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I have two arrays of strings, not necessarily of the same length, I want to find all the possible "sets" of combinations between two values from the arrays, without repeats from either array.
For example, given the arrays:
{ "A1", "A2", "A3" }
{ "B1", "B2" }
The result I want is the following sets:
{ ("A1", "B1"), ("A2", "B2") }
{ ("A1", "B1"), ("A3", "B2") }
{ ("A1", "B2"), ("A2", "B1") }
{ ("A1", "B2"), ("A3", "B1") }
{ ("A2", "B1"), ("A3", "B2") }
{ ("A2", "B2"), ("A3", "B1") }

My general direction is to create recursive function that takes as a parameter the two arrays and removes each "chosen" strings at a time, calling itself until either array is empty, however I'm kinda worried about performance issues (I need to run this code on about a 1000 pairs of string arrays).
Can anyone direct my towards an efficient method to do this?

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One of the pairs in the answer is: {("A1", "B1"), ("A2", "B2")}; is this another valid pair, or a duplicate: {("A2", "B2"), ("A1", "B1")} –  C.Evenhuis May 19 '11 at 13:00
What do you mean by "efficient"? Given two arrays of size n and m, n <= m, there will be m*...*(m-n+1) sets. –  YXD May 19 '11 at 13:05
@C.Evenhuis The order between combinations doesn't matter, I just need the unique sets –  JohnoBoy May 19 '11 at 13:06
@Mr E I usually take recursive algorithms with a grain of salt, they can be achieved quickly but can have poor performance, hence my comment –  JohnoBoy May 19 '11 at 13:07
Possibly relevant:… –  Jim Mischel May 19 '11 at 14:02

6 Answers 6

up vote 7 down vote accepted

It might be beneficial to think of the two arrays as sides of a table:

        A1      A2      A3
B1 | B1,A1 | B1,A2 | B1,A3 |
B2 | B2,A1 | B2,A2 | B2,A3 |

This implies a loop nested within another, one loop for the rows and the other for the columns. This will give you the initial set of pairs:

{B1,A1} {B1,A2} {B1,A3} {B2,A1} {B2,A2} {B2,A3}

Then it is a matter of building up the combinations of that initial set. You can visualise the combinations similarly, with the set of pairs for both the rows and columns:

      B1,A1 B1,A2 B1,A3 B2,A1 B2,A2 B2,A3
B1,A1|     |  X  |  X  |  X  |  X  |  X  |
B1,A2|     |     |  X  |  X  |  X  |  X  |
B1,A3|     |     |     |  X  |  X  |  X  |
B2,A1|     |     |     |     |  X  |  X  |
B2,A2|     |     |     |     |     |  X  |
B2,A3|     |     |     |     |     |     |

Again this can be accomplished with a pair of nested loops (hint: your inner loop's range will be determined by the outer loop's value).

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To my understanding, using a pair of nested loops cannot generate the complete set without the assumption that one of the initial two arrays has a length of two. A more sensible manner of solving this problem in general is to use depth-first search. –  Jingjie Zheng Apr 6 at 16:56
Another solution is to fix the order of the smaller array, generate all the permutations of the longer, and make a match with the same index of the two arrays to the length of the smaller array. –  Jingjie Zheng Apr 6 at 17:22
Please see my answer for clarifications. –  Jingjie Zheng Apr 6 at 18:42
@JingjieZheng The two initial arrays can be any length. You can visualise this by adding rows/columns to the table as appropriate. –  Paul Ruane Apr 6 at 19:57

very simple way is

string[] arr = new string[3];
        string[] arr1 = new string[4];
        string[] jointarr = new string[100];

        for (int i = 0; i < arr.Length; i++)
            arr[i] = "A" + (i + 1);

        for (int i = 0; i < arr1.Length; i++)
            arr1[i] = "B" + (i + 1);

        int k=0;
        for (int i = 0; i < arr.Length; i++)
            for (int j = 0; j < arr1.Length; j++)
                jointarr[k] = arr[i] + " " + arr1[j];
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While this will give me all possible string pairs, what I need is the unique combinations of these pairs –  JohnoBoy May 22 '11 at 5:11

Its not quite the same problem, but there's a solution I did to the following question that would probably be a decent start point:

Array of array combinations

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There are lots of questions (and answers) regarding combinations of two lists on this site (see sidebar). Your use case seems only superficially different if I understand it correctly.

Wouldn't it suffice to have a method

IEnumerable<Tuple<string, string>> Combinations(
  IEnumerable<string> list1, 
  IEnumerable<string> list2) {}

(which exists in various forms and sizes already in the 'duplicates') and then use that by following these steps (homework = you fill in the details):

Iterate over all combinations of list 1 & list 2 (using something like the above) and

  • Filter list 1 by the first element of the current combination
  • Filter list 2 by the second element of the current combination
  • Combine the current combination with all possible combinations of the filtered lists (using something like the method above)
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If I understand your problem correctly, all combinations can be derived with:

  • chose 2 different elements {A_i, A_j} from A,
  • chose 2 different elements {B_k, B_l} from B,
  • make 2 combinations with these elements { (A_i, B_k), (A_j, B_l) }, { (A_i, B_l), (A_j, B_k) }.

With all combinations of 2 element subsets from A and B, you get all combinations you are looking for.

There are |A| * (|A| - 1) * |B| * (|B| - 1) / 2 combinations.

Easies implementation is with 4 loops:

for i = 1 ... |A|
  for j = i+1 ... |A|
    for k = 1 ... |B|
      for l = k+1 ... |B|
        make 2 combinations {(A_i, B_k),(A_j, B_l)}, {(A_i, B_l), (A_j, B_k)}
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Your problem is equivalent to the following problem:

Problem Statement:
Given two vectors A with size n, B with size m, where n <= m.
A = [0, 1, 2, ..., n - 1].
B = [0, 1, 2, ..., m - 1].
Find all possible injective and non-surjective mappings from A to B. One possible injective and non-surjective mapping

As the size of A is smaller, in one mapping, the number of correspondences is equal to the size of A, i.e., n.

Then we generate all the possible permutations of B, so that the beginning n elements in each permutation can have an one to one correspondence with the elements in A.

The first several permutations and mappings go as follows: Permutation 1 Permutation 2 Permutation 3 Permutation 4


class Helper {
     * @brief generateArray
     * @param size
     * @return A vector [0, 1, ..., size - 1]
    vector<int> generateArray(int size) {
        vector<int> arr;
        for (int i = 0; i < size; ++i) {
        return arr;

     * @brief generateMatches
     * @param n, cardinality of the vector X, where X = [0,1, ..., n - 1].
     * @param m, cardinality of the vector Y, where Y = [0,1, ..., m - 1].
     * @return All possible injective and non-surjective mappings 
     * from the smaller vector to the larger vector.
    vector<vector<pair<int, int> > > generateMatches(int n, int m) {
        // Deal with n > m. Swap back when generating pairs.
        bool swapped = false;
        if (n > m) {
            swapped = true;
            swap(n, m);
        // Now n is smaller or equal to m
        vector<int> A = generateArray(n);
        vector<int> B = generateArray(m);
        vector<vector<pair<int, int> > > matches;
        // Generate all the permutations of m
        do {
            vector<pair<int, int> > match;
            for (int i = 0; i < n; ++i) {
                pair<int, int> p;
                if (swapped) {
                    // Swap back to the original order.
                    p = make_pair(A[i], B[i]);
                } else {
                    p = make_pair(B[i], A[i]);
                // Generate next permutation.
        } while(next_permutaion(B.begin(), B.end())); 
        return matches;
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