# Euclid's Algorithm Time Complexity

I have a question about the Euclid's Algorithm for finding greatest common divisors.

gcd(p,q) where p > q and q is a n-bit integer.

I'm trying to follow a time complexity analysis on the algorithm (input is n-bits as above)

``````gcd(p,q)
if (p == q)
return q
if (p < q)
gcd(q,p)
while (q != 0)
temp = p % q
p = q
q = temp
return p
``````

I already understand that the sum of the two numbers, `u + v` where `u` and `v` stand for initial values of `p` and `q` , reduces by a factor of at least `1/2`.

Now let `m` be the number of iterations for this algorithm. We want to find the smallest integer `m` such that `(1/2)^m(u + v) <= 1`

Here is my question. I get that sum of the two numbers at each iteration is upper-bounded by `(1/2)^m(p + q)`. But I don't really see why the max `m` is reached when this quantity is `<= 1`.

The answer is O(n) for n-bits `q`, but this is where I'm getting stuck.

• It is not true that `p+q` is halfed at a step. Consider `p=199` and `q=100`. Mar 29, 2017 at 4:52
• I made some edits. Mar 29, 2017 at 6:10
• It is O (Log(min a, b )) Mar 29, 2017 at 6:28
• This might help stackoverflow.com/a/18473133/2290983 Mar 29, 2017 at 7:41
• Possible duplicate of Time complexity of Euclid's Algorithm Mar 29, 2017 at 13:49