If you omit the
Compare completely, it will get the default value, which is
less (which gives the result of the
< operator applied to your key) - which may or may not even compile for your key.
The reason for having an ordering is that it allows the implementation to look up elements more quickly by their key (when inserting, deleting etc), To understand why, imagine looking words up in a dictionary. Traditional dictionaries use alphabetical order, which makes words easy to look up. If you were preparing a dictionary for a language that isn't easily ordered - say a pictographic language - then either it would be very hard to find words in it at all (you'd have to search the whole dictionary), or you'd try to find a logical way to order them (e.g. by putting all the pictures that can be drawn with one pen stroke first, then two lines, etc...) - because even if this order was completely arbitrary, it would make finding entries in the dictionary far more efficient.
Similarly, even if your keys don't need to be ordered for your own purposes, and don't have any natural order, you can usually define an ordering that is good enough to address these concerns. The ordering must be transitive (if
a<c), and strict (never return true for
a<a), asymmetric (
b>a never both true). Ideally it should order all elements (if
b are different then either
b<a), though you can get away with that not being true (ie a strict weak ordering) - though that's rather technical.
Indeed, perhaps the most obvious use for it is the rare case where it is completely impossible to order the items - in which case you can supply a comparison operator which always returns false. This will very likely result in poor performance, but will at least function correctly.