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I'm trying to write a function(in java) that will return the number of factors a specific number has.

The following restrictions should be taken into account.

  1. It should be done with BigInteger
  2. Storing previous generated numbers are not allowed, thus more processing and less memory.(You can't use "Sieve of Atkin" like in this)
  3. Negative numbers can be ignored.

This is what I have so far... but it is extremely slow.

public static int getNumberOfFactors(BigInteger number) {
    // If the number is 1
    int numberOfFactors = 1;

    if (number.compareTo(BigInteger.ONE) <= 0)  {
        return numberOfFactors;
    }

    BigInteger boundry = number.divide(new BigInteger("2"));
    BigInteger counter = new BigInteger("2");

    while (counter.compareTo(boundry) <= 0) {
        if (number.mod(counter).compareTo(BigInteger.ZERO) == 0) {
            numberOfFactors++;
        }

        counter = counter.add(BigInteger.ONE);
    }

    // For the number it self
    numberOfFactors++;

    return numberOfFactors;
}

Ps. Not homework

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This also fails if there are repeated factors e.g. 2*2*2 will return 2 (1 for 2 and one for 4) –  Peter Lawrey Apr 13 '12 at 10:17
1  
@PeterLawrey Not true - he is iterating all the factors, never does division. –  Boris Strandjev Apr 13 '12 at 10:19
4  
Factorization can be so slow that it is used in certain cryptographic algorithms. –  9000 Apr 13 '12 at 10:22
    
It's called Euler's totient function, 9000 is right it is not easy problem. –  Betlista Apr 13 '12 at 11:34
1  
@PeterLawrey The question never said it should only return the number of prime factors. I'd assume from the way the question is worded that the number of factors for 8 should return 4 (1, 2, 4, 8) –  patros Apr 13 '12 at 12:53
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2 Answers 2

up vote 13 down vote accepted

I can propose faster solution, though I have a feeling that it will not be fast enough yet. Your solution runs in O(n) and mine will work in O(sqrt(n)).

I am going to use the fact that if n = xi1p1 * xi2p2 * xi3p3 * ... xikpk is the prime factorization of n (i.e. xij are all distinct primes) then n has (p1 + 1) * (p2 + 1) * ... * (pk + 1) factors in total.

Now here goes the solution:

BigInteger x = new BigInteger("2");
long totalFactors = 1;
while (x.multiply(x).compareTo(number) <= 0) {
    int power = 0;
    while (number.mod(x).equals(BigInteger.ZERO)) {
        power++;
        number = number.divide(x);
    }
    totalFactors *= (power + 1);
    x = x.add(BigInteger.ONE);
}
if (!number.equals(BigInteger.ONE)) {
    totalFactors *= 2;
}
System.out.println("The total number of factors is: " + totalFactors);

This can be further optimized if you consider the case of 2 separately and then have the step for x equal to 2 not 1 (iterating only the odd numbers).

Also note that in my code I modify number, you might find it more suitable to keep number and have another variable equal to number to iterate over.

I suppose that this code will run reasonably fast for numbers not greater than 264.

EDIT I will add the measures of reasonably fast to the answer for completeness. As it can be seen in the comments below I made several measurements on the performance of the proposed algorithm for the test case 1000000072, which was proposed by Betlista:

  • If the algorithm is used as is the time taken is 57 seconds on my machine.
  • If I consider only the odd numbers the time is reduced to 28 seconds
  • If I change the check for the end condition of the while to comparing with the square root of number which I find using binary search the time taken reduces to 22 second.
  • Finally when I tried switching all the BigIntegers with long the time was reduced to 2 seconds. As the proposed algorithm will not run fast enough for number larger than the range of long it might make sense to switch the implementation to long
share|improve this answer
    
reasonably fast? How long that code runs for 100000007^2 on your computer? –  Betlista Apr 13 '12 at 11:29
1  
@Betlista with the current solution 57 seconds, when I iterated over only the odd numbers - 28 seconds. When I added a binary search for the square root (so that I avoid multiplications) I reduced it to 22. Probably you are right that in extreme cases it is not that reasonably fast as I claim it to be, but I can't think of better solutions. –  Boris Strandjev Apr 13 '12 at 11:50
1  
@Betlista btw replacing all big integers with long reduced the time to 3 seconds. regretfully the BigInteger are quite of restriction here. –  Boris Strandjev Apr 13 '12 at 11:58
    
To speed this up slightly, add ONE the first time and add TWO after that. i.e 2,3,5,7,.... This halves the run time. –  Peter Lawrey Apr 13 '12 at 12:07
1  
It looks like this would return 4 for 9... aren't you counting the square root twice as a factor? –  patros Apr 13 '12 at 12:58
show 6 more comments

Some improvements:

  1. You only need to check up to sqrt(n), not n/2. That makes your algorithm O(sqrt(n)) instead of O(n).
  2. You only need to check odd numbers after checking 2, which should double the speed.
  3. Although you can't use previous numbers, you can construct a sieve with known primes and a little storage: 2, 3 are prime, so only need to check (for example) 11,13,17,19,23 and not 12,14,15,16,18. Thus you can store a pattern of deltas from 3: [+2,+4], repeat every 6:
var deltas = [2,4];
var period = 6;
var val = 3;
var i=0;
while(val<sqrt(n)) {
    var idx = i%deltas.length; // i modulo num deltas
    val += deltas[idx];
    count += isFactor(n,val);
    // if reached end of deltas, add period
    if(idx == deltas.length-1) {
        val += period - deltas[idx];
    }
    ++i;
}

Once you have this result, you obviously have to add 2 and/or 3 if they are factors.

I worked the above pattern out when I was bored at school. You can work out the pattern for any list of primes, but there is a law of diminishing returns; each prime you add increases the period, and hugely increases the length of the list of deltas. So for a long list of known primes, you get an extremely long list of deltas and only a minor improvement in speed. However, do test whether a speed up is worth it.

Since it merely knocks out a known fraction of the values (2/3rds using the 2-value delta shown), this is stil O(sqrt(n)).

Combining the sieve with the sqrt bound, you should get a speedup of 4/(3*sqrt(n)).

[Edit: was adding the period to the last value, not period-lastdelta. Thanks @Betlista]

share|improve this answer
    
I think that your code is not working fine at least for n = 9 or n = 49. The idea about period could be "skip numbers ending with one of 0, 2, 4, 5, 6, 8", so deltas are 4, 2, 2, 2 starting from 3 - checking 4 of 10 numbers... –  Betlista Apr 13 '12 at 12:16
    
9 is divisible by 3, so the check for 3 should be done outside the loop. 49 is divisible by 7, and 7 is picked as the +4 delta from 3 in the first iteration. 49 will also be hit by the +4 delta on the 8th iteration. –  Phil H Apr 13 '12 at 12:22
    
deltas[0] is 2, so you are checking 5, 9, 11, 15... (skipping primes 7 and 13) How the 49 can be hit if there is val < sqrt(n) condition ? Initialization for count is missing, but I guess it's 2 –  Betlista Apr 13 '12 at 12:33
    
@Betlista: Thanks for checking that, I wasn't adding the right thing at the end of the list. Instead of adding 6, I should add 6-4 (the final delta). That way you get 5,7, 11,13, 17,19 –  Phil H Apr 13 '12 at 12:43
    
I tried and it skipped 19, 23 and 43 for example... –  Betlista Apr 13 '12 at 13:12
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