Despite the "buried zero" worst case already pointed out, I would still recommend implementing an algorithm that can often speed things up, depending on p,q. For example, suppose that you have n numbers, and each increasing and decreasing region has size at least k. Then if you check 2^m elements in your array, including the first and last element and the rest of the elements as equally spaced as possible, starting with m=2 and then iteratively increasing m by 1, eventually you will reach m when you find 3 pairs of consecutive elements (A,B),(C,D),(E,F) from left-to-right out of the 2^m elements that you have checked, which satisfy A < B, C > D, E < F (some pairs may share elements). If my back-of-the-envelope calculation is correct, then the worst-case m you will need to achieve this will have you checking no more than 4n/k elements, so e.g. if k=100 you are much faster than checking all n elements. Then you know everything before A and everything after F are increasing sequences, and you can binary search through them. Now, if m got big enough that you checked at least sqrt(n) elements, then you can finish up by doing a brute-force search between A and F and the overall running time will be O(n/k + sqrt(n)). On the other hand, if the final m had you check fewer than sqrt(n) elements, then you can further increase m until you have checked sqrt(n) elements. Then there will be 2 pairs of consecutive checked elements (A,B),(C,D) that satisfy A < B, C > D, and there will also be 2 pairs of consecutive checked elements (W,X),(Y,Z) later in the array that satisfy W > X, Y < Z. Then everything before A is increasing, everything between D and W is decreasing, and everything after Z is increasing. So you can binary search these 3 regions in the array. The remaining part of the array that you haven't entirely searched through has size O(sqrt(n)), so you can use brute-force search the unchecked regions and the overall running time is O(sqrt(n)). Thus the bound O(n/k + sqrt(n)) holds in general. I have a feeling this is worst-case optimal, but I don't have a proof.