No, this is not possible. It would be impossible to write such a function, because you can have lists whose finiteness might be unknown: consider a recursive loop generating a list of all the twin primes it can find. Or, to follow up on what Daniel Pratt mentioned in the comments, you could have a list of all the steps a universal Turing machine takes during its execution, ending the list when the machine halts. Then, you could simply check whether such a list is infinite, and solve the Halting problem!
The only question an implementation could answer is whether a list is cyclic: if one of its tail pointers points back to a previous cell of the list. However, this is implementation-specific (Haskell doesn't specify anything about how implementations must represent values), impure (different ways of writing the same list would give different answers), and even dependent on things like whether the list you pass in to such a function has been evaluated yet. Even then, it still wouldn't be able to distinguish finite lists from infinite lists in the general case!
(I mention this because, in many languages (such as members of the Lisp family), cyclic lists are the only kind of infinite lists; there's no way to express something like "a list of all integers". So, in those languages, you can check whether a list is finite or not.)