First of all, `(n-1)!`

means `(n-1)(n-2)...(2)(1)`

. This is clearly not what you want here.

If you count the actual number of iterations it's `0 + 1 + 2 + ... + (n-2) + (n-1)`

. Note that there are `n`

terms in the sum, and that we can pair them off in a way such that the average value of each pair is `(n-1)/2`

. (Pair the highest and lowest, the second highest and second lowest, etc.) If `n`

is odd, you'll have one left over that can't be paired, but conveniently its value is also `(n-1)/2`

. Thus you have `n`

terms and the average of all terms is `(n-1)/2`

, so the total sum is `n(n-1)/2`

.

Now, for big O notation it doesn't matter exactly how many iterations we have -- we just want to know the limit when `n`

is very large. Note that our number of iterations can be written as `(1/2)n^2 - (1/2)n`

. For very large `n`

, the `n^2`

term is way, way bigger than the `n`

term, so we drop the `n`

term. That just leaves us with `(1/2)n^2`

, but another rule of big O notation is we don't care about the constant factor, so we just write that it's O(n^2).