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what is the fastest way to compute the greatest common divisor of n numbers?

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2  
finding GCD recursively is the fastest known method. Do you want some kind of special optimization? – Shamim Hafiz Feb 3 '11 at 11:28
1  
@Gunner: The question is about the GCD of more than 2 arguments. – Marcelo Cantos Feb 3 '11 at 11:30
1  
Every method I can think of that does not use the fact that gcd(a,b,c)=gcd(gcd(a,b),c) is slower. – Peter G. Feb 3 '11 at 12:38
1  
Why do you ask? Using gcd(a,b,c)=gcd(gcd(a,b),c) is the best method, much faster in general than using for example factorization. In fact, for polynomials one uses gcd with the derivative first to find factors which occurs more than once. – starblue Feb 3 '11 at 13:00
1  
I'd probably try to find the greatest common power of base of number representation by counting common trailing zeros, followed by taking the remainder from dividing the second smallest number in set by the smallest - wait, this is just GCD from smallest to largest. Meh. Look for Lehmer and why matrix multiplication helps it. – greybeard May 10 at 5:44

You may want to sort the numbers first and compute the gcd recursively starting from the smallest two numbers.

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Without recursion:

int result = numbers[0];
for(int i = 1; i < numbers.length; i++){
    result = gcd(result, numbers[i]);
}
return result;

For very large arrays, it might be faster to use the fork-join pattern, where you split your array and calculate gcds in parallel. Here is some pseudocode:

int calculateGCD(int[] numbers){
    if(numbers.length <= 2){
        return gcd(numbers);    
    }
    else {
        INVOKE-IN-PARALLEL {
            left = calculateGCD(extractLeftHalf(numbers));
            right = calculateGCD(extractRightHalf(numbers));
        }
        return gcd(left,right);
    }
}
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If you have a lot of small numbers, factorization may be actually faster.

//Java
int[] array = {60, 90, 45};
int gcd = 1;
outer: for (int d = 2; true; d += 1 + (d % 2)) {
    boolean any = false;
    do {
        boolean all = true;
        any = false;
        boolean ready = true;
        for (int i = 0; i < array.length; i++) {
            ready &= (array[i] == 1);
            if (array[i] % d == 0) {
                any = true;
                array[i] /= d;
            } else all = false;
        }
        if (all) gcd *= d;
        if (ready) break outer;
    } while (any);
}
System.out.println(gcd);

(works for some examples, but not really tested)

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Refer the Wikipedia link for further optimized algorithm for the problem: http://en.wikipedia.org/wiki/Lehmer%27s_GCD_algorithm

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Here's a gcd method that uses the property that gcd(a, b, c) = gcd(a, gcd(b, c)).
It uses BigInteger's gcd method since it is already optimized.

public static BigInteger gcd(BigInteger[] parts){
    BigInteger gcd = parts[0];
    for(int i = 1; i < parts.length; i++)
        gcd = parts[i].gcd(gcd);
    return gcd;
}
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I have wrote this function for calculating gcd of n numbers by using C++'s in built __gcd(int a, int b) function.

int gcd(vector<int>vec, int vsize)
{
    int gcd = vec[0];
    for (int i=1; i<vsize; i++)
    {
        gcd = __gcd(gcd, vec[i]);
    }
    return gcd;
}
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up vote -1 down vote accepted

Here was the answer I was looking for. The best way to find the gcd of n numbers is indeed using recursion.ie gcd(a,b,c)=gcd(gcd(a,b),c). But I was getting timeouts in certain programs when I did this.

The optimization that was needed here was that the recursion should be solved using fast matrix multiplication algorithm.

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8  
Can you elaborate ? – g4ur4v Nov 18 '12 at 17:25
    
An accepted answer with two down votes? This is why, I have trust issues. – Aman Garg Jan 1 at 12:40
    
There is a "half-GCD" algorithm used in GNU MultiPrecision, which purportedly uses matrix multiplication: Subquadratic GCD, based on Niels Möller, “On Schönhage’s algorithm and subquadratic integer GCD computation”, in Mathematics of Computation, volume 77, January 2008, pp. 589-607. (From just squinting my eyes, GMP does not seem to directly support GCD of more than two numbers.) – greybeard May 10 at 5:18

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