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For some reason, I am having trouble thinking of a good way to rewrite this function so it uses constant stack space. Most online discussions of tree recursion cheat by using the Fibonacci function and exploiting the properties of that particular problem. Does anyone have any ideas for this "real-world" (well, more real-world than the Fibonacci series) use of recursion?

Clojure is an interesting case since it does not have tail-call optimization, but only tail recursion via the "recur" special form. It also strongly discourages the use of mutable state. It does have many lazy constructs including tree-seq, but I am not able to see how they can help me for this case. Can anyone share some techniques they have picked up from C, Scheme, Haskell, or other programming languages?

(defn flatten [x]
  (let [type (:type x)]
    (cond (or (= type :NIL) (= type :TEXT))
          (= type :CONCAT)
          (doc-concat (flatten (:doc1 x))
                      (flatten (:doc2 x)))
          (= type :NEST)
          (doc-nest (:level x)
                    (flatten (:doc x)))
          (= type :LINE)
          (doc-text " ")
          (= type :UNION)
          (recur (:doc1 x)))))

edit: By request in the comments...

Restated in general terms and using Scheme -- how do I rewrite the following recursion pattern so it doesn't consume stack space or require tail-call optimization of non-self-calls?

(define (frob x)
  (cond ((foo? x)
        ((bar? x)
         (macerate (f x) (frob (g x))))
        ((thud? x)
         (frobnicate (frob (g x))
                     (frob (h x))))))

I chose annoying names to drive home the point that I am looking for answers that don't rely on the algebraic properties of x, macerate, frobnicate, f, g, or h. I just want to rewrite the recursion.


Rich Hickey has kindly added an explicit trampoline function to Clojure.

share|improve this question
i would say "C++" but that would be unhelpful ;-) – Steven A. Lowe Nov 24 '08 at 21:21
it would be easier to help if you explain what does the function do. maybe also using a more common LISP dialect, i myself like to use Scheme at home, but really don't like the look of clojure – Javier Nov 24 '08 at 21:30
I added a Scheme version of the question but I doubt it will be of much help to you. :) – Steven Huwig Nov 24 '08 at 21:43
use continuation passing style, then it's allocated on the heap and not the stack! :) – apg Nov 24 '08 at 21:49
CPS requires tail call optimization. :( – Steven Huwig Nov 24 '08 at 21:50
up vote 6 down vote accepted

Please don't downvote this because it's ugly. I know it's ugly. But it's a way to do it in trampoline-style (no system stack overflow), and without using gotos.

push x,1 on homemade stack
while stack length > 1
  n = pop
  if (n==1)
    x = pop
    if (type(x)==NIL || type(x)==TEXT)
      push x // this is the "return value"
    else if (type(x)==CONCAT)
      push 2 // say call doc-concat
      push doc2(x), 1 // 2nd recursion
      push doc1(x), 1 // 1st recursion
    else if (type(x)==NEST)
      push 3 // say call doc-nest
      push level(x) // push level argument to doc-nest
      push doc(x), 1 // schedule recursion
    else if (type(x)==LINE)
      push " " // return a blank
    else if (type(x)==UNION)
      push doc1(x), 1 // just recur
  else if (n==2)
    push doc-concat(pop, pop) // finish the CONCAT case
  else if (n==3)
    push doc-nest(pop, pop) // finish the NEST case
// final value is the only value on the stack
share|improve this answer
That's very helpful -- thanks. – Steven Huwig Nov 25 '08 at 1:09
You'll probably have to tweak it a bit. – Mike Dunlavey Nov 25 '08 at 1:13
Cleaned it up a bit. – Mike Dunlavey Nov 25 '08 at 1:26
Nice, pseudo-code explanation of trampolining. – Daniel Spiewak Nov 26 '08 at 1:15

The main hurdle to easily transforming your algorithm is that it doesn't result in a sequence of calls to the same function; but alternates between a few ones, each operating on the result of the other.

i'd say you have three alternatives:

  1. totally reformulate the algorithm (that's what the Fibonacci examples do).
  2. combine all functions into a single one with lots of cond's (ugly, and maybe won't result in a real tail-recursion, even with a single function).
  3. turn the flow inside-out: write a single, simple tail-recursive function that transforms the input data into the sequence of operations that have to be performed, and then eval it.
share|improve this answer

If flatten calls itself twice (in the :CONCAT case) how can it be turned into a loop? Maybe I'm missing something. Seems it's inherently a tree-walk.

I mean, there are ways to do a tree-walk without stack, but something has to be unbounded, like if you do it with a FIFO, or as was suggested, with continuations.

share|improve this answer
Unbounded heap is fine -- it's just the StackOverflowError from Java that I want to avoid. – Steven Huwig Nov 24 '08 at 23:42
Well, in that case, you can just make your own stack out of an unbounded list, and turn your routine into a loop. If you want, I'll pseudo-code it in another answer. – Mike Dunlavey Nov 24 '08 at 23:59

The standard general technique is conversion to trampolined style. For your particular problem (implementing prettyprinting combinators) you might find helpful Derek Oppen's 1980 paper "Prettyprinting" (not on the web AFAIK). It presents a stack-based imperative algorithm similar to Wadler's later functional one.

share|improve this answer
Thanks for the citations. I've an ACM DL subscription and Oppen's paper is there. Some light reading for the holidays... – Steven Huwig Nov 25 '08 at 1:07

You could use continuation-passing:

(define (frob0 x k)
  (cond ((foo? x)
         (k x))
        ((bar? x)
         (frob0 (g x) 
           (lambda (y) 
             (k (macerate (f x) y))))
        ((thud? x)
         (frob0 (g x) 
           (lambda (y)
             (frob0 (h x) 
               (lambda (z)
                 (k (frobnicate y z))))))))

(define (frob x)
  (frob0 x (lambda (y) y))

This will not make things easier to understand :-(

share|improve this answer
Yep, typo. Thanks for pointing it out. CPS requires tail-call optimization to work this way -- the calls to (k ...) can stack up. Clojure doesn't do TCO. – Steven Huwig Nov 24 '08 at 23:42
Oops. That's right. This isn't very helpful then. – Chris Conway Nov 25 '08 at 1:25
...except to get more people to complain about the lack of TCO in the JVM. :) – Steven Huwig Nov 25 '08 at 1:51
But, as stated in another comment, you could make this use Trampolined style. It'll be slower since you'll most likely use exceptions for it, but it'd work. – apg Nov 25 '08 at 13:39

The best I can come up with is something like this:

(define (doaction vars action)
  (cond ((symbol=? action 'frob)
         (cond ((foo? (first vars))
                (first vars))
               ((bar? (first vars))
                (doaction (list (f (first vars)) (doaction (g x) 'frob)) 'macerate)

It's not fully tail recursive, but likely the best you can get. TCO is really the way to go. (I understand that Clojure can't have it due to the JVM).

share|improve this answer

The following is not a specific answer to your question, but hopefully it will be a useful example. It replaces multiple recursions (which would otherwise require an unbounded call stack) with a stack of tasks.

(in Haskellish code):

data Tree = Null | Node Tree Val Tree

-- original, non-tail-recursive function: flatten :: Tree -> Result flatten Null = nullval flatten (Node a v b) = nodefunc (flatten a) v (flatten b)

-- modified, tail-recursive code: data Task = A Val Tree | B Result Val

eval :: Tree -> [Task] -> Result use :: Result -> [Task] -> Result

eval Null tasks = use nullval tasks eval (Node a v b) tasks = eval a ((A v b):tasks)

use aval ((A v b):tasks) = eval b ((B aval v):tasks) use bval ((B aval v):tasks) = use (nodefunc aval v bval) tasks use val [] = val

-- actual substitute function flatten2 :: Tree -> Result flatten2 tree = eval tree []

share|improve this answer

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