# Complexity of Code = n^2? [closed]

What is the complexity of the following code:

int data[] = { /* some numbers here */ };
n = data.length;

int lessThanCounter = 0;
for (int i=0; i<n; i++)
for (int j=n-1; j>i; j--)
if (data[i]<data[j]) lessThanCounter++;


By my calculations it is O(n^2) - is this correct?

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## closed as off topic by Wooble, Achintya Jha, Shawn Chin, Neolisk, John KraftMay 1 at 15:36

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As your outer loop executes n times then the first multiplier is n.

The inner loop executes n-1, n-2 ... 0 which is roughly equivalent to (n-1)/2.

This therefore executes n * (n-1)/2 times and is therefore either O(n^2) or O(n^2/2) depending on which flavour of big-O you are being taught.

NB: I added the O(n^2/2) to pander to the many educational establishments that do not properly understand Big Oh and therefore expect their students to evaluate the Big-Oh of bubble-sort in that way. I apologise for that clearly misleading mistake.

NBB: In case that is not clear O(n^2/2) is wrong and I knew it was wrong when I posted it. However, if your teacher expects you to put that in your answer just do so. It is unlikely you will ever make progress attempting to explain why it is wrong.

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Which "flavour" of Big-O exists where O(n^2/2) is different from O(n^2)? –  sepp2k May 1 at 11:27
( Not mathematical. Maybe banana :-) ) –  Stephen C May 1 at 11:29
@sepp2k - <Grin> - The "flavour" of "Big Oh completely misunderstood" - often taught in colleges and many less reputable establishments. –  OldCurmudgeon May 1 at 11:31
There is no such thing as O(N^2/2). –  EJP May 1 at 12:16
Technically, O(n^2/2) is fine. It's exactly the same as the shorter O(n^2) or the longer O(123456789012345*n^2/6), so it's "wrong" to use the more verbose forms, but it's not incorrect, @EJP. –  Daniel Fischer May 1 at 12:44

Yes, that's correct. The body of the inner loop is executed n-1 times on the first iteration of the outer loop, n-2 times on the second iteration and so on until the nth iteration when it iterates n-n = 0 times. So it's executed n-1 + n-2 + ... + 0 = (n-1)*n/2 = (n^2-n)/2 times total, which is indeed in O(n^2).

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To prove that the running time of your algorithm is O(n^2), In the first loop

for(int i=0:i<n;i++)


i goes from 0 to n and the second loop :

for(int j = n-1;j>i;j--)


j goes from n-1 downto i

The comparisons on data[i], data[j] and lessThanCounter++ are all executed in constant time O(1)

Therefore you have this summation:

 $\sum_0^{n}(\sum_{n-1}^{i})1$.


by eliminating the internal summation you obtain : i+n+2

you now have sum(i=0 to n-1) of (n+i+2)

then sum(i=0 to n-1) of (n+2) + sum(i=0 to n-1) of i = (n+1)*(n+2) + n(n+1)/2

which is clearly O(n^2)

Hope it helps!

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@Pavel Nobody suggested that the if mattered (it would only matter if the if contained a break or a non-O(1) operation). We suggested that not every loop inside a loop leads to O(n^2) running time. –  sepp2k May 1 at 11:39