Any recursive function can be be converted to use the heap, rather than the stack, to track the context. The process is called `trampolining`

.

Here's how it could be implemented with Scalaz.

```
object TrampolineUsage extends App {
import scalaz._, Scalaz._, Free._
def quickSort[T: Order](xs: List[T]): Trampoline[List[T]] = {
assert(Thread.currentThread().getStackTrace.count(_.getMethodName == "quickSort") == 1)
xs match {
case Nil =>
return_ {
Nil
}
case x :: tail =>
val (left, right) = tail.partition(_ < x)
suspend {
for {
ls <- quickSort(left)
rs <- quickSort(right)
} yield ls ::: (x :: rs)
}
}
}
val xs = List.fill(32)(util.Random.nextInt())
val sorted = quickSort(xs).run
println(sorted)
val (steps, sorted1) = quickSort(xs).foldRun(0)((i, f) => (i + 1, f()))
println("sort took %d steps".format(steps))
}
```

Of course, you need either a really big structure or a really small stack to have a practical problem with a non-tail-recursive divide and conquer algorithm, as you can handle 2^N elements with a stack depth of N.

http://blog.richdougherty.com/2009/04/tail-calls-tailrec-and-trampolines.html

**UPDATE**

`scalaz.Trampoline`

is a special case of a (much) more general structure, `Free`

. It's defined as `type Trampoline[+A] = Free[Function0, A]`

. It's actually possible to write `quickSort`

more generically, so it is parameterized by the type constructor used in `Free`

. This example shows how this is done, and how you can then use the same code to bind using the stack, the heap, or in concurrently.

https://github.com/scalaz/scalaz/blob/scalaz-seven/example/src/main/scala/scalaz/example/TrampolineUsage.scala