Hashiryo's Library
This documentation is automatically generated by competitive-verifier/competitive-verifier
素数判定 (src/NumberTheory/is_prime.hpp)
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- Last update: 2024-10-01 17:03:34+09:00
- Include:
#include "src/NumberTheory/is_prime.hpp"
unsigned long long 型の整数が素数かどうかを判定する。
関数
| 名前 | 概要 | 計算量 |
|---|---|---|
is_prime(n) |
n が素数なら true, 素数でないなら false を返す。 |
$O(\log n)$ |
説明
ミラーラビン素数判定法に基づいている。
unsigned long long の範囲の整数 n に対して、決定的に正しい結果を返す。
constexpr なのでコンパイル時にも使用可能。
使用例
#include <iostream>
#include "NumberTheory/is_prime.hpp"
int main() {
std::cout << is_prime(2) << std::endl; // 1
std::cout << is_prime(7) << std::endl; // 1
std::cout << is_prime(10) << std::endl; // 0
std::cout << is_prime(998244353) << std::endl; // 1
// constepxr
constexpr bool p = is_prime(1000000007);
static_assert(p);
return 0;
}
Depends on
剰余の高速化 (src/Internal/Remainder.hpp)Required by
- 多倍長整数 (src/FFT/BigInt.hpp)
- 線形漸化的数列の第$k$項 (src/FFT/bostan_mori.hpp)
- 畳み込み (src/FFT/convolve.hpp)
- 多項式の拡張互除法 (src/FFT/extgcd.hpp)
- 形式的冪級数 (src/FFT/FormalPowerSeries.hpp)
- 形式的冪級数 div (src/FFT/fps_div.hpp)
- 形式的冪級数 exp (src/FFT/fps_exp.hpp)
- 形式的冪級数の逆元 (src/FFT/fps_inv.hpp)
- 形式的冪級数 sqrt (src/FFT/fps_sqrt.hpp)
- 多変数畳み込み (src/FFT/MultiVariateConvolution.hpp)
- Number-Theoretic-Transform (src/FFT/NTT.hpp)
- 多項式 (src/FFT/Polynomial.hpp)
- 多項式行列の総積 (src/FFT/polynomial_matrix_prod.hpp)
- 多項式の評価点シフト (src/FFT/sample_points_shift.hpp)
- 有名な数列(形式的冪級数使用) (src/FFT/sequences.hpp)
- 複数の値代入と多項式補間 (src/FFT/SubProductTree.hpp)
- 二項係数 ($\mathbb{Z}/m\mathbb{Z}$) (src/Math/BinomialCoefficient.hpp)
- k乗根 ($\mathbb{F}_p$) (src/Math/mod_kth_root.hpp)
- 平方根 ($\mathbb{F}_p$) (src/Math/mod_sqrt.hpp)
- テトレーション $a\upuparrows b$ ($\mathbb{Z}/m\mathbb{Z}$) (src/Math/mod_tetration.hpp)
指数に乗せられるModInt (src/Math/ModInt_Exp.hpp)- 疎な形式的冪級数 (src/Math/sparse_fps.hpp)
- スターリング数 ($\mathbb{F}_p$) (src/Math/StirlingNumber.hpp)
- 約数配列 (src/NumberTheory/ArrayOnDivisors.hpp)
- 高速素因数分解など (src/NumberTheory/Factors.hpp)
- 原始根と位数 $\mathbb{F}_p^{\times}$ (src/NumberTheory/OrderFp.hpp)
Verified with
- test/alone/constexpr_factors.test.cpp
- test/alone/constexpr_is_prime.test.cpp
- test/alone/constexpr_mod_sqrt.test.cpp
- test/alone/constexpr_mod_tetration.test.cpp
- test/alone/constexpr_orderfp.test.cpp
- test/aoj/3072.sfps.test.cpp
- test/aoj/3072.test.cpp
- test/aoj/NTL_1_D.test.cpp
- test/aoj/NTL_2_A.test.cpp
- test/aoj/NTL_2_B.test.cpp
- test/aoj/NTL_2_C.test.cpp
- test/aoj/NTL_2_D.test.cpp
- test/aoj/NTL_2_E.test.cpp
- test/aoj/NTL_2_F.test.cpp
- test/atcoder/abc136_d.test.cpp
- test/atcoder/abc179_d.test.cpp
- test/atcoder/abc198_f.interpolate.test.cpp
- test/atcoder/abc212_g.test.cpp
- test/atcoder/abc213_h.test.cpp
- test/atcoder/abc222_h.sparse_FPS.test.cpp
- test/atcoder/abc228_e.test.cpp
- test/atcoder/abc230_h.test.cpp
- test/atcoder/abc248_g.test.cpp
- test/atcoder/abc276_g.sparse_FPS.test.cpp
- test/atcoder/abc335_g.test.cpp
- test/atcoder/arc080_f.WeightedMatching.test.cpp
- test/atcoder/s8pc_3_g.test.cpp
- test/loj/6686.Dirich.test.cpp
- test/loj/6686.mul.test.cpp
- test/yosupo/bernoulli.test.cpp
- test/yosupo/binomial_coefficient.test.cpp
- test/yosupo/comp_of_FPS.test.cpp
- test/yosupo/convolution1000000007.test.cpp
- test/yosupo/convolution_large.test.cpp
- test/yosupo/convolution_mod_2_64.test.cpp
- test/yosupo/division_of_big_integers.test.cpp
- test/yosupo/division_of_Poly.test.cpp
- test/yosupo/exp_of_FPS.FPS.test.cpp
- test/yosupo/exp_of_FPS.test.cpp
- test/yosupo/exp_of_sparse_FPS.test.cpp
- test/yosupo/factorize.test.cpp
- test/yosupo/frequency_table_of_tree_distance.test.cpp
- test/yosupo/inv_of_FPS.FPS.test.cpp
- test/yosupo/inv_of_FPS.test.cpp
- test/yosupo/inv_of_Poly.test.cpp
- test/yosupo/inv_of_sparse_FPS.test.cpp
- test/yosupo/kth_root_mod.test.cpp
- test/yosupo/kth_term_of_linearly_recurrent_sequence.test.cpp
- test/yosupo/log_of_FPS.FPS.test.cpp
- test/yosupo/log_of_FPS.test.cpp
- test/yosupo/log_of_sparse_FPS.test.cpp
- test/yosupo/multipoint_evaluation.test.cpp
- test/yosupo/multivariate_convolution.test.cpp
- test/yosupo/partition.MSET.test.cpp
- test/yosupo/partition.test.cpp
- test/yosupo/polynomial_interpolation.test.cpp
- test/yosupo/pow_of_FPS.FPS.test.cpp
- test/yosupo/pow_of_FPS.test.cpp
- test/yosupo/pow_of_sparse_FPS.test.cpp
- test/yosupo/primarity_test.test.cpp
- test/yosupo/primitive_root.test.cpp
- test/yosupo/sharp_p_subset_sum.PSET.test.cpp
- test/yosupo/sharp_p_subset_sum.test.cpp
- test/yosupo/shift_of_FPS.test.cpp
- test/yosupo/shift_of_sampling_points_of_polynomial.test.cpp
- test/yosupo/sqrt_mod.test.cpp
- test/yosupo/sqrt_of_FPS.test.cpp
- test/yosupo/sqrt_of_sparse_FPS.test.cpp
- test/yosupo/stirling_1.test.cpp
- test/yosupo/stirling_1_small_p_large_n.test.cpp
- test/yosupo/stirling_2.test.cpp
- test/yosupo/stirling_2_small_p_large_n.test.cpp
- test/yosupo/subset_convolution.multivar_conv.test.cpp
- test/yosupo/tetration_mod.test.cpp
- test/yukicoder/1080.sparse_FPS.test.cpp
- test/yukicoder/1080.test.cpp
- test/yukicoder/1145.test.cpp
- test/yukicoder/125.multiple_mobius.test.cpp
- test/yukicoder/125.phi.test.cpp
- test/yukicoder/137.div_at.test.cpp
- test/yukicoder/1533.test.cpp
- test/yukicoder/1728.test.cpp
- test/yukicoder/1939.test.cpp
- test/yukicoder/215.Poly.test.cpp
- test/yukicoder/215.test.cpp
- test/yukicoder/2264.test.cpp
- test/yukicoder/2578.test.cpp
- test/yukicoder/502.test.cpp
- test/yukicoder/8030.test.cpp
- test/yukicoder/8046.test.cpp
- test/yukicoder/963.FPS.test.cpp
- test/yukicoder/963.test.cpp
- test/yukicoder/980.sparse_fps.cpp
- test/yukicoder/980.sparse_fps2.cpp
- test/yukicoder/980.test.cpp
Code
#pragma once
#include "src/Internal/Remainder.hpp"
namespace math_internal {
template <class Uint, class MP, u32... args> constexpr bool miller_rabin(Uint n) {
const MP md(n);
const Uint s= __builtin_ctzll(n - 1), d= n >> s, one= md.set(1), n1= md.norm(md.set(n - 1));
for (u32 a: (u32[]){args...})
if (Uint b= a % n; b)
if (Uint p= md.norm(pow(md.set(b), d, md)); p != one)
for (int i= s; p != n1; p= md.norm(md.mul(p, p)))
if (!(--i)) return 0;
return 1;
}
}
constexpr bool is_prime(unsigned long long n) {
if (n < 2 || n % 6 % 4 != 1) return (n | 1) == 3;
if (n < (1 << 30)) return math_internal::miller_rabin<unsigned, math_internal::MP_Mo32, 2, 7, 61>(n);
if (n < (1ull << 62)) return math_internal::miller_rabin<unsigned long long, math_internal::MP_Mo64, 2, 325, 9375, 28178, 450775, 9780504, 1795265022>(n);
if (n < (1ull << 63)) return math_internal::miller_rabin<unsigned long long, math_internal::MP_D2B1_1, 2, 325, 9375, 28178, 450775, 9780504, 1795265022>(n);
return math_internal::miller_rabin<unsigned long long, math_internal::MP_D2B1_2, 2, 325, 9375, 28178, 450775, 9780504, 1795265022>(n);
}#line 2 "src/Internal/Remainder.hpp"
namespace math_internal {
using namespace std;
using u8= unsigned char;
using u32= unsigned;
using i64= long long;
using u64= unsigned long long;
using u128= __uint128_t;
struct MP_Na { // mod < 2^32
u32 mod;
constexpr MP_Na(): mod(0) {}
constexpr MP_Na(u32 m): mod(m) {}
constexpr inline u32 mul(u32 l, u32 r) const { return u64(l) * r % mod; }
constexpr inline u32 set(u32 n) const { return n; }
constexpr inline u32 get(u32 n) const { return n; }
constexpr inline u32 norm(u32 n) const { return n; }
constexpr inline u32 plus(u64 l, u32 r) const { return l+= r, l < mod ? l : l - mod; }
constexpr inline u32 diff(u64 l, u32 r) const { return l-= r, l >> 63 ? l + mod : l; }
};
template <class u_t, class du_t, u8 B> struct MP_Mo { // mod < 2^32, mod < 2^62
u_t mod;
constexpr MP_Mo(): mod(0), iv(0), r2(0) {}
constexpr MP_Mo(u_t m): mod(m), iv(inv(m)), r2(-du_t(mod) % mod) {}
constexpr inline u_t mul(u_t l, u_t r) const { return reduce(du_t(l) * r); }
constexpr inline u_t set(u_t n) const { return mul(n, r2); }
constexpr inline u_t get(u_t n) const { return n= reduce(n), n >= mod ? n - mod : n; }
constexpr inline u_t norm(u_t n) const { return n >= mod ? n - mod : n; }
constexpr inline u_t plus(u_t l, u_t r) const { return l+= r, l < (mod << 1) ? l : l - (mod << 1); }
constexpr inline u_t diff(u_t l, u_t r) const { return l-= r, l >> (B - 1) ? l + (mod << 1) : l; }
private:
u_t iv, r2;
static constexpr u_t inv(u_t n, int e= 6, u_t x= 1) { return e ? inv(n, e - 1, x * (2 - x * n)) : x; }
constexpr inline u_t reduce(const du_t &w) const { return u_t(w >> B) + mod - ((du_t(u_t(w) * iv) * mod) >> B); }
};
using MP_Mo32= MP_Mo<u32, u64, 32>;
using MP_Mo64= MP_Mo<u64, u128, 64>;
struct MP_Br { // 2^20 < mod <= 2^41
u64 mod;
constexpr MP_Br(): mod(0), x(0) {}
constexpr MP_Br(u64 m): mod(m), x((u128(1) << 84) / m) {}
constexpr inline u64 mul(u64 l, u64 r) const { return rem(u128(l) * r); }
static constexpr inline u64 set(u64 n) { return n; }
constexpr inline u64 get(u64 n) const { return n >= mod ? n - mod : n; }
constexpr inline u64 norm(u64 n) const { return n >= mod ? n - mod : n; }
constexpr inline u64 plus(u64 l, u64 r) const { return l+= r, l < (mod << 1) ? l : l - (mod << 1); }
constexpr inline u64 diff(u64 l, u64 r) const { return l-= r, l >> 63 ? l + (mod << 1) : l; }
private:
u64 x;
constexpr inline u128 quo(const u128 &n) const { return (n * x) >> 84; }
constexpr inline u64 rem(const u128 &n) const { return n - quo(n) * mod; }
};
template <class du_t, u8 B> struct MP_D2B1 { // mod < 2^63, mod < 2^64
u64 mod;
constexpr MP_D2B1(): mod(0), s(0), d(0), v(0) {}
constexpr MP_D2B1(u64 m): mod(m), s(__builtin_clzll(m)), d(m << s), v(u128(-1) / d) {}
constexpr inline u64 mul(u64 l, u64 r) const { return rem((u128(l) * r) << s) >> s; }
constexpr inline u64 set(u64 n) const { return n; }
constexpr inline u64 get(u64 n) const { return n; }
constexpr inline u64 norm(u64 n) const { return n; }
constexpr inline u64 plus(du_t l, u64 r) const { return l+= r, l < mod ? l : l - mod; }
constexpr inline u64 diff(du_t l, u64 r) const { return l-= r, l >> B ? l + mod : l; }
private:
u8 s;
u64 d, v;
constexpr inline u64 rem(const u128 &u) const {
u128 q= (u >> 64) * v + u;
u64 r= u64(u) - (q >> 64) * d - d;
if (r > u64(q)) r+= d;
if (r >= d) r-= d;
return r;
}
};
using MP_D2B1_1= MP_D2B1<u64, 63>;
using MP_D2B1_2= MP_D2B1<u128, 127>;
template <class u_t, class MP> constexpr u_t pow(u_t x, u64 k, const MP &md) {
for (u_t ret= md.set(1);; x= md.mul(x, x))
if (k & 1 ? ret= md.mul(ret, x) : 0; !(k>>= 1)) return ret;
}
}
#line 3 "src/NumberTheory/is_prime.hpp"
namespace math_internal {
template <class Uint, class MP, u32... args> constexpr bool miller_rabin(Uint n) {
const MP md(n);
const Uint s= __builtin_ctzll(n - 1), d= n >> s, one= md.set(1), n1= md.norm(md.set(n - 1));
for (u32 a: (u32[]){args...})
if (Uint b= a % n; b)
if (Uint p= md.norm(pow(md.set(b), d, md)); p != one)
for (int i= s; p != n1; p= md.norm(md.mul(p, p)))
if (!(--i)) return 0;
return 1;
}
}
constexpr bool is_prime(unsigned long long n) {
if (n < 2 || n % 6 % 4 != 1) return (n | 1) == 3;
if (n < (1 << 30)) return math_internal::miller_rabin<unsigned, math_internal::MP_Mo32, 2, 7, 61>(n);
if (n < (1ull << 62)) return math_internal::miller_rabin<unsigned long long, math_internal::MP_Mo64, 2, 325, 9375, 28178, 450775, 9780504, 1795265022>(n);
if (n < (1ull << 63)) return math_internal::miller_rabin<unsigned long long, math_internal::MP_D2B1_1, 2, 325, 9375, 28178, 450775, 9780504, 1795265022>(n);
return math_internal::miller_rabin<unsigned long long, math_internal::MP_D2B1_2, 2, 325, 9375, 28178, 450775, 9780504, 1795265022>(n);
}