Lucky number - It is the smallest integer for which m > 1. For a given positive integer n, pn# m is a prime number, where pn# is the first n product primes.
For example, to calculate the third lucky number, first calculate the product of the first 3 prime numbers (2, 3, 5), which is 30. Adding 2 gives us 32, which is an even number, and adding 3 gives us 33, which is a multiple of 3. Integers up to 6 can also be excluded. Adding 7 gives us 37, which is a prime number. Therefore, 7 is the third lucky number.
The lucky number for the first original number is -
3, 5, 7, 13, 23, 17, 19, 23, 37, 61, 67, 61, 71, 47, 107, 59, 61, 109….
Given a number n. Find the nth lucky number.
Input: n = 3
Output: 7
Explanation - Product of the first 3 price figures -
2 3 5 = 30 30 + 7 = 37, a prime number.
Input: n = 7
Output: 19
Explanation - Product of the first 7 prime numbers -
2 3 5 7 11 13 17 = 510510 510510 + 19 = 510529, a prime number.
A simple way to solve this problem is to first calculate pn#, the product of the first n prime numbers, and then find the difference between pn# and the next prime number. The difference obtained will be a lucky number.
procedure prime (num) if num <= 1 ans = TRUE end if for i = 2 to sqrt(num) if i is a factor of num ans = false end if ans = true end procedure procedure nthFortunate (n) prod = 1 count = 0 for i = 2 to count < n if i is prime prod = prod * i count = count + 1 end if nextPrime = prod + 2 while nextPrime is not prime nextPrime = next Prime + 1 ans = nextPrime - prod end procedure
In the following program, the lucky number is calculated by calculating the primitive of the first n prime numbers and finding the next prime number after the primitive. The lucky number is the difference between the next prime number and the primitive number.
#include <bits/stdc++.h> using namespace std; // Function to find if a number is prime or not bool prime(unsigned long long int num){ if (num <= 1) return true; for (int i = 2; i <= sqrt(num); i++){ if (num % i == 0) return false; } return true; } // Function to find the nth Fortunate number unsigned long long int nthFortunate(int n){ long long int prod = 1, count = 0; // Calculating product/primorial of first n prime numbers for (int i = 2; count < n; i++){ if (prime(i)){ prod *= i; count++; } } // Find the next prime greater than the product of n prime numbers unsigned long long int nextPrime = prod + 2; while (!prime(nextPrime)){ nextPrime++; } // Fortunate number is the difference between prime and primorial unsigned long long int ans = nextPrime - prod; return ans; } int main(){ int n = 15; cout << n << "th Fortunate number : " << nthFortunate(n); return 0; }
15th Fortunate number : 107
Time complexity - O(nsqrt(n)), where the complexity of the prime() function is O(sqrt(n)), and the complexity of the for loop in nthFortunate() is O(nsqrt(n)) .
Space complexity - O(1)
The Sieve of Eratosthenes is used to bring all prime numbers up to a limit, which will give us a value MAX. In this method, we create a boolean array containing all true entries and mark all non-prime indexes as false. Then multiply the first n prime numbers in the array to get the product of the first n prime numbers. Then similarly to the previous method, start at 2 and add 1 to the product to get the next prime number. The difference between the next prime number and the product is the required lucky number.
procedure nthFortunate (n) MAX is set prime[MAX] = {true} prime[0] = false prime[1] = false for i = 1 to i*i <= MAX if prime[i] for j = i*i to MAX with j = j + i in each iteration prime [j] = false end if prod = 1 count = 0 for i = 2 to count < n if prime[i] prod = prod * i count = count + 1 end if nextPrime = prod + 2 while nextPrime is not prime nextPrime = nextPrime + 1 ans = nextPrime - prod end procedure
In the following program, a Boolean prime array of size MAX records all prime numbers before MAX. The original is then found by multiplying the first n prime numbers. Then similar to the previous method, find nextPrime. The difference between nextPrime and Product is the lucky number.
#include <bits/stdc++.h> using namespace std; // Function to find the nth Fortunate number unsigned long long int nthFortunate(int n){ // Setting upper limit for Sieve of Eratosthenes const unsigned long long int MAX = 1000000000; vector<bool> prime(MAX, true); prime[0] = prime[1] = false; // Sieve of Eratosthenes to find all primes up to MAX for (unsigned long long int i = 2; i * i <= MAX; i++){ if (prime[i]){ // Setting all the multiples of i to false for (int j = i * i; j <= MAX; j += i){ prime[j] = false; } } } // Find the first n primes and calculate their product unsigned long long int prod = 1, count = 0; for (unsigned long long int i = 2; count < n; i++){ if (prime[i]){ prod *= i; count++; } } // Find next prime greater than product unsigned long long int nextPrime = prod + 2; while (!prime[nextPrime]) nextPrime++; // Fortunate number is difference between prime and product return nextPrime - prod; } int main(){ int n = 25; cout << n << "th Fortunate number : " << nthFortunate(n); return 0; }
15th Fortunate number : 107
Time complexity - O(n log(log(n)))
Space complexity - O(MAX)
To sum up, the nth lucky number can be found in the following two ways.
Elementary method: Find the product of the first n prime numbers, and calculate the next prime number based on the product. The difference between the prime number and the product is the nth lucky number.
Sieve of Eratosthenes: Find all prime numbers that reach a certain limit, and then calculate the product with the next prime number to find the lucky number.
Both methods are valid for smaller values of n simply due to variable size limitations. For larger values, more efficient and optimized solutions are required.
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