competitive-programming-library

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:heavy_check_mark: number/primes.hpp

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#pragma once
#include <algorithm>
#include <cassert>
#include <cstdint>
#include <map>
#include <vector>
#include "utils/macros.hpp"

/**
 * @note O(\sqrt{n})
 */
struct prepared_primes {
    int size;
    std::vector<int> sieve;
    std::vector<int> primes;

    prepared_primes(int size_)
        : size(size_) {

        sieve.resize(size);
        REP3 (p, 2, size) if (sieve[p] == 0) {
            primes.push_back(p);
            for (int k = p; k < size; k += p) {
                if (sieve[k] == 0) {
                    sieve[k] = p;
                }
            }
        }
    }

    std::vector<int64_t> list_prime_factors(int64_t n) {
        assert (1 <= n and n < (int64_t)size * size);
        std::vector<int64_t> result;

        // trial division for large part
        for (int p : primes) {
            if (n < size or n < (int64_t)p * p) {
                break;
            }
            while (n % p == 0) {
                n /= p;
                result.push_back(p);
            }
        }

        // small part
        if (n == 1) {
            // nop
        } else if (n < size) {
            while (n != 1) {
                result.push_back(sieve[n]);
                n /= sieve[n];
            }
        } else {
            result.push_back(n);
        }

        assert (std::is_sorted(ALL(result)));
        return result;
    }

    bool is_prime(int64_t n) {
        return list_prime_factors(n).size() == 1;
    }

    std::vector<int64_t> list_all_factors(int64_t n) {
        auto p = list_prime_factors(n);
        std::vector<int64_t> d;
        d.push_back(1);
        for (int l = 0; l < p.size(); ) {
            int r = l + 1;
            while (r < p.size() and p[r] == p[l]) ++ r;
            int n = d.size();
            REP (k1, r - l) {
                REP (k2, n) {
                    d.push_back(d[d.size() - n] * p[l]);
                }
            }
            l = r;
        }
        return d;
    }

    std::map<int64_t, int> list_prime_factors_as_map(int64_t n) {
        std::map<int64_t, int> cnt;
        for (int64_t p : list_prime_factors(n)) {
            ++ cnt[p];
        }
        return cnt;
    }

    int64_t euler_totient(int64_t n) {
        int64_t phi = 1;
        int64_t last = -1;
        for (int64_t p : list_prime_factors(n)) {
            if (last != p) {
                last = p;
                phi *= p - 1;
            } else {
                phi *= p;
            }
        }
        return phi;
    }
};

#line 2 "number/primes.hpp"
#include <algorithm>
#include <cassert>
#include <cstdint>
#include <map>
#include <vector>
#line 2 "utils/macros.hpp"
#define REP(i, n) for (int i = 0; (i) < (int)(n); ++ (i))
#define REP3(i, m, n) for (int i = (m); (i) < (int)(n); ++ (i))
#define REP_R(i, n) for (int i = (int)(n) - 1; (i) >= 0; -- (i))
#define REP3R(i, m, n) for (int i = (int)(n) - 1; (i) >= (int)(m); -- (i))
#define ALL(x) std::begin(x), std::end(x)
#line 8 "number/primes.hpp"

/**
 * @note O(\sqrt{n})
 */
struct prepared_primes {
    int size;
    std::vector<int> sieve;
    std::vector<int> primes;

    prepared_primes(int size_)
        : size(size_) {

        sieve.resize(size);
        REP3 (p, 2, size) if (sieve[p] == 0) {
            primes.push_back(p);
            for (int k = p; k < size; k += p) {
                if (sieve[k] == 0) {
                    sieve[k] = p;
                }
            }
        }
    }

    std::vector<int64_t> list_prime_factors(int64_t n) {
        assert (1 <= n and n < (int64_t)size * size);
        std::vector<int64_t> result;

        // trial division for large part
        for (int p : primes) {
            if (n < size or n < (int64_t)p * p) {
                break;
            }
            while (n % p == 0) {
                n /= p;
                result.push_back(p);
            }
        }

        // small part
        if (n == 1) {
            // nop
        } else if (n < size) {
            while (n != 1) {
                result.push_back(sieve[n]);
                n /= sieve[n];
            }
        } else {
            result.push_back(n);
        }

        assert (std::is_sorted(ALL(result)));
        return result;
    }

    bool is_prime(int64_t n) {
        return list_prime_factors(n).size() == 1;
    }

    std::vector<int64_t> list_all_factors(int64_t n) {
        auto p = list_prime_factors(n);
        std::vector<int64_t> d;
        d.push_back(1);
        for (int l = 0; l < p.size(); ) {
            int r = l + 1;
            while (r < p.size() and p[r] == p[l]) ++ r;
            int n = d.size();
            REP (k1, r - l) {
                REP (k2, n) {
                    d.push_back(d[d.size() - n] * p[l]);
                }
            }
            l = r;
        }
        return d;
    }

    std::map<int64_t, int> list_prime_factors_as_map(int64_t n) {
        std::map<int64_t, int> cnt;
        for (int64_t p : list_prime_factors(n)) {
            ++ cnt[p];
        }
        return cnt;
    }

    int64_t euler_totient(int64_t n) {
        int64_t phi = 1;
        int64_t last = -1;
        for (int64_t p : list_prime_factors(n)) {
            if (last != p) {
                last = p;
                phi *= p - 1;
            } else {
                phi *= p;
            }
        }
        return phi;
    }
};

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