Given an integer N, a binary string S and an array W[]. S denotes the sequence of N * 2 persons entering the hall, where 0 denotes a boy and 1 denotes a girl. W[] denotes the width of seats in each row, where each row consists of exactly 2 seats. The task is to find a possible arrangement of the persons entering the hall such that following conditions are satisfied:
- A boy chooses a row in which both seats are empty. Among all such rows, he chooses the one with the minimum width.
- A girl chooses a row in which one seat is occupied by a boy. Among all such rows, she chooses the one with the maximum width.
Examples:
Input: N = 3, W[] = {2, 1, 3}, S = “001011”
Output: 2 1 1 3 3 2
Explanation:
People enter the hall in the following way:
Person 1: First person is a boy, and all the seats are vacant at this time. So, he can select any row and take a seat. Among all rows, the one with minimum width of seat is 2nd. So, the first person sits on a seat in the 2nd row.
Person 2: Second person is also a boy, and now 2 seats are vacant with width of seats 2 & 3. So, he takes the seat in row 1 as it has minimum width of seats.
Person 3: Third one is a girl, and she can sit in a row in which one seat is already occupied, i.e, row 1 and row 2. Among these rows, the girl chooses to sit in the row with maximum width, so she sits in row 1.
Person 4: Fourth one is a boy, and he can sit only in row 3, as only 3rd row is vacant now.
Person 5: Fifth one is a girl, and she can sit in row 2 or row 3, which have one of the seats occupied. So she chooses row 3 as it has a seat with width more than that in row 2.
Person 6: Finally a girl comes, and she can take a seat only in row 2.Input: N = 3, W[] = {1, 3, 2}, S = “010011”
Output: 1 1 3 2 2 3
Naive Approach: The simplest approach is to take an array of pairs of size N and mark it occupied on every boy’s entry into the bus if both pair values are marked vacant and have the minimum width. Similarly, mark occupied on girl’s entry only when a single value is marked occupied and having maximum width.
Time Complexity: O(N2)
Auxiliary Space: O(N)
Efficient Approach: To optimize the above approach, the idea is to use a priority queue. Follow the steps below too solve the problem:
- Sort the given array arr[] of the width of seats in ascending order.
- Create a priority queue and keep an index variable to keep track of the number of rows occupied by a boy in arr[].
- Create a vector ans[] to store the result.
- Iterate through each character of the string s and if s[i] is 0, then push the index of arr[ind] in the vector and push arr[ind] into the queue.
- Otherwise, pop the top element of the queue, and then push the index of this element in the vector.
- After the above steps. print the value stored in ans[].
Below is the implementation of the above approach:
// C++ program for the above approach #include <bits/stdc++.h> using namespace std;
// Function to find the arrangement // of seating void findTheOrder( int arr[], string s,
int N)
{ // Stores the row in which the
// ith person sits
vector< int > ans;
// Stores the width of seats along
// with their index or row number
pair< int , int > A[N];
for ( int i = 0; i < N; i++)
A[i] = { arr[i], i + 1 };
// Sort the array
sort(A, A + N);
// Store the seats and row for
// boy's seat
priority_queue<pair< int , int > > q;
// Stores the index of row upto
// which boys have taken seat
int index = 0;
// Iterate the string
for ( int i = 0; i < 2 * N; i++) {
if (s[i] == '0' ) {
// Push the row number at
// index in vector and heap
ans.push_back(A[index].second);
q.push(A[index]);
// Increment the index to let
// the next boy in the next
// minimum width vacant row
index++;
}
// Otherwise
else {
// If girl then take top of
// element of the max heap
ans.push_back(q.top().second);
// Pop from queue
q.pop();
}
}
// Print the values
for ( auto i : ans) {
cout << i << " " ;
}
} // Driver Code int main()
{ // Given N
int N = 3;
// Given arr[]
int arr[] = { 2, 1, 3 };
// Given string
string s = "001011" ;
// Function Call
findTheOrder(arr, s, N);
return 0;
} |
// Java program for the above approach import java.io.*;
import java.util.*;
class Pair
{ int first, second;
Pair( int first, int second)
{
this .first = first;
this .second = second;
}
} class GFG{
// Function to find the arrangement // of seating static void findTheOrder( int arr[], String s,
int N)
{ // Stores the row in which the
// ith person sits
List<Integer> ans = new ArrayList<Integer>();
// Stores the width of seats along
// with their index or row number
List<Pair> A = new ArrayList<Pair>();
for ( int i = 0 ; i < N; i++)
{
Pair p = new Pair(arr[i], i + 1 );
A.add(p);
}
// Sort the array
Collections.sort(A, (p1, p2) -> p1.first -
p2.first);
// Store the seats and row for
// boy's seat
PriorityQueue<Pair> q = new PriorityQueue<Pair>(
N, (p1, p2) -> p2.first - p1.first);
// Stores the index of row upto
// which boys have taken seat
int index = 0 ;
// Iterate the string
for ( int i = 0 ; i < 2 * N; i++)
{
if (s.charAt(i) == '0' )
{
// Push the row number at
// index in vector and heap
ans.add(A.get(index).second);
q.add(A.get(index));
// Increment the index to let
// the next boy in the next
// minimum width vacant row
index++;
}
// Otherwise
else
{
// If girl then take top of
// element of the max heap
ans.add(q.peek().second);
// Pop from queue
q.poll();
}
}
// Print the values
for ( int i : ans)
{
System.out.print(i + " " );
}
} // Driver Code public static void main(String[] args)
{ // Given N
int N = 3 ;
// Given arr[]
int arr[] = { 2 , 1 , 3 };
// Given string
String s = "001011" ;
// Function Call
findTheOrder(arr, s, N);
} } // This code is contributed by jithin |
# Python3 program for the above approach # Function to find the arrangement # of seating def findTheOrder(arr, s, N):
# Stores the row in which the
# ith person sits
ans = []
# Stores the width of seats along
# with their index or row number
A = [[] for i in range (N)]
for i in range (N):
A[i] = [arr[i], i + 1 ]
# Sort the array
A = sorted (A)
# Store the seats and row for
# boy's seat
q = []
# Stores the index of row upto
# which boys have taken seat
index = 0
# Iterate the string
for i in range ( 2 * N):
if (s[i] = = '0' ):
# Push the row number at
# index in vector and heap
ans.append(A[index][ 1 ])
q.append(A[index])
# Increment the index to let
# the next boy in the next
# minimum width vacant row
index + = 1
# Otherwise
else :
# If girl then take top of
# element of the max heap
ans.append(q[ - 1 ][ 1 ])
# Pop from queue
del q[ - 1 ]
q = sorted (q)
# Print the values
for i in ans:
print (i, end = " " )
# Driver Code if __name__ = = '__main__' :
# Given N
N = 3
# Given arr[]
arr = [ 2 , 1 , 3 ]
# Given string
s = "001011"
# Function Call
findTheOrder(arr, s, N)
# This code is contributed by mohit kumar 29 |
// C# program for the above approach using System;
using System.Collections.Generic;
class GFG
{ // Function to find the arrangement
// of seating
static void findTheOrder( int [] arr, string s, int N)
{
// Stores the row in which the
// ith person sits
List< int > ans = new List< int >();
// Stores the width of seats along
// with their index or row number
Tuple< int , int >[] A = new Tuple< int , int >[N];
for ( int i = 0; i < N; i++)
A[i] = new Tuple< int , int >(arr[i], i + 1);
// Sort the array
Array.Sort(A);
// Store the seats and row for
// boy's seat
List<Tuple< int , int >> q = new List<Tuple< int , int >>();
// Stores the index of row upto
// which boys have taken seat
int index = 0;
// Iterate the string
for ( int i = 0; i < 2 * N; i++)
{
if (s[i] == '0' )
{
// Push the row number at
// index in vector and heap
ans.Add(A[index].Item2);
q.Add(A[index]);
q.Sort();
q.Reverse();
// Increment the index to let
// the next boy in the next
// minimum width vacant row
index++;
}
// Otherwise
else
{
// If girl then take top of
// element of the max heap
ans.Add(q[0].Item2);
// Pop from queue
q.RemoveAt(0);
}
}
// Print the values
foreach ( int i in ans)
{
Console.Write(i + " " );
}
}
// Driver code
static void Main()
{
// Given N
int N = 3;
// Given arr[]
int [] arr = { 2, 1, 3 };
// Given string
string s = "001011" ;
// Function Call
findTheOrder(arr, s, N);
}
} // This code is contributed by divyesh072019. |
<script> // Javascript program for the above approach // Function to find the arrangement // of seating function findTheOrder(arr, s, N)
{ // Stores the row in which the
// ith person sits
let ans = [];
// Stores the width of seats along
// with their index or row number
let A = [];
for (let i = 0; i < N; i++)
{
let p = [arr[i], i + 1];
A.push(p);
}
// Sort the array
A.sort( function (p1, p2){ return p1[0]-p2[0];});
// Store the seats and row for
// boy's seat
let q = [];
// Stores the index of row upto
// which boys have taken seat
let index = 0;
// Iterate the string
for (let i = 0; i < 2 * N; i++)
{
if (s[i] == '0')
{
// Push the row number at
// index in vector and heap
ans.push(A[index][1]);
q.push(A[index]);
// Increment the index to let
// the next boy in the next
// minimum width vacant row
index++;
}
// Otherwise
else
{
// If girl then take top of
// element of the max heap
ans.push(q[0][1]);
// Pop from queue
q.shift();
}
q.sort( function (a,b){ return b[0]-a[0];});
}
// Print the values
for (let i=0;i< ans.length;i++)
{
document.write(ans[i] + " " );
}
} // Driver Code // Given N let N = 3; // Given arr[] let arr = [ 2, 1, 3 ]; // Given string let s = "001011" ;
// Function Call findTheOrder(arr, s, N); // This code is contributed by patel2127 </script> |
2 1 1 3 3 2
Time Complexity: O(N * log N)
Auxiliary Space: O(N)