When analyzing the time complexity of an algorithm, I actually find it helpful to *not* look at the code and to instead think about the core idea driving the algorithm. If you know conceptually what the algorithm is doing, it's often easier to figure out the time complexity by just thinking through what the algorithm is going to do and then deriving the time complexity from there.

Let's apply that approach here. So how exactly does selection sort work? Well, it starts off by finding the minimum value in the last n elements and swapping it to position 0, then finding the minimum value in the last n - 1 elements and swapping it to position 1, then finding the minimum value in the last n - 2 elements and swapping it to position 2, etc.

The "hard part" of the algorithm is figuring out which of the last n - k elements is the smallest. Selection sort does this by iterating over those elements and comparing each against the element that currently is known to be the smallest. That requires n - k - 1 comparisons.

Let's see how many comparisons that is. On the first iteration, we need to make n - 1 comparisons. On the second iteration, we make n - 2 comparisons. On the third, we make n - 3 comparisons. Summing up the number of comparisons gives us a good way of measuring the total work:

(n - 1) + (n - 2) + (n - 3) + ... + 3 + 2 + 1 = n(n - 1) / 2

This is a famous summation - it's worth committing it to memory - and tells us how many comparisons are required. The number of comparisons made is a great proxy for the total amount of work done. Since there are n(n - 1) / 2 = n^{2} / 2 - n / 2 = Θ(n^{2}) comparisons made, the time complexity of selection sort is Θ(n^{2}).

`N-1, N-2, N-3...1`

. Now add them up, then look at this proof. The result is`N(N+1)/2 - N`

, which is`O(N^2)`

complexity. Also worth reading the algorithm description.