2

I am working on a prime factorization program implemented in Java. The goal is to find the largest prime factor of 600851475143 (Project Euler problem 3). I think I have most of it done, but I am getting a few errors. Also my logic seems to be off, in particular the method that I have set up for checking to see if a number is prime.

public class PrimeFactor {

    public static void main(String[] args) {
        int count = 0;
        for (int i = 0; i < Math.sqrt(600851475143L); i++) {
            if (Prime(i) && i % Math.sqrt(600851475143L) == 0) {
                count = i;
                System.out.println(count);
            }
        }
    }

    public static boolean Prime(int n) {
        boolean isPrime = false;
        // A number is prime iff it is divisible by 1 and itself only
        if (n % n == 0 && n % 1 == 0) {
            isPrime = true;
        }
        return isPrime;
    }
}

Edit

public class PrimeFactor {

    public static void main(String[] args) {
        for (int i = 2; i <= 600851475143L; i++) {
            if (isPrime(i) == true) {
                System.out.println(i);
            }
        }
    }

    public static boolean isPrime(int number) {
        if (number == 1) return false;
        if (number == 2) return true;
        if (number % 2 == 0) return false;
        for (int i = 3; i <= number; i++) {
            if (number % i == 0) return false;
        }
        return true;
    }
}
  • What errors do you get? and in which lines do you get errors? – Eternal Noob Nov 25 '10 at 2:56
  • 5
    Your Prime method always returns true because n%n == 0 && n%1 == 0 for all n. That is, all numbers are divisible by themselves and 1. You're missing the "only" part of the definition. – Aaron Novstrup Nov 25 '10 at 2:59
  • Unfortunately, you're not even close. Your primality algorithm doesn't work, because all numbers are divisible by themselves and zero- it's just that primes aren't divisible by anything else, and you have to implement a check for that. The Sieve of Erasthones needs 600GB of RAM to operate up to a value in the 600B range, so recursive prime factorization is the only practical strategy, and with a large problem space, it will take hours or days. This is the basis of all modern encryption: prime factorization above the size of RAM is very slow. – Adam Norberg Nov 25 '10 at 3:02
  • Yes that was one of the logical errors, how could I fix that? – kachilous Nov 25 '10 at 3:03
  • 1
    @Adam, I think you mean " divisible by themselves and one ". – paxdiablo Nov 25 '10 at 3:17

12 Answers 12

22

Why make it so complicated? You don't need do anything like isPrime(). Divide it's least divisor(prime) and do the loop from this prime. Here is my simple code :

public class PrimeFactor {

    public static int largestPrimeFactor(long number) {
        int i;

        for (i = 2; i <= number; i++) {
            if (number % i == 0) {
                number /= i;
                i--;
            }
        }

        return i;
    }

    /**
     * @param args
     */
    public static void main(String[] args) {
        System.out.println(largestPrimeFactor(13195));
        System.out.println(largestPrimeFactor(600851475143L));
    }
}
  • thanks. very straightforward – kachilous Dec 15 '10 at 18:02
  • Just a tip: what's with large prime numbers greater than 2147483647 (Integer.MAX_VALUE) ? Maybe you should use long as the type of the variable "i" in that case. – kisp Apr 12 '13 at 8:58
  • @kisp Why are we doing i--? – user6857832 Oct 12 '16 at 13:07
  • Are you testing me? ;) This cycle take factors in order from the smallest. A number can be dived by the same for multiple times, imagine 2 * 2 * 2 * 2 – kisp Oct 13 '16 at 8:51
10

edit: I hope this doesn't sound incredibly condescending as an answer. I just really wanted to illustrate that from the computer's point of view, you have to check all possible numbers that could be factors of X to make sure it's prime. Computers don't know that it's composite just by looking at it, so you have to iterate

Example: Is X a prime number?

For the case where X = 67:

How do you check this?

I divide it by 2... it has a remainder of 1 (this also tells us that 67 is an odd number)
I divide it by 3... it has a remainder of 1
I divide it by 4... it has a remainder of 3
I divide it by 5... it has a remainder of 2
I divide it by 6... it has a remainder of 1

In fact, you will only get a remainder of 0 if the number is not prime.

Do you have to check every single number less than X to make sure it's prime? Nope. Not anymore, thanks to math (!)

Let's look at a smaller number, like 16.

16 is not prime.

why? because

2*8 = 16
4*4 = 16

So 16 is divisible evenly by more than just 1 and itself. (Although "1" is technically not a prime number, but that's technicalities, and I digress)

So we divide 16 by 1... of course this works, this works for every number

Divide 16 by 2... we get a remainder of 0  (8*2)
Divide 16 by 3... we get a remainder of 1  
Divide 16 by 4... we get a remainder of 0  (4*4)
Divide 16 by 5... we get a remainder of 1
Divide 16 by 6... we get a remainder of 4
Divide 16 by 7... we get a remainder of 2
Divide 16 by 8... we get a remainder of 0  (8*2)

We really only need one remainder of 0 to tell us it's composite (the opposite of "prime" is "composite").

Checking if 16 is divisible by 2 is the same thing as checking if it's divisible by 8, because 2 and 8 multiply to give you 16.

We only need to check a portion of the spectrum (from 2 up to the square-root of X) because the largest number that we can multiply is sqrt(X), otherwise we are using the smaller numbers to get redundant answers.

Is 17 prime?

17 % 2 = 1
17 % 3 = 2
17 % 4 = 1 <--| approximately the square root of 17 [4.123...]
17 % 5 = 2 <--|
17 % 6 = 5
17 % 7 = 3

The results after sqrt(X), like 17 % 7 and so on, are redundant because they must necessarily multiply with something smaller than the sqrt(X) to yield X.

That is,

A * B = X

if A and B are both greater than sqrt(X) then

A*B will yield a number that is greater than X.

Thus, one of either A or B must be smaller than sqrt(X), and it is redundant to check both of these values since you only need to know if one of them divides X evenly (the even division gives you the other value as an answer)

I hope that helps.

edit: There are more sophisticated methods of checking primality and Java has a built-in "this number is probably prime" or "this number is definitely composite" method in the BigInteger class as I recently learned via another SO answer :]

4

You need to do some research on algorithms for factorizing large numbers; this wikipedia page looks like a good place to start. In the first paragraph, it states:

When the numbers are very large, no efficient integer factorization algorithm is publicly known ...

but it does list a number of special and general purpose algorithms. You need to pick one that will work well enough to deal with 12 decimal digit numbers. These numbers are too large for the most naive approach to work, but small enough that (for example) an approach based on enumerating the prime numbers starting from 2 would work. (Hint - start with the Sieve of Erasthones)

  • Actually, for numbers this size, the most naive method should still be fine. I did a quick change using 600852871609, which is 775147^2, and a naive test (albeit, in C++ instead of Java) still gives what appear to be instantaneous results (and timing says less than 0.1 seconds). – Jerry Coffin Nov 25 '10 at 4:41
  • @Jerry - it depends on how naively you test whether each number is prime. I'm trying to be somewhat vague here to encourage the OP to work it out for himself. – Stephen C Nov 25 '10 at 6:33
4

Here is very elegant answer - which uses brute force (not some fancy algorithm) but in a smart way - by lowering the limit as we find primes and devide composite by those primes...

It also prints only the primes - and just the primes, and if one prime is more then once in the product - it will print it as many times as that prime is in the product.

    public class Factorization {
    public static void main(String[] args) {
    long composite = 600851475143L;
    int limit = (int)Math.sqrt(composite)+1;
    for (int i=3; i<limit; i+=2)
    {
        if (composite%i==0)
        {
            System.out.println(i);
            composite = composite/i;
            limit = (int)Math.sqrt(composite)+1;
            i-=2;   //this is so it could check same prime again
        }
    }
    System.out.println(composite);
    }
}
  • I just noticed that it will totally miss factors of two (although it is easy to see if the number is even when entering number) - there could be another while(composite%2==0) before this loop to check how many times it has factor of two in itself... – Stijak Apr 9 '12 at 13:44
2

You want to iterate from 2 -> n-1 and make sure that n % i != 0. That's the most naive way to check for primality. As explained above, this is very very slow if the number is large.

2

To find factors, you want something like:

long limit = sqrt(number);
for (long i=3; i<limit; i+=2)
    if (number % i == 0)
        print "factor = " , i;

In this case, the factors are all small enough (<7000) that finding them should take well under a second, even with naive code like this. Also note that this particular number has other, smaller, prime factors. For a brute force search like this, you can save a little work by dividing out the smaller factors as you find them, and then do a prime factorization of the smaller number that results. This has the advantage of only giving prime factors. Otherwise, you'll also get composite factors (e.g., this number has four prime factors, so the first method will print out not only the prime factors, but the products of various combinations of those prime factors).

If you want to optimize that a bit, you can use the sieve of Eratosthenes to find the prime numbers up to the square root, and then only attempt division by primes. In this case, the square root is ~775'000, and you only need one bit per number to signify whether it's prime. You also (normally) only want to store odd numbers (since you know immediately that all even numbers but two are composite), so you need ~775'000/2 bits = ~47 Kilobytes.

In this case, that has little real payoff though -- even a completely naive algorithm will appear to produce results instantly.

  • how would you know that i is prime if your just checking to see if i divides evenly into number – kachilous Nov 25 '10 at 3:31
  • @Krysten: you wouldn't. As I said, this finds factors, not just prime factors. I've edited the answer, however, to add a method that will only show prime factors. – Jerry Coffin Nov 25 '10 at 3:42
  • @Krysten: 29 is a prime number because there are no numbers less than 29 that evenly divide into it. No number from 2 to 28 can divide 29 and not have a remainder or a fractional component. Thus, you can divide a number by every integer below it to determine if it is prime or not. You can also notice that you only have to divide it by every number up to the square root of the number you are checking, and this is because...[I will elaborate in an answer for more space/formatting] – sova Nov 25 '10 at 3:46
1

I think you're confused because there is no iff [if-and-only-if] operator.

Going to the square root of the integer in question is a good shortcut. All that remains is checking if the number within that loop divides evenly. That's simply [big number] % i == 0. There is no reason for your Prime function.

Since you are looking for the largest divisor, another trick would be to start from the highest integer less than the square root and go i--.

Like others have said, ultimately, this is brutally slow.

  • You could always check 2, start at 3 and increment i by 2 every step to reduce the time by half. A simple way to improve this method of determining primality. – AndyPerfect Nov 25 '10 at 3:15
1
    private static boolean isPrime(int k) throws IllegalArgumentException
     {
        int j;

        if (k < 2) throw new IllegalArgumentException("All prime numbers are greater than 1.");
        else {
            for (j = 2; j < k; j++) {
                if (k % j == 0) return false;
            }
        }

        return true;
    }

    public static void primeFactorsOf(int n) {
        boolean found = false;

        if (isPrime(n) == true) System.out.print(n + " ");
        else {
            int i = 2;
            while (found == false) {
                if ((n % i == 0) && (isPrime(i))) {
                    System.out.print(i + ", ");
                    found = true;
                } else i++;
            }
            primeFactorsOf(n / i);
        }
    }
  • can't handle 600851475149. – Will Ness Jun 23 '16 at 22:43
0

For those answers which use a method isPrime(int) : boolean, there is a faster algorithm than the one previously implemented (which is something like)

private static boolean isPrime(long n) { //when n >= 2
    for (int k = 2; k < n; k++)
        if (n % k == 0) return false;

    return true;
}

and it is this:

private static boolean isPrime(long n) { //when n >= 2
    if (n == 2 || n == 3) return true;

    if (n % 2  == 0 || n % 3 == 0) return false;

    for (int k = 1; k <= (Math.floor(Math.sqrt(n)) + 1) / 6; k++)
        if (n % (6 * k + 1) == 0 || n % (6 * k - 1) == 0) return false;

    return true;
}

I made this algorithm using two facts:

  1. We only need to check for n % k == 0 up to k <= Math.sqrt(n). This is true because for anything higher, factors merely "flip" ex. consider the case n = 15, where 3 * 5 = 5 * 3, and 5 > Math.sqrt(15). There is no need for this overlap of checking both 15 % 3 == 0 and 15 % 5 == 0, when we could just check one of these expressions.
  2. All primes (excluding 2 and 3) can be expressed in the form (6 * k) + 1 or (6 * k) - 1, because any positive integer can be expressed in the form (6 * k) + n, where n = -1, 0, 1, 2, 3, or 4 and k is an integer <= 0, and the cases where n = 0, 2, 3, and 4 are all reducible.

Therefore, n is prime if it is not divisible by 2, 3, or some integer of the form 6k ± 1 <= Math.sqrt(n). Hence the above algorithm.

--

Wikipedia article on testing for primality

--

Edit: Thought I might as well post my full solution (*I did not use isPrime(), and my solution is nearly identical to the top answer, but I thought I should answer the actual question):

public class Euler3 {

    public static void main(String[] args) {
        long[] nums = {13195, 600851475143L};

        for (num : nums)
            System.out.println("Largest prime factor of " + num + ": " + lpf(num));

    }

    private static lpf(long n) {
        long largestPrimeFactor = 1;
        long maxPossibleFactor = n / 2;

        for (long i = 2; i <= maxPossibleFactor; i++)
            if (n % i == 0) {
                n /= i;
                largestPrimeFactor = i;

                i--;
            }

            return largestPrimeFactor;

    }

}
  • HI, and welcome to Stack Overflow. :) how about 600851475149, can you find two key improvements to your code so that it could factorize that number, in a sane amount of time? (and the top-voted answer here is no good, like most of the rest of them, unfortunately). – Will Ness Jun 23 '16 at 22:42
  • Hi! Sorry I never saw your comment, but I figured better late than never. One thing I though of would be to create a list beginning 0,0,2,3,0,5,0,7,0... and containing zeroes in place for all elements except those of the form 6k-1 and 6k+1, where the number itself sits there, and going up to floor(sqrt(n)). Then, skipping zeroes, dividing out all instances of a given number, storing that number, and then replacing it and all its multiples with 0. This combines the 6k-1 and 6k+1 trick, the Sieve of Eratosthenes, as well as reducing the maximum number to test. What other tricks am I missing? – Ben Colson Sep 7 '18 at 5:27
  • Hi. You describe a complete re-write. I meant, make two changes in long maxPossibleFactor = n / 2; for (long i = 2; i <= maxPossibleFactor; i++){ ... }. – Will Ness Sep 7 '18 at 10:16
  • Hmm, perhaps set maxPossibleFactor = floor(sqrt(n)) and instead of i++, divide out factors of 2 and 3 first, and then increase i by two each time i.e. i+=2 (and then replace the i-- inside the for loop with i-=2). As an aside, how do you insert into comments text that has the code-like format? – Ben Colson Sep 7 '18 at 22:17
  • increase by 2 until when? is the question. for code formatting, enclose code in backticks (`...`). If the code contains backticks, enclose in double-backticks. – Will Ness Sep 8 '18 at 13:11
0

To find all prime factorization

import java.math.BigInteger;
import java.util.Scanner;


public class BigIntegerTest {


     public static void main(String[] args) {


            BigInteger myBigInteger = new BigInteger("65328734260653234260");//653234254
            BigInteger originalBigInteger;
            BigInteger oneAddedOriginalBigInteger;
            originalBigInteger=myBigInteger;
            oneAddedOriginalBigInteger=originalBigInteger.add(BigInteger.ONE);
            BigInteger index;
            BigInteger countBig;


            for (index=new BigInteger("2");  index.compareTo(myBigInteger.add(BigInteger.ONE)) <0; index = index.add(BigInteger.ONE)){

                countBig=BigInteger.ZERO;
                while(myBigInteger.remainder(index) == BigInteger.ZERO ){
                    myBigInteger=myBigInteger.divide(index);
                    countBig=countBig.add(BigInteger.ONE);
                }

                if(countBig.equals(BigInteger.ZERO)) continue;
                System.out.println(index+ "**" + countBig);

            }
            System.out.println("Program is ended!");
     }
}
0

I got a very similar problem for my programming class. In my class it had to calculate for an inputted number. I used a solution very similar to Stijak. I edited my code to do the number from this problem instead of using an input.

Some differences from Stijak's code are these:

I considered even numbers in my code.

My code only prints the largest prime factor, not all factors.

I don't recalculate the factorLimit until I have divided all instances of the current factor off.

I had all the variables declared as long because I wanted the flexibility of using it for very large values of number. I found the worst case scenario was a very large prime number like 9223372036854775783, or a very large number with a prime number square root like 9223371994482243049. The more factors a number has the faster the algorithm runs. Therefore, the best case scenario would be numbers like 4611686018427387904 (2^62) or 6917529027641081856 (3*2^61) because both have 62 factors.

public class LargestPrimeFactor
{
    public static void main (String[] args){
        long number=600851475143L, factoredNumber=number, factor, factorLimit, maxPrimeFactor;
        while(factoredNumber%2==0)
            factoredNumber/=2;
        factorLimit=(long)Math.sqrt(factoredNumber);
        for(factor=3;factor<=factorLimit;factor+=2){
            if(factoredNumber%factor==0){
                do  factoredNumber/=factor;
                while(factoredNumber%factor==0);
                factorLimit=(long)Math.sqrt(factoredNumber);
            }
        }
        if(factoredNumber==1)
            if(factor==3)
                maxPrimeFactor=2;
            else
                maxPrimeFactor=factor-2;
        else
            maxPrimeFactor=factoredNumber;
        if(maxPrimeFactor==number)
            System.out.println("Number is prime.");
        else
            System.out.println("The largest prime factor is "+maxPrimeFactor);
    }
}
0
public class Prime
{
 int i;   

 public Prime( )
 {
    i = 2;
 }

 public boolean isPrime( int test ) 
 {
    int k;

    if( test < 2 )
        return false;
    else if( test == 2 )  
        return true;
    else if( ( test > 2 ) && ( test % 2 == 0 ) )
        return false;
    else
    {
        for( k = 3; k < ( test/2 ); k += 2 )
        {
            if( test % k == 0 ) 
                return false;
        }

    }

    return true;

 }

 public void primeFactors( int factorize )
 {
    if( isPrime( factorize ) )
    {
        System.out.println( factorize );
        i = 2;
    }
    else
    {
        if( isPrime( i ) && ( factorize % i == 0 ) )
        {
            System.out.print( i+", " );
            primeFactors( factorize / i );
        }
        else
        {
            i++;
            primeFactors( factorize );
        }
   }

   public static void main( String[ ] args )
   {
       Prime p = new Prime( );

       p.primeFactors( 649 );
       p.primeFactors( 144 );
       p.primeFactors( 1001 );
   }
}

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