Basically, I have an array containing 25 different people, I need to select 5 of these people and have every single combination possible, without using duplicates of the same person.

The only logical way I can think of doing it is by having 5 for loops and checking if person has already been used, although this seems like there's probably a better method involving recursion.

If anyone can help I'd be very appreciated.

Here's an example of my class;

public class Calculator {

    final Person[] people = new Person[25]; //Pretend we have filled in this info already

    public List<Group> generateList()
        final List<Group> possible = new ArrayList<>();
        for (int a = 0; a < 25; a++)
            for (int b = 0; b < 25; b++)
                for (int c = 0; c < 25; c++)
                    for (int d = 0; d < 25; d++)
                        for (int e = 0; e < 25; e++)
                            final Group next = new Group();
                            next.set = new Person[] {
        return possible;

    class Group {

        Person[] set = new Person[5];


    class Person {

        String name;
        int age;



However I'm not sure the best way to do this and if that would even get every combination. I also know there's no duplicate checking here, which I'd do by checking;

if(b == a) continue;


I would appreciate any help.


One possibility would be to use a combinatorics library like: http://code.google.com/p/combinatoricslib/.

// Create the initial vector
   ICombinatoricsVector<String> initialVector = Factory.createVector(
      new String[] { "red", "black", "white", "green", "blue" } );

   // Create a simple combination generator to generate 3-combinations of the initial vector
   Generator<String> gen = Factory.createSimpleCombinationGenerator(initialVector, 3);

   // Print all possible combinations
   for (ICombinatoricsVector<String> combination : gen) {

The example is from the project page (see link). It should be pretty easy to transfer it to your use case.


There are many options.


you can improve your algoritghm by using

for a = 0 to 25 
  for b = a+1 to 25  // use ascending-order rule 
    for c = b+1 to 25

etc - this eliminates duplicate checking, taking advantage of the factorial nature of the problem


you can alternatively implement these as a single for loop over the whole N^R items (if you chose R items from N), and discard permutations that are not in full ascending order. This is good if you don't know R beforehand. Imagine you are counting in base N

for i = 0 to N^R // count in base N
  for digit = 0 to R 
    value[digit] = (i/N^digit) mod (N^(digit+1)) // extract the required digit
    if digit>0 && value[digit]<value[digit-1], SKIP  

In other words, you count sequentially on these R indexes.


The final option, which is longer to code but more efficient for large R and N, is to use a set of indices:

// i is an array size R, with items ranging from 0 to N
i = int[]{ 0, 1, 2, 3, 4 }; // each is an index of the items in N

while !finished
    j=0; // index to start incrementing at
    i[j] ++;

then if you go above N on any index, increase j, increment i[j], and set all the i[k<j] to [0 1 2 ... j-1], and start counting again! this cycles most efficiently through all combinations.

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