I am very new to both Monads and Monoids and recently also learned about MonadPlus. From what I see, Monoid and MonadPlus both provide a type with a associative binary operation and an identity. (I'd call this a semigroup in mathematical parlance.) So what is the difference between Monoid and MonadPlus?

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A semigroup is a monoid without an identity--they're different things. In practice, I've found monoids to be far more common in programming than semigroups, but there is a nice semigroups package you can use if you do need those. –  Tikhon Jelvis Jun 12 '13 at 2:53
Also see Matt Fenwick's question "Confused by the meaning of the 'Alternative' type class and its relationship to other type classes" (full disclosure: which I answered). –  Antal S-Z Jun 12 '13 at 13:21

A semigroup is a structure equipped with an associative binary operation. A monoid is a semigroup with an identity element for the binary operation.

Every monad has to adhere to the monad laws. For our case, the important one is the associativity law. Expressed using `>>=`:

``````(m >>= f) >>= g     ≡   m >>= (\x -> f x >>= g)
``````

Now let's apply this law to deduce the associativity for `>> :: m a -> m b -> m b`:

``````(m >> n) >> p       ≡ (m >>= \_ -> n) >>= \_ -> p
≡ m >>= (\x -> (\_ -> n) x >>= \_ -> p)
≡ m >>= (\x -> n >>= \_ -> p)
≡ m >>= (\x -> n >> p)
≡ m >> (n >> p)
``````

(where we picked `x` so that it doesn't appear in `m`, `n` or `p`).

If we specialize `>>` to the type `m a -> m a -> m a` (substituting `b` for `a`), we see that for any type `a` the operation `>>` forms a semigroup on `m a`. Since it's true for any `a`, we get a class of semigroups indexed by `a`. However, they are not monoids in general - we don't have an identity element for `>>`.

`MonadPlus` adds two more operations, `mplus` and `mzero`. `MonadPlus` laws state explicitly that `mplus` and `mzero` must form a monoid on `m a` for an arbitrary `a`. So again, we get a class of monoids indexed by `a`.

Note the difference between `MonadPlus` and `Monoid`: `Monoid` says that some single type satisfies the monoidal rules, while `MonadPlus` says that for all possible `a` the type `m a` satisfies the monoidal laws. This is a much stronger condition.

So a `MonadPlus` instance forms two different algebraic structures: A class of semigroups with `>>` and a class of monoids with `mplus` and `mzero`. (This is not something uncommon, for example the set of natural numbers greater than zero `{1,2,...}` forms a semigroup with `+` and a monoid with `×` and `1`.)

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So `MonadPlus` with `mplus` is also a semigroup, right? –  Code-Apprentice Jun 12 '13 at 18:01
@Code-Guru Exactly - any monoid is also a semigroup, if we drop the identity element. –  Petr Pudlák Jun 12 '13 at 18:27
Isn't `(a->m a)` with `>=>` also a monoid, with identity `return`? –  Hjulle Mar 4 at 13:02
@Hjulle For a fixed `a` it is, as a moniod can be viewed as a category with a single object. –  Petr Pudlák Mar 4 at 15:30
Isn't `+` a monoid in natural numbers with `0` ? –  Fresheyeball Apr 27 at 16:14

If we have that `MonadPlus m` holds then you'd say `m` is a `Monad`, but `m a` (the type resulting from applying `a` to the type "function" `m`) is a monoid.

If we define (similar to `Data.Monoid`'s definition, but we'll make use of this later)

``````class                Semigroup a where  (<>) :: a -> a -> a
class Semigroup a => Monoid    a where  zero :: a
``````

then it has

``````mzero :: MonadPlus m => m a
mplus :: MonadPlus m => m a -> m a -> m a
``````

with pretty comparable types and the apropriate laws

``````-- left and right identity
mplus a     mzero   ==   a
mplus mzero a       ==   a

-- associativity
(a `mplus` b) `mplus` c   ==   a `mplus` (b `mplus` c)
``````

We can even define a Haskell `Monoid` if we use `-XFlexibleInstances`

``````{-# LANGUAGE FlexibleInstances #-}
instance MonadPlus m => Semigroup (m a) where  (<>) = mplus
instance MonadPlus m => Monoid    (m a) where  zero = mzero
``````

though these overlap badly with the instances in `Data.Monoid`, which is probably why it isn't a standard instance.

Another example of a monoid like this is `Alternative m => m a` from `Control.Applicative`.

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`MonadPlus` has some laws that interact with `Monad`; e.g. `(a `mplus` b) >>= f = (a >>= f) `mplus` (b >>= f)`. –  luqui Jun 12 '13 at 5:21
Re the overlap with `Data.Monoid`: this is exactly what I was confused by. Why isn't it automatically the case that `forall a. MonadPlus m => Monoid (m a)`? If we weren't worried about backwards compatibility, and could assume `-XFlexibleInstances`, then is there any further reason for that not to automatically hold? –  dubiousjim Jul 16 '14 at 18:44
@dubiousjim Consider this:`Just "a" `mappend` Just "b" == Just "ab"`, `Just "a" `mplus` Just "b" == Just "a"` –  Yuhta Apr 19 at 16:15

I must stress the very important difference: unlike Monoid, and unlike what the other answers state, MonadPlus does not provide a type with an associate binary operation and the identity. Haskell Report, the only document that can claim the status of the Standard, does not specify the laws of MonadPlus and hence does not require mplus to be associative or mzero to be its left or right unit. Perhaps the authors were still debating the laws: there are very good reasons for mplus to be not associative. For example, if mplus is associative but non-commutative, the non-deterministic search computation represented by MonadPlus cannot be complete (that is, there exist solutions we cannot find). Since it is quite rare that mplus is commutative, any complete non-deterministic search procedure cannot be represented by MonadPlus, if we insist on the associativity. There has been a detailed discussion of this very issue of MonadPlus laws on SC: Must mplus always be associative

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