# Algorithm to find all possible splits of a list

I am working with a linked list that I created which contains a set of numbers as data. I need to find a way to test every possible two-set partition of this list for something, and to do that, I need to break the list into every possible two-set combination. Order is not important and there will be duplicates.

``````For instance, for a list of numbers {1 4 3 1}, the possible splits are

{1} and {4, 3, 1}
{4} and {1, 3, 1}
{3} and {1, 4, 1}
{1} and {1, 4, 3}
{1, 4} and {3, 1}
{1, 3} and {4, 1}
{1, 1} and {4, 3}
``````

A list of 4 numbers is not difficult, but things become more complicated as the list grows larger, and I am having trouble seeing a pattern. Can anyone help me find an algorithm for this?

Edit:

Sorry, I didn't see the question. This is what I have tried so far. My loop structure is wrong. When I figure out what I am doing after trying on a regular array, I will extend the algorithm to fit my linked list.

``````public class TwoSubsets
{
public static void main(String[] args)
{
int[] list = {1, 3, 5, 7, 8};
int places = 1;

int[] subsetA = new int[10];
int[] subsetB = new int[10];

for (int i = 0; i < list.length; i++)
{
subsetA[i] = list[i];
for (int current = 0; current < (5 - i ); current++)
{
subsetB[current] = list[places];
places++;

}

System.out.print("subsetA = ");
for (int j = 0; j < subsetA.length; j++)
{
System.out.print(subsetA[j] + " ");
}

System.out.println();
System.out.print("subsetB = ");
for (int k = 0; k < subsetB.length; k++)
{
System.out.print(subsetB[k] + " ");
}

}
}

}
``````
• I added an edit to show what I have done so far. However, my question seems to be "on hold." Commented Nov 10, 2013 at 19:13

So you are looking for all (proper) subsets of a given set, apart from complementary ones. If your list has n elements, you would have 2^n subsets. But since you don't want the empty subset and you want to identify the partition (A,B) with (B,A) you get 2^(n-1)-1 partitions.

To enumerate them you could identify a partition with a binary number with n digits where a digit 0 in position k means that the k-th element of the list is in the first set of your partition, 1 means that it is in the second one. You want to identify a number with its complementary (exchanging a set with the other) and you want to exclude 0 (empty subset).

So you can use bitwise operations. The XOR operator gives you the complementary subdivision. So something like the following should work:

``````int m = (1<<n)-1; // where n is the number of elements, m=111111...11 in binary
for (int i=0;i<m-1;++i) {
if (i>(m^i)) continue; // this was already considered with 0 and 1 exchanged
// here the binary digits of i represent the partition
for (int j=0;j<n;++j) {
if ((1<<j) & i) {
// the j-th element of the list goes into the second set of the partition
} else {
// the j-th element of the list goes into the first set of the partition
}
}
}
``````
• Just need to add the duplicate removal part. Commented Nov 11, 2013 at 2:47
• removal of what? The if ... continue removes duplicates in the order of the subsets. Commented Nov 12, 2013 at 6:23
• In the case of {1,1,2}, you should produce the partition {[1,2],[1]} and {[1,1],[2]}. But your solution will give {[1,2],[1]} twice, since there are two 1's in the input. One from the binary number 100, another from 010. Commented Nov 12, 2013 at 7:48

Code:

``````public static void main(String[] args) {
for(String element : findSplits(list)) {
System.out.println(element);
}
}

static ArrayList<String> findSplits(ArrayList<Integer> set) {
ArrayList<String> output = new ArrayList();
ArrayList<Integer> first = new ArrayList(), second = new ArrayList();
String bitString;
int bits = (int) Math.pow(2, set.size());
while (bits-- > 0) {
bitString = String.format("%" + set.size() + "s", Integer.toBinaryString(bits)).replace(' ', '0');
for (int i = 0; i < set.size(); i++) {
if (bitString.substring(i, i+1).equals("0")) {
} else {
}
}
if (first.size() < set.size() && second.size() < set.size()) {
if (!output.contains(first + " " + second) && !output.contains(second + " " + first)) {
output.add(first + " " + second);
}
}
first.clear();
second.clear();
}
return output;
}
``````

Output:

``````[1] [1, 4, 3]
[3] [1, 4, 1]
[3, 1] [1, 4]
[4] [1, 3, 1]
[4, 1] [1, 3]
[4, 3] [1, 1]
[4, 3, 1] [1]
``````

Using linked lists to store the subsets is actually quite ideal -- the code will come together easier than using arrays.

Write a recursive function which builds the subsets. It will take the following arguments:

• An "input" list
• An "output" list
• a vector of results (this will be a "collecting parameter", if that means anything to you)

Here is a rough code sketch in Ruby:

`````` # 'input', and 'output' are linked-list nodes
# we'll assume they have 'value' and 'next' attributes
# we'll further assume that a new node can be allocated with Node.new(value,next)
# the lists are null-terminated

def build_subsets(input, output, results)
if input.nil?
results << output
else
item = input.value
input = input.next
build_subsets(input, Node.new(item, output), results)
build_subsets(input, output, results)
end
end
``````

Invoke it something like this:

`````` results = []
build_subsets(list, nil, results)
``````

After tha, all the subsets will be in `results`. I know you need a Java translation, but this should be easy to translate to Java. I'm just giving you the idea of how the code could work.