# How can I convert a function of input size defined recursively into a direct function of problem input size?

Say I have an algorithm which operates on an input of size n and I know that the time it takes for n is twice the time it takes for n-1. I can observe in this simple case (assuming it takes, say, 1 second for n = 0) that the algorithm takes 2n seconds.

Is there a general method for converting between recursively-defined definitions to the more familiar direct type of expression?

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What is the "direct type"? –  danben Feb 2 '10 at 16:41
f(n) = 2**n instead of f(n) = 2*f(n-1) –  NellerLess Feb 2 '10 at 16:42

"Recursive functions" like this are called Recurrence Relations, and their "direct types" are known as the Closed-form solution.

While the Master Theorem listed by Poita is very helpful in computing time-complexity, it has nothing to do with actually solving recurrence relations.

Wikipedia and Wolfram's Math World (under "See Also") list the closed-forms of some common classes of recurrence relations. However, complicated (non-linear) recurrence relations can be very difficult to find closed-form solutions to, if one exists at all. There is no general algorithm for solving them.

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Master Theorem

In particular:

With T(n) = aT(n/b) + nc

If logba < c, then T(n) = O(nc)

If logba = c, then T(n) = O(nclog[n])

If logba > c, then T(n) = O(nlogba)

That's one useful theorem to know, but doesn't fully answer your question.

What you are looking for is the generator function of a recurrence relation. In general, these are only solvable for very simple cases, i.e. when f(n) = Af(n-1) + Bf(n-1) and f(0) = f(1) = 1 (or f(1) = A). Other recurrence relations are very difficult to solve.