# Assymptotic time complexity of this algorithm

I would like to know the time complexity of the following algorithm. At first glance the time complexity looks to be O(n^5) and that is what is mentioned in majority of the sites i have seen on the internet. But a careful analysis seems to give a different answer, here is the code:

``````public void fun(int n)
{
int i,j,k,sum=0;
for(i=0;i<n;i++)
{
for(j=0;j<i*i;j++)
{
if(j%i==0)
{
for(k=0;k<j;k++)
sum++;
}
}
}
}
``````
-
Well, if `i < j` what's `i % j` ? –  chill Nov 26 '12 at 9:28
@chill sorry, that was a typo... its j%i –  sasidhar Nov 26 '12 at 9:32

Note that `j%i c== 0` will yield `true` `O(i)` times (for each distinct `i`) - thus the inner loop will repeat itself `O(i)` times in each "outer" iteration.

Thus the complexity is `O(n*n^2 + n*n^3) = O(n^4)`

Explanation:
`O(n*n^2)` is for the "middle loop" which repeats itself regardless of the evaluation of the if condition. It is `O(n^3)` since you get: `1 + 4 + 9 + 16 + ... + n^2` which is a sum of squares and is `O(n^3)`.
`O(n*n^3)` is a bit trickier:

For each `i`, each inner loop repeats `i` times, so for each `i` you get: `i + 2i + 3i + ... + (i-1)i` total repeats of the inner loop. It is easy to see that it is in fact `i(1 + 2 + ... + i-1)` which is `O(i^3)`.

Now, we can see that since it happens for each `i` - the total complexity will be (not being formal, just intuitive): `O(1^3) + O(2^3) + ... + O(n^3)` which is `O(n^4)` from sum of cubed series

Conclusion:
Though cold analysis might have shown `O(n^5)` - since the inner loop does not repeat itself for each iteration of the middle loop - the total complexity is `O(n^4)`

-