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I have a quick sort algorithm and a counter that I increment every time a compare or swap is performed. Here are my results for random integer arrays of different sizes -

Array size --- number of operations

10000 --- 238393

20000 --- 511260

40000 --- 1120512

80000 --- 2370145

Edit:

I have removed the incorrect question I was asking in this post. What I am actually asking is -

What Im trying to find out is 'do these results stack up with the theoretical complexity of quicksort (O(N*log(N)))?

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1  
That's not analysis, that's an experiment. –  delnan Mar 2 '12 at 17:33
    
Changed the thread title –  Jim_CS Mar 2 '12 at 17:38
    
It is also experimenting with a very little information. –  amit Mar 2 '12 at 17:40
    
You don't determine the complexity through experiments, you think about it and prove it. O(N*log(N)) is quicksort btw. –  hackartist Mar 2 '12 at 17:40
    
@hackartist: O(nlogn) is quicksort for average case analysis. the worst case is quadric. –  amit Mar 2 '12 at 17:42

2 Answers 2

up vote 1 down vote accepted

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:

graph

We can clearly see that:

  1. The behavior of your results is sub quadric
  2. The behavior is above linear.
  3. 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:

  1. This method proves nothing about the algorithm, and particularly doesn't give you any worst case [or even average case] bound.
  2. 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?

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Appreciate the graphs mate, ty for the explanations too. –  Jim_CS Mar 2 '12 at 18:42

Now, basically what I need to know is how do I interpret those results so I can determine the Big Oh complexity of QuickSort?

By definition, it is impossible to determine the asymptotic complexity of algorithms by considering their behavior for any (finite) set of inputs and extrapolating.

If you want to try anyway, what you should do is what you do in any science: look at the data, come up with a hypothesis (e.g., "these data are approximated by the curve ...") and then try to disprove it (by checking more numbers, for instance). If you can't disprove the hypothesis through further experiments aimed at disproving it, then it can stand. You'll never really know whether you've got it right using this method, but then again, that's true of all empirical science.

As others have pointed out, the preferred (this is an understatement; universally accepted and sole acceptable may be a better phrasing) method of determining the asymptotic bounds of an algorithm is, well, to analyze it mathematically, and produce a proof that it obeys the bound.

EDIT:

This is ignoring the intricacies involved in fitting curves to data, as well as the fact that designing an effectiv experiment is hard to do. I assume you know how to fit curves (it would be no different here than in any other data analysis... you just need to know what you're looking for and how to look) and that you have designed your experiment in such a way that (a) you can answer the questions you want to answer and (b) the answers you get will have some kind of validity. These are separate issues and require literally years of formal education and training in order to begin to properly use and understand.

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