# Find all unique subsets of a set of values

I have an algorithm problem. I am trying to find all unique subset of values from a larger set of values.

For example say I have the set `{1,3,7,9}`. What algorithm can I use to find these subsets of 3?

```{1,3,7}
{1,3,9}
{1,7,9}
{3,7,9}
```

Subsets should not repeat, and order is unimportant, set {1,2,3} is the same as set {3,2,1} for these purposes. Psudocode (or the regular kind) is encouraged.

A brute force approach is obviously possible, but not desired.

For example such a brute force method would be as follows.

```for i = 0 to size
for j = i + 1 to size
for k = j + 1 to size
subset[] = {set[i],set[j],set[k]}
```

Unfortunately this requires an additional loop for each element desired in the subset, which is undesirable if, for example, you want a subset of 8 elements.

-
I'm sorry I was following both tags, my bad. –  Paulo Bu Dec 16 '13 at 16:00
Can it be mathematically proved that the number of `unique` subsets is equal to the number of elements given in the parent set? I feel like this is true (haven't tested it). –  The Platypus Dec 16 '13 at 16:09
Well for a subset of 3 it seems to follow this equation `unique subsets = 1/6*x^3 + x^2 + 11/6^x + 1`. Where `x` is the difference in set size to subset size. –  Chase Dec 16 '13 at 16:23
Brute force as in what exactly? I'd probably call any way to generate these sets (as opposed to just counting them) brute force. –  Dukeling Dec 16 '13 at 16:29
Essentially same question as stackoverflow.com/questions/127704/… which has a ton of answers –  Peter Webb Dec 17 '13 at 10:23

Some Java code using recursion.

The basic idea is to try to swap each element with the current position and then recurse on the next position (but we also need `startPos` here to indicate what the last position that we swapped with was, otherwise we'll get a simple permutation generator). Once we've got enough elements, we print all those and return.

``````static void subsets(int[] arr, int pos, int depth, int startPos)
{
if (pos == depth)
{
for (int i = 0; i < depth; i++)
System.out.print(arr[i] + "  ");
System.out.println();
return;
}
for (int i = startPos; i < arr.length; i++)
{
// optimization - not enough elements left
if (depth - pos + i > arr.length)
return;

// swap pos and i
int temp = arr[pos];
arr[pos] = arr[i];
arr[i] = temp;

subsets(arr, pos+1, depth, i+1);

// swap pos and i back - otherwise things just gets messed up
temp = arr[pos];
arr[pos] = arr[i];
arr[i] = temp;
}
}

public static void main(String[] args)
{
subsets(new int[]{1,3,7,9}, 0, 3, 0);
}
``````

Prints:

``````1  3  7
1  3  9
1  7  9
3  7  9
``````

A more detailed explanation (through example):

First things first - in the above code, an element is kept in the same position by performing a swap with itself - it doesn't do anything, just makes the code a bit simpler.

Also note that at each step we revert all swaps made.

Say we have input `1 2 3 4 5` and we want to find subsets of size 3.

First we just take the first 3 elements - `1 2 3`.

Then we swap the `3` with `4` and `5` respectively,
and the first 3 elements gives us `1 2 4` and `1 2 5`.

Note that we've just finished doing all sets containing `1` and `2` together.

Now we want sets of the form `1 3 X`, so we swap `2` and `3` and get `1 3 2 4 5`. But we already have sets containing `1` and `2` together, so here we want to skip `2`. So we swap `2` with `4` and `5` respectively, and the first 3 elements gives us `1 3 4` and `1 3 5`.

Now we swap `2` and `4` to get `1 4 3 2 5`. But we want to skip `3` and `2`, so we start from `5`. We swap `3` and `5`, and the first 3 elements gives us `1 4 5`.

And so on.

Skipping elements here is perhaps the most complex part. Note that whenever we skip elements, it just involves continuing from after the position we swapped with (when we swapped `2` and `4`, we continued from after the `4` was). This is correct because there's no way an element can get to the left of the position we're swapping with without having been processed, nor can a processed element get to the right of that position, because we process all the elements from left to right.

Think in terms of the for-loops

It's perhaps the simplest to think of the algorithm in terms of for-loops.

``````for i = 0 to size
for j = i + 1 to size
for k = j + 1 to size
subset[] = {set[i],set[j],set[k]}
``````

Each recursive step would represent a for-loop.

`startPos` is `0`, `i+1` and `j+1` respectively.

`depth` is how many for-loops there are.

`pos` is which for-loop we're currently at.

Since we never go backwards in a deeper loop, it's safe to use the start of the array as storage for our elements, as long as we revert the changes when we're done with an iteration.

-
Swapping the numbers around in the array is clever. Could you explain how this works in more detail? –  Chase Dec 16 '13 at 17:03
@Chase Tried to explain a bit more - hope it helps. –  Dukeling Dec 16 '13 at 17:41
Oh, it is basically what I did, but done recursively (properly). Recursion still messes me up sometimes. –  Chase Dec 16 '13 at 18:09

If you are interested only in subsets of size 3, then this can be done using three simple nested for loops.

``````for ( int i = 0; i < arr.size(); i++ )
for ( int j = i+1; j < arr.size(); j++ )
for ( int k = j+1; k < arr.size(); k++ )
std::cout << "{ " << arr[i] <<"," << arr[j] <<"," << arr[k] <<" }";
``````

For a more general case you will have to use recursion.

``````void recur( set<int> soFar, set<int> remaining, int subSetSize ) {
if (soFar.size() == subSetSize) {
print soFar;
return;
}

for ( int I = 0; I < remaining.size(); I++ ) {
//take out Ith element from remaining and push it in soFar.
// recur( newSofar, newRemaining, subSetSize);
}
}
``````
-
Haha, I was just posting the nested loop was undesirable. After Dukeling asked about brute force methods in the comments. –  Chase Dec 16 '13 at 16:44
@Chase see my update. –  user1990169 Dec 16 '13 at 16:48