# Every combination of object array

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[] {
people[a],
people[b],
people[c],
people[d],
people[e]
};
}
}
}
}
}
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;

Etc.

I would appreciate any help.

-
smells like homework to me. And a duplicate –  Benjamin Gruenbaum Dec 17 '12 at 14:55
duplicates stackoverflow.com/questions/11162226/… ? –  RC. Dec 17 '12 at 14:56
A Better Link : Very much possible using recursion. Another way is to do is using the property of binary combinations –  Extreme Coders Dec 17 '12 at 15:00

There are many options.

(1)

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

(2)

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.

(3)

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.

-

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) {
System.out.println(combination);
}
``````

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

-
+1 for the library. I'm using it! –  KillBill May 29 at 7:51