Sometimes, something that is true about how a program behaves is not provable within its source language. Other times, it may be provable, but not efficiently so. Still other times, it may be provable, but proving it would require a tremendous amount of time and effort on the part of the programmer.
Data.Sequence represents sequences as size-annotated finger trees. It maintains the invariant that the number of elements in any subtree equals the annotation stored in its root. The implementation of
zipWith for sequences splits the longer sequence to match the length of the shorter one, then uses an efficient, operationally lazy technique to zip them together.
This technique involves splitting the second sequence multiple times along the natural structure of the first sequence. When it reaches a leaf of the first sequence, it relies on the associated fragment of the second sequence having exactly one element. This is guaranteed to happen as long as the annotation invariant is maintained. If this invariant fails,
zipWith has no option but to throw an error.
To encode the annotation invariant in Haskell, you'd need to index the underlying pieces of finger tree with their lengths. You'd then need each operation to prove that it maintains the invariant. This sort of thing is possible, and languages like Coq, Agda, and Idris try to reduce the pain and inefficiency. But they still have pain, and sometimes massive inefficiency. Haskell isn't really properly set up for such work as yet, and may never be great for it (that's just not its main goal as a language). It would be extremely painful, and also extremely inefficient. Since efficiency was the reason for choosing this implementation in the first place, that's just not an option.