The definition "Monads are just monoids in the category of endofunctors.", which although true is a bad place to start. It's from a blog post that was largely intended to be a joke. But if you are interested in the correspondence it can be demonstrated in Haskell:

The laymen description of a category is an abstract collection of objects and morphisms between objects. Mappings between categories are called *functors* and map objects to objects and morphisms to morphisms associatively and preserves identities. An *endofunctor* is a functor from a category to itself.

```
{-# LANGUAGE MultiParamTypeClasses,
ConstraintKinds,
FlexibleInstances,
FlexibleContexts #-}
class Category c where
id :: c x x
(.) :: c y z -> c x y -> c x z
class (Category c, Category d) => Functor c d t where
fmap :: c a b -> d (t a) (t b)
type Endofunctor c f = Functor c c f
```

Mappings between functors which satisfy the so called naturality conditions are called *natural transformations*. In Haskell these are polymorphic functions of type: `(Functor f, Functor g) => forall a. f a -> g a`

.

A *monad* on a category `C`

is three things `(T,η,μ)`

, `T`

is endofunctor and `1`

is the identity functor on `C`

. Mu and eta are two natural transformations that satisfy a triangle identity and an associativity identity, and are defined as:

In Haskell `μ`

is `join`

and `η`

is `return`

`return :: Monad m => a -> m a`

`join :: Monad m => m (m a) -> m a`

A categorical definition of Monad in Haskell could be written:

```
class (Endofunctor c t) => Monad c t where
eta :: c a (t a)
mu :: c (t (t a)) (t a)
```

The bind operator can be derived from these.

```
(>>=) :: (Monad c t) => c a (t b) -> c (t a) (t b)
(>>=) f = mu . fmap f
```

This is a complete definition, but equivalently you can also show that the Monad laws can be expressed as Monoid laws with a *functor category*. We can construct this functor category which is a category with objects as functors ( i.e. mappings between categories) and natural transformations (i.e. mappings between functors) as morphisms. In a category of endofunctors all functors are functors between the same category.

```
newtype CatFunctor c t a b = CatFunctor (c (t a) (t b))
```

We can show this gives rise to a category with functor composition as morphism composition:

```
-- Note needs UndecidableInstances to typecheck
instance (Endofunctor c t) => Category (CatFunctor c t) where
id = CatFunctor id
(CatFunctor g) . (CatFunctor f) = CatFunctor (g . f)
```

The monoid has the usual definition:

```
class Monoid m where
unit :: m
mult :: m -> m -> m
```

A monoid over a category of functors has a natural transformations as identity a and a multiplication operation which combines natural transformations. Kleisli composition can be defined to satisfy the multiplication law.

```
(<=<) :: (Monad c t) => c y (t z) -> c x (t y) -> c x (t z)
f <=< g = mu . fmap f . g
```

And so you have it "Monads are just monoids in the category of endofunctors" which is just a "pointfree" version of the normal definition of monads from endofunctors and (mu, eta).

```
instance (Monad c t) => Monoid (c a (t a)) where
unit = eta
mult = (<=<)
```

With a bit of substitution one can show that the monoidal properties of `(<=<)`

Are equivalent statement of the triangle and associativity diagrams for the monad's natural transformations.

```
f <=< unit == f
unit <=< f == f
f <=< (g <=< h) == (f <=< g) <=< h
```

If you're interested in diagrammatic representations I have written a bit about representing them with string diagrams.