The "neat alternative presentation" for `Applicative`

is based on the following two equivalencies

```
pure a = fmap (const a) unit
unit = pure ()
ff <*> fa = fmap (\(f,a) -> f a) $ ff ** fa
fa ** fb = pure (,) <*> fa <*> fb
```

The trick to get this "neat alternative presentation" for `Applicative`

is the same as the trick for `zipWith`

- replace explicit types and constructors in the interface with things that the type or constructor can be passed into to recover what the original interface was.

```
unit :: f ()
```

Is replaced with `pure`

which we can substitute the type `()`

and the constructor `() :: ()`

into to recover `unit`

.

```
pure :: a -> f a
pure () :: f ()
```

And similarly (though not as straightforward) for substituting the type `(a,b)`

and the constructor `(,) :: a -> b -> (a,b)`

into `liftA2`

to recover `**`

.

```
liftA2 :: (a -> b -> c) -> f a -> f b -> f c
liftA2 (,) :: f a -> f b -> f (a,b)
```

`Applicative`

then gets the nice `<*>`

operator by lifting function application `($) :: (a -> b) -> a -> b`

into the functor.

```
(<*>) :: f (a -> b) -> f a -> f b
(<*>) = liftA2 ($)
```

To find a "neat alternative presentation" for `PtS`

we need to find

- something we can substitute the type
`Void`

into to recover `unit`

- something we can substitute the type
`Either a b`

and the constructors `Left :: a -> Either a b`

and `Right :: b -> Either a b`

into to recover `**`

(If you notice that we already have something the constructors `Left`

and `Right`

can be passed to you can probably figure out what we can replace `**`

with without following the steps I used; I didn't notice this until after I solved it)

### unit

This immediately gets us an alternative to `unit`

for sums:

```
empty :: f a
empty = fmap absurd unit
unit :: f Void
unit = empty
```

### operator

We'd like to find an alternative to `(**)`

. There is an alternative to sums like `Either`

that allows them to be written as functions of products. It shows up as the visitor pattern in object oriented programming languages where sums don't exist.

```
data Either a b = Left a | Right b
{-# LANGUAGE RankNTypes #-}
type Sum a b = forall c. (a -> c) -> (b -> c) -> c
```

It's what you would get if you changed the order of `either`

's arguments and partially applied them.

```
either :: (a -> c) -> (b -> c) -> Either a b -> c
toSum :: Either a b -> Sum a b
toSum e = \forA forB -> either forA forB e
toEither :: Sum a b -> Either a b
toEither s = s Left Right
```

We can see that `Either a b ≅ Sum a b`

. This allows us to rewrite the type for `(**)`

```
(**) :: f a -> f b -> f (Either a b)
(**) :: f a -> f b -> f (Sum a b)
(**) :: f a -> f b -> f ((a -> c) -> (b -> c) -> c)
```

Now it's clear what `**`

does. It delays `fmap`

ing something onto both of its arguments, and combines the results of those two mappings. If we introduce a new operator, `<||> :: f c -> f c -> f c`

which simply assumes that the `fmap`

ing was done already, then we can see that

```
fmap (\f -> f forA forB) (fa ** fb) = fmap forA fa <||> fmap forB fb
```

Or back in terms of `Either`

:

```
fa ** fb = fmap Left fa <||> fmap Right fb
fa1 <||> fa2 = fmap (either id id) $ fa1 ** fa2
```

So we can express everything `PtS`

can express with the following class, and everything that could implement `PtS`

can implement the following class:

```
class Functor f => AlmostAlternative f where
empty :: f a
(<||>) :: f a -> f a -> f a
```

This is almost certainly the same as the `Alternative`

class, except we didn't require that the `Functor`

be `Applicative`

.

### Conclusion

It's just a `Functor`

that is a `Monoid`

for all types. It'd be equivalent to the following:

```
class (Functor f, forall a. Monoid (f a)) => MonoidalFunctor f
```

The `forall a. Monoid (f a)`

constraint is pseudo-code; I don't know a way to express constraints like this in Haskell.

`Void`

in the type of`PtS.unit`

, don't you mean Empty, since it should be a unit for`Either`

? – Dominique Devriese Apr 27 '14 at 7:04`Void`

to represent the empty type. I was confused because the name void in C-like languages corresponds to the unit type, which you write as`()`

. – Dominique Devriese Apr 27 '14 at 7:20