# Using continuation to transform binary recursion to tail recursion

As I'm reading the Programming F# book, I found the example code snippet on page 195 as follows:

``````type ContinuationStep<'a> =
| Finished
| Step of 'a * (unit -> ContinuationStep<'a>)

let iter f binTree =
let rec linearize binTree cont =
match binTree with
| Empty -> cont()
| Node(x, l, r) ->
Step(x, (fun () -> linearize l (fun() -> linearize r cont)))

let steps = linearize binTree (fun () -> Finished)

let rec processSteps step =
match step with
| Finished -> ()
| Step(x, getNext)
-> f x
processSteps (getNext())

processSteps steps
``````

By using continuation, the binary recursion of traversing a binary has been transformed to tail-recursive function `processSteps`. My question is that the other function, `linearize` seems to be non-tail-recursive. Does that mean we are not able to transform a binary-recursion to a tail-recursion completely even using continuation?

-

The example is a bit subtle because it does not use ordinary continuations, but instead builds a structure that can be evaluated step-by-step. In a place where you would normally make a recursive call, it returns a value `Step` that contains the function that you'd (recursively) call.

In the second case, the `linearize` function returns a `Step` containing a function that will call `linearize` recursively, but it does not immediately make the recursive call. So the function does not make a recursive call (it just stores a recursive reference).

It only makes sense to consider whether the program is tail-recursive when you look at `processSteps`, because that does the actual looping - and that is tail-recursive, because it runs a `Step` by `Step` without keeping stack space for each `Step`.

If you wanted to construct a list instead of a chain of lazy steps then you'd have to make the recursive call to `linearize` immediately inside the continuation:

``````let rec linearize binTree cont =
match binTree with
| Empty -> cont []
| Node(x, l, r) ->
linearize l (fun l -> linearize r (fun v -> cont (x::v)))
``````

This is essentially the same as the previous function, but it actually calls `linearize` instead of building `Step` containing a function that will call `linearize`.

-
`linearize` is tail-recursive: you don't need to come back from the recursive call to continue the computation.
``````fun () -> linearize l (fun() -> linearize r cont)
doesn't call `linearize`. The computation is suspended until `processSteps` calls `getNext ()`.