# Cartesian product of an arbitrary number of sets

Do you know some neat Java libaries that allow you to make cartesian product of two (or more) sets?

For example: I have three sets. One with objects of class Person, second with objects of class Gift and third with objects of class GiftExtension.

The number of sets might vary so I cannot do this in nested foreach loop. Under some conditions my application needs to make a product of Person-Gift pair, sometimes it is triple Person-Gift-GiftExtension, sometimes there might even be sets Person-Gift-GiftExtension-GiftSecondExtension-GiftThirdExtension, etc.

Edit: Previous solutions for two sets removed. See edit history for details.

Here is a way to do it recursively for an arbitrary number of sets:

``````public static Set<Set<Object>> cartesianProduct(Set<?>... sets) {
if (sets.length < 2)
throw new IllegalArgumentException(
"Can't have a product of fewer than two sets (got " +
sets.length + ")");

return _cartesianProduct(0, sets);
}

private static Set<Set<Object>> _cartesianProduct(int index, Set<?>... sets) {
Set<Set<Object>> ret = new HashSet<Set<Object>>();
if (index == sets.length) {
} else {
for (Object obj : sets[index]) {
for (Set<Object> set : _cartesianProduct(index+1, sets)) {
}
}
}
return ret;
}
``````

Note that it is impossible to keep any generic type information with the returned sets. If you knew in advance how many sets you wanted to take the product of, you could define a generic tuple to hold that many elements (for instance `Triple<A, B, C>`), but there is no way to have an arbitrary number of generic parameters in Java.

• I think this is a really great way to deal with Pairs. If he does not know if he might need pairs, triples, quadrupels... then it's not directly fitting, but he could use Pair<Pair<Person,Gift>,GiftExtension> i think. Apr 3, 2009 at 15:03
• The return type should be `Set<List<Object>>`, otherwise you might get sets of different size in the result (because duplicates). Jul 30, 2019 at 11:31
• If I change argument of `cartesianProduct` to ArrayList, the cartesian products is returned by reversed order. I mean, first element of cartesian product will be element of last set given. Why is that? Apr 13, 2020 at 8:25
• How to change the arguments to `ArrayList<ArrayList<Double>>` and return the method in `ArrayList<ArrayList<Double>>` data type? When I do modifications, the ordering of cartesian product changes. Apr 13, 2020 at 9:01
• @MuhammadAshfaq Probably the simplest way is to reorder the output afterwards. Sets don't have ordering, so my method doesn't concern itself at all with order. Apr 13, 2020 at 14:48

This is a pretty old question, but why not use Guava's cartesianProduct?

• Because that was implemented after the question was posted. See stackoverflow.com/a/1723050/600500. Oct 14, 2015 at 19:00
• Currently, this is the easier solution ;) May 4, 2017 at 11:24

The method below creates the cartesian product of a list of list of strings:

``````protected <T> List<List<T>> cartesianProduct(List<List<T>> lists) {
List<List<T>> resultLists = new ArrayList<List<T>>();
if (lists.size() == 0) {
return resultLists;
} else {
List<T> firstList = lists.get(0);
List<List<T>> remainingLists = cartesianProduct(lists.subList(1, lists.size()));
for (T condition : firstList) {
for (List<T> remainingList : remainingLists) {
ArrayList<T> resultList = new ArrayList<T>();
}
}
}
return resultLists;
}
``````

Example:

``````System.out.println(cartesianProduct(Arrays.asList(Arrays.asList("Apple", "Banana"), Arrays.asList("Red", "Green", "Blue"))));
``````

would yield this:

``````[[Apple, Red], [Apple, Green], [Apple, Blue], [Banana, Red], [Banana, Green], [Banana, Blue]]
``````
• would the time complexity for this be O(n)^2 Jan 22, 2017 at 2:06

The number of sets might vary so I cannot do this in nested foreach loop.

Two hints:

• A x B x C = A x (B x C)
• Recursion

Index-based solution

Working with the indices is an alternative that is fast and memory-efficient and can handle any number of sets. Implementing Iterable allows easy use in a for-each loop. See the #main method for a usage example.

``````public class CartesianProduct implements Iterable<int[]>, Iterator<int[]> {

private final int[] _lengths;
private final int[] _indices;
private boolean _hasNext = true;

public CartesianProduct(int[] lengths) {
_lengths = lengths;
_indices = new int[lengths.length];
}

public boolean hasNext() {
return _hasNext;
}

public int[] next() {
int[] result = Arrays.copyOf(_indices, _indices.length);
for (int i = _indices.length - 1; i >= 0; i--) {
if (_indices[i] == _lengths[i] - 1) {
_indices[i] = 0;
if (i == 0) {
_hasNext = false;
}
} else {
_indices[i]++;
break;
}
}
return result;
}

public Iterator<int[]> iterator() {
return this;
}

public void remove() {
throw new UnsupportedOperationException();
}

/**
* Usage example. Prints out
*
* <pre>
* [0, 0, 0] a, NANOSECONDS, 1
* [0, 0, 1] a, NANOSECONDS, 2
* [0, 0, 2] a, NANOSECONDS, 3
* [0, 0, 3] a, NANOSECONDS, 4
* [0, 1, 0] a, MICROSECONDS, 1
* [0, 1, 1] a, MICROSECONDS, 2
* [0, 1, 2] a, MICROSECONDS, 3
* [0, 1, 3] a, MICROSECONDS, 4
* [0, 2, 0] a, MILLISECONDS, 1
* [0, 2, 1] a, MILLISECONDS, 2
* [0, 2, 2] a, MILLISECONDS, 3
* [0, 2, 3] a, MILLISECONDS, 4
* [0, 3, 0] a, SECONDS, 1
* [0, 3, 1] a, SECONDS, 2
* [0, 3, 2] a, SECONDS, 3
* [0, 3, 3] a, SECONDS, 4
* [0, 4, 0] a, MINUTES, 1
* [0, 4, 1] a, MINUTES, 2
* ...
* </pre>
*/
public static void main(String[] args) {
String[] list1 = { "a", "b", "c", };
TimeUnit[] list2 = TimeUnit.values();
int[] list3 = new int[] { 1, 2, 3, 4 };

int[] lengths = new int[] { list1.length, list2.length, list3.length };
for (int[] indices : new CartesianProduct(lengths)) {
System.out.println(Arrays.toString(indices) //
+ " " + list1[indices] //
+ ", " + list2[indices] //
+ ", " + list3[indices]);
}
}
}
``````

Here is an Iterable, which allows you to use a simplified for-loop:

``````import java.util.*;

// I use the well known char and int.
class CartesianIteratorTest {

public static void main (String[] args) {
List <Object> lc = Arrays.asList (new Object [] {'A', 'B', 'C', 'D'});
List <Object> lC = Arrays.asList (new Object [] {'a', 'b', 'c'});
List <Object> li = Arrays.asList (new Object [] {1, 2, 3, 4});
// sometimes, a generic solution like List <List <String>>
// might be possible to use - typically, a mixture of types is
// the common nominator
List <List <Object>> llo = new ArrayList <List <Object>> ();

// Preparing the List of Lists is some work, but then ...
CartesianIterable <Object> ci = new CartesianIterable <Object> (llo);

for (List <Object> lo: ci)
show (lo);
}

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

How is it done? We need an Iterable, to use the simplified for-loop, and an Iterator has to be returned from the Iterable. We return a List of Objects - this could be a Set instead of List, but Set has no indexed access, so it would be a bit more complicated, to implement it with Set instead of List. Instead of a generic solution, Object would have been fine for many purposes, but generics allow for more restrictions.

``````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;
}
}
}
}
``````

The mathematical work is done in the 'get'-method. Think about 2 sets of 10 elements. You have a total of 100 combinations, enumerated from 00, 01, 02, ... 10, ... to 99. For 5 X 10 elements 50, for 2 X 3 elements 6 combinations. The modulo of the sublist size helps to pick one element for each iteration.

Iterable i the least interesting thing here:

``````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);
}
}
``````

To implement Iterable, which allows the for-each kind of loop, we have to implement iterator (), and for Iterator we have to implement hasNext (), next () and remove ().

Result:

``````(A, a, 1, )
(B, a, 1, )
(C, a, 1, )
(D, a, 1, )
(A, b, 1, )
(B, b, 1, )
(C, b, 1, )
(D, b, 1, )
...
(A, a, 2, )
...
(C, c, 4, )
(D, c, 4, )
``````

Here is an `Iterator` that gives the cartesian product of a two-dimensional array, where the arrays components represent the sets from the question (one can always convert actual `Set`s to arrays):

``````public class CartesianIterator<T> implements Iterator<T[]> {
private final T[][] sets;
private final IntFunction<T[]> arrayConstructor;

private int count = 0;
private T[] next = null;

public CartesianIterator(T[][] sets, IntFunction<T[]> arrayConstructor) {
Objects.requireNonNull(sets);
Objects.requireNonNull(arrayConstructor);

this.sets = copySets(sets);
this.arrayConstructor = arrayConstructor;
}

private static <T> T[][] copySets(T[][] sets) {
// If any of the arrays are empty, then the entire iterator is empty.
// This prevents division by zero in `hasNext`.
for (T[] set : sets) {
if (set.length == 0) {
return Arrays.copyOf(sets, 0);
}
}
return sets.clone();
}

@Override
public boolean hasNext() {
if (next != null) {
return true;
}

int tmp = count;
T[] value = arrayConstructor.apply(sets.length);
for (int i = 0; i < value.length; i++) {
T[] set = sets[i];

int index = tmp % radix;

value[i] = set[index];

}

if (tmp != 0) {
// Overflow.
return false;
}

next = value;
count++;

return true;
}

@Override
public T[] next() {
if (!hasNext()) {
throw new NoSuchElementException();
}

T[] tmp = next;
next = null;
return tmp;
}
}
``````

The basic idea is to treat `count` as a multi-radix number (digit `i` has its own radix which equals the length of the `i`'th "set"). Whenever we have to resolve `next` (that is, when `hasNext()` is called and `next` is `null`), we decompose the number into its digits in this multi-radix. These digits are now used as the indices from which we draw elements from the different sets.

Example use:

``````String[] a = { "a", "b", "c"};
String[] b = { "X" };
String[] c = { "r", "s" };

String[][] abc = { a, b, c };

Iterable<String[]> it = () -> new CartesianIterator<>(abc, String[]::new);
for (String[] s : it) {
System.out.println(Arrays.toString(s));
}
``````

Output:

``````[a, X, r]
[b, X, r]
[c, X, r]
[a, X, s]
[b, X, s]
[c, X, s]
``````

If one doesn't like arrays, the code is trivially convertible into using collections.

I guess this is more or less similar to the answer given by "user unknown", only without recursion and collections.

You can get the Cartesian product of an arbitrary number of sets of different types and store it into a set of sets of objects `Set<Set<Object>>` using Java 9 Streams as follows:

Try it online!

``````public static Set<Set<Object>> cartesianProduct(Set<?>... sets) {
// incorrect incoming data
if (sets == null) return Collections.emptySet();
return Arrays.stream(sets)
// non-null and non-empty sets
.filter(set -> set != null && set.size() > 0)
// represent each set element as Set<Object>
.map(set -> set.stream().map(Set::<Object>of)
// Stream<Set<Set<Object>>>
.collect(Collectors.toSet()))
// summation of pairs of inner sets
.reduce((set1, set2) -> set1.stream()
// combinations of inner sets
.flatMap(inner1 -> set2.stream()
// merge two inner sets into one
.map(inner2 -> Stream.of(inner1, inner2)
.flatMap(Set::stream)
.collect(Collectors.toCollection(
// set of combinations
// returns Set<Set<Object>>, otherwise an empty set
.orElse(Collections.emptySet());
}
``````
``````public static void main(String[] args) {
Set<Integer> set1 = Set.of(1, 2, 3);
Set<String> set2 = Set.of("A", "B", "C");
Set<Object> set3 = Set.of(new Time(0));

Set<Set<Object>> sets = cartesianProduct(set1, set2, set3);
// output
sets.forEach(System.out::println);
}
``````

Output:

``````[1, A, 03:00:00]
[1, B, 03:00:00]
[1, C, 03:00:00]
[2, A, 03:00:00]
[2, B, 03:00:00]
[2, C, 03:00:00]
[3, A, 03:00:00]
[3, B, 03:00:00]
[3, C, 03:00:00]
``````

See also: How to create a data structure similar to the cartesian product of three lists of different types?

Yes, there is Functional Java.

For a set `s`:

``````s.bind(P.p2(), s);
``````
• note that fj.data.Set does not have a bind method, but it does have toStream() and iterableSet(Iterable) to convert to/from fj.data.Stream which does have a bind method. Apr 3, 2009 at 22:50

a simple solution, for example, for Integer set should be as follows:

``````void printCombination(List<Set<Integer>> listSet, Set<Integer> combination) {
if (listSet.isEmpty()) {
System.out.println("a combination :" + combination);

return;
}

Set<Integer> intSet = listSet.get(0);
for (Integer it : intSet) {
Set<Integer> combination1 = new HashSet<Integer>();

List<Set<Integer>> listSet1 = new ArrayList<Set<Integer>>();
listSet1.remove(0);
this.printCombination(listSet1, combination1);
}

}
``````

You can apply a simple generator interferace named `Seq` via this library. Unlike Guava's cartesianProduct, the sets/lists/iterables do not need to be within the same generic type bound `B`, all types are welcome. And all you need to do is writing the product as normal nested for-loops.

``````public static void main(String[] args) {
List<String> ls1 = Arrays.asList("a", "b");
List<Integer> ls2 = Arrays.asList(1, 2);
List<Character> ls3 = Arrays.asList('x', 'y');

Seq<String> seq = c -> {
for (String s : ls1) {
for (Integer i : ls2) {
for (Character d : ls3) {
c.accept(s + i + d);
}
}
}
};

System.out.println(seq.toSet());
}
``````

The result would be

``````[a2x, a1y, b1x, b2y, a1x, a2y, b2x, b1y]
``````