Generally speaking, what we strive for is the best we can manage to do. But depending on what we're doing, that might be O(1), O(log log N), O(log N), O(N), O(N log N), O(N^{2}), O(N^{3}), or (or certain algorithms) perhaps O(N!) or even O(2^{N}).

Just for example, when you're dealing with searching in a sorted collection, binary search borders on trivial and gives O(log N) complexity. If the distribution of items in the collection is reasonably predictable, we can typically do even better--around O(log log N). Knowing that, an algorithm that was O(N) or O(N^{2}) (for a couple of obvious examples) would probably be pretty disappointing.

On the other hand, sorting is generally quite a bit higher complexity--the "good" algorithms manage O(N log N), and the poorer ones are typically around O(N^{2}). Therefore, for sorting an O(N) algorithm is actually very good (in fact, only possible for rather constrained types of inputs), and we can pretty much count on the fact that something like O(log log N) simply isn't possible.

Going even further, we'd be happy to manage a matrix multiplication in only O(N^{2}) instead of the usual O(N^{3}). We'd be *ecstatic* to get optimum, reproducible answers to the traveling salesman problem or subset sum problem in only O(N^{3}), given that optimal solutions to these normally require O(N!).