I'm trying to find a formal way to think about the space complexity in haskell. I have found this article about the Graph Reduction (GR) technique which seems to me as a way to go. But I'm having problems applying it in some cases. Consider the following example:

Say we have a binary tree:

``````data Tree = Node [Tree] | Leaf [Int]

makeTree :: Int -> Tree
makeTree 0 = Leaf [0..99]
makeTree n = Node [ makeTree (n - 1)
, makeTree (n - 1) ]
``````

and two functions that traverse the tree, one (count1) which streams nicely and the the other one (count2) that creates the whole tree in memory at once; according to the profiler.

``````count1 :: Tree -> Int
count1 (Node xs) = 1 + sum (map count1 xs)
count1 (Leaf xs) = length xs

-- The r parameter should point to the root node to act as a retainer.
count2 :: Tree -> Tree -> Int
count2 r (Node xs) = 1 + sum (map (count2 r) xs)
count2 r (Leaf xs) = length xs
``````

I think I understand how it works in the case of count1, here is what I think happens in terms of graph reduction:

``````count1 \$ makeTree 2
=> 1 + sum \$ map count1 xs
=> 1 + sum \$ count1 x1 : map count1 xs
=> 1 + count1 x1                                + (sum \$ map count1 xs)
=> 1 + (1 + sum \$ map count1 x1)                + (sum \$ map count1 xs)
=> 1 + (1 + sum \$ (count1 x11) : map count1 x1) + (sum \$ map count1 xs)
=> 1 + (1 + count1 x11 + sum \$ map count1 x1)   + (sum \$ map count1 xs)
=> 1 + (1 + count1 x11 + sum \$ map count1 x1)   + (sum \$ map count1 xs)
=> 1 + (1 + 100 + sum \$ map count1 x1)          + (sum \$ map count1 xs)
=> 1 + (1 + 100 + count x12)                    + (sum \$ map count1 xs)
=> 1 + (1 + 100 + 100)                          + (sum \$ map count1 xs)
=> 202                                          + (sum \$ map count1 xs)
=> ...
``````

I think it's clear from the sequence that it runs in constant space, but what changes in case of the count2?

I understand smart pointers in other languages so I vaguely understand that the extra r parameter in count2 function somehow keeps nodes of the tree from beeing destroyed, but I would like to know the exact mechanism, or at least a formal one which I could use in other cases as well.

Thanks for looking.

-
Can you show how you call count2? Your comment indicates that you do something like: let t = makeTree 2 in count2 t t –  Ingo Apr 5 '11 at 13:27
@lngo, yes, here is the code I use for testing. –  Peter Jankuliak Apr 5 '11 at 13:33
You should read a bit about garbage collection. –  sclv Apr 5 '11 at 14:38
The fact that count2 doesn't run in (almost) constant space is not a property of Haskell, but of a particular Haskell implementation. It would be perfectly reasonable to garbage collect the tree even for count2, but it requires the compiler to prove that the first argument to count2 is never reachable. This is a bit tricky. –  augustss Apr 5 '11 at 16:36
@Peter -- the let binding in the harness code shouldn't make a difference to GC. The issue is not if the name is in scope, it is if the object is reachable. Many more details in SPJ's two books: research.microsoft.com/en-us/um/people/simonpj/papers/… –  sclv Apr 5 '11 at 19:05