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Find sum of XNOR of all unordered pairs from given Array

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Given an array arr[] of size N, the task is to find the sum of all XNOR values of all possible unordered pairs from the given array.

Examples:

Input: N = 5, arr[] = {2, 2, 2, 1, 1}
Output:10
Explanation: Here, 
2 XNOR 2 = 3, 2 XNOR 2 = 3, 2 XNOR 2 = 3, 1 XNOR 1 = 1, 2 XNOR 1 = 0, 2 XNOR 1 = 0, 2 XNOR 1 = 0, 2 XNOR 1 = 0, 2 XNOR 1 = 0, 2 XNOR 1 = 0, Therefore sum is 3+3+3+1=10.

Input: N = 3, arr[] = {1, 2, 3}
Output: 3
Explanation: Here, 1 XNOR 2 = 0, 1 XNOR 3 = 1, 2 XNOR 3 = 2. Therefore sum is 0+1+2 = 3

 

Approach: The only possible case for a bit to be set after the XNOR operation is that both the bits must be the same. Follow the below steps to solve the problem:

  • Maintain a bit array of size 30. 0th position from left means 2^29 is included in binary representation &, 29th position from left means 2^0 is included in binary representation.
  • For each element, if the ith bit is set then increment the ith position of the bit array.
  • After encountering the MSB containing ‘1’ calculate the ‘0’ and ‘1’ bits.
  • Until a ‘1’ bit is encountered, all the ‘0’ bits will be wasted bits. Store them separately.
  • Finally, let’s say for an ith position there is y number of ones. Therefore, there are y*(y-1)/2 pairs for an ith bit having (1, 1) bit combination which gives result 1 as XNOR. Also, let’s say till the same position there is x number of zeroes. Therefore, there are y*(y-1)/2 pairs for an ith bit having (0, 0) bit combination which gives result 1 as XNOR.
  • Now for the case of leading zeroes, multiply the number of wasted bits with the number of 0 bits. Do this for each bit position and calculate the answer.

For better understanding, Consider the array {35, 42, 27, 69}. Here are the binary representations of all four elements of the array.

Binary representations of array elements.

  • The one-pointed with the arrow is the first bit of that element which is 1. Hence it is the most significant bit for that element. Similarly, MSB for all other elements is colored green.
  • The zeroes appearing before the MSB are wasted bits and colored in red. The size of these binary arrays are 30 each.
  • In the first 23 positions of the bits array, the number of wasted bits are four, and the number of 1’s are zero, and the number of 0’s are zero, as seen in the picture.
  • In the 24th position, wasted bits are 3, and the number of 1’s will be 1 as MSB is encountered at the 24th element of element 69.

23rd bit: No. of wasted bits: 4, No. of 1’s: 0, No.of 0’s: 0
24th bit: No. of wasted bits: 3, No. of 1’s: 1, No.of 0’s: 0
25th bit: No. of wasted bits: 1, No. of 1’s: 2, No.of 0’s: 1 ( since it occurs after MSB )
26th bit: No. of wasted bits: 0, No. of 1’s: 1, No.of 0’s: 3
27th bit: No. of wasted bits: 0, No. of 1’s: 2, No.of 0’s: 2
28th bit: No. of wasted bits: 0, No. of 1’s: 1, No.of 0’s: 3
29th bit: No. of wasted bits: 0, No. of 1’s: 3, No.of 0’s: 1
30th bit: No. of wasted bits: 0, No. of 1’s: 3, No.of 0’s: 1

  • Now in each of these bits, for the XNOR value to be 1 in any of the pair of bits, either both should be 1, or both should be 0.
  • For both should be 1, it has N[i]*(N[i]-1)/2 pairs, where N[i] is the number of 1’s in ith position in all the elements.
  • Similarly, for both should be 0, it has M[i]*(M[i]-1)/2 pairs, where M[i] is the number of 0’s in ith position in all the elements. Since the required answer is the sum of all possibilities. So, for an ith bit, add 2^(30-i-1) for all possible pairs.
  • In case both should be 0, also consider wasted bits which occur in where any of the elements have a 0 (non-wasted) in the same position of the wasted bits. Let the wasted bits be W[i].
  • So total sum = (N[i]*(N[i]-1)/2)*(2^(30-i-1) + (M[i]*(M[i]-1)/2)*(2^(30-i-1)  + (W[i]*M[i]*(2^(30-i-1))) where 0<= i <=30.
  • So, for the above example, till 23rd bit, everything is 0. From 24th bit is listed here.
  • total = ((1*0)/2)*(2^6) + ((0*(-1))/2)*(2^6) + 3*0*(2^6) +  ((2*1)/2)*(2^5) + ((1*0)/2)*(2^5) + 1*1*(2^5) +  ((1*0)/2)*(2^4) + ((3*2)/2)*(2^4) + 0*3*(2^4) +  ((2*1)/2)*(2^3) + ((2*1)/2)*(2^3) + 0*2*(2^3) +  ((1*0)/2)*(2^2) + ((3*2)/2)*(2^2) + 0*3*(2^2) + ((3*2)/2)*(2^1) + ((1*0)/2)*(2^1) + 0*1*(2^1) +  ((3*2)/2)*(2^0) + ((1*0)/2)*(2^0) + 0*1*(2^0)
  • total = 0 + 0 + 0 + 32 + 0 + 32 + 0 + 48 + 0 + 8 + 8 + 0 + 0 + 12 + 0 + 6 + 0 + 0 + 3 + 0 + 0
  • Therefore, total sum = 149

Below is the implementation of the above approach.

C++




#include <bits/stdc++.h>
using namespace std;
 
// Function to find the required sum
int findSum(int n, int r[])
{
  // Store the result
  int result = 0;
 
  // bits[i][0] and bits[i][1] has
  // count of all 1's and 0's in the
  // ith bit of all elements respectively
  // bits[i][2] has count of wasted zeroes
  // of ith bit for all elements
  int bits[30][3];
  memset(bits, 0, sizeof(bits));
 
  // Iterating through all elements
  for (int i = 0; i < n; i++) {
    int num = r[i];
 
    // Flag variable set to 1 after
    // first occurrence of 1 (MSB)
    int flag = 0;
 
    // Iterating through all the bits
    for (int j = 29; j >= 0; j--) {
 
      // If msb not found
      if (flag == 0) {
        // Msb found
        if (num >= pow(2, j)) {
 
          // Set flag to 1
          flag = 1;
          num -= pow(2, j);
          bits[29 - j][0]++;
        }
        else {
          bits[29 - j][2]++;
        }
        // Continue till msb is encountered
        continue;
      }
 
      // Incrementing number
      // of 1's in jth bit
      if (num >= pow(2, j)) {
        num -= pow(2, j);
        bits[29 - j][0]++;
      }
      else {
 
        // Incrementing number
        // of 0's in jth bit
        bits[29 - j][1]++;
      }
    }
  }
 
  // Iterating through all bits
  for (int i = 0; i < 30; i++) {
 
    // Total number of 1's in
    // ith bit of all elements
    int y = bits[i][0];
 
    // Total number of 0's in
    // ith bit of all elements
    int x = bits[i][1];
 
    // Total number of wasted 0's
    // before msb of ith bit of all elements
    int msboff = bits[i][2];
 
    // y*(y-1)/2 pairs for ith bit has (1, 1)
    // bit combo which gives result 1 in XNOR
    int onePairs = (y * (y - 1)) / 2;
 
    // Adding value of ith
    // bit number of (1, 1) pairs
    // times to result
    // (2^(30-i-1) => 2 ^ 29, 2 ^ 28 etc.
    result += onePairs * pow(2, 30 - i - 1);
 
    // x*(x-1)/2 pairs for ith bit has (0, 0)
    // bit combo which gives result 1 in XNOR
    int zeroPairs = (x * (x - 1)) / 2;
    result += zeroPairs * pow(2, 30 - i - 1);
 
    result += (msboff * x) * pow(2, 30 - i - 1);
  }
 
  return result;
}
 
// Driver code
int main()
{
  int n = 5;
  int r[5] = { 2, 2, 2, 1, 1 };
 
  // Function call
  cout << findSum(n, r) << endl;
  return 0;
}
 
// This code is contributed by phasing17.


Java




class Main {
    // Function to find the required sum
    static int findSum(int n, int[] r) {
 
        // Store the result
        int result = 0;
 
        // bits[i][0] and bits[i][1] has
        // count of all 1's and 0's in the
        // ith bit of all elements respectively
        // bits[i][2] has count of wasted zeroes
        // of ith bit for all elements
        int[][] bits = new int[30][3];
 
        // Iterating through all elements
        for (int i : r) {
 
            // Converting element to binary
            String binary = Integer.toBinaryString(i);
 
            // zfill adds zeros to the front
            binary = String.format("%30s", binary).replace(' ', '0');
 
            // Flag variable set to 1 after
            // first occurrence of 1 (MSB)
            int flag = 0;
 
            // Iterating through all the bits
            for (int j = 0; j < 30; j++) {
                // If msb not found
                if (flag == 0) {
 
                    // Msb found
                    if (binary.charAt(j) == '1') {
 
                        // Set flag to 1
                        flag = 1;
 
                        // Incrementing number
                        // of 1's in jth bit
                        bits[j][0] += 1;
 
                    } else {
                        // Incrementing number of
                        // wasted zeroes before msb
                        bits[j][2] += 1;
                    }
                    // Continue till msb is encountered
                    continue;
                }
 
                // Incrementing number
                // of 1's in jth bit
                if (binary.charAt(j) == '1') {
                    bits[j][0] += 1;
                } else {
                    // Incrementing number
                    // of 0's in jth bit
                    bits[j][1] += 1;
                }
            }
        }
 
        // Iterating through all bits
        for (int i = 0; i < 30; i++) {
 
            // Total number of 1's in
            // ith bit of all elements
            int y = bits[i][0];
 
            // Total number of 0's in
            // ith bit of all elements
            int x = bits[i][1];
 
            // Total number of wasted 0's
            // before msb of ith bit of all elements
            int msboff = bits[i][2];
 
            // y*(y-1)/2 pairs for ith bit has (1, 1)
            // bit combo which gives result 1 in XNOR
            int onePairs = (y * (y - 1)) / 2;
 
            // Adding value of ith
            // bit number of (1, 1) pairs
            // times to result
            // (2^(30-i-1) => 2 ^ 29, 2 ^ 28 etc.
            result += onePairs * (int) Math.pow(2, 30 - i - 1);
 
            // x*(x-1)/2 pairs for ith bit has (0, 0)
            // bit combo which gives result 1 in XNOR
            int zeroPairs = ((x*(x-1))/2);
            result += zeroPairs * Math.pow(2, 30-i-1);
 
            result += (msboff * x)* Math.pow(2, 30-i-1);
        }
 
    return result;
    }
    public static void main(String[] args) {
    int n = 5;
    int[] r = {2, 2, 2, 1, 1};
    System.out.println(findSum(n, r));
}
 
}


Python3




# Python program for the above approach
 
# Function to find the required sum
 
 
def findSum(n, r):
 
    # Store the result
    result = 0
 
    # bits[i][0] and bits[i][1] has
    # count of all 1's and 0's in the
    # ith bit of all elements respectively
    # bits[i][2] has count of wasted zeroes
    # of ith bit for all elements
    bits = [[0, 0, 0] for i in range(30)]
 
    # Iterating through all elements
    for i in r:
 
        # Converting element to binary
        binary = bin(i)[2:]
 
        # zfill adds zeros to the front
        binary = binary.zfill(30)
 
        # Flag variable set to 1 after
        # first occurrence of 1 (MSB)
        flag = 0
 
        # Iterating through all the bits
        for j in range(30):
            # If msb not found
            if(flag == 0):
 
                # Msb found
                if(binary[j] == '1'):
 
                    # Set flag to 1
                    flag = 1
 
                    # Incrementing number
                    # of 1's in jth bit
                    bits[j][0] += 1
 
                # If msb not found yet
                else:
                    # Incrementing number of
                    # wasted zeroes before msb
                    bits[j][2] += 1
 
                # Continue till msb is encountered
                continue
 
            # Incrementing number
            # of 1's in jth bit
            if(binary[j] == '1'):
                bits[j][0] += 1
 
            # Incrementing number
            # of 0's in jth bit
            else:
                bits[j][1] += 1
 
    # Iterating through all bits
    for i in range(30):
 
        # Total number of 1's in
        # ith bit of all elements
        y = bits[i][0]
 
        # Total number of 0's in
        # ith bit of all elements
        x = bits[i][1]
 
        # Total number of wasted 0's
        # before msb of ith bit of all elements
        msboff = bits[i][2]
 
        # y*(y-1)/2 pairs for ith bit has (1, 1)
        # bit combo which gives result 1 in XNOR
        onePairs = (y*(y-1))//2
 
        # Adding value of ith
        # bit number of (1, 1) pairs
        # times to result
        # (2^(30-i-1) => 2 ^ 29, 2 ^ 28 etc.
        result += onePairs * pow(2, 30-i-1)
 
        # x*(x-1)/2 pairs for ith bit has (0, 0)
        # bit combo which gives result 1 in XNOR
        zeroPairs = ((x*(x-1))//2)
 
        # Adding value of ith bit
        # number of (0, 0) pairs
        # times to result
        # (2^(30-i-1) => 2 ^ 29, 2 ^ 28 etc.)
        result += zeroPairs * pow(2, 30-i-1)
 
        # Same for leading zeroes
        result += (msboff * x)*pow(2, 30-i-1)
 
    return result
 
 
# Driver code
if __name__ == '__main__':
    n = 5
    r = [2, 2, 2, 1, 1]
    print(findSum(n, r))


C#




// C# code implementation for the abvoe approach
using System;
 
public class GFG {
 
  // Function to find the required sum
  static int findSum(int n, int[] r)
  {
    // Store the result
    int result = 0;
 
    // bits[i][0] and bits[i][1] has
    // count of all 1's and 0's in the
    // ith bit of all elements respectively
    // bits[i][2] has count of wasted zeroes
    // of ith bit for all elements
    int[, ] bits = new int[30, 3];
 
    // Iterating through all elements
    for (int i = 0; i < r.Length; i++) {
      // Converting element to binary
      string binary
        = Convert.ToString(r[i], 2).PadLeft(30,
                                            '0');
 
      // Flag variable set to 1 after
      // first occurrence of 1 (MSB)
      int flag = 0;
 
      // Iterating through all the bits
      for (int j = 0; j < 30; j++) {
        // If msb not found
        if (flag == 0) {
          // Msb found
          if (binary[j] == '1') {
            // Set flag to 1
            flag = 1;
 
            // Incrementing number
            // of 1's in jth bit
            bits[j, 0] += 1;
          }
          else {
            // Incrementing number of
            // wasted zeroes before msb
            bits[j, 2] += 1;
          }
          // Continue till msb is encountered
          continue;
        }
 
        // Incrementing number
        // of 1's in jth bit
        if (binary[j] == '1') {
          bits[j, 0] += 1;
        }
        else {
          // Incrementing number
          // of 0's in jth bit
          bits[j, 1] += 1;
        }
      }
    }
 
    // Iterating through all bits
    for (int i = 0; i < 30; i++) {
      // Total number of 1's in
      // ith bit of all elements
      int y = bits[i, 0];
 
      // Total number of 0's in
      // ith bit of all elements
      int x = bits[i, 1];
 
      // Total number of wasted 0's
      // before msb of ith bit of all elements
      int msboff = bits[i, 2];
 
      // y*(y-1)/2 pairs for ith bit has (1, 1)
      // bit combo which gives result 1 in XNOR
      int onePairs = (y * (y - 1)) / 2;
 
      // Adding value of ith
      // bit number of (1, 1) pairs
      // times to result
      // (2^(30-i-1) => 2 ^ 29, 2 ^ 28 etc.
      result
        += onePairs * (int)Math.Pow(2, 30 - i - 1);
 
      // x*(x-1)/2 pairs for ith bit has (0, 0)
      // bit combo which gives result 1 in XNOR
      int zeroPairs = ((x * (x - 1)) / 2);
      result
        += zeroPairs * (int)Math.Pow(2, 30 - i - 1);
 
      result += (msboff * x)
        * (int)Math.Pow(2, 30 - i - 1);
    }
    return result;
  }
 
  static public void Main()
  {
 
    // Code
    int n = 5;
    int[] r = { 2, 2, 2, 1, 1 };
    Console.WriteLine(findSum(n, r));
  }
}
 
// This code is contributed by lokeshmvs21.


Javascript




<script>
    // JavaScript program for the above approach
 
    // Function to find the required sum
    const findSum = (n, r) => {
 
        // Store the result
        let result = 0;
 
        // bits[i][0] and bits[i][1] has
        // count of all 1's and 0's in the
        // ith bit of all elements respectively
        // bits[i][2] has count of wasted zeroes
        // of ith bit for all elements
        let bits = new Array(30).fill(0).map(() => new Array(3).fill(0));
        // Iterating through all elements
        for (let i in r) {
 
            // Converting element to binary
            let binary = Number(r[i]).toString(2);
            binary = binary.split("");
            while (binary.length < 30) {
                binary.unshift('0');
            }
            // Flag variable set to 1 after
            // first occurrence of 1 (MSB)
            let flag = 0;
 
            // Iterating through all the bits
            for (let j = 0; j < 30; j++) {
                // If msb not found
                if (flag == 0) {
 
                    // Msb found
                    if (binary[j] == '1') {
 
                        // Set flag to 1
                        flag = 1;
 
                        // Incrementing number
                        // of 1's in jth bit
                        bits[j][0] += 1;
                    }
 
                    // If msb not found yet
                    else
                        // Incrementing number of
                        // wasted zeroes before msb
                        bits[j][2] += 1;
 
                    // Continue till msb is encountered
                    continue;
                }
 
                // Incrementing number
                // of 1's in jth bit
                if (binary[j] == '1')
                    bits[j][0] += 1;
 
                // Incrementing number
                // of 0's in jth bit
                else
                    bits[j][1] += 1;
            }
        }
        // document.write(`${bits}<br/>`)
        // Iterating through all bits
        for (let i = 0; i < 30; i++) {
 
            // Total number of 1's in
            // ith bit of all elements
            let y = bits[i][0];
 
 
            // Total number of 0's in
            // ith bit of all elements
            let x = bits[i][1];
 
            // Total number of wasted 0's
            // before msb of ith bit of all elements
            let msboff = bits[i][2];
 
            // y*(y-1)/2 pairs for ith bit has (1, 1)
            // bit combo which gives result 1 in XNOR
            let onePairs = (y * (y - 1)) / 2;
            // Adding value of ith
            // bit number of (1, 1) pairs
            // times to result
            // (2^(30-i-1) => 2 ^ 29, 2 ^ 28 etc.
            result += onePairs * Math.pow(2, 30 - i - 1);
 
            // x*(x-1)/2 pairs for ith bit has (0, 0)
            // bit combo which gives result 1 in XNOR
            let zeroPairs = (x * (x - 1)) / 2;
 
            // Adding value of ith bit
            // number of (0, 0) pairs
            // times to result
            // (2^(30-i-1) => 2 ^ 29, 2 ^ 28 etc.)
            result += zeroPairs * Math.pow(2, 30 - i - 1);
 
            // Same for leading zeroes
            result += (msboff * x) * Math.pow(2, 30 - i - 1);
        }
 
        return result;
    }
 
    // Driver code
    let n = 5;
    let r = [2, 2, 2, 1, 1];
    document.write(findSum(n, r));
 
// This code is contributed by rakeshsahni
 
</script>


Output

10

Time Complexity: O(30*N)
Auxiliary Space: O(1)



Last Updated : 15 Feb, 2023
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