The following is all based on my (mis)understanding of this very
interesting paper posted by Matthew Pickering in his
comment: *From monoids to near-semirings: the essence of MonadPlus and
Alternative*. All results are theirs; all mistakes are mine.

## From free monoids to `DList`

To build up the intuition, first consider the free monoid `[]`

over
the category of Haskell types `Hask`

. One problem with `[]`

is that if
you have

```
(xs `mappend` ys) `mappend` zs = (xs ++ ys) ++ zs
```

then evaluating that requires traversing and re-traversing `xs`

for
each left-nested application of `mappend`

.

The solution is to use CPS in the form of difference
lists:

```
newtype DList a = DL { unDL :: [a] -> [a] }
```

The paper considers the generic form of this (called the Cayley
representation) where we're not tied to the free monoid:

```
newtype Cayley m = Cayley{ unCayley :: Endo m }
```

with conversions

```
toCayley :: (Monoid m) => m -> Cayley m
toCayley m = Cayley $ Endo $ \m' -> m `mappend` m'
fromCayley :: (Monoid m) => Cayley m -> m
fromCayley (Cayley k) = appEndo k mempty
```

## Two directions of generalization

We can generalize the above construction in two ways: first, by
considering monoids not over `Hask`

, but over endofunctors of `Hask`

;
i.e.
monads; and second, by enriching the algebraic structure into
near-semirings.

`Free`

monads to `Codensity`

For any Haskell (endo)functor `f`

, we can construct the free
monad `Free f`

, and
it will have the analogous performance problem with left-nested binds,
with the analogous solution of using the Cayley representation
`Codensity`

.

## Near-semirings instead of just monoids

This is where the paper stops reviewing concepts that are well-known
by the working Haskell programmer, and starts homing in on its goal. A
near-semiring is like a ring, except simpler, since both addition and
multiplication are just required to be monoids. The connection between
the two operations is what you expect:

```
zero |*| a = zero
(a |+| b) |*| c = (a |*| c) |+| (b |*| c)
```

where `(zero, |+|)`

and `(one, |*|)`

are the two monoids over some
shared base:

```
class NearSemiring a where
zero :: a
(|+|) :: a -> a -> a
one :: a
(|*|) :: a -> a -> a
```

The free near-semiring (over `Hask`

) turns out to be the following
`Forest`

type:

```
newtype Forest a = Forest [Tree a]
data Tree a = Leaf | Node a (Forest a)
instance NearSemiring (Forest a) where
zero = Forest []
one = Forest [Leaf]
(Forest xs) |+| (Forest ys) = Forest (xs ++ ys)
(Forest xs) |*| (Forest ys) = Forest (concatMap g xs)
where
g Leaf = ys
g (Node a n) = [Node a (n |*| (Forest ys))]
```

(good thing we don't have commutativity or inverses,
those make free representations far from
trivial...)

Then, the paper applies the Cayley representation twice, to the two
monoidal structures.

However, if we do this naively, we do
not get a good representation: we want to represent a near-semiring,
and therefore the whole near-semiring structure must be taken into
account and not just one chosen monoid structure. [...] [W]e obtain
the semiring of endomorphisms over endomorphisms `DC(N)`

:

```
newtype DC n = DC{ unDC :: Endo (Endo n) }
instance (Monoid n) => NearSemiring (DC n) where
f |*| g = DC $ unDC f `mappend` unDC g
one = DC mempty
f |+| g = DC $ Endo $ \h -> appEndo (unDC f) h `mappend` h
zero = DC $ Endo $ const mempty
```

(I've changed the implementation here slightly from the paper to
emphasize that we are using the `Endo`

structure twice). When we'll
generalize this, the two layers will not be the same. The paper then
goes on to say:

Note that `rep`

is not a near-semiring homomorphism from `N`

into `DC(N)`

as it does not preserve the unit [...] Nevertheless, [...] the
semantics of a computation over a near-semiring will be preserved if
we lift values to the representation, do the near-semiring computation
there, and then go back to the original near-semiring.

`MonadPlus`

is almost a near-semiring

The paper then goes on to reformulate the `MonadPlus`

typeclass so
that it corresponds to the near-semiring rules: `(mzero, mplus)`

is monoidal:

```
m `mplus` mzero = m
mzero `mplus` m = m
m1 `mplus` (m2 `mplus` m3) = (m1 `mplus` m2) `mplus` m3
```

and it interacts with the monad-monoid as expected:

```
join mzero = mzero
join (m1 `mplus` m2) = join m1 `mplus` join m2
```

Or, using binds:

```
mzero >>= _ = mzero
(m1 `mplus` m2) >>= k = (m1 >>= k) `mplus` (m2 >>= k)
```

However, these are **not** the rules of the existing `MonadPlus`

typeclass from
`base`

,
which are listed as:

```
mzero >>= _ = mzero
_ >> mzero = mzero
```

The paper calls `MonadPlus`

instances that satisfy the
near-semiring-like laws "nondeterminism monads", and
cites `Maybe`

as an example that is a `MonadPlus`

but not a
nondeterminism monad, since setting `m1 = Just Nothing`

and ```
m2 = Just
(Just False)
```

is a counter-example to ```
join (m1 `mplus` m2) = join m1
`mplus` join m2
```

.

## Free and Cayley representation of nondeterminism monads

Putting everything together, on one hand we have the `Forest`

-like
free nondeterminism monad:

```
newtype FreeP f x = FreeP { unFreeP :: [FFreeP f x] }
data FFreeP f x = PureP x | ConP (f (FreeP f x))
instance (Functor f) => Functor (FreeP f) where
fmap f x = x >>= return . f
instance (Functor f) => Monad (FreeP f) where
return x = FreeP $ return $ PureP x
(FreeP xs) >>= f = FreeP (xs >>= g)
where
g (PureP x) = unFreeP (f x)
g (ConP x) = return $ ConP (fmap (>>= f) x)
instance (Functor f) => MonadPlus (FreeP f) where
mzero = FreeP mzero
FreeP xs `mplus` FreeP ys = FreeP (xs `mplus` ys)
```

and on the other, the double-Cayley representation of the two monoidal
layers:

```
newtype (:^=>) f g x = Ran{ unRan :: forall y. (x -> f y) -> g y }
newtype (:*=>) f g x = Exp{ unExp :: forall y. (x -> y) -> (f y -> g y) }
instance Functor (g :^=> h) where
fmap f m = Ran $ \k -> unRan m (k . f)
instance Functor (f :*=> g) where
fmap f m = Exp $ \k -> unExp m (k . f)
newtype DCM f x = DCM {unDCM :: ((f :*=> f) :^=> (f :*=> f)) x}
instance Monad (DCM f) where
return x = DCM $ Ran ($x)
DCM (Ran m) >>= f = DCM $ Ran $ \g -> m $ \a -> unRan (unDCM (f a)) g
instance MonadPlus (DCM f) where
mzero = DCM $ Ran $ \k -> Exp (const id)
mplus m n = DCM $ Ran $ \sk -> Exp $ \f fk -> unExp (a sk) f (unExp (b sk) f fk)
where
DCM (Ran a) = m
DCM (Ran b) = n
caylize :: (Monad m) => m a -> DCM m a
caylize x = DCM $ Ran $ \g -> Exp $ \h m -> x >>= \a -> unExp (g a) h m
-- I wish I called it DMC earlier...
runDCM :: (MonadPlus m) => DCM m a -> m a
runDCM m = unExp (f $ \x -> Exp $ \h m -> return (h x) `mplus` m) id mzero
where
DCM (Ran f) = m
```

The paper gives the following example of a computation running in a
nondeterminism monad that will behave poorly for `FreeP`

:

```
anyOf :: (MonadPlus m) => [a] -> m a
anyOf [] = mzero
anyOf (x:xs) = anyOf xs `mplus` return x
```

Indeed, while

```
length $ unFreeP (anyOf [1..100000] :: FreeP Identity Int)
```

takes ages, the Cayley-transformed version

```
length $ unFreeP (runDCM $ anyOf [1..100000] :: FreeP Identity Int)
```

returns instantly.