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I have n elements in a set U (lets assume represented by an array of size n). I want to find all possible ways of dividing the set U into two sets A and B, where |A| + |B| = n.

So for example, if U = {a,b,c,d}, the combinations would be:

  1. A = {a} -- B = {b,c,d}
  2. A = {b} -- B = {a,c,d}
  3. A = {c} -- B = {a,b,d}
  4. A = {d} -- B = {a,b,c}
  5. A = {a,b} -- B = {c,d}
  6. A = {a,c} -- B = {b,d}
  7. A = {a,d} -- B = {b,c}

Note that the following two cases are considered equal and only one should be computed:

Case 1: A = {a,b} -- B = {c,d}

Case 2: A = {c,d} -- B = {a,b}

Also note that none of the sets A or B can be empty.

The way I'm thinking of implementing it is by just keeping track of indices in the array and moving them step by step. The number of indices will be equal to the number of elements in the set A, and set B will contain all the remaining un-indexed elements.

I was wondering if anyone knew of a better implementation. Im looking for better efficiency because this code will be executed on a fairly large set of data.


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1 Answer 1

up vote 1 down vote accepted

Take all the integers from 1 to 2^(n-1), non-inclusive. So if n = 4, the integers from 1 to 7.

Each of these numbers, written in binary, represents the elements present in set A. Set B consists of the remaining elements. Note that since we're only going to 2^(n-1), not 2^n, the high bit is always set for set B; we're always putting the first element in set B, since you want order not to matter.

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Thanks for the quick reply! I like the method and tried it on a few cases and it seems to work well! I was wondering if you have any idea where i might find a (more or less) formal proof as to why this works. –  alguru Aug 9 '11 at 18:33
Every item x is either in set A or not, which corresponds to whether bit number x is 1 or 0. All possible 2^N subsets of your set of N values are representable by an N-bit binary number this way, and we're just going through all N-bit binary numbers. –  dfan Aug 9 '11 at 18:56

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