# Calculating T(n) Time Complexity of an Algorithm

I am looking for some clarification in working out the time efficiency of an Algorithm, specifically T(n). The algorithm below is not as efficient as it could be, though it's a good example to learn from I believe. I would appreciate a line-by-line confirmation of the sum of operations in the code:

Pseudo-code

`````` 1.  Input: array X of size n
2.  Let A = an empty array of size n
3.  For i = 0 to n-1
4.      Let s = x[0]
5.      For j = 0 to i
6.          Let sum = sum + x[j]
7.      End For
8.      Let A[i] = sum / (i+1)
9.  End For
10. Output: Array A
``````

My attempt at calculating T(n)

`````` 1.  1
2.  n
3.  n
4.  n(2)
5.  n(n-1)
6.  n(5n)
7.  -
8.  n(6)
9.  -
10. 1

T(n) = 1 + n + n + 2n + n^2 - n + 5n^2 + 6n + 1
= 6n^2 + 9n + 2
``````

So, T(n) = 6n^2 + 9n + 2 is what I arrive at, from this I derive Big-O of O(n^2). What errors, if any have I made in my calculation...

Edit: ...in counting the primitive operations to derive T(n)?

-
It's a straight-forward double loop without conditional breaks, so it's `O(n^2)` alright... –  Kerrek SB Oct 28 '11 at 17:05
Thanks, I was in little doubt that it was not O(n^2), just a little unsure about the calucations beforehand for T(n) –  Josh Oct 28 '11 at 17:15

``````0 + 1 + 2 +  + (n-1) = (n-1)n/2 = O(n^2)