Obtaining powerset of a set in java

The powerset of {1, 2, 3} is:

{{}, {2}, {3}, {2, 3}, {1, 2}, {1, 3}, {1, 2, 3}, {1}}

Lets say I have a Set in Java...

Set<Integer> mySet = new HashSet<Integer>();
Set<Set<Integer>> powerSet = getPowerset(mySet);

What I want is the function getPowerset, with the best possible order of complexity.
(I think it might be O(2^n) )

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Surely you are joking Mr. SLaks! –  João Silva Nov 4 '09 at 0:19
@JG: No, I'm not. Unless he's doing homework, I can't imagine why one would need a powerset. –  SLaks Nov 4 '09 at 1:00
Suppose you have a set of configurations -- say "A", "B" and "C" --, that can be used to parametrize a model, and you want to see which subset yields the best result -- e.g. just "A". A possible solution would be to test each member of the powerset. –  João Silva Nov 4 '09 at 21:41
Exactly mister JG –  Manuel Aráoz Nov 5 '09 at 4:01
It's a Google interview question for software developers. It's a contrived problem to test your agility of mind. –  Eric Leschinski May 15 '12 at 21:32
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Yes, it is O(2^n) indeed, since you need to generate, well, 2^n possible combinations. Here's a working implementation, using generics and sets:

public static <T> Set<Set<T>> powerSet(Set<T> originalSet) {
Set<Set<T>> sets = new HashSet<Set<T>>();
if (originalSet.isEmpty()) {
return sets;
}
List<T> list = new ArrayList<T>(originalSet);
Set<T> rest = new HashSet<T>(list.subList(1, list.size()));
for (Set<T> set : powerSet(rest)) {
Set<T> newSet = new HashSet<T>();
}
return sets;
}

And a test, given your example input:

Set<Integer> mySet = new HashSet<Integer>();
for (Set<Integer> s : SetUtils.powerSet(mySet)) {
System.out.println(s);
}
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Would it be faster to use Iterator instead of using list? E.g.: Set<T> rest = new HashSet<T>(originalSet); Iterator<T> i = rest.iterator(); T head = i.next(); i.remove(); ? –  Dimath Jan 12 at 21:51
this is based on the 'side effect' that addAll ignores empty sets –  Cosmin Vacaroiu Sep 18 at 22:32

Manuel,

Actually, I've written code that does what you're asking for in O(1). The question is what you plan to do with the Set next. If you're just going to call size() on it, that's O(1), but if you're going to iterate it that's obviously O(2^n).

contains() would be O(n), etc.

Do you really need this?

EDIT: This code is now available in Guava.

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I need to iterate over every subset –  Manuel Aráoz Nov 5 '09 at 4:02
But do you need to store every subset? –  finnw Nov 5 '09 at 13:10
What if I just want the powersets with exactly k elements? Is your code efficient for that? –  Eyal Dec 2 at 17:11

Here is a tutorial describing exactly what you want, including the code. You're correct in that the complexity is O(2^n).

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Isn't complexity (n*2^n)? Because binary string is of length n, and in each iteration of the main loop we iterate the entire binary string. –  Maggie Sep 17 at 5:53

Here's a solution where i use a generator, the advantage being, the entire power set is never stored at once...so you can iterate over it one-by-one without needing it to be stored in memory, i'd like to think it's a better option...Note the Complexity is the same O(2^n) but the memory requirements reduce (assuming the Garbage Collector Behaves! ;) )

/**
*
*/
package org.mechaevil.util.Algorithms;

import java.util.BitSet;
import java.util.Iterator;
import java.util.Set;
import java.util.TreeSet;

/**
* @author st0le
*
*/
public class PowerSet<E> implements Iterator<Set<E>>,Iterable<Set<E>>{
private E[] arr = null;
private BitSet bset = null;

@SuppressWarnings("unchecked")
public PowerSet(Set<E> set)
{
arr = (E[])set.toArray();
bset = new BitSet(arr.length + 1);
}

@Override
public boolean hasNext() {
return !bset.get(arr.length);
}

@Override
public Set<E> next() {
Set<E> returnSet = new TreeSet<E>();
for(int i = 0; i < arr.length; i++)
{
if(bset.get(i))
}
//increment bset
for(int i = 0; i < bset.size(); i++)
{
if(!bset.get(i))
{
bset.set(i);
break;
}else
bset.clear(i);
}

return returnSet;
}

@Override
public void remove() {
throw new UnsupportedOperationException("Not Supported!");
}

@Override
public Iterator<Set<E>> iterator() {
return this;
}

}

To call it use this pattern

Set<Character> set = new TreeSet<Character> ();
for(int i = 0; i < 5; i++)

PowerSet<Character> pset = new PowerSet<Character>(set);
for(Set<Character> s:pset)
{
System.out.println(s);
}

It's from my Project Euler Library... :)

-

I was looking for a solution that wasn't a huge as the ones posted here. Despite being fairly old, figured I'd post the code I just wrote. This targets java 7, so it will require a handful of pastes for versions 5 and 6.

Set<Set<Object>> powerSetofNodes(Set<Object> orig) {
Set<Set<Object>> powerSet = new HashSet<>(), runSet = new HashSet<>(),
thisSet = new HashSet<>();
while(powerSet.size() < (Math.pow(2, orig.size())-1)) {
if(powerSet.isEmpty()) {
for(Object o : orig) {
Set<Object> s = new TreeSet<>();
}
continue;
}
for(Object o : orig) {
for(Set<Object> s : runSet) {
Set<Object> s2 = new TreeSet<>();
}
}
runSet.clear();
thisSet.clear();
}
return powerSet;

Here's some example code to test:

Set<Object> hs = new HashSet<>();
for(Set<Object> s : powerSetofNodes(hs)) {
System.out.println(Arrays.toString(s.toArray()));
}
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One way without recursion is the following: Use a binary mask and make all the possible combinations.

public HashSet<HashSet> createPowerSet(Object[] array)
{
HashSet<HashSet> powerSet=new HashSet();

for(int i=0;i<Math.pow(2, array.length);i++)
{
HashSet set=new HashSet();
{
}

}

return powerSet;
}

{
boolean carry=false;

{
carry=true;
}
else

{
{
carry=false;
}
else
break;

}

}
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The following solution is borrowed from my book "Coding Interviews: Questions, Analysis & Solutions":

Some integers in an array are selected that compose a combination. A set of bits is utilized, where each bit stands for an integer in the array. If the i-th character is selected for a combination, the i-th bit is 1; otherwise, it is 0. For instance, three bits are used for combinations of the array [1, 2, 3]. If the first two integers 1 and 2 are selected to compose a combination [1, 2], the corresponding bits are {1, 1, 0}. Similarly, bits corresponding to another combination [1, 3] are {1, 0, 1}. We are able to get all combinations of an array with length n if we can get all possible combinations of n bits.

A number is composed of a set of bits. All possible combinations of n bits correspond to numbers from 1 to 2^n-1. Therefore, each number in the range between 1 and 2^n-1 corresponds to a combination of an array with length n. For example, the number 6 is composed of bits {1, 1, 0}, so the first and second characters are selected in the array [1, 2, 3] to generate the combination [1, 2]. Similarly, the number 5 with bits {1, 0, 1} corresponds to the combination [1, 3].

The Java code to implement this solution looks like below:

public static ArrayList<ArrayList<Integer>> powerSet(int[] numbers) {
ArrayList<ArrayList<Integer>> combinations = new ArrayList<ArrayList<Integer>>();
BitSet bits = new BitSet(numbers.length);
do{
}while(increment(bits, numbers.length));

return combinations;
}

private static boolean increment(BitSet bits, int length) {
int index = length - 1;

while(index >= 0 && bits.get(index)) {
bits.clear(index);
--index;
}

if(index < 0)
return false;

bits.set(index);
return true;
}

private static ArrayList<Integer> getCombination(int[] numbers, BitSet bits){
ArrayList<Integer> combination = new ArrayList<Integer>();
for(int i = 0; i < numbers.length; ++i) {
if(bits.get(i))
}

return combination;
}

The method increment increases a number represented in a set of bits. The algorithm clears 1 bits from the rightmost bit until a 0 bit is found. It then sets the rightmost 0 bit to 1. For example, in order to increase the number 5 with bits {1, 0, 1}, it clears 1 bits from the right side and sets the rightmost 0 bit to 1. The bits become {1, 1, 0} for the number 6, which is the result of increasing 5 by 1.

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I came up with another solution based on @Harry He's ideas. Probably not the most elegant but here it goes as I understand it:

Let's take the classical simple example PowerSet of S P(S) = {{1},{2},{3}}. We know the formula to get the number of subsets is 2^n (7 + empty set). For this example 2^3 = 8 subsets.

In order to find each subset we need to convert 0-7 decimal to binary representation shown in the conversion table below:

If we traverse the table row by row, each row will result in a subset and the values of each subset will come from the enabled bits.

Each column in the Bin Value section corresponds to the index position in the original input Set.

Here my code:

public class PowerSet {

/**
* @param args
*/
public static void main(String[] args) {
PowerSet ps = new PowerSet();
Set<Integer> set = new HashSet<Integer>();
for (Set<Integer> s : ps.powerSet(set)) {
System.out.println(s);
}
}

public Set<Set<Integer>> powerSet(Set<Integer> originalSet) {
// Original set size e.g. 3
int size = originalSet.size();
// Number of subsets 2^n, e.g 2^3 = 8
int numberOfSubSets = (int) Math.pow(2, size);
Set<Set<Integer>> sets = new HashSet<Set<Integer>>();
ArrayList<Integer> originalList = new ArrayList<Integer>(originalSet);
for (int i = 0; i < numberOfSubSets; i++) {
// Get binary representation of this index e.g. 010 = 2 for n = 3
//Get sub-set
Set<Integer> set = getSet(bin, originalList));
}
return sets;
}

//Gets a sub-set based on the binary representation. E.g. for 010 where n = 3 it will bring a new Set with value 2
private Set<Integer> getSet(String bin, List<Integer> origValues){
Set<Integer> result = new HashSet<Integer>();
for(int i = bin.length()-1; i >= 0; i--){
//Only get sub-sets where bool flag is on
if(bin.charAt(i) == '1'){
int val = origValues.get(i);
}
}
return result;
}

//Converts an int to Bin and adds left padding to zero's based on size
private String getPaddedBinString(int i, int size) {
String bin = Integer.toBinaryString(i);
bin = String.format("%0" + size + "d", Integer.parseInt(bin));
return bin;
}

}
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If you're using GS Collections, you can use the powerSet() method on all SetIterables.

MutableSet<Integer> set = UnifiedSet.newSetWith(1, 2, 3);
System.out.println("powerSet = " + set.powerSet());
// prints: powerSet = [[], [1], [2], [1, 2], [3], [1, 3], [2, 3], [1, 2, 3]]

Note: I am a developer on GS collections.

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If S is a finite set with N elements, then the power set of S contains 2^N elements. The time to simply enumerate the elements of the powerset is 2^N, so O(2^N) is a lower bound on the time complexity of (eagerly) constructing the powerset.

Put simply, any computation that involves creating powersets is not going to scale for large values of N. No clever algorithm will help you ... apart from avoiding the need to create the powersets!

-

Some of the solutions above suffer when the size of the set is large because they are creating a lot of object garbage to be collected and require copying data. How can we avoid that? We can take advantage of the fact that we know how big the result set size will be (2^n), preallocate an array that big, and just append to the end of it, never copying.

The speedup grows quickly with n. I compared it to João Silva's solution above. On my machine (all measurements approximate), n=13 is 5x faster, n=14 is 7x, n=15 is 12x, n=16 is 25x, n=17 is 75x, n=18 is 140x. So that garbage creation/collection and copying is dominating in what otherwise seem to be similar big-O solutions.

Preallocating the array at the beginning appears to be a win compared to letting it grow dynamically. With n=18, dynamic growing takes about twice as long overall.

public static <T> List<List<T>> powerSet(List<T> originalSet) {
// result size will be 2^n, where n=size(originalset)
// good to initialize the array size to avoid dynamic growing
int resultSize = (int) Math.pow(2, originalSet.size());
// resultPowerSet is what we will return
List<List<T>> resultPowerSet = new ArrayList<List<T>>(resultSize);

// Initialize result with the empty set, which powersets contain by definition

// for every item in the original list
for (T itemFromOriginalSet : originalSet) {

// iterate through the existing powerset result
// loop through subset and append to the resultPowerset as we go
// must remember size at the beginning, before we append new elements
int startingResultSize = resultPowerSet.size();
for (int i=0; i<startingResultSize; i++) {
List<T> oldSubset = resultPowerSet.get(i);

// create a new element by adding a new item from the original list
List<T> newSubset = new ArrayList<T>(oldSubset);

// add this element to the result powerset (past startingResultSize)
}
}
return resultPowerSet;
}
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If n < 63, which is a reasonable assumption since you'd run out of memory (unless using an iterator implementation) trying to construct the power set anyway, this is a more concise way to do it. Binary operations are way faster than Math.pow() and arrays for masks, but somehow Java users are afraid of them...

List<T> list = new ArrayList<T>(originalSet);
int n = list.size();

Set<Set<T>> powerSet = new HashSet<Set<T>>();

for( long i = 0; i < (1 << n - 1); i++) {
Set<T> element = new HashSet<T>();
for( int j = 0; j < n; j++ )
if( (i >> j) % 2 == 1 ) element.add(list.get(j));