Please take a look in http://www.cs.yale.edu/homes/hudak/CS429F04/AFPLectureNotes.pdf, which explains how Arrows work in FRP.

2-tuples are used in defining Arrows because it's needed to represent an arrowized function taking 2 arguments.

In FRP, constants and variables are often represented as arrows which ignores its "input", e.g.

```
twelve, eleven :: Arrow f => f p Int
twelve = arr (const 12)
eleven = arr (const 11)
```

Function applications are then turned into compositions (`>>>`

):

```
# (6-) 12
arr (6-) <<< twelve
```

Now how do we turn a 2-argument function into an arrow? For instance

```
(+) :: Num a => a -> a -> a
```

due to currying we may treat this as a function returning a function. So

```
arr (+) :: (Arrow f, Num a) => f a (a -> a)
```

now let's apply it to a constant

```
arr (+) -- # f a (a -> a)
<<< twelve -- # f b Int
:: f b (Int -> Int)
+----------+ +-----+ +--------------+
| const 12 |----> | (+) | == | const (+ 12) |
+----------+ +-----+ +--------------+
```

hey wait, it doesn't work. The result is still an arrow that returns a function, but we expect something akin to `f Int Int`

. **We notice that currying fails in Arrow because only composition is allowed.** Therefore we must *uncurry* the function first

```
uncurry :: (a -> b -> c) -> ((a, b) -> c)
uncurry (+) :: Num a => (a, a) -> a
```

Then we have the arrow

```
(arr.uncurry) (+) :: (Num a, Arrow f) => f (a, a) a
```

The 2-tuple arises because of this. Then the bunch functions like `&&&`

are needed to deal with these 2-tuples.

```
(&&&) :: f a b -> f a d -> f a (b, d)
```

then the addition can be correctly performed.

```
(arr.uncurry) (+) -- # f (a, a) a
<<< twelve -- # f b Int
&&& eleven -- # f b Int
:: f b a
+--------+
|const 12|-----.
+--------+ | +-----+ +----------+
&&&====> | (+) | == | const 23 |
+--------+ | +-----+ +----------+
|const 11|-----'
+--------+
```

(Now, why don't we need things like `&&&&`

for 3-tuples for functions having 3 arguments? Because a `((a,b),c)`

can be used instead.)

Edit: From John Hughes's original paper *Generalising Monads to Arrows*, it states the reason as

## 4.1 Arrows and Pairs

However, even though in case of monads the operators `return`

and `>>=`

are all we need to begin writing useful code, for arrows the analogous operators `arr`

and `>>>`

are not sufficient. Even the simple monadic addition function that we saw earlier

```
add :: Monad m => m Int -> m Int -> m Int
add x y = x >>= \u -> (y >>= \v -> return (u + v))
```

cannot yet be expressed in an arrow form. Making dependence on an input explicit, we see that an analogous definition should take the form

```
add :: Arrow a => a b Int -> a b Int -> a b Int
add f g = ...
```

where we must combine `f`

and `g`

in sequence. The only sequencing operator available is `>>>`

, but `f`

and `g`

do not have the right types to be composed. Indeed, the `add`

function needs to *save the input* of type `b`

across the computation of `f`

, so as to be able to supply the same input to `g`

. Likewise the result of `f`

must be saved across the computation of `g`

, so that the two results can eventually be added together and returned. The arrow combinators so far introduced give us no way to save a value across another computation, and so we have no alternative but to introduce another combinator.