I hope you're fitting to the peaks, since you're looking for worst-case complexity.

Anyway...

If **a** and **b** are **N** bits long, then in the worst case (Fibonacci pairs), the extended Euclidean algorithm will take **O(N)** iterations.

Let **f(N)** be the cost of a single iteration. Certainly **f(N)** will be at least linear, but still polynomial, and nearly half of the iterations in each case will involve arguments at least **N/2** bits long, so the total complexity will be in **O(f(N) log N)**

Now, what exactly **f(N)** is will depend in the particulars of how large-integer operations are implemented in your library. The division/remainder operation will dominate, although wikipedia says that if you use Newton–Raphson division then the complexity of that is the same as multiplication (although there will certainly be a constant multiplier!).

Multiplication costs **O(N * log N * log log N)** in the limit with the Schönhage–Strassen, and hopefully your library will use that eventually... so when the numbers get *really* big, the extended Euclidean algorithm should take **O(N * log^2 N * log log N)** in the worst case.