GADTs allow you to have your types to contain more information about the values they represent. They do this by stretching Haskell `data`

declarations a little bit of the way to the inductive type families in a dependently typed language.

The quintessential example is typed Higher Order Abstract Syntax represented as a GADT.

```
{-# LANGUAGE GADTs #-}
{-# LANGUAGE TypeOperators #-} -- Not needed, just for convenience of (:@) below
module HOAS where
data Exp a where
Lam :: (Exp s -> Exp t) -> Exp (s -> t)
(:@) :: Exp (s -> t) -> Exp s -> Exp t
Con :: a -> Exp a
intp :: Exp a -> a
intp (Con a) = a
intp (Lam f) = intp . f . Con
intp (fun :@ arg) = intp fun (intp arg)
```

In this example, `Exp`

is a GADT. Note that the `Con`

constructor is very normal, but the `App`

and `Lam`

constructors introduce new type variables quite freely. These are existentially quantified type variables and they represent rather complex relationships between the different arguments to `Lam`

and `App`

.

In particular, they ensure that any `Exp`

can be interpreted as a well-typed Haskell expression. Without using GADTs we'd need to use sum types to represent the values in our terms and handle type errors.

```
>>> intp $ Con (+1) :@ Con 1
2
>>> Con (+1) :@ Con 'a'
<interactive>:1:11: Warning:
No instance for (Num Char) arising from a use of `+'
Possible fix: add an instance declaration for (Num Char)
In the first argument of `Con', namely `(+ 1)'
In the first argument of `App', namely `(Con (+ 1))'
In the expression: App (Con (+ 1)) (Con 'a')
>>> let konst = Lam $ \x -> Lam $ \y -> x
>>> :t konst
konst :: Exp (t -> s -> t)
>>> :t intp $ konst :@ Con "first"
intp $ konst :@ Con "first" :: s -> [Char]
>>> intp $ konst :@ Con "first" :@ Con "second"
"first"
```