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What is the most efficient method to evaluate the value of n choose k ? The brute force way I think would be to find n factorial / k factorial / (n-k) factorial .

A better strategy may be to use dp according to this recursive formula. Is there any other better method to evaluate n choose k ?

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Well, for starters you can replace n!/k! with n*(n-1)*(n-2)*...*(k+1) No point in calculating n! and k! in full when many of the factors cancel out. –  Tim Goodman Mar 8 '13 at 19:56
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@M42: this question is not a duplicate of the one you link to. That question asks for all combinations of k elements from n, whereas this question only wants the number of such combinations. –  Luke Woodward Mar 10 '13 at 12:32
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I voted to reopen...don't agree with the close votes. –  Andrew Mao Mar 11 '13 at 5:00
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How is the question off topics and how is it not related to programming? I am asking for a program that calculates the value of "n choose k" . –  Nikunj Banka Mar 12 '13 at 10:47
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If a moderator sees this -- I vote to remove moderator privileges from the user that closed this as "off topic". If they can't be bothered to respond to the comments challenging that ruling, then they are actually detracting from the value of this communal resource rather than adding to it. –  ms-tg Mar 24 at 17:00
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closed as off topic by user7116, M42, IronMan84, Jim G., Soner Gönül Mar 10 '13 at 20:30

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8 Answers

up vote 9 down vote accepted

You could use the Multiplicative formula for this:

enter image description here

http://en.wikipedia.org/wiki/Binomial_coefficient#Multiplicative_formula

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we can speed it up by calculating (n choose n-k) instead of (n choose k) when n-k < k. –  Nikunj Banka Mar 9 '13 at 14:06
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Here is my version, which works purely in integers (the division by k always produces an integer quotient) and is fast at O(k):

function choose(n, k)
    if k == 0 return 1
    return (n * choose(n - 1, k - 1)) / k

I wrote it recursively because it's so simple and pretty, but you could transform it to an iterative solution if you like.

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It's not O(k); k is strictly less than n, so you can't ignore the contribution of n to the run-time. At best, you can say it is O(k M(n)), where M(n) is the speed of your multiplication algorithm. –  chepner Mar 8 '13 at 20:13
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Correct, but pedantic. The function stated above makes O(k) multiplications and divisions. I ignored the bit-complexity of the operations themselves. –  user448810 Mar 8 '13 at 20:19
    
This function calculates n!/k!. That's not what the question is about –  icepack Mar 8 '13 at 20:28
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@icepack: No, it doesn't. The numerator ranges from n to n-k+1. The denominator ranges from k to 1. Thus, choose(9,4) = (9*8*7*6) / (4*3*2*1) = 126, which is correct. By contrast, 9!/4! = 362880 / 24 = 15120. –  user448810 Mar 8 '13 at 20:40
    
Sorry, you're right - very elegant –  icepack Mar 8 '13 at 21:00
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Probably the easiest way to compute binomial coefficients (n choose k) without overflowing is to use Pascal's triangle. No fractions or multiplications are necessary. (n choose k). The nth row and kth entry of Pascal's triangle gives the value.

Take a look at this page. This is an O(n^2) operation with only addition, which you can solve with dynamic programming. It's going to be lightning fast for any number that can fit in a 64-bit integer.

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and O(n^2) additional space –  icepack Mar 8 '13 at 20:29
    
@rici correct, but that would be an optimization to the presented method –  icepack Mar 8 '13 at 21:04
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If you're going to calculate many combinations like this, calculating the Pascal's Triangle is sure the best option. As you already know the recursive formula, I think I can past some code here:

MAX_N = 100
MAX_K = 100

C = [[1] + [0]*MAX_K for i in range(MAX_N+1)]

for i in range(1, MAX_N+1):
    for j in range(1, MAX_K+1):
        C[i][j] = C[i-1][j-1] + C[i-1][j];

print C[10][2]
print C[10][8]
print C[10][3]
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"Most efficient" is a poor request. What are you trying to make efficient? The stack? Memory? Speed? Overall, my opinion is that the recursive method is most efficient because it only uses addition (a cheap operation) and the recursion won't be too bad for most cases. The function is:

nchoosek(n, k)
{
    if(k==0) return 1;
    if(n==0) return 0;
    return nchoosek(n-1, k-1)+nchoosek(n-1,k);
}
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That's a tree recursion and for big values for n and k it might not finish at all. –  Pedrom Mar 8 '13 at 19:53
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It's O(2^n) time and O(n) space. Factorial computation is O(n) time and O(1) space. –  icepack Mar 8 '13 at 19:54
    
I disagree. This is effectively computing Pascal's triangle; it's most definitely NOT O(2^n) - it's O(n^2). This is a square, not a tree. Plus, it will never overflow if the result is storable in a long, and addition is much faster than multiplication and division. Even more, you can memoize with f(n, k) = f(n, n-k), and all the edge cases are 1. –  Andrew Mao Mar 8 '13 at 20:05
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This IS most definitely exponential. The complexity of computing nchoosek(n,k) is nchoosek(n,k) at least, since your base cases are 0 and 1. If you do the same with dynamic programming, you'll get a n^2 complexity, here you're calculating the same results many times. –  double_squeeze Mar 8 '13 at 20:12
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@AndrewMao Each call to this function results in 2 nodes in the recursion tree. The recursion stops after n steps (I assume k <= n but that doesn't matter in general case) ==> 2^n nodes in the tree, O(2^n) running time. Memoization is orthogonal to this method, the benefits of memoization aren't related to recursion. –  icepack Mar 8 '13 at 20:12
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If you have a lookup table of factorials then the calculation of C(n,k) will be very fast.

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For big number of n and k that lookup table might be prohibitive. Also there should be an option for values outside that table. –  Pedrom Mar 8 '13 at 19:58
    
@Pedrom There was no mention of limitations on the magnitude of numbers in the question. It's tagged language-agnostic and algorithms. –  Andrew Morton Mar 8 '13 at 20:05
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The problem with the n!/k!(n-k)! approach is not so much the cost as the issue with ! growing very rapidly so that, even for values of nCk which are well within the scope of, say, 64-bit integers, intermediate calculations are not. If you don't like kainaw's recursive addition approach you could try the multiplicative approach:

nCk == product(i=1..k) (n-(k-i))/i

where product(i=1..k) means the product of all the terms when i takes the values 1,2,...,k.

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You're right about the possibility of overflow corrupting things well before the final answer stops fitting in a machine word, but I don't like your solution: it will produce fractional values for some factors, e.g. for the i=2 factor when n=4 and k=3. (Of course the factors will multiply together in the end to give an integer, but your way means intermediate results need to be stored in floating point -- yuck!) –  j_random_hacker Aug 11 '13 at 0:24
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The fastest way is probably to use the formula, and not pascals triangle. Let's start not to do multiplications when we know that we're going to divide by the same number later. If k < n/2, let's have k = n - k. We know that C(n,k) = C(n,n-k) Now :

n! / (k! x (n-k)!) = (product of numbers between (k+1) and n) / (n-k)!

At least with this technique, you're never dividing by a number that you used to multiply before. You have (n-k) multiplications, and (n-k) divisions.

I'm thinking about a way to avoid all divisions, by finding GCDs between the numbers that we have to multiply, and those we have to divide. I'll try to edit later.

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Finding the GCD will surely reduce the amount of operations. Unfortunately, the GCD finding for itself would be a much heavier task. –  icepack Mar 8 '13 at 20:24
    
Yes I'm afraid of that. But the GCDs would be computed on small numbers, when the multiplication has a big one. And actually I'm not sure that a GCD is harder than a division. –  double_squeeze Mar 8 '13 at 20:30
    
I tend to be skeptical, but it would be interesting to see the results :) –  icepack Mar 8 '13 at 20:34
    
Division and GCD both have a O(n^2) complexity for 2 numbers of size n. Here we would calculate division on a big and a small number, whereas the GCD would be on 2 small numbers, but we would need to do it for all the numbers. If I had to do it by hand, I think I'd try to find at least the obvious multiples and GCDs, to avoid doing useless divisions. –  double_squeeze Mar 8 '13 at 20:36
    
If you want the prime factorization of C(n,k), you can use Krummer's Theorem. (You need to know all the primes less than or equal to n.) planetmath.org/encyclopedia/KummersTheorem.html This doesn't quite avoid divisions, since you need to be able to express k and n-k base p for each prime p. –  rici Mar 8 '13 at 20:36
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