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Consider a binary tree:

  1. n is a node, if n is an integer
  2. (+ a b) is a node, if a and b are nodes.

We have the following three operations:

  1. (+ a b) -> (+ b a)
  2. (+ (+ a b) c) -> (+ a (+ b c))
  3. (+ a (+ b c)) -> (+ (+ a b) c) -- (2. in reverse)

I need an algorithm for giving all the possible permutations of a given tree using these operations. Any operation maybe applied to any subtree. With a permutation I mean any tree that has the exact same set of leaves. It's probably not very difficult, but I just can't seem to figure it out.

[Edit] The leaves can also be names (i.e. variables), so relying on their properties as integers is not an option. The trees do represent sums.

[Edit2] The point of this excercise is to reduce a sum by finding terms of the form A and -A, swizzling the tree to get them into a subtree (+ A -A) in order to eliminate them. The three operations above are axioms in my system and they need to be used all the way, otherwise it's not possible to prove that the reduced tree is equal to the original. Since I'm using Twelf logic programming language, if I can figure out an algorithm to do what I originally asked, the rest follows easily, but alternative solutions are of course welcome.

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What is offensive in that question? And why is it downvoted? –  Burkhard Mar 16 '09 at 18:24
    
I guess someone's offended by people posting homework. –  chaos Mar 16 '09 at 18:35
    
I assure you, it's not a homework problem. It's for an automated proof system I'm doing. –  TrayMan Mar 16 '09 at 18:36
    
Sorry, didn't realize it had been tagged homework by someone else. –  chaos Mar 16 '09 at 18:40
    
It looks like homework –  fmsf Mar 16 '09 at 18:43

6 Answers 6

Seems like the most straightforward solution would be a depth-first traversal of your tree to collect all of the nodes into a list, generate all of the permutations of list, dump each permutation into binary tree.

So, given the list (+ a (+ b c) ), we have the nodes [a; b; c], which have the following permutations:

[a; b; c]
[a; c; b]
[b; a; c]
[b; c; a]
[c; a; b]
[c; b; a]

The first item in the list is your head, the following two items are the child nodes, the next four items are the child-child nodes, and so on.

The complexity of this increases dramatically if you need produce a list of all possible trees, rather than just balanced ones. In that case, you'd need to group them like this:

[a; b; c; d]
[(a; b); c; d]
[(a; b; c); d]
[a; (b; c); d]
[a; (b; c; d)]
[a; b; (c; d)]
[a; b; d; c]
// first permutation
[(a; b); d; c]
[(a; b; d); c]
...

Where each n-tuple is a set of nodes. For more than a few nodes, the universe will experience a heat-death before your algorithm ever completed.

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I have considered this as a possible solution, however it has certain complications. I'll ellaborate in my question. –  TrayMan Mar 16 '09 at 19:07

The solution to this problem is undoubtably going to include Catalan numbers. There are Cn-1 possible binary trees with n leaves, and there are n! possible orderings of the leaves, so there are n! * Cn-1 possible trees. Enumerating them is slightly trickier, though.

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Fortunately the number of leaves is going to be relatively small. –  TrayMan Mar 16 '09 at 18:57

These operations are analogous to addition with the following properties: closure, associativity, commutativity. For a matching node, each leaves the set of leaves the same, and can be applied in a recursive fashion. To count the permutations of a given node x (in some strange mix of Haskell and F#)

let count x = match x with
  | LeafNode -> 1
  | TreeNode (a,b) -> 2 * count a * count b
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well apparently Haskell + F# = ocaml... because you wrote that. :) –  nlucaroni Mar 16 '09 at 18:50
    
oh yeah! i supposed i forgot the rec declaration, and then its just F# –  eulerfx Mar 16 '09 at 18:51
    
The trees represent sums, however the actual leaves are not all integers. I guess I should've put that up in the question. –  TrayMan Mar 16 '09 at 18:59
    
addition does not imply integers, i was coming from the perspective of group theory and illustrating the analogy of the problem to that of counting within the abelian group, because the said operations satisfy it's properties. –  eulerfx Mar 16 '09 at 19:05
    
Of course. I managed to misread your post. –  TrayMan Mar 16 '09 at 19:19

You have associativity and commutativity, so you can move elements around freely. A practical approach to this problem is something like the following:

  • Comb the tree to one side, you get a list.

  • Sort the list, so that the elements that should cancel out are next to each other.

  • Move the elements into a subtree and cancel.

To get your desired proof you have to build small proofs for these operation which you then combine.

Alternatively you could look up AC-matching.

Trying all permutations as you suggest will just get you a big combinatorical explosion.

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Unfortunately, I cannot have an ordering for the leaves, so sorting is not possible. The number of leaves is small (about 5), which is why I'm not particularly concerned with the 'large' number of permutations. –  TrayMan Mar 17 '09 at 12:11
    
I'm unfamiliar with AC-matching and a cursory look shows that it's related, but I don't see how it applies to this problem. –  TrayMan Mar 17 '09 at 12:35

As pointed out, if you really have the commutativity and associativity axioms, you are best off by just collecting the summands and processing them as a set or a list.

If that's not satisfactory, the next thing is to observe that actually you do not seem to need all the permutations, but you want to rewrite your expressions in order to simplify them. That can be made much more efficient than producing all the permutations!

However, to repeat :), if you ONLY have commutativity and associativity, process the terms in a set.

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It's true that I don't need all the permutations. It just seemed like a simple brute force way of doing it. –  TrayMan Mar 17 '09 at 13:54

I've discovered a solution to the underlying problem of reducing trees:

  1. Find a pair of leaves A and -A from the tree.
  2. a) If A and -A are in the same child, recurse.
  3. b) 'Bubble' A and -A to the top of their respective childs. There are eight possible resulting cases, but they all look something like this (+ (x A) (-A y)). Going from that to (+ (+ x y) (+ A -A)) is easy.

As suggested, another way to do it would be to first convert the tree into a list: (+ A (+ B (+ ...)) X), then find a matching pair A and -A and bring them to top. I suspect that this may produce a longer proof (which is undesirable) than the above algorithm, though I haven't tried it.

Still, I find the original question fascinating and I'd like to try how an algorithm based on that would compare to the above.

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