How can I flatten a nested list like this:
[1, 2, 3, 4] == flatten [[[1,2],[3]],[[4]]]
Since nobody else has given this, it is possible to define a function which will flatten lists of an arbitrary depth by using MultiParamTypeClasses. I haven't actually found it useful, but hopefully it could be considered an interesting hack. I got the idea from Oleg's polyvariadic function implementation.
{-# LANGUAGE MultiParamTypeClasses, OverlappingInstances, FlexibleInstances #-}
module Flatten where
class Flatten i o where
flatten :: [i] -> [o]
instance Flatten a a where
flatten = id
instance Flatten i o => Flatten [i] o where
flatten = concatMap flatten
Now if you load it and run in ghci:
*Flatten> let g = [1..5]
*Flatten> flatten g :: [Integer]
[1,2,3,4,5]
*Flatten> let h = [[1,2,3],[4,5]]
*Flatten> flatten h :: [Integer]
[1,2,3,4,5]
*Flatten> let i = [[[1,2],[3]],[],[[4,5],[6]]]
*Flatten> :t i
i :: [[[Integer]]]
*Flatten> flatten i :: [Integer]
[1,2,3,4,5,6]
Note that it's usually necessary to provide the result type annotation, because otherwise ghc can't figure out where to stop recursively applying the flatten
class method. If you use a function with a monomorphic type that's sufficient however.
*Flatten> :t sum
sum :: Num a => [a] -> a
*Flatten> sum $ flatten g
<interactive>:1:7:
No instance for (Flatten Integer a0)
arising from a use of `flatten'
Possible fix: add an instance declaration for (Flatten Integer a0)
In the second argument of `($)', namely `flatten g'
In the expression: sum $ flatten g
In an equation for `it': it = sum $ flatten g
*Flatten> let sumInt = sum :: [Integer] -> Integer
*Flatten> sumInt $ flatten g
15
*Flatten> sumInt $ flatten h
15
OverlappingInstances
extension allows something roughly approximating the ability to pattern match on type constructors, with the caveat that cases are chosen by specificity, not order of definition. It's a pretty "straightforward" bit of scary type-level metaprogramming hackery, and occasionally actually useful. Recursing through nested (->)
s allows variadic functions, or with nested tuples stuff like heterogenous lists. It's all very enjoyable.
– C. A. McCann
May 13 '11 at 16:39
where
helper function with no signature you might get some confusing things happening), and also that it interacts poorly with polymorphism (as in the notes at the end of the post). If you really want to understand its issues, just try to use it wherever you thought you needed it. You will learn. ;)
– luqui
Aug 7 '16 at 5:43
Yes, it’s concat
from the Standard Prelude, given by
concat :: [[a]] -> [a]
concat xss = foldr (++) [] xss
If you want to turn [[[a]]]
into [a]
, you must use it twice:
Prelude> (concat . concat) [[[1,2],[3]],[[4]]]
[1,2,3,4]
As others have pointed out, concat :: [[a]] -> [a]
is the function you are looking for, and it can't flatten nested lists of arbitrary depth. You need to call it multiple times to flatten it down to the desired level.
The operation does generalize to other monads, though. It is then known as join
, and has the type Monad m => m (m a) -> m a
.
Prelude Control.Monad> join [[1, 2], [3, 4]]
[1,2,3,4]
Prelude Control.Monad> join (Just (Just 3))
Just 3
Prelude Control.Monad.Reader> join (+) 21
42
(+)
is a -> a -> a
which is the same as a -> (a -> a)
one more step: (a->) ( (a->) a )
, do you see the similarity between this and [[a]]
which is the same as [] ([] a)
?
– enobayram
Jan 5 '16 at 8:46
import Data.List
let flatten = intercalate []
flatten $ flatten [[[1,2],[3]],[[4]]]
[1,2,3,4]
As hammar pointed out, join
is the "monadic" way to flatten a list. You can use the do
-Notation as well to write easily flatten functions of several levels:
flatten xsss = do xss <- xsss
xs <- xss
x <- xs
return x
An arbitrarily nested list can be approximated by a Data.Tree
, which can be flattened by the appropriately named function flatten
.
I say approximated because Data.Tree
allows a data item to be attached to every node, not just the leaves. However, you could create a Data.Tree (Maybe a)
, and attach Nothing
to the body nodes, and flatten with catMaybes . flatten
.
You can remove one level of nesting using concat
, and consequently you can apply n levels of nesting by applying concat
n times.
It is not possible to write a function which removes an arbitrary level of nestings, as it is not possible to express the type of a function, which takes an arbitrarily nested list and returns a flat list, using Haskell's type system (using the list datatype that is - you can write your own datatype for arbitrarily nested lists and write a flatten function for that).