First, your example doesn't even get that far with me for the current GHC, because you need to enable
ImpredecativeTypes as well. Doing so results in a warning that ImpredicativeTypes will be simplified or removed in the next GHC. So we're not in good territory here. Nonetheless, adding the proper Num constraint (
foo :: [forall a. Num a => a]) does allow your example to compile.
Let's leave aside impredicative types and look at a simpler example:
data Foo = Foo (forall a. a)
foo = Foo 1
This also doesn't compile with the error
Could not deduce (Num a) from the context ().
Why? Well, the type promises that you're going to give the Foo constructor something with the quality that for any type
a, it produces an
a. The only thing that satisfies this is bottom. An integer literal, on the other hand, promises that for any type
a that is of class Num it produces an
a. So the types are clearly incompatible. We can however pull the forall a bit further out, to get what you probably want:
data Foo = forall a. Foo a
foo = Foo 1
So that compiles. But what can we do with it? Well, let's try to define an extractor function:
unFoo (Foo x) = x
Quantified type variable 'a' escapes. So we can define that, but we can't do much interesting with it. If we gave a class context, then we could at least use some of the class functions on it.
There is a time and place for existentials, including ones without class context, but its fairly rare, especially when you're getting started. When you do end up using them, often it will be in the context of GADTs, which are a superset of existential types, but in which the way that existentials arise feels quite natural.