From the question "Is partitioning easier than sorting?":

Suppose I have a list of items and an equivalence relation on them, and comparing two items takes constant time. I want to return a partition of the items, e.g. a list of linked lists, each containing all equivalent items.

One way of doing this is to extend the equivalence to an ordering on the items and order them (with a sorting algorithm); then all equivalent items will be adjacent.

(Keep in mind the distinction between equality and equivalence.)

Clearly the equivalence relation must be considered when designing the ordering algorithm. For example, if the equivalence relation is "people born in the same year are equivalent", then sorting based on the person's name is not appropriate.

Can you suggest a datatype and equivalence relation such that it is not possible to create an ordering?

How about a datatype and equivalence relation where it

*is*possible to create such an ordering, but it is*not*possible to define a hash function on the datatype that will map equivalent items to the same hash value.

(Note: it is OK if nonequivalent items map to the same hash value (collide) -- I'm not asking to solve the collision problem -- but on the other hand, `hashFunc(item) { return 1; }`

is cheating.)

My suspicion is that for any datatype/equivalence pair where it is possible to define an ordering, it will also be possible to define a suitable hash function, and they will have similar algorithmic complexity. A counterexample to that conjecture would be enlightening!

smallequivalence relation (either through hashing or through sorting) that is also a superset of the isomorphism equivalence relation, you would immediately have a good step for a graph isomorphism algorithm. All graph isomorphism algorithms I've seen remotely resemble hashing graphs, again and again (trimming more and more the tentative equivalence relation, till whatever remains is handled by brute force). – Dimitris Andreou Jul 16 '10 at 18:43