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Lets say that we have a type which has this definition :

data Tree a = Leaf a | Branch [Tree a] deriving (Show,Eq)

What I want to make is a function which will return a Boolean. False if my binary tree contains a Leaf and True if not.

Here is my code :

tester :: Tree a -> Bool
tester (Leaf x) = False
tester (Branch y) = if (Branch (map tester y)) then True else False

I know that the main problem of this is that there is no way to evaluate (Branch (map tester y)) but I really have no idea how to fix it.

I can add a new clause, for example something like this tester (Branch y) = True, but I don't think this is a great idea.

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(Note that if x then True else False can be simplified to x, in all situations.) – huon Sep 8 '12 at 14:04
This isn't a binary tree - a binary tree is a tree whose branches are defined Branch (Tree a) (Tree a) – amindfv Sep 8 '12 at 15:07

tester wasn't a descriptive name, so I called it leafless, and thinking about leafy was much easier.

leafy :: Tree a -> Bool
leafy (Leaf x) = True              -- yup - there's a leafy
leafy (Branch ts) = any leafy ts   -- yes if there are any leaves (recursive)

We just need to negate the result to get what we wanted.

leafless :: Tree a -> Bool
leafless = not.leafy

(any :: (a -> Bool) -> [a] -> Bool and any f xs checks whether any of the elements of the list satisfy the test (predicate) f. It works like or (map f xs).)

You can't (Branch (map tester y)) because the constructor Branch has type [Tree a] -> Tree a but map tester y is of type [Bool], not [Tree a]. You didn't need to write Branch on the right hand side; you've used it correctly on the left hand side to pattern-match against branches - it's not needed any more.

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There is a more idiomatic way to write leafless than writing recursion yourself:

{-# LANGUAGE DeriveFoldable #-}
import qualified Data.Foldable as F

data Tree a = Leaf a | Branch [Tree a] deriving (Show,Eq,F.Foldable)

leafless :: Tree a -> Bool
leafless = F.foldl (\x y -> False) True

Or even shorter:

leafless :: Tree a -> Bool
leafless = null . F.toList

Also, your type of tree is called "Rose Tree" and is already in Data.Tree

share|improve this answer
Note that a branch is defined with a list of nodes, so actually there could be a finite tree whose "tips" were all Branch [] – amindfv Sep 8 '12 at 15:05
Yeah, fixed :) I actually found that out before reading your comment – nponeccop Sep 8 '12 at 15:06
+1 very nice, especially null.toList which is absolutely beautiful. It makes me happy to see such things. I admit I felt I ought to use Foldable but stuck with a recursive solution, and I'll use the excuse that the questioner sounds inexperienced, so I'm allowed to be basic! – AndrewC Sep 8 '12 at 16:09

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