Given an array of N integers, the task is to perform the following two queries:
query(start, end) : Print the number of prime numbers in the subarray from start to end
update(i, x) : update the value at index i to x, i.e arr[i] = x
Examples:
Input : arr = {1, 2, 3, 5, 7, 9}
Query 1: query(start = 0, end = 4)
Query 2: update(i = 3, x = 6)
Query 3: query(start = 0, end = 4)
Output :4
3
Explanation:
In Query 1, the subarray [0...4]
has 4 primes viz. {2, 3, 5, 7}
In Query 2, the value at index 3
is updated to 6, the array arr now is, {1, 2, 3,
6, 7, 9}
In Query 3, the subarray [0...4]
has 3 primes viz. {2, 3, 7}
Method 1 (Brute Force): A similar problem can be found here. Here there are no updates.We can modify this to handle updates but for this we need to build the prefix array always when we perform an update which makes the time complexity of this approach O(Q * N)
Method 2 (Efficient): Since, we need to handle both range queries and point updates, a segment tree is best suited for this purpose.
We can use Sieve of Eratosthenes to preprocess all the primes till the maximum value arri can take say MAX in O(MAX log(log(MAX)).
Building the segment tree: We basically reduce the problem to subarray sum using segment tree.
Now, we can build the segment tree where a leaf node is represented as either 0 (if it is not a prime number) or 1 (if it is a prime number).
The internal nodes of the segment tree equal to the sum of its child nodes, thus a node represents the total primes in the range from L to R where the range L to R falls under this node and the sub-tree below it.
Handling Queries and Point Updates: Whenever we get a query from start to end, then we can query the segment tree for the sum of nodes in range start to end, which in turn represent the number of primes in range start to end.
If we need to perform a point update and update the value at index i to x, then we check for the following cases:
Let the old value of arri be y and the new value be x Case 1: If x and y both are primes Count of primes in the subarray does not change so we just update array and donot modify the segment tree Case 2: If x and y both are non primes Count of primes in the subarray does not change so we just update array and donot modify the segment tree Case 3: If y is prime but x is non prime Count of primes in the subarray decreases so we update array and add -1 to every range, the index i which is to be updated, is a part of in the segment tree Case 4: If y is non prime but x is prime Count of primes in the subarray increases so we update array and add 1 to every range, the index i which is to be updated, is a part of in the segment tree
Implementation:
CPP
// C++ program to find number of prime numbers in a // subarray and performing updates#include <bits/stdc++.h>using namespace std;#define MAX 1000void sieveOfEratosthenes(bool isPrime[]){ isPrime[1] = false; for (int p = 2; p * p <= MAX; p++) { // If prime[p] is not changed, then // it is a prime if (isPrime[p] == true) { // Update all multiples of p for (int i = p * 2; i <= MAX; i += p) isPrime[i] = false; } }}// A utility function to get the middle index from corner indexes.int getMid(int s, int e) { return s + (e - s) / 2; }/* A recursive function to get the number of primes in a given range of array indexes. The following are parameters for this function. st --> Pointer to segment tree index --> Index of current node in the segment tree. Initially 0 is passed as root is always at index 0 ss & se --> Starting and ending indexes of the segment represented by current node, i.e., st[index] qs & qe --> Starting and ending indexes of query range */int queryPrimesUtil(int* st, int ss, int se, int qs, int qe, int index){ // If segment of this node is a part of given range, then return // the number of primes in the segment if (qs <= ss && qe >= se) return st[index]; // If segment of this node is outside the given range if (se < qs || ss > qe) return 0; // If a part of this segment overlaps with the given range int mid = getMid(ss, se); return queryPrimesUtil(st, ss, mid, qs, qe, 2 * index + 1) + queryPrimesUtil(st, mid + 1, se, qs, qe, 2 * index + 2);}/* A recursive function to update the nodes which have the given index in their range. The following are parameters st, si, ss and se are same as getSumUtil() i --> index of the element to be updated. This index is in input array. diff --> Value to be added to all nodes which have i in range */void updateValueUtil(int* st, int ss, int se, int i, int diff, int si){ // Base Case: If the input index lies outside the range of // this segment if (i < ss || i > se) return; // If the input index is in range of this node, then update // the value of the node and its children st[si] = st[si] + diff; if (se != ss) { int mid = getMid(ss, se); updateValueUtil(st, ss, mid, i, diff, 2 * si + 1); updateValueUtil(st, mid + 1, se, i, diff, 2 * si + 2); }}// The function to update a value in input array and segment tree.// It uses updateValueUtil() to update the value in segment treevoid updateValue(int arr[], int* st, int n, int i, int new_val, bool isPrime[]){ // Check for erroneous input index if (i < 0 || i > n - 1) { printf("Invalid Input"); return; } int diff, oldValue; oldValue = arr[i]; // Update the value in array arr[i] = new_val; // Case 1: Old and new values both are primes if (isPrime[oldValue] && isPrime[new_val]) return; // Case 2: Old and new values both non primes if ((!isPrime[oldValue]) && (!isPrime[new_val])) return; // Case 3: Old value was prime, new value is non prime if (isPrime[oldValue] && !isPrime[new_val]) { diff = -1; } // Case 4: Old value was non prime, new_val is prime if (!isPrime[oldValue] && isPrime[new_val]) { diff = 1; } // Update the values of nodes in segment tree updateValueUtil(st, 0, n - 1, i, diff, 0);}// Return number of primes in range from index qs (query start) to// qe (query end). It mainly uses queryPrimesUtil()void queryPrimes(int* st, int n, int qs, int qe){ int primesInRange = queryPrimesUtil(st, 0, n - 1, qs, qe, 0); cout << "Number of Primes in subarray from " << qs << " to " << qe << " = " << primesInRange << "\n";}// A recursive function that constructs Segment Tree // for array[ss..se].// si is index of current node in segment tree stint constructSTUtil(int arr[], int ss, int se, int* st, int si, bool isPrime[]){ // If there is one element in array, check if it // is prime then store 1 in the segment tree else // store 0 and return if (ss == se) { // if arr[ss] is prime if (isPrime[arr[ss]]) st[si] = 1; else st[si] = 0; return st[si]; } // If there are more than one elements, then recur // for left and right subtrees and store the sum // of the two values in this node int mid = getMid(ss, se); st[si] = constructSTUtil(arr, ss, mid, st, si * 2 + 1, isPrime) + constructSTUtil(arr, mid + 1, se, st, si * 2 + 2, isPrime); return st[si];}/* Function to construct segment tree from given array. This function allocates memory for segment tree and calls constructSTUtil() to fill the allocated memory */int* constructST(int arr[], int n, bool isPrime[]){ // Allocate memory for segment tree // Height of segment tree int x = (int)(ceil(log2(n))); // Maximum size of segment tree int max_size = 2 * (int)pow(2, x) - 1; int* st = new int[max_size]; // Fill the allocated memory st constructSTUtil(arr, 0, n - 1, st, 0, isPrime); // Return the constructed segment tree return st;}// Driver program to test above functionsint main(){ int arr[] = { 1, 2, 3, 5, 7, 9 }; int n = sizeof(arr) / sizeof(arr[0]); /* Preprocess all primes till MAX. Create a boolean array "isPrime[0..MAX]". A value in prime[i] will finally be false if i is Not a prime, else true. */ bool isPrime[MAX + 1]; memset(isPrime, true, sizeof isPrime); sieveOfEratosthenes(isPrime); // Build segment tree from given array int* st = constructST(arr, n, isPrime); // Query 1: Query(start = 0, end = 4) int start = 0; int end = 4; queryPrimes(st, n, start, end); // Query 2: Update(i = 3, x = 6), i.e Update // a[i] to x int i = 3; int x = 6; updateValue(arr, st, n, i, x, isPrime); // uncomment to see array after update // for(int i = 0; i < n; i++) cout << arr[i] << " "; // Query 3: Query(start = 0, end = 4) start = 0; end = 4; queryPrimes(st, n, start, end); return 0;} |
Java
// Java program to find number of prime numbers in a // subarray and performing updates import java.io.*;import java.util.*;class GFG { static int MAX = 1000 ; static void sieveOfEratosthenes(boolean isPrime[]) { isPrime[1] = false; for (int p = 2; p * p <= MAX; p++) { // If prime[p] is not changed, then // it is a prime if (isPrime[p] == true) { // Update all multiples of p for (int i = p * 2; i <= MAX; i += p) isPrime[i] = false; } } } // A utility function to get the middle index from corner indexes. static int getMid(int s, int e) { return s + (e - s) / 2; } /* A recursive function to get the number of primes in a given range of array indexes. The following are parameters for this function. st --> Pointer to segment tree index --> Index of current node in the segment tree. Initially 0 is passed as root is always at index 0 ss & se --> Starting and ending indexes of the segment represented by current node, i.e., st[index] qs & qe --> Starting and ending indexes of query range */ static int queryPrimesUtil(int[] st, int ss, int se, int qs, int qe, int index) { // If segment of this node is a part of given range, then return // the number of primes in the segment if (qs <= ss && qe >= se) return st[index]; // If segment of this node is outside the given range if (se < qs || ss > qe) return 0; // If a part of this segment overlaps with the given range int mid = getMid(ss, se); return queryPrimesUtil(st, ss, mid, qs, qe, 2 * index + 1) + queryPrimesUtil(st, mid + 1, se, qs, qe, 2 * index + 2); } /* A recursive function to update the nodes which have the given index in their range. The following are parameters st, si, ss and se are same as getSumUtil() i --> index of the element to be updated. This index is in input array. diff --> Value to be added to all nodes which have i in range */ static void updateValueUtil(int[] st, int ss, int se, int i, int diff, int si) { // Base Case: If the input index lies outside the range of // this segment if (i < ss || i > se) return; // If the input index is in range of this node, then update // the value of the node and its children st[si] = st[si] + diff; if (se != ss) { int mid = getMid(ss, se); updateValueUtil(st, ss, mid, i, diff, 2 * si + 1); updateValueUtil(st, mid + 1, se, i, diff, 2 * si + 2); } } // The function to update a value in input array and segment tree. // It uses updateValueUtil() to update the value in segment tree static void updateValue(int arr[], int[] st, int n, int i, int new_val, boolean isPrime[]) { // Check for erroneous input index if (i < 0 || i > n - 1) { System.out.println("Invalid Input"); return; } int diff = 0; int oldValue; oldValue = arr[i]; // Update the value in array arr[i] = new_val; // Case 1: Old and new values both are primes if (isPrime[oldValue] && isPrime[new_val]) return; // Case 2: Old and new values both non primes if ((!isPrime[oldValue]) && (!isPrime[new_val])) return; // Case 3: Old value was prime, new value is non prime if (isPrime[oldValue] && !isPrime[new_val]) { diff = -1; } // Case 4: Old value was non prime, new_val is prime if (!isPrime[oldValue] && isPrime[new_val]) { diff = 1; } // Update the values of nodes in segment tree updateValueUtil(st, 0, n - 1, i, diff, 0); } // Return number of primes in range from index qs (query start) to // qe (query end). It mainly uses queryPrimesUtil() static void queryPrimes(int[] st, int n, int qs, int qe) { int primesInRange = queryPrimesUtil(st, 0, n - 1, qs, qe, 0); System.out.println("Number of Primes in subarray from " + qs + " to " + qe + " = " + primesInRange); } // A recursive function that constructs Segment Tree // for array[ss..se]. // si is index of current node in segment tree st static int constructSTUtil(int arr[], int ss, int se, int[] st, int si, boolean isPrime[]) { // If there is one element in array, check if it // is prime then store 1 in the segment tree else // store 0 and return if (ss == se) { // if arr[ss] is prime if (isPrime[arr[ss]]) st[si] = 1; else st[si] = 0; return st[si]; } // If there are more than one elements, then recur // for left and right subtrees and store the sum // of the two values in this node int mid = getMid(ss, se); st[si] = constructSTUtil(arr, ss, mid, st, si * 2 + 1, isPrime) + constructSTUtil(arr, mid + 1, se, st, si * 2 + 2, isPrime); return st[si]; } /* Function to construct segment tree from given array. This function allocates memory for segment tree and calls constructSTUtil() to fill the allocated memory */ static int[] constructST(int arr[], int n, boolean isPrime[]) { // Allocate memory for segment tree // Height of segment tree int x = (int)(Math.ceil(Math.log(n)/Math.log(2))); // Maximum size of segment tree int max_size = 2 * (int)Math.pow(2, x) - 1; int[] st = new int[max_size]; // Fill the allocated memory st constructSTUtil(arr, 0, n - 1, st, 0, isPrime); // Return the constructed segment tree return st; } // Driver code public static void main (String[] args) { int arr[] = { 1, 2, 3, 5, 7, 9 }; int n = arr.length; /* Preprocess all primes till MAX. Create a boolean array "isPrime[0..MAX]". A value in prime[i] will finally be false if i is Not a prime, else true. */ boolean[] isPrime = new boolean[MAX + 1]; Arrays.fill(isPrime, Boolean.TRUE); sieveOfEratosthenes(isPrime); // Build segment tree from given array int[] st = constructST(arr, n, isPrime); // Query 1: Query(start = 0, end = 4) int start = 0; int end = 4; queryPrimes(st, n, start, end); // Query 2: Update(i = 3, x = 6), i.e Update // a[i] to x int i = 3; int x = 6; updateValue(arr, st, n, i, x, isPrime); // uncomment to see array after update // for(int i = 0; i < n; i++) cout << arr[i] << " "; // Query 3: Query(start = 0, end = 4) start = 0; end = 4; queryPrimes(st, n, start, end); }}// This code is contributed by avanitrachhadiya2155 |
Python3
# Python3 program to find number of prime numbers in a# subarray and performing updatesfrom math import ceil, floor, logMAX = 1000def sieveOfEratosthenes(isPrime): isPrime[1] = False for p in range(2, MAX + 1): if p * p > MAX: break # If prime[p] is not changed, then # it is a prime if (isPrime[p] == True): # Update all multiples of p for i in range(2 * p, MAX + 1, p): isPrime[i] = False# A utility function to get the middle index from corner indexes.def getMid(s, e): return s + (e - s) // 2## /* A recursive function to get the number of primes in a given range# of array indexes. The following are parameters for this function.## st --> Pointer to segment tree# index --> Index of current node in the segment tree. Initially# 0 is passed as root is always at index 0# ss & se --> Starting and ending indexes of the segment represented# by current node, i.e., st[index]# qs & qe --> Starting and ending indexes of query range */def queryPrimesUtil(st, ss, se, qs, qe, index): # If segment of this node is a part of given range, then return # the number of primes in the segment if (qs <= ss and qe >= se): return st[index] # If segment of this node is outside the given range if (se < qs or ss > qe): return 0 # If a part of this segment overlaps with the given range mid = getMid(ss, se) return queryPrimesUtil(st, ss, mid, qs, qe, 2 * index + 1) + \ queryPrimesUtil(st, mid + 1, se, qs, qe, 2 * index + 2)# /* A recursive function to update the nodes which have the given# index in their range. The following are parameters# st, si, ss and se are same as getSumUtil()# i --> index of the element to be updated. This index is# in input array.# diff --> Value to be added to all nodes which have i in range */def updateValueUtil(st, ss, se, i, diff, si): # Base Case: If the input index lies outside the range of # this segment if (i < ss or i > se): return # If the input index is in range of this node, then update # the value of the node and its children st[si] = st[si] + diff if (se != ss): mid = getMid(ss, se) updateValueUtil(st, ss, mid, i, diff, 2 * si + 1) updateValueUtil(st, mid + 1, se, i, diff, 2 * si + 2)# The function to update a value in input array and segment tree.# It uses updateValueUtil() to update the value in segment treedef updateValue(arr,st, n, i, new_val,isPrime): # Check for erroneous input index if (i < 0 or i > n - 1): printf("Invalid Input") return diff, oldValue = 0, 0 oldValue = arr[i] # Update the value in array arr[i] = new_val # Case 1: Old and new values both are primes if (isPrime[oldValue] and isPrime[new_val]): return # Case 2: Old and new values both non primes if ((not isPrime[oldValue]) and (not isPrime[new_val])): return # Case 3: Old value was prime, new value is non prime if (isPrime[oldValue] and not isPrime[new_val]): diff = -1 # Case 4: Old value was non prime, new_val is prime if (not isPrime[oldValue] and isPrime[new_val]): diff = 1 # Update the values of nodes in segment tree updateValueUtil(st, 0, n - 1, i, diff, 0)# Return number of primes in range from index qs (query start) to# qe (query end). It mainly uses queryPrimesUtil()def queryPrimes(st, n, qs, qe): primesInRange = queryPrimesUtil(st, 0, n - 1, qs, qe, 0) print("Number of Primes in subarray from ", qs," to ", qe," = ", primesInRange)# A recursive function that constructs Segment Tree# for array[ss..se].# si is index of current node in segment tree stdef constructSTUtil(arr, ss, se, st,si,isPrime): # If there is one element in array, check if it # is prime then store 1 in the segment tree else # store 0 and return if (ss == se): # if arr[ss] is prime if (isPrime[arr[ss]]): st[si] = 1 else: st[si] = 0 return st[si] # If there are more than one elements, then recur # for left and right subtrees and store the sum # of the two values in this node mid = getMid(ss, se) st[si] = constructSTUtil(arr, ss, mid, st,si * 2 + 1, isPrime) + \ constructSTUtil(arr, mid + 1, se, st,si * 2 + 2, isPrime) return st[si]# /* Function to construct segment tree from given array.# This function allocates memory for segment tree and# calls constructSTUtil() to fill the allocated memory */def constructST(arr, n, isPrime): # Allocate memory for segment tree # Height of segment tree x = ceil(log(n, 2)) # Maximum size of segment tree max_size = 2 * pow(2, x) - 1 st = [0]*(max_size) # Fill the allocated memory st constructSTUtil(arr, 0, n - 1, st, 0, isPrime) # Return the constructed segment tree return st# Driver codeif __name__ == '__main__': arr= [ 1, 2, 3, 5, 7, 9] n = len(arr) # /* Preprocess all primes till MAX. # Create a boolean array "isPrime[0..MAX]". # A value in prime[i] will finally be false # if i is Not a prime, else true. */ isPrime = [True]*(MAX + 1) sieveOfEratosthenes(isPrime) # Build segment tree from given array st = constructST(arr, n, isPrime) # Query 1: Query(start = 0, end = 4) start = 0 end = 4 queryPrimes(st, n, start, end) # Query 2: Update(i = 3, x = 6), i.e Update # a[i] to x i = 3 x = 6 updateValue(arr, st, n, i, x, isPrime) # uncomment to see array after update # for(i = 0 i < n i++) cout << arr[i] << " " # Query 3: Query(start = 0, end = 4) start = 0 end = 4 queryPrimes(st, n, start, end)# This code is contributed by mohit kumar 29 |
C#
// C# program to find number of prime numbers in a // subarray and performing updates using System;public class GFG{ static int MAX = 1000 ; static void sieveOfEratosthenes(bool[] isPrime) { isPrime[1] = false; for (int p = 2; p * p <= MAX; p++) { // If prime[p] is not changed, then // it is a prime if (isPrime[p] == true) { // Update all multiples of p for (int i = p * 2; i <= MAX; i += p) isPrime[i] = false; } } } // A utility function to get the middle index from corner indexes. static int getMid(int s, int e) { return s + (e - s) / 2; } /* A recursive function to get the number of primes in a given range of array indexes. The following are parameters for this function. st --> Pointer to segment tree index --> Index of current node in the segment tree. Initially 0 is passed as root is always at index 0 ss & se --> Starting and ending indexes of the segment represented by current node, i.e., st[index] qs & qe --> Starting and ending indexes of query range */ static int queryPrimesUtil(int[] st, int ss, int se, int qs, int qe, int index) { // If segment of this node is a part of given range, then return // the number of primes in the segment if (qs <= ss && qe >= se) return st[index]; // If segment of this node is outside the given range if (se < qs || ss > qe) return 0; // If a part of this segment overlaps with the given range int mid = getMid(ss, se); return queryPrimesUtil(st, ss, mid, qs, qe, 2 * index + 1) + queryPrimesUtil(st, mid + 1, se, qs, qe, 2 * index + 2); } /* A recursive function to update the nodes which have the given index in their range. The following are parameters st, si, ss and se are same as getSumUtil() i --> index of the element to be updated. This index is in input array. diff --> Value to be added to all nodes which have i in range */ static void updateValueUtil(int[] st, int ss, int se, int i, int diff, int si) { // Base Case: If the input index lies outside the range of // this segment if (i < ss || i > se) return; // If the input index is in range of this node, then update // the value of the node and its children st[si] = st[si] + diff; if (se != ss) { int mid = getMid(ss, se); updateValueUtil(st, ss, mid, i, diff, 2 * si + 1); updateValueUtil(st, mid + 1, se, i, diff, 2 * si + 2); } } // The function to update a value in input array and segment tree. // It uses updateValueUtil() to update the value in segment tree static void updateValue(int[] arr, int[] st, int n, int i, int new_val, bool[] isPrime) { // Check for erroneous input index if (i < 0 || i > n - 1) { Console.WriteLine("Invalid Input"); return; } int diff = 0; int oldValue; oldValue = arr[i]; // Update the value in array arr[i] = new_val; // Case 1: Old and new values both are primes if (isPrime[oldValue] && isPrime[new_val]) return; // Case 2: Old and new values both non primes if ((!isPrime[oldValue]) && (!isPrime[new_val])) return; // Case 3: Old value was prime, new value is non prime if (isPrime[oldValue] && !isPrime[new_val]) { diff = -1; } // Case 4: Old value was non prime, new_val is prime if (!isPrime[oldValue] && isPrime[new_val]) { diff = 1; } // Update the values of nodes in segment tree updateValueUtil(st, 0, n - 1, i, diff, 0); } // Return number of primes in range from index qs (query start) to // qe (query end). It mainly uses queryPrimesUtil() static void queryPrimes(int[] st, int n, int qs, int qe) { int primesInRange = queryPrimesUtil(st, 0, n - 1, qs, qe, 0); Console.WriteLine("Number of Primes in subarray from " + qs + " to " + qe + " = " + primesInRange); } // A recursive function that constructs Segment Tree // for array[ss..se]. // si is index of current node in segment tree st static int constructSTUtil(int[] arr, int ss, int se, int[] st, int si, bool[] isPrime) { // If there is one element in array, check if it // is prime then store 1 in the segment tree else // store 0 and return if (ss == se) { // if arr[ss] is prime if (isPrime[arr[ss]]) st[si] = 1; else st[si] = 0; return st[si]; } // If there are more than one elements, then recur // for left and right subtrees and store the sum // of the two values in this node int mid = getMid(ss, se); st[si] = constructSTUtil(arr, ss, mid, st, si * 2 + 1, isPrime) + constructSTUtil(arr, mid + 1, se, st, si * 2 + 2, isPrime); return st[si]; } /* Function to construct segment tree from given array. This function allocates memory for segment tree and calls constructSTUtil() to fill the allocated memory */ static int[] constructST(int[] arr, int n, bool[] isPrime) { // Allocate memory for segment tree // Height of segment tree int x = (int)(Math.Ceiling(Math.Log(n) / Math.Log(2))); // Maximum size of segment tree int max_size = 2 * (int)Math.Pow(2, x) - 1; int[] st = new int[max_size]; // Fill the allocated memory st constructSTUtil(arr, 0, n - 1, st, 0, isPrime); // Return the constructed segment tree return st; } // Driver code static public void Main () { int[] arr = { 1, 2, 3, 5, 7, 9 }; int n = arr.Length; /* Preprocess all primes till MAX. Create a boolean array "isPrime[0..MAX]". A value in prime[i] will finally be false if i is Not a prime, else true. */ bool[] isPrime = new bool[MAX + 1]; Array.Fill(isPrime, true); sieveOfEratosthenes(isPrime); // Build segment tree from given array int[] st = constructST(arr, n, isPrime); // Query 1: Query(start = 0, end = 4) int start = 0; int end = 4; queryPrimes(st, n, start, end); // Query 2: Update(i = 3, x = 6), i.e Update // a[i] to x int i = 3; int x = 6; updateValue(arr, st, n, i, x, isPrime); // uncomment to see array after update // for(int i = 0; i < n; i++) cout << arr[i] << " "; // Query 3: Query(start = 0, end = 4) start = 0; end = 4; queryPrimes(st, n, start, end); }}// This code is contributed by rag2127 |
Javascript
<script>// Javascript program to find number of prime numbers in a// subarray and performing updateslet MAX = 1000;function sieveOfEratosthenes(isPrime) { isPrime[1] = false; for (let p = 2; p * p <= MAX; p++) { // If prime[p] is not changed, then // it is a prime if (isPrime[p] == true) { // Update all multiples of p for (let i = p * 2; i <= MAX; i += p) isPrime[i] = false; } }}// A utility function to get the middle index from corner indexes.function getMid(s, e) { return Math.floor(s + (e - s) / 2); }/* A recursive function to get the number of primes in a given rangeof array indexes. The following are parameters for this function. st --> Pointer to segment treeindex --> Index of current node in the segment tree. Initially 0 is passed as root is always at index 0ss & se --> Starting and ending indexes of the segment represented by current node, i.e., st[index]qs & qe --> Starting and ending indexes of query range */function queryPrimesUtil(st, ss, se, qs, qe, index) { // If segment of this node is a part of given range, then return // the number of primes in the segment if (qs <= ss && qe >= se) return st[index]; // If segment of this node is outside the given range if (se < qs || ss > qe) return 0; // If a part of this segment overlaps with the given range let mid = getMid(ss, se); return queryPrimesUtil(st, ss, mid, qs, qe, 2 * index + 1) + queryPrimesUtil(st, mid + 1, se, qs, qe, 2 * index + 2);}/* A recursive function to update the nodes which have the givenindex in their range. The following are parametersst, si, ss and se are same as getSumUtil()i --> index of the element to be updated. This index is in input array.diff --> Value to be added to all nodes which have i in range */function updateValueUtil(st, ss, se, i, diff, si) { // Base Case: If the input index lies outside the range of // this segment if (i < ss || i > se) return; // If the input index is in range of this node, then update // the value of the node and its children st[si] = st[si] + diff; if (se != ss) { let mid = getMid(ss, se); updateValueUtil(st, ss, mid, i, diff, 2 * si + 1); updateValueUtil(st, mid + 1, se, i, diff, 2 * si + 2); }}// The function to update a value in input array and segment tree.// It uses updateValueUtil() to update the value in segment treefunction updateValue(arr, st, n, i, new_val, isPrime) { // Check for erroneous input index if (i < 0 || i > n - 1) { document.write("Invalid Input"); return; } let diff = 0; let oldValue; oldValue = arr[i]; // Update the value in array arr[i] = new_val; // Case 1: Old and new values both are primes if (isPrime[oldValue] && isPrime[new_val]) return; // Case 2: Old and new values both non primes if ((!isPrime[oldValue]) && (!isPrime[new_val])) return; // Case 3: Old value was prime, new value is non prime if (isPrime[oldValue] && !isPrime[new_val]) { diff = -1; } // Case 4: Old value was non prime, new_val is prime if (!isPrime[oldValue] && isPrime[new_val]) { diff = 1; } // Update the values of nodes in segment tree updateValueUtil(st, 0, n - 1, i, diff, 0);}// Return number of primes in range from index qs (query start) to// qe (query end). It mainly uses queryPrimesUtil()function queryPrimes(st, n, qs, qe) { let primesInRange = queryPrimesUtil(st, 0, n - 1, qs, qe, 0); document.write("Number of Primes in subarray from " + qs + " to " + qe + " = " + primesInRange + "<br>");}// A recursive function that constructs Segment Tree// for array[ss..se].// si is index of current node in segment tree stfunction constructSTUtil(arr, ss, se, st, si, isPrime) { // If there is one element in array, check if it // is prime then store 1 in the segment tree else // store 0 and return if (ss == se) { // if arr[ss] is prime if (isPrime[arr[ss]]) st[si] = 1; else st[si] = 0; return st[si]; } // If there are more than one elements, then recur // for left and right subtrees and store the sum // of the two values in this node let mid = getMid(ss, se); st[si] = constructSTUtil(arr, ss, mid, st, si * 2 + 1, isPrime) + constructSTUtil(arr, mid + 1, se, st, si * 2 + 2, isPrime); return st[si];}/* Function to construct segment tree from given array.This function allocates memory for segment tree andcalls constructSTUtil() to fill the allocated memory */function constructST(arr, n, isPrime) { // Allocate memory for segment tree // Height of segment tree let x = (Math.ceil(Math.log(n) / Math.log(2))); // Maximum size of segment tree let max_size = 2 * Math.pow(2, x) - 1; let st = new Array(max_size); // Fill the allocated memory st constructSTUtil(arr, 0, n - 1, st, 0, isPrime); // Return the constructed segment tree return st;}// Driver codelet arr = [1, 2, 3, 5, 7, 9];let n = arr.length;/* Preprocess all primes till MAX.Create a boolean array "isPrime[0..MAX]".A value in prime[i] will finally be falseif i is Not a prime, else true. */let isPrime = new Array(MAX + 1);isPrime.fill(true);sieveOfEratosthenes(isPrime);// Build segment tree from given arraylet st = constructST(arr, n, isPrime);// Query 1: Query(start = 0, end = 4)let start = 0;let end = 4;queryPrimes(st, n, start, end);// Query 2: Update(i = 3, x = 6), i.e Update// a[i] to xlet i = 3;let x = 6;updateValue(arr, st, n, i, x, isPrime);// uncomment to see array after update// for(let i = 0; i < n; i++) cout << arr[i] << " ";// Query 3: Query(start = 0, end = 4)start = 0;end = 4;queryPrimes(st, n, start, end);// This code is contributed by gfgking</script> |
Output
Number of Primes in subarray from 0 to 4 = 4 Number of Primes in subarray from 0 to 4 = 3
The time complexity of each query and update is O(logn) and that of building the segment tree is O(n)
Note: Here, the time complexity of pre-processing primes till MAX using the sieve of Eratosthenes is O(MAX log(log(MAX))) where MAX is the maximum value arri can take.
Auxiliary Space: O(MAX+n)
Related Topic: Segment Tree
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