What you've described is essentially a monoid. In GHCI:

```
Prelude> :m + Data.Monoid
Prelude Data.Monoid> :info Monoid
class Monoid a where
mempty :: a
mappend :: a -> a -> a
mconcat :: [a] -> a
```

As you can see a monoid has three associated functions:

The `mempty`

function is sort of like the identity function of the monoid. For example a `Num`

can behave as a monoid apropos two operations: sum and product. For a sum `mempty`

is defined as `0`

. For a product `mempty`

is defined as `1`

.

```
mempty `mappend` a = a
a `mappend` mempty = a
```

The `mappend`

function is similar to your `union`

function. For exampe for a sum of `Num`

s `mappend`

is defined as `(+)`

and for a product of `Num`

s `mappend`

is defined as `(*)`

.

The `mconcat`

function is similar to a fold. However because of the properties of a monoid it doesn't matter whether we fold from the left, fold from the right or fold from an arbitrary position. This is because `mappend`

is supposed to be associative:

```
(a `mappend` b) `mappend` c = a `mappend` (b `mappend` c)
```

Note however that Haskell doesn't enforce the monoid laws. Hence if you make a type an instance of the `Monoid`

typeclass then you're responsible to ensure that it satisfies the monoid laws.

In your case it's difficult to understand how `union`

behaves from its type signature: `a -> a -> a`

. Surely you can't make a type variable an instance of a typeclass. That's not allowed. You need to be more specific. What does `union`

actually do?

To give you an example of how to make a type an instance of the monoid typeclass:

```
newtype Sum a = Sum { getSum :: a }
instance Num a => Monoid (Sum a) where
mempty = 0
mappend = (+)
```

That's it. We don't need to define the `mconcat`

function because that has a default implementation that depends upon `mempty`

and `mappend`

. Hence when we define `mempty`

and `mappend`

we get `mconcat`

for free.

Now you can use `Sum`

as follows:

```
getSum . mconcat $ map Sum [1..6]
```

This is what's happening:

- You're mapping the
`Sum`

constructor over `[1..6]`

to produce `[Sum 1, Sum 2, Sum 3, Sum 4, Sum 5, Sum 6]`

.
- You give the resulting list to
`mconcat`

which folds it to `Sum 21`

.
- You use
`getSum`

to extract the `Num`

from `Sum 21`

.

Note however that the default implementation of `mconcat`

is `foldr mappend mempty`

(i.e. it's a right fold). For most cases the default implementation is sufficient. However in your case you might want to override the default implementation:

```
foldParallel :: Monoid a => [a] -> a
foldParallel [] = mempty
foldParallel [a] = a
foldParallel xs = foldParallel left `mappend` foldParallel right
where size = length xs
index = (size + size `mod` 2) `div` 2
(left, right) = splitAt index xs
```

Now we can create a new instance of `Monoid`

as follows:

```
data Something a = Something { getSomething :: a }
instance Monoid (Something a) where
mempty = unionEmpty
mappend = union
mconcat = foldParallel
```

We use it as follows:

```
getSomething . mconcat $ map Something [1..6]
```

Note that I defined `mempty`

as `unionEmpty`

. I don't know what type of data the `union`

function acts on. Hence I don't know what `mempty`

should be defined as. Thus I'm simply calling it `unionEmpty`

. Define it as you see fit.