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Bitwise Operators in C/C++

In C, the following 6 operators are bitwise operators (also known as bit operators as they work at the bit-level). They are used to perform bitwise operations in C.
 

Bitwise Operators in C/C++

  1. The & (bitwise AND) in C or C++ takes two numbers as operands and does AND on every bit of two numbers. The result of AND is 1 only if both bits are 1.  
  2. The | (bitwise OR) in C or C++ takes two numbers as operands and does OR on every bit of two numbers. The result of OR is 1 if any of the two bits is 1. 
  3. The ^ (bitwise XOR) in C or C++ takes two numbers as operands and does XOR on every bit of two numbers. The result of XOR is 1 if the two bits are different. 
  4. The << (left shift) in C or C++ takes two numbers, the left shifts the bits of the first operand, and the second operand decides the number of places to shift. 
  5. The >> (right shift) in C or C++ takes two numbers, right shifts the bits of the first operand, and the second operand decides the number of places to shift. 
  6. The ~ (bitwise NOT) in C or C++ takes one number and inverts all bits of it.

Let’s look at the truth table of the bitwise operators.

       X       

       Y       

       X & Y       

       X | Y       

       X ^ Y       

0

0

0

0

0

0

1

0

1

1

1

0

0

1

1

1

1

1

1

0

Example of Bitwise Operators in C

The following program uses bitwise operators to perform bit operations in C.

C++




// C++ Program to demonstrate use of bitwise operators
#include <iostream>
using namespace std;
 
int main() {
    // a = 5(00000101), b = 9(00001001)
    int a = 5, b = 9;
 
    // The result is 00000001
    cout<<"a = " << a <<","<< " b = " << b <<endl;
    cout << "a & b = " << (a & b) << endl;
 
    // The result is 00001101
    cout << "a | b = " << (a | b) << endl;
 
    // The result is 00001100
    cout << "a ^ b = " << (a ^ b) << endl;
 
    // The result is 11111010
    cout << "~a = " << (~a) << endl;
 
    // The result is 00010010
    cout<<"b << 1" <<" = "<< (b << 1) <<endl;
 
    // The result is 00000100
    cout<<"b >> 1 "<<"= " << (b >> 1 )<<endl;
 
    return 0;
}
 
// This code is contributed by sathiyamoorthics19


C




// C Program to demonstrate use of bitwise operators
#include <stdio.h>
int main()
{
    // a = 5(00000101), b = 9(00001001)
    unsigned char a = 5, b = 9;
 
    // The result is 00000001
    printf("a = %d, b = %d\n", a, b);
    printf("a&b = %d\n", a & b);
 
    // The result is 00001101
    printf("a|b = %d\n", a | b);
 
    // The result is 00001100
    printf("a^b = %d\n", a ^ b);
 
    // The result is 11111010
    printf("~a = %d\n", a = ~a);
 
    // The result is 00010010
    printf("b<<1 = %d\n", b << 1);
 
    // The result is 00000100
    printf("b>>1 = %d\n", b >> 1);
 
    return 0;
   
}


Output

a = 5, b = 9
a & b = 1
a | b = 13
a ^ b = 12
~a = -6
b << 1 = 18
b >> 1 = 4

Time Complexity: O(1)                                                            

Auxiliary Space: O(1)

Interesting Facts About Bitwise Operators

1. The left-shift and right-shift operators should not be used for negative numbers.
If the second operand(which decides the number of shifts) is a negative number, it results in undefined behavior in C. For example results of both 1 <<- 1 and 1 >> -1 is undefined. Also, if the number is shifted more than the size of the integer, the behavior is undefined. For example, 1 << 33 is undefined if integers are stored using 32 bits. Another thing is NO shift operation is performed if the additive expression (operand that decides no of shifts) is 0. See this for more details. 
Note: In C++, this behavior is well-defined.

2. Interestingly!! The bitwise OR of two numbers is just the sum of those two numbers if there is no carry involved, otherwise, you just add their bitwise AND.
Let’s say, we have a=5(101) and b=2(010), since there is no carry involved, their sum is just a|b. Now, if we change ‘a’ to 6 which is 110 in binary, their sum would change to a|b + a&b since there is a carry involved. 

3. The bitwise XOR operator is the most useful operator from a technical interview perspective.
It is used in many problems. A simple example could be “Given a set of numbers where all elements occur an even number of times except one number, find the odd occurring number” This problem can be efficiently solved by just doing XOR to all numbers. 
 

C++




#include <iostream>
using namespace std;
 
// Function to return the only odd
// occurring element
int findOdd(int arr[], int n)
{
    int res = 0, i;
    for (i = 0; i < n; i++)
        res ^= arr[i];
    return res;
}
 
// Driver Method
int main(void)
{
    int arr[] = { 12, 12, 14, 90, 14, 14, 14 };
    int n = sizeof(arr) / sizeof(arr[0]);
    cout << "The odd occurring element is  "<< findOdd(arr, n);
    return 0;
}
 
// This code is contributed by shivanisinghss2110


C




#include <stdio.h>
 
// Function to return the only odd
// occurring element
int findOdd(int arr[], int n)
{
    int res = 0, i;
    for (i = 0; i < n; i++)
        res ^= arr[i];
    return res;
}
 
// Driver Method
int main(void)
{
    int arr[] = { 12, 12, 14, 90, 14, 14, 14 };
    int n = sizeof(arr) / sizeof(arr[0]);
    printf("The odd occurring element is %d ",
           findOdd(arr, n));
    return 0;
}


Output

The odd occurring element is  90

Time Complexity: O(n)                                                              

Auxiliary Space: O(1)

 

The following are many other interesting problems using XOR operator. 

  1. Find the Missing Number
  2. Swap two numbers without using a temporary variable
  3. A Memory-Efficient Doubly Linked List
  4. Find the two non-repeating elements
  5. Find the two numbers with odd occurrences in an unsorted array
  6. Add two numbers without using arithmetic operators.
  7. Swap bits in a given number
  8. Count the number of bits to be flipped to convert a to b
  9. Find the element that appears once
  10. Detect if two integers have opposite signs

4. The Bitwise operators should not be used in place of logical operators.
The result of logical operators (&&, || and !) is either 0 or 1, but bitwise operators return an integer value. Also, the logical operators consider any non-zero operand as 1. For example, consider the following program, the results of & and && are different for the same operands. 

C++




#include <iostream>
using namespace std;
 
int main()
{
    int x = 2, y = 5;
    (x & y) ? cout <<"True " : cout <<"False ";
    (x && y) ? cout <<"True " : cout <<"False ";
    return 0;
}
 
 
 
// This code is contributed by shivanisinghss2110


C




#include <stdio.h>
 
int main()
{
    int x = 2, y = 5;
    (x & y) ? printf("True ") : printf("False ");
    (x && y) ? printf("True ") : printf("False ");
    return 0;
}


Output

False True 

Time Complexity: O(1)                                                              

Auxiliary Space: O(1)

5. The left-shift and right-shift operators are equivalent to multiplication and division by 2 respectively.
As mentioned in point 1, it works only if numbers are positive. 
 

C++




#include <iostream>
using namespace std;
 
int main() {
 
    int x = 19;
    cout<<"x << 1 = "<< (x << 1) <<endl;
    cout<<"x >> 1 = "<< (x >> 1) <<endl;
    return 0;
}
 
// This code is contributed by sathiyamoorthics19


C




#include <stdio.h>
 
int main()
{
    int x = 19;
    printf("x << 1 = %d\n", x << 1);
    printf("x >> 1 = %d\n", x >> 1);
    return 0;
}


Output

x << 1 = 38
x >> 1 = 9

Time Complexity: O(1)                                                             

Auxiliary Space: O(1)

5. The & operator can be used to quickly check if a number is odd or even.
The value of the expression (x & 1) would be non-zero only if x is odd, otherwise, the value would be zero. 
 

C++




#include <iostream>
using namespace std;
 
int main() {
 
    int x = 19 ;
    (x & 1) ? cout<<"Odd" : cout<< "Even" ;
       
    return 0;
}
 
// This code is contributed by sathiyamoorthics19


C




#include <stdio.h>
 
int main()
{
    int x = 19;
    (x & 1) ? printf("Odd") : printf("Even");
    return 0;
}


Output

Odd

Time Complexity: O(1)                                                                

Auxiliary Space: O(1)

6. The ~ operator should be used carefully.
The result of ~ operator on a small number can be a big number if the result is stored in an unsigned variable. And the result may be a negative number if the result is stored in a signed variable (assuming that the negative numbers are stored in 2’s complement form where the leftmost bit is the sign bit) 

C++




#include <iostream>
using namespace std;
 
int main() {
 
    unsigned int x = 1;
    signed int a = 1;
    cout<<"Signed Result "<< ~a <<endl ;
    cout<<"Unsigned Result "<< ~x ;
    return 0;
}
// This code is contributed by sathiyamoorthics19


C




// Note that the output of the following
// program is compiler dependent
#include <stdio.h>
 
int main()
{
    unsigned int x = 1;
    printf("Signed Result %d \n", ~x);
    printf("Unsigned Result %ud \n", ~x);
    return 0;
}


Output

Signed Result -2
Unsigned Result 4294967294

Time Complexity: O(1)                                                              

 Auxiliary Space: O(1)

Must Refer:

  1. Bits manipulation (Important tactics)
  2. Bitwise Hacks for Competitive Programming
  3. Bit Tricks for Competitive Programming 

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