**Summary**: `(>>=)`

and `traverse`

look similar because they both are arrow mappings of functors, while `foldMap`

is (almost) a specialised `traverse`

.

Before we begin, there is one bit of terminology to explain. Consider `fmap`

:

```
fmap :: Functor f => (a -> b) -> (f a -> f b)
```

A Haskell `Functor`

is a functor from the **Hask** category (the category with Haskell functions as arrows) to itself. In category theory terms, we say that the (specialised) `fmap`

is the *arrow mapping* of this functor, as it is the part of the functor that takes arrows to arrows. (For the sake of completeness: a functor consists of an arrow mapping plus an *object mapping*. In this case, the objects are Haskell types, and so the object mapping takes types to types -- more specifically, the object mapping of a `Functor`

is its type constructor.)

We will also want to keep in mind the category and functor laws:

```
-- Category laws for Hask:
f . id = id
id . f = f
h . (g . f) = (h . g) . f
-- Functor laws for a Haskell Functor:
fmap id = id
fmap (g . f) = fmap g . fmap f
```

In what follows, we will work with categories other than **Hask**, and functors which are not `Functor`

s. In such cases, we will replace `id`

and `(.)`

by the appropriate identity and composition, `fmap`

by the appropriate arrow mapping and, in one case, `=`

by an appropriate equality of arrows.

## (=<<)

To begin with the more familiar part of the answer, for a given monad `m`

the `a -> m b`

functions (also known as Kleisli arrows) form a category (the Kleisli category of `m`

), with `return`

as identity and `(<=<)`

as composition. The three category laws, in this case, are just the monad laws:

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

Now, your asked about flipped bind:

```
(=<<) :: Monad m => (a -> m b) -> (m a -> m b)
```

It turns out that `(=<<)`

is the arrow mapping of a functor from the Kleisli category of `m`

to **Hask**. The functor laws applied to `(=<<)`

amount to two of the monad laws:

```
return =<< x = x -- right unit
(g <=< f) =<< x = g =<< (f =<< x) -- associativity
```

## traverse

Next, we need a detour through `Traversable`

(a sketch of a proof of the results in this section is provided at the end of the answer). First, we note that the `a -> f b`

functions for *all* applicative functors `f`

taken at once (as opposed to one at each time, as when specifying a Kleisli category) form a category, with `Identity`

as identity and `Compose . fmap g . f`

as composition. For that to work, we also have to adopt a more relaxed equality of arrows, which ignores the `Identity`

and `Compose`

boilerplate (which is only necessary because I am writing this in pseudo-Haskell, as opposed to proper mathematical notation). More precisely, we will consider that that any two functions that can be interconverted using any composition of the `Identity`

and `Compose`

isomorphisms as equal arrows (or, in other words, we will not distinguish between `a`

and `Identity a`

, nor between `f (g a)`

and `Compose f g a`

).

Let's call that category the "traversable category" (as I cannot think of a better name right now). In concrete Haskell terms, an arrow in this category is a function which adds an extra layer of `Applicative`

context "below" any previous existing layers. Now, consider `traverse`

:

```
traverse :: (Traversable t, Applicative f) => (a -> f b) -> (t a -> f (t b))
```

Given a choice of traversable container, `traverse`

is the arrow mapping of a functor from the "traversable category" to itself. The functor laws for it amount to the traversable laws.

In short, both `(=<<)`

and `traverse`

are analogues of `fmap`

for functors involving categories other than **Hask**, and so it is not surprising that their types are a bit similar to each other.

## foldMap

We still have to explain what all of that has to do with `foldMap`

. The answer is that `foldMap`

can be recovered from `traverse`

(cf. danidiaz's answer -- it uses `traverse_`

, but as the applicative functor is `Const m`

the result is essentially the same):

```
-- cf. Data.Traversable
foldMapDefault :: (Traversable t, Monoid m) => (a -> m) -> (t a -> m)
foldMapDefault f = getConst . traverse (Const . f)
```

Thanks to the `const`

/`getConst`

isomorphism, this is clearly equivalent to:

```
foldMapDefault' :: (Traversable t, Monoid m)
=> (a -> Const m b) -> (t a -> Const m (t b))
foldMapDefault' f = traverse f
```

Which is just `traverse`

specialised to the `Monoid m => Const m`

applicative functors. Even though `Traversable`

is not `Foldable`

and `foldMapDefault`

is not `foldMap`

, this provides a decent justification for why the type of `foldMap`

resembles that of `traverse`

and, transitively, that of `(=<<)`

.

As a final observation, note that the arrows of the "traversable category" with applicative functor `Const m`

for some `Monoid`

`m`

do *not* form a subcategory, as there is no identity unless `Identity`

is among the possible choices of applicative functor. That probably means there is nothing else of interest to say about `foldMap`

from the perspective of this answer. The only single choice of applicative functor that gives a subcategory is `Identity`

, which is not at all surprising, given how a traversal with `Identity`

amounts to `fmap`

on the container.

## Appendix

Here is a rough sketch of the derivation of the `traverse`

result, yanked from my notes from several months ago with minimal editing. `~`

means "equal up to (some relevant) isomorphism".

```
-- Identity and composition for the "traversable category".
idT = Identity
g .*. f = Compose . fmap g . f
-- Category laws: right identity
f .*. idT ~ f
f .*. idT
Compose . fmap f . idT
Compose . fmap f . Identity
Compose . Identity . f
f -- using getIdentity . getCompose
-- Category laws: left identity
idT .*. f ~ f
idT .*. f
Compose . fmap Identity . f
f -- using fmap getIdentity . getCompose
-- Category laws: associativity
h .*. (g .*. f) ~ (h .*. g) .*. f
h .*. (g .*. f) -- LHS
h .*. (Compose . fmap g . f)
Compose . fmap h . (Compose . fmap g . f)
Compose . Compose . fmap (fmap h) . fmap g . f
(h .*. g) .*. f -- RHS
(Compose . fmap h . g) .*. f
Compose . fmap (Compose . fmap h . g) . f
Compose . fmap (Compose . fmap h) . fmap g . f
Compose . fmap Compose . fmap (fmap h) . fmap g . f
-- using Compose . Compose . fmap getCompose . getCompose
Compose . Compose . fmap (fmap h) . fmap g . f -- RHS ~ LHS
```

```
-- Functor laws for traverse: identity
traverse idT ~ idT
traverse Identity ~ Identity -- i.e. the identity law of Traversable
-- Functor laws for traverse: composition
traverse (g .*. f) ~ traverse g .*. traverse f
traverse (Compose . fmap g . f) ~ Compose . fmap (traverse g) . traverse f
-- i.e. the composition law of Traversable
```

`concatMap'`

is`foldMap`

from the`Foldable`

class in`Data.Foldable`

. – ThreeFx Oct 10 '16 at 5:32