The essential factor for me is the answer to the following question:
Is the structure of my datatype relevant to the outside world?
For example, the internal structure of the list datatype is very much relevant to the outside world - it has an inductive structure that is certainly very useful to expose to consumers, because they construct functions that proceed by induction on the structure of the list. If the list is finite, then these functions are guaranteed to terminate. Also, defining functions in this way makes it easy to provide properties about them, again by induction.
By contrast, it is best for the
Set datatype to be kept abstract. Internally, it is implemented as a tree in the
containers package. However, it might as well have been implemented using arrays, or (more usefully in a functional setting) with a tree with a slightly different structure and respecting different invariants (balanced or unbalanced, branching factor, etc). The need to enforce any invariants above and over those that the constructors already enforce through their types, by the way, precludes letting the datatype be concrete.
The essential difference between the list example and the set example is that the
Set datatype is only relevant for the operations that are possible on
Set's. Whereas lists are relevant because the standard library already provides many functions to act on them, but in addition their structure is relevant.
As a sidenote, one might object that actually the inductive structure of lists, which is so fundamental to write functions whose termination and behaviour is easy to reason about, is captured abstractly by two functions that consume lists:
foldl. Given these two basic list operators, most functions do not need to inspect the structure of a list at all, and so it could be argued that lists too coud be kept abstract. This argument generalizes to many other similar structures, such as all
Traversable structures, all
Foldable structures, etc. However, it is nigh impossible to capture all possible recursion patterns on lists, and in fact many functions aren't recursive at all. Given only
foldl, one would, writing
head for example would still be possible, though quite tedious:
head xs = fromJust $ foldl (\b x -> maybe (Just x) Just b) Nothing xs
We're much better off just giving away the internal structure of the list.
One final point is that sometimes the actual representation of a datatype isn't relevant to the outside world, because say it is some kind of optimised and might not be the canonical representation, or there isn't a single "canonical" representation. In these cases, you'll want to keep your datatype abstract, but offer "views" of your datatype, which do provide concrete representations that can be pattern matched on.
One example would be if wanted to define a
Complex datatype of complex numbers, where both cartesian forms and polar forms can be considered canonical. In this case, you would keep
Complex abstract, but export two views, ie functions
cartesian that return a pair of a length and an angle or a coordinate in the cartesian plane, respectively.