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There are a lot of related questions here on SO, but they all ask about writing a program to compute the complexity of arbitrary algorithms (which is obviously undecideable). I am willing to make the following restrictions on the input:

  1. The algorithm terminates
  2. The algorithm is purely functional

The question is, can a program be written to compute the time complexity of such an algorithm through static analysis? If the input algorithm does not terminate, the program behaviour is undefined (it may crash, return a lie, or fail to terminate).

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Can you edit and actually ask a question that can be answered? I see a statement of requirements, but no actual question. –  Ken White Nov 14 '12 at 0:41
@KenWhite the question wis in the title, but I've updated to put it more clearly in the body :) –  singpolyma Nov 14 '12 at 1:42
:-) I read a statement in the title (no question at all). It's much clearer now what you are actually asking. Thanks, and +1. –  Ken White Nov 14 '12 at 1:45

3 Answers 3

Given the restriction that the algorithm stops it's possible. Execute the algorithm for each possible input and measure execution time. Next, choose a function as a possible upper boundary and test it for each of the results. If not good enough, increase the boundary and retest. Repeat till the boundary is good enough.

Edit: This solution assumes boundaries of a real computer program, i.e. the quantity of different inputs isn't infinite. Otherwise, it's not possible to compute the complexity of a general algorithm. Consider the algorithm for which the complexity is O(n) = nO(n-1). Since the input is infinite, you won't be able to find any function f that can bound the complexity.

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That seems like an answer that may be true, but it isn't very satisfying... –  Jamey Sharp Nov 14 '12 at 6:01
why isn't it satisfying? The question is purely theoretical, so is the answer. I suppose it can be optimized but don't see a reason for doing so –  icepack Nov 14 '12 at 6:51
Personally, I'd find value in a practical solution--can you imagine compiler warnings about inadvertent n**3 algorithms? But as a theoretical answer it still leaves something to be desired, in the heuristic approach to finding boundary functions. This setting doesn't offer much incentive for improving it, though, I'll grant. –  Jamey Sharp Nov 14 '12 at 8:05
I would say that finding whether a general algorithm is bounded by O(n3) will require at least O(n3) computations, either at compile time or at runtime - I don't think either is acceptable in normal situation –  icepack Nov 14 '12 at 8:40
This solution is unlikely to terminate on most terminating inputs (because there are often an infinite number of possible inputs), and also is not very rigorous, being mostly an heursitic. –  singpolyma Nov 14 '12 at 13:32

This is what I would try:

Record the time for some sufficiently large and sufficiently different sized inputs (say 100 000, 1 000 000, 10 000 000, but these values will take forever to execute with O(n^3), so you may want to run it repeatedly by increasing input size by factors of 10 until you get an run that takes a few minutes). I'll assume 3 input sizes is enough, not sure if it is.

Many algorithms have different running times for different inputs of the same size, you may have to run it for a few different inputs of the same size and average the result.

So complexity O(1) is the fastest, then O(log(n)), O(n^1/2), O(n), O(nlogn), O(n^2), O(n^3) with a whole lot in between and a whole lot more, but these should be sufficient to start.

Try O(1), so try to fit the equation k to the first 2 points. This is quite easy, just find a value of k which matches the points best. Check how close the last point is to this equation (how close it is to k).

Try O(log(n)), so try to fit mlog(n) + c to the first 2 points. We know n and the result, so just use elementary maths to solve the equation. Check how close the last point is to this equation (substitute n for the 3rd point into mlog(n) + c (we already know m and c) and subtract the 3rd point's value (and take the absolute value for distance)).

Now do the same for O(n^1/2) with the equation mn^1/2 + c, O(n) with the equation mn + c, etc. and find the equation that best matches the last point, and that's close to the complexity. If you check the complexities in increasing order of complexity, it would be sufficient to just stop as soon as you've reached a value close to the target.

You may also want to include other terms, such as for O(n^2) you can have mn^2 + kn + c, but this will complicate things quite a bit.

Once you've done this a few times, you just use the history of running times to determine the latest algorithm's running time.

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