I have a basic question on the time complexity of basic operations when using hash tables as opposed to binary search trees (or balanced ones).

In basic algorithm courses, which is unfortunately the only type I have studies, I learned that ideally, the time complexity of look-up/insert using **Hashtables** is O(1). For **binary (search) trees**, it is O(log(n)) where "n" is the "number" of input objects. So far, hashtable is the winner (I guess) in terms of asymptotic access time.

Now take "**n**" as the size of the data structure array, and "**m**" as the number of distinct input objects (values) to be stored in the DS.

For me, there is an ambiguity in the time complexity of data structure operations (e.g., lookup). Is it really possible to do Hashing with a "calculation/evaluation" complexity constant time in "**n**"? Specifically, if we know we have "**m**" distinct values for the objects which are being stored, then can the hash function still run faster than "Omega (log(**m**))"?
If not, then I would claim that the complexity for nontrivial applications has to be O( log ( **n** ) ) since in practice "**n**" and "**m**" are not drastically different.

I can't see a way such function can be found. For example, take **m**= 2^O( **k**) be the total number of distinct strings of length "**k**" bytes. A hash function has to go over all "**k**" bytes and even if it takes only constant time to do the calculations for each byte, then the overall time needed to hash the input is Omega( **k** ) = Omega( log( **m**) ).

Having said that, for cases where the number of potential inputs is comparable to the size of the table, e.g., "**m**" is almost equal to "**n**", the hashing complexity does not look like constant time to me.

nandmareoften drastically different. It's not unusual to have a 64-bit key, but a hash table with 2^64 values is impossible. – svick Nov 26 '13 at 2:24