# Permuting All Possible (0, 1) value arrays

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I am having writing an algorithm to generate all possible permutations of an array of this kind:

n = length
k = number of 1's in array

So this means if we have k 1's we will have n-k 0's in the array.

For example: n = 5; k = 3;

So obviously there are 5 choose 3 possible permutations for this array because
n!/(k!(n-k)!
5!/(3!2!) = (5*4)/2 = 10
possible values for the array

Here are all the values:
11100
11010
11001
10110
10101
10011
01110
01101
01011
00111

I am guessing i should use a recursive algorithms but i am just not seeing it. I am writing this algorithm in C++.

Any help would be appreciated!

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 Is this homework? – Péter Török Sep 17 '10 at 12:14 See related question: stackoverflow.com/questions/3437205/c-0-1-permutations/… – NullUserException♦ Sep 17 '10 at 12:15 no, this is not homework oh and yes it is a combination not permutation... – gprime Sep 17 '10 at 12:38 Have you checked the FAQ:stackoverflow.com/tags/algorithm/faq? – Aryabhatta Sep 17 '10 at 16:27 possible duplicate of Algorithm to return all combinations of k elements from n – Aryabhatta Sep 17 '10 at 16:27
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You can split up the combinations into those starting with 1 (n-1, k-1) and those starting with 0 (n-1, k).

This is essentially the recursive formula for the choose function.

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Just start with `00111` and then use `std::next_permutation` to generate the rest:

``````#include <algorithm>
#include <iostream>
#include <string>

int main()
{
std::string s = "00111";
do
{
std::cout << s << '\n';
}
while (std::next_permutation(s.begin(), s.end()));
}
``````

output:

``````00111
01011
01101
01110
10011
10101
10110
11001
11010
11100
``````
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If he needs to implement the algorithem, as I understand the OP, this wont help. – InsertNickHere Sep 17 '10 at 12:20
@Insert: Oh, is this a homework question? – FredOverflow Sep 17 '10 at 12:21
OP says it's not homework so standard libs should be encouraged, not downvoted. – Mark Peters Sep 17 '10 at 13:08
dident downvote. Did saw his comment too late that its not hw. – InsertNickHere Sep 18 '10 at 8:02

What you want is actually a combination since the 1's and 0's are indistinguishable and therefore their order doesn't matter (e.g. 1 1 1 vs 1 1 1).

I recently had to rewrite a combination function myself because my initial version was written recursively in a very straightforward way (pick an element, get all the combinations of the remaining array, insert the element in various places) and did not perform very well.

I searched StackOverflow and just seeing the pictures in this answer lit up the iconic lightbulb over my head.

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 It's not actually a combination either, is it? Since the 1s and 0s are distinguished from each other. `111000 != 010101` but those would be considered the same combination. – Mark Peters Sep 17 '10 at 13:14 Oh, I see how it's a combination. It would be choose k from {1, 2, 3, 4, ... n} which would be the indices of the 1s in the resultant combination. – Mark Peters Sep 17 '10 at 13:15

If you want to do this recursively, observe that the set of permutations you want is equal to all the ones that start with `"1"`, together with all the ones that start with `"0"`. So in calculating `(n,k)`, you will recurse on `(n-1,k-1)` and `(n-1,k)`, with special cases where `k = 0` and `k = n`.

This recursion is the reason that the binomial coefficients appear as the values in Pascal's triangle.

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Homework and recursive algorithm? OK, here you go:

Base case: You have two elements, name them "a" and "b" and produce the concatenations ab, then ba.

Step: If your second Element is longer than 1, split it up in first field/letter and the other part, and pass that recursively as parameters to the function itself.

That will work for any strings and arrays.

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Its about 0-1 permutations, so probably its much more eficient to iteratively increment an integer and in case it has desired bits count, print out its binary representation.

Here a sketch:

``````void printAllBinaryPermutations(int k, int n)
{
int max = pow(2, n) - 1;
for(int i=0; i<=max;i++)
{
if(hasBitCountOf(i, k)) // i has k 1's?
{
printAsBinary(i, n);
}
}
}

bool hasBitCountOf(int v, int expectedBitCount)
{
int count = 0;
while(v>0 && count<= expectedBitCount)
{
int half = v >> 1;
if(half<<1 != v)
{
// v is odd
count++;
}
v = half;
}

return count==expectedBitCount;
}

void printAsBinary(int number, int strLen)
{
for(int i=strLen-1; i>=0; i--)
{
bool is0 = (number & pow(2,i)) == 0;
if (is0)
{
cout<<'0';
}
else
{
cout<<'1';
}
}

cout<<endl;

}
``````
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 even though i am iterating over much more combinations than actually are generated, this solution should be more efficient as this is simple bit shifting and incrementing, and no stack blowing recursion. – Adesit Sep 17 '10 at 13:38

I am not sure this helps, plus it is just some weird pseudocode, but this should give you the desired ouput.

``````permutation (prefix, ones, zeros, cur) {
if (ones + zeros == 0) output(cur);
else {
if (cur != -1) prefix = concat(prefix,cur);
if (ones > 0) permutation(prefix, ones - 1, zeros, 1);
if (zeros > 0) permutation(prefix, ones, zeros - 1, 0);
}
}

permutation(empty, 3, 2, -1);
``````

greetz
back2dos

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