I need to design an interval search algorithm that works on 64-bit keys. The match is when key k is between k1 and k2. An important requirement is that the lookup speed is better than O(log n). Researching available literature didn't turn up anything better than interval search trees. I wonder if it's feasible at all.
If your keys have distribution, closed to uniform, you can use Interpolation search, which has O(log log N) time - this is much better, than O(log n).
UPD: Just an idea: If you have enough extra memory, you can build trie-like structure. There will be O(1) search time. Idea following: For example, lets we set tree of arrays, where each array indexed by some byte of key. Arrays linked to trie. So, root element of trie - is array, where index is high byte of the key. But anyway this is not practical, because of in the bottom node, for search borders, need to perform linear search with ~64 iterations.
You can dispatch by leading bytes until the problem is small. That avoids most of the overhead of an interval tree, while maintaining the flexibility of one.
So you have a table of 256 structs that point to 256 structs on down as far as needed until you either encounter a flag saying, "no match", or you are pointed to a small interval tree for the exact matching condition. Processing the top of this tree with straightforward jumps rather than traversing multiple comparisons, possible pipeline stalls, etc, may be a significant performance improvement for you.