How can i generate 4 bit binary combination using recursion in C for 0,1?

For this array, trying something like this:

``````void rollover(int val,int count) {
if(count==0) {
return;
}
printf("%d ",val);
count--;
rollover(val,count);
}
int main() {
int arr[]={0,1};
for(int i=0;i<=1;i++) {
rollover(arr[i],4);
}
printf("\n");
return 0;
}
``````

Expected output using recursion method:

``````0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
``````

Can't understand how to write that rec function. I have spent several hours to solve it. Can someone assist to write that function?

I am/was trying to do something like G_G posted below. How can i write such recursion function? Do i have to use one for loop to call that recursion function or two for loop with recursion or should i call the recursion function twice? For example:

``````void rollover(int val,int count) {
if(count==0) {
return;
}
printf("%d ",val);
count--;
rollover(val,count);
//.. do something if necessary ..
rollover(val,count);
//.. do something if necessary ..
}
``````
• What have you achieved so far? Commented Apr 22, 2013 at 15:19
• so with the code above, you call `rec(0, 4)` and `rec(1, 4)`, what exactly do you expect? Commented Apr 22, 2013 at 15:20
– cola
Commented Apr 22, 2013 at 15:23
• @ExP, for rec(0,4) expecting to print first 8 row starting with zero and with rec(1,4) expecting to print last 8 row starting with one.
– cola
Commented Apr 22, 2013 at 15:24

Simplest solution : binary conversion, no recursion

``````for(int i = 0; i < 16: ++i) {
printf("%u%u%u%u", i/8%2, i/4%2, i/2%2, i%2);
}
``````

See MOHAMED's answer for a recursive version of this loop

Binary recursion used by the following solutions

``````          _ 000
_ 00 _/
/      \_ 001
0        _ 010
\_ 01 _/
\_ 011
_ 100
_ 10 _/
/      \_ 101
1        _ 110
\_ 11 _/
\_ 111
``````

Recursive solution using `char*` buffer, no binary conversion

``````void char_buffer_rec(char number[4], int n) {
if(n > 0) {
number[4-n] = '0';
char_buffer_rec(number, n - 1);
number[4-n] = '1';
char_buffer_rec(number, n - 1);
}
else {
printf("%s\n", number);
}
}
``````

usage :

``````char number[5] = {0};
char_buffer_rec(number, 4);
``````

Recursive solution using only `int`, no buffer, no binary conversion

``````void int_ten_rec(int number, int tenpower) {
if(tenpower > 0) {
int_ten_rec(number, tenpower/10);
int_ten_rec(number + tenpower, tenpower/10);
}
else {
printf("%04u\n", number);
}
}
``````

usage :

``````int_ten_rec(0, 1000);
``````

Another version of this solution replacing `tenpower` width `bitwidth`, replacing the printf `width` with a variable padding depending on the length variable. `length` could be defined as a new parameter, a program constant, etc.

``````void int_rec(int number, int bitwidth) {
static int length = bitwidth;
int i, n;
if(bitwidth > 0) {
int_rec(number, bitwidth-1);
/* n := 10^(bitwidth-2) */
for(i=0,n=1;i<bitwidth-1;++i,n*=10);
int_rec(number + n, bitwidth-1);
}
else {
/* i := number of digit in 'number' */
for(i=1,n=number;n>=10;++i,n/=10);
/* print (length-i) zeros */
for(n=i; n<length; ++n) printf("0");
printf("%u\n", number);
}
}
``````

usage :

``````int_rec(0, 4);
``````

Tree Solution, recursive using `char*` buffer, no binary conversion

``````struct Node {
int val;
struct Node *left, *right;
};

void build_tree(struct Node* tree, int n) {
if(n > 0) {
tree->left = (Node*)malloc(sizeof(Node));
tree->right= (Node*)malloc(sizeof(Node));
tree->left->val = 0;
build_tree(tree->left, n - 1);
tree->right->val = 1;
build_tree(tree->right, n - 1);
}
else {
tree->left = tree->right = NULL;
}
}

void print_tree(struct Node* tree, char* buffer, int index) {
if(tree->left != NULL && tree->right != NULL) {
sprintf(buffer+index, "%u", tree->val);
print_tree(tree->left, buffer, index+1);
sprintf(buffer+index, "%u", tree->val);
print_tree(tree->right, buffer, index+1);
}
else {
printf("%s%u\n", buffer, tree->val);
}
}
``````

usage :

``````    char buffer[5] = {0};
Node* tree = (Node*)malloc(sizeof(Node));
tree->val = 0;
build_tree(tree, 4);
print_tree(tree, buffer, 0);
``````

But this would print an additional `0` at the begining of each line, to avoid this, build two smaller trees :

``````    Node* tree0 = (Node*)malloc(sizeof(Node));
Node* tree1 = (Node*)malloc(sizeof(Node));
tree0->val = 0;
tree1->val = 1;
build_tree(tree0, 3);
build_tree(tree1, 3);
print_tree(tree0, buffer, 0);
print_tree(tree1, buffer, 0);
``````

Recursive solution using int* array

``````#define MAX_LENGTH 32
int number[MAX_LENGTH];
void int_buffer_rec(int n, int length) {
if(n > 0) {
number[length - n] = 0;
int_buffer_rec(n - 1, length);
number[length - n] = 1;
int_buffer_rec(n - 1, length);
}
else {
for(int i = 0; i < length; ++i) {
printf("%u", number[i]);
}
printf("\n");
}
}
``````

usage :

``````int_buffer_rec(4, 4);
``````
• Thank You. But can you rewrite that code without making string or without using characters. Can you use integer for recursion instead of characters?
– cola
Commented Apr 22, 2013 at 16:02
• You could use an integer (or more logical, boolean) array as a buffer, but you would have to print it manually at the end which is less convenient than a char array. In any case you can't do this without some sort of accumulation buffer, if you want to use only `int` as recursion parameters (as in MOHAMED's answer), you would have to convert it to binary before printing it and a simple loop would do the same job. Commented Apr 22, 2013 at 17:04
• Can you rewrite that code to make a binary tree(depth=4), left side 0 and right side 1 ?
– cola
Commented Apr 23, 2013 at 1:38
• Well that's basically what this algorithm is doing, except it doesn't actually store the tree in memory. Building a tree won't be more helpful because while traversing the tree in depth you won't be able to print before reaching the leafs so you'll still need a buffer to store the path you've taken in the tree. See my last edit for an example using a binary tree, you'll see my initial solution is a simplified version of the last one. Commented Apr 23, 2013 at 7:48
• Thank you for your reply. But i am looking for a answer like G_G posted. Tree looks complex here for this. Using recursion only can do this.
– cola
Commented Apr 24, 2013 at 23:29

the recursion could be done with `+1`

``````void f(unsigned int x)
{
printf("%u%u%u%u\n",
(x>>3)&0x1,
(x>>2)&0x1,
(x>>1)&0x1,
x&0x1);
if(x==0xF) return;
else f(x+1);
}

int main(void)
{
f(0);
}
``````

Execution:

``````\$ ./test
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
``````
• //print here the first 4 bits of x = right side 4 bits = less significant bits ? That means, i have to convert from decimal to binary ?
– cola
Commented Apr 22, 2013 at 15:34
• But that's more a stack-loop than a real recursion. Commented Apr 22, 2013 at 15:36
• @guru I updated my answer concerning the print of 4 first bits of x Commented Apr 22, 2013 at 15:40
• Actually i don't want to convert from decimal to binary or to use shift operator.
– cola
Commented Apr 22, 2013 at 15:47

just traverse DFS a binary tree of depth 4, going left is 0, going right is 1.

``````tr(int dep, int val)
{
if(dep == 4)
{
printf("\n");
}
else
{
printf("%d", val);
tr(dep+1, 0); // going left
tr(dep+1, 1); // going right
}

return;
}

int main()
{
tr(0,0);
}
``````
• I edited the answer, however the code will not print the whole bit pattern everytime but just the portions that changes from the previous one Commented Apr 23, 2013 at 10:14

I tried to limit my solution using to the same arguments but I would definitively add an extra argument to know the initial value of count.

``````void rec(int val, int count) {
if (count <= 1) {
int i;
int f = 0;
for (i = sizeof(int) * 8; i >= 0; i--) {
f |= (val >> i) & 1;
if (f) {
printf("%d", (val >> i) & 1);
}
}
printf("\n");
} else {
rec(val * 2, count - 1);
rec(val * 2 + 1, count - 1);
}
}
``````

Output:

``````1
10
11
100
101
110
111
1000
1001
1010
1011
1100
1101
1110
1111
``````

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

void rec2(int val, int count, int b) {
if (count <= 1) {
int i;
for (i = b - 1; i >= 0; i--) {
printf("%d", (val >> i) & 1);
}
printf("\n");
} else {
rec2(val * 2, count - 1, b);
rec2(val * 2 + 1, count - 1, b);
}
}

void rec(int val, int count) {
rec2(val, count, count);
}

int main() {
rec(0, 4);
rec(1, 4);
return 0;
}
``````

Output:

``````0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
``````
• Can you follow the exact pattern of the 4 bit output? Like 0000,0001 ?
– cola
Commented Apr 26, 2013 at 1:07
• Yes, see my edit. Also works with any number of bits, that's the big difference with the other solutions. Commented Apr 26, 2013 at 12:41
• Is it possible to avoid using bitwise/shifting operator somehow? Is it possible to avoid converting from decimal to binary?
– cola
Commented Apr 26, 2013 at 13:25
• Most probably but I don't see the point. It's not a complicated operator and the other alternatives will be slower for most of them if not all. Commented Apr 26, 2013 at 19:12

Let us start by designing the prototype of the recursive function. Hopefully, it'll make sense from there. Take a look at a non-recursive version of this code, and you'll need the same variables. You don't need to pass any of them as arguments, but I'd prefer to pass them all, and make the solution as flexible and modular as possible. Consider the return value, too. That should probably indicate some sort of success, in order to mimic consistency with the C standard library.

``````int count_r(char *destination, /* The storage for the function to store *
*     the 0s and 1s as we count.        */
size_t length,     /* The number of digits in the number.   */
char *digit);      /* The set of digits                     */
``````

Now let us focus on designing the first iteration. Like in primary school, we start by defining our `count_r` to iterate only single digits at a time. Once we can prove that it knows how to count from `0` to `9`, we introduce it to double digits... but for now, one step at a time.

Let us assume `destination` is initialised to contain `length` bytes of `digits[0]`, prior to the first call. This initialisation is done by the caller, and the caller would presumably output that pre-initialised array before calling. The first iteration should modify only one byte: The one indicated by `length`, and then return to the caller.

``````int count_r(char *destination, size_t length, char *digit) {
/* The position of the right-most digit is before the '\0' in destination, *
*     so we need to decrement length                                      */
length--;

/* Find the digit at the very end of destination, within our "digit" parameter */
char *d = strchr(digit, destination[length]);

/* d[1] points to the next digit (or '\0') */
destination[length] = d[1];
return 0;
}
``````

The caller then presumably prints the array, and calls `count_r` again with the same buffer to increment the counter. This works with different bases, and by reversing the `digit` string we can decrement instead of incrementing. However, as we'll soon see, it fails after it reaches the highest number it can count to: `'F'` in the example below.

``````int main(void) {
char num[] = "0";
do {
puts(num);
} while (count_r(num, strlen(num), "0123456789ABCDEF") == 0);
}
``````

When the time comes for counting higher, d[1] will be `'\0'` as it will have iterated beyond the set of digits and into the null terminator for the string. Let us consider adding code to handle our second iteration.

A bit of code is needed to set `destination[length]` back to the first `digit` and recursively move left onto the next digit. This occurs when `d[1] == '\0'`, so we can write an `if (...) { ... }` branch to handle that.

There is a problem when `length` is passed in as 0, which we would discover after implementing the change mentioned just now. Here is where the function should return `1` to indicating that counting has finished, because it has moved as far left as possible and reached the highest number possible.

``````void count_r(char *destination, size_t length, char *digit) {
/* The position of the right-most digit is before the '\0' in destination, *
*     so we need to decrement length                                      */
if (length-- == 0) { return 1; }

/* Find the digit at the very end of destination, within our "digit" parameter */
char *d = strchr(digit, destination[length]);

/* d[1] points to the next digit (or '\0') */
if (d[1] == '\0') {
/* Set destination[length] to the first digit */
destination[length] = digit[0];
/* Recurse onto the next digit. We've already decremented length */
return count_r(destination, length, digit);
}

destination[length] = d[1];
return 0;
}
``````

After adding a few `assert`ions (eg. `assert(strlen(digit) > 1);`) and writing some testcases, we might then decide that this function is ready for production. I hope I was able to help. :)

Recursion is a programming technique that allows the programmer to express operations in terms of themselves. In C and C++ , this takes the form of a function that calls itself.

``````#include<iostream>
#include<cstdio>
using namespace std;
void rec(int val)
{
if(val<16)
{
printf("%u%u%u%u", val>>3, (val&4)>>2, (val&2)>>1, val&1);
printf("\n");
rec(++val);    //calling val+1 here
}
return;
}
int main()
{
rec(0);  //calling recursion for 0
}
``````

This gives you exact output you want..!

If you don't want to use bit shift operators ..

``````#include<iostream>
#include<cstdio>
using namespace std;
void rec(int val)
{
if(val<16)
{
for(int b=val,a=8,i=0;i<4;b%=a,a/=2,i++)
printf("%u",(b/a));
printf("\n");
rec(++val);// calling val+1 here
}
return;
}

int main()
{
rec(0);//calling recursion for 0
}
``````
• Thank You for your answer. But i am looking for a solution without using shifting/bitwise operator. Only using recursion and printf() .
– cola
Commented Apr 25, 2013 at 9:49
• Also converting from decimal to binary is not allowed. Can it be re-writen without doing conversion from decimal to binary?
– cola
Commented Apr 26, 2013 at 1:01
• @guru Can you please update your question completely with the information What exactly do you expect from your function ? Commented Apr 26, 2013 at 5:26
• @MissingNumber you cannot use `printf()` without `<cstdio>`. i'l edit Commented Apr 26, 2013 at 5:59
• @MissingNumber no just because it is in namespace std doesnt mean you cannot include `cstdio` namespaces are open that means you can add to a namespace in a different header file, and you have to include that header to know the presence of a member. even if you write using namespace std; and include only iostream, then whats in iostream within namespace std only is visible. Commented Apr 26, 2013 at 6:53

This problem can be generalized to obtain binary combination of any length by using recursion. For example, if you want to get all binary combinations of `length=4`, just call `printBinaryCombination("????", 0)` (i.e. four `?`s need to replaced with `0` or `1`).

The corresponding code is as follows:

``````void printBinaryCombination(string str, int current)
{
int length = str.length();
if (length == 0)
return;

if (current == length)
printf("%s\n", str.c_str());
else
{
if (str[current] == '?')
{
str[current] = '0';
printBinaryCombination(str, current+1);

str[current] = '1';
printBinaryCombination(str, current+1);

// change back for next time
str[current] = '?';
}
else
printBinaryCombination(str, current+1);
}
}
``````

EDIT: Actually, the above function is also powerful to handle all binary combinations that contains random number of `?`s, each of which can be `0` or `1`. For example, if you call `printBinaryCombination("1??0", 0)`, it will print:

``````1000
1010
1100
1110
``````

To generate n bit combination you asked for(you asked for n=4) general recursive implementation for any n would be:

Main function:

``````vector<string> ve,ve1;
int main(int argc, char const *argv[])
{
/* code */
int n;
cin>>n;
generate("0",n,true);
generate("1",n,false);
for(int i=0;i<ve.size();i++){
cout<<ve[i]<<endl;
}
for(int i=0;i<ve1.size();i++){
cout<<ve1[i]<<endl;
}
return 0;
}
``````

Generate function which recursively generates the binary strings:

``````void generate(string s,int n,bool b){
if(n==1){
if(b==true){
ve.push_back(s);
}
else{
ve1.push_back(s);
}
return;
}else{
generate(s+"0",n-1,b);
generate(s+"1",n-1,b);
}
}
``````

Hope this helps..

SOLN 1: a more generalized answer(compilable under c90, c99). booleans being output as int. Limitations :
1) uses math library.(its heavier so).

``````#include<stdio.h>
#include<math.h>
#define MAXBITS 4
//#define MAXVALUES (((int)pow(2,maxb))-1)
const int MAXVALUES = (((int)pow(2,maxb))-1) //if this gives warning then use #define version.

void bin(int val,int total)
{
int i = 0;
if(val <= MAXVALUES)            //can write pow(2,total-1)-1 but anyways..
{
for(i =0 ; i < total;i++)
{
printf("%d",!!(val&(int)pow(2,total-i-1)));
}
printf("\n");

}
else return;
bin(val+1,total);
}

int main()
{
setbuf(stdout,NULL);
bin(0,MAXBITS);//4 bits
return 0;
}
``````

Soln 2 :This can be done by char printing. no shift operator.

limitation(s) :
1) it can print(correctly) only upto 15(dec) or 0x0F(hex) values.
2) a total of
`(5 * sizeof(char) * total) + (( total + 2) * (sizeof(int) + sizeof(int)))` created on stack(so wasteful).

``````#include<stdio.h>
#include<stdlib.h>
#include<math.h>
#define MAXVALUES 15
#define MAXBITS 4
void bin(int val,int total) //@prototype void bin(int val);remove redundant total.
{
char *s = malloc(sizeof(char)*(total+1)); //cant declare variable array(atleast pre c99)
int i = 0;
if(val <= MAXVALUES )
{
for(i =0 ; i < total;i++)
{
s[total - i-1] = !!(val&(int)pow(2,i)) + '0';
}
s[total] = '\0';
printf("%s\n",s);
}
else return;
bin(val+1,total);
}

int main()
{
bin(0,MAXBITS);//4 bits
return 0;
}
``````
• Why bin(0,20) ? I thought that the total value meant the number of bits, not the maximum value. See example. Commented Apr 25, 2013 at 8:05
• `total` is just redundant i can reduce the code further. well i'l localize the answer it to the current code. Commented Apr 25, 2013 at 8:08
• @guru the first solution is very generic. you could use that Commented Apr 25, 2013 at 11:49
• @MissingNumber Yes whats wrong in MAXBITS being 4, if you need a 4 bit binary value?infact if i give `n` bits it will print upto 2^n Commented Apr 26, 2013 at 5:34
• @MissingNumber oh you must be referring to `#define MAXVALUE 5` and op had asked for 4? i changed it. typo. Commented Apr 26, 2013 at 5:40

This general purpose c++ code works for any number of bits. just change const int num to any number of bits you want to generate binary code of...

``````const int num=3;
string code="";

void GenerateBinaryCode(string str,unsigned int n){
if(n==0){
cout<<str<<endl;
}
else{
str[num-n]='0';
GenerateBinaryCode(str,  n-1);
str[num-n]='1';
GenerateBinaryCode(str, n-1);
}
}
int main(){
for(int i=0; i<num; i++)
code+="x";

GenerateBinaryCode(code,num);

}
``````

Here's a recursive implementation in C using only an int 2D array (no strings, chars or bitshifting) for arbitrary bit lengths.

``````static void btable(int* a, int i, int n, int k, size_t len) {
if (k >= len)
return;
for (int j = (i+n)/2; j < n; j++)
*(a+j*len+k) = 1;
btable(a,i,(i+n)/2,k+1,len);
btable(a,(i+n)/2,n,k+1,len);
}
``````

Then you can call the function with

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

int main(void) {

int n = 4;
int (*a)[n] = malloc(sizeof(int[(int)pow(2,n)][n]));
btable(*a,0,pow(2,n),0,n);

for (int i = 0; i < pow(2,n); i++) { // verify output
for (int j = 0; j < n; j++)
printf("%d",a[i][j]);
printf("\n");
}

return 0;
}
``````

Before to present the final solution, I'll show two functions that we can use for our goal.

The main idea of the next function is to add the elements of the `l1` list to each list that is contained in `l2`. For example:

``````l1 = [0]
l2 = [ [1,1] , [1,0] ]
then
f1(l1,l2) = [ [0,1,1] ,[0,1,0]]

def f1(l1:List[Int],l2:List[List[Int]]): List[List[Int]] = l2.map{ r=> l1:::r}
``````

The first parameter is a list that contains a list of integers that will be added to each list of numbers contained in the `l2` list. For example:

``````l1 = [ [0] , [1]]
l2 = [ [1,0], [1,1] ]
f(l1,l2) = [ [0,1,0],[0,1,1], [1,1,0],[1,1,1] ]

def f(l1:List[List[Int]],l2:List[List[Int]]): List[List[Int]] = l1.map{ r=> f1(r,l2)} flatten
``````

Now, that we have the auxiliary methods, we create the function that will solve the requirement

``````/**
n : The max number of digits that the binary number can contain
*/

def binaryNumbers(n:Int):List[List[Int]] = n match {
case 1 => List(List(0),List(1))
case _ => f( List(List(0),List(1)) , binaryNumbers(n-1) )
}

Example: binaryNumbers(2) = List( List(0,0), List(0,1), List(1,0), List(1,1) )
``````
• The question author explicitly asked how to solve the problem in C. Commented Aug 22, 2017 at 1:19