# JAVA : generating power set with subset length between 3 and a max

Everything is in the title .. =)

I want to create a powerset fastly, only with subset of length between 3 (minimum constant length) and a maximum. This maximum should be 5 most of the times but I want it variable (from 3 to 5,6). The original set may be large. I need to store theses subset for further processing.

I've seen Obtaining a powerset of a set in Java, but here they generate every subset of the power set. I've also seen efficient powerset algorithm for subsets of minimal length , for C#, but I think ,as Adam S said, I will run into low running time performances and memory issues.

I'd like to combine theses ideas into an ideal one for my goal. My last hope would be to generate every subset fastly ( maybe with the algorithm in Guava ) and to iterate over to take only with desired length...but even to read it's ugly ;)

Anyone got ideas ?

-

I borrowed heavily from st0le's answer.

Basically, as I iterated through the bit array that was controlling the set generation, I checked to make sure that the number of bits was between the minimum and maximum.

Here's the code.

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

public class PowerSet<E> implements Iterator<Set<E>>, Iterable<Set<E>> {
private int     minSize;
private int     maxSize;
private E[]     arr     = null;
private BitSet  bset    = null;

@SuppressWarnings("unchecked")
public PowerSet(Set<E> set, int minSize, int maxSize) {
this.minSize = Math.min(minSize, set.size());
this.maxSize = Math.min(maxSize, set.size());

arr = (E[]) set.toArray();
bset = new BitSet(arr.length + 1);

for (int i = 0; i < minSize; i++) {
bset.set(i);
}
}

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

@Override
public Set<E> next() {
Set<E> returnSet = new TreeSet<E>();
// System.out.println(printBitSet());
for (int i = 0; i < arr.length; i++) {
if (bset.get(i)) {
}
}

int count;
do {
incrementBitSet();
count = countBitSet();
} while ((count < minSize) || (count > maxSize));

// System.out.println(returnSet);
return returnSet;
}

protected void incrementBitSet() {
for (int i = 0; i < bset.size(); i++) {
if (!bset.get(i)) {
bset.set(i);
break;
} else
bset.clear(i);
}
}

protected int countBitSet() {
int count = 0;
for (int i = 0; i < bset.size(); i++) {
if (bset.get(i)) {
count++;
}
}
return count;

}

protected String printBitSet() {
StringBuilder builder = new StringBuilder();
for (int i = 0; i < bset.size(); i++) {
if (bset.get(i)) {
builder.append('1');
} else {
builder.append('0');
}
}
return builder.toString();
}

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

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

public static void main(String[] args) {
Set<Character> set = new TreeSet<Character>();
for (int i = 0; i < 7; i++)

PowerSet<Character> pset = new PowerSet<Character>(set, 3, 5);
int count = 1;
for (Set<Character> s : pset) {
System.out.println(count++ + ": " + s);
}
}

}
``````

And here are the test results:

``````1: [A, B, C]
2: [A, B, D]
3: [A, C, D]
4: [B, C, D]
5: [A, B, C, D]
6: [A, B, E]
7: [A, C, E]
8: [B, C, E]
9: [A, B, C, E]
10: [A, D, E]
11: [B, D, E]
12: [A, B, D, E]
13: [C, D, E]
14: [A, C, D, E]
15: [B, C, D, E]
16: [A, B, C, D, E]
17: [A, B, F]
18: [A, C, F]
19: [B, C, F]
20: [A, B, C, F]
21: [A, D, F]
22: [B, D, F]
23: [A, B, D, F]
24: [C, D, F]
25: [A, C, D, F]
26: [B, C, D, F]
27: [A, B, C, D, F]
28: [A, E, F]
29: [B, E, F]
30: [A, B, E, F]
31: [C, E, F]
32: [A, C, E, F]
33: [B, C, E, F]
34: [A, B, C, E, F]
35: [D, E, F]
36: [A, D, E, F]
37: [B, D, E, F]
38: [A, B, D, E, F]
39: [C, D, E, F]
40: [A, C, D, E, F]
41: [B, C, D, E, F]
42: [A, B, G]
43: [A, C, G]
44: [B, C, G]
45: [A, B, C, G]
46: [A, D, G]
47: [B, D, G]
48: [A, B, D, G]
49: [C, D, G]
50: [A, C, D, G]
51: [B, C, D, G]
52: [A, B, C, D, G]
53: [A, E, G]
54: [B, E, G]
55: [A, B, E, G]
56: [C, E, G]
57: [A, C, E, G]
58: [B, C, E, G]
59: [A, B, C, E, G]
60: [D, E, G]
61: [A, D, E, G]
62: [B, D, E, G]
63: [A, B, D, E, G]
64: [C, D, E, G]
65: [A, C, D, E, G]
66: [B, C, D, E, G]
67: [A, F, G]
68: [B, F, G]
69: [A, B, F, G]
70: [C, F, G]
71: [A, C, F, G]
72: [B, C, F, G]
73: [A, B, C, F, G]
74: [D, F, G]
75: [A, D, F, G]
76: [B, D, F, G]
77: [A, B, D, F, G]
78: [C, D, F, G]
79: [A, C, D, F, G]
80: [B, C, D, F, G]
81: [E, F, G]
82: [A, E, F, G]
83: [B, E, F, G]
84: [A, B, E, F, G]
85: [C, E, F, G]
86: [A, C, E, F, G]
87: [B, C, E, F, G]
88: [D, E, F, G]
89: [A, D, E, F, G]
90: [B, D, E, F, G]
91: [C, D, E, F, G]
``````
-
great !! c'est genial ;) Thanks a lot. For now it works very well with small number, i'll try it with bigger =) –  Nikkolasg Mar 19 '13 at 15:30

Please specify if the number of elements are bounded.

For 3 - 5,6 elements an array of indices is feasible, maybe `short[6]`.

For instance with upto 32 element an `int` could hold the set, and one could either:

``````// dumb:
for (int mask = 0; ; ;) {
if (3 <= cardinality && cardinality <= 6) {
...
}
}
``````

For more than 64 elements still maybe BitSet would offer compactness.

The decision here, is bound by easy statistics: how many elements and so on. For the int/long/BitSet solution one could start with a BitSet as this has a nicer API. For instance one can go to the next powerset with equal number of bits by flipping two bits. If one is mathematically inclined, De Bruijn cycles might be interesting.

-
I haven't look further into this solution because i wanted a simple solution first. Now I'm looking for a really fast solution. Would it be possible to use BigInteger from java ? because, there is no known bound on the number of elements. because the method incrementBitSet() is a really slow operation and with integer could just be simplified as += 1 ... In fact, I will try to implement it and give feedback. –  Nikkolasg Apr 23 '13 at 18:56
Pb : biginteger does not have a bitCount method which can return the number of set bit in his representation. I've search for other implementations but didn t find anything useful due to the lack of this function. –  Nikkolasg Apr 23 '13 at 19:29
`bitCount` generally is something like `int bitCount(int n) { return n == 0? 0 : 1 + bitCount(n & (n - 1)); }` but BigInteger does have a bitCount I thought. –  Joop Eggen Apr 24 '13 at 8:02
But in your code above, Integer.bitCount returns the number of "1" bits, whereas in biginteger, it returns the number of bit differing from sign bit. Not the same thing, and i want the first one,which is not implemented in biginteger. –  Nikkolasg Apr 24 '13 at 11:36
You are right, but for positive BigIntegers bitCount is okay. –  Joop Eggen Apr 24 '13 at 12:55