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First, define two integers N and K, where N >= K, both known at compile time. For example: N = 8 and K = 3.

Next, define a set of integers [0, N) (or [1, N] if that makes the answer simpler) and call it S. For example: {0, 1, 2, 3, 4, 5, 6, 7}

The number of subsets of S with K elements is given by the formula C(N, K). Example

My problem is this: Create a perfect minimal hash for those subsets. The size of the example hash table will be C(8, 3) or 56.

I don't care about ordering, only that there be 56 entries in the hash table, and that I can determine the hash quickly from a set of K integers. I also don't care about reversibility.

Example hash: hash({5, 2, 3}) = 42. (The number 42 isn't important, at least not here)

Is there a generic algorithm for this that will work with any values of N and K? I wasn't able to find one by searching Google, or my own naive efforts.

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Just to be clear; what are the input and output of your hash function? – Oliver Charlesworth Jan 4 '13 at 16:30
@OliCharlesworth Edited. Input is one of the possible combinations, output is an integer in [0, C(N, K)). – Veronica Deane Jan 4 '13 at 16:32

There is an algorithm to code and decode a combination into its number in the lexicographical order of all combinations with a given fixed K. The algorithm is linear to N for both code and decode of the combination. What language are you interested in?

EDIT: here is example code in c++(it founds the lexicographical number of a combination in the sequence of all combinations of n elements as opposed to the ones with k elements but is really good starting point):

typedef long long ll;

// Returns the number in the lexicographical order of all combinations of n numbers
// of the provided combination. 
ll code(vector<int> a,int n)
    int cur = 0;
    int m = a.size();

    ll res =0;
    for(int i=0;i<a.size();i++)
        if(a[i] == cur+1)
            cur = a[i];
            int number_of_greater_nums = n - a[i];
            for(int j = a[i]-1,increment=1;j>cur;j--,increment++)
                res += 1LL << (number_of_greater_nums+increment);
            cur = a[i];
    return res;
// Takes the lexicographical code of a combination of n numbers and returns the 
// combination
vector<int> decode(ll kod, int n)
    vector<int> res;
    int cur = 0;

    int left = n; // Out of how many numbers are we left to choose.
        ll all = 1LL << left;// how many are the total combinations
        for(int i=n;i>=0;i--)
            if(all - (1LL << (n-i+1)) +1 <= kod)
                left = n-i;
                kod -= all - (1LL << (n-i+1)) +1;
    return res;

I am sorry I have an algorithm for the problem you are asking for right now, but I believe it will be a good exercise to try to understand what I do above. Truth is this is one of the algorithms I teach in the course "Design and analysis of algorithms" and that is why I had it pre-written.

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Is there no constant time algorithm? I'd really prefer that. – Veronica Deane Jan 4 '13 at 16:42
@KendallFrey You can not have a constant time algorithm - your input is of size N (for the problem I solve above)! You can not perform better than the algorithm above. I guess you can write a O(K) solution for your problem by slightly modifying the solution above and again you can't perform better as this is the input size. – Ivaylo Strandjev Jan 4 '13 at 16:42
Sorry, by constant time I meant O(K). K will be a compile-time constant. – Veronica Deane Jan 4 '13 at 16:48
@KendallFrey I believe you can get as low as O(K) assuming you have already calculated the powers of two up to N. Still I think that as K will probably be in the order of N there will not be a huge difference(Number of combinations grows really fast so both N and K will be quite small). – Ivaylo Strandjev Jan 4 '13 at 16:57
@KendallFrey is it possible that you got the complexity for my solution wrong? My solution is linear to the number of numbers in S namely N, not to the number of possible combinations. – Ivaylo Strandjev Jan 4 '13 at 17:00

This is what you (and I) need:

hash() maps k-tuples from [1..n] onto the set 1..C(n,k)\subset N. The effort is k subtractions (and O(k) is a lower bound anyway, see Strandjev's remark above):

// bino[n][k] is (n "over" k) = C(n,k) = {n \choose k}
// these are assumed to be precomputed globals

int hash(V a,int n, int k) {// V is assumed to be ordered, a_k<...<a_1
  // hash(a_k,..,a_2,a_1) = (n k) - sum_(i=1)^k (n-a_i   i) 
  // ii is "inverse i", runs from left to right

  int res = bino[n][k];
  int i;

  for(unsigned int ii = 0; ii < a.size(); ++ii) {
    i = a.size() - ii;   
    res = res - bino[n-a[ii]][i];
  return res;
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If you are looking for a way to obtain the lexicographic index or rank of a unique combination then your problem falls under the binomial coefficient. The binomial coefficient handles problems of choosing unique combinations in groups of K with a total of N items.

I have written a class in C# to handle common functions for working with the binomial coefficient. It performs the following tasks:

  1. Outputs all the K-indexes in a nice format for any N choose K to a file. The K-indexes can be substituted with more descriptive strings or letters.

  2. Converts the K-indexes to the proper lexicographic index or rank of an entry in the sorted binomial coefficient table. This technique is much faster than older published techniques that rely on iteration. It does this by using a mathematical property inherent in Pascal's Triangle and is very efficient compared to iterating over the set.

  3. Converts the index in a sorted binomial coefficient table to the corresponding K-indexes. I believe it is also faster than older iterative solutions.

  4. Uses Mark Dominus method to calculate the binomial coefficient, which is much less likely to overflow and works with larger numbers.

  5. The class is written in .NET C# and provides a way to manage the objects related to the problem (if any) by using a generic list. The constructor of this class takes a bool value called InitTable that when true will create a generic list to hold the objects to be managed. If this value is false, then it will not create the table. The table does not need to be created in order to use the 4 above methods. Accessor methods are provided to access the table.

  6. There is an associated test class which shows how to use the class and its methods. It has been extensively tested with 2 cases and there are no known bugs.

To read about this class and download the code, see Tablizing The Binomial Coeffieicent.

The following tested code will iterate through each unique combinations:

public void Test10Choose5()
   String S;
   int Loop;
   int N = 10;  // Total number of elements in the set.
   int K = 5;  // Total number of elements in each group.
   // Create the bin coeff object required to get all
   // the combos for this N choose K combination.
   BinCoeff<int> BC = new BinCoeff<int>(N, K, false);
   int NumCombos = BinCoeff<int>.GetBinCoeff(N, K);
   // The Kindexes array specifies the indexes for a lexigraphic element.
   int[] KIndexes = new int[K];
   StringBuilder SB = new StringBuilder();
   // Loop thru all the combinations for this N choose K case.
   for (int Combo = 0; Combo < NumCombos; Combo++)
      // Get the k-indexes for this combination.  
      BC.GetKIndexes(Combo, KIndexes);
      // Verify that the Kindexes returned can be used to retrive the
      // rank or lexigraphic order of the KIndexes in the table.
      int Val = BC.GetIndex(true, KIndexes);
      if (Val != Combo)
         S = "Val of " + Val.ToString() + " != Combo Value of " + Combo.ToString();
      SB.Remove(0, SB.Length);
      for (Loop = 0; Loop < K; Loop++)
         if (Loop < K - 1)
            SB.Append(" ");
      S = "KIndexes = " + SB.ToString();

You should be able to port this class over fairly easily to the language of your choice. You probably will not have to port over the generic part of the class to accomplish your goals. Depending on the number of combinations you are working with, you might need to use a bigger word size than 4 byte ints.

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