time complexity of strangely nested loops

``````for(i=1;i<n*n;i++)
for(k=1,l=1;l<n;k=k+2,l=l+k)
foo;
``````

How would I estimate the time complexity of a construct like this?

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Looking at this loop by loop:

The outer loop is from 1 to n squared, therefore `O(n^2)`
The inner loop is from 1 to n but the steps are 1, 4, 9, 16... instead of 1, 2, 3, 4..., therefore `O(sqrt(n))`

Nested loops multiply the complexity, so we go for `O(sqrt(n)*n^2)` or `O(n^2.5)`

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although l isn't incrementing at a constant rate in the inner loop - I think it's more like O(sqrt(n)) for the inner one. –  Frederick Cheung Dec 30 '11 at 3:03
Fair point, editing answer now. –  ridecar2 Dec 30 '11 at 3:07

Generally ridecar2 is correct but be careful because sometimes you can get a trick question where e.g. the size of your data is n*n array, which means that iteration of that array is o(n) not o(n^2) despite the fact that it looks like:

``````for(int i=0; i<n; i++)
for(int j=0; j<n; j++)
doStuff();
``````
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I would put that whole thing as `O(n^2)`, would I be right? –  ridecar2 Dec 30 '11 at 3:12
are you referring to mine or his? My example is definitely O(n) but in his case n doesn't necessarily have to be the size of data so I would recommend caution. –  Mr1159pm Dec 30 '11 at 3:16
yours, as it's a loop that executes n times inside another loop that executes n times giving `O(n^2)` –  ridecar2 Dec 30 '11 at 3:20
That's why it is a trick question. O(something) describes efficiency in relation to data size. Let's replace array nn with array kk. which means that size of the data n=k*k. the algorithm performs O(k^2) ops k^2 is your n which means that the iteration of the array is O(n) –  Mr1159pm Dec 30 '11 at 3:26
Damn, I'd forgotten to assert that the data size was n or redefine things. Thanks for that! –  ridecar2 Dec 30 '11 at 3:28

Your algorithm can be simplified like the following:

``````for ( i = 1; i < n * n; i ++ )
for ( l = 1 ; l * l < n ; l = l ++ )
foo;
``````

Therefore, you can represent it using Sigma Notation to formally infer the exact order of growth complexity, like the following:

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