Yes, the quantifier is meaningful and is required for the types to make sense.
First note that there's really no such thing as an "unquantified" type signature in Haskell. Signatures without a
forall are really implicitly quantified. This code ...
f :: [a] -> [a] -- No `forall` here ...
f (x:xs) = xs ++ [x :: a] -- ... or here.
... really means this:
f :: forall a . [a] -> [a] -- With a `forall` here ...
f (x:xs) = xs ++ [x :: forall a . a] -- ... and another one here.
So let's figure out what this says. The important thing is to notice that the type variables named
a in the signatures for
f and for
x are bound by separate quantifiers. This means that they are different variables, despite sharing a name. So the above code is equivalent to this:
f :: forall a . [a] -> [a]
f (x:xs) = xs ++ [x :: forall b . b] -- I've changed `a` to `b`
With the names differentiated, it's now clear not only that the type variables in the signatures for
x are unrelated, but that the signature for
x claims that
x can have any type. But this is impossible, since
x must have the particular type bound to
f is applied to an argument. And indeed the type-checker rejects this code.
On the other hand, with a single
forall in the signature for
f :: forall a . [a] -> [a] -- A `forall` here ...
f (x:xs) = xs ++ [x :: a] -- ... but not here.
a in the signature on
x is bound by the quantifier at the beginning of
f's type signature, so this
a represents the same type as the type represented by the variables called