`MonadPlus`

and `Monoid`

serve different purposes.

A `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.

However, `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 **`Alternative`

?

`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 isn't a superclass of `Monad`

.

Effectively, `Alternative`

is to `Applicative`

what `MonadPlus`

is to `Monad`

.

For these we 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.

However, since `Applicative`

is *not* a superclass of `Monad`

and `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 obeying

```
empty <*> m = empty
```

isn't strictly enough to prove that

```
empty >>= f = empty
```

So claiming that something is a `MonadPlus`

is stronger than claiming it is `Alternative`

.

Now, by convention, the `MonadPlus`

and `Alternative`

for a given type should agree, but the `Monoid`

may be *completely* different.

For instance the `MonadPlus`

and `Alternative`

for `Maybe`

do the obvious thing:

```
instance MonadPlus Maybe where
mzero = Nothing
mplus (Just a) _ = Just a
mplus _ mb = mb
```

but the `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
```

**TL;DR** `MonadPlus`

is a stronger claim than `Alternative`

, which in turn is a stronger claim than `Monoid`

, and while the `MonadPlus`

and `Alternative`

instances for a type should be related, the `Monoid`

may be (and sometimes is) something completely different.

`Applicative`

and`MonadPlus`

seem to beexactlythe same (modulo superclass constraints). – Peter Apr 16 '12 at 2:22`ArrowZero`

and`ArrowPlus`

for arrows. My bet: to make type signatures cleaner (which makes differing superclass constraintsthereal difference). – Cat Plus Plus Apr 16 '12 at 2:28`ArrowZero`

and`ArrowPlus`

have kind`* -> * -> *`

, which means you can pass them in for the arrow type once for a function that needs to use them for a multitude of types, to use a`Monoid`

you'd have to require an instance of`Monoid`

for each particular instantiation, and you'd have no guarantee they were handled in a similar way, the instances could be unrelated! – Edward Kmett Apr 16 '12 at 2:52