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On a recent exam, we were given a function to count how many doubles (not the primitive double, but how many times an item appears twice) appear in an unsorted ArrayList.

I correctly determined that the Big O complexity was O(N^2), but was only given partial credit because I incorrectly determined the full complexity. The function was as follows:

public static <T> int countDoubles(ArrayList<T> list, int index, Comparator<? super T> cmp) {
    if (index >= list.size())
        return 0;
    int count = 0;
    for (int i = index + 1; i < list.size(); i++) {
        if (cmp.compare(list.get(index), list.get(i)) == 0)
            count++;
    }
    return count + countDoubles(list, index + 1, cmp);
}

In the exam solution he just released, he gave this explaination:

There are N items in the input collection, and the method calls itself over and over with a reduction step that produces a new index N times till it reaches the base case (end of the collection). For each recursive frame there is a for loop that work on one less element in the collection in each frame repeatedly until it reaches the end of the collection. So there are N recursive calls and N -1 steps for the first call, N-2 for the second, N-3 for the third and so on, until the end of the array is reached. This behavior has a quadratic growth in terms of the upper bound complexity as it will present the following expression:

T(N) = (N-1) + (N-2) + (N-3) + ... + 1 = N(N-1)/2 = ((N^2)/2) - (N/2) = O(N^2)

In attempt to correctly understand this I attempted to draw out a simple array of size ten, reducing its examined size by one every time.

[] [] [] [] [] [] [] [] [] []
   [] [] [] [] [] [] [] [] []
      [] [] [] [] [] [] [] []
         [] [] [] [] [] [] []
            [] [] [] [] [] []
               [] [] [] [] []
                  [] [] [] []
                     [] [] []
                        [] []
                           []

Counting the levels of recursion makes sense as N. Counting each element out yields that 9 + 8 ... = 45 Considering that 100 (N levels of recursion * N elements) is 100, I do not understand where N/2 comes from, let alone ((N^2)/2) - (N/2).

Any explaination is much appreciated, as I have been looking for the past month and can't seem to fully grasp what I'm missing. Thank you.

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Try to read about the Master Theorem – eliasah Jul 3 '14 at 5:56
up vote 2 down vote accepted

The sum of the integers from 1 to M is ((M+1) * M) / 2. That's just a mathematical fact (typically proven by induction). Try some examples if you aren't convinced.

The first pass through the algorithm does N-1 compares, and each level of recursion does one less compare, until the last level of recursion does 1 compare. So the total number of compares (for all levels of recursion) is the sum of the integers from 1 to N-1. Substituting N-1 for M in the formula gives the total number of compares as (N * (N-1)) / 2.

From there, it's just algebra

(N * (N-1)) / 2 = (N * N - N) / 2 = ((N^2) / 2) - (N / 2)

The reason for breaking it down that way is because big-O only cares about the N with the largest exponent. Of course, big-O also doesn't care about constants. So you throw away the (N / 2) and you ignore the / 2 and the answer is O(N^2), which is the biggest crock o' ...

Well, never mind my opinion on the matter, that's just the way it is.

share|improve this answer
    
Ooohhhkay. I think I understand much more now. My math was partially wrong, because I wasn't including M, which is 10. I stopped short at 45 when it should have been 55. Additionally, I wasn't even aware of the equation ((M+1) * M) / 2 being used in this situation to sum these up (I was misunderstanding and thinking it was just half of the N^2, which was completely wrong). After that the algebra makes complete sense! Thanks a TON! – BCqrstoO Jul 3 '14 at 6:41
    
Yup, that formula should come in handy at least a few times in your programming career, so it's a good one to know :) – user3386109 Jul 3 '14 at 7:14

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