# A monad is just a monoid in the category of endofunctors, what's the problem?

Who first said the following?

A monad is just a monoid in the category of endofunctors, what's the problem?

And on a less important note, is this true and if so could you give an explanation (hopefully one that can be understood by someone who doesn't have much Haskell experience)?

• See "Categories for the Working Mathematician" – Don Stewart Oct 6 '10 at 15:27
• You don't need to understand this to use monads in Haskell. From a practical perspective they are just a clever way to pass around "state" through some underground plumbing. – starblue Oct 7 '10 at 18:00
• Actually, really understanding this quote did help me understand monads in a deeper sense, as well as monoids and functors. It only requires you to know other concepts which you should know anyway, to truly understand those concepts. And when you do, it nicely brings the concept to a single mental point. So ignore the stupid unconstructive comments above. All one needs, is a proper explanation of those concepts, before reading that quote. Then it’t exactly the right thing to say. Which is the whole joke behind it. (That people don’t know those concepts.) – Evi1M4chine Mar 3 '13 at 16:29
• I'd like to add this excellent blog post here too: stephendiehl.com/posts/monads.html It doesn't directly answer the question, but in my opinion Stephen does a superb job of tying categories and monads in Haskell together. If you've read the above answers - this should help unify the two ways of looking at this. – Ben Ford Aug 1 '13 at 11:09
• More precisely "For any category C, the category [C,C] of its endofunctors has a monoidal structure induced by the composition. A monoid object in [C,C] is a monad on C." - from en.wikipedia.org/wiki/Monoid_%28category_theory%29. See en.wikipedia.org/wiki/Monad_%28category_theory%29 for definition of monad in category theory. – user4322779 Jun 23 '15 at 0:04

## 6 Answers

That particular phrasing is by James Iry, from his highly entertaining Brief, Incomplete and Mostly Wrong History of Programming Languages, in which he fictionally attributes it to Philip Wadler.

The original quote is from Saunders Mac Lane in Categories for the Working Mathematician, one of the foundational texts of Category Theory. Here it is in context, which is probably the best place to learn exactly what it means.

But, I'll take a stab. The original sentence is this:

All told, a monad in X is just a monoid in the category of endofunctors of X, with product × replaced by composition of endofunctors and unit set by the identity endofunctor.

X here is a category. Endofunctors are functors from a category to itself (which is usually all `Functor`s as far as functional programmers are concerned, since they're mostly dealing with just one category; the category of types - but I digress). But you could imagine another category which is the category of "endofunctors on X". This is a category in which the objects are endofunctors and the morphisms are natural transformations.

And of those endofunctors, some of them might be monads. Which ones are monads? Exactly the ones which are monoidal in a particular sense. Instead of spelling out the exact mapping from monads to monoids (since Mac Lane does that far better than I could hope to), I'll just put their respective definitions side by side and let you compare:

## A monoid is...

• A set, S
• An operation, • : S × S → S
• An element of S, e : 1 → S

### ...satisfying these laws:

• (a • b) • c = a • (b • c), for all a, b and c in S
• e • a = a • e = a, for all a in S

## A monad is...

• An endofunctor, T : X → X (in Haskell, a type constructor of kind `* -> *` with a `Functor` instance)
• A natural transformation, μ : T × T → T, where × means functor composition (μ is known as `join` in Haskell)
• A natural transformation, η : I → T, where I is the identity endofunctor on X (η is known as `return` in Haskell)

### ...satisfying these laws:

• μ ∘ Tμ = μ ∘ μT
• μ ∘ Tη = μ ∘ ηT = 1 (the identity natural transformation)

With a bit of squinting you might be able to see that both of these definitions are instances of the same abstract concept.

• thanks for the explanation and thanks for the Brief, Incomplete and Mostly Wrong History of Programming Languages article. I thought it might be from there. Truly one of the greatest pieces of programming humor. – Roman A. Taycher Oct 6 '10 at 13:39
• @Jonathan: In the classical formulation of a monoid, × means the cartesian product of sets. You can read more about that here: en.wikipedia.org/wiki/Cartesian_product, but the basic idea is that an element of S × T is a pair (s, t), where s ∈ S and t ∈ T. So the signature of the monoidal product • : S × S -> S in this context simply means a function that takes 2 elements of S as input and produces another element of S as an output. – Tom Crockett Oct 20 '10 at 8:19
• @TahirHassan - In the generality of category theory, we deal with opaque "objects" instead of sets, and so there is no a priori notion of "elements". But if you think about the category Set where the objects are sets and the arrows are functions, the elements of any set S are in one-to-one correspondence with the functions from any one-element set to S. That is, for any element e of S, there is exactly one function f : 1 -> S, where 1 is any one-element set... (cont'd) – Tom Crockett Nov 1 '12 at 23:22
• @TahirHassan 1-element sets are themselves specializations of the more general category-theoretic notion of "terminal objects": a terminal object is any object of a category for which there is exactly one arrow from any other object to it (you can check that this is true of 1-element sets in Set). In category theory terminal objects are simply referred to as 1; they are unique up to isomorphism so there is no point distinguishing them. So now we have a purely category-theoretical description of "elements of S" for any S: they are just the arrows from 1 to S! – Tom Crockett Nov 1 '12 at 23:26
• @TahirHassan - To put this in Haskell terms, think about the fact that if `S` is a type, all you can do when writing a function `f :: () -> S` is pick out some particular term of type `S` (an "element" of it, if you will) and return it... you've been given no real information with the argument, so there's no way to vary the behavior of the function. So `f` must be a constant function which just returns the same thing every time. `()` ("Unit") is the terminal object of the category Hask, and it's no coincidence that there is exactly 1 (non-divergent) value which inhabits it. – Tom Crockett Nov 1 '12 at 23:35

Intuitively, I think that what the fancy math vocabulary is saying is that:

# Monoid

A monoid is a set of objects, and a method of combining them. Well known monoids are:

• numbers you can add
• lists you can concatenate
• sets you can union

There are more complex examples also.

Further, every monoid has an identity, which is that "no-op" element that has no effect when you combine it with something else:

• 0 + 7 == 7 + 0 == 7
• [] ++ [1,2,3] == [1,2,3] ++ [] == [1,2,3]
• {} union {apple} == {apple} union {} == {apple}

Finally, a monoid must be associative. (you can reduce a long string of combinations anyway you want, as long as you don't change the left-to-right-order of objects) Addition is OK ((5+3)+1 == 5+(3+1)), but subtraction isn't ((5-3)-1 != 5-(3-1)).

# Monad

Now, let's consider a special kind of set and a special way of combining objects.

## Objects

Suppose your set contains objects of a special kind: functions. And these functions have an interesting signature: They don't carry numbers to numbers or strings to strings. Instead, each function carries a number to a list of numbers in a two-step process.

1. Compute 0 or more results
2. Combine those results unto a single answer somehow.

Examples:

• 1 -> [1] (just wrap the input)
• 1 -> [] (discard the input, wrap the nothingness in a list)
• 1 -> [2] (add 1 to the input, and wrap the result)
• 3 -> [4, 6] (add 1 to input, and multiply input by 2, and wrap the multiple results)

## Combining Objects

Also, our way of combining functions is special. A simple way to combine function is composition: Let's take our examples above, and compose each function with itself:

• 1 -> [1] -> [[1]] (wrap the input, twice)
• 1 -> [] -> [] (discard the input, wrap the nothingness in a list, twice)
• 1 -> [2] -> [ UH-OH! ] (we can't "add 1" to a list!")
• 3 -> [4, 6] -> [ UH-OH! ] (we can't add 1 a list!)

Without getting too much into type theory, the point is that you can combine two integers to get an integer, but you can't always compose two functions and get a function of the same type. (Functions with type a -> a will compose, but a-> [a] won't.)

So, let's define a different way of combining functions. When we combine two of these functions, we don't want to "double-wrap" the results.

Here is what we do. When we want to combine two functions F and G, we follow this process (called binding):

1. Compute the "results" from F but don't combine them.
2. Compute the results from applying G to each of F's results separately, yielding a collection of collection of results.
3. Flatten the 2-level collection and combine all the results.

Back to our examples, let's combine (bind) a function with itself using this new way of "binding" functions:

• 1 -> [1] -> [1] (wrap the input, twice)
• 1 -> [] -> [] (discard the input, wrap the nothingness in a list, twice)
• 1 -> [2] -> [3] (add 1, then add 1 again, and wrap the result.)
• 3 -> [4,6] -> [5,8,7,12] (add 1 to input, and also multiply input by 2, keeping both results, then do it all again to both results, and then wrap the final results in a list.)

This more sophisticated way of combining functions is associative (following from how function composition is associative when you aren't doing the fancy wrapping stuff).

Tying it all together,

• a monad is a structure that defines a way to combine (the results of) functions,
• analogously to how a monoid is a structure that defines a way to combine objects,
• where the method of combination is associative,
• and where there is a special 'No-op' that can be combined with any something to result in something unchanged.

# Notes

There are lots of ways to "wrap" results. You can make a list, or a set, or discard all but the first result while noting if there are no results, attach a sidecar of state, print a log message, etc, etc.

I've played a bit loose with the definitions in hopes of getting the essential idea across intuitively.

I've simplified things a bit by insisting that our monad operates on functions of type a -> [a]. In fact, monads work on functions of type a -> m b, but the generalization is kind of a technical detail that isn't the main insight.

• This is a nice explanation of how every monad constitutes a category (the Kleisli category is what you're demonstrating--there is also the Eilenberg-Moore category). But due to the fact that you can't compose any two Kleisli arrows `a -> [b]` and `c -> [d]` (you can only do this if `b` = `c`), this doesn't quite describe a monoid. It's actually the flattening operation you described, rather than function composition, which is the "monoid operator". – Tom Crockett Dec 10 '11 at 19:35
• Granted, if you limited a monad to only one type, i.e. if you only allowed Kleisli arrows of the form `a -> [a]`, this would be a monoid (because you'd be reducing the Kleisli category to a single object, and any category of only one object is by definition a monoid!), but it would not capture the full generality of the monad. – Tom Crockett Dec 10 '11 at 19:46
• On the last note, it helps to remember, that a -> [a] is just a -> [] a. ([] is just type constructor too.) And so it can not only be seen as a -> m b, but [] is indeed an instance of the Monad class. – Evi1M4chine Mar 3 '13 at 17:34
• This is the best and most grokkable explanation of monads and their mathematical background of monoids I have come across in literally weeks. This is what should be printed in every Haskell book when it comes to monads, hands down. UPVOTE! Maybe further get the piece of information, that monads are realized as parameterized typeclass instances wrapping whatever put in them in haskell, into the post. (At least that is how I understood them by now. Correct me if I am wrong. See haskell.org/haskellwiki/What_a_Monad_is_not ) – sjas Dec 2 '13 at 19:20
• This is fantastic - it's the only explanation I've understood well enough to be able to explain it to someone else... But I still don't understand why this is a valuable way to think of anything. :( – Adam Barnes Feb 4 at 0:48

First, the extensions and libraries that we're going to use:

``````{-# LANGUAGE RankNTypes, TypeOperators #-}

import Control.Monad (join)
``````

Of these, `RankNTypes` is the only one that's absolutely essential to the below. I once wrote an explanation of `RankNTypes` that some people seem to have found useful, so I'll refer to that.

Quoting Tom Crockett's excellent answer, we have:

## A monad is...

• An endofunctor, T : X -> X
• A natural transformation, μ : T × T -> T, where × means functor composition
• A natural transformation, η : I -> T, where I is the identity endofunctor on X

### ...satisfying these laws:

• μ(μ(T × T) × T)) = μ(T × μ(T × T))
• μ(η(T)) = T = μ(T(η))

How do we translate this to Haskell code? Well, let's start with the notion of a natural transformation:

``````-- | A natural transformations between two 'Functor' instances.  Law:
--
-- > fmap f . eta g == eta g . fmap f
--
-- Neat fact: the type system actually guarantees this law.
--
newtype f :-> g =
Natural { eta :: forall x. f x -> g x }
``````

A type of the form `f :-> g` is analogous to a function type, but instead of thinking of it as a function between two types (of kind `*`), think of it as a morphism between two functors (each of kind `* -> *`). Examples:

``````listToMaybe :: [] :-> Maybe
listToMaybe = Natural go
where go [] = Nothing
go (x:_) = Just x

maybeToList :: Maybe :-> []
maybeToList = Natural go
where go Nothing = []
go (Just x) = [x]

reverse' :: [] :-> []
reverse' = Natural reverse
``````

Basically, in Haskell, natural transformations are functions from some type `f x` to another type `g x` such that the `x` type variable is "inaccessible" to the caller. So for example, `sort :: Ord a => [a] -> [a]` cannot be made into a natural transformation, because it's "picky" about which types we may instantiate for `a`. One intuitive way I often use to think of this is the following:

• A functor is a way of operating on the content of something without touching the structure.
• A natural transformation is a way of operating on the structure of something without touching or looking at the content.

Now, with that out of the way, let's tackle the clauses of the definition.

The first clause is "an endofunctor, T : X -> X." Well, every `Functor` in Haskell is an endofunctor in what people call "the Hask category," whose objects are Haskell types (of kind `*`) and whose morphisms are Haskell functions. This sounds like a complicated statement, but it's actually a very trivial one. All it means is that that a `Functor f :: * -> *` gives you the means of constructing a type `f a :: *` for any `a :: *` and a function `fmap f :: f a -> f b` out of any `f :: a -> b`, and that these obey the functor laws.

Second clause: the `Identity` functor in Haskell (which comes with the Platform, so you can just import it) is defined this way:

``````newtype Identity a = Identity { runIdentity :: a }

instance Functor Identity where
fmap f (Identity a) = Identity (f a)
``````

So the natural transformation η : I -> T from Tom Crockett's definition can be written this way for any `Monad` instance `t`:

``````return' :: Monad t => Identity :-> t
return' = Natural (return . runIdentity)
``````

Third clause: The composition of two functors in Haskell can be defined this way (which also comes with the Platform):

``````newtype Compose f g a = Compose { getCompose :: f (g a) }

-- | The composition of two 'Functor's is also a 'Functor'.
instance (Functor f, Functor g) => Functor (Compose f g) where
fmap f (Compose fga) = Compose (fmap (fmap f) fga)
``````

So the natural transformation μ : T × T -> T from Tom Crockett's definition can be written like this:

``````join' :: Monad t => Compose t t :-> t
join' = Natural (join . getCompose)
``````

The statement that this is a monoid in the category of endofunctors then means that `Compose` (partially applied to just its first two parameters) is associative, and that `Identity` is its identity element. I.e., that the following isomorphisms hold:

• `Compose f (Compose g h) ~= Compose (Compose f g) h`
• `Compose f Identity ~= f`
• `Compose Identity g ~= g`

These are very easy to prove because `Compose` and `Identity` are both defined as `newtype`, and the Haskell Reports define the semantics of `newtype` as an isomorphism between the type being defined and the type of the argument to the `newtype`'s data constructor. So for example, let's prove `Compose f Identity ~= f`:

``````Compose f Identity a
~= f (Identity a)                 -- newtype Compose f g a = Compose (f (g a))
~= f a                            -- newtype Identity a = Identity a
Q.E.D.
``````
• In the `Natural` newtype, I can't figure out what the `(Functor f, Functor g)` constraint is doing. Could you explain? – dfeuer Mar 20 '15 at 15:53
• @dfeuer It's not really doing anything essential. – Luis Casillas Mar 20 '15 at 18:15
• @LuisCasillas I've removed those `Functor` constraints since they don't seem necessary. If you disagree then feel free to add them back. – Lambda Fairy Mar 21 '15 at 8:03
• Can you elaborate on what it means formally for the product of functors to be taken as composition? In particular, what are the projection morphisms for functor composition? My guess is that the product is only defined for a functor F against itself, F x F and only when `join` is defined. And that `join` is the projection morphism. But I'm not sure. – tksfz Apr 1 '15 at 21:54

Note: No, this isn't true. At some point there was a comment on this answer from Dan Piponi himself saying that the cause and effect here was exactly the opposite, that he wrote his article in response to James Iry's quip. But it seems to have been removed, perhaps by some compulsive tidier.

Below is my original answer.

It's quite possible that Iry had read From Monoids to Monads, a post in which Dan Piponi (sigfpe) derives monads from monoids in Haskell, with much discussion of category theory and explicit mention of "the category of endofunctors on Hask" . In any case, anyone who wonders what it means for a monad to be a monoid in the category of endofunctors might benefit from reading this derivation.

• "Perhaps by some compulsive tidier" - or, as we fondly refer to them on this site, a moderator `:-)`. – halfer Apr 19 '18 at 17:30

I came to this post by way of better understanding the inference of the infamous quote from Mac Lane's Category Theory For the Working Mathematician.

In describing what something is, it's often equally useful to describe what it's not.

The fact that Mac Lane uses the description to describe a Monad, one might imply that it describes something unique to monads. Bear with me. To develop a broader understanding of the statement, I believe it needs to be made clear that he is not describing something that is unique to monads; the statement equally describes Applicative and Arrows among others. For the same reason we can have two monoids on Int (Sum and Product), we can have several monoids on X in the category of endofunctors. But there is even more to the similarities.

Both Monad and Applicative meet the criteria:

• endo => any arrow, or morphism that starts and ends in the same place
• functor => any arrow, or morphism between two Categories

(e.g., in day to day `Tree a -> List b`, but in Category `Tree -> List`)

• monoid => single object; i.e., a single type, but in this context, only in regards to the external layer; so, we can't have `Tree -> List`, only `List -> List`.

The statement uses "Category of..." This defines the scope of the statement. As an example, the Functor Category describes the scope of `f * -> g *`, i.e., `Any functor -> Any functor`, e.g., `Tree * -> List *` or `Tree * -> Tree *`.

What a Categorical statement does not specify describes where anything and everything is permitted.

In this case, inside the functors, `* -> *` aka `a -> b` is not specified which means `Anything -> Anything including Anything else`. As my imagination jumps to Int -> String, it also includes `Integer -> Maybe Int`, or even `Maybe Double -> Either String Int` where `a :: Maybe Double; b :: Either String Int`.

So the statement comes together as follows:

• functor scope `:: f a -> g b` (i.e., any parameterized type to any parameterized type)
• endo + functor `:: f a -> f b` (i.e., any one parameterized type to the same parameterized type) ... said differently,
• a monoid in the category of endofunctor

So, where is the power of this construct? To appreciate the full dynamics, I needed to see that the typical drawings of a monoid (single object with what looks like an identity arrow, `:: single object -> single object`), fails to illustrate that I'm permitted to use an arrow parameterized with any number of monoid values, from the one type object permitted in Monoid. The endo, ~ identity arrow definition of equivalence ignores the functor's type value and both the type and value of the most inner, "payload" layer. Thus, equivalence returns `true` in any situation where the functorial types match (e.g., `Nothing -> Just * -> Nothing` is equivalent to `Just * -> Just * -> Just *` because they are both `Maybe -> Maybe -> Maybe`).

Sidebar: ~ outside is conceptual, but is the left most symbol in `f a`. It also describes what "Haskell" reads-in first (big picture); so Type is "outside" in relation to a Type Value. The relationship between layers (a chain of references) in programming is not easy to relate in Category. The Category of Set is used to describe Types (Int, Strings, Maybe Int etc.) which includes the Category of Functor (parameterized Types). The reference chain: Functor Type, Functor values (elements of that Functor's set, e.g., Nothing, Just), and in turn, everything else each functor value points to. In Category the relationship is described differently, e.g., `return :: a -> m a` is considered a natural transformation from one Functor to another Functor, different from anything mentioned thus far.

Back to the main thread, all in all, for any defined tensor product and a neutral value, the statement ends up describing an amazingly powerful computational construct born from its paradoxical structure:

• on the outside it appears as a single object (e.g., `:: List`); static
• but inside, permits a lot of dynamics
• any number of values of the same type (e.g., Empty | ~NonEmpty) as fodder to functions of any arity. The tensor product will reduce any number of inputs to a single value... for the external layer (~`fold` that says nothing about the payload)
• infinite range of both the type and values for the inner most layer

In Haskell, clarifying the applicability of the statement is important. The power and versatility of this construct, has absolutely nothing to do with a monad per se. In other words, the construct does not rely on what makes a monad unique.

When trying to figure out whether to build code with a shared context to support computations that depend on each other, versus computations that can be run in parallel, this infamous statement, with as much as it describes, is not a contrast between the choice of Applicative, Arrows and Monads, but rather is a description of how much they are the same. For the decision at hand, the statement is moot.

This is often misunderstood. The statement goes on to describe `join :: m (m a) -> m a` as the tensor product for the monoidal endofunctor. However, it does not articulate how, in the context of this statement, `(<*>)` could also have also been chosen. It truly is a an example of six/half dozen. The logic for combining values are exactly alike; same input generates the same output from each (unlike the Sum and Product monoids for Int because they generate different results when combining Ints).

So, to recap: A monoid in the category of endofunctors describes:

``````   ~t :: m * -> m * -> m *
and a neutral value for m *
``````

`(<*>)` and `(>>=)` both provide simultaneous access to the two `m` values in order to compute the the single return value. The logic used to compute the return value is exactly the same. If it were not for the different shapes of the functions they parameterize (`f :: a -> b` versus `k :: a -> m b`) and the position of the parameter with the same return type of the computation (i.e., `a -> b -> b` versus `b -> a -> b` for each respectively), I suspect we could have parameterized the monoidal logic, the tensor product, for reuse in both definitions. As an exercise to make the point, try and implement `~t`, and you end up with `(<*>)` and `(>>=)` depending on how you decide to define it `forall a b`.

If my last point is at minimum conceptually true, it then explains the precise, and only computational difference between Applicative and Monad: the functions they parameterize. In other words, the difference is external to the implementation of these type classes.

In conclusion, in my own experience, Mac Lane's infamous quote provided a great "goto" meme, a guidepost for me to reference while navigating my way through Category to better understand the idioms used in Haskell. It succeeds at capturing the scope of a powerful computing capacity made wonderfully accessible in Haskell.

However, there is irony in how I first misunderstood the statement's applicability outside of the monad, and what I hope conveyed here. Everything that it describes turns out to be what is similar between Applicative and Monads (and Arrows among others). What it doesn't say is precisely the small but useful distinction between them.

- E

The answers here do an excellent job in defining both monoids and monads, however, they still don't seem to answer the question:

And on a less important note, is this true and if so could you give an explanation (hopefully one that can be understood by someone who doesn't have much Haskell experience)?

The crux of the matter that is missing here, is the different notion of "monoid", the so-called categorification more precisely -- the one of monoid in a monoidal category. Sadly Mac Lane's book itself makes it very confusing:

All told, a monad in `X` is just a monoid in the category of endofunctors of `X`, with product `×` replaced by composition of endofunctors and unit set by the identity endofunctor.

## Main confusion

Why is this confusing? Because it does not define what is "monoid in the category of endofunctors" of `X`. Instead, this sentence suggests taking a monoid inside the set of all endofunctors together with the functor composition as binary operation and the identity functor as a monoidal unit. Which works perfectly fine and turns into a monoid any subset of endofunctors that contains the identity functor and is closed under functor composition.

Yet this is not the correct interpretation, which the book fails to make clear at that stage. A Monad `f` is a fixed endofunctor, not a subset of endofunctors closed under composition. A common construction is to use `f` to generate a monoid by taking the set of all `k`-fold compositions `f^k = f(f(...))` of `f` with itself, including `k=0` that corresponds to the identity `f^0 = id`. And now the set `S` of all these powers for all `k>=0` is indeed a monoid "with product × replaced by composition of endofunctors and unit set by the identity endofunctor".

And yet:

• This monoid `S` can be defined for any functor `f` or even literally for any self-map of `X`. It is the monoid generated by `f`.
• The monoidal structure of `S` given by the functor composition and the identity functor has nothing do with `f` being or not being a monad.

And to make things more confusing, the definition of "monoid in monoidal category" comes later in the book as you can see from the table of contents. And yet understanding this notion is absolutely critical to understanding the connection with monads.

## (Strict) monoidal categories

Going to Chapter VII on Monoids (which comes later than Chapter VI on Monads), we find the definition of the so-called strict monoidal category as triple `(B, *, e)`, where `B` is a category, `*: B x B-> B` a bifunctor (functor with respect to each component with other component fixed) and `e` is a unit object in `B`, satisfying the associativity and unit laws:

``````(a * b) * c = a * (b * c)
a * e = e * a = a
``````

for any objects `a,b,c` of `B`, and the same identities for any morphisms `a,b,c` with `e` replaced by `id_e`, the identity morphism of `e`. It is now instructive to observe that in our case of interest, where `B` is the category of endofunctors of `X` with natural transformations as morphisms, `*` the functor composition and `e` the identity functor, all these laws are satisfied, as can be directly verified.

What comes after in the book is the definition of the "relaxed" monoidal category, where the laws only hold modulo some fixed natural transformations satisfying so-called coherence relations, which is however not important for our cases of the endofunctor categories.

## Monoids in monoidal categories

Finally, in section 3 "Monoids" of Chapter VII, the actual definition is given:

A monoid `c` in a monoidal category `(B, *, e)` is an object of `B` with two arrows (morphisms)

``````mu: c * c -> c
nu: e -> c
``````

making 3 diagrams commutative. Recall that in our case, these are morphisms in the category of endofunctors, which are natural transformations corresponding to precisely `join` and `return` for a monad. The connection becomes even clearer when we make the composition `*` more explicit, replacing `c * c` by `c^2`, where `c` is our monad.

Finally, notice that the 3 commutative diagrams (in the definition of a monoid in monoidal category) are written for general (non-strict) monoidal categories, while in our case all natural transformations arising as part of the monoidal category are actually identities. That will make the diagrams exactly the same as the ones in the definition of a monad, making the correspondence complete.

## Conclusion

In summary, any monad is by definition an endofunctor, hence an object in the category of endofunctors, where the monadic `join` and `return` operators satisfy the definition of a monoid in that particular (strict) monoidal category. Vice versa, any monoid in the monoidal category of endofunctors is by definition a triple `(c, mu, nu)` consisting of an object and two arrows, e.g. natural transformations in our case, satisfying the same laws as a monad.

Finally, note the key difference between the (classical) monoids and the more general monoids in monoidal categories. The two arrows `mu` and `nu` above are not anymore a binary operation and a unit in a set. Instead, you have one fixed endofunctor `c`. The functor composition `*` and the identity functor alone do not provide the complete structure needed for the monad, despite that confusing remark in the book.

Another approach would be to compare with the standard monoid `C` of all self-maps of a set `A`, where the binary operation is the composition, that can be seen to map the standard cartesian product `C x C` into `C`. Passing to the categorified monoid, we are replacing the cartesian product `x` with the functor composition `*`, and the binary operation gets replaced with the natural transformation `mu` from `c * c` to `c`, that is a collection of the `join` operators

``````join: c(c(T))->c(T)
``````

for every object `T` (type in programming). And the identity elements in classical monoids, which can be identified with images of maps from a fixed one-point-set, get replaced with the collection of the `return` operators

``````return: T->c(T)
``````

But now there are no more cartesian products, so no pairs of elements and thus no binary operations.