Backstory (skip to second-to-last paragraph for data structure part): I'm working on a compression algorithm (of the LZ77 variety). The algorithm boils down to finding the longest match between a given string and all strings that have already been seen.

To do this quickly, I've used a hash table (with separate chaining) as recommended in the DEFLATE spec: I insert every string seen so far one at a time (one per input byte) with *m* slots in the chain for each hash code. Insertions are fast (constant-time with no conditional logic), but searches are slow because I have to look at O(*m*) strings to find the longest match. Because I do hundreds of thousands of insertions and tens of thousands of lookups in a typical example, I need a highly efficient data structure if I want my algorithm to run quickly (currently it's too slow for *m* > 4; I'd like an *m* closer to 128).

I've implemented a special case where *m* is 1, which runs *very* fast buts offers only so-so compression. Now I'm working on an algorithm for those who'd prefer improved compression ratio over speed, where the larger *m* is, the better the compression gets (to a point, obviously). Unfortunately, my attempts so far are too slow for the modest gains in compression ratio as *m* increases.

So, I'm looking for a data structure that allows very fast insertion (since I do more insertions than searches), but still fairly fast searches (better than O(*m*)). Does an O(1) insertion and O(log *m*) search data structure exist? Failing that, what would be the best data structure to use? I'm willing to sacrifice memory for speed. I should add that on my target platform, jumps (ifs, loops, and function calls) are very slow, as are heap allocations (I have to implement everything myself using a raw byte array in order to get acceptable performance).

So far, I've thought of storing the *m* strings in sorted order, which would allow O(log *m*) searches using a binary search, but then the insertions also become O(log *m*).

Thanks!