To begin with, let me offer short answers to each of these questions. I will then expand each into a longer detailed answer, but these short ones will hopefully help in navigating those.

No, `Alternative`

and `Monoid`

don’t mean different things; `Alternative`

is for types which have the structure both of `Applicative`

and of `Monoid`

. “Picking” and “combining” are two different intuitions for the same broader concept.

`Alternative`

contains `empty`

as well as `<|>`

because the designers thought this would be useful, and because this gives rise to a monoid. In terms of picking, `empty`

corresponds to making an impossible choice.

We need both `Alternative`

and `Monoid`

because the former obeys (or should) *more* laws than the latter; these laws relate the monoidal and applicative structure of the type constructor. Additionally, `Alternative`

can’t depend on the inner type, while `Monoid`

can.

`MonadPlus`

is slightly stronger than `Alternative`

, as it must obey more laws; these laws relate the monoidal structure to the monadic structure in addition to the applicative structure. If you have instances of both, they should coincide.

Doesn’t `Alternative`

mean something totally different from `Monoid`

?

Not really! Part of the reason for your confusion is that the Haskell `Monoid`

class uses some pretty bad (well, insufficiently general) names. This is how a mathematician would define a monoid (being very explicit about it):

**Definition.** A *monoid* is a set *M* equipped with a distinguished element *ε* ∈ *M* and a binary operator · : *M* × *M* → *M*, denoted by juxtaposition, such that the following two conditions hold:

*ε* is the identity: for all *m* ∈ *M*, *m**ε* = *ε**m* = *m*.
- · is associative: for all
*m*₁,*m*₂,*m*₃ ∈ *M*, (*m*₁*m*₂)*m*₃ = *m*₁(*m*₂*m*₃).

That’s it. In Haskell, ε is spelled `mempty`

and · is spelled `mappend`

(or, these days, `<>`

), and the set *M* is the type `M`

in `instance Monoid M where ...`

.

Looking at this definition, we see that it says nothing about “combining” (or about “picking,” for that matter). It says things about · and about *ε*, but that’s it. Now, it’s certainly true that combining things works well with this structure: *ε* corresponds to having no things, and *m*₁*m*₂ says that if I glom *m*₁ and *m*₂’s stuff together, I can get a new thing containing all their stuff. But here’s an alternative intuition: *ε* corresponds to no choices at all, and *m*₁*m*₂ corresponds to a choice between *m*₁ and *m*₂. This is the “picking” intuition. Note that both obey the monoid laws:

- Having nothing at all and having no choice are both the identity.
- If I have no stuff and glom it together with some stuff, I end up with that same stuff again.
- If I have a choice between no choice at all (something impossible) and some other choice, I have to pick the other (possible) choice.

- Glomming collections together and making a choice are both associative.
- If I have three collections of things, it doesn’t matter if I glom the first two together and then the third, or the last two together and then the first; either way, I end up with the same total glommed collection.
- If I have a choice between three things, it doesn’t matter if I (a) first choose between first-or-second and third and then, if I need to, between first and second, or (b) first choose between first and second-or-third and then, if I need to, between second and third. Either way, I can pick what I want.

(Note: I’m playing fast and loose here; that’s why it’s intuition. For instance, it’s important to remember that · need not be commutative, which the above glosses over: it’s perfectly possible that *m*₁*m*₂ ≠ *m*₂*m*₁.)

Behold: both these sorts of things (and many others—is multiplying numbers really either “combining” *or* “picking”?) obey the same rules. Having an intuition is important to develop understanding, but it’s the rules and definitions that determine what’s *actually* going on.

And the best part is that these both of these intuitions can be interpreted by the same carrier! Let *M* be some set of sets (not a set of *all* sets!) containing the empty set, let *ε* be the empty set ∅, and let · be set union ∪. It is easy to see that ∅ is an identity for ∪, and that ∪ is associative, so we can conclude that (*M*,∅,∪) is a monoid. Now:

- If we think about sets as being collections of things, then ∪ corresponds to glomming them together to get more things—the “combining” intuition.
- If we think about sets as representing possible actions, then ∪ corresponds to increasing your pool of possible actions to pick from—the “picking” intuition.

And this is exactly what’s going on with `[]`

in Haskell: `[a]`

is a `Monoid`

for all `a`

, and `[]`

as an applicative functor (and monad) is used to represent nondeterminism. Both the combining and the picking intuitions coincide at the same type: `mempty = empty = []`

and `mappend = (<|>) = (++)`

.

So the `Alternative`

class is just there to represent objects which (a) are applicative functors, and (b) when instantiated at a type, have a value and a binary function on them which follow some rules. Which rules? The monoid rules. Why? Because it turns out to be useful :-)

Why does `Alternative`

need an empty method/member?

Well, the snarky answer is “because `Alternative`

represents a monoid structure.” But the real question is: *why* a monoid structure? Why not just a semigroup, a monoid without *ε*? One answer is to claim that monoids are just more useful. I think many people (but perhaps not Edward Kmett) would agree with this; almost all of the time, if you have a sensible `(<|>)`

/`mappend`

/·, you’ll be able to define a sensible `empty`

/`mempty`

/*ε*. On the other hand, having the extra generality is nice, since it lets you place more things under the umbrella.

You also want to know how this meshes with the “picking” intuition. Keeping in mind that, in some sense, the right answer is “know when to abandon the ‘picking’ intuition,” I think you *can* unify the two. Consider `[]`

, the applicative functor for nondeterminism. If I combine two values of type `[a]`

with `(<|>)`

, that corresponds to nondeterministically picking either an action from the left or an action from the right. But sometimes, you’re going to have no possible actions on one side—and that’s fine. Similarly, if we consider parsers, `(<|>)`

represents a parser which parses either what’s on the left or what’s on the right (it “picks”). And if you have a parser which always fails, that ends up being an identity: if you pick it, you immediately reject that pick and try the other one.

All this said, remember that it *would* be entirely possible to have a class almost like `Alternative`

, but lacking `empty`

. That would be perfectly valid—it could even be a superclass of `Alternative`

—but happens not to be what Haskell did. Presumably this is out of a guess as to what’s useful.

Why does the `Alternative`

type class need an `Applicative`

constraint, and why does it need a kind of `* -> *`

? … Why not just [use] `liftA2 mappend`

?

Well, let’s consider each of these three proposed changes: getting rid of the `Applicative`

constraint for `Alternative`

; changing the kind of `Alternative`

’s argument; and using `liftA2 mappend`

instead of `<|>`

and `pure mempty`

instead of `empty`

. We’ll look at this third change first, since it’s the most different. Suppose we got rid of `Alternative`

entirely, and replaced the class with two plain functions:

```
fempty :: (Applicative f, Monoid a) => f a
fempty = pure mempty
(>|<) :: (Applicative f, Monoid a) => f a -> f a -> f a
(>|<) = liftA2 mappend
```

We could even keep the definitions of `some`

and `many`

. And this *does* give us a monoid structure, it’s true. But it seems like it gives us the wrong one . Should `Just fst >|< Just snd`

fail, since `(a,a) -> a`

isn’t an instance of `Monoid`

? No, but that’s what the above code would result in. The monoid instance we *want* is one that’s inner-type agnostic (to borrow terminology from Matthew Farkas-Dyck in a very related haskell-cafe discussion which asks some very similar questions); the `Alternative`

structure is about a monoid determined by `f`

’s structure, not the structure of `f`

’s argument.

Now that we think we want to leave `Alternative`

as some sort of type class, let’s look at the two proposed ways to change it. If we change the kind, we *have* to get rid of the `Applicative`

constraint; `Applicative`

only talks about things of kind `* -> *`

, and so there’s no way to refer to it. That leaves two possible changes; the first, more minor, change is to get rid of the `Applicative`

constraint but leave the kind alone:

```
class Alternative' f where
empty' :: f a
(<||>) :: f a -> f a -> f a
```

The other, larger, change is to get rid of the `Applicative`

constraint and change the kind:

```
class Alternative'' a where
empty'' :: a
(<|||>) :: a -> a -> a
```

In both cases, we have to get rid of `some`

/`many`

, but that’s OK; we can define them as standalone functions with the type `(Applicative f, Alternative' f) => f a -> f [a]`

or `(Applicative f, Alternative'' (f [a])) => f a -> f [a]`

.

Now, in the second case, where we change the kind of the type variable, we see that our class is exactly the same as `Monoid`

(or, if you still want to remove `empty''`

, `Semigroup`

), so there’s no advantage to having a separate class. And in fact, even if we leave the kind variable alone but remove the `Applicative`

constraint, `Alternative`

just becomes `forall a. Monoid (f a)`

, although we can’t write these quantified constraints in Haskell, not even with all the fancy GHC extensions. (Note that this expresses the inner-type–agnosticism mentioned above.) Thus, if we can make either of these changes, then we have no reason to keep `Alternative`

(except for being able to express that quantified constraint, but that hardly seems compelling).

So the question boils down to “is there a relationship between the `Alternative`

parts and the `Applicative`

parts of an `f`

which is an instance of both?” And while there’s nothing in the documentation, I’m going to take a stand and say *yes*—or at the very least, there *ought* to be. I think that `Alternative`

is supposed to obey some laws relating to `Applicative`

(in addition to the monoid laws); in particular, I think those laws are something like

**Right distributivity (of **`<*>`

): `(f <|> g) <*> a = (f <*> a) <|> (g <*> a)`

**Right absorption (for **`<*>`

): `empty <*> a = empty`

**Left distributivity (of **`fmap`

): `f <$> (a <|> b) = (f <$> a) <|> (f <$> b)`

**Left absorption (for **`fmap`

): `f <$> empty = empty`

These laws appear to be true for `[]`

and `Maybe`

, and (pretending its `MonadPlus`

instance is an `Alternative`

instance) `IO`

, but I haven’t done any proofs or exhaustive testing. (For instance, I originally thought that *left* distributivity held for `<*>`

, but this “performs the effects” in the wrong order for `[]`

.) By way of analogy, though, it is true that `MonadPlus`

is expected to obey similar laws (although there is apparently some ambiguity about which). I had originally wanted to claim a third law, which seems natural:

**Left absorption (for **`<*>`

): `a <*> empty = empty`

However, although I believe `[]`

and `Maybe`

obey this law, `IO`

doesn’t, and I think (for reasons that will become apparent in the next couple of paragraphs) it’s best not to require it.

And indeed, it appears that Edward Kmett has some slides where he espouses a similar view; to get into that, we’ll need to take brief digression involving some more mathematical jargon. The final slide, “I Want More Structure,” says that “A Monoid is to an Applicative as a Right Seminearring is to an Alternative,” and “If you throw away the argument of an Applicative, you get a Monoid, if you throw away the argument of an Alternative you get a RightSemiNearRing.”

Right seminearrings? “How did right seminearrings get into it?” I hear you cry. Well,

**Definition.** A *right near-semiring* (also *right seminearring*, but the former seems to be used more on Google) is a quadruple (*R*,+,·,0) where (*R*,+,0) is a monoid, (*R*,·) is a semigroup, and the following two conditions hold:

- · is right-distributive over +: for all
*r*,*s*,*t* ∈ *R*, (*s* + *t*)*r* = *sr* + *tr*.
- 0 is right-absorbing for ·: for all
*r* ∈ *R*, 0*r* = 0.

A *left near-semiring* is defined analogously.

Now, this doesn’t quite work, because `<*>`

is not truly associative or a binary operator—the types don’t match. I think this is what Edward Kmett is getting at when he talks about “throw[ing] away the argument.” Another option might be to say (I’m unsure if this is right) that we actually want (`f a`

, `<|>`

, `<*>`

, `empty`

) to form a *right near-semiringoid*, where the “-oid” suffix indicates that the binary operators can only be applied to specific pairs of elements (à la *groupoids*). And we’d also want to say that (`f a`

, `<|>`

, `<$>`

, `empty`

) was a left near-semiringoid, although this could conceivably follow from the combination of the `Applicative`

laws and the right near-semiringoid structure. But now I’m getting in over my head, and this isn’t deeply relevant anyway.

At any rate, these laws, being *stronger* than the monoid laws, mean that perfectly valid `Monoid`

instances would become invalid `Alternative`

instances. There are (at least) two examples of this in the standard library: `Monoid a => (a,)`

and `Maybe`

. Let’s look at each of them quickly.

Given any two monoids, their product is a monoid; consequently, tuples can be made an instance of `Monoid`

in the obvious way (reformatting the base package’s source):

```
instance (Monoid a, Monoid b) => Monoid (a,b) where
mempty = (mempty, mempty)
(a1,b1) `mappend` (a2,b2) = (a1 `mappend` a2, b1 `mappend` b2)
```

Similarly, we can make tuples whose first component is an element of a monoid into an instance of `Applicative`

by accumulating the monoid elements (reformatting the base package’s source):

```
instance Monoid a => Applicative ((,) a) where
pure x = (mempty, x)
(u, f) <*> (v, x) = (u `mappend` v, f x)
```

However, tuples aren’t an instance of `Alternative`

, because they can’t be—the monoidal structure over `Monoid a => (a,b)`

isn’t present for all types `b`

, and `Alternative`

’s monoidal structure must be inner-type agnostic. Not only must `b`

be a monad, to be able to express `(f <> g) <*> a`

, we need to use the `Monoid`

instance for functions, which is for functions of the form `Monoid b => a -> b`

. And even in the case where we have all the necessary monoidal structure, it violates *all four* of the `Alternative`

laws. To see this, let `ssf n = (Sum n, (<> Sum n))`

and let `ssn = (Sum n, Sum n)`

. Then, writing `(<>)`

for `mappend`

, we get the following results (which can be checked in GHCi, with the occasional type annotation):

- Right distributivity:
`(ssf 1 <> ssf 1) <*> ssn 1 = (Sum 3, Sum 4)`

`(ssf 1 <*> ssn 1) <> (ssf 1 <*> ssn 1) = (Sum 4, Sum 4)`

- Right absorption:
`mempty <*> ssn 1 = (Sum 1, Sum 0)`

`mempty = (Sum 0, Sum 0)`

- Left distributivity:
`(<> Sum 1) <$> (ssn 1 <> ssn 1) = (Sum 2, Sum 3)`

`((<> Sum 1) <$> ssn 1) <> ((<> Sum 1) <$> ssn 1) = (Sum 2, Sum 4)`

- Left absorption:
`(<> Sum 1) <$> mempty = (Sum 0, Sum 1)`

`mempty = (Sum 1, Sum 1)`

Next, consider `Maybe`

. As it stands, `Maybe`

’s `Monoid`

and `Alternative`

instances *disagree*. (Although the haskell-cafe discussion I mention at the beginning of this section proposes changing this, there’s an `Option`

newtype from the semigroups package which would produce the same effect.) As a `Monoid`

, `Maybe`

lifts semigroups into monoids by using `Nothing`

as the identity; since the base package doesn’t have a semigroup class, it just lifts monoids, and so we get (reformatting the base package’s source):

```
instance Monoid a => Monoid (Maybe a) where
mempty = Nothing
Nothing `mappend` m = m
m `mappend` Nothing = m
Just m1 `mappend` Just m2 = Just (m1 `mappend` m2)
```

On the other hand, as an `Alternative`

, `Maybe`

represents prioritized choice with failure, and so we get (again reformatting the base package’s source):

```
instance Alternative Maybe where
empty = Nothing
Nothing <|> r = r
l <|> _ = l
```

And it turns out that only the latter satisfies the `Alternative`

laws. The `Monoid`

instance fails less badly than `(,)`

’s; it *does* obey the laws with respect to `<*>`

, although almost by accident—it comes form the behavior of the only instance of `Monoid`

for functions, which (as mentioned above), lifts functions that return monoids into the reader applicative functor. If you work it out (it’s all very mechanical), you’ll find that right distributivity and right absorption for `<*>`

all hold for both the `Alternative`

and `Monoid`

instances, as does left absorption for `fmap`

. And left distributivity for `fmap`

does hold for the `Alternative`

instance, as follows:

```
f <$> (Nothing <|> b)
= f <$> b by the definition of (<|>)
= Nothing <|> (f <$> b) by the definition of (<|>)
= (f <$> Nothing) <|> (f <$> b) by the definition of (<$>)
f <$> (Just a <|> b)
= f <$> Just a by the definition of (<|>)
= Just (f a) by the definition of (<$>)
= Just (f a) <|> (f <$> b) by the definition of (<|>)
= (f <$> Just a) <|> (f <$> b) by the definition of (<$>)
```

However, it fails for the `Monoid`

instance; writing `(<>)`

for `mappend`

, we have:

`(<> Sum 1) <$> (Just (Sum 0) <> Just (Sum 0)) = Just (Sum 1)`

`((<> Sum 1) <$> Just (Sum 0)) <> ((<> Sum 1) <$> Just (Sum 0)) = Just (Sum 2)`

Now, there is one caveat to this example. If you only require that `Alternative`

s be compatibility with `<*>`

, and not with `<$>`

, then `Maybe`

is fine. Edward Kmett’s slides, mentioned above, don’t make reference to `<$>`

, but I think it seems reasonable to require laws with respect to it as well; nevertheless, I can’t find anything to back me up on this.

Thus, we can conclude that being an `Alternative`

is a *stronger* requirement than being a `Monoid`

, and so it requires a different class. The purest example of this would be a type with an inner-type agnostic `Monoid`

instance and an `Applicative`

instance which were incompatible with each other; however, there aren’t any such types in the base package, and I can’t think of any. (It’s possible none exist, although I’d be surprised.) Nevertheless, these inner-type gnostic examples demonstrate why the two type classes must be different.

What’s the point of the `MonadPlus`

type class?

`MonadPlus`

, like `Alternative`

, is a strengthening of `Monoid`

, but with respect to `Monad`

instead of `Applicative`

. According to Edward Kmett in his answer to the question “Distinction between typeclasses `MonadPlus`

, `Alternative`

, and `Monoid`

?”, `MonadPlus`

is *also* stronger than `Alternative`

: the law `empty <*> a`

, for instance, doesn’t imply that `empty >>= f`

. AndrewC provides two examples of this: `Maybe`

and its dual. The issue is complicated by the fact that there are two potential sets of laws for `MonadPlus`

. It is universally agreed that `MonadPlus`

is supposed to form a monoid with `mplus`

and `mempty`

, and it’s supposed to satisfy the *left zero* law, `mempty >>= f = mempty`

. Hhowever, some `MonadPlus`

ses satisfy *left distribution*, `mplus a b >>= f = mplus (a >>= f) (b >>= f)`

; and others satisfy *left catch*, `mplus (return a) b = return a`

. (Note that left zero/distribution for `MonadPlus`

are analogous to right distributivity/absorption for `Alternative`

; `(<*>)`

is more analogous to `(=<<)`

than `(>>=)`

.) Left distribution is probably “better,” so any `MonadPlus`

instance which satisfies left catch, such as `Maybe`

, is an `Alternative`

but not the first kind of `MonadPlus`

. And since left catch relies on ordering, you can imagine a newtype wrapper for `Maybe`

whose `Alternative`

instance is *right*-biased instead of *left*-biased: `a <|> Just b = Just b`

. This will satisfy neither left distribution nor left catch, but will be a perfectly valid `Alternative`

.

However, since any type which *is* a `MonadPlus`

ought to have its instance coincide with its `Alternative`

instance (I believe this is required in the same way that it is required that `ap`

and `(<*>)`

are equal for `Monad`

s that are `Applicative`

s), you could imagine defining the `MonadPlus`

class instead as

```
class (Monad m, Alternative m) => MonadPlus' m
```

The class doesn’t need to declare new functions; it’s just a promise about the laws obeyed by `empty`

and `(<|>)`

for the given type. This design technique isn’t used in the Haskell standard libraries, but is used in some more mathematically-minded packages for similar purposes; for instance, the lattices package uses it to express the idea that a lattice is just a join semilattice and a meet semilattice over the same type which are linked by absorption laws.

The reason you can’t do the same for `Alternative`

, even if you wanted to guarantee that `Alternative`

and `Monoid`

always coincided, is because of the kind mismatch. The desired class declaration would have the form

```
class (Applicative f, forall a. Monoid (f a)) => Alternative''' f
```

but (as mentioned far above) not even GHC Haskell supports quantified constraints.

Also, note that having `Alternative`

as be a superclass of `MonadPlus`

would require `Applicative`

being a superclass of `Monad`

, so good luck getting that to happen. If you run into that problem, there’s always the `WrappedMonad`

newtype, which turns any `Monad`

into an `Applicative`

in the obvious way; there’s an `instance MonadPlus m => Alternative (WrappedMonad m) where ...`

which does exactly what you’d expect.