In (an idealized version of) Haskell, is there a concrete type `a`

such that we can implement `Eq a`

lawfully, but it is impossible to implement `Ord a`

? The order doesn't need to be meaningful, and any total order suffices, as long as it is implemented by a function that terminates and obeys the axioms.

This comes from the consideration that, to use certain efficient data structures such as `Data.Set`

, we must have a decidable total order. However sets can technically be implemented with `Eq`

alone, just that it becomes very inefficient. So is it possible to always implement `Ord`

? All the counterexamples I know of — `Integer -> Bool`

for example — can't implement `Eq`

either.

There is a likely candidate, though. The type `(Integer -> Bool) -> Bool`

, surprisingly, has computable `Eq`

. But to me it seems to *also* have computable `Ord`

! Since the modulus (see the link) is computable, we can first order functions by their modulus, and then compare the two functions on their 2^n different input prefixes, where n is the modulus.

I'm also interested in this question in other (non-contrived) type theories. There is indeed a type theory in which we have counterexamples: with nominal types, the atoms can be compared for equality but not order since everything is invariant under permutation of names by construction. What about MLTT? Or system F?

`Complex a`

does not have an instance. It could have one, but not one that is compatible with its`Num`

instance -- i.e. that has`a < b && c < d => a+c < b+d`

. It was decided that this law is a sort of implicit assumption of most programmers, and could be a source of bugs if the`Ord`

instance was made easily available.