` until `comp` is not divisible by `i` anymore (to check for powers of `i`). Because you're starting with small values of `i` then you will never get a composite number that divides `comp` if you reduce it by `i` each time. When you've reduced `comp` to 1 then the current `i` will be the greatest prime factor and your answer to the problem.

Also, you're lines:

``````    prime = Three.checkPrime(i);
if(prime==true)
``````

can be reduced to:

``````if (Three.checkPrime(i));
``````

because Three.checkPrime() will return, and ultimately be evaluated as, a boolean value.

-

You can simply loop to `sqrt(2)` instead of `n/2` which will save lots of time.

-

Once you've found a factor of your number, you can divide it out to make the remaining number smaller.

``````if (prime)
{
System.out.println(i);

// The factor may occur multiple times, so we need a loop.
do {
comp /= i;
} while (comp % i == 0);
}
``````

Doing this also guarantees that whenever `i` divides `comp`, `i` must be prime since all the smaller primes have already been divided out, so you can remove the prime check:

``````for (i = 2; i < comp/2; i++)
{
if (comp % i == 0)
{
System.out.println(i);

do {
comp /= i;
} while (comp % i == 0);
}
}
``````

Finally, you only need to check `i` up to the square root of `comp` since any factor larger than the square root must be accompanied by one that's smaller than the square root. (i.e. if `i*j == comp`, one of `i` or `j` must be `<=` the square root of `comp`).

There are a few more tricks that can be applied, but this should be more than enough for this problem.

-

Your algorithm is slow. Here's the standard way to factor an integer by trial division:

``````define factors(n)
f = 2
while f * f <= n
if n % f == 0
output f
n /= f
else
f = f + 1
output n
``````

There are better ways to factor integers; you can read about some of them in an essay at my blog. But this algorithm is sufficient for Project Euler #3, delivering an answer in less than a second in most any modern language.

-

Here i am writing two different logic to solne this problem . I am quite sure it work faster

First one is

``````import java.util.ArrayList;
import java.util.List;

public class Problem3 {
public void hfactor(long num)
{
List<Long> ob =new ArrayList<Long>();
long working =num;
long current =2;
while(working !=1)
{boolean isprime = true;
for(Long prime :ob)
{
if(current%prime == 0)
{ isprime =false;
break;
}
}
if(isprime)
if(working%current ==0)
{
working /=current;
}
}

current++;
}
System.out.println(ob.get(ob.size()-1));
}

public static void main(String[] args) {
Problem3 ob1 =new Problem3();
ob1.hfactor(13195);
}
}
``````

Second is

``````public static void main(String[] args) {
List <Long> ob = new ArrayList<Long>();
List<Long> ob1 = new ArrayList<Long>();

long num =13195;
for(int i = 2; i<num; i++)
{
if (num%i ==0)
}

for (int i =0; i<ob.size(); i++)
for(int j =2; j<ob.get(i); j++)
{
if (ob.get(i)%j ==0)
{
ob.set(i, (long) 0);
}
}
for(int i =0; i<ob.size(); i++){
if(ob.get(i)!=0)
{