You might ask yourself what the type of that generalized comparison function would be. First of all we need a way to encode the component types:
data Tuple ??? = Nil | Cons a (Tuple ???)
There is really nothing valid we can replace the question marks with. The conclusion is that a regular ADT is not sufficient, so we need our first language extension, GADTs:
data Tuple :: ??? -> * where
Nil :: Tuple ???
Cons :: a -> Tuple ??? -> Tuple ???
Yet we end up with question marks. Filling in the holes requires another two extensions, DataKinds and TypeOperators:
data Tuple :: [*] -> * where
Nil :: Tuple '
Cons :: a -> Tuple as -> Tuple (a ': as)
As you see we needed three type system extensions just to encode the type. Can we compare now? Well, it's not that straightforward to answer, because it's actually far from obvious how to write a standalone comparison function. Luckily the type class mechanism allows us to take a simple recursive approach. However, this time we are not just recursing on the value level, but also on the type level. Obviously empty tuples are always equal:
instance Eq (Tuple ') where
_ == _ = True
But the compiler complains again. Why? We need another extension, FlexibleInstances, because
' is a concrete type. Now we can compare empty tuples, which isn't that compelling. What about non-empty tuples? We need to compare the heads as well as the rest of the tuple:
instance (Eq a, Eq (Tuple as)) => Eq (Tuple (a ': as)) where
Cons x xs == Cons y ys = x == y && xs == ys
Seems to make sense, but boom! We get another complaint. Now the compiler wants FlexibleContexts, because we have a not-fully-polymorphic type in the context,
That's a total of five type system extensions, three of them just to express the tuple type, and they didn't exist before GHC 7.4. The other two are needed for comparison. Of course there is a payoff. We get a very powerful tuple type, but because of all those extensions, we obviously can't put such a tuple type into the base library.