Think of `forall`

as an anonymous type function. All data types in Haskell which have type variables in their type signature implicitly have a `forall`

. For example consider:

```
f :: a -> Int
f _ = 1
```

The above function `f`

takes an argument of any type and returns an `Int`

. Where does the `a`

come from? It comes from the `forall`

quantifier. Hence it's equivalent to:

```
f :: (forall a . a -> Int)
f _ = 1
```

The `forall`

quatifier can be used for any data type, not just functions. For example consider the types of the following values:

```
() :: ()
10 :: Int
pi :: Floating a => a
```

Here `()`

and `10`

are monomorphic (i.e. they can only be of one concrete type). On the other hand `pi`

is polymorphic with a typeclass constraint (i.e. it can be of any type as long as that type is a instance of `Floating`

). The type of `pi`

written out explicitly is:

```
pi :: (forall a . Floating a => a)
```

Again the `forall`

quantifier acts like a type function. It provides you the type variable `a`

. Now consider the type of function `g`

:

```
g :: (forall a . a) -> Int
g _ = 1
```

Here `g`

expects an argument of type `forall a . a`

and returns an `Int`

. This is the reason `g ()`

doesn't work: `()`

is of type `()`

, not of type `forall a . a`

. In fact the only value of type `forall a . a`

is `undefined`

:

```
undefined :: a
```

Written out explicitly with `forall`

:

```
undefined :: (forall a . a)
```

If you noticed I've always put parentheses around the `forall`

quantifications. The reason I did this is to show you that when you use a `forall`

quantification on a function the quantification extends all the way to the right. This is just like a lambda: if you don't put parentheses around the lambda Haskell will extend the lambda function all the way to the right. Hence the type of `f`

is `(forall a . a -> Int)`

and not `(forall a . a) -> Int`

.

Remember in the first case Haskell expects the type of the argument to be `a`

(i.e. anything). However in the second case Haskell expects the type of the argument to be `(forall a . a)`

(i.e. `undefined`

). Of course if you try to evaluate `undefined`

then your program will immediately halt with an error. Fortunately you're not trying to evaluate it.