The key insight here is that f1 always returns one, given anything, and f1(1) is evaluated in constant time.

Each of these functions will result in two recursive calls -- an inner recursive call first then an outer recursive call -- except in the case in which n is one. In that case the function will evaluate zero recursive calls.

However, since function f1 always returns 1 regardless of its input, one of the recursive calls it makes, the outer recursive call, will always be called on n of 1. Thus the time complexity of f1 reduces to the time complexity of f(n) = f(n-1) which is O(n) -- because the only other call it will make takes O(1) time.

When evaluating f2 on the other hand, the inner recursive call will be called on n-1 and the outer recursive call will be called on n-1 as well because f2(n) yields n. You can see this by induction. By definition, f2 of 1 is 1. Assume f2(n) = n. Then by definition f2(n+1) yields 1 + f2(f2(n+1-1)) which reduces to 1 + (n+1-1) or just n+1, by the induction hypothesis.

Thus each call to f2(n) results in two times however many calls f2(n-1) makes. This implies a O(2^n) time complexity.

`+1`

in the return statement of the second function is probably the answer. – Tim Biegeleisen Jul 24 '19 at 16:15