Your function can't be tail recursive. The reason is that your recursive calls to `insert`

don't end the computation, they're used as a subexpressions, in this case in `new Node(...)`

. For example. if you were just searching for the bottom element, it would easy to make it tail recursive.

**What's happening:** As you're descending the tree down, calling `insert`

on each of the nodes, but you have to remember the way back to the root, since you have to reconstruct the tree after you replace a bottom leaf with your new value.

**A possible solution:** Remember the down path explicitly, not on stack. Let's use a simplified data structure for the example:

```
sealed trait Tree;
case object EmptyTree extends Tree;
case class Node(elem: Int, left:Tree, right:Tree) extends Tree;
```

Now define what a path is: It's a list of nodes together with the information if we went right or left. The root is always at the end of the list, the leaf at the start.

```
type Path = List[(Node, Boolean)]
```

Now we can make a tail recursive function that computes a path given a value:

```
// Find a path down the tree that leads to the leaf where `v` would belong.
private def path(tree: Tree, v: Int): Path = {
@tailrec
def loop(t: Tree, p: Path): Path =
t match {
case EmptyTree => p
case n@Node(w, l, r) =>
if (v < w) loop(l, (n, false) :: p)
else loop(r, (n, true) :: p)
}
loop(tree, Nil)
}
```

and a function that takes a path and a value and reconstructs a new tree with the value as a new node at the bottom of the path:

```
// Given a path reconstruct a new tree with `v` inserted at the bottom
// of the path.
private def rebuild(path: Path, v: Int): Tree = {
@tailrec
def loop(p: Path, subtree: Tree): Tree =
p match {
case Nil => subtree
case (Node(w, l, r), false) :: q => loop(q, Node(w, subtree, r))
case (Node(w, l, r), true) :: q => loop(q, Node(w, l, subtree))
}
loop(path, Node(v, EmptyTree, EmptyTree))
}
```

Inserting is then easy:

```
def insert(tree: Tree, v: Int): Tree =
rebuild(path(tree, v), v)
```

Note that this version isn't particularly efficient. Probably you could make it more efficient using `Seq`

, or even further by using a mutable stack to store the path. But with `List`

the idea can be expressed nicely.

**Disclaimer:** I only compiled the code, I haven't tested it at all.

**Notes:**

- This is a special example of using zippers to traverse a functional tree. With zippers you can apply the same idea on any kind of tree and walk the tree in various directions.
- If you want the tree to be useful for larger sets of elements (which you probably do, if you're getting stack overflows), I'd strongly recommend making it self-balanced. That is, update the structure of the tree so that it's depth is always
*O(log n)*. Then your operations will be fast in all cases, you won't have to worry about stack overflows and you can use your stack-based, non-tail-recursive version. Probably the easiest variant of a self-balancing tree is the AA tree.