# Finding cartesian product in Java

I want to find cartesian product of set of elements. Here's an example

example 1 :
sets :(ab) (bc) (ca)

cartesian product is,

abc aba acc aca bbc bba bcc bca

example 2 :
sets : (zyx) b c

cartesian product is,

zbc ybc xbc

So I am thinking of an algorithm to execute in java which can find cartesian product of particular amount of groups defined at compile time at the start.

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If only everything was that easy!

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+1 Indeed... :-) –  Dirk Jul 3 '11 at 14:59
While this gives the desired result, the poster did ask for an algorithm, not a pre-defined method...also, what if the poster can't use this library? –  Cupcake Jul 3 '11 at 15:30
I think that will be able to solve my problem. Thanx Neil. –  Bhushan Nagaonkar Jul 3 '11 at 15:42
@keoki : ya i did ask for algorithm but I think it will be too complicated for me now...hehe...thanx for so prompt ans –  Bhushan Nagaonkar Jul 3 '11 at 15:43
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import java.util.*;

class CartesianIterator <T> implements Iterator <List <T>> {

private final List <List <T>> lilio;
private int current = 0;
private final long last;

public CartesianIterator (final List <List <T>> llo) {
lilio = llo;
long product = 1L;
for (List <T> lio: lilio)
product *= lio.size ();
last = product;
}

public boolean hasNext () {
return current != last;
}

public List <T> next () {
++current;
return get (current - 1, lilio);
}

public void remove () {
++current;
}

private List<T> get (final int n, final List <List <T>> lili) {
switch (lili.size ())
{
case 0: return new ArrayList <T> (); // no break past return;
default: {
List <T> inner = lili.get (0);
List <T> lo = new ArrayList <T> ();
lo.add (inner.get (n % inner.size ()));
lo.addAll (get (n / inner.size (), lili.subList (1, lili.size ())));
return lo;
}
}
}
}

class CartesianIterable <T> implements Iterable <List <T>> {

private List <List <T>> lilio;

public CartesianIterable (List <List <T>> llo) {
lilio = llo;
}

public Iterator <List <T>> iterator () {
return new CartesianIterator <T> (lilio);
}
}

And test it with your Data:

class CartesianIteratorTest {

public static void main (String[] args) {
List <Character> la = Arrays.asList (new Character [] {'a', 'b'});
List <Character> lb = Arrays.asList (new Character [] {'b', 'c'});
List <Character> lc = Arrays.asList (new Character [] {'c', 'a'});
List <List <Character>> llc = new ArrayList <List <Character>> ();

CartesianIterable <Character> ci = new CartesianIterable <Character> (llc);
for (List<Character> lo: ci)
show (lo);

la = Arrays.asList (new Character [] {'x', 'y', 'z'});
lb = Arrays.asList (new Character [] {'b'});
lc = Arrays.asList (new Character [] {'c'});
llc = new ArrayList <List <Character>> ();

ci = new CartesianIterable <Character> (llc);
for (List<Character> lo: ci)
show (lo);
}

public static void show (List <Character> lo) {
System.out.print ("(");
for (Object o: lo)
System.out.print (o);
System.out.println (")");
}
}

Result:

(abc)
(bbc)
(acc)
(bcc)
(aba)
(bba)
(aca)
(bca)
(xbc)
(ybc)
(zbc)
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A purely functional approach to this can be found in this paper (a "functional pearl")... It might not be easily translatable to Java, though.

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