The Haskell `Category`

class offers methods to work with categories whose objects are precisely the Haskell types of some kind. Specifically,

```
class Category c where
id :: c x x
(.) :: c y z -> c x y -> c x z
```

The names of the methods should look very familiar. Notably,

```
instance Category (->) where
id x = x
f . g = \x -> f (g x)
```

You probably know that monoids are semigroups with identities, expressed in Haskell using

```
class Monoid a where
mappend :: a -> a -> a
mempty :: a
```

But another mathematical perspective is that they're categories with exactly one object. If we have a monoid, we can easily turn it into a category:

```
-- We don't really need this extension, but
-- invoking it will make the code below more useful.
{-# LANGUAGE PolyKinds #-}
import Control.Category
import Data.Monoid
import Prelude hiding ((.), id)
newtype Mon m a b = Mon m
instance Monoid m => Category (Mon m) where
id = Mon mempty
Mon x . Mon y = Mon (x `mappend` y)
```

Going the other way is a little bit trickier. One way to do it is to choose a kind with exactly one type, and look at categories whose sole object is that type (prepare for yucky code, which you can skip if you like; the bit below is less scary). This shows that we can freely convert between a `Category`

whose object is the type `'()`

in the `()`

kind and a `Monoid`

. The arrows of the category become the elements of the monoid.

```
{-# LANGUAGE DataKinds, GADTs, PolyKinds #-}
data Cat (c :: () -> () -> *) where
Cat :: c '() '() -> Cat c
instance Category c => Monoid (Cat c) where
mempty = Cat id
Cat f `mappend` Cat g = Cat (f . g)
```

But this is yucky! Ew! And pinning things down so tightly doesn't usually accomplish anything from a *practical* perspective. But we can get the *functionality* without so much mess, by playing a little trick!

```
{-# LANGUAGE GADTs, PolyKinds #-}
import Control.Category
import Data.Monoid
import Prelude hiding ((.), id)
newtype Cat' (c :: k -> k -> *) (a :: k) (b :: k) = Cat' (c a b)
instance (a ~ b, Category c) => Monoid (Cat' c a b) where
mempty = Cat' id
Cat' f `mappend` Cat' g = Cat' (f . g)
```

Instead of confining ourselves to a `Category`

that really only has one object, we simply confine ourselves to looking at *one object at a time*.

The existing `Monoid`

instance for functions makes me sad. I think it would be much more *natural* to use a `Monoid`

instance for functions based on their `Category`

instance, using the `Cat'`

approach:

```
instance a ~ b => Monoid (a -> b) where
mempty = id
mappend = (.)
```

Since there's already a `Monoid`

instance, and overlapping instances are evil, we have to make do with a `newtype`

. We could just use

```
newtype Morph a b = Morph {appMorph :: a -> b}
```

and then write

```
instance a ~ b => Monoid (Morph a b) where
mempty = Morph id
Morph f `mappend` Morph g = Morph (f . g)
```

and for some purposes maybe this is the way to go, but since we're using a `newtype`

already we usually might as well drop the non-standard equality context and use `Data.Monoid.Endo`

, which builds that equality into the type:

```
newtype Endo a = Endo {appEndo :: a -> a}
instance Monoid (Endo a) where
mempty = Endo id
Endo f `mappend` Endo g = Endo (f . g)
```

`Monoid b => Monoid (a->b)`

instance, which conflicts with yours. Please try it with a`newtype`

wrapper, so you have a “clean slate”. (`newtype Fun a b = Fun (a->b)`

, that would be.)`newtype Endo a = Endo (a -> a)`

, like in Data.Monoid.