Short version: Hashtables can't work with only the hash codes of their data; they must contain actual data. If all you provide to the hash table is a hash, then it's the data. A hashtable of hashes, which is what you seem to be trying to create, would not have problems with resizing. As far as the hashtable is concerned, the hash you inserted is the data, and whatever was hashed to produce the data is irrelevant.
A hashtable and a table of hashes are two orthogonal ideas. It sounds like you're conflating the two in a way that doesn't make much sense in either context.
For a hashtable, the entire point is to map keys unambiguously to values. Without both, the table is useless. The hash code that a hashtable uses is not, and can not be, logically separated from the data -- it comes from the data, and is often calculated on the fly. The sole purpose of the hash code is to quickly locate (or store) the actual key->value mapping; you still need an actual key and an actual value to map.
The big reason for needing the actual key is, the hash code only goes so far. To some degree, every useful hashtable and every hash function is inherently bound by the pigeonhole principle. This means
- Every hash function by definition can return equal hash codes for two different values; and
- Every useful hashtable has to resolve collisions somehow (between equal hash codes and/or between different hash codes that point at the same bucket).
Hashtables are actually doubly affected by the pigeonhole principle; they not only have to reduce the data to a (typically int-sized) hash code, but since most hash tables can't reasonably have 4 billion buckets, the code then has to do some further reduction with that hash code to turn it into a bucket number. (A common example is taking the hash code times some prime number, mod the number of buckets.)
Even read-only hashtables typically have to resolve collisions. Imagine a read-only hash table that uses a hash function so perfect that every value in the table ends up in its own bucket. Even in this case, what happens when you try to find a key that's not in the table, but produces a hash code that resolves to a bucket containing a key that is in the table? Either you need the value itself to double-check against, or the table lies and says the key exists, even if the hash code is not actually equal!
Basically the table uses the hash code of the lookup key (or, more typically, the return value from some function on that hash code) to figure out what bucket to look in, and then compares each actual key in that bucket with the actual lookup key in order to disambiguate. This wouldn't work without an actual key of some sort, unless:
- your hash function was guaranteed to produce a unique value for every input (making it no longer a hash function, but an encoding or encryption function), and
- you had an infinite number of buckets.
The only way you could have hashes in a hash table without the original data, is if the hashes are the data. In that case you have a hashtable of hashes. In the case you're mentioning, you might use a hash of the username as a key, mapping to a SHA /mcrypt/bcrypt/whatever hash of the password. In that case, the hash is the key, and no one cares about the username anymore. This would not cause problems with resizing or whatever, as the hash function the hashtable uses has very little to do with the hash function you used; as far as the hashtable cares, the hash you gave it is just another value, and has its own hash code, and that hash code is what the hashtable uses internally to find stuff.
I might warn you against using hashes for usernames, though. I'd suggest that at least one piece of the auth data be collision-proof, and hashes are by their very nature not collision-proof. And i'll personally tear up your programming license if i catch you running around storing unhashed passwords in a potentially user-visible location. :) Perhaps if you encrypted the username instead of hashing it? That'd effectively guarantee its uniqueness, and if you use public-key encryption and "forget" the private key, it's effectively as irreversible as hashing. Nifty side effect is, public-key encryption is generally kinda slow due to how it works. You're basically taking a 1024-bit or larger number and multiplying it by itself thousands of times. So you have some built-in protection against brute force.