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This question is for a program I am trying to write which involves connecting chains of physical parts together. I believe I have distilled it down into the simplest form of the question. I would also appreciate if someone knows any additional words that describe this problem, as about 30 min of searching for related questions hasn't even turned up a name for this problem.

You have N vectors. If you choose one value from each vector and do not allow any repeats, you will have one permutation of the type I am trying to find. What is a pseudo-code algorithm to find all of them without brute forcing?

You have the vectors

v1=[1 2]   v2=[1 2 3]   v3=[1 2 3 4]  

(Edit note: The nesting of the vectors is unintentional and cannot be leveraged in the algorithm.) You pick values from each of the vectors and don't allow repeats.

Value 1 is from v1 ---> 2
Value 2 is from v2 ---> 1   
Value 3 is from v3 ---> 4

Resulting permutation is [2 1 4].

This is one allowable permutation. Here is an example of a permutation that is not allowed because it repeats.

Value 1 is from v1 ---> 2
Value 2 is from v2 ---> 1
Value 3 is from v3 ---> 2    

Resulting permutation is [2 1 2], which is invalid due to repeats.

What is an algorithm to find all valid permutations?

Bonus points if you can calculate how many permutations there are before calculating them.

I'll be sure to post back if I can come up with an answer before anyone else can.

share|improve this question
Could you provide a short example of inputs and desired result? – MBo Sep 11 '12 at 4:31
Definitely. Edited the question to provide an example. – Shaun Sep 11 '12 at 4:52
up vote 4 down vote accepted

The example you give has nested vectors, meaning that the entries in v_i are a subset of those in v_{i+1}. If this is indeed the general case for your application, then the number of solutions is simply:

n_1 * (n_2 - 1) * ... * (n_k - (k-1))

where n_i is the length of v_i and there are k nested vectors.

As far as algorithms are concerned, if you want to generate all possible solutions, then I cannot see a better way than to choose from each successive vector after eliminating already selected entries.

If you aren't nested, a good way to visualize this problem is as a Marriage Problem in the following sense. Make k vertices corresponding to the given k vectors

v_1  v_2 ...  v_k

and another m vertices corresponding to the distinct entries of the combined vectors

a_1 a_2 ... a_m

Then connect a_i to v_j if and only if a_i appears in v_j. The goal is to find a maximum matching between the vs and the as that touches all of the v's. That is, choose k edges so that each v_i is an endpoint of exactly one edge.

Any of the standard algorithms, e.g. using augmented paths, will work to find one solution or generate them all.

share|improve this answer
PengOne, the nesting of the vectors was unintentional. Regardless, I think I have to study the marriage problem link you supply so that I can understand the rest of your response which addresses the unnested case. I think this may be some next-level business of the type that mere mortal mechanical engineers like myself find daunting. Will return to this in 20 hours or so and see if I can understand and respond. Thanks for your efforts. – Shaun Sep 11 '12 at 5:31
@Shaun Read a bit on matchings in the wikipedia article, but the easiest is to make a simple example, even with the nested example you gave. This really does boil down to matchings, so eventually you'll need to know about those. Luckily and unluckily, there is a great deal of literature on the subject. There are also well-known algorithms to solve these problems. – PengOne Sep 11 '12 at 5:34
Thanks man I will look into this. – Shaun Sep 11 '12 at 5:37
OK, wow, this graph theory stuff seems to relate very highly to the "chains of physical parts" program that I mention I am trying to attack in the question. It also seems like interesting stuff just for general engineering knowledge. Thanks again. – Shaun Sep 11 '12 at 5:50
Further research indicates that the graph that you suggest constructing from the a_is and v_js is a bipartite graph. I am going to look for algorithms which will find all maximum matchings of a bipartite graph which satisfy the condition of touching all v_js. – Shaun Sep 12 '12 at 0:45

I think you can solve this problem incrementally. Let s1, s2, s3,..,sk be the solutions involving v1, v2, .., vn. Now with vn+1 for every current solution si and element j (j in vn+1), see if j is already in si, if not then add it to your new collection (corresponding to n+1).

  1. Initialize S={ {j} for j in v1 }
  2. For n=2..m:
    1. newS = {}
    2. for j in vn
      1. for s in S
        1. if j not in s add sU{j} to newS S = newS
  3. return S
share|improve this answer
Thanks for your response. I'm not following the part about vn+1. Why would I want to add new vectors to chose from? The vn vectors are part of the problem definition which I am picturing as unchanging. Sorry, I really did read your code closely, but I still am not following. Thanks for your response, though. – Shaun Sep 11 '12 at 5:24
@Shaun What I am saying is if s is a solution to (v1, v2, .., vn), and t is an element of vn+1, we can just check if t is in s, if not, sU{t} is a solution to (v1, v2, ..., vn+1) – ElKamina Sep 12 '12 at 3:44
What is vn+1? What function is U{t}? – Shaun Sep 12 '12 at 16:47

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