I wanted to know what is the worst case timecomplexity of the pow() function that's built in c++?
That depends on the underlying architecture. On the most common desktop architecture, x86, this is a constant time operation. See this question for more details on how it could be implemented on x86: How to: pow(real, real) in x86 


Here is one implementation, take a look. To be sure, it is a rather complex piece of code, with some 19 special cases. The time complexity does not appear to be dependent on the values passed in. Here is a short description of the method used to compute



You don't mention what system/architecture you're on, so we are left guessing. However, if you're not looking for specifics and just want to browse the code of a freely available implementation See http://www.netlib.org/fdlibm/, specifically http://www.netlib.org/fdlibm/w_pow.c See this question's answer for more background: http://stackoverflow.com/a/2285277/25882 


pow
always has exactly the same number of inputs, complexity (at least as the term is normally used) simply doesn't apply. You can apply complexity measures based on the size of a single input, but that doesn't generally apply to something likepow
in the standard library that takes only a fixedsize input. It could/would apply to computing powers when dealing with arbitrary precision numbers. – Jerry Coffin Nov 16 '12 at 15:33f(x)
in terms ofx
and to assume that it is unbounded (the number of inputs is also bounded by practical limits). – Dietmar Kühl Nov 16 '12 at 16:10O(f(x))
, but it's not entirely clear whatx
is, not to mention whatf(x)
is. I say "may be", because it's also unclear that the concept ofx
approaching infinity applies in this case. It's ultimately more about precision than the magnitudes of the numbers though. – Jerry Coffin Nov 16 '12 at 17:22