Calculate Combination based on position

I have combinations like this:

1,2,3,4 //index 0
1,2,3,5 //index 1
1,2,3,6 //index 2

and so on until 7,8,9,10

So this will be n=10 k=4 from combinatorics

How calculate combination by index

For example when my index==1
myCmb = func(index)
returns 1,2,3,5

this is example i need this for bigest numbers, and for more params and without (if this possible) many loops

i find something like this to obtain position: http://answers.yahoo.com/question/index?qid=20110320070039AA045ib

I want now reverse this...

I programming in C++ Thanks for any sugesstions or help

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How big are your "biggest" numbers? How many are "many" loops? –  Pablo May 10 '11 at 20:19
Not a duplicate, but the answer to this question is there somewhere: stackoverflow.com/questions/127704/… –  Robᵩ May 10 '11 at 20:37
I've merged your two accounts together. Also, StackOverflow isn't a forum; if you have a new question, please ask a new question. If you want to include more information in your question, please edit it. If you want to interact with one of the people who has answered, you can leave them a comment. –  Will May 12 '11 at 12:30

2 Answers

It seems like you want to find the k-combination for a given number.

Following the example, here's something that should work:

``````#include <cstddef>
#include <iostream>
#include <string>
#include <boost/lexical_cast.hpp>
#include <boost/math/special_functions/binomial.hpp>

std::size_t Choose(double n, double k) {
using boost::math::binomial_coefficient;
if (n < k) return 0;
return static_cast<std::size_t>(binomial_coefficient<double>(n, k));
}

// Returns the largest n such that Choose(n, k) <= pos.
int CombinationElement(int k, int pos) {
int n = k;
int coeff = 1, prev_coeff = 0;

while (coeff <= pos) {
coeff = Choose(++n, k);
prev_coeff = coeff;
}

return n - 1;
}

// Returns an k-combination at position pos.
std::vector<int> Combination(int k, int pos) {
std::vector<int> combination;
for (; k > 0; --k) {
int n = CombinationElement(k, pos);
combination.push_back(n);
pos -= Choose(n, k);
}
return combination;
}

int main(int argc, char** argv) {
using std::cout;
using std::endl;

if (argc != 3) {
cout << "Usage:  \$ " << argv[0] << " K POS" << endl;
cout << "Prints the K-combination at position POS." << endl;
return 1;
}

int k = boost::lexical_cast<int>(argv[1]);
int pos = boost::lexical_cast<int>(argv[2]);

std::vector<int> combination = Combination(k, pos);

for (int i = 0; i < k; i++)
cout << combination[i] << " ";
cout << std::endl;
}
``````

Note, for convenience, the code depends on Boost to calculate binomial coefficients (`boost::math::binomial_coefficient<T>`), and to parse strings into integers (`boost::lexical_cast`).

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Here is an implementation in Mathematica, from the package Combinatorica. The semantics are fairly generic, so I think it is helpful. Please leave a comment if you need anything explained.

``````UnrankKSubset::usage = "UnrankKSubset[m, k, l] gives the mth k-subset of set l, listed in lexicographic order."

UnrankKSubset[m_Integer, 1, s_List] := {s[[m + 1]]}
UnrankKSubset[0, k_Integer, s_List] := Take[s, k]
UnrankKSubset[m_Integer, k_Integer, s_List] :=
Block[{i = 1, n = Length[s], x1, u, \$RecursionLimit = Infinity},
u = Binomial[n, k];
While[Binomial[i, k] < u - m, i++];
x1 = n - (i - 1);
Prepend[UnrankKSubset[m - u + Binomial[i, k], k-1, Drop[s, x1]], s[[x1]]]
]
``````

Usage is like:

``````UnrankKSubset[1, 4, {1, 2, 3, 4, 5, 6, 7, 8, 9, 10}]
``````
`   {1, 2, 3, 5}`

As you can see this function operates on sets.

Below is my attempt to explain the code above.

UnrankKSubset is a recursive function with three arguments, called (m, k, s):

1. `m` an Integer, the "rank" of the combination in lexigraphical order, starting from zero.
2. `k` an Integer, the number of elements in each combination
3. `s` a List, the elements from which to assemble combinations

There are two boundary conditions on the recursion:

1. for any rank `m`, and any list `s`, if the number of elements in each combination `k` is `1`, then:

return the `m + 1` element of the list `s`, itself in a list.

(`+ 1` is needed because Mathematica indexes from one, rather than zero. I believe in C++ this would be s[m] )

2. if rank `m` is `0` then for any `k` and any `s`:

return the first `k` elements of `s`

The main recursive function, for any other arguments than ones specified above:

local variables: (`i`, `n`, `x1`, `u`)

`Binomial` is binomial coefficient: `Binomial[7, 5]` = 21

Do:

``````i = 1
n = Length[s]
u = Binomial[n, k]
While[Binomial[i, k] < u - m, i++];
x1 = n - (i - 1);
``````

Then return:

``````Prepend[
UnrankKSubset[m - u + Binomial[i, k], k - 1, Drop[s, x1]],
s[[x1]]
]
``````

That is, "prepend" the `x1` element of list `s` (remember Mathematica indexes from one, so I believe this would be the `x1 - 1` index in C++) to the list returned by the recursively called UnrankKSubset function with the arguments:

• `m - u + Binomial[i, k]`
• `k - 1`
• `Drop[s, x1]`

`Drop[s, x1]` is the rest of list `s` with the first `x1` elements removed.

If anything above is not understandable, or if what you wanted was an explanation of the algorithm, rather than an explanation of the code, please leave a comment and I will try again.

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I don't use mathematica i need write this as c++ function can you know how this gonna be in c++ ? –  josh May 13 '11 at 14:25
@josh, I am sorry, I only know Mathematica. I was hoping that since this Mathematica code is primarily procedural, rather than functional, it would translate to C/C++ well enough. Would you like me to try explaining the code above, step by step? –  Mr.Wizard May 13 '11 at 15:11
Yes if you can, thank you very much! –  josh May 13 '11 at 15:20
@josh, please see my edit. –  Mr.Wizard May 14 '11 at 17:13
Thank you, I'm gonna look at this and try to write this in C++, if im gonna be have any questions i ask you again.. for explanation, but this looks clear. Thank you for your time and help. –  josh May 15 '11 at 13:00