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I'm thinking of doing a for loop starting along the lines of:

for(int i = 0; i <= 20, i++){ 

    if i = 1; 

       i --;

` and then I'm running trouble when considering the case when i = 0. There's 2 possible cases, i.e., print i = 0, or print i = 1. I can see that this is going to be defined recursively, i.e., each bit is defined based on the previous digits.

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I think, FFFFFFFF is 20 one you need all numbers those are not in FFFFFFFF << i for i =0 to 11 for 32 bit number – Grijesh Chauhan Oct 28 '13 at 18:06
Can you please elaborate a little bit? Show an example? I didn't get it. – Filipe Gonçalves Oct 28 '13 at 20:23
Duplicate of… but that one doesn't have an answer. It does have a hint in a comment, though :) – rici Oct 29 '13 at 1:39

2 Answers 2

I did not clearly understand your question, but I guessed, you want to get "all integers from 1 to (1<<20), with no blocks like 11 or 111 or 111, etc".

If so, this is the code:

for(int m = 0x55555; m <= 0xAAAAA; m <<= 1) {
  int x = m;
  do {
    printf("x=0x%05x\n", x);
  } while(x = (x - 1) & m);
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I want to print out all the possible combinations of 1's and 0's with anywhere to 1 bit to 20 bits and with there being no consecutive ones. For example: 100100101 would work but 1100000000000000000 – Adam Staples Oct 29 '13 at 7:20
Provided code does this. It just print in hex format, not binary. I think, binary print you can write yourself. – maxihatop Oct 30 '13 at 3:40

If I understood it well, you want to generate every 20 bit pattern which does not contain consecutive 1's. For example, 00000000000000000001 is valid, but 00000000000000000011 is not.

This is a naturally recursive problem. You can think of it like a tree where each node is either a 1 or a 0. Nodes that are a 1 can only have one child (a 0 bit), and nodes that are 0 have 2 childs, because after a 0 there can be another 0. Pictorially, it works like this:

Bits tree

The tree expands like that until we hit a depth of 20. I'll call this value CUTOFF, since you may want to change it in the future. The idea behind the code is precisely the idea conveyed by the tree:

#include <stdio.h>
#define CUTOFF 20

char buffer[CUTOFF+1];

void print_bits(char next_bit, unsigned char count) {
    buffer[count] = next_bit + '0';
    if (count == CUTOFF-1) {
        buffer[CUTOFF] = '\0';
        printf("%s\n", buffer);
    print_bits(!next_bit, count+1);
    if (next_bit == 0)
        print_bits(next_bit, count+1);

We keep a buffer with the bit string because we need to print it more than once for the case that next_bit == 0. The buffer is a way to know the path from the root to the current node, and each node can only write in the position corresponding to its depth (tracked by count).

You can start the party with:

int main(void) {
    print_bits(0, 0);
    print_bits(1, 0);
    return 0;

For very large values of CUTOFF (greater than 255), you may want to change count from unsigned char to int.

Note that this code will, by definition, find 00000000000000000000 to be a valid entry. If you want to always have at least a 1, you have to ignore this case. You can test for it using strcmp() in the base case of the recursion, but that would be inefficient. Another possible approach is to keep a counter of how many ones you have written, and test its value in the base case (or just use a flag to indicate if there has been at least a "1" written).

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