#pragma GCC target ("sse,sse2,sse3,ssse3,sse4,popcnt,abm,mmx,avx,tune=native") #pragma GCC optimize("O3") //#pragma GCC optimize("unroll-loops") #ifndef NDEBUG #define NDEBUG #endif #include #include #include #include #ifdef _MSC_VER #include #else #include #endif class U64Mont { public: const uint64_t n; // == n const uint64_t ni; // n * ni == 1 (mod 2**64) const uint64_t n1; // == n - 1 const uint64_t nh; // == (n + 1) / 2 const uint64_t r; // == 2**64 (mod n) const uint64_t n1r; // == -(2**64) (mod n) const uint64_t r2; // == 2**128 (mod n) const uint64_t d; // == n1 >> k // n == 2**k * d + 1 const uint32_t k; // == trailing_zeros(n1) U64Mont(uint64_t n, uint64_t ni, uint64_t n1, uint64_t nh, uint64_t r, uint64_t n1r, uint64_t r2, uint64_t d, uint32_t k) : n(n), ni(ni), n1(n1), nh(nh), r(r), n1r(n1r), r2(r2), d(d), k(k) {} static U64Mont build(uint64_t n) { assert(n & 1 == 1); // // n is odd number, n = 2*k+1, n >= 1, n < 2**64, k is non-negative integer, k >= 0, k < 2**63 // ni0 := n; // = 2*k+1 = (1+(2**2)*((k*(k+1))**1))/(2*k+1) uint64_t ni = n; // ni1 := ni0 * (2 - (n * ni0)); // = (1-(2**4)*((k*(k+1))**2))/(2*k+1) // ni2 := ni1 * (2 - (n * ni1)); // = (1-(2**8)*((k*(k+1))**4))/(2*k+1) // ni3 := ni2 * (2 - (n * ni2)); // = (1-(2**16)*((k*(k+1))**8))/(2*k+1) // ni4 := ni3 * (2 - (n * ni3)); // = (1-(2**32)*((k*(k+1))**16))/(2*k+1) // ni5 := ni4 * (2 - (n * ni4)); // = (1-(2**64)*((k*(k+1))**32))/(2*k+1) // // (n * ni5) mod 2**64 = ((2*k+1) * ni5) mod 2**64 = 1 mod 2**64 for (int i = 0; i < 5; ++i) { ni = ni * (2 - n * ni); } assert(n * ni == 1); // n * ni == 1 (mod 2**64) uint64_t n1 = n - 1; // == n - 1 uint64_t nh = (n >> 1) + 1; // == (n + 1) / 2 uint64_t r = (-n) % n; // == 2**64 (mod n) uint64_t n1r = n - r; // == -(2**64) (mod n) uint64_t r2 = (uint64_t)((-((__uint128_t)n)) % ((__uint128_t)n)); // == 2**128 (mod n) // n == 2**k * d + 1 uint32_t k = __builtin_ctzll(n1); // == trailing_zeros(n1) uint64_t d = n1 >> k; U64Mont tobj(n, ni, n1, nh, r, n1r, r2, d, k); return tobj; } uint64_t add(uint64_t a, uint64_t b) { // add(a, b) == a + b (mod n) assert(a < n); assert(b < n); unsigned long long t, u; unsigned char f1 = _addcarry_u64(0, a, b, &t); unsigned char f2 = _subborrow_u64(0, t, f1 ? n : 0, &u); return f2 ? t : u; } uint64_t sub(uint64_t a, uint64_t b) { // sub(a, b) == a - b (mod n) assert(a < n); assert(b < n); unsigned long long t; unsigned char f = _subborrow_u64(0, a, b, &t); return t + (f ? n : 0); } uint64_t div2(uint64_t ar) { // div2(ar) == ar / 2 (mod n) assert(ar < n); if ((ar & 1) == 0) { return (ar >> 1); } else { return (ar >> 1) + nh; } } uint64_t mrmul(uint64_t ar, uint64_t br) { // mrmul(ar, br) == (ar * br) / r (mod n) // R == 2**64 // gcd(N, R) == 1 // N * ni mod R == 1 // 0 <= ar < N < R // 0 <= br < N < R // T := ar * br // t := floor(T / R) - floor(((T * ni mod R) * N) / R) // if t < 0 then return t + N else return t assert(ar < n); assert(br < n); __uint128_t t = ((__uint128_t)ar) * ((__uint128_t)br); uint64_t u = (uint64_t)(t >> 64); uint64_t v = (uint64_t)((((__uint128_t)(((uint64_t)t) * ni)) * ((__uint128_t)n)) >> 64); unsigned long long w; unsigned char f = _subborrow_u64(0, u, v, &w); return w + (f ? n : 0); } uint64_t mr(uint64_t ar) { // mr(ar) == ar / r (mod n) // R == 2**64 // gcd(N, R) == 1 // N * ni mod R == 1 // 0 <= ar < N < R // t := floor(ar / R) - floor(((ar * ni mod R) * N) / R) // if t < 0 then return t + N else return t assert(ar < p_this->n); uint64_t v = (uint64_t)((((__uint128_t)(ar * ni)) * ((__uint128_t)n)) >> 64); return v == 0 ? 0 : n - v; } uint64_t ar(uint64_t ar) { // ar(a) == a * r (mod n) assert(ar < n); return mrmul(ar, r2); } uint64_t pow(uint64_t ar, uint64_t b) { // pow(ar, b) == ((ar / r) ** b) * r (mod n) assert(ar < n); uint64_t t = ((b & 1) == 0) ? r : ar; b >>= 1; while (b != 0) { ar = mrmul(ar, ar); if ((b & 1) != 0) { t = mrmul(t, ar); } b >>= 1; } return t; } }; const uint64_t bases[] = {2,325,9375,28178,450775,9780504,1795265022}; int miller_rabin(uint64_t n) { // Deterministic variants of the Miller-Rabin primality test // http://miller-rabin.appspot.com/ if (n == 2) { return 1; } if (n < 2 || (n & 1) == 0) { return 0; } U64Mont mont = U64Mont::build(n); for (int i = 0; i < 7; ++i) { uint64_t a = bases[i]; assert(a > 0); if (a >= n) { a %= n; if (a == 0) { continue; } } uint64_t ar = mont.ar(a); uint64_t tr = mont.pow(ar, mont.d); if (tr == mont.r || tr == mont.n1r) { continue; } for (int j = 1; j < mont.k; ++j) { tr = mont.mrmul(tr, tr); if (tr == mont.n1r) { goto cont; } } return 0; cont: continue; } return 1; } int main(int argc, char *argv[]) { struct timespec start_time, end_time; clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &start_time); int n; scanf("%d", &n); for(int i = 0; i < n; ++i) { uint64_t x; scanf("%lld", &x); printf("%lld %d\n", x, miller_rabin(x)); } clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &end_time); int sec = end_time.tv_sec - start_time.tv_sec; int nsec = end_time.tv_nsec - start_time.tv_nsec; double d_sec = (double)sec + (double)nsec / (1000 * 1000 * 1000); fprintf(stderr, "time:%f\n", d_sec); }