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Given a combination of k of the first n natural numbers, for some reason I need to find the position of such combination among those returned by itertools.combination(range(1,n),k) (the reason is that this way I can use a list instead of a dict to access values associated to each combination, knowing the combination).

Since itertools yields its combinations in a regular pattern it is possible to do it (and I also found a neat algorithm), but I'm looking for an even faster/natural way which I might ignore.

By the way here is my solution:

def find_idx(comb,n):
    for c in comb:
        #idx+=sum(nck(n-2-x,k-1) for x in range(c-last_c-1)) # a little faster without nck caching
        idx+=nck(n-1,k)-nck(n-c+last_c,k) # more elegant (thanks to Ray), faster with nck caching
    return idx

where nck returns the binomial coefficient of n,k.

For example:

comb=list(itertools.combinations(range(1,14),6))[654] #pick the 654th combination
find_idx(comb,14) # -> 654

And here is an equivalent but maybe less involved version (actually I derived the previous one from the following one). I considered the integers of the combination c as positions of 1s in a binary digit, I built a binary tree on parsing 0/1, and I found a regular pattern of index increments during parsing:

def find_idx(comb,n):
    b=bin(sum(1<<(x-1) for x in comb))[2:]
    for s in b[::-1]:
        if s=='0':
    return idx
share|improve this question
+1 It might be helpful to take a look at the "source code" of itertools.combinations: – Joel Cornett Jan 22 '13 at 9:54
These look like iterative versions of the unchoose ranker I keep in the toolbox. find_idx seems faster than unchoose, which isn't surprising, as Python recursion tends to be slow. – DSM Jan 22 '13 at 10:06
Thinking out loud: would combinatorial numbers help here? – larsmans Jan 22 '13 at 17:03
@Iarsmans Great link, thanks. Nevertheless I found a difference between lexicographic ordering explained in Wikipedia and the one used by itertools: the former assume decreasing ordering of chosen items, the latter increasing ordering. I'm trying to reduce my algorithm to something analogous (is not that far) to the elegant and fast one in Wikipedia, but I don't know whether it's feasible, due to such difference. – mmj Jan 22 '13 at 21:49

3 Answers 3

up vote 1 down vote accepted

Your solution seems quite fast. In find_idx, you have two for loop, the inner loop can be optimized using the formular:

C(n, k) + C(n-1, k) + ... + C(n-r, k) = C(n+1, k+1) - C(n-r, k+1)

so, you can replace sum(nck(n-2-x,k-1) for x in range(c-last_c-1)) with nck(n-1, k) - nck(n-c+last_c, k).

I don't know how you implement your nck(n, k) function, but it should be O(k) measured in time complexity. Here I provide my implementation:

from operator import mul
from functools import reduce # In python 3
def nck_safe(n, k):
    if k < 0 or n < k: return 0
    return reduce(mul, range(n, n-k, -1), 1) // reduce(mul, range(1, k+1), 1)

Finally, your solution become O(k^2) without recursion. It's quite fast since k wouldn't be too large.


I've noticed that nck's parameters are (n, k). Both n and k won't be too large. We may speed up the program by caching.

def nck(n, k, _cache={}):
    if (n, k) in _cache: return _cache[n, k]
    # before returning the result
    _cache[n, k] = result
    return result

In python3 this can be done by using functools.lru_cache decorator:

def nck(n, k):
share|improve this answer
Great "theoretical" improvement, I was looking exactly for such a formula. Unfortunately it seems not to bring much performance gain. I tried some tests and with great disappointment I found no speed advancement in comparison to the original version with sum. I guess that after all you need more cycles to calculate the 2 nck than to compute the several nck of the sum in the original version. By the way I updated the code to reflect your "theoretical" optimization. – mmj Feb 4 '13 at 11:42
Next optimization step should be to find a similar formula even for the main loop. – mmj Feb 4 '13 at 11:50
What a pity that the trick don't work well. I've introduced another way in my updated answer. The two method can be combined to use. – Ray Feb 5 '13 at 14:44
Caching surely is a possibility when the ranges of n and k are small (I actually used it in my real implementation), and in such case your improvement is useful cause it always needs just 2 lookups. – mmj Feb 6 '13 at 20:59

Looks like you need to better specify your task or I am just getting it wrong. For me it seems that when you iterating through the itertools.combination you can save indexes you need to an appropriate data structure. If you need all of them then I would go with the dict (one dict for all your needs):

combinationToIdx = {}
for (idx, comb) in enumerate(itertools.combinations(range(1,14),6)):
    combinationToIdx[comb] = idx

def findIdx(comb):
    return combinationToIdx[comb]
share|improve this answer
Using dict is more time and memory consuming than using list. Moreover, if you have (like I do) billions of combinations, to store all comb/index pairs you might need more memory and time than you have, whereas a function needs few bytes of memory and you spend time to get the index only when you need it. – mmj Jan 23 '13 at 9:38

If you are looking for a way to efficiently 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.

share|improve this answer
Can you translate to Python or at least to pseudocode the function used to find the index of a specific combination? – mmj Jan 24 '13 at 14:50

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