I have a question about writing recursive algorithms in a functional style. I will use Scala for my example here, but the question applies to any functional language.

I am doing a depth-first enumeration of an *n*-ary tree where each node has a label and a variable number of children. Here is a simple implementation that prints the labels of the leaf nodes.

```
case class Node[T](label:T, ns:Node[T]*)
def dfs[T](r:Node[T]):Seq[T] = {
if (r.ns.isEmpty) Seq(r.label) else for (n<-r.ns;c<-dfs(n)) yield c
}
val r = Node('a, Node('b, Node('d), Node('e, Node('f))), Node('c))
dfs(r) // returns Seq[Symbol] = ArrayBuffer('d, 'f, 'c)
```

Now say that sometimes I want to be able to give up on parsing oversize trees by throwing an exception. Is this possible in a functional language? Specifically is this possible without using mutable state? That seems to depend on what you mean by "oversize". Here is a purely functional version of the algorithm that throws an exception when it tries to handle a tree with a depth of 3 or greater.

```
def dfs[T](r:Node[T], d:Int = 0):Seq[T] = {
require(d < 3)
if (r.ns.isEmpty) Seq(r.label) else for (n<-r.ns;c<-dfs(n, d+1)) yield c
}
```

But what if a tree is oversized because it is too broad rather than too deep? Specifically what if I want to throw an exception the *n*-th time the `dfs()`

function is called recursively regardless of how deep the recursion goes? The only way I can see how to do this is to have a mutable counter that is incremented with each call. I can't see how to do it without a mutable variable.

I'm new to functional programming and have been working under the assumption that anything you can do with mutable state can be done without, but I don't see the answer here. The only thing I can think to do is write a version of `dfs()`

that returns a view over all the nodes in the tree in depth-first order.

```
dfs[T](r:Node[T]):TraversableView[T, Traversable[_]] = ...
```

Then I could impose my limit by saying `dfs(r).take(n)`

, but I don't see how to write this function. In Python I'd just create a generator by `yield`

ing nodes as I visited them, but I don't see how to achieve the same effect in Scala. (Scala's equivalent to a Python-style `yield`

statement appears to be a visitor function passed in as a parameter, but I can't figure out how to write one of these that will generate a sequence view.)

**EDIT** Getting close to the answer.

Here is an function that returns a `Stream`

of nodes in depth-first order.

```
def dfs[T](r: Node[T]): Stream[Node[T]] = {
(r #:: Stream.empty /: r.ns)(_ ++ dfs(_))
}
```

That is almost it. The only problem is that `Stream`

memoizes all results, which is a waste of memory. I want a traversable view. The following is the idea, but does not compile.

```
def dfs[T](r: Node[T]): TraversableView[Node[T], Traversable[Node[T]]] = {
(Traversable(r).view /: r.ns)(_ ++ dfs(_))
}
```

It gives a "found `TraversableView[Node[T], Traversable[Node[T]]]`

, required `TraversableView[Node[T], Traversable[_]]`

error for the `++`

operator. If I change the return type to `TraversableView[Node[T], Traversable[_]]`

, I get the same problem with the "found" and "required" clauses switched. So there's some magic type variance incantation I haven't lit upon yet, but this is close.