# Finding all the subsets of a set

I need an algorithm to find all of the subsets of a set where the number of elements in a set is `n`.

``````S={1,2,3,4...n}
``````

Edit: I am having trouble understanding the answers provided so far. I would like to have step-by-step examples of how the answers work to find the subsets.

For example,

``````S={1,2,3,4,5}
``````

How do you know `{1}` and `{1,2}` are subsets?

Could Someone help me with a simple function in c++ to find subsets of {1,2,3,4,5}

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The question is pretty vague, do you mean all possible subsets? –  sris Apr 8 '09 at 8:07
The number of subsets isn't n! That is the number of permutations. The number of subsets (cardinality of the power set) is 2^n –  sris Apr 8 '09 at 8:19
D'oh! Just call me homer, too morning early for brain correct working right . . . snzzzzzzzzzzz –  Binary Worrier Apr 8 '09 at 8:24

It's very simple to do this recursively. The basic idea is that for each element, the set of subsets can be divided equally into those that contain that element and those that don't, and those two sets are otherwise equal.

• For n=1, the set of subsets is {{}, {1}}
• For n>1, find the set of subsets of 1,...,n-1 and make two copies of it. For one of them, add n to each subset. Then take the union of the two copies.

Edit To make it crystal clear:

• The set of subsets of {1} is {{}, {1}}
• For {1, 2}, take {{}, {1}}, add 2 to each subset to get {{2}, {1, 2}} and take the union with {{}, {1}} to get {{}, {1}, {2}, {1, 2}}
• Repeat till you reach n
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THANKS BUT I STILL UNABLE TO FIGURE HOW COULD I ADD 2 TO EACH SUBSET AND HOW COULD I TAKE THE UNION...COULD U PLZ DESCRIBE WITH THIS SET {1,2,3,4,5} –  Rahul Vyas Apr 8 '09 at 13:08
Sorry, if you can't figure that out, I can't help you. –  Michael Borgwardt Apr 8 '09 at 13:39
i mean if u tell me ur example in a algorithm or in a c/c++ program. –  Rahul Vyas Apr 8 '09 at 14:36
The real base case should be "The powerset of {} is {{}}." Then the poserset of {n} is {{}} `union` {n}. And so forth. –  Ingo Apr 9 '09 at 8:43
True, but I thought it would be easier to understand this way. –  Michael Borgwardt Apr 9 '09 at 9:47

Too late to answer, but an iterative approach sounds easy here:

1) for a set of n elements, get the value of 2^n. There will be 2^n no.of subsets. (2^n because each element can be either present(1) or absent(0). So for n elements there will be 2^n subsets. )
`Eg. for 3 elements, say {a,b,c}, there will be 2^3=8 subsets`

2) Get a binary representation of 2^n.
`Eg. 8 in binary is 1000`

3) Go from 0 to (2^n - 1). In each iteration, for each 1 in the binary representation, form a subset with elements that correspond to the index of that 1 in the binary representation.

Eg:

``````For the elements {a, b, c}
000 will give    {}
001 will give    {c}
010 will give    {b}
011 will give    {b, c}
100 will give    {a}
101 will give    {a,c}
110 will give    {a, b}
111 will give    {a, b, c}
``````

4) Do a union of all the subsets thus found in step 3. Return.
`Eg. Simple union of above sets!`

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How will your solution handle n > 32 ? as I guess your saveing 2^n in an `int`.No? –  Elad Benda Feb 9 '13 at 12:08
Sorry, I haven't written any code implementing the above, but yeah for n>32 using an int32 would be a problem :). An alternative solution is mentioned above by Michael Borgwardt. –  rgamber Feb 9 '13 at 20:34
We can use a bit array of size n in place of an integer and use that instead if integer to iterate over all subsets.Can post my answer here if anyone is interested. –  Nitin Garg Jan 21 '14 at 5:11

If you want to enumerate all possible subsets have a look at this paper. They discuss different approaches such as lexicographical order, gray coding and the banker's sequence. They give an example implementation of the banker's sequence and discuss different characteristics of the solutions e.g. performance.

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Here, I've explained it in detail. Do upvote, if you like the blogpost.

http://cod3rutopia.blogspot.in/

Any way if you can't find my blog here is the explanation.

Its a problem which is recursive in nature.

Essentially for an element to be present in a subset there are 2 options:

1)It is present in the set

2)It is absent in the set.

This is the reason why a set of n numbers has 2^n subsets.(2 options per element)

Here is the pseudo-code(C++) to print all the subsets followed by an example explaining how the code works. 1)A[] is the array of numbers whose subsets you want to find out. 2) bool a[] is the array of booleans where a[i] tells whether the number A[i] is present in the set or not.

``````print(int A[],int low,int high)
{
if(low>high)
{
for(all entries i in bool a[] which are true)
print(A[i])
}
else
{set a[low] to true //include the element in the subset
print(A,low+1,high)
set a[low] to false//not including the element in the subset
print(A,low+1,high)
}
}
``````
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What if the blog is not online anymore? Or just down for maintenance? Provide the source code IN your answer, dont link to it. –  Manuel Jul 14 '13 at 19:21
OK Manuel but the problem is I don't want to merely provide the source code .I've an explanation along with it and I don't want to write everything all over again. –  Jaskaran Jul 15 '13 at 6:17
If there is already everything explained in your blogpost, just copy+paste it? –  Manuel Jul 15 '13 at 7:06

In case anyone else comes by and was still wondering, here's a function using Michael's explanation in C++

``````vector< vector<int> > getAllSubsets(vector<int> set)
{
vector< vector<int> > subset;
vector<int> empty;
subset.push_back( empty );

for (int i = 0; i < set.size(); i++)
{
vector< vector<int> > subsetTemp = subset;

for (int j = 0; j < subsetTemp.size(); j++)
subsetTemp[j].push_back( set[i] );

for (int j = 0; j < subsetTemp.size(); j++)
subset.push_back( subsetTemp[j] );
}
return subset;
}
``````

Take into account though, that this will return a set of size 2^N with ALL possible subsets, meaning there will possibly be duplicates. If you don't want this, I would suggest actually using a `set` instead of a `vector`(which I used to avoid iterators in the code).

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You dont have to mess with recursion and other complex algorithms. You can find all subsets using bit patterns (decimal to binary) of all numbers between 0 and 2^(N-1). Here N is cardinality or number-of-items in that set. The technique is explained here with an implementation and demo.

http://codeding.com/?article=12

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Here is a solution in Scala:

``````def subsets[T](s : Set[T]) : Set[Set[T]] =
if (s.size == 0) Set(Set()) else {
val tailSubsets = subsets(s.tail);
}
``````
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Here's some pseudocode. You can cut same recursive calls by storing the values for each call as you go and before recursive call checking if the call value is already present.

The following algorithm will have all the subsets excluding the empty set.

``````list * subsets(string s, list * v){
if(s.length() == 1){
return v;
}
else
{
list * temp = subsets(s[1 to length-1], v);
int length = temp->size();

for(int i=0;i<length;i++){
}

return temp;
}
}
``````
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Here is a working code which I wrote some time ago

``````// Return all subsets of a given set
#include<iostream>
#include<cstdio>
#include<algorithm>
#include<vector>
#include<string>
#include<sstream>
#include<cstring>
#include<climits>
#include<cmath>
#include<iterator>
#include<set>
#include<map>
#include<stack>
#include<queue>
using namespace std;

typedef vector<int> vi;
typedef vector<long long> vll;
typedef vector< vector<int> > vvi;
typedef vector<string> vs;

vvi get_subsets(vi v, int size)
{
if(size==0) return vvi(1);
vvi subsets = get_subsets(v,size-1);

vvi more_subsets(subsets);

for(typeof(more_subsets.begin()) it = more_subsets.begin(); it !=more_subsets.end(); it++)
{
(*it).push_back(v[size-1]);
}

subsets.insert(subsets.end(), (more_subsets).begin(), (more_subsets).end());
return subsets;
}

int main()
{
int ar[] = {1,2,3};
vi v(ar , ar+int(sizeof(ar)/sizeof(ar[0])));
vvi subsets = get_subsets(v,int((v).size()));

for(typeof(subsets.begin()) it = subsets.begin(); it !=subsets.end(); it++)
{
printf("{ ");

for(typeof((*it).begin()) it2 = (*it).begin(); it2 !=(*it).end(); it2++)
{
printf("%d,",*it2 );
}
printf(" }\n");
}
printf("Total subsets = %d\n",int((subsets).size()) );
}
``````
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-1 for obfuscating the flow control with macros –  Ben Voigt Jul 14 '13 at 19:36
@BenVoigt, sorry for that, now I have edited the code ,removed the macros, so that it is easily understood –  krishna222 Dec 15 '13 at 8:05

one simple way would be the following pseudo code:

``````Set getSubsets(Set theSet)
{
SetOfSets resultSet = theSet, tempSet;

for (int iteration=1; iteration < theSet.length(); iteration++)
foreach element in resultSet
{
foreach other in resultSet
if (element != other && !isSubset(element, other) && other.length() >= iteration)
tempSet.append(union(element, other));
}
union(tempSet, resultSet)
tempSet.clear()
}

}
``````

Well I'm not totaly sure this is right, but it looks ok.

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here is my recursive solution.

``````vector<vector<int> > getSubsets(vector<int> a){

//base case
//if there is just one item then its subsets are that item and empty item
//for example all subsets of {1} are {1}, {}

if(a.size() == 1){
vector<vector<int> > temp;
temp.push_back(a);

vector<int> b;
temp.push_back(b);

return temp;

}
else
{

//here is what i am doing

// getSubsets({1, 2, 3})
//without = getSubsets({1, 2})
//without = {1}, {2}, {}, {1, 2}

//with = {1, 3}, {2, 3}, {3}, {1, 2, 3}

//total = {{1}, {2}, {}, {1, 2}, {1, 3}, {2, 3}, {3}, {1, 2, 3}}

int last = a[a.size() - 1];

a.pop_back();

vector<vector<int> > without = getSubsets(a);

vector<vector<int> > with = without;

for(int i=0;i<without.size();i++){

with[i].push_back(last);

}

vector<vector<int> > total;

for(int j=0;j<without.size();j++){
total.push_back(without[j]);
}

for(int k=0;k<with.size();k++){
total.push_back(with[k]);
}

}

}
``````
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Bottom up with O(n) space solution

``````#include <stdio.h>

void print_all_subset(int *A, int len, int *B, int len2, int index)
{
if (index >= len)
{
for (int i = 0; i < len2; ++i)
{
printf("%d ", B[i]);
}
printf("\n");

return;
}
print_all_subset(A, len, B, len2, index+1);

B[len2] = A[index];
print_all_subset(A, len, B, len2+1, index+1);
}

int main()
{
int A[] = {1, 2, 3, 4, 5, 6, 7};
int B[7] = {0};

print_all_subset(A, 7, B, 0, 0);
}
``````
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Here is a simple recursive algorithm in python for finding all subsets of a set:

``````def find_subsets(so_far, rest):
print 'parameters', so_far, rest
if not rest:
print so_far
else:
find_subsets(so_far + [rest[0]], rest[1:])
find_subsets(so_far, rest[1:])

find_subsets([], [1,2,3])
``````

The output will be the following: \$python subsets.py

``````parameters [] [1, 2, 3]
parameters [1] [2, 3]
parameters [1, 2] [3]
parameters [1, 2, 3] []
[1, 2, 3]
parameters [1, 2] []
[1, 2]
parameters [1] [3]
parameters [1, 3] []
[1, 3]
parameters [1] []
[1]
parameters [] [2, 3]
parameters [2] [3]
parameters [2, 3] []
[2, 3]
parameters [2] []
[2]
parameters [] [3]
parameters [3] []
[3]
parameters [] []
[]
``````

Watch the following video from Stanford for a nice explanation of this algorithm:

``````https://www.youtube.com/watch?v=NdF1QDTRkck&feature=PlayList&p=FE6E58F856038C69&index=9
``````
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a simple bitmasking can do the trick as discussed earlier .... by rgamber

``````#include<iostream>
#include<cstdio>

#define pf printf
#define sf scanf

using namespace std;

void solve(){

int t; char arr[99];
cin >> t;
int n = t;
while( t-- )
{
for(int l=0; l<n; l++) cin >> arr[l];
for(int i=0; i<(1<<n); i++)
{
for(int j=0; j<n; j++)
if(i & (1 << j))
pf("%c", arr[j]);
pf("\n");
}
}
}

int main() {
solve();
return 0;
}
``````
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