Given an array of integers, find the k smallest numbers after deleting given elements. In case of repeating elements delete only one instance in the given array for every instance of element present in the array containing the elements to be deleted.
Assume that there are at least k elements left in the array after making n deletions.
Examples:
Input : array[] = { 5, 12, 33, 4, 56, 12, 20 }, del[] = { 12, 56, 5 }, k = 3
Output : 4 12 20
Explanation : After deletions { 33, 4, 12, 20 } will be left. Print top 3 smallest elements from it.
Approach :
- Insert all the numbers in the hash map which are to be deleted from the array, so that we can check if the element in the array is also present in the Delete-array in O(1) time.
- Traverse through the array. Check if the element is present in the hash map.
- If present, erase it from the hash map.
- Else, insert it into a Min heap.
- After inserting all the elements excluding the ones which are to be deleted, Pop-out k elements from the Min heap.
Implementation:
C++
#include "iostream" #include "queue" #include "unordered_map" #include "vector" using namespace std; // Find k minimum element from arr[0..m-1] after deleting // elements from del[0..n-1] void findElementsAfterDel( int arr[], int m, int del[], int n, int k) { // Hash Map of the numbers to be deleted unordered_map< int , int > mp; for ( int i = 0; i < n; ++i) { // Increment the count of del[i] mp[del[i]]++; } priority_queue< int , vector< int >, greater< int > > heap; for ( int i = 0; i < m; ++i) { // Search if the element is present if (mp.find(arr[i]) != mp.end()) { // Decrement its frequency mp[arr[i]]--; // If the frequency becomes 0, // erase it from the map if (mp[arr[i]] == 0) mp.erase(arr[i]); } // Else push it in the min heap else heap.push(arr[i]); } // Print top k elements in the min heap for ( int i = 0; i < k; ++i) { cout << heap.top() << " " ; // Pop the top element heap.pop(); } } int main() { int array[] = { 5, 12, 33, 4, 56, 12, 20 }; int m = sizeof (array) / sizeof (array[0]); int del[] = { 12, 56, 5 }; int n = sizeof (del) / sizeof (del[0]); int k = 3; findElementsAfterDel(array, m, del, n, k); return 0; } |
Java
// Java program to find the k maximum // number from the array after n deletions import java.util.*; public class GFG { // Find k minimum element from arr[0..m-1] after deleting // elements from del[0..n-1] static void findElementsAfterDel( int [] arr, int m, int [] del, int n, int k) { // Hash Map of the numbers to be deleted HashMap<Integer, Integer> mp = new HashMap<>(); for ( int i = 0 ; i < n; ++i) { // Increment the count of del[i] if (mp.containsKey(del[i])) { mp.put(del[i], mp.get(del[i])+ 1 ); } else { mp.put(del[i], 1 ); } } Vector<Integer> heap = new Vector<Integer>(); for ( int i = 0 ; i < m; ++i) { // Search if the element is present if (mp.containsKey(arr[i])) { // Decrement its frequency mp.put(arr[i], mp.get(arr[i]) - 1 ); // If the frequency becomes 0, // erase it from the map if (mp.get(arr[i]) == 0 ) mp.remove(arr[i]); } // Else push it in the min heap else heap.add(arr[i]); } Collections.sort(heap); // Print top k elements in the min heap for ( int i = 0 ; i < k; ++i) { System.out.print(heap.get( 0 ) + " " ); // Pop the top element heap.remove( 0 ); } } // Driver code public static void main(String[] args) { int [] array = { 5 , 12 , 33 , 4 , 56 , 12 , 20 }; int m = array.length; int [] del = { 12 , 56 , 5 }; int n = del.length; int k = 3 ; findElementsAfterDel(array, m, del, n, k); } } // This code is contributed by divvyeshrabadiya07. |
Python3
# Python3 program to find the k maximum # number from the array after n deletions import math as mt import heapq # Find k maximum element from arr[0..m-1] # after deleting elements from del[0..n-1] def findElementsAfterDel(arr, m, dell, n, k): # Hash Map of the numbers to be deleted mp = dict () for i in range (n): # Increment the count of del[i] if dell[i] in mp.keys(): mp[dell[i]] + = 1 else : mp[dell[i]] = 1 heap = [] for i in range (m): # Search if the element is present if (arr[i] in mp.keys()): # Decrement its frequency mp[arr[i]] - = 1 # If the frequency becomes 0, # erase it from the map if (mp[arr[i]] = = 0 ): mp.pop(arr[i]) # else push it to heap else : heap.append(arr[i]) # creating min heap and heapifying it heapq.heapify(heap) # returning nsmallest elements from the min heap. return heapq.nsmallest(k, heap) # Driver code array = [ 5 , 12 , 33 , 4 , 56 , 12 , 20 ] m = len (array) dell = [ 12 , 56 , 5 ] n = len (dell) k = 3 print ( * findElementsAfterDel(array, m, dell, n, k)) '''Code is written by RAJAT KUMAR''' |
C#
// C# program to find the k maximum // number from the array after n deletions using System; using System.Collections.Generic; class GFG { // Find k minimum element from arr[0..m-1] after deleting // elements from del[0..n-1] static void findElementsAfterDel( int [] arr, int m, int [] del, int n, int k) { // Hash Map of the numbers to be deleted Dictionary< int , int > mp = new Dictionary< int , int >(); for ( int i = 0; i < n; ++i) { // Increment the count of del[i] if (mp.ContainsKey(del[i])) { mp[del[i]]++; } else { mp[del[i]] = 1; } } List< int > heap = new List< int >(); for ( int i = 0; i < m; ++i) { // Search if the element is present if (mp.ContainsKey(arr[i])) { // Decrement its frequency mp[arr[i]]--; // If the frequency becomes 0, // erase it from the map if (mp[arr[i]] == 0) mp.Remove(arr[i]); } // Else push it in the min heap else heap.Add(arr[i]); } heap.Sort(); // Print top k elements in the min heap for ( int i = 0; i < k; ++i) { Console.Write(heap[0] + " " ); // Pop the top element heap.RemoveAt(0); } } // Driver code static void Main() { int [] array = { 5, 12, 33, 4, 56, 12, 20 }; int m = array.Length; int [] del = { 12, 56, 5 }; int n = del.Length; int k = 3; findElementsAfterDel(array, m, del, n, k); } } // This code is contributed by divyesh072019. |
Javascript
<script> // JavaScript program to find the k maximum // number from the array after n deletions // Find k minimum element from // arr[0..m-1] after deleting // elements from del[0..n-1] function findElementsAfterDel(arr,m,del,n,k) { // Hash Map of the numbers to be deleted let mp = new Map(); for (let i = 0; i < n; ++i) { // Increment the count of del[i] if (mp.has(del[i])) { mp.set(del[i], mp.get(del[i])+1); } else { mp.set(del[i], 1); } } let heap = []; for (let i = 0; i < m; ++i) { // Search if the element is present if (mp.has(arr[i])) { // Decrement its frequency mp.set(arr[i], mp.get(arr[i]) - 1); // If the frequency becomes 0, // erase it from the map if (mp.get(arr[i]) == 0) mp. delete (arr[i]); } // Else push it in the min heap else heap.push(arr[i]); } heap.sort( function (a,b){ return a-b;}); // Print top k elements in the min heap for (let i = 0; i < k; ++i) { document.write(heap[0] + " " ); // Pop the top element heap.splice(0,1); } } // Driver code let array=[5, 12, 33, 4, 56, 12, 20 ]; let m = array.length; let del=[12, 56, 5 ]; let n = del.length; let k = 3; findElementsAfterDel(array, m, del, n, k); // This code is contributed by unknown2108 </script> |
4 12 20
Complexity Analysis:
- Time Complexity: O(M*log(M)), since inserting in a priority queue is logarithmic operation and we are doing it M times in worst case where M is the array size.
- Auxiliary Space: O(M + N), where M and N represents the size of the given two arrays.
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