We begin with the type of `foldMap`

:

```
foldMap :: (Foldable t, Monoid m) => (a -> m) -> t a -> m
```

`foldMap`

works by mapping the `a -> m`

function over the data structure and then running through it smashing the elements into a single accumulated value with `mappend`

.

Next, we note that, given some type `b`

, the `b -> b`

functions form a monoid, with `(.)`

as its binary operation (i.e. `mappend`

) and `id`

as the identity element (i.e. `mempty`

. In case you haven't met it yet, `id`

is defined as `id x = x`

). If we were to specialise `foldMap`

for that monoid, we would get the following type:

```
foldEndo :: Foldable t => (a -> (b -> b)) -> t a -> (b -> b)
```

(I called the function `foldEndo`

because an endofunction is a function from one type to the same type.)

Now, if we look at the signature of the list `foldr`

```
foldr :: (a -> b -> b) -> b -> [a] -> b
```

we can see that `foldEndo`

matches it, except for the generalisation to any `Foldable`

and for some reordering of the arguments.

Before we get to an implementation, there is a technical complication in that `b -> b`

can't be directly made an instance of `Monoid`

. To solve that, we use the `Endo`

newtype wrapper from `Data.Monoid`

instead:

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

Written in terms of `Endo`

, `foldEndo`

is just specialised `foldMap`

:

```
foldEndo :: Foldable t => (a -> Endo b) -> t a -> Endo b
```

So we will jump directly to `foldr`

, and define it in terms of `foldMap`

.

```
foldr :: Foldable t => (a -> b -> b) -> b -> t a -> b
foldr f z t = appEndo (foldMap (Endo . f) t) z
```

Which is the default definition you can find in `Data.Foldable`

. The trickiest bit is probably `Endo . f`

; if you have trouble with that, think of `f`

not as a binary operator, but as a function of one argument with type `a -> (b -> b)`

; we then wrap the resulting endofunction with `Endo`

.

As for `foldl`

, the derivation is essentially the same, except that we use a different monoid of endofunctions, with `flip (.)`

as the binary operation (i.e. we compose the functions in the opposite direction).

`/=`

you get if you implement`==`

as discussed here