Find the Prefix-MEX Array for given Array
Given an array A[] of N elements, the task is to create a Prefix-MEX array for this given array. Prefix-MEX array B[] of an array A[] is created such that MEX of A[0] till A[i] is B[i].
MEX of an array refers to the smallest missing non-negative integer of the array.
Examples:
Input: A[] = {1, 0, 2, 4, 3}
Output: 0 2 3 3 5
Explanation: In the array A, elements
Till 1st index, elements are [1] and mex till 1st index is 0.
Till 2nd index, elements are [1, 0] and mex till 2nd index is 2.
Till 3rd index, elements are [ 1, 0, 2] and mex till 3rd index is 3.
Till 4th index, elements are [ 1, 0, 2, 4] and mex till 4th index is 3.
Till 5th index, elements are [ 1, 0, 2, 4, 3] and mex till 5th index is 5.
So our final array B would be [0, 2, 3, 3, 5].Input: A[] = [ 1, 2, 0 ]
Output: [ 0, 0, 3 ]
Explanation: In the array A, elements
Till 1st index, elements are [1] and mex till 1st index is 0.
Till 2nd index, elements are [1, 2] and mex till 2nd index is 0.
Till 3rd index, elements are [ 1, 2, 0] and mex till 3rd index is 3.
So our final array B would be [0, 0, 3].
Naive Approach: The simplest way to solve the problem is:
For each element at ith (0 ≤ i < N)index of the array A[], find MEX from 0 to i and store it at B[i].
Follow the steps mentioned below to implement the idea:
- Iterate over the array from i = 0 to N-1:
- For every ith index in array A[]:
- Run a for loop to find the MEX of index 0 till i.
- Then store this MEX at index i in the resultant array B[i].
- For every ith index in array A[]:
- Return the resultant array B[] at the end.
Time Complexity: O(N2)
Auxiliary Space: O(N)
Efficient Approach: This approach is based on the usage of Set data structure.
A set stores data in sorted order. We can take advantage of that and store all the non-negative integers till the maximum value of the array. Then traverse through each array element and remove the visited data from set. The smallest remaining element will be the MEX for that index.
Follow the steps below to implement the idea:
- Find the maximum element of the array A[].
- Create a set and store the numbers from 0 to the maximum element in the set.
- Traverse through the array from i = 0 to N-1:
- For each element, erase that element from the set.
- Now find the smallest element remaining in the set.
- This is the prefix MEX for the ith element. Store this value in the resultant array.
- Return the resultant array as the required answer.
Below is the implementation of the above approach.
C++
// C++ code to implement the approach #include <bits/stdc++.h> using namespace std; // Function to find the prefix MEX // for each array element vector< int > Prefix_Mex(vector< int >& A, int n) { // Maximum element in vector A int mx_element = *max_element(A.begin(), A.end()); // Store all number from 0 // to maximum element + 1 in a set set< int > s; for ( int i = 0; i <= mx_element + 1; i++) { s.insert(i); } // Loop to calculate Mex for each index vector< int > B(n); for ( int i = 0; i < n; i++) { // Checking if A[i] is present in set auto it = s.find(A[i]); // If present then we erase that element if (it != s.end()) s.erase(it); // Store the first element of set // in vector B as Mex of prefix vector B[i] = *s.begin(); } // Return the vector B return B; } // Driver code int main() { vector< int > A = { 1, 0, 2, 4, 3 }; int N = A.size(); // Function call vector< int > B = Prefix_Mex(A, N); // Print the prefix MEX array for ( int i = 0; i < N; i++) { cout << B[i] << " " ; } return 0; } |
Java
// Java code to implement the approach import java.util.Arrays; import java.util.LinkedHashSet; import java.util.stream.Collectors; class GFG{ // Function to find the prefix MEX // for each array element static int [] Prefix_Mex( int [] A, int n) { // Maximum element in vector A int mx_element = Arrays.stream(A).max().getAsInt(); // Store all number from 0 // to maximum element + 1 in a set LinkedHashSet<Integer> s = new LinkedHashSet<>(); for ( int i = 0 ; i <= mx_element + 1 ; i++) { s.add(i); } // Loop to calculate Mex for each index int []B = new int [n]; for ( int i = 0 ; i < n; i++) { // Checking if A[i] is present in set // If present then we erase that element if (s.contains(A[i])) s.remove(A[i]); // Store the first element of set // in vector B as Mex of prefix vector B[i] = s.stream().collect(Collectors.toList()).get( 0 ); } // Return the vector B return B; } // Driver code public static void main(String[] args) { int [] A = { 1 , 0 , 2 , 4 , 3 }; int N = A.length; // Function call int [] B = Prefix_Mex(A, N); // Print the prefix MEX array for ( int i = 0 ; i < N; i++) { System.out.print(B[i]+ " " ); } } } // This code is contributed by shikhasingrajput |
Python3
# Python code to implement the approach # Function to find the prefix MEX # for each array element def Prefix_Mex(A, n): # Maximum element in vector A mx_element = max (A) # Store all number from 0 # to maximum element + 1 in a set s = {} for i in range (mx_element + 2 ): s[i] = True # Loop to calculate Mex for each index B = [ 0 ] * n for i in range (n): # Checking if A[i] is present in set # If present then we erase that element if A[i] in s.keys(): del s[A[i]] # Store the first element of set # in vector B as Mex of prefix vector B[i] = int ( list (s.keys())[ 0 ]) # Return the list B return B # Driver code if __name__ = = "__main__" : A = [ 1 , 0 , 2 , 4 , 3 ] N = len (A) # Function call B = Prefix_Mex(A, N) # Print the prefix MEX array for i in range (N): print (B[i], end = " " ) # This code is contributed by Rohit Pradhan |
C#
// C# code to implement the approach using System; using System.Collections.Generic; using System.Linq; public class GFG{ // Function to find the prefix MEX // for each array element static int [] Prefix_Mex( int [] A, int n) { // Maximum element in vector A int mx_element =A.Max(); // Store all number from 0 // to maximum element + 1 in a set HashSet< int > s = new HashSet< int >(); for ( int i = 0; i <= mx_element + 1; i++) { s.Add(i); } // Loop to calculate Mex for each index int []B = new int [n]; for ( int i = 0; i < n; i++) { // Checking if A[i] is present in set // If present then we erase that element if (s.Contains(A[i])) s.Remove(A[i]); // Store the first element of set // in vector B as Mex of prefix vector B[i] = s.FirstOrDefault(); } // Return the vector B return B; } // Driver code public static void Main(String[] args) { int [] A = { 1, 0, 2, 4, 3 }; int N = A.Length; // Function call int [] B = Prefix_Mex(A, N); // Print the prefix MEX array for ( int i = 0; i < N; i++) { Console.Write(B[i]+ " " ); } } } // This code is contributed by shikhasingrajput |
Javascript
<script> // JavaScript code to implement the approach // Function to find the prefix MEX // for each array element const Prefix_Mex = (A, n) => { // Maximum element in vector A let mx_element = Math.max(...A); // Store all number from 0 // to maximum element + 1 in a set let s = new Set(); for (let i = 0; i <= mx_element + 1; i++) { s.add(i); } // Loop to calculate Mex for each index let B = new Array(n).fill(0); for (let i = 0; i < n; i++) { // Checking if A[i] is present in set let it = s.has(A[i]); // If present then we erase that element if (it) s. delete (A[i]); // Store the first element of set // in vector B as Mex of prefix vector B[i] = s.values().next().value; } // Return the vector B return B; } // Driver code let A = [1, 0, 2, 4, 3]; let N = A.length; // Function call let B = Prefix_Mex(A, N); // Print the prefix MEX array for (let i = 0; i < N; i++) { document.write(`${B[i]} `); } // This code is contributed by rakeshsahni </script> |
0 2 3 3 5
Time Complexity: O(N * log N )
- O(N) for iterating the vector, and
- O(log N) for inserting and deleting the element from the set.
Auxiliary Space: O(N)
Efficient Approach 2: This approach is based on using an array and a pointer to keep track of the MEX.
Follow these steps mentioned below to implement this idea:
- Find the maximum element of the array A[].
- Create a boolean array of size equal to the maximum element + 1, B[] with all values initialised as 0.
- Create a variable to track the current MEX.
- Traverse through the A[] from i = 0 to N-1:
- For each element, set the value in B[] at index equal to the value of the element at i in A[] to true.
- Update the current MEX by increasing the variable until value in B[] at MEX is true.
- Store this value in the resultant array.
- Return the resultant array as the required answer.
Below is the implementation of the above approach.
C++
#include <bits/stdc++.h> using namespace std; // Function to compute Prefix Mex vector< int > Prefix_Mex(vector< int >& A, int n) { // Create a boolean vector to track the presence of numbers vector< bool > b(n+1); // Initialize mex (minimum excluded value) to 0 int mex = 0; // Result vector to store the Prefix Mex values vector< int > result(n); // Loop through the input vector A for ( int i = 0; i < n; i++) { // Mark the current element as present b[A[i]] = true ; // Update mex until a non-present value is found while (b[mex] == true ) { mex++; } // Store the current mex value in the result vector result[i] = mex; } // Return the result vector return result; } int main() { // Input vector vector< int > A = { 2, 1, 0, 3, 5, 4 }; // Get the size of the input vector int n = A.size(); // Compute the Prefix Mex values using the defined function vector< int > result = Prefix_Mex(A, n); // Print the Prefix Mex values for ( int i = 0; i < n; i++) { cout << result[i] << " " ; } // Return 0 to indicate successful execution return 0; } |
Java
import java.util.Arrays; public class Main { // Function to compute Prefix Mex static int [] prefixMex( int [] A, int n) { // Create a boolean array to track the presence of numbers boolean [] b = new boolean [n+ 1 ]; // Initialize mex (minimum excluded value) to 0 int mex = 0 ; // Result array to store the Prefix Mex values int [] result = new int [n]; // Loop through the input array A for ( int i = 0 ; i < n; i++) { // Mark the current element as present b[A[i]] = true ; // Update mex until a non-present value is found while (b[mex]) { mex++; } // Store the current mex value in the result array result[i] = mex; } // Return the result array return result; } public static void main(String[] args) { // Input array int [] A = { 2 , 1 , 0 , 3 , 5 , 4 }; // Get the size of the input array int n = A.length; // Compute the Prefix Mex values using the defined function int [] result = prefixMex(A, n); // Print the Prefix Mex values for ( int i = 0 ; i < n; i++) { System.out.print(result[i] + " " ); } } } |
Python3
def prefix_mex(A, n): # Create a boolean list to track the presence of numbers b = [ False ] * (n + 1 ) # Initialize mex (minimum excluded value) to 0 mex = 0 # Result list to store the Prefix Mex values result = [ 0 ] * n # Loop through the input list A for i in range (n): # Mark the current element as present b[A[i]] = True # Update mex until a non-present value is found while b[mex]: mex + = 1 # Store the current mex value in the result list result[i] = mex # Return the result list return result # Main A = [ 2 , 1 , 0 , 3 , 5 , 4 ] n = len (A) result = prefix_mex(A, n) for i in result: print (i, end = ' ' ) |
C#
using System; class Program { // Function to compute Prefix Mex static int [] PrefixMex( int [] A, int n) { // Create a boolean array to track the presence of numbers bool [] b = new bool [n+1]; // Initialize mex (minimum excluded value) to 0 int mex = 0; // Result array to store the Prefix Mex values int [] result = new int [n]; // Loop through the input array A for ( int i = 0; i < n; i++) { // Mark the current element as present b[A[i]] = true ; // Update mex until a non-present value is found while (b[mex]) { mex++; } // Store the current mex value in the result array result[i] = mex; } // Return the result array return result; } static void Main() { // Input array int [] A = {2, 1, 0, 3, 5, 4}; // Get the size of the input array int n = A.Length; // Compute the Prefix Mex values using the defined function int [] result = PrefixMex(A, n); // Print the Prefix Mex values foreach ( int i in result) { Console.Write(i + " " ); } } } |
Javascript
// Function to compute Prefix Mex function prefixMex(A, n) { // Create a boolean array to track the presence of numbers let b = Array(n+1).fill( false ); // Initialize mex (minimum excluded value) to 0 let mex = 0; // Result array to store the Prefix Mex values let result = Array(n).fill(0); // Loop through the input array A for (let i = 0; i < n; i++) { // Mark the current element as present b[A[i]] = true ; // Update mex until a non-present value is found while (b[mex]) { mex++; } // Store the current mex value in the result array result[i] = mex; } // Return the result array return result; } // Main let A = [2, 1, 0, 3, 5, 4]; let n = A.length; let result = prefixMex(A, n); // Print the Prefix Mex values console.log(result.join( ' ' )); |
0 0 3 4 4 6
Time Complexity: O(N)
- O(N) for iterating the vector.
- O(N) for updating the MEX. Important thing to note is that the inner while loop can run only N times independent of the outer for loop.
Space Complexity: O(N)
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