# Fast Iterative GCD

I have GCD(n, i) where i=1 is increasing in loop by 1 up to n. Is there any algorithm which calculate all GCD's faster than naive increasing and compute GCD using Euclidean algorithm?

PS I've noticed if n is prime I can assume that number from 1 to n-1 would give 1, because prime number would be co-prime to them. Any ideas for other numbers than prime?

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C++ implementation, works in O(n * log log n) (assuming size of integers are O(1)):

``````#include <cstdio>
#include <cstring>
using namespace std;

void find_gcd(int n, int *gcd) {
// divisor[x] - any prime divisor of x
//              or 0 if x == 1 or x is prime
int *divisor = new int[n + 1];
memset(divisor, 0, (n + 1) * sizeof(int));

// This is almost copypaste of sieve of Eratosthenes, but instead of
// just marking number as 'non-prime' we remeber its divisor.
// O(n * log log n)
for (int x = 2; x * x <= n; ++x) {
if (divisor[x] == 0) {
for (int y = x * x; y <= n; y += x) {
divisor[y] = x;
}
}
}

for (int x = 1; x <= n; ++x) {
if (n % x == 0) gcd[x] = x;
else if (divisor[x] == 0) gcd[x] = 1; // x is prime, and does not divide n (previous line)
else {
int a = x / divisor[x], p = divisor[x]; // x == a * p
// gcd(a * p, n) = gcd(a, n) * gcd(p, n / gcd(a, n))
// gcd(p, n / gcd(a, n)) == 1 or p
gcd[x] = gcd[a];
if ((n / gcd[a]) % p == 0) gcd[x] *= p;
}
}
}

int main() {
int n;
scanf("%d", &n);
int *gcd = new int[n + 1];
find_gcd(n, gcd);
for (int x = 1; x <= n; ++x) {
printf("%d:\t%d\n", x, gcd[x]);
}
return 0;
}
``````
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I think it's what I was looking for. Could you expalin me what does make commented out code in last for statement inside find_gcd function - or it's irrelevant (just part of some other algorithm)? –  abc Feb 24 '13 at 15:37
These two commented out lines were supposed to be an explanation (or prove of correctness maybe) of what I do in next two lines - it's not a code. I thought it will be helpful to add them, but it seems it's misleading :) They're irrelevant. –  lopek Feb 24 '13 at 16:34

## SUMMARY

The possible answers for the gcd consist of the factors of n.

You can compute these efficiently as follows.

## ALGORITHM

First factorise n into a product of prime factors, i.e. n=p1^n1*p2^n2*..*pk^nk.

Then you can loop over all factors of n and for each factor of n set the contents of the GCD array at that position to the factor.

If you make sure that the factors are done in a sensible order (e.g. sorted) you should find that the array entries that are written multiple times will end up being written with the highest value (which will be the gcd).

## CODE

Here is some Python code to do this for the number 1400=2^3*5^2*7:

``````prime_factors=[2,5,7]
prime_counts=[3,2,1]
N=1
for prime,count in zip(prime_factors,prime_counts):
N *= prime**count

GCD = [0]*(N+1)
GCD[0] = N
def go(i,n):
"""Try all counts for prime[i]"""
if i==len(prime_factors):
for x in xrange(n,N+1,n):
GCD[x]=n
return
n2=n
for c in xrange(prime_counts[i]+1):
go(i+1,n2)
n2*=prime_factors[i]
go(0,1)
print N,GCD
``````
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