# algebraic data type for tree

I'm trying to build a tree where its children are represented in a list. Each of the children may themselves be subtrees etc. So I go this way --

``````data Children a = NoChildren | Cons a (Children a) deriving (Show, Read, Ord, Eq)
data Tree a = EmptyTree | Node a (Children a) deriving (Show, Read, Ord, Eq)
``````

now i try to create a tree like this

``````let subtree1 = Node 67 NoChildren
let subtree2 = Node 86 NoChildren
let tree1 = Node 83 (subtree1 `Cons` (subtree2 `Cons` NoChildren))
``````

it works fine till subtree2. tree1 is not created. The error thrown is this -

``````<interactive>:96:15:
No instance for (Num (Tree Integer))
arising from the literal `83'
Possible fix: add an instance declaration for (Num (Tree Integer))
In the first argument of `Node', namely `83'
In the expression: Node 81 (subtree1 `Cons` (subtree2 `Cons` NoChildren))
In an equation for `tree1':
tree1 = Node 81 (subtree1 `Cons` (subtree2 `Cons` NoChildren))
``````

I don't understand this error error at all. Why is it complaining that 83 is a literal. subtree1 and subtree2 had literals too and they were fine...

I solved the problem by doing the following

``````data Tree a = EmptyTree | Node a [Tree a] deriving (Show, Read, Ord, Eq)

flatten [] = []
flatten x:xs = x ++ flatten xs

preorder EmptyTree = []
preorder (Node a []) = [a]
preorder (Node a children) = [a] ++ flatten (map preorder children)
``````
-

``````data Children a = NoChildren | Cons a (Children a)
``````

means your `Children a` is isomorphic to `[a]`, and hence your

``````data Tree a = EmptyTree | Node a (Children a)
``````

is isomorphic to

``````data List a = Empty | Nonempty a [a]
``````

which is again isomorphic to `[a]`.

What you want is that the children themselves are `Tree`s, so you should use

``````data Children a = NoChildren | Cons (Tree a) (Children a)
``````

or plain

``````data Tree a = EmptyTree | Node a [Tree a]
``````

The error is because `subtree1` has type `Tree a` for some `a` belonging to `Num` (ditto for `subtree2`). Then when you write

``````tree1 = Node 83 (subtree1 `Cons` (subtree2 `Cons` NoChildren))
``````

the inferred type of `tree1` is `Tree (Tree a)` (for some `a` belonging to `Num`), and hence

``````83 :: Tree a
``````

But there's no `Num` instance for `Tree`s.

-
thanks for the answer and explanation. I had used [Tree a] but it was giving the dreaded "cannot construct the infinite type" error. I resolved that as well. – shashydhar Jan 15 '13 at 19:59
• After defaulting `Num a => a` to `Integer`, `subtree1` and `subtree2` are of type `Tree Integer`.
• Because every element of

``````subtree1 `Cons` (subtree2 `Cons` NoChildren)
``````

has type `Tree Integer`, the resulting structure has type `Children (Tree Integer)`.

• `Node 83` has type `Num a => Children a -> Tree a`. The first argument is of type `Children (Tree Integer)`, as previously mentioned, so the compiler tries to find proof of `Num (Tree Integer)`. That doesn't exist, so type inference fails.
• After the failure, the error is traced back to `83`, because that should have been a `Tree Integer` too, and a literal with type `Num a => a` can't have that type.

The solution here would be either that

• `Children` refers back to `Tree` (`Cons (Tree a) (Children a)` instead of `Cons a (Children a)`), which would make good use of your custom type `Children`, or
• `Tree` should do that by itself (e.g. `Node a (Children (Tree a))` instead of `Node a (Children a)`), which is a much more modular option.

Also note that it's probably better to use the well-known `[]` instead of `Children`, as mentioned by Daniel Fischer.

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