Though you cannot get the asymptotic bound of your method by only experimenting, sometimes you can **evaluate** its behavior by drawing a graph of the complexities similar to your function, and looking at the behavior.

You can do it with drawing a graph of some functions `y = f(n)`

such that `f(10000) ~= g(10000)`

[where `g`

is your function], and check the behavior difference.

In your example, we get the following graphs:

We can clearly see that:

- The behavior of your results is sub quadric
- The behavior is above linear.
- It is very close to logarithmic behavior, but just a bit "higher".

From this, we can deduce that your algorithms is **probably** `O(n^2)`

[not strict! remember, big O is not a strict bound], and also could be `O(nlogn)`

, if we deduce the difference from the `O(nlogn)`

function is a noise.

**Notes:**

- This method
**proves nothing** about the algorithm, and particularly
doesn't give you any worst case [or even average case] bound.
- This method is
**usually used to evaluate two algorithms**, and not some pre defined functions, to check which is better for which inputs.

**EDIT:**

I drew all the graphs as `y1(x) = f(x)`

, `y2(x) = g(x)`

, ... because I found it easier to explain this way, but usually when you compare two algorithms [as you often actually use this method], the function is `y(x) = f(x) / g(x)`

, and you check if `y(x)`

is staying close to 1, growing, shrinking?

average caseanalysis. the worst case is quadric. – amit Mar 2 '12 at 17:42