What he put was not the factorial recursion, but the time complexity of it.

Assuming this is the pseudocode for such a recurrence:

```
1. func factorial(n)
2. if (n == 0)
3. return 1
4. return n * (factorial - 1)
```

- I am assuming that tail-recursion elimination is not involved.

Line 2 and 3 costs a constant time, c1 and c2.

Line 4 costs a constant time as well. However, it calls factorial(n-1) which will take some time T(n-1). Also, the time it takes to multiply factorial(n-1) by n can be ignored once T(n-1) is used.

Time for the whole function is just the sum: T(n) = c1 + c2 + T(n-1).

This, in big-o notation, is reduced to T(n) = 1 + T(n-1).

This is, as Diam has pointed out, is a flat recursion, therefore its running time should be O(n). Its space complexity will be enormous though.