How to match a tree against a large set of patterns?

I have a potentially infinite set of symbols: `A, B, C, ...` There is also a distinct special placeholder symbol `?` (its meaning will be explained below).

Consider non-empty finite trees such that every node has a symbol attached to it and 0 or more non-empty sub-trees. The order of sub-trees of a given node is significant (so, for example, if there is a node with 2 sub-trees, we can distinguish which one is left and which one is right). Any given symbol can appear in the tree 0 of more times attached to different nodes. The placeholder symbol `?` can be attached only to leaf nodes (i.e. nodes having no sub-trees). It follows from the usual definition of a tree that trees are acyclic.

The finiteness requirement means that the total number of nodes in a tree is a positive finite integer. It follows that the total number of attached symbols, the tree depth and the total number of nodes in every sub-tree are all finite.

Trees are given in a functional notation: a node is represented by a symbol attached to it and, if there are any sub-trees, it is followed by parentheses containing comma-separated list of sub-trees represented recursively in the same way. So, for example the tree

``````                    A
/ \
?   B
/ \
A   C
/|\
A C Q
\
?
``````

is represented as `A(?,B(A(A,C,Q(?)),C))`.

I have a pre-calculated unchanging set of trees S that will be used as patterns to match. The set will typically have ~ 105 trees, and every its element will typically have ~ 10-30 nodes. I can use a plenty of time to create beforehand any representation of S that will best suit my problem stated below.

I need to write a function that accepts a tree T (typically with ~ 102 nodes) and checks as fast as possible if T contains as a subtree any element of S, provided that any node with placeholder symbol `?` matches any non-empty subtree (both when it appears in T or in an element of S).

Please suggest a data structure to store the set S and an algorithm to check for a match. Any programing language or a pseudo-code is OK.

-
Try researching 'regular tree grammars' and tree automata. –  Antimony Jun 16 '13 at 3:07
@tmyklebu `A(?)` considered as a pattern means a node with the symbol `A` attached that has exactly one sub-tree. So, it does not match `A(B,C)` or `A`, but it would match `A(B)` or `A(B(C,D))`. –  TauMu Jun 16 '13 at 19:22
@jwpat7 I mentioned left and right sub-trees in the case when there is a node with two sub-trees. If a node has only one sub-tree, it does not matter how the sub-tree is positioned on the visual diagram. There are no empty sub-trees — so, no such things as `A(,B)`. The notation `Q(?)` denotes the node `Q` with the single sub-tree consisting of the single node with the placeholder symbol `?`. If considered as a pattern, it matches any tree with the root node `Q` and exactly one non-empty sub-tree of any form, for example, `Q(A)` or `Q(A(B,C(D)))`... –  TauMu Jun 16 '13 at 19:38
@jwpat7 ...But `Q(?)` does not match `Q` (0 sub-trees), `Q(A,B)` (2 sub-trees) or `A(Q)` (wrong symbol at the root). It matches `?` though, because the placeholder `?` stands for any tree, including those placeholder-free trees that could be matched by `Q(?)`. So, given a mere possibility of a match, we consider the match successful. It could be also perceived that because `?` is a more general (more inclusive) pattern than `Q(?)`, the match is effectively performed in the other direction (i.e. `?` matches any tree including `Q(?)`). Sorry, I did not explained this last point in my question. –  TauMu Jun 16 '13 at 19:48
@jwpat7 ...I think, a more clear explanation would be that in case when both a 'pattern' tree (an element of S) and a 'data' tree T contain placeholders `?`, the match is considered successful iff there exist a placeholder-free tree that could be successfully matched by both 'pattern' and 'data' trees (in other words, when the patterns overlap). –  TauMu Jun 16 '13 at 20:16

This paper describes a variant of the Aho–Corasick algorithm, where instead of using a finite state machine (which the standard Aho–Corasick algorithm uses for string matching) the algorithm instead uses a pushdown automaton for subtree matching. Like the Aho-Corasick string-matching algorithm, their variant only requires one pass through the input tree to match against the entire dictionary of S.

The paper is quite complex - it may be worth it to contact the author to see if he has any source code available.

-
+1. On inspection of this paper, it appears to match OP's requirements better than my suggestion. –  Ira Baxter Jun 16 '13 at 4:42