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docs, test: fit modular inverse fermat little theorem to contributing guidelines #2779

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124 changes: 83 additions & 41 deletions math/modular_inverse_fermat_little_theorem.cpp
Original file line number Diff line number Diff line change
Expand Up @@ -43,56 +43,98 @@
* (as \f$a\times a^{-1} = 1\f$)
*/

#include <iostream>
#include <vector>
#include <cassert> /// for assert
#include <cstdint> /// for std::int64_t
#include <iostream> /// for IO implementations

/** Recursive function to calculate exponent in \f$O(\log n)\f$ using binary
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* exponent.
/**
* @namespace math
* @brief Maths algorithms.
*/
namespace math {
/**
* @namespace modular_inverse_fermat
* @brief Calculate modular inverse using Fermat's Little Theorem.
*/
namespace modular_inverse_fermat {
/**
* @brief Calculate exponent with modulo using binary exponentiation.
* @param a The base
* @param b The exponent
* @param m The modulo
* @return The result of \f$a^{b} % m\f$
*/
int64_t binExpo(int64_t a, int64_t b, int64_t m) {
a %= m;
int64_t res = 1;
while (b > 0) {
if (b % 2) {
res = res * a % m;
}
a = a * a % m;
// Dividing b by 2 is similar to right shift.
b >>= 1;
std::int64_t binExpo(std::int64_t a, std::int64_t b, std::int64_t m) {
a %= m;
std::int64_t res = 1;
while (b > 0) {
if (b % 2 != 0) {
res = res * a % m;
}
return res;
a = a * a % m;
// Dividing b by 2 is similar to right shift by 1 bit
b >>= 1;
}
return res;
}

/** Prime check in \f$O(\sqrt{m})\f$ time.
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/**
* @brief Check if an integer is a prime number in \f$O(\sqrt{m})\f$ time.
* @param m An intger to check for primality
* @return true if the number is prime
* @return false if the number is not prime
*/
bool isPrime(int64_t m) {
if (m <= 1) {
return false;
} else {
for (int64_t i = 2; i * i <= m; i++) {
if (m % i == 0) {
return false;
}
}
bool isPrime(std::int64_t m) {
if (m <= 1) {
return false;
}
for (std::int64_t i = 2; i * i <= m; i++) {
if (m % i == 0) {
return false;
}
return true;
}
return true;
}
/**
* @brief calculates the modular inverse.
* @param a Integer value for the base
* @param m Integer value for modulo
* @return The result that is the modular inverse of a modulo m
*/
std::int64_t modular_inverse(std::int64_t a, std::int64_t m) {
while (a < 0) {
a += m;
}

// Check for invalid cases
if (!isPrime(m) || a == 0) {
return -1; // Invalid input
}

return binExpo(a, m - 2, m); // Fermat's Little Theorem
}
} // namespace modular_inverse_fermat
} // namespace math

/**
* @brief Self-test implementation
* @return void
*/
static void test() {
assert(math::modular_inverse_fermat::modular_inverse(0, 97) == -1);
assert(math::modular_inverse_fermat::modular_inverse(15, -2) == -1);
assert(math::modular_inverse_fermat::modular_inverse(3, 10) == -1);
assert(math::modular_inverse_fermat::modular_inverse(3, 7) == 5);
assert(math::modular_inverse_fermat::modular_inverse(1, 101) == 1);
assert(math::modular_inverse_fermat::modular_inverse(-1337, 285179) == 165519);
assert(math::modular_inverse_fermat::modular_inverse(123456789, 998244353) == 25170271);
assert(math::modular_inverse_fermat::modular_inverse(-9876543210, 1000000007) == 784794281);
}

/**
* Main function
* @brief Main function
* @return 0 on exit
*/
int main() {
int64_t a, m;
// Take input of a and m.
std::cout << "Computing ((a^(-1))%(m)) using Fermat's Little Theorem";
std::cout << std::endl << std::endl;
std::cout << "Give input 'a' and 'm' space separated : ";
std::cin >> a >> m;
if (isPrime(m)) {
std::cout << "The modular inverse of a with mod m is (a^(m-2)) : ";
std::cout << binExpo(a, m - 2, m) << std::endl;
} else {
std::cout << "m must be a prime number.";
std::cout << std::endl;
}
test(); // run self-test implementation
return 0;
}
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