One option would be to create a specific data type for your use case, with the additional advantage of having proper names for things.

Another would be to create a specialized `* -> *`

tuples as:

```
newtype FTuple4 fa fb fc fd r = FTuple4 (fa r, fb r, fc r, fd r)
deriving (Eq, Ord, Show)
```

So the tuple is homogeneous in values, but heterogeneous in functors.
Then you can define

```
instance (Functor fa, Functor fb, Functor fc, Functor fd) =>
Functor (FTuple4 fa fb fc fd) where
fmap f (FTuple4 (a, b, c, d)) =
FTuple4 (fmap f a, fmap f b, fmap f c, fmap f d)
```

and

```
main = let ft = FTuple4 (Just 1,
[1,2,3],
Nothing,
Right 4 :: Either String Int)
in print $ fmap (+ 1) ft
```

With this approach, you can pattern match on the result easily, without losing information about the types of the individual elements, their order etc. And, you can have similar instances for `Foldable`

, `Traversable`

, `Applicative`

etc.

Also you don't need to implement the `Functor`

instance yourself, you can use GHC's deriving extensions, so all you need to write to get all the instances is is just

```
{-# LANGUAGE DeriveFunctor, DeriveFoldable, DeriveTraversable #-}
import Data.Foldable
import Data.Traversable
newtype FTuple4 fa fb fc fd r = FTuple4 (fa r, fb r, fc r, fd r)
deriving (Eq, Ord, Show, Functor, Foldable, Traversable)
```

And even this can be further automated for arbitrary length using Template Haskell.

The advantage of this approach is mainly in the fact that it just wraps ordinary tuples, so you can seamlessly switch between `(,,,)`

and `FTuple4`

, if you need.

Another alternative, without having your own data type, would be to use nested functor products, since what you're describing is just a product of 4 functors.

```
import Data.Functor.Product
main = let ft = Pair (Just 1)
(Pair [1,2,3]
(Pair Nothing
(Right 4 :: Either String Int)
))
(Pair a (Pair b (Pair c d))) = fmap (+ 1) ft
in print (a, b, c, d)
```

This is somewhat verbose, but you can do much better by creating your own functor product using type operators:

```
{-# LANGUAGE TypeOperators, DeriveFunctor #-}
data (f :*: g) a = f a :*: g a
deriving (Eq, Ord, Show, Functor)
infixl 1 :*:
main = let a :*: b :*: c :*: d = fmap (+ 1) $ Just 1 :*:
[1,2,3] :*:
Nothing :*:
(Right 4 :: Either String Int)
in print (a, b, c, d)
```

This gets probably as terse and universal as possible.

`data (f :+: g) a = FLeft (f a) | FRight (g a)`

. Then`l :: [Maybe :+: []]`

, and you have to tag the elements of`l`

with`FLeft`

or`FRight`

depending on which functor they are. It's a bit messy, but the power is there. – luqui Jul 5 at 20:07`IFunctor`

on`Maybe`

etc in C# because it doesn't have higher-kinded types: joeduffyblog.com/2008/11/04/longing-for-higherkinded-c – Ganesh Sittampalam Jul 5 at 20:50