I have built a tree from which I want to collect all the Leaf types:

Branch [] (Branch [0] (Leaf [0,1]) (Branch [0] (Leaf [0,2]) (Branch
[0] (Leaf [0,3]) (Leaf [0])))) (Branch [] (Branch [1] (Leaf [1,2])
(Branch [1] (Leaf [1,3]) (Leaf [1]))) (Branch [] (Branch [2] (Leaf
[2,3]) (Leaf [2])) (Branch [] (Leaf [3]) (Leaf []))))

What I get as a type in GHCI (:t) of the above variable is :

Tree [Int]

The data structure is the following:

data Tree a = Empty | Leaf a | Branch a (Tree a) (Tree a)

I am trying to isolate ONLY the leaves such that I would obtain :

[ [0,1], [0,2] .. [3], [] ]

I've been trying to run a filter on the results, however that doesn't work. I've tried to using the function Data.Foldable.toList, however it pulls all the branches in as well and results in a large list of lists with multiple duplicates and no possibility to tell whether it's a branch or a leaf.

3 Answers 3


Although other approaches exist, probable the easiest one is to use recursion. Here the base cases are Empty and Leaf. In case of an Empty, we return an empty list, in case of a Leaf, we can return a list with one element: the one wrapped in the leaf, so:

leave_elements :: Tree a -> [a]
leave_elements Empty = []
leave_elements (Leaf x) = [x]
leave_elements (Branch ...) = ...

We still need to fill in the Branch case, here we see three elements in the constructor: a, which we can ignore, and the two subtrees. We can recursively call the leave_elements recursively on the subtrees, and append the lists of the data of the leaves of the subtrees. For example:

leave_elements :: Tree a -> [a]
leave_elements Empty = []
leave_elements (Leaf x) = [x]
leave_elements (Branch _ l r) = leave_elements l ++ leave_elements r

For your given sample tree, this produces:

Prelude> leave_elements (Branch [] (Branch [0] (Leaf [0,1]) (Branch [0] (Leaf [0,2]) (Branch [0] (Leaf [0,3]) (Leaf [0])))) (Branch [] (Branch [1] (Leaf [1,2]) (Branch [1] (Leaf [1,3]) (Leaf [1]))) (Branch [] (Branch [2] (Leaf [2,3]) (Leaf [2])) (Branch [] (Leaf [3]) (Leaf [])))))

We can also boost performance by using for instance a tail we pass recursively:

leave_elements :: Tree a -> [a]
leave_elements = go []
    where go tl Empty = tl
          go tl (Leaf x) = (x:tl)
          go tl (Branch _ l r) = go (go tl r) l

Or we can work with Data.DList:

import Data.DList

leave_elements :: Tree a -> [a]
leave_elements = toList . go
    where go Empty = empty
          go (Leaf x) = singleton x
          go (Branch _ l r) = append (go l) (go r)
  • 1
    Extra credit: use Data.DList instead of list append for an asymptotically faster traversal.
    – luqui
    Commented Mar 1, 2018 at 21:31
  • @luqui: I don't think we need to pass DLists per se, we can emulate that with recursively passing a future tail. Commented Mar 1, 2018 at 21:39
  • 2
    yeah same diff. I like DList because it is clearer to me what's going on -- we're just using a different representation of a list. That parameter could be anything; go (go tl r) l is just a way of saying "append" but it's rather obfuscated.
    – luqui
    Commented Mar 1, 2018 at 23:09

A more advanced technique, which saves you the effort of writing and maintaining recursive functions by hand, is to use a generic programming library such as lens's Plated module.

Here's how Plated works: you describe how to identify a value's children - immediate substructures having the same type as the value itself - by writing an instance of the Plated class, and the library's various higher-order functions take care of recursively finding the children's children and so on. In the case of your Tree datatype, only the Branch constructor has children (the left and right children), so those are the only places we apply f.

instance Plated (Tree a) where
    plate f (Branch x l r) = Branch x <$> f l <*> f r
    plate f t = pure t

(If you're willing to derive Data then you don't even have to write plate.)

Plated's universe function can now recursively search a tree's children, and the children's children, and so on, returning a lazy list which yields every node in the tree. It works roughly like this:

universe :: Plated a => a -> [a]
universe t = t : [descendant | child <- toListOf plate t, descendant <- universe child]

So to find all the leaves, you just have to filter this list to search for Leaf constructors.

leaves :: Tree a -> [a]
leaves t = [x | Leaf x <- universe t]

Job done!


As @BenjaminHodgson notes in the comments the following solution is valid, but cannot have a consistent implementation across other typeclasses. For example making Tree an instance of Traversable would result in an implementation of the traverse function that necessarily touches all elements of the Tree. I am leaving this up for learning purposes, but don't use this solution.

Using the Foldable typeclass:

import qualified Data.Foldable as F

instance F.Foldable Tree where
    foldMap f Empty = mempty
    foldMap f (Branch x l r) = foldMap f l `mappend`
                               foldMap f r
    foldMap f (Leaf x) = f x

For your tree:

Prelude> foldr (\x acc -> x: acc) [] tree
  • I downvoted this answer because it is not a good example of a Foldable instance. While it’s not law-breaking per se (because Foldable doesn’t have any laws to speak of), it’s widely agreed upon that a Foldable t instance should pick all of the as out of a t a, not just some of them. Since Tree as written can be made an instance of Traversable, this Foldable instance wouldn’t agree with such a Traversable instance. Commented Mar 3, 2018 at 0:50
  • @BenjaminHodgson Thanks for the feedback - I'm new to Haskell. What's the downside of creating a type that only allows access to some of its data? Wouldn't the Traversable implementation do the same thing (traverse only the leaves)? In other languages data structures that hide some of their data may be unorthodox sometimes but not necessarily a bad idea.
    – Alex
    Commented Mar 3, 2018 at 1:01
  • 1
    That’s a good question. The Traversable instance cannot leave any of the as where they are because of the type of traverse :: (Traversable t, Applicative f) => (a -> f b) -> t a -> f (t b). All of the as in the t must be transformed into bs. Commented Mar 3, 2018 at 1:05
  • Generally speaking, the notion of data hiding is not a bad thing at all. It allows you freedom of choice in the way your datatype is implemented. Haskell programmers use data hiding just as much as the next guy. However hiding values whose type is chosen by the user just doesn’t make sense as an engineering decision: such data must have been supplied by the user in the first place so why hide it? Commented Mar 3, 2018 at 1:08
  • @BenjaminHodgson Good point... Also for the Tree to be traversable it must be a functor, and if it only traversed its leaves it would violate the functor identity law. I'm going to make note of your comments and leave the answer up for posterity. Thanks for the intel!
    – Alex
    Commented Mar 3, 2018 at 2:11

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