In general, there are a number of variations in how hash tables handle overflow.

Many (including Java's, if memory serves) resize when the load factor (percentage of bins in use) exceeds some particular percentage. The downside of this is that the speed is undependable -- most insertions will be O(1), but a few will be O(N).

To ameliorate that problem, some resize gradually instead: when the load factor exceeds the magic number, they:

- Create a second (larger) hash table.
- Insert the new item into the new hash table.
- Move some items from the existing hash table to the new one.

Then, each subsequent insertion moves another chunk from the old hash table to the new one. This retains the O(1) average complexity, and can be written so the complexity for every insertion is essentially constant: when the hash table gets "full" (i.e., load factor exceeds your trigger point) you double the size of the table. Then, each insertion you insert the new item and move one item from the old table to the new one. The old table will empty exactly as the new one fills up, so *every* insertion will involve exactly two operations: inserting one new item and moving one old one, so insertion speed remains essentially constant.

There are also other strategies. One I particularly like is to make the hash table a table of balanced trees. With this, you usually ignore overflow entirely. As the hash table fills up, you just end up with more items in each tree. In theory, this means the complexity is O(log N), but for any practical size it's proportional to `log N/M`

, where M=number of buckets. For practical size ranges (e.g., up to several billion items) that's essentially constant (`log N`

grows *very* slowly) and and it's often a little faster for the largest table you can fit in memory, and a lost faster for smaller sizes. The shortcoming is that it's only really practical when the objects you're storing are fairly large -- if you stored (for example) one character per node, the overhead from two pointers (plus, usually, balance information) per node would be extremely high.