**Answer 1:**

```
(pure f) (pure x, pure y) = (pure x, pure f y)
```

I don't understand what you mean by this line. It looks like nonsense: `pure f`

would be a pair, and you can't apply a pair as if it were a function.

From there, the definition of `pure :: a -> (r, a)`

could depend on what `r`

is.

That is exactly the problem. `r`

is fully general; the instance declaration says `((,) r)`

is a Functor *for all types *`r`

. That means you have to somehow implement a single `pure :: a -> (r, a)`

that works with any type `r`

that a caller might choose. This is impossible because there is no way to conjure up an arbitrary `r`

from thin air.

Or as your quote says:

In particular, there is no way how to define `pure :: a -> (r, a)`

for an arbitrary `r`

.

If you try to do something like

```
pure x = (0 :: Integer, x)
```

you get an error:

```
Couldn't match expected type ‘r’ with actual type ‘Integer’
‘r’ is a rigid type variable bound by
the instance declaration
at ...
```

**Answer 2:**

What would `<*>`

look like for pairs? It would be a function like

```
(<*>) :: (r, a -> b) -> (r, a) -> (r, b)
(r1, f) (r2, x) = (???, f x)
```

But what do you do with the `???`

part? You have to put a value of `r`

there, and fortunately you have some of those available (`r1`

, `r2`

). The problem is that (for arbitrary `r`

) there is no general way to combine two values, so you have to pick one of them.

That's where you run into trouble with the laws:

```
pure id <*> v = v
```

This law says we have to pick `r2`

to preserve `v`

.

```
u <*> pure y = pure ($ y) <*> u
```

Since we have to pick `r2`

in `<*>`

, the right-hand side of this law says the result will contain the `r`

part of `u`

. But that clashes with the left-hand side, which says that we get whatever `r`

was returned by `pure y`

. (`u`

is a completely arbitrary pair so there's no way a fixed value returned by `pure`

is always going to match it.)

So we have a contradiction, meaning we can't even define `<*>`

for `((,) r)`

. Therefore the answer to your second question is "no".

That said, there is a standard `Applicative`

instance for pairs but it requires `r`

to be a `Monoid`

:

```
instance (Monoid r) => Applicative ((,) r) where
pure x = (mempty, x)
(r1, f) (r2, x) = (mappend r1 r2, f x)
```