plusOne :: [[(Int, Int, Int)]] -> [[(Int, Int, Int)]]

Given a list of lists of 3-tuples. If I want to iterate through the list and +1 to the Int values, how should I approach this? I'm not sure if this is a scenario where Maps should be used or not.

Can someone point me into the right direction?

  • plusOne = map (map (+1)) ? – arrowd Oct 12 at 6:53
  • Divide and conquer. First write a fun tion to manipulate one list element. Then combine it with a function that manipulates lists. – n.m. Oct 12 at 7:03
  • You might want to introduce a type to make your function signature more readable. For example String is a type for [Char]. – Elmex80s Oct 12 at 7:31
  • @arrowd You can't (+1) a 3-tuple, but you can indeed use map (map f) for a suitable f. – chi Oct 12 at 13:34

Split the functions. The lists are easy; one map each. But tuples don't traverse the way they do in e.g. Python, so they require unpacking to access the elements; this is possible with generic programming but far easier with pattern matching. Tuples can hold fields of varying types, so something like map couldn't access all of them. We can make our own map-analogue for triples specifically:

map3t :: (x -> y) -> (x, x, x) -> (y, y, y)
map3t f (a, b, c) = (f a, f b, f c)

Now we can inspect each level of our type and handle it separately:

op :: Int -> Int
op = (+1)
t3 :: (Int, Int, Int) -> (Int, Int, Int)
t3 = map3t op
lt3 :: [(Int, Int, Int)] -> [(Int, Int, Int)]
lt3 = map t3
llt3 :: [[(Int, Int, Int)]] -> [[(Int, Int, Int)]]
llt3 = map lt3

This is not recursion, although map may be implemented using recursion ( is). Each function calls a different function for the inner level.

Here is an example of a not very generic way of how we can use map to access nested lists,which also can be matched on 3tuples with a lambda function:

fun :: (Num a, Num b, Num c) => [[(a, b, c)]] -> [[(a, b, c)]]
fun xs = map (map(\(x,y,z) -> (x+1,y+1,z+1))) xs

Pros: En easy and understandable oneliner to solve a specific problem

Cons: Not generic for the function applied to the elements, can become fuzzy and out of hand with more complex and bigger input structures.

Mapping with a hard coded function forcing you to make a new map for each operation. So a better way in that case would be to refactor the function itself, ie :

fun2 f xs = map (map(op f)) xs
    op f' (x,y,z) = (f' x,f' y, f' z)

Making op a function to which you can give an operation for the specific type.

Making the signature for the function more generic on the types of operations: (Notice here that we can no longer be sure of the type of x,y,z, which before were numerics (because of the +1 operation) giving us a more generic version of the function, but also making us more responsible of matching the types correctly, no string operations on integers etc.)

fun2 :: (t -> c) -> [[(t, t, t)]] -> [[(c, c, c)]]

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

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

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)))

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