# Using 2^n steps to get every possible combination of people in a room

Here is the excise:

You start with an empty room and a group of n people waiting outside. At each step, you may either admit one person into the room, or let one out. Can you arrange a sequence of 2n steps, so that every possible combination of people is achieved exactly once?

My solution is:

I can have a bit array which has n elements. Each element's status stands for whether this person is in the room or not. So totally we will have 2n different combinations of people in the room.

The algorithm can be a standard backtrack to list out all the combinations.

I am just wondering whether my thought is too naive or simple?

Any trap in this excise?

Edit:

For people who are interested in the implementation of `gray code`, please see

http://yagni.com/graycode/

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The algorithm can be a standard backtrack to list out all the combinations.

Your solution "works", but if implemented naively, it will requires a lot more than 2n steps.

See the following sentence in the problem statement:

At each step, you may either admit one person into the room, or let one out.

In your solution, when you list all bit-vectors, you'll probably have `0111` followed by `1000` which means that three people will have to leave the room, and one person will have to enter.

That requires 4 steps, and not one, thus you'll get a lot more than 2n steps to run through all combinations.

However, you can arrange the bit-vectors you describe, in a way such that only one bit differs between two consecutive vectors. This is what is refered to as Gray code.

Here's an example from the Wikipedia article:

``````Dec  Gray   Binary
0   000    000
1   001    001
2   011    010
3   010    011
4   110    100
5   111    101
6   101    110
7   100    111
``````

Notice how

1. all bit-vectors are covered, and
2. for each consecutive vector, only one bit changes.

This means that you'll be able to iterate through all combinations in precisely 2n steps.

How to implement such sequence generator is also explained in the Wikipedia page, but if it's an exercise, I suggest you make an attempt yourself before peeking ;)

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Thanks. You pointed out the "trap" I overlooked - the 2^n steps to get the result (not only to get 2^n combinations) – Jackson Tale May 12 '12 at 10:58
In particular, the straightforward method would involve about twice as many, approximately 2^(n+1), steps. – ninjagecko May 12 '12 at 11:04
@ninjagecko it is 2^(n+1)-1 steps in my algorithm, just to be precise. – Jackson Tale May 12 '12 at 11:16
Gray code: good catch! I didn't even think of it. :) – Li-aung Yip May 12 '12 at 11:23
So you mean I just generate gray code, and image the gray code sequence as my desired bit sequence (combinations). So in this way, we don't need to care about the actually binary vector (the right hand side of your example) because the gray code sequences are already a full set of combinations we desire. – Jackson Tale May 12 '12 at 12:01

You are looking for a Gray code sequence generator. Neighbouring values in a Gray code sequence differ by only one bit.

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But do you think my thinking is also working? – Jackson Tale May 12 '12 at 10:43
@JacksonTale: I don't know. How are you ensuring that neighbouring values in your output sequence differ by only one bit? – Oliver Charlesworth May 12 '12 at 10:44

Here is the working code for gray code sequence generation

``````// Binary Reflected Gray Code
void brgc( int *a, int n, int idx, int reflect )
{
if ( n == idx ) {
printIntArr( a, n );
} else {
a[ idx ] = reflect;
brgc( a, n, idx + 1, 0 );
a[ idx ] = !reflect;
brgc( a, n, idx + 1, 1 );
}
}

int main( int argc, char *argv[] )
{
if ( argc != 2 ) {
printf( "Usage...\n" );
return -1;
}
int n = atoi( argv[ 1 ] );
int *a = malloc( sizeof( int ) * n );
brgc( a, n, 0, 0 );
}
``````
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``````/ package whatever; // don't place package name! /

import java.util.*;
import java.lang.*;
import java.io.*;

/ Name of the class has to be "Main" only if the class is public. /
class Ideone
{
public static void main (String[] args) throws java.lang.Exception
{
int numberofPeople=3;
int size = 1<<numberofPeople;
for(int i=0;i<size;i++)
{
int num = i^(i>>1);
System.out.println(Integer.toBinaryString(num));
}
}
}
``````
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