In category theory, a monad is the composition of two adjoint functors. For example, the Maybe monad is the free pointed-set functor composed with the forgetful functor. Likewise, the List monad is the free monoid functor composed with the forgetful functor.

Monoid is one of the simplest algebraic structures, so I wonder if programming can benefit from more complex ones. I didn't find the free group monad in standard Haskell packages, so I'll define it here

```
data FreeGroup a = Nil | PosCons a (FreeGroup a) | NegCons a (FreeGroup a)
```

The `==`

operator is defined such that `NegCons x (PosCons x y) == y`

. Accordingly, in `length :: FreeGroup a -> Int`

, each `PosCons`

is counted +1 and each `NegCons`

-1 (it is the only group morphism to Int that values +1 on each PosCons).

As in lists (free monoids), `concat`

is just multiplication and `map`

is the functorial lift of functions. So the monad instance of `FreeGroup`

is exactly the same as that of `List`

.

Does the free group monad have any programming uses ? Also, there is often an interpretation of a monad as a value in a context : for `List`

the context would be choice or uncertainty. Is there such an interpretation for the free group monad ?

How about free rings and vector spaces (which are always free) ?

For any algebraic structure `S`

, the existence of a categorical free functor `FS :: Set -> S`

means the existence of a function Haskell calls fold :

```
foldS :: S s => (a -> s) -> FS a -> s
```

It lifts a function on the basis `a`

to an `S`

-morphism on the free object `FS a`

. The usual `foldr`

function is a specialization of `foldMonoid`

(called `foldMap`

in Haskell, for some reason I don't quite get), the monoid being the set of functions `b -> b`

with composition as multiplication.

For the sake of completeness, here is the monad instance of `FreeGroup`

:

```
mult :: FreeGroup a -> FreeGroup a -> FreeGroup a
mult Nil x = x
mult x Nil = x
mult (PosCons x y) z = PosCons x (mult y z)
mult (NegCons x y) z = NegCons x (mult y z)
inverse :: FreeGroup a -> FreeGroup a
inverse Nil = Nil
inverse (PosCons x y) = mult (inverse y) (NegCons x Nil)
inverse (NegCons x y) = mult (inverse y) (PosCons x Nil)
groupConcat :: FreeGroup (FreeGroup a) -> FreeGroup a
groupConcat Nil = Nil
groupConcat (PosCons x l) = mult x (groupConcat l)
groupConcat (NegCons x l) = mult (inverse x) (groupConcat l)
instance Functor FreeGroup where
fmap f Nil = Nil
fmap f (PosCons x y) = PosCons (f x) (fmap f y)
fmap f (NegCons x y) = NegCons (f x) (fmap f y)
instance Applicative FreeGroup where
pure x = PosCons x Nil
fs <*> xs = do { f <- fs; x <- xs; return $ f x; }
instance Monad FreeGroup where
l >>= f = groupConcat $ fmap f l
```

`NegCons x (PosCons x y) == y`

, you need an`Eq`

instance for the`a`

in`FreeGroup a`

. You cannot force that. I doubt`FreeGroup`

is a monad in haskell.`instance Eq a => Eq [a]`

. The monad definition doesn't need the`==`

operator, I just spoke of it the explain the link between`PosCons`

and`NegCons`

.`Eq`

constraint here like in the example you gave in the comment because for`Monad`

you don't have "access" to the type argument. You cannot put an`Eq`

constraint on`instance Monad FreeGroup where ...`

. I guess this could work if you avoid equality by not having the Monad instance put it in any sort of normal form.`type instance Element (FreeGroup a) = a`

and then`instance Eq a => MonoFoldable (FreeGroup a) where ...`

. The`ofoldMap`

implementation will have to collapse positive and negative elements appropriately. You'll probably also want`normalize :: Eq a => FreeGroup a -> FreeGroup a`

. The need to normalize manually, and track normalization without help from the type checker, is probably the biggest barrier to making this useful.5more comments