Monoid newtypes: A zero space noop to tell the compiler what to do
Monoids are great to wrap an existing data type in a new type to tell the compiler what operation you want to do.
Since they're newtypes, they don't take any additional space and applying Sum
or getSum
is a noop.
Example: Monoids in Foldable
There's more than one way to generalise foldr (see this very good question for the most general fold, and this question if you like the tree examples below but want to see a most general fold for trees).
One useful way (not the most general way, but definitely useful) is to say something's foldable if you can combine its elements into one with a binary operation and a start/identity element. That's the point of the Foldable
typeclass.
Instead of explicitly passing in a binary operation and start element, Foldable
just asks that the element data type is an instance of Monoid.
At first sight this seems frustrating because we can only use one binary operation per data type  but should we use (+)
and 0
for Int
and take sums but never products, or the other way round? Perhaps should we use ((+),0)
for Int
and (*),1
for Integer
and convert when we want the other operation? Wouldn't that waste a lot of precious processor cycles?
Monoids to the rescue
All we need to do is tag with Sum
if we want to add, tag with Product
if we want to multiply, or even tag with a handrolled newtype if we want to do something different.
Let's fold some trees! We'll need
fold :: (Foldable t, Monoid m) => t m > m
 if the element type is already a monoid
foldMap :: (Foldable t, Monoid m) => (a > m) > t a > m
 if you need to map a function onto the elements first
The DeriveFunctor
and DeriveFoldable
extensions ({# LANGUAGE DeriveFunctor, DeriveFoldable #}
) are great if you want to map over and fold up your own ADT without writing the tedious instances yourself.
import Data.Monoid
import Data.Foldable
import Data.Tree
import Data.Tree.Pretty  from the prettytree package
see :: Show a => Tree a > IO ()
see = putStrLn.drawVerticalTree.fmap show
numTree :: Num a => Tree a
numTree = Node 3 [Node 2 [],Node 5 [Node 2 [],Node 1 []],Node 10 []]
familyTree = Node " Grandmama " [Node " Uncle Fester " [Node " Cousin It " []],
Node " Gomez  Morticia " [Node " Wednesday " [],
Node " Pugsley " []]]
Example usage
Strings are already a monoid using (++)
and []
, so we can fold
with them, but numbers aren't, so we'll tag them using foldMap
.
ghci> see familyTree
" Grandmama "


/ \
" Uncle Fester " " Gomez  Morticia "
 
" Cousin It " 
/ \
" Wednesday " " Pugsley "
ghci> fold familyTree
" Grandmama Uncle Fester Cousin It Gomez  Morticia Wednesday Pugsley "
ghci> see numTree
3


/  \
2 5 10


/ \
2 1
ghci> getSum $ foldMap Sum numTree
23
ghci> getProduct $ foldMap Product numTree
600
ghci> getAll $ foldMap (All.(<= 10)) numTree
True
ghci> getAny $ foldMap (Any.(> 50)) numTree
False
Roll your own Monoid
But what if we wanted to find the maximum element? We can define our own monoids. I'm not sure why Max
(and Min
) aren't in. Maybe it's because noone likes thinking about Int
being bounded or they just don't like an identity element that's based on an implementation detail. In any case here it is:
newtype Max a = Max {getMax :: a}
instance (Ord a,Bounded a) => Monoid (Max a) where
mempty = Max minBound
mappend (Max a) (Max b) = Max $ if a >= b then a else b
ghci> getMax $ foldMap Max numTree :: Int  Int to get Bounded instance
10
Conclusion
We can use newtype Monoid wrappers to tell the compiler which way to combine things in pairs.
The tags do nothing, but show what combining function to use.
It's like passing the functions in as an implicit parameter rather than an explicit one (because that's kind of what a type class does anyway).
sum = getSum . Data.Foldable.foldMap Sum