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.