# Big-Oh analysis of the running time?

For each of the following program fragments, give a Big-Oh analysis of the running time. I have two problems that I am not 100% sure if there right, can somebody help me

``````// Fragment 1
for( int  i  =  0;  i  <  n;  i++ )
for(  int  j  =  0;  j  <  n  *  n;  j++ )
for(  int  k  =  0;  k  <  j;  k++ )
sum++;
Answer: O(n^5) not really sure n*n??

// Fragment 2
for(  int  i  =  1;  i  <=  n;  i++ )
for(  int  j  =  1;  j  <=  i  *  i;  j++ )
if (j % i == 0)
for(  int k  =  0;  k  <  j;  k++)
sum++;
``````
-
For the first one, you loop `(n) * (n * n) * (1 + 2 + ... + n * n) = n^3 * n(n+1)/2 = n^3 * (n^2 + n + 1) / 2 = n^5 + ... => O(n^5)`. What is your question about the second one? –  Blender Sep 29 '12 at 4:05
I just like to know if that is the right answer?? –  mario Sep 29 '12 at 4:07

Decompose the problem space per loop. Start from the outermost loop. What are the loops really going up to?

For the first problem, we have the following pattern.

• The outer loop will run n times.
• The outer inner loop will run n2 times, and is not bound by the current value of the inner loop.
• The innermost loop will run up to j times, which causes it to be bound by the current value of the outer inner loop.
• All of your steps are in linear chunks, meaning you will go from 0 to your ending condition in a linear fashion.

Here's what the summation actually looks like.

So, what would that translate into? You have to unroll the sums. It's not going to be O(n5), though.

For the second problem, we have the following pattern.

• The outer loop runs up to and including n times.
• The outer inner loop runs up to and including i2 times.
• The innermost loop runs up to j times, on the condition that `j % i == 0`. That means that the innermost loop isn't executed every time.

I'll leave this problem for you to solve out. You do have to take the approach of unrolling the sums and reducing them to their algebraic counterparts.

-

for Fragment 1:

`````` lets say m = n^2
Sigma(i=0...n)  m Sigma(j=0.....m) j
=> n * (m(m+1)/2)
=> n ^ 5
``````

for Fragment 2:

``````last loop runs for i-1 times ...
Sigma(i=0...n)  Sigma(j=0.....i-1) Sigma(k=0.....j) k
approximately its Sigma(i=0...n) i^2
~=> n^3
``````