The following line in your code is executed
n times for each call to
sum_prob = sum_prob + c / pow((double) i, alpha);
It is regrettable that it is necessary to call the
pow() function because, internally, this function sums not one but two Taylor series [considering that
pow(x, alpha) == exp(alpha*log(x))]. If
alpha is an integer, of course, then you can speed the code up a lot by replacing
pow() with simple multiplication. If
alpha is a rational number, then you may be able to speed the code up to a lesser degree by coding a Newton-Raphson iteration to take the place of the two Taylor series. If the last condition holds, please advise.
Fortunately, you have indicated that
alpha does not change. Can you not speed the code up a lot by preparing a table of
pow((double) i, alpha), then letting
zipf() look numbers up the table? That way,
zipf() would not have to call
pow() at all. I suspect that this would save significant time.
Yet further improvements are possible. What if you factored a function
sumprob() out of
zipf()? Could you not prepare an even more aggressive look-up table for
Maybe some of these ideas will move you in the right direction. See what you cannot do with them.
Update: I see that your question as now revised may not be able to use this answer. From the present point, your question may resolve into a question in complex variable theory. Such are often not easy questions, as you know. It may be that a sufficiently clever mathematician has discovered a relevant recurrence relation or some trick like the normal distribution's Box-Muller technique but, if so, I am not acquainted with the technique. Good luck. (It probably does not matter to you but, in case it does, the late N. N. Lebedev's excellent 1972 book Special Functions and Their Applications is available in English translation from the Russian in an inexpensive paperback edition. If you really, really wanted to crack this problem, you might read Lebedev next -- but, of course, that is a desperate measure, isn't it?)