Sign up ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

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?

share|improve this question

2 Answers 2

up vote 2 down vote accepted

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;
share|improve this answer
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


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

You can compute these efficiently as follows.


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).


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

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):
    for c in xrange(prime_counts[i]+1):
print N,GCD
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.