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Belirli bir aralıktaki bir sayının sahip olduğu maksimum bölen sayısını sorgulama

Verilen Q türündeki sorgular: Sol Sağ her sorgu için bir sayının belirlediği maksimum bölen sayısını yazdırmanız gerekir. x (L<= x <= R) sahip olmak. 
Örnekler:  
 

  L = 1 R = 10  : 1 has 1 divisor. 2 has 2 divisors. 3 has 2 divisors. 4 has 3 divisors. 5 has 2 divisors. 6 has 4 divisors. 7 has 2 divisors. 8 has 4 divisors. 9 has 3 divisors. 10 has 4 divisors. So the answer for above query is 4 as it is the maximum number of divisors a number has in [1 10].


 


Önkoşullar: Eratostenes Eleği Segment Ağacı
Aşağıda sorunu çözmeye yönelik adımlar verilmiştir.
 



  1. Öncelikle bir sayının kaç böleni olduğunu görelim n = p1k1* P2k2* ... * PNkN (burada p1P2... PNasal sayılardır) sahiptir; cevap şu (k1+ 1)*(k2+ 1)*...*(kN+ 1) . Nasıl? Asal çarpanlara ayırmadaki her asal sayı için kBen+ 1 bir bölenin olası kuvvetleri (0 1 2... kBen).
  2. Şimdi öncelikle dizi oluşturduğumuz bir sayının asal çarpanlarına ayrılmasını nasıl bulacağımızı görelim. en küçük_prime[] en küçük asal bölenini saklayan Ben en Beno indeks yeni bir sayı elde etmek için bir sayıyı en küçük asal bölenine böleriz (aynı zamanda bu yeni sayının en küçük asal bölenini de saklarız) yeni sayının en küçük asal çarpanı önceki sayıdan farklı olduğunda sayının en küçük asal çarpanı değişene kadar bunu yapmaya devam ederiz kBenben içinbuVerilen sayının asal çarpanlarına ayrılmasında asal sayı.
  3. Son olarak tüm sayıların bölen sayısını elde ederiz ve bunları segmentlerdeki maksimum sayıları koruyan bir segment ağacında saklarız. Her sorguya segment ağacını sorgulayarak yanıt veriyoruz.


 

C++ 
// A C++ implementation of the above idea to process // queries of finding a number with maximum divisors. #include    using namespace std; #define maxn 1000005 #define INF 99999999 int smallest_prime[maxn]; int divisors[maxn]; int segmentTree[4 * maxn]; // Finds smallest prime factor of all numbers in // range[1 maxn) and stores them in smallest_prime[] // smallest_prime[i] should contain the smallest prime // that divides i void findSmallestPrimeFactors() {  // Initialize the smallest_prime factors of all  // to infinity  for (int i = 0 ; i < maxn ; i ++ )  smallest_prime[i] = INF;  // to be built like eratosthenes sieve  for (long long i = 2; i < maxn; i++)  {  if (smallest_prime[i] == INF)  {  // prime number will have its smallest_prime  // equal to itself  smallest_prime[i] = i;  for (long long j = i * i; j < maxn; j += i)  // if 'i' is the first prime number reaching 'j'  if (smallest_prime[j] > i)  smallest_prime[j] = i;  }  } } // number of divisors of n = (p1 ^ k1) * (p2 ^ k2) ... (pn ^ kn) // are equal to (k1+1) * (k2+1) ... (kn+1) // this function finds the number of divisors of all numbers // in range [1 maxn) and stores it in divisors[] // divisors[i] stores the number of divisors i has void buildDivisorsArray() {  for (int i = 1; i < maxn; i++)  {  divisors[i] = 1;  int n = i p = smallest_prime[i] k = 0;  // we can obtain the prime factorization of the number n  // n = (p1 ^ k1) * (p2 ^ k2) ... (pn ^ kn) using the  // smallest_prime[] array we keep dividing n by its  // smallest_prime until it becomes 1 whilst we check  // if we have need to set k zero  while (n > 1)  {  n = n / p;  k ++;  if (smallest_prime[n] != p)  {  //use p^k initialize k to 0  divisors[i] = divisors[i] * (k + 1);  k = 0;  }  p = smallest_prime[n];  }  } } // builds segment tree for divisors[] array void buildSegtmentTree(int node int a int b) {  // leaf node  if (a == b)  {  segmentTree[node] = divisors[a];  return ;  }  //build left and right subtree  buildSegtmentTree(2 * node a (a + b) / 2);  buildSegtmentTree(2 * node + 1 ((a + b) / 2) + 1 b);  //combine the information from left  //and right subtree at current node  segmentTree[node] = max(segmentTree[2 * node]  segmentTree[2 *node + 1]); } //returns the maximum number of divisors in [l r] int query(int node int a int b int l int r) {  // If current node's range is disjoint with query range  if (l > b || a > r)  return -1;  // If the current node stores information for the range  // that is completely inside the query range  if (a >= l && b <= r)  return segmentTree[node];  // Returns maximum number of divisors from left  // or right subtree  return max(query(2 * node a (a + b) / 2 l r)  query(2 * node + 1 ((a + b) / 2) + 1 blr)); } // driver code int main() {  // First find smallest prime divisors for all  // the numbers  findSmallestPrimeFactors();  // Then build the divisors[] array to store  // the number of divisors  buildDivisorsArray();  // Build segment tree for the divisors[] array  buildSegtmentTree(1 1 maxn - 1);  cout << 'Maximum divisors that a number has '  << ' in [1 100] are '  << query(1 1 maxn - 1 1 100) << endl;  cout << 'Maximum divisors that a number has'  << ' in [10 48] are '  << query(1 1 maxn - 1 10 48) << endl;  cout << 'Maximum divisors that a number has'  << ' in [1 10] are '  << query(1 1 maxn - 1 1 10) << endl;  return 0; }
Java 
// Java implementation of the above idea to process // queries of finding a number with maximum divisors. import java.util.*; class GFG { static int maxn = 10005; static int INF = 999999; static int []smallest_prime = new int[maxn]; static int []divisors = new int[maxn]; static int []segmentTree = new int[4 * maxn]; // Finds smallest prime factor of all numbers  // in range[1 maxn) and stores them in  // smallest_prime[] smallest_prime[i] should  // contain the smallest prime that divides i static void findSmallestPrimeFactors() {  // Initialize the smallest_prime factors   // of all to infinity  for (int i = 0 ; i < maxn ; i ++ )  smallest_prime[i] = INF;  // to be built like eratosthenes sieve  for (int i = 2; i < maxn; i++)  {  if (smallest_prime[i] == INF)  {  // prime number will have its   // smallest_prime equal to itself  smallest_prime[i] = i;  for (int j = i * i; j < maxn; j += i)  // if 'i' is the first  // prime number reaching 'j'  if (smallest_prime[j] > i)  smallest_prime[j] = i;  }  } } // number of divisors of n = (p1 ^ k1) * (p2 ^ k2) ... (pn ^ kn) // are equal to (k1+1) * (k2+1) ... (kn+1) // this function finds the number of divisors of all numbers // in range [1 maxn) and stores it in divisors[] // divisors[i] stores the number of divisors i has static void buildDivisorsArray() {  for (int i = 1; i < maxn; i++)  {  divisors[i] = 1;  int n = i p = smallest_prime[i] k = 0;  // we can obtain the prime factorization of   // the number n n = (p1 ^ k1) * (p2 ^ k2) ... (pn ^ kn)   // using the smallest_prime[] array we keep dividing n   // by its smallest_prime until it becomes 1   // whilst we check if we have need to set k zero  while (n > 1)  {  n = n / p;  k ++;  if (smallest_prime[n] != p)  {  // use p^k initialize k to 0  divisors[i] = divisors[i] * (k + 1);  k = 0;  }  p = smallest_prime[n];  }  } } // builds segment tree for divisors[] array static void buildSegtmentTree(int node int a int b) {  // leaf node  if (a == b)  {  segmentTree[node] = divisors[a];  return ;  }  //build left and right subtree  buildSegtmentTree(2 * node a (a + b) / 2);  buildSegtmentTree(2 * node + 1 ((a + b) / 2) + 1 b);  //combine the information from left  //and right subtree at current node  segmentTree[node] = Math.max(segmentTree[2 * node]  segmentTree[2 *node + 1]); } // returns the maximum number of divisors in [l r] static int query(int node int a int b int l int r) {  // If current node's range is disjoint  // with query range  if (l > b || a > r)  return -1;  // If the current node stores information   // for the range that is completely inside  // the query range  if (a >= l && b <= r)  return segmentTree[node];  // Returns maximum number of divisors from left  // or right subtree  return Math.max(query(2 * node a (a + b) / 2 l r)  query(2 * node + 1   ((a + b) / 2) + 1 b l r)); } // Driver Code public static void main(String[] args)  {    // First find smallest prime divisors   // for all the numbers  findSmallestPrimeFactors();  // Then build the divisors[] array to store  // the number of divisors  buildDivisorsArray();  // Build segment tree for the divisors[] array  buildSegtmentTree(1 1 maxn - 1);  System.out.println('Maximum divisors that a number ' +   'has in [1 100] are ' +   query(1 1 maxn - 1 1 100));  System.out.println('Maximum divisors that a number ' +   'has in [10 48] are ' +   query(1 1 maxn - 1 10 48));  System.out.println('Maximum divisors that a number ' +   'has in [1 10] are ' +   query(1 1 maxn - 1 1 10));  } } // This code is contributed by PrinciRaj1992
Python 3 
# Python 3 implementation of the above  # idea to process queries of finding a # number with maximum divisors. maxn = 1000005 INF = 99999999 smallest_prime = [0] * maxn divisors = [0] * maxn segmentTree = [0] * (4 * maxn) # Finds smallest prime factor of all  # numbers in range[1 maxn) and stores  # them in smallest_prime[] smallest_prime[i]  # should contain the smallest prime that divides i def findSmallestPrimeFactors(): # Initialize the smallest_prime  # factors of all to infinity for i in range(maxn ): smallest_prime[i] = INF # to be built like eratosthenes sieve for i in range(2 maxn): if (smallest_prime[i] == INF): # prime number will have its  # smallest_prime equal to itself smallest_prime[i] = i for j in range(i * i maxn  i): # if 'i' is the first prime # number reaching 'j' if (smallest_prime[j] > i): smallest_prime[j] = i # number of divisors of n = (p1 ^ k1) *  # (p2 ^ k2) ... (pn ^ kn) are equal to  # (k1+1) * (k2+1) ... (kn+1). This function # finds the number of divisors of all numbers # in range [1 maxn) and stores it in divisors[] # divisors[i] stores the number of divisors i has def buildDivisorsArray(): for i in range(1 maxn): divisors[i] = 1 n = i p = smallest_prime[i] k = 0 # we can obtain the prime factorization  # of the number n n = (p1 ^ k1) * (p2 ^ k2)  # ... (pn ^ kn) using the smallest_prime[]  # array we keep dividing n by its  # smallest_prime until it becomes 1 whilst  # we check if we have need to set k zero while (n > 1): n = n // p k += 1 if (smallest_prime[n] != p): # use p^k initialize k to 0 divisors[i] = divisors[i] * (k + 1) k = 0 p = smallest_prime[n] # builds segment tree for divisors[] array def buildSegtmentTree( node a b): # leaf node if (a == b): segmentTree[node] = divisors[a] return #build left and right subtree buildSegtmentTree(2 * node a (a + b) // 2) buildSegtmentTree(2 * node + 1 ((a + b) // 2) + 1 b) #combine the information from left #and right subtree at current node segmentTree[node] = max(segmentTree[2 * node] segmentTree[2 * node + 1]) # returns the maximum number of  # divisors in [l r] def query(node a b l r): # If current node's range is disjoint # with query range if (l > b or a > r): return -1 # If the current node stores information  # for the range that is completely inside  # the query range if (a >= l and b <= r): return segmentTree[node] # Returns maximum number of divisors  # from left or right subtree return max(query(2 * node a (a + b) // 2 l r) query(2 * node + 1 ((a + b) // 2) + 1 b l r)) # Driver code if __name__ == '__main__': # First find smallest prime divisors  # for all the numbers findSmallestPrimeFactors() # Then build the divisors[] array to  # store the number of divisors buildDivisorsArray() # Build segment tree for the divisors[] array buildSegtmentTree(1 1 maxn - 1) print('Maximum divisors that a number has ' ' in [1 100] are ' query(1 1 maxn - 1 1 100)) print('Maximum divisors that a number has' ' in [10 48] are ' query(1 1 maxn - 1 10 48)) print( 'Maximum divisors that a number has' ' in [1 10] are ' query(1 1 maxn - 1 1 10)) # This code is contributed by ita_c
C# 
// C# implementation of the above idea  // to process queries of finding a number // with maximum divisors. using System;   class GFG { static int maxn = 10005; static int INF = 999999; static int []smallest_prime = new int[maxn]; static int []divisors = new int[maxn]; static int []segmentTree = new int[4 * maxn]; // Finds smallest prime factor of all numbers  // in range[1 maxn) and stores them in  // smallest_prime[] smallest_prime[i] should  // contain the smallest prime that divides i static void findSmallestPrimeFactors() {  // Initialize the smallest_prime   // factors of all to infinity  for (int i = 0 ; i < maxn ; i ++ )  smallest_prime[i] = INF;  // to be built like eratosthenes sieve  for (int i = 2; i < maxn; i++)  {  if (smallest_prime[i] == INF)  {  // prime number will have its   // smallest_prime equal to itself  smallest_prime[i] = i;  for (int j = i * i; j < maxn; j += i)  // if 'i' is the first  // prime number reaching 'j'  if (smallest_prime[j] > i)  smallest_prime[j] = i;  }  } } // number of divisors of  // n = (p1 ^ k1) * (p2 ^ k2) ... (pn ^ kn) // are equal to (k1+1) * (k2+1) ... (kn+1) // this function finds the number of divisors  // of all numbers in range [1 maxn) and stores  // it in divisors[] divisors[i] stores the // number of divisors i has static void buildDivisorsArray() {  for (int i = 1; i < maxn; i++)  {  divisors[i] = 1;  int n = i p = smallest_prime[i] k = 0;  // we can obtain the prime factorization of   // the number n   // n = (p1 ^ k1) * (p2 ^ k2) ... (pn ^ kn)   // using the smallest_prime[] array   // we keep dividing n by its smallest_prime   // until it becomes 1 whilst we check if  // we have need to set k zero  while (n > 1)  {  n = n / p;  k ++;  if (smallest_prime[n] != p)  {  // use p^k initialize k to 0  divisors[i] = divisors[i] * (k + 1);  k = 0;  }  p = smallest_prime[n];  }  } } // builds segment tree for divisors[] array static void buildSegtmentTree(int node   int a int b) {  // leaf node  if (a == b)  {  segmentTree[node] = divisors[a];  return;  }  //build left and right subtree  buildSegtmentTree(2 * node a (a + b) / 2);  buildSegtmentTree(2 * node + 1   ((a + b) / 2) + 1 b);  //combine the information from left  //and right subtree at current node  segmentTree[node] = Math.Max(segmentTree[2 * node]  segmentTree[2 *node + 1]); } // returns the maximum number of divisors in [l r] static int query(int node int a int b int l int r) {  // If current node's range is disjoint  // with query range  if (l > b || a > r)  return -1;  // If the current node stores information   // for the range that is completely inside  // the query range  if (a >= l && b <= r)  return segmentTree[node];  // Returns maximum number of divisors from left  // or right subtree  return Math.Max(query(2 * node a (a + b) / 2 l r)  query(2 * node + 1   ((a + b) / 2) + 1 b l r)); } // Driver Code public static void Main(String[] args)  {    // First find smallest prime divisors   // for all the numbers  findSmallestPrimeFactors();  // Then build the divisors[] array   // to store the number of divisors  buildDivisorsArray();  // Build segment tree for the divisors[] array  buildSegtmentTree(1 1 maxn - 1);  Console.WriteLine('Maximum divisors that a number ' +   'has in [1 100] are ' +   query(1 1 maxn - 1 1 100));  Console.WriteLine('Maximum divisors that a number ' +   'has in [10 48] are ' +   query(1 1 maxn - 1 10 48));  Console.WriteLine('Maximum divisors that a number ' +   'has in [1 10] are ' +   query(1 1 maxn - 1 1 10));  } } // This code is contributed by 29AjayKumar
JavaScript 
<script> // JavaScript implementation of the above idea to process // queries of finding a number with maximum divisors.    let maxn = 10005;  let INF = 999999;  let smallest_prime = new Array(maxn);  for(let i=0;i<maxn;i++)  {  smallest_prime[i]=0;  }  let divisors = new Array(maxn);  for(let i=0;i<maxn;i++)  {  divisors[i]=0;  }  let segmentTree = new Array(4 * maxn);  for(let i=0;i<4*maxn;i++)  {  segmentTree[i]=0;  }    // Finds smallest prime factor of all numbers   // in range[1 maxn) and stores them in   // smallest_prime[] smallest_prime[i] should   // contain the smallest prime that divides i  function findSmallestPrimeFactors()  {  // Initialize the smallest_prime factors   // of all to infinity  for (let i = 0 ; i < maxn ; i ++ )  smallest_prime[i] = INF;    // to be built like eratosthenes sieve  for (let i = 2; i < maxn; i++)  {  if (smallest_prime[i] == INF)  {  // prime number will have its   // smallest_prime equal to itself  smallest_prime[i] = i;  for (let j = i * i; j < maxn; j += i)  {   // if 'i' is the first  // prime number reaching 'j'  if (smallest_prime[j] > i)  smallest_prime[j] = i;  }  }  }  }    // number of divisors of n = (p1 ^ k1) * (p2 ^ k2) ... (pn ^ kn)  // are equal to (k1+1) * (k2+1) ... (kn+1)  // this function finds the number of divisors of all numbers  // in range [1 maxn) and stores it in divisors[]  // divisors[i] stores the number of divisors i has  function buildDivisorsArray()  {  for (let i = 1; i < maxn; i++)  {  divisors[i] = 1;  let n = i;  let p = smallest_prime[i]  let k = 0;    // we can obtain the prime factorization of   // the number n n = (p1 ^ k1) * (p2 ^ k2) ... (pn ^ kn)   // using the smallest_prime[] array we keep dividing n   // by its smallest_prime until it becomes 1   // whilst we check if we have need to set k zero  while (n > 1)  {  n = Math.floor(n / p);  k++;    if (smallest_prime[n] != p)  {  // use p^k initialize k to 0  divisors[i] = divisors[i] * (k + 1);  k = 0;  }  p = smallest_prime[n];  }  }  }    // builds segment tree for divisors[] array  function buildSegtmentTree(nodeab)  {  // leaf node  if (a == b)  {  segmentTree[node] = divisors[a];  return ;  }    //build left and right subtree  buildSegtmentTree(2 * node a Math.floor((a + b) / 2));  buildSegtmentTree((2 * node) + 1 Math.floor((a + b) / 2) + 1 b);    //combine the information from left  //and right subtree at current node  segmentTree[node] = Math.max(segmentTree[2 * node]  segmentTree[(2 *node) + 1]);  }    // returns the maximum number of divisors in [l r]  function query(nodeablr)  {  // If current node's range is disjoint  // with query range  if (l > b || a > r)  return -1;    // If the current node stores information   // for the range that is completely inside  // the query range  if (a >= l && b <= r)  return segmentTree[node];    // Returns maximum number of divisors from left  // or right subtree  return Math.max(query(2 * node a   Math.floor((a + b) / 2) l r)  query(2 * node + 1  Math.floor((a + b) / 2) + 1 b l r));  }  // Driver Code    // First find smallest prime divisors   // for all the numbers  findSmallestPrimeFactors();    // Then build the divisors[] array to store  // the number of divisors  buildDivisorsArray();    // Build segment tree for the divisors[] array  buildSegtmentTree(1 1 maxn - 1);    document.write('Maximum divisors that a number ' +  'has in [1 100] are ' + query(1 1 maxn - 1 1 100)+'  
');      document.write('Maximum divisors that a number ' +   'has in [10 48] are ' +   query(1 1 maxn - 1 10 48)+'  
');      document.write('Maximum divisors that a number ' +   'has in [1 10] are ' +   query(1 1 maxn - 1 1 10)+'  
');    // This code is contributed by avanitrachhadiya2155   </script>

Çıkış:  
 

Maximum divisors that a number has in [1 100] are 12 Maximum divisors that a number has in [10 48] are 10 Maximum divisors that a number has in [1 10] are 4

Zaman Karmaşıklığı:  O((maksn + Q) * log(maksn))

  • Elek için: O(maksn * log(log(maksn)) )
  • Her sayının bölenlerini hesaplamak için: Peki1 + k2 + ... + kn) < O(log(maksn))
  • Her aralığı sorgulamak için: O(log(maksn))

Yardımcı Alan: Açık)

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