Okay, so you have this type

```
data Const a b = Const { getConst :: a }
```

Your first question was *"Where does the *`b`

come from?"

The answer is that it doesn't come from anywhere. In the same way that you can think of `Maybe b`

as a container that holds either 0 or 1 values of type `b`

, a `Const a b`

is a container that holds exactly 0 values of type `b`

(but does definitely hold a value of type `a`

).

Your second question was *"Why is it there?"*

Well, sometimes it's useful to have a functor that says it might contain values of type `b`

, but actually holds something else (e.g. think of the `Either a b`

functor -- the difference is that `Either a b`

*might* hold a value of type `b`

, whereas `Const a b`

definitely doesn't).

Then you asked about the code snippets `pure id <*> Const "hello"`

and `Const id <*> Const "hello"`

. You thought that these were the same, but they're not. The reason is that the `Applicative`

instance for `Const`

looks like

```
instance Monoid m => Applicative (Const m) where
-- pure :: a -> Const m a
pure _ = Const mempty
-- <*> :: Const m (a -> b) -> Const m a -> Const m b
Const m1 <*> Const m2 = Const (m1 <> m2)
```

Since there aren't actually any values having the type of the second parameter, we only have to deal with those having the type of the first parameter, which we know is a monoid. That's why we can make `Const`

an instance of `Applicative`

-- we need to pull a value of type `m`

from somewhere, and the `Monoid`

instance gives us a way to make one from nowhere (using `mempty`

).

So what happens in your examples? You have `pure id <*> Const "hello"`

which must have type `Const String a`

since `id :: a -> a`

. The monoid in this case is `String`

. We have `mempty = ""`

for a `String`

, and `(<>) = (++)`

. So you end up with

```
pure id <*> Const "hello" = Const "" <*> Const "hello"
= Const ("" <> "hello")
= Const ("" ++ "hello")
= Const "hello"
```

On the other hand, when you write `Const id <*> Const "hello"`

the left-hand argument has type `Const (a -> a) b`

and the right has type `Const String b`

and you see that the types don't match, which is why you get a type error.

Now, why is this ever useful? One application is in the lens library, which lets you use getters and setters (familiar from imperative programming) in a pure functional setting. A simple definition of a lens is

```
type Lens b a = forall f. Functor f => (a -> f a) -> (b -> f b)
```

i.e. if you give it a function that transforms values of type `a`

, it will give you back a function that transforms values of type `b`

. What is that useful for? Well, let's pick a random function of type `a -> f a`

for a particular functor `f`

. If we choose the `Identity`

functor, which looks like

```
data Identity a = Identity { getIdentity :: a }
```

then if `l`

is a lens, the definition

```
modify :: Lens b a -> (a -> a) -> (b -> b)
modify l f = runIdentity . l (Identity . f)
```

provides you with a way to take functions that transform `a`

s and turn them into functions that transform `b`

s.

Another function of type `a -> f a`

we could pass in is `Const :: a -> Const a a`

(notice that we've specialized so that the second type is the same as the first). Then the action of the lens `l`

is to turn it into a function of type `b -> Const a b`

, which tells us that it might contain a `b`

, but actually *sneakily* it really contains an `a`

! Once we've applied it to something of type `b`

in order to get a `Const a b`

, we can hit it with `getConst :: Const a b -> a`

to pull a value of type `a`

out of the hat. So this gives us a way to extract values of type `a`

from a `b`

-- i.e it's a getter. The definition looks like

```
get :: Lens b a -> b -> a
get l = getConst . l Const
```

As an example of a lens, you could define

```
first :: Lens (a,b) a
first f (a,b) = fmap (\x -> (x,b)) (f a)
```

so that you could open up a GHCI session and write

```
>> get first (1,2)
1
>> modify first (*2) (3,4)
(6,4)
```

which, as you might imagine, is useful in all kinds of situations.