# Extended Euclidean Algorithm runs in time O(log(m)^2)

I'm interested in justification of the following line from the wikipedia article:

"This algorithm [extended euclidean algorithm] runs in time O(log(m)^2), assuming |a| < m, and is generally more efficient than exponentiation." http://en.wikipedia.org/wiki/Modular_multiplicative_inverse

Why is this so? Can anyone explain this to me? I understand completely the algorithm and all the maths, it is just that i do not see how to determine the complexity of such algorithms. Any more general hints?

Also, additionally: Is log meant to be the natural logarithm (ln) or the one with base 2?

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"An algorithm is said to take logarithmic time if T(n) = O(log n). Due to the use of the binary numeral system by computers, the logarithm is frequently base 2 (that is, log2 n, sometimes written lg n). However, by the change of base equation for logarithms, loga n and logb n differ only by a constant multiplier, which in big-O notation is discarded; thus O(log n) is the standard notation for logarithmic time algorithms regardless of the base of the logarithm.", so log base doesn't matter it's really a constant base. –  CBredlow Dec 19 '12 at 13:53