# Tail recursive function to find depth of a tree in Ocaml

I have a type `tree` defined as follows

``````type 'a tree = Leaf of 'a | Node of 'a * 'a tree * 'a tree ;;
``````

I have a function to find the depth of the tree as follows

``````let rec depth = function
| Leaf x -> 0
| Node(_,left,right) -> 1 + (max (depth left) (depth right))
;;
``````

This function is not tail recursive. Is there a way for me to write this function in tail recursive way?

-
I believe you can if you transform to continuation passing style. –  Jeffrey Scofield Feb 17 '12 at 5:27

## 2 Answers

You can trivially do this by turning the function into CPS (Continuation Passing Style). The idea is that instead of calling `depth left`, and then computing things based on this result, you call `depth left (fun dleft -> ...)`, where the second argument is "what to compute once the result (`dleft`) is available".

``````let depth tree =
let rec depth tree k = match tree with
| Leaf x -> k 0
| Node(_,left,right) ->
depth left (fun dleft ->
depth right (fun dright ->
k (1 + (max dleft dright))))
in depth tree (fun d -> d)
``````

This is a well-known trick that can make any function tail-recursive. Voilà, it's tail-rec.

The next well-known trick in the bag is to "defunctionalize" the CPS result. The representation of continuations (the `(fun dleft -> ...)` parts) as functions is neat, but you may want to see what it looks like as data. So we replace each of these closures by a concrete constructor of a datatype, that captures the free variables used in it.

Here we have three continuation closures: `(fun dleft -> depth right (fun dright -> k ...))`, which only reuses the environment variables `right` and `k`, `(fun dright -> ...)`, which reuses `k` and the now-available left result `dleft`, and `(fun d -> d)`, the initial computation, that doesn't capture anything.

``````type ('a, 'b) cont =
| Kleft of 'a tree * ('a, 'b) cont (* right and k *)
| Kright of 'b * ('a, 'b) cont     (* dleft and k *)
| Kid
``````

The defunctorized function looks like this:

``````let depth tree =
let rec depth tree k = match tree with
| Leaf x -> eval k 0
| Node(_,left,right) ->
depth left (Kleft(right, k))
and eval k d = match k with
| Kleft(right, k) ->
depth right (Kright(d, k))
| Kright(dleft, k) ->
eval k (1 + max d dleft)
| Kid -> d
in depth tree Kid
;;
``````

Instead of building a function `k` and applying it on the leaves (`k 0`), I build a data of type `('a, int) cont`, which needs to be later `eval`uated to compute a result. `eval`, when it gets passed a `Kleft`, does what the closure `(fun dleft -> ...)` was doing, that is it recursively call `depth` on the right subtree. `eval` and `depth` are mutually recursive.

Now look hard at `('a, 'b) cont`, what is this datatype? It's a list!

``````type ('a, 'b) next_item =
| Kleft of 'a tree
| Kright of 'b

type ('a, 'b) cont = ('a, 'b) next_item list

let depth tree =
let rec depth tree k = match tree with
| Leaf x -> eval k 0
| Node(_,left,right) ->
depth left (Kleft(right) :: k)
and eval k d = match k with
| Kleft(right) :: k ->
depth right (Kright(d) :: k)
| Kright(dleft) :: k ->
eval k (1 + max d dleft)
| [] -> d
in depth tree []
;;
``````

And a list is a stack. What we have here is actually a reification (transformation into data) of the call stack of the previous recursive function, with two different cases corresponding to the two different kinds of non-tailrec calls.

Note that the defunctionalization is only there for fun. In pratice the CPS version is short, easy to derive by hand, rather easy to read, and I would recommend using it. Closures must be allocated in memory, but so are elements of `('a, 'b) cont` -- albeit those might be represented more compactly`. I would stick to the CPS version unless there are very good reasons to do something more complicated.

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I think Thomas's answer is a little better, as it is clearer and more efficient. –  Fabrice Le Fessant Feb 17 '12 at 15:02
It all depends on whether the OP is trying to learn how to make a function tail-recursive, or this function. –  gasche Feb 17 '12 at 15:05
The good thing about Reynolds defunctionalization of CPS-converted code is that it recovers, more or less mechanically, the well-known tail-recursive accumulating versions of regular (i.e., with only one kind of recursive call) non-tail-recursive functions, in that the type of reified continuations is invariably isomorphic to the type of lists. –  user593999 Feb 17 '12 at 15:54
@Steve, it is correct that this transformation has the same complexity than the original non-tailrec version -- indeed, it would be just a bit too good to have a general technique to reduce space usage of any recursive function! Yet I'd say that the general motivation for tailrec is rather to save stack space, for implementations that use the C/OS/hardware stack, because it is much more severely restricted than the rest of memory. In the happy cases where you can reduce space complexity, you're actually writing a new, different algorithm. –  gasche Feb 18 '12 at 5:24
That said, the defunctionalized CPS version sometimes help in finding this new space-efficient algorithm: you can sometimes derive this better version by equational reasoning on the CPS-defunctionalized code. If you try for example this technique on the `length : 'a list -> int` function, you'll notice that the resulting `cont` type is isomorphic to integers, and using integers instead directly gives you the constant-memory tailrec version. –  gasche Feb 18 '12 at 5:32

In this case (depth computation), you can accumulate over pairs (`subtree depth` * `subtree content`) to obtain the following tail-recursive function:

``````let depth t =
let rec aux depth = function
| [] -> depth
| (d, Leaf _) :: t -> aux (max d depth) t
| (d, Node (_,left,right)) :: t ->
let accu = (d+1, left) :: (d+1, right) :: t in
aux depth accu in
aux 0 [0, t]
``````

For more general cases, you will indeed need to use the CPS transformation described by Gabriel.

-
Indeed this is a much neater presentation for this particular algorithm. You can actually understand this algorithm as a composition of two techniques: the use of lists is a usual tailrec-ification of a depth-first traversal (one use a FIFO queue of next neighbors for breadth-first traversal, and a LIFO list for depth-first), and the threaded parameter `depth` is a hidden state monad that is used to accumulate information about the result -- a reference would also do the job. –  gasche Feb 17 '12 at 13:34