Title and tags should explain the question adequately.
Err, not really. You used the tag
There's already some good answers here, so I'll take a different approach and be a bit more formal. Polymorphic values are essentially functions on types, but Haskell's syntax leaves both type abstraction and type application implicit, which obscures the issue. We'll use the notation of System F, which has explicit type abstraction and type application.
For example, the familiar
So a value of polymorphic type is like a function from types to values. The caller of a polymorphic function gets to choose a type argument, and the function must comply.
How, then, would we write a term of type
Within the body marked
However, we know nothing concrete about
or an undefined value
or a list containing undefined values only
but not much else.
or as many:
But what are our choices for
Now we're well and truly stuck. We have to provide a value of type
So our options for
etc. And let's not forget
A value of universal (∀) type is a function from types to values. A value of existential (∃) type is a pair of a type and a value.
More specifically: A value of type
is a pair
where S is a type, and where
Here's an existential type signature and a few terms with that type:
In other words, we can put any value we like into
The user of a value of type
The user of a value of type
So what's a less useless existential? How about values paired with a binary operation:
We've packaged up a type and some operations on that type. The user can apply our operations but cannot inspect the concrete value — we can't pattern-match on
Using existentials for real
The direct syntax for existentials using ∃ and type-value pairs would be quite convenient. UHC partially supports this direct syntax. But GHC does not. To introduce existentials in GHC we need to define new "wrapper" types.
Translating the above example:
There's a couple differences from our theoretical treatment. Type application, type abstraction, and type pairs are again implicit. Also, the wrapper is confusingly written with
Often, we use existential quantification to "capture" a typeclass constraint. We could do something similar here:
The difference, then, is that while the first can be used as a list of any type (by definition, basically), the latter can't be used as a list of any concrete type at all, since there's no way to pin it down to any single type.
To address the tag--an existential type is one that, within some scope, will be instantiated to some unknown concrete type. It could be anything, so is represented by something like the
It may help to think of the
When used for types
After this setup lets look at our types starting with
In a similar way
To do a final check lets define:
and in ghci: