Monoid serve different purposes.
Monoid is parameterized over a type of kind
class Monoid m where
mempty :: m
mappend :: m -> m -> m
and so it can be instantiated for almost any type for which there is an obvious operator that is associative and which has a unit.
MonadPlus not only specifies that you have a monoidal structure, but also that that structure is related to how the
Monad works, and that that structure doesn't care about the value contained in the monad, this is (in part) indicated by the fact that
MonadPlus takes an argument of kind
* -> *.
class Monad m => MonadPlus m where
mzero :: m a
mplus :: m a -> m a -> m a
In addition to the monoid laws, we have two potential sets of laws we can apply to
MonadPlus. Sadly, the community disagrees as to what they should be.
At the least we know
mzero >>= k = mzero
but there are two other competing extensions, the left (sic) distribution law
mplus a b >>= k = mplus (a >>= k) (b >>= k)
and the left catch law
mplus (return a) b = return a
So any instance of
MonadPlus should satisfy one or both of these additional laws.
So what about
Applicative was defined after
Monad, and logically belongs as a superclass of
Monad, but largely due to the different pressures on the designers back in Haskell 98, even
Functor wasn't a superclass of
Monad until 2015. Now we finally have
Applicative as a superclass of
Monad in GHC (if not yet in a language standard.)
Alternative is to
MonadPlus is to
For these we'd get
empty <*> m = empty
analogously to what we have with
MonadPlus and there exist similar distributive and catch properties, at least one of which you should satisfy.
empty <*> m = empty law is too strong a claim. It doesn't hold for Backwards, for instance!
When we look at MonadPlus, the empty >>= f = empty law is nearly forced on us. The empty construction can't have any 'a's in it to call the function
f with anyways.
Applicative is not a superclass of
Alternative is not a superclass of
MonadPlus, we wind up defining both instances separately.
Moreover, even if
Applicative was a superclass of
Monad, you'd wind up needing the
MonadPlus class anyways, because even if we did obey
empty <*> m = empty
that isn't strictly enough to prove that
empty >>= f = empty
So claiming that something is a
MonadPlus is stronger than claiming it is
Now, by convention, the
Alternative for a given type should agree, but the
Monoid may be completely different.
For instance the
Maybe do the obvious thing:
instance MonadPlus Maybe where
mzero = Nothing
mplus (Just a) _ = Just a
mplus _ mb = mb
Monoid instance lifts a semigroup into a
Monoid. Sadly because there did not exist a
Semigroup class at the time in Haskell 98, it does so by requring a
Monoid, but not using its unit. ಠ_ಠ
instance Monoid a => Monoid (Maybe a) where
mempty = Nothing
mappend (Just a) (Just b) = Just (mappend a b)
mappend Nothing x = x
mappend x Nothing = x
mappend Nothing Nothing = Nothing
MonadPlus is a stronger claim than
Alternative, which in turn is a stronger claim than
Monoid, and while the
Alternative instances for a type should be related, the
Monoid may be (and sometimes is) something completely different.