#include #include #include /* * calculates (a * b) % c taking into account that a * b might overflow */ long long mulmod(long long a, long long b, long long mod) { long long x = 0,y = a % mod; while (b > 0) { if (b % 2 == 1) { x = (x + y) % mod; } y = (y * 2) % mod; b /= 2; } return x % mod; } /* * modular exponentiation */ long long modulo(long long base, long long exponent, long long mod) { long long x = 1; long long y = base; while (exponent > 0) { if (exponent % 2 == 1) x = (x * y) % mod; y = (y * y) % mod; exponent = exponent / 2; } return x % mod; } /* * Miller-Rabin Primality test, iteration signifies the accuracy */ int Miller(long long p,int iteration) { int i; long long s; if (p < 2) { return 0; } if (p != 2 && p % 2==0) { return 0; } s = p - 1; while (s % 2 == 0) { s /= 2; } for (i = 0; i < iteration; i++) { long long a = rand() % (p - 1) + 1, temp = s; long long mod = modulo(a, temp, p); while (temp != p - 1 && mod != 1 && mod != p - 1) { mod = mulmod(mod, mod, p); temp *= 2; } if (mod != p - 1 && temp % 2 == 0) { return 0; } } return 1; } //Main int main() { int iteration = 5; long long num; printf("Enter integer to test primality: "); scanf("%lld", &num); if ( Miller( num, iteration)) printf("\n%lld is prime\n", num); else printf("\n%lld is not prime\n", num); return 0; }