### How to understand `Function as Functor`

and `Function as Applicative`

?

First, how to understand function as functor?

We can regard functor as an empty box such as:

```
instance Functor Maybe where
fmap :: (a -> b) -> f a -> f b
fmap f (Just x) = Just (f x)
fmap f Nothing = Nothing
```

there, `Maybe`

type can be seen as an **empty box with one slot** which take a type to generate a concrete type `Maybe a`

. In the `fmap`

function:

- The first parameter is a function, which maps from a to b;
**The second parameter is a value of the type with the slot filled(concrete type), this concrete type is generated by type constructor and has the type ***f a* (*f* is `Maybe`

, so *f a* is `Maybe a`

).

When we implement function functors, for function functors must have two parameters to make a type `a -> b`

, if we want our function functor has exactly one slot, we should first fill a slot, so the type constructor of function functor is ((->) r):

```
instance Functor ((->) r) where
fmap f g = (\x -> f (g x))
```

As the same as the `fmap`

function in `Maybe`

Functor, we should regard the second parameter *g* as a value of a concrete type which is generate by *f* (*f* equals `(->) r`

), so *f a* is `(->) r a`

which can be seen as `r -> a`

. Finally, it is not difficult to understand that the *g x* in the `fmap`

function cannot be seen as `r -> x`

, it is just a function application which can be seen as `(r -> a) x`

, also `(x -> a)`

.

Finally, it is not hard to understand that the <*> function in Applicative function `(->) r`

can be implemented as following:

```
<*> :: f (a -> b) -> f a -> f b
<*> :: (r -> a -> b) -> (r -> a) -> (r -> b)
<&> :: (a -> b) -> (r -> a) -> (r -> b)
f <*> g = \r -> f r (g r)
```

for *g r* will map *r* to *a*, *f r a* will map *r, a* to *b*, so the whole lambda function can be seen as `r -> b`

, also `f b`

. For an instance:

```
((+) <*> (+3)) 5
```

the result is 5 + (5 + 3) = 13.

### How to understand in functions as applicatives, `(+) <$> (+3) <*> (*100) $ 5`

= 508?

We know `(+)`

has type: `Num a, a -> a -> a`

;

We also know `(+3)`

and `(*100)`

has type: `Num r, a, r -> a`

;

`(+) <$> (+3)`

equals `pure (+) <*> (+3)`

, where `:t pure (+)`

equals `Num _, a, _ -> a -> a -> a`

In another words, the `pure (+)`

simply takes a `_`

parameter whatever and return the `+`

operator, the parameter `_`

has no effect on the final return value. `pure (+)`

also maps the return value of function `(+3)`

to a function. Now for

```
f <*> g = \r -> f r (g r)
```

we can apply the operators and get:

```
pure (+) <*> (+3) =
\r -> f r (gr) =
\r -> + (gr) =
\r -> + (r + 3) =
\r x -> x + (r + 3)
```

it has the type `r -> x -> a`

. We then calculate `pure (+) <*> (+3) <*> (*100)`

using the definition of <*>, and get:

```
pure (+) <*> (+3) <*> (*100) =
\r -> f r (gr) =
\r -> (r + 3) + (gr)
\r -> (r + 3) + (r * 100)
```

then we apply this function with parameter 5, we get:

```
(5 + 3) + (5 * 100) = 508
```

we can simply think this applicative style as first to calculate the value after `<$>`

and sum them up with the operator before `<$>`

. In last example, this operator is a binary operator equals `(+)`

, we can replace it with a triple operator `(\x y z -> [x,y,z])`

, so the following equation holds:

```
(\x y z -> [x,y,z]) <$> (+3) <*> (*2) <*> (/2) $ 5 = [8.0,10.0,2.5]
```

`pure (+5)`

discards its first argument, so it's`const (+5) 4 $ (4 * 3)`

or`4 * 3 + 5`

which is consistent with`(+5) . (*3) $ 4`

. Additionally,`f <*> g = \x -> f (g x)`

is of type`(b -> c) -> (a -> b) -> (a -> c)`

which neither typechecks with`pure (+ 5) <*> (* 3) $ 4`

nor the class declaration of`Applicative`

.