# Why does the 2-tuple Functor instance only apply the function to the second element?

``````import Control.Applicative

main = print \$ fmap (*2) (1,2)
``````

produces `(1,4)`. I would expect it it to produce `(2,4)` but instead the function is applied only to the second element of the tuple.

Update I've basically figured this out almost straight away. I'll post my own answer in a minute..

Let me answer this with a question: Which output do you expect for:

``````main = print \$ fmap (*2) ("funny",2)
``````

You can have something as you want (using `data Pair a = Pair a a` or so), but as `(,)` may have different types in their first and second argument, you are out of luck.

Pairs are, essentially, defined like this:

``````data (,) a b = (,) a b
``````

The `Functor` class looks like this:

``````class Functor f where
fmap :: (a -> b) -> f a -> f b
``````

Since the types of function arguments and results must have kind `*` (i.e. they represent values rather than type functions that can be applied further or more exotic things), we must have `a :: *`, `b :: *`, and, most importantly for our purposes, `f :: * -> *`. Since `(,)` has kind `* -> * -> *`, it must be applied to a type of kind `*` to obtain a type suitable to be a `Functor`. Thus

``````instance Functor ((,) x) where
-- fmap :: (a -> b) -> (x,a) -> (x,b)
``````

So there's actually no way to write a `Functor` instance doing anything else.

One useful class that offers more ways to work with pairs is `Bifunctor`, from `Data.Bifunctor`.

``````class Bifunctor f where
bimap :: (a -> b) -> (c -> d) -> f a c -> f b d
bimap f g = first f . second g

first :: (a -> b) -> f a y -> f b y
first f = bimap f id

second :: (c -> d) -> f x c -> f x d
second g = bimap id g
``````

This lets you write things like the following (from `Data.Bifunctor.Join`):

``````  newtype Join p a =
Join { runJoin :: p a a }

instance Bifunctor p => Functor (Join p) where
fmap f = Join . bimap f f . runJoin
``````

`Join (,)` is then essentially the same as `Pair`, where

``````data Pair a = Pair a a
``````

Of course, you can also just use the `Bifunctor` instance to work with pairs directly.

• Why is `-- fmap :: (a -> b) -> (y,x,a) -> (y,x,b)` not working for 3-tuples? – Dmitri Zaitsev Dec 26 '16 at 9:03
• @DmitriZaitsev It would, if you defined a `Functor` instance for `((,,) x y)`. `(x,y)` and `(x,y,z)` are very different (families of) types, as there is no single "tuple" type (family). – chepner Jun 1 '18 at 14:29

The `Functor` instance is actually from the GHC.Base module which is imported by `Control.Applicative`.

Trying to write the instance I want, I can see that it won't work, given the definition of tuples; the instance requires just one type parameter, while the 2-tuple has two.

A valid `Functor` instance would at least have to be on tuples, `(a,a)` that have the same type for each element, but you cannot do anything sneaky, like define the instance on:

`````` type T2 a = (a,a)
``````

because instance types aren't permitted to be synonyms.

The above restricted 2-tuple synonym is logically the same as the type:

``````data T2 a = T2 a a
``````

which can have a Functor instance:

``````instance Functor T2 where
fmap f (T2 x y) = T2 (f x) (f y)
``````

As Gabriel remarked in the comments, this can be useful for branching structures or concurrency.

• Actually, that IS useful as an instance of the functor class. For example, I can define a tree as `type Tree a = Free T2 a`. In fact, most uses of that type (in its capacity as a functor) involve branching or concurrency of some sort. – Gabriel Gonzalez Nov 18 '12 at 18:35
• It's worth mentioning that if you want to specify which part of the tuple to map over, you can use `Control.Lens`. A `Setter` is like a `Functor` instance that you specify explicitly, so `over _1 (+1) (5,3)` ==> `(6,3)`; `over _2 (*2) ("funny,2)` ==> `("funny",4)`; `over both length ("hi","there")` ==> `(2,5)`; `over (both._1) (*10) ((1,2),(3,4))` ==> `((10,2),(30,4))`. – shachaf Nov 19 '12 at 0:01
• thanks @shachaf, that's a helpful comment. – Peter Hall Nov 19 '12 at 9:06
• You can also use arrows if you want to run it on the first element or second element: `first` and `second`. – CMCDragonkai May 4 '15 at 7:00
• @CMCDragonkai, I would much prefer the simpler `Bifunctor` versions of those functions in this case; it's easier to understand and generalizes in what I think is probably a more common direction. – dfeuer Jan 4 '16 at 23:19