It sounds like the following may all be true:

- Your keys are strings.
- Inserts are done once.
- Lookups are done frequently.
- The number of key-value pairs is relatively small (say, fewer than a K or so).

If so, you might consider a sorted list over any of these other structures. This would perform worse than the others during inserts, as a sorted list is O(N) on insert, versus O(1) for a linked list or hash table, and O(log_{2}N) for a balanced binary tree. But lookups in a sorted list may be faster than any of these others structures (I'll explain this shortly), so you may come out on top. Also, if you perform all your inserts at once (or otherwise don't require lookups until all insertions are complete), then you can simplify insertions to O(1) and do one much quicker sort at the end. What's more, a sorted list uses less memory than any of these other structures, but the only way this is likely to matter is if you have many small lists. If you have one or a few large lists, then a hash table is likely to out-perform a sorted list.

Why might lookups be faster with a sorted list? Well, it's clear that it's faster than a linked list, with the latter's O(N) lookup time. With a binary tree, lookups only remain O(log_{2} N) if the tree remains perfectly balanced. Keeping the tree balanced (red-black, for instance) adds to the complexity and insertion time. Additionally, with both linked lists and binary trees, each element is a separately-allocated^{1} *node*, which means you'll have to dereference pointers and likely jump to potentially widely varying memory addresses, increasing the chances of a cache miss.

As for hash tables, you should probably read a couple of other questions here on StackOverflow, but the main points of interest here are:

- A hash table can degenerate to O(N) in the worst case.
- The cost of hashing is non-zero, and in some implementations it can be significant, particularly in the case of strings.
- As in linked lists and binary trees, each entry is a
*node* storing more than just key and value, also separately-allocated in some implementations, so you use more memory and increase chances of a cache miss.

Of course, if you really care about how any of these data structures will perform, you should test them. You should have little problem finding good implementations of any of these for most common languages. It shouldn't be too difficult to throw some of your real data at each of these data structures and see which performs best.

_{It's possible for an implementation to pre-allocate an array of nodes, which would help with the cache-miss problem. I've not seen this in any real implementation of linked lists or binary trees (not that I've seen every one, of course), although you could certainly roll your own. You'd still have a slightly higher possibility of a cache miss, though, since the node objects would be necessarily larger than the key/value pairs.}