If you examine the type for `foldMap`

```
class Foldable f where
foldMap :: Monoid m => (a -> m) -> f a -> m
```

You'll see that it has an unbound type `m`

. Generally when this occurs it means that `m`

could be *anything*, but here it also constrains `m`

with `Monoid m`

. That's there the `Monoid`

comes from.

It's worth noting that if we didn't have the `Monoid`

instance then it's quite hard to define a function that returns a value that "could be anything". If you try it, you'll find it's almost impossible (without "cheating").

```
impossible :: Int -> b -- no constraints on `b` at all!
impossible i = ...?
```

But it's quite easy if we know a little bit about the type

```
veryPossible :: Num b => Int -> b
veryPossible i = fromIntegral i
-- or
veryPossible2 i = fromIntegral (i * i) + fromIntegral i
```

As another example, consider the type of the expression

```
expr m = mconcat [m <> m <> mempty, mempty <> m]
```

since this expression is built up based on some unknown value `m`

and uses *only* the functions in the `Monoid`

class or their derivatives, it's type reflects that. The most general type of `expr`

is

```
expr :: Monoid m => m -> m
```

Again here, `m`

is a free type variable constrained to be *some* `Monoid`

.

The reason `foldMap`

lets you use `Monoid`

functions is because it explicitly constrains the kinds of things that the `m`

in its type signature can be. By putting constraints there we gain more power to manipulate them.