I'll sketch an answer and then provide some working source code.
First off, you need an algorithm to hash a tree. We can assume, without loss of generality, that the children of each of your tree's nodes are ordered from least to greatest (or vice versa).
Run this algorithm on every member of ST and save the hashes.
Now, take your test tree T and generate all of its subtrees TP that retain the original root. You can do this (perhaps inefficiently) by:
- Making a set S of its nodes
- Generating the power set P of S
- Generating the subtrees by removing the nodes present in each member of P from copies of T
- Adding those subtrees which retain the original root to TP.
Now generate a set of all of the hashes of TP.
Now check each of your ST hashes for membership in TP.
ST hash storage requires
O(n) space in ST, and possibly the space to hold the trees.
You can optimize the membership code so that it requires no storage space (I have not done this in my test code). The code will require approximately 2**N checks, where N is the number of nodes in T.
So the algorithm runs in
O(H 2**N), where H is the size of ST and N is the number of nodes in T. The best way of speeding this up is to find an improved algorithm for generating the subtrees of T.
The following Python code accomplishes this:
#Generate a hash of a tree by recursively hashing children
children.sort(key=lambda x: tree.get_node(x).tag, cmp=lambda x,y:x-y)
for child in children:
hash = "1"+digester.hexdigest()
hash = "0"+digester.hexdigest()
#Generate a power set of a set
"powerset([1,2,3]) --> () (1,) (2,) (3,) (1,2) (1,3) (2,3) (1,2,3)"
s = list(iterable)
return itertools.chain.from_iterable(itertools.combinations(s, r) for r in range(len(s)+1))
#Generate all the subsets of a tree which still share the original root
#by using a power set of all the tree's nodes to remove nodes from the tree
nodes=[x.identifier for x in tree.nodes.values()]
for s in powerset(nodes):
for n in s:
if len([x.identifier for x in culled_tree.nodes.values()])>0:
#Generate a member of ST
treeA = treelib.Tree()
#Generate a member of ST
treeB = treelib.Tree()
#Generate hashes for members of ST
hashes=[(HashTree(tree), tree) for tree in ST]
#Generate a test tree
#Generate all the subtrees of this tree which still retain the original root
#Hash all of the subtrees
Thashes=set([HashTree(x) for x in Tsets])
#For each member of ST, check to see if that member is present in the test
for hash in hashes:
if hash in Thashes:
print [x for x in hash.expand_tree()]