# Best algorithm to find all possible permutation of given binary bits

I am looking for an optimal algorithm to find out remaining all possible permutation of a give binary number.

For ex:

Binary number is : ........1. algorithm should return the remaining 2^7 remaining binary numbers, like 00000001,00000011, etc.

Thanks, sathish

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Is this a homework assignment? If not, some context would be useful. – Bart Kiers Nov 12 '09 at 9:24
You mean given the number of bits ? and isn't there an error in your example ? – pgras Nov 12 '09 at 9:31

The example given is not a permutation!

A permutation is a reordering of the input.

So if the input is 00000001, 00100000 and 00000010 are permutations, but 00000011 is not.

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Ok, but no solution in sight... – Ben Apr 16 '13 at 8:48

If this is only for small numbers (probably up to 16 bits), then just iterate over all of them and ignore the mismatches:

``````int fixed = 0x01; // this is the fixed part
int mask = 0x01; // these are the bits of the fixed part which matter
for (int i=0; i<256; i++) {
if (i & mask == fixed) {
print i;
}
}
``````
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to find all you aren't going to do better than looping over all numbers e.g. if you want to loop over all 8 bit numbers

``````for (int i =0; i < (1<<8) ; ++i)
{
//do stuff with i
}
``````

if you need to output in binary then look at the string formatting options you have in what ever language you are using.

e.g.

printf("%b",i); //not standard in C/C++

for calculation the base should be irrelavent in most languages.

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-1 this is not a permutations algorithm – Yuval Adam Nov 12 '09 at 9:29
To be fair, though, sathishs did mention the other 2^7 numbers. I agree it's not a permutation algorithm, but it does seem to be in the spirit of the request. – Boojum Nov 12 '09 at 9:33
permutaions of a fixed size number is identical to counting, or have i missed something? – jk. Nov 12 '09 at 9:34
@jk: Yes but you must map each counter value to a value of the result set. You don't provide the result set anywhere. – Aaron Digulla Nov 12 '09 at 9:36
+1, i think this correctly matches the poorly-phrased question. The OP seems to want all binary combinations for a given number of bits, this is how you compute them. – laura Nov 12 '09 at 9:42

Why are you making it complicated ! It is as simple as the following:

``````// permutation of i  on a length K
// Example  : decimal  i=10  is permuted over length k= 7
//  [10]0001010-> [5] 0000101-> [66] 1000010 and 33, 80, 40, 20  etc.

main(){
int i=10,j,k=7; j=i;
do printf("%d \n", i= ( (i&1)<< k + i >>1); while (i!=j);
}
``````
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There are many permutation generating algorithms you can use, such as this one:

``````#include <stdio.h>

void print(const int *v, const int size)
{
if (v != 0) {
for (int i = 0; i < size; i++) {
printf("%4d", v[i] );
}
printf("\n");
}
} // print

void visit(int *Value, int N, int k)
{
static level = -1;
level = level+1; Value[k] = level;

if (level == N)
print(Value, N);
else
for (int i = 0; i < N; i++)
if (Value[i] == 0)
visit(Value, N, i);

level = level-1; Value[k] = 0;
}

main()
{
const int N = 4;
int Value[N];
for (int i = 0; i < N; i++) {
Value[i] = 0;
}
visit(Value, N, 0);
}
``````

Make sure you adapt the relevant constants to your needs (binary number, 7 bits, etc...)

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I read your question as: "given some binary number with some bits always set, create the remaining possible binary numbers".

For example, given 1xx1: you want: 1001, 1011, 1101, 1111.

An O(N) algorithm is as follows.

Suppose the bits are defined in mask m. You also have a hash h.

To generate the numbers < n-1, in pseudocode:

```counter = 0
for x in 0..n-1:
x' = x | ~m
if h[x'] is not set:
h[x'] = counter
counter += 1
```

The idea in the code is to walk through all numbers from 0 to n-1, and set the pre-defined bits to 1. Then memoize the resulting number (iff not already memoized) by mapping the resulting number to the value of a running counter.

The keys of h will be the permutations. As a bonus the h[p] will contain a unique index number for the permutation p, although you did not need it in your original question, it can be useful.

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If you are really looking for permutations then the following code should do.

To find all possible permutations of a given binary string(pattern) for example.

The permutations of 1000 are 1000, 0100, 0010, 0001:

``````void permutation(int no_ones, int no_zeroes, string accum){
if(no_ones == 0){
for(int i=0;i<no_zeroes;i++){
accum += "0";
}

cout << accum << endl;
return;
}
else if(no_zeroes == 0){
for(int j=0;j<no_ones;j++){
accum += "1";
}

cout << accum << endl;
return;
}

permutation (no_ones - 1, no_zeroes, accum + "1");
permutation (no_ones , no_zeroes - 1, accum + "0");
}

int main(){
string append = "";

//finding permutation of 11000
permutation(2, 6, append);  //the permutations are

//11000
//10100
//10010
//10001
//01100
//01010

cin.get();
}
``````
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If you intend to generate all the string combinations for n bits , then the problem can be solved using backtracking.

Here you go :

``````//Generating all string of n bits assuming A[0..n-1] is array of size n
public class Backtracking {

int[] A;

void Binary(int n){
if(n<1){
for(int i : A)
System.out.print(i);
System.out.println();
}else{
A[n-1] = 0;
Binary(n-1);
A[n-1] = 1;
Binary(n-1);
}
}
public static void main(String[] args) {
// n is number of bits
int n = 8;

Backtracking backtracking = new Backtracking();
backtracking.A = new int[n];
backtracking.Binary(n);
}
}
``````
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