Find number of pairs (x, y) in an array such that x^y > y^x
Given two arrays X[] and Y[] of positive integers, find a number of pairs such that x^y > y^x where x is an element from X[] and y is an element from Y[].
Examples:
Input: X[] = {2, 1, 6}, Y = {1, 5}
Output: 3
Explanation: There are total 3 pairs where pow(x, y) is greater than pow(y, x) Pairs are (2, 1), (2, 5) and (6, 1)Input: X[] = {10, 19, 18}, Y[] = {11, 15, 9}
Output: 2
Explanation: There are total 2 pairs where pow(x, y) is greater than pow(y, x) Pairs are (10, 11) and (10, 15)
C++
long long countPairsBruteForce(long long X[], long long Y[], long long m, long long n){ long long ans = 0; for (int i = 0; i < m; i++) for (int j = 0; j < n; j++) if (pow(X[i], Y[j]) > pow(Y[j], X[i])) ans++; return ans;} |
Java
public static long countPairsBruteForce(long X[], long Y[], int m, int n){ long ans = 0; for (int i = 0; i < m; i++) for (int j = 0; j < n; j++) if (Math.pow(X[i], Y[j]) > Math.pow(Y[j], X[i])) ans++; return ans;} |
Python3
def countPairsBruteForce(X, Y, m, n): ans = 0 for i in range(m): for j in range(n): if (pow(X[i], Y[j]) > pow(Y[j], X[i])): ans += 1 return ans |
C#
public static int countPairsBruteForce(int[] X, int[] Y, int m, int n){ int ans = 0; for (int i = 0; i < m; i++) for (int j = 0; j < n; j++) if (Math.Pow(X[i], Y[j]) > Math.Pow(Y[j], X[i])) ans++; return ans;} |
Javascript
function countPairsBruteForce(X, Y, m, n){ let ans = 0; for(let i=0; i<m; i++ ){ for(let j=0;j<n;j++){ if ((Math.pow(X[i], Y[j]) > Math.pow(Y[j], X[i]))){ ans += 1; } } } return ans;} |
Time Complexity: O(M*N) where M and N are sizes of given arrays.
Auxiliary Space: O(1)
Efficient Solution:
The problem can be solved in O(nLogn + mLogn) time. The trick here is if y > x then x^y > y^x with some exceptions.
Following are simple steps based on this trick.
- Sort array Y[].
- For every x in X[], find the index idx of the smallest number greater than x (also called ceil of x) in Y[] using binary search, or we can use the inbuilt function upper_bound() in algorithm library.
- All the numbers after idx satisfy the relation so just add (n-idx) to the count.
Base Cases and Exceptions:
Following are exceptions for x from X[] and y from Y[]
- If x = 0, then the count of pairs for this x is 0.
- If x = 1, then the count of pairs for this x is equal to count of 0s in Y[].
- If x>1, then we also need to add count of 0s and count of 1s to the answer.
- x smaller than y means x^y is greater than y^x.
- x = 2, y = 3 or 4
- x = 3, y = 2
Note that the case where x = 4 and y = 2 is not there
Following diagram shows all exceptions in tabular form. The value 1 indicates that the corresponding (x, y) form a valid pair.
In the following implementation, we pre-process the Y array and count 0, 1, 2, 3 and 4 in it, so that we can handle all exceptions in constant time. The array NoOfY[] is used to store the counts.
Below is the implementation of the above approach:
C++
// C++ program to finds the number of pairs (x, y)// in an array such that x^y > y^x#include <bits/stdc++.h>using namespace std;// Function to return count of pairs with x as one element// of the pair. It mainly looks for all values in Y[] where// x ^ Y[i] > Y[i] ^ xint count(int x, int Y[], int n, int NoOfY[]){ // If x is 0, then there cannot be any value in Y such // that x^Y[i] > Y[i]^x if (x == 0) return 0; // If x is 1, then the number of pairs is equal to number // of zeroes in Y[] if (x == 1) return NoOfY[0]; // Find number of elements in Y[] with values greater // than x upper_bound() gets address of first greater // element in Y[0..n-1] int* idx = upper_bound(Y, Y + n, x); int ans = (Y + n) - idx; // If we have reached here, then x must be greater than // 1, increase number of pairs for y=0 and y=1 ans += (NoOfY[0] + NoOfY[1]); // Decrease number of pairs for x=2 and (y=4 or y=3) if (x == 2) ans -= (NoOfY[3] + NoOfY[4]); // Increase number of pairs for x=3 and y=2 if (x == 3) ans += NoOfY[2]; return ans;}// Function to return count of pairs (x, y) such that// x belongs to X[], y belongs to Y[] and x^y > y^xint countPairs(int X[], int Y[], int m, int n){ // To store counts of 0, 1, 2, 3 and 4 in array Y int NoOfY[5] = { 0 }; for (int i = 0; i < n; i++) if (Y[i] < 5) NoOfY[Y[i]]++; // Sort Y[] so that we can do binary search in it sort(Y, Y + n); int total_pairs = 0; // Initialize result // Take every element of X and count pairs with it for (int i = 0; i < m; i++) total_pairs += count(X[i], Y, n, NoOfY); return total_pairs;}// Driver programint main(){ int X[] = { 2, 1, 6 }; int Y[] = { 1, 5 }; int m = sizeof(X) / sizeof(X[0]); int n = sizeof(Y) / sizeof(Y[0]); cout << "Total pairs = " << countPairs(X, Y, m, n); return 0;} |
Java
// Java program to finds number of pairs (x, y)// in an array such that x^y > y^ximport java.util.Arrays;class Test { // Function to return count of pairs with x as one // element of the pair. It mainly looks for all values // in Y[] where x ^ Y[i] > Y[i] ^ x static int count(int x, int Y[], int n, int NoOfY[]) { // If x is 0, then there cannot be any value in Y // such that x^Y[i] > Y[i]^x if (x == 0) return 0; // If x is 1, then the number of pairs is equal to // number of zeroes in Y[] if (x == 1) return NoOfY[0]; // Find number of elements in Y[] with values // greater than x getting upperbound of x with // binary search int idx = Arrays.binarySearch(Y, x); int ans; if (idx < 0) { idx = Math.abs(idx + 1); ans = Y.length - idx; } else { while (idx < n && Y[idx] == x) { idx++; } ans = Y.length - idx; } // If we have reached here, then x must be greater // than 1, increase number of pairs for y=0 and y=1 ans += (NoOfY[0] + NoOfY[1]); // Decrease number of pairs for x=2 and (y=4 or y=3) if (x == 2) ans -= (NoOfY[3] + NoOfY[4]); // Increase number of pairs for x=3 and y=2 if (x == 3) ans += NoOfY[2]; return ans; } // Function to returns count of pairs (x, y) such that // x belongs to X[], y belongs to Y[] and x^y > y^x static long countPairs(int X[], int Y[], int m, int n) { // To store counts of 0, 1, 2, 3 and 4 in array Y int NoOfY[] = new int[5]; for (int i = 0; i < n; i++) if (Y[i] < 5) NoOfY[Y[i]]++; // Sort Y[] so that we can do binary search in it Arrays.sort(Y); long total_pairs = 0; // Initialize result // Take every element of X and count pairs with it for (int i = 0; i < m; i++) total_pairs += count(X[i], Y, n, NoOfY); return total_pairs; } // Driver method public static void main(String args[]) { int X[] = { 2, 1, 6 }; int Y[] = { 1, 5 }; System.out.println( "Total pairs = " + countPairs(X, Y, X.length, Y.length)); }} |
Python3
# Python3 program to find the number# of pairs (x, y) in an array# such that x^y > y^ximport bisect# Function to return count of pairs# with x as one element of the pair.# It mainly looks for all values in Y# where x ^ Y[i] > Y[i] ^ xdef count(x, Y, n, NoOfY): # If x is 0, then there cannot be # any value in Y such that # x^Y[i] > Y[i]^x if x == 0: return 0 # If x is 1, then the number of pairs # is equal to number of zeroes in Y if x == 1: return NoOfY[0] # Find number of elements in Y[] with # values greater than x, bisect.bisect_right # gets address of first greater element # in Y[0..n-1] idx = bisect.bisect_right(Y, x) ans = n - idx # If we have reached here, then x must be greater than 1, # increase number of pairs for y=0 and y=1 ans += NoOfY[0] + NoOfY[1] # Decrease number of pairs # for x=2 and (y=4 or y=3) if x == 2: ans -= NoOfY[3] + NoOfY[4] # Increase number of pairs # for x=3 and y=2 if x == 3: ans += NoOfY[2] return ans# Function to return count of pairs (x, y)# such that x belongs to X,# y belongs to Y and x^y > y^xdef count_pairs(X, Y, m, n): # To store counts of 0, 1, 2, 3, # and 4 in array Y NoOfY = [0] * 5 for i in range(n): if Y[i] < 5: NoOfY[Y[i]] += 1 # Sort Y so that we can do binary search in it Y.sort() total_pairs = 0 # Initialize result # Take every element of X and # count pairs with it for x in X: total_pairs += count(x, Y, n, NoOfY) return total_pairs# Driver Codeif __name__ == '__main__': X = [2, 1, 6] Y = [1, 5] print("Total pairs = ", count_pairs(X, Y, len(X), len(Y)))# This code is contributed by shaswatd673 |
C#
// C# program to finds number of pairs (x, y)// in an array such that x^y > y^xusing System;class GFG { // Function to return count of pairs // with x as one element of the pair. // It mainly looks for all values in Y[] // where x ^ Y[i] > Y[i] ^ x static int count(int x, int[] Y, int n, int[] NoOfY) { // If x is 0, then there cannot be any // value in Y such that x^Y[i] > Y[i]^x if (x == 0) return 0; // If x is 1, then the number of pairs // is equal to number of zeroes in Y[] if (x == 1) return NoOfY[0]; // Find number of elements in Y[] with // values greater than x getting // upperbound of x with binary search int idx = Array.BinarySearch(Y, x); int ans; if (idx < 0) { idx = Math.Abs(idx + 1); ans = Y.Length - idx; } else { while (idx < n && Y[idx] == x) { idx++; } ans = Y.Length - idx; } // If we have reached here, then x // must be greater than 1, increase // number of pairs for y = 0 and y = 1 ans += (NoOfY[0] + NoOfY[1]); // Decrease number of pairs // for x = 2 and (y = 4 or y = 3) if (x == 2) ans -= (NoOfY[3] + NoOfY[4]); // Increase number of pairs for x = 3 and y = 2 if (x == 3) ans += NoOfY[2]; return ans; } // Function to that returns count // of pairs (x, y) such that x belongs // to X[], y belongs to Y[] and x^y > y^x static int countPairs(int[] X, int[] Y, int m, int n) { // To store counts of 0, 1, 2, 3 and 4 in array Y int[] NoOfY = new int[5]; for (int i = 0; i < n; i++) if (Y[i] < 5) NoOfY[Y[i]]++; // Sort Y[] so that we can do binary search in it Array.Sort(Y); int total_pairs = 0; // Initialize result // Take every element of X and count pairs with it for (int i = 0; i < m; i++) total_pairs += count(X[i], Y, n, NoOfY); return total_pairs; } // Driver method public static void Main() { int[] X = { 2, 1, 6 }; int[] Y = { 1, 5 }; Console.Write( "Total pairs = " + countPairs(X, Y, X.Length, Y.Length)); }}// This code is contributed by Sam007 |
Javascript
<script>// JavaScript program to finds number of pairs (x, y)// in an array such that x^y > y^x// Iterative function to implement Binary Search function binarySearch(arr, x) { let start=0, end=arr.length-1; // Iterate while start not meets end while (start<=end){ // Find the mid index let mid=parseInt((start + end)/2); // If element is present at mid, return True if (arr[mid]===x) return mid; // Else look in left or right half accordingly else if (arr[mid] < x) start = mid + 1; else end = mid - 1; } return -1;} // Function to return count of pairs with x as one // element of the pair. It mainly looks for all values // in Y where x ^ Y[i] > Y[i] ^ x function count(x , Y , n , NoOfY) { // If x is 0, then there cannot be any value in Y // such that x^Y[i] > Y[i]^x if (x == 0) return 0; // If x is 1, then the number of pairs is equal to // number of zeroes in Y if (x == 1) return NoOfY[0]; // Find number of elements in Y with values // greater than x getting upperbound of x with // binary search var idx = binarySearch(Y, x); var ans; if (idx < 0) { idx = Math.abs(idx + 1); ans = Y.length - idx; } else { while (idx < n && Y[idx] == x) { idx++; } ans = Y.length - idx; } // If we have reached here, then x must be greater // than 1, increase number of pairs for y=0 and y=1 ans += (NoOfY[0] + NoOfY[1]); // Decrease number of pairs for x=2 and (y=4 or y=3) if (x == 2) ans -= (NoOfY[3] + NoOfY[4]); // Increase number of pairs for x=3 and y=2 if (x == 3) ans += NoOfY[2]; return ans; } // Function to returns count of pairs (x, y) such that // x belongs to X, y belongs to Y and x^y > y^x function countPairs(X , Y , m , n) { // To store counts of 0, 1, 2, 3 and 4 in array Y var NoOfY = Array(5).fill(-1); for (var i = 0; i < n; i++) if (Y[i] < 5) NoOfY[Y[i]]++; // Sort Y so that we can do binary search in it Y.sort((a,b)=>a-b); var total_pairs = 0; // Initialize result // Take every element of X and count pairs with it for (var i = 0; i < m; i++) total_pairs += count(X[i], Y, n, NoOfY); return total_pairs; } // Driver method var X = [ 2, 1, 6 ]; var Y = [ 1, 5 ]; document.write("Total pairs = " + countPairs(X, Y, X.length, Y.length));// This code contributed by umadevi9616</script> |
Output
Total pairs = 3
Time Complexity: O(n log n + m log n), where m and n are the sizes of arrays X[] and Y[] respectively. The sort step takes O(n log n) time. Then every element of X[] is searched in Y[] using binary search. This step takes O(m log n) time.
Auxiliary Space: O(1)
https://www.youtube.com/watch?v=chYKJGPNEvg
This article is contributed by Aarti_Rathi and Shubham Mittal. Please write comments if you find anything incorrect, or you want to share more information about the topic discussed above.
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