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In Computer Science, it is very important for Computer Scientists to know how to calculate the running times of algorithms in order to optimize code. For you Computer Scientists, I pose a question.

I understand that, in terms of n, a double-nested for-loop typically has a running time of n2 and a triple-nested for-loop typically has a running time of n3.

However, for a case where the code looks like this, would the running time be n4?

x = 0;
for(a = 0; a < n; a++)
    for(b = 0; b < 2a; b++)
        for (c=0; c < b*b; c++)
            x++;

I simplified the running time for each line to be virtually (n+1) for the first loop, (2n+1) for the second loop, and (2n)2+1 for the third loop. Assuming the terms are multiplied together, and we extract the highest term to find the Big Oh, would the running time be n4, or would it still follow the usual running-time of n3?

I would appreciate any input. Thank you very much in advance.

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I don't understand why would you expect this to be O(n^3)? –  MK. Jan 26 '11 at 4:59

3 Answers 3

You are correct, n*2n*4n2 = O(n4).

The triple nested loop only means there will be three numbers to multiply to determine the final Big O - each multiplicand itself is dependent on how much "processing" each loop does though.

In your case the first loop does O(n) operations, the second one O(2n) = O(n) and the inner loop does O(n2) operations, so overall O(n*n*n2) = O(n4).

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added sup tags to your powers, hope you don't mind, but I think it's more readable that way. –  paxdiablo Jan 26 '11 at 5:21
    
@paxdiablo thanks! - I didn't know that tag existed, otherwise I would have used it. –  BrokenGlass Jan 26 '11 at 13:38

Could this be a question for Mathematics?

My gut feelings, like BrokenGlass is that it is O(n⁴).

EDIT: Sum of squares and Sum of cubes give a pretty good understanding of what is involved. The answer is a resounding O(n^4): sum(a=0 to n) of (sum(b=0 to 2a) of (b^2)). The inner sum is congruent to a^3. Therefore your outer sum is congruent to n^4.

Pity, I thought you might get away with some log instead of n^4. Never mind.

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Formally, using Sigma Notation, you can obtain this:

enter image description here

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