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I need a way of calculating combinations without running out of memory. Here's what i have so far.

public static long combination(long n, long k) // nCk
{
    return (divideFactorials(factorial(n), ((factorial(k) * factorial((n - k))))));
}

public static long factorial(long n)
{
    long result;
    if (n <= 1) return 1;
    result = factorial(n - 1) * n;
    return result;
}

public static long divideFactorials(long numerator, long denominator)
{
    return factorial(Math.Abs((numerator - denominator)));
}

I have tagged it as C#, but the solution should ideally be language independent.

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4  
These numbers are called "binomial coefficients" and as a very common object, have appeared before in SO: stackoverflow.com/q/4256188/422353 –  madth3 Oct 19 '12 at 23:35
1  
What kind of combination exactly are you trying to get? Is it simply nCk, or is it something else? I am just asking because your comment at the top says "nCk" but your code does not directly calculate that. –  phil13131 Oct 19 '12 at 23:36
3  
Yes, add this line to factorial(): if (n > 20) throw new OverflowException(); –  Hans Passant Oct 19 '12 at 23:42
    
It's simply nCk. –  Nyx Oct 20 '12 at 0:23

5 Answers 5

up vote 5 down vote accepted
public static long combination(long n, long k)
    {
        double sum=0;
        for(long i=0;i<k;i++)
        {
            sum+=Math.log10(n-i);
            sum-=Math.log10(i+1);
        }
        return (long)Math.pow(10, sum);
    }
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1  
Even though the original post uses longs, your return value should really be a double or long double. As you did the calculations using doubles, there is really no point in converting it back into a long, as the answer is not necessarily 100% exact. Also it limits your values for n and k even more. –  phil13131 Oct 20 '12 at 0:26
    
This works perfectly. Thank you. –  Nyx Oct 20 '12 at 0:50

One of the best methods for calculating the binomial coefficient I have seen suggested is by Mark Dominus. It is much less likely to overflow with larger values for N and K than some other methods.

public static long GetBinCoeff(long N, long K)
{
   // This function gets the total number of unique combinations based upon N and K.
   // N is the total number of items.
   // K is the size of the group.
   // Total number of unique combinations = N! / ( K! (N - K)! ).
   // This function is less efficient, but is more likely to not overflow when N and K are large.
   // Taken from:  http://blog.plover.com/math/choose.html
   //
   long r = 1;
   long d;
   if (K > N) return 0;
   for (d = 1; d <= K; d++)
   {
      r *= N--;
      r /= d;
   }
   return r;
}
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Just for the sake of completion: the standard C math library has implementations of both Γ and lnΓ (called tgamma and lgamma), where

Γ(n) = (n-1)!

The library computation is certainly faster and more accurate than summing logarithms. For a lot more information, see Wikipedia and Mathworld.

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Looking at your code, it is no wonder that you will run out of memory quite fast. Your method divideFactorials calls the method factorial and uses as argument the difference "numerator-denominator". That difference is very likely going to be very large according to your code and you will be stuck in a very long loop in your factorial method.

If it is really just about finding nCk (which I assume because your comment in your code), just use:

public static long GetnCk(long n, long k)
{
    long bufferNum = 1;
    long bufferDenom = 1;

    for(long i = n; i > Math.Abs(n-k); i--)
    {
        bufferNum *= i;
    }

    for(long i = k; i => 1; i--)
    {
        bufferDenom *= i;
    }

    return (long)(bufferNom/bufferDenom);
}

Of course using this method you will run out of range very fast, because a long does not actually support very long numbers, so n and k have to be smaller than 20.

Supposing that you actually work with very large numbers you could use doubles instead of longs, as the powers become more and more significant.

Edit: If you use large numbers you could also use Stirling's Formula:

As n becomes large ln(n!) -> n*ln(n) - n.

Putting this into code:

public static double GetnCk(long n, long k)
{
    double buffern = n*Math.Log(n) - n;
    double bufferk = k*Math.Log(k) - k;
    double bufferkn = Math.Abs(n-k)*Math.Log(Math.Abs(n-k)) - Math.Abs(n-k);

    return Math.Exp(buffern)/(Math.Exp(bufferk)*Math.Exp(bufferkn));
}

I only propose this answer, as you said language independent, the C# code is just used to demonstrate it. Since you need to use large numbers for n and k for this to work, i propose this as a general way for finding the binomial coefficient for large combinations.

For cases were n and k are both smaller than around 200-300, you should use the answer Victor Mukherjee proposed, as it is exact.

Edit2: Edited my first code.

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I tried out Victor's answer to about 20, 000 iterations and it ran perfectly. However, I did run out of memory at that range. If I need a greater range, I'll probably use this. Thank you for your answer. –  Nyx Oct 20 '12 at 0:50
    
@Marv Why would you run out of memory? It's not recursive and there are no datastructures involved. –  phant0m Oct 20 '12 at 12:03
    
@phant0m You're right. I create several data structures on every iteration. I guess the choice of algorithm won't change a thing, except maybe the time it takes. –  Nyx Oct 20 '12 at 17:15

Here is a solution which is very similar to Bob Byran, but checks two more preconditions to speed up the code.

    /// <summary>
    /// Calculates the binomial coefficient (nCk) (N items, choose k)
    /// </summary>
    /// <param name="n">the number items</param>
    /// <param name="k">the number to choose</param>
    /// <returns>the binomial coefficient</returns>
    public static long BinomCoefficient(long n, long k)
    {
        if (k > n) { return 0; }
        if (n == k) { return 1; } // only one way to chose when n == k
        if (k > n - k) { k = n - k; } // Everything is symmetric around n-k, so it is quicker to iterate over a smaller k than a larger one.
        long c = 1;
        for (long i = 1; i <= k; i++)
        {
            c *= n--;
            c /= i;
        }
        return c;
    }
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