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Given an unknown amount of lists, each with an unknown length, I need to generate a singular list with all possible unique combinations. For example, given the following lists:

X: [A, B, C] 
Y: [W, X, Y, Z]

Then I should be able to generate 12 combinations:

[AW, AX, AY, AZ, BW, BX, BY, BZ, CW, CX, CY, CZ]

If a third list of 3 elements were added, I'd have 36 combinations, and so forth.

Any ideas on how I can do this in Java?
(pseudo code would be fine too)

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1  
This sounds remarkably like a homework problem –  AndrewC Jun 19 '13 at 13:43
    
It wasn't, I had a momentary brain-lapse at work so instead of taking ages figuring this out on my own, I came here :) –  Michael Hillman Jun 20 '13 at 15:49

5 Answers 5

up vote 6 down vote accepted

You need recursion:

Let's say all your lists are in Lists, which is a list of lists. Let Result be the list of your required permutations: Do it like this

void GeneratePermutations(List<List<Character>> Lists, List<String> result, int depth, String current)
{
    if(depth == Lists.size())
    {
       result.add(current);
       return;
     }

    for(int i = 0; i < Lists.get(depth).size(); ++i)
    {
        GeneratePermutations(Lists, result, depth + 1, current + Lists.get(depth).get(i));
    }
}

The ultimate call will be like this

GeneratePermutations(Lists, Result, 0, EmptyString);

I don't know Java very well. The above code is half C++, half C#, half pseudocode. I'd appreciate if someone could edit this for Java.

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It was mostly javaish. I removed the String.add and String.removeLastCharacter but in doing so changed your logic slightly (for the better hopefully). Feel free to revert. –  James Montagne Jun 19 '13 at 13:55
    
After a little editing so that it'd work with Lists of Doubles (I used Strings in my question as I thought it my be easier to explain), this worked perfectly, Thanks! –  Michael Hillman Jun 19 '13 at 14:40

Use the nested loop solution provided by some other answers here to combine two lists.

When you have more than two lists,

  1. Combine the first two into one new list.
  2. Combine the resulting list with the next input list.
  3. Repeat.
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Without recursion unique combinations:

    String sArray[] = new String []{"A", "A", "B", "C"};
    //convert array to list
    List<String> list1 = Arrays.asList(sArray);
    List<String> list2 = Arrays.asList(sArray);
    List<String> list3 = Arrays.asList(sArray);

    LinkedList<List <String>> lists = new LinkedList<List <String>>();

    lists.add(list1);
    lists.add(list2);
    lists.add(list3);

    Set<String> combinations = new TreeSet<String>();
    Set<String> newCombinations;

    for (String s: lists.removeFirst())
        combinations.add(s);

    while (!lists.isEmpty()) {
        List<String> next = lists.removeFirst();
        newCombinations =  new TreeSet<String>();
        for (String s1: combinations) 
            for (String s2 : next) 
              newCombinations.add(s1 + s2);               

        combinations = newCombinations;
    }
    for (String s: combinations)
        System.out.print(s+" ");    
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I don't think you want combinations and newCombinations to be Sets. He didn't specify any sort of uniqueness restrictions. I would just make them both Lists and then I believe it works. –  rliu Jun 19 '13 at 17:17
    
He said "all possible unique combinations". Result will be "AAA, AAA, ABA..." in my case {"A", "A", "B", "C"} after using lists instead of sets. –  Ruslan Ostafiychuk Jun 20 '13 at 6:19
    
Ah you're right. His example made me think he didn't care though since he said "if we add a third list of length 3 then there will be 36" which isn't necessarily true if you care about uniqueness. Oh well, I +1'd already –  rliu Jun 20 '13 at 17:00

This topic came in handy. I've rewritten the previous solution fully in Java and more user friendly. Furthermore, I use collections and generics for more flexibility:

/**
 * Combines several collections of elements and create permutations of all of them, taking one element from each
 * collection, and keeping the same order in resultant lists as the one in original list of collections.
 * 
 * <ul>Example
 * <li>Input  = { {a,b,c} , {1,2,3,4} }</li>
 * <li>Output = { {a,1} , {a,2} , {a,3} , {a,4} , {b,1} , {b,2} , {b,3} , {b,4} , {c,1} , {c,2} , {c,3} , {c,4} }</li>
 * </ul>
 * 
 * @param collections Original list of collections which elements have to be combined.
 * @return Resultant collection of lists with all permutations of original list.
 */
public static <T> Collection<List<T>> permutations(List<Collection<T>> collections) {
  if (collections == null || collections.isEmpty()) {
    return Collections.emptyList();
  } else {
    Collection<List<T>> res = Lists.newLinkedList();
    permutationsImpl(collections, res, 0, new LinkedList<T>());
    return res;
  }
}

/** Recursive implementation for {@link #permutations(List, Collection)} */
private static <T> void permutationsImpl(List<Collection<T>> ori, Collection<List<T>> res, int d, List<T> current) {
  // if depth equals number of original collections, final reached, add and return
  if (d == ori.size()) {
    res.add(current);
    return;
  }

  // iterate from current collection and copy 'current' element N times, one for each element
  Collection<T> currentCollection = ori.get(d);
  for (T element : currentCollection) {
    List<T> copy = Lists.newLinkedList(current);
    copy.add(element);
    permutationsImpl(ori, res, d + 1, copy);
  }
}

I'm using guava library for collections creation.

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for (String s1: list1) {
 for (String s2 : list2) {
   System.out.println(s1 + s2);
 }
}
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