NÄRMASTE PRIMTAL MINDRE ÄN GIVET TAL N

Du får ett nummer n (3<= n < 10^6 ) and you have to find nearest prime less than n?

Exempel:

string.format

Input : n = 10 Output: 7 Input : n = 17 Output: 13 Input : n = 30 Output: 29

A enkel lösning för detta problem är att iterera från n-1 till 2 och för varje nummer kontrollera om det är ett primtal . Om primer sedan tillbaka den och bryt slingan. Den här lösningen ser bra ut om det bara finns en fråga. Men inte effektivt om det finns flera frågor för olika värden på n.

Nedan är implementeringen av ovanstående tillvägagångssätt:

snabbsort

C++

// C++ program for the above approach #include    using namespace std; // Function to return nearest prime number int prime(int n) {  // All prime numbers are odd except two  if (n & 1)  n -= 2;  else  n--;  int i j;  for (i = n; i >= 2; i -= 2) {  if (i % 2 == 0)  continue;  for (j = 3; j <= sqrt(i); j += 2) {  if (i % j == 0)  break;  }  if (j > sqrt(i))  return i;  }  // It will only be executed when n is 3  return 2; } // Driver Code int main() {  int n = 17;  cout << prime(n);  return 0; }

// C program for the above approach #include  #include  // Function to return nearest prime number int prime(int n) {  // All prime numbers are odd except two  if (n & 1)  n -= 2;  else  n--;  int i j;  for (i = n; i >= 2; i -= 2) {  if (i % 2 == 0)  continue;  for (j = 3; j <= sqrt(i); j += 2) {  if (i % j == 0)  break;  }  if (j > sqrt(i))  return i;  }  // It will only be executed when n is 3  return 2; } // Driver Code int main() {  int n = 17;  printf('%d' prime(n));  return 0; } // This code is contributed by Sania Kumari Gupta

Java

// Java program for the above approach import java.io.*; class GFG {  // Function to return nearest prime number  static int prime(int n)  {  // All prime numbers are odd except two  if (n % 2 != 0)  n -= 2;  else  n--;  int i j;  for (i = n; i >= 2; i -= 2) {  if (i % 2 == 0)  continue;  for (j = 3; j <= Math.sqrt(i); j += 2) {  if (i % j == 0)  break;  }  if (j > Math.sqrt(i))  return i;  }  // It will only be executed when n is 3  return 2;  }  // Driver Code  public static void main(String[] args)  {  int n = 17;  System.out.print(prime(n));  } } // This code is contributed by subham348.

Python3

# Python program for the above approach # Function to return nearest prime number from math import floor sqrt def prime(n): # All prime numbers are odd except two if (n & 1): n -= 2 else: n -= 1 ij = 03 for i in range(n 2 -2): if(i % 2 == 0): continue while(j <= floor(sqrt(i)) + 1): if (i % j == 0): break j += 2 if (j > floor(sqrt(i))): return i # It will only be executed when n is 3 return 2 # Driver Code n = 17 print(prime(n)) # This code is contributed by shinjanpatra

// C# program for the above approach using System; class GFG {  // Function to return nearest prime number  static int prime(int n)  {  // All prime numbers are odd except two  if (n % 2 != 0)  n -= 2;  else  n--;  int i j;  for (i = n; i >= 2; i -= 2) {  if (i % 2 == 0)  continue;  for (j = 3; j <= Math.Sqrt(i); j += 2) {  if (i % j == 0)  break;  }  if (j > Math.Sqrt(i))  return i;  }  // It will only be executed when n is 3  return 2;  }  // Driver Code  public static void Main()  {  int n = 17;  Console.Write(prime(n));  } } // This code is contributed by subham348.

JavaScript

<script> // Javascript program for the above approach // Function to return nearest prime number function prime(n) {    // All prime numbers are odd except two  if (n & 1)  n -= 2;  else  n--;  let i j;  for(i = n; i >= 2; i -= 2)   {  if (i % 2 == 0)  continue;  for(j = 3; j <= Math.sqrt(i); j += 2)   {  if (i % j == 0)  break;  }  if (j > Math.sqrt(i))  return i;  }  // It will only be executed when n is 3  return 2; } // Driver Code let n = 17; document.write(prime(n)); // This code is contributed by souravmahato348 </script>

Produktion

Tidskomplexitet: O(n log n + log n) = O(n log n)
Utrymmes komplexitet: O(1)
En effektiv lösning för detta problem är att generera alla primtal mindre än 10^6 med hjälp av Sikt av Sundaram och lagra sedan i en array i ökande ordning. Ansök nu modifierad binär sökning att söka närmaste primtal mindre än n.

C++

// C++ program to find the nearest prime to n. #include   #define MAX 1000000 using namespace std; // array to store all primes less than 10^6 vector<int> primes; // Utility function of Sieve of Sundaram void Sieve() {  int n = MAX;  // In general Sieve of Sundaram produces primes  // smaller than (2*x + 2) for a number given  // number x  int nNew = sqrt(n);  // This array is used to separate numbers of the  // form i+j+2ij from others where 1 <= i <= j  int marked[n/2+500] = {0};  // eliminate indexes which does not produce primes  for (int i=1; i<=(nNew-1)/2; i++)  for (int j=(i*(i+1))<<1; j<=n/2; j=j+2*i+1)  marked[j] = 1;  // Since 2 is a prime number  primes.push_back(2);  // Remaining primes are of the form 2*i + 1 such  // that marked[i] is false.  for (int i=1; i<=n/2; i++)  if (marked[i] == 0)  primes.push_back(2*i + 1); } // modified binary search to find nearest prime less than N int binarySearch(int leftint rightint n) {  if (left<=right)  {  int mid = (left + right)/2;  // base condition is if we are reaching at left  // corner or right corner of primes[] array then  // return that corner element because before or  // after that we don't have any prime number in  // primes array  if (mid == 0 || mid == primes.size()-1)  return primes[mid];  // now if n is itself a prime so it will be present  // in primes array and here we have to find nearest  // prime less than n so we will return primes[mid-1]  if (primes[mid] == n)  return primes[mid-1];  // now if primes[mid]n that  // mean we reached at nearest prime  if (primes[mid] < n && primes[mid+1] > n)  return primes[mid];  if (n < primes[mid])  return binarySearch(left mid-1 n);  else  return binarySearch(mid+1 right n);  }  return 0; } // Driver program to run the case int main() {  Sieve();  int n = 17;  cout << binarySearch(0 primes.size()-1 n);  return 0; }

Java

// Java program to find the nearest prime to n. import java.util.*; class GFG {   static int MAX=1000000; // array to store all primes less than 10^6 static ArrayList<Integer> primes = new ArrayList<Integer>(); // Utility function of Sieve of Sundaram static void Sieve() {  int n = MAX;  // In general Sieve of Sundaram produces primes  // smaller than (2*x + 2) for a number given  // number x  int nNew = (int)Math.sqrt(n);  // This array is used to separate numbers of the  // form i+j+2ij from others where 1 <= i <= j  int[] marked = new int[n / 2 + 500];  // eliminate indexes which does not produce primes  for (int i = 1; i <= (nNew - 1) / 2; i++)  for (int j = (i * (i + 1)) << 1;   j <= n / 2; j = j + 2 * i + 1)  marked[j] = 1;  // Since 2 is a prime number  primes.add(2);  // Remaining primes are of the form 2*i + 1 such  // that marked[i] is false.  for (int i = 1; i <= n / 2; i++)  if (marked[i] == 0)  primes.add(2 * i + 1); } // modified binary search to find nearest prime less than N static int binarySearch(int leftint rightint n) {  if (left <= right)  {  int mid = (left + right) / 2;  // base condition is if we are reaching at left  // corner or right corner of primes[] array then  // return that corner element because before or  // after that we don't have any prime number in  // primes array  if (mid == 0 || mid == primes.size() - 1)  return primes.get(mid);  // now if n is itself a prime so it will be present  // in primes array and here we have to find nearest  // prime less than n so we will return primes[mid-1]  if (primes.get(mid) == n)  return primes.get(mid - 1);  // now if primes[mid]n that  // mean we reached at nearest prime  if (primes.get(mid) < n && primes.get(mid + 1) > n)  return primes.get(mid);  if (n < primes.get(mid))  return binarySearch(left mid - 1 n);  else  return binarySearch(mid + 1 right n);  }  return 0; } // Driver code public static void main (String[] args)  {  Sieve();  int n = 17;  System.out.println(binarySearch(0  primes.size() - 1 n)); } } // This code is contributed by mits

Python3

# Python3 program to find the nearest # prime to n. import math MAX = 10000; # array to store all primes less # than 10^6 primes = []; # Utility function of Sieve of Sundaram def Sieve(): n = MAX; # In general Sieve of Sundaram produces # primes smaller than (2*x + 2) for a  # number given number x nNew = int(math.sqrt(n)); # This array is used to separate numbers # of the form i+j+2ij from others where  # 1 <= i <= j marked = [0] * (int(n / 2 + 500)); # eliminate indexes which does not # produce primes for i in range(1 int((nNew - 1) / 2) + 1): for j in range(((i * (i + 1)) << 1) (int(n / 2) + 1) (2 * i + 1)): marked[j] = 1; # Since 2 is a prime number primes.append(2); # Remaining primes are of the form  # 2*i + 1 such that marked[i] is false. for i in range(1 int(n / 2) + 1): if (marked[i] == 0): primes.append(2 * i + 1); # modified binary search to find nearest # prime less than N def binarySearch(left right n): if (left <= right): mid = int((left + right) / 2); # base condition is if we are reaching  # at left corner or right corner of  # primes[] array then return that corner  # element because before or after that  # we don't have any prime number in # primes array if (mid == 0 or mid == len(primes) - 1): return primes[mid]; # now if n is itself a prime so it will  # be present in primes array and here # we have to find nearest prime less than # n so we will return primes[mid-1] if (primes[mid] == n): return primes[mid - 1]; # now if primes[mid]n  # that means we reached at nearest prime if (primes[mid] < n and primes[mid + 1] > n): return primes[mid]; if (n < primes[mid]): return binarySearch(left mid - 1 n); else: return binarySearch(mid + 1 right n); return 0; # Driver Code Sieve(); n = 17; print(binarySearch(0 len(primes) - 1 n)); # This code is contributed by chandan_jnu

// C# program to find the nearest prime to n. using System; using System.Collections; class GFG {   static int MAX = 1000000; // array to store all primes less than 10^6 static ArrayList primes = new ArrayList(); // Utility function of Sieve of Sundaram static void Sieve() {  int n = MAX;  // In general Sieve of Sundaram produces   // primes smaller than (2*x + 2) for a   // number given number x  int nNew = (int)Math.Sqrt(n);  // This array is used to separate numbers of the  // form i+j+2ij from others where 1 <= i <= j  int[] marked = new int[n / 2 + 500];  // eliminate indexes which does not produce primes  for (int i = 1; i <= (nNew - 1) / 2; i++)  for (int j = (i * (i + 1)) << 1;   j <= n / 2; j = j + 2 * i + 1)  marked[j] = 1;  // Since 2 is a prime number  primes.Add(2);  // Remaining primes are of the form 2*i + 1   // such that marked[i] is false.  for (int i = 1; i <= n / 2; i++)  if (marked[i] == 0)  primes.Add(2 * i + 1); } // modified binary search to find  // nearest prime less than N static int binarySearch(int left int right int n) {  if (left <= right)  {  int mid = (left + right) / 2;  // base condition is if we are reaching at left  // corner or right corner of primes[] array then  // return that corner element because before or  // after that we don't have any prime number in  // primes array  if (mid == 0 || mid == primes.Count - 1)  return (int)primes[mid];  // now if n is itself a prime so it will be   // present in primes array and here we have   // to find nearest prime less than n so we  // will return primes[mid-1]  if ((int)primes[mid] == n)  return (int)primes[mid - 1];  // now if primes[mid]n   // that mean we reached at nearest prime  if ((int)primes[mid] < n &&  (int)primes[mid + 1] > n)  return (int)primes[mid];  if (n < (int)primes[mid])  return binarySearch(left mid - 1 n);  else  return binarySearch(mid + 1 right n);  }  return 0; } // Driver code static void Main()  {  Sieve();  int n = 17;  Console.WriteLine(binarySearch(0  primes.Count - 1 n)); } } // This code is contributed by chandan_jnu

PHP

 // PHP program to find the nearest // prime to n. $MAX = 10000; // array to store all primes less // than 10^6 $primes = array(); // Utility function of Sieve of Sundaram function Sieve() { global $MAX $primes; $n = $MAX; // In general Sieve of Sundaram produces // primes smaller than (2*x + 2) for a  // number given number x $nNew = (int)(sqrt($n)); // This array is used to separate numbers // of the form i+j+2ij from others where  // 1 <= i <= j $marked = array_fill(0 (int)($n / 2 + 500) 0); // eliminate indexes which does not // produce primes for ($i = 1; $i <= ($nNew - 1) / 2; $i++) for ($j = ($i * ($i + 1)) << 1; $j <= $n / 2; $j = $j + 2 * $i + 1) $marked[$j] = 1; // Since 2 is a prime number array_push($primes 2); // Remaining primes are of the form  // 2*i + 1 such that marked[i] is false. for ($i = 1; $i <= $n / 2; $i++) if ($marked[$i] == 0) array_push($primes 2 * $i + 1); } // modified binary search to find nearest // prime less than N function binarySearch($left $right $n) { global $primes; if ($left <= $right) { $mid = (int)(($left + $right) / 2); // base condition is if we are reaching  // at left corner or right corner of  // primes[] array then return that corner  // element because before or after that  // we don't have any prime number in // primes array if ($mid == 0 || $mid == count($primes) - 1) return $primes[$mid]; // now if n is itself a prime so it will  // be present in primes array and here // we have to find nearest prime less than // n so we will return primes[mid-1] if ($primes[$mid] == $n) return $primes[$mid - 1]; // now if primes[mid]n  // that means we reached at nearest prime if ($primes[$mid] < $n && $primes[$mid + 1] > $n) return $primes[$mid]; if ($n < $primes[$mid]) return binarySearch($left $mid - 1 $n); else return binarySearch($mid + 1 $right $n); } return 0; } // Driver Code Sieve(); $n = 17; echo binarySearch(0 count($primes) - 1 $n); // This code is contributed by chandan_jnu ?>

JavaScript

 <script>  // JavaScript program to find the nearest prime to n.  // array to store all primes less than 10^6  var primes = [];  // Utility function of Sieve of Sundaram  var MAX = 1000000;  function Sieve()   {  let n = MAX;  // In general Sieve of Sundaram produces primes  // smaller than (2*x + 2) for a number given  // number x  let nNew = parseInt(Math.sqrt(n));  // This array is used to separate numbers of the  // form i+j+2ij from others where 1 <= i <= j  var marked = new Array(n / 2 + 500).fill(0);  // eliminate indexes which does not produce primes  for (let i = 1; i <= parseInt((nNew - 1) / 2); i++)  for (let j = (i * (i + 1)) << 1; j <= parseInt(n / 2); j = j + 2 * i + 1)  marked[j] = 1;  // Since 2 is a prime number  primes.push(2);  // Remaining primes are of the form 2*i + 1 such  // that marked[i] is false.  for (let i = 1; i <= parseInt(n / 2); i++)  if (marked[i] == 0)  primes.push(2 * i + 1);  }  // modified binary search to find nearest prime less than N  function binarySearch(left right n) {  if (left <= right) {  let mid = parseInt((left + right) / 2);  // base condition is if we are reaching at left  // corner or right corner of primes[] array then  // return that corner element because before or  // after that we don't have any prime number in  // primes array  if (mid == 0 || mid == primes.length - 1)  return primes[mid];  // now if n is itself a prime so it will be present  // in primes array and here we have to find nearest  // prime less than n so we will return primes[mid-1]  if (primes[mid] == n)  return primes[mid - 1];  // now if primes[mid]n that  // mean we reached at nearest prime  if (primes[mid] < n && primes[mid + 1] > n)  return primes[mid];  if (n < primes[mid])  return binarySearch(left mid - 1 n);  else  return binarySearch(mid + 1 right n);  }  return 0;  }  // Driver program to run the case  Sieve();  let n = 17;  document.write(binarySearch(0 primes.length - 1 n));  // This code is contributed by Potta Lokesh  </script>

Produktion

Tidskomplexitet: O(n log n)
Utrymmeskomplexitet: O(n)

Ett annat tillvägagångssätt (försöksdelningsmetod):

Börja leta efter primtal genom att dividera det givna talet n med alla tal mindre än n. Det första primtal du möter kommer att vara det närmaste primtal mindre än n.

Algoritm:

Initiera en variabel som kallas "prime" till 0.
Börja från n-1 iterera genom alla nummer mindre än n i fallande ordning.
För varje nummer utför jag följande steg:
a. Initiera en variabel som heter 'is_prime' till true.
b. Börja från 2 iterera genom alla nummer mindre än i i stigande ordning.
c. För varje nummer j kontrollera om j delar i utan att lämna en rest. Om j delar sig sätter jag 'is_prime' till false och bryter ut ur loopen.
d. Om 'is_prime' fortfarande är sant efter att ha kontrollerat alla möjliga divisorer ställ in 'prime' på i och bryt ut slingan.
Returnera 'primtal' som närmaste primtal mindre än n.

Nedan är implementeringen av ovanstående tillvägagångssätt:

C++

// CPP code to find the nearest prime to N // Using Trial Division method #include    #include  using namespace std; // Function to find the nearest prime to N // Using Trial Division method bool is_prime(int n) {  if (n <= 1) {  return false;  }  for (int i = 2; i <= sqrt(n); i++) {  if (n % i == 0) {  return false;  }  }  return true; } int nearest_prime(int n) {  int prime = 0;  for (int i = n-1; i >= 2; i--) {  if (is_prime(i)) {  prime = i;  break;  }  }  return prime; } int main() {  int n = 17;  int prime = nearest_prime(n);  if (prime == 0) {  cout << 'There is no prime less than ' << n << endl;  }  else {  cout << prime << endl;  }  return 0; } // This code is contributed by Susobhan Akhuli

Java

// Java code to find the nearest prime to N // Using Trial Division method import java.util.*; public class GFG {  // Function to find the nearest prime to N  // Using Trial Division method  public static boolean isPrime(int n)  {  if (n <= 1) {  return false;  }  for (int i = 2; i <= Math.sqrt(n); i++) {  if (n % i == 0) {  return false;  }  }  return true;  }  public static int nearestPrime(int n)  {  int prime = 0;  for (int i = n - 1; i >= 2; i--) {  if (isPrime(i)) {  prime = i;  break;  }  }  return prime;  }  public static void main(String[] args)  {  int n = 17;  int prime = nearestPrime(n);  if (prime == 0) {  System.out.println(  'There is no prime less than ' + n);  }  else {  System.out.println(prime);  }  } } // This code is contributed by Susobhan Akhuli

Python3

# Python code to find the nearest prime to N # using Trial Division method import math # Function to check if a number is prime or not def is_prime(n): if n <= 1: return False for i in range(2 int(math.sqrt(n)) + 1): if n % i == 0: return False return True # Function to find the nearest prime to N # Using Trial Division method def nearest_prime(n): prime = 0 for i in range(n - 1 1 -1): if is_prime(i): prime = i break return prime # Main function to test the above functions if __name__ == '__main__': n = 17 prime = nearest_prime(n) if prime == 0: print(f'There is no prime less than {n}') else: print(prime) # This code is contributed by sankar.

// C# code implementation for the above approach using System; public class GFG {  // Function to check if a number is prime  static bool IsPrime(int n)  {  if (n <= 1) {  return false;  }  for (int i = 2; i <= Math.Sqrt(n); i++) {  if (n % i == 0) {  return false;  }  }  return true;  }  // Function to find the nearest prime to n  static int NearestPrime(int n)  {  int prime = 0;  for (int i = n - 1; i >= 2; i--) {  if (IsPrime(i)) {  prime = i;  break;  }  }  return prime;  }  static public void Main()  {  // Code  int n = 17;  int prime = NearestPrime(n);  if (prime == 0) {  Console.WriteLine('There is no prime less than '  + n);  }  else {  Console.WriteLine(prime);  }  } } // This code is contributed by karthik.

JavaScript

// Javascript code to find the nearest prime to N // Using Trial Division method // Function to check if a number is prime function isPrime(n) {  if (n <= 1) {  return false;  }  for (let i = 2; i <= Math.sqrt(n); i++) {  if (n % i === 0) {  return false;  }  }  return true; } // Function to find the nearest prime to n function nearestPrime(n) {  let prime = 0;  for (let i = n - 1; i >= 2; i--) {  if (isPrime(i)) {  prime = i;  break;  }  }  return prime; } let n = 17; let prime = nearestPrime(n); if (prime === 0) {  console.log('There is no prime less than ' + n); } else {  console.log(prime); } // This code is contributed by karthik.

Produktion

Tidskomplexitet: O(N* sqrt(N))
Hjälputrymme: O(1)

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TechCodeview

Närmaste primtal mindre än givet tal n

Ett annat tillvägagångssätt (försöksdelningsmetod):

Algoritm: