To define a monad for `(->) r`

, we need two operations, `return`

and `(>>=)`

, subject to three laws:

```
instance Monad ((->) r) where
```

If we look at the signature of return for `(->) r`

```
return :: a -> r -> a
```

we can see its just the constant function, which ignores its second argument.

```
return a r = a
```

Or alternately,

```
return = const
```

To build `(>>=)`

, if we specialize its type signature with the monad `(->) r`

,

```
(>>=) :: (r -> a) -> (a -> r -> b) -> r -> b
```

there is really only one possible definition.

```
(>>=) x y z = y (x z) z
```

Using this monad is like passing along an extra argument `r`

to every function. You might use this for configuration, or to pass options way down deep into the bowels of your program.

We can check that it is a monad, by verifying the three monad laws:

```
1. return a >>= f = f a
return a >>= f
= (\b -> a) >>= f -- by definition of return
= (\x y z -> y (x z) z) (\b -> a) f -- by definition of (>>=)
= (\y z -> y ((\b -> a) z) z) f -- beta reduction
= (\z -> f ((\b -> a) z) z) -- beta reduction
= (\z -> f a z) -- beta reduction
= f a -- eta reduction
2. m >>= return = m
m >>= return
= (\x y z -> y (x z) z) m return -- definition of (>>=)
= (\y z -> y (m z) z) return -- beta reduction
= (\z -> return (m z) z) -- beta reduction
= (\z -> const (m z) z) -- definition of return
= (\z -> m z) -- definition of const
= m -- eta reduction
```

The final monad law:

```
3. (m >>= f) >>= g ≡ m >>= (\x -> f x >>= g)
```

follows by similar, easy equational reasoning.

We can define a number of other classes for ((->) r) as well, such as Functor,

```
instance Functor ((->) r) where
```

and if we look at the signature of

```
-- fmap :: (a -> b) -> (r -> a) -> r -> b
```

we can see that its just composition!

```
fmap = (.)
```

Similarly we can make an instance of `Applicative`

```
instance Applicative ((->) r) where
-- pure :: a -> r -> a
pure = const
-- (<*>) :: (r -> a -> b) -> (r -> a) -> r -> b
(<*>) g f r = g r (f r)
```

What is nice about having these instances is they let you employ all of the Monad and Applicative combinators when manipulating functions.

There are plenty of instances of classes involving (->), for instance, you could hand-write the instance of Monoid for (b -> a), given a Monoid on `a`

as:

```
enter code here
instance Monoid a => Monoid (b -> a) where
-- mempty :: Monoid a => b -> a
mempty _ = mempty
-- mappend :: Monoid a => (b -> a) -> (b -> a) -> b -> a
mappend f g b = f b `mappend` g b
```

but given the Monad/Applicative instance, you can also define this instance with

```
instance Monoid a => Monoid (r -> a) where
mempty = pure mempty
mappend = liftA2 mappend
```

using the Applicative instance for `(->) r`

or with

```
instance Monoid a => Monoid (r -> a) where
mempty = return mempty
mappend = liftM2 mappend
```

using the Monad instance for `(->) r`

.

Here the savings are minimal, but, for instance the @pl tool for generating point-free code, which is provided by lambdabot on the #haskell IRC channel abuses these instances quite a bit.

`type F a b = (->) a b`

and this`f :: (->) a b`

.`(->) a b`

as`a->b`

, right? So, (->) is an operator in types.`return :: a -> (a -> r)`

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