# Tree Traversal in Haskell

Here is a peice of code to traverse a tree which is not working:

data Tree = Leaf Int | Node Int Tree Tree deriving Show

preorder(Leaf n) = [n]
preorder(Node n t0 t1) = [n] ++ (preorder t0) ++ (preorder t1)

inorder(Leaf n) = [n]
inorder(Node n t0 t1) = (inorder t0) ++ [n] ++ (inorder t1)

postorder(Leaf n) = [n]
postorder(Node n t0 t1) = (postorder t0) ++ (postorder t1) ++ [n]

I have been asked to execute the following:

Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6))

When I execute the above statement it returns back as it is, when it should return:

preorder t = [8,3,5,2,1,9,6]

inorder t = [5,3,2,8,9,1,6]

postorder t =[5,2,3,9,6,1,8]

How can I fix this?

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I don't quite understand your problem; postorder (Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6))) gives the expected result, as does applying inorder and postorder to that same tree. –  valderman Feb 22 '12 at 18:52
Asked by whom? Is this a homework? –  n.m. Feb 22 '12 at 18:54
if t = Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6)), this works as expected. –  amindfv Feb 22 '12 at 18:55
Oh! You're literally evaluating Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6)), and getting the same result back. That's data, and you need to give it to a function, to return a new value. –  amindfv Feb 22 '12 at 18:59
Yes, as @amindfv writes, fire up ghci and just type in preorder (Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6))) (and hit ender). This will evaluate the function preorder on this tree. –  danr Feb 22 '12 at 19:32

What you have given:

Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6))

is a value of type Tree. You can give this value a name by creating a binding or definition for it. If you're working in a source file, you can just do

myTree = Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6))

or give it a type signature:

myTree :: Tree  -- this is the type signature
myTree = Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6))

If you're working in the interpreter, ghci, you can use let to create a new definition:

Prelude> let myTree = Node 8 (Node 3 (Leaf 5) (Leaf 2)) (Node 1 (Leaf 9) (Leaf 6))

Your task seems to be to evaluate each of the functions postorder, inorder and preorder when given this tree. If you're in a source file, you'll want to save the result in a definition:

inOrderResult :: [Int]
inOrderResult = inorder myTree

(Note that we passed in myTree as an argument to the function inorder.) And if you're working with ghci, just typing

Prelude> inorder myTree

will print the result to the terminal.

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