Define a proper functor to wrap your tuples.

```
data Three a = Three {getThree :: (a, a, a)} deriving (Show, Functor)
```

If you don't want to use the `DeriveFunctor`

extension, the definition is simple:

```
instance Functor Three where
fmap f (Three (x, y, z)) = Three (f x, f y, f z)
```

Then you can simply define `plusOne`

as

```
>>> plusOne = let f = getThree . fmap (+1) . Three in fmap (fmap f)
```

where `f`

is a function that wraps a 3-tuple, maps `(+1)`

over each element, and unwraps the result. This gets mapped over your list of lists:

```
> x = [[(1, 2, 3), (4,5,6)], [(7,8,9)]]
> plusOne x
[[(2,3,4),(5,6,7)],[(8,9,10)]]
```

You can also use `Data.Functor.Compose`

to eliminate one of the levels of `fmap`

(or, at least hide it behind another set of names to break up the monotony):

```
> getCompose . fmap (getThree . fmap (+1) . Three) . Compose $ x
[[(2,3,4),(5,6,7)],[(8,9,10)]]
```

We've applied the same pattern of wrapping/fmaping/unwrapping twice. We can abstract that away with a helper function

```
-- wrap, map, and unwrap
wmu pre post f = post . fmap f . pre
plusOne = wmu Compose getCompose $ wmu Three getThree $ (+1)
```

One might notice a similarity between `wmu`

and `dimap`

(specialized to `(->)`

):

```
wmu pre post = dimap pre post . fmap
```

Everything is even simpler if you can replace the generic tuple with a custom product type in the first place.

```
data Triplet a = Triplet a a a
-- Can be derived as well
instance Functor Triplet where
fmap f (Triplet x y z) = Triplet (f x) (f y) (f z)
plusOne :: [[Triplet Int]] -> [[Triplet Int]]
plusOne = fmap (fmap (fmap (+1)))
```

`plusOne = map (map (+1))`

? – arrowd Oct 12 at 6:53`String`

is a type for`[Char]`

. – Elmex80s Oct 12 at 7:31`(+1)`

a 3-tuple, but you can indeed use`map (map f)`

for a suitable`f`

. – chi Oct 12 at 13:34