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Given several vectors/sets, each of which contains multiple integer numbers which are different within one vector. Now I want to check, whether there exists a set which is composed by extracting only one element from each given vectors/sets, in the same time the extracted numbers are nonidentical from each other.

For example, given sets a, b, c, d as:

a <- (1,3,5); 
b <- (3,6,8); 
c <- (2,3,4); 
d <- (2,4,6)

I can find out sets like (1, 8, 4, 6) or (3, 6, 2, 4) ..... actually, I only need to find out one such set to prove the existence.

applying brutal force search, there can be maximal m^k combinations to check, where m is the size of given sets, k is the number of given sets.

Are there any cleverer ways? Thank you!

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Can I assume these things: 1) that each set is sorted, 2) there cannot be more than, say 100, elements in each set, 3) and there cannot be more than, say 10, sets? –  Nawaz Feb 15 '12 at 17:55
    
Thanks Nawaz. Yes, it doesn't hurt to make such assumption in the beginning. –  ulyssis2 Feb 15 '12 at 18:11
    
The only thing I can think of is reducing the problem set by short-circuiting the combnation generation. So, if you have a 2 don't try any combos in the next set that contains 1, 2, and/or 3. If you chose 3 in set "a" then all combo generation which are generated using 3 in set "b" would be elimated. It won't reduce the O(m^k) but it will reduce the actual runtime. –  Justin Feb 15 '12 at 18:27

1 Answer 1

up vote 10 down vote accepted

You can reformulate your problem as a matching in a bipartite graph:

  • the node of the left side are your sets,
  • the node of the right side are the integer appearing in the sets.

There is an edge between a "set" node and an "integer" node if the set contains the given integer. Then, you are trying to find a matching in this bipartite graph: each set will be associated to one integer and no integer will be used twice. The running time of a simple algorithm to find such a matching is O(|V||E|), here |V| is smaller than (m+1)k and |E| is equal to mk. So you have a solution in O(m^2 k^2). See: Matching in bipartite graphs.

Algorithm for bipartite matching:

The algorithm works on oriented graphs. At the beginning, all edges are oriented from left to right. Two nodes will be matched if the edge between them is oriented from right to left, so at the beginning, the matching is empty. The goal of the algorithm is to find "augmenting paths" (or alternating paths), i.e. paths that increase the size the matching.

An augmenting path is a path in the directed graph starting from an unmatched left node and ending at an unmatched right node. Once you have an augmenting path, you just have to flip all the edges along the path to one increment the size of the matching. (The size of the matching will be increased because you have one more edge not belonging to the matching. This is called an alternating path because the path alternate between edges not belonging to the matching, left to right, and edges belonging to the matching, right to left.)

Here is how you find an augmenting path:

  1. all the nodes are marked as unvisited,
  2. you pick an unvisited and unmatched left node,
  3. you do a depth first search until you find an unmatched right node (then you have an augmenting path). If you cannot find an unmatched right node, you go to 2.

If you cannot find an augmenting path, then the matching is optimal.

Finding an augmenting path is of complexity O(|E|), and you do this at most min(k, m) times, since the size of best matching is bounded by k and m. So for your problem, the complexity will be O(mk min(m, k)).

You can also see this reference, section 1., for a more complete explanation with proofs.

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thanks Edouard, it is a brilliant idea! but could you please tell me what algorithm can be used? I know it is awkward to ask for concrete algorithm, but I am really not familiar with matching in graph theory. Thanks. –  ulyssis2 Feb 15 '12 at 22:41
    
I edited my answer to add the description of an algorithm for bipartite matching. –  Edouard Feb 16 '12 at 0:38

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