# What is the Big O analysis of this algorithm?

I'm working on a data structures course and I'm not sure how to proceed w/ this Big O analysis:

``````sum = 0;
for(i = 1; i < n; i++)
for(j = 1; j < i*i; j++)
if(j % i == 0)
for(k = 0; k < j; k++)
sum++;
``````

My initial idea is that this is O(n^3) after reduction, because the innermost loop will only run when `j`/`i` has no remainder and the multiplication rule is inapplicable. Is my reasoning correct here?

Let's ignore the outer loop for a second here, and let's analyze it in terms of `i`.

The mid loop runs `i^2` times, and is invoking the inner loop whenever `j%i == 0`, that means you run it on `i, 2i, 3i, ...,i^2`, and at each time you run until the relevant `j`, this means that the inner loop summation of running time is:

``````i + 2i + 3i + ... + (i-1)*i  = i(1 + 2 + ... + i-1) = i* [i*(i-1)/2]
``````

The last equality comes from sum of arithmetic progression.
The above is in `O(i^3)`.

repeat this to the outer loop which runs from `1` to `n` and you will get running time of `O(n^4)`, since you actually have:

``````C*1^3 + C*2^3 + ... + C*(n-1)^3 = C*(1^3 + 2^3 + ... + (n-1)^3) =
= C/4 * (n^4 - 2n^3 + n^2)
``````

The last equation comes from sum of cubes
And the above is in `O(n^4)`, which is your complexity.

• inner loop do not run when `j = i^2` since j-loop end after loop body for `j = i^2 - 1` – hk6279 Mar 19 '15 at 20:13
• @hk6279 Thank you. Obviously it does not influence the big O notation, but you're 100% correct. Fixed. – amit Mar 19 '15 at 20:15
• I think this answer is missing a minor detail. You also need to count the number of times `j%i == 0` is checked. It turns out of course it is checked only `O(i^2)` times compared to `O(i^3)` executions of the innermost statement, so `O(i^3)` wins out. But if it the condition were instead something like `if (j <= 10)`, your analysis would be incorrect. – 6005 Mar 19 '15 at 21:12
• @C-S I avoided it because it is pretty obvious this number is smaller (asymptotically) then `i^3`. – amit Mar 19 '15 at 21:17
• @amit OK, but if someone wrote that it was "pretty obvious" on a CS theory problem set, I would dock them points ;) – 6005 Mar 19 '15 at 21:20