cp-library-cpp
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列を変数として持つ多項式の評価
(library/convolution/polynomial_eval.hpp)
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- Last update: 2023-09-15 20:02:25+09:00
- Include:
#include "library/convolution/polynomial_eval.hpp"
polynomial_eval
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シグネチャ
template <typename T, auto transform, auto transform_inv, typename F> std::vector<T> polynomial_eval(std::vector<T> &&a, F f) // (1) template <typename T, auto transform, auto transform_inv, typename F> std::vector<T> polynomial_eval(const std::vector<T> &a, F f) // (2) -
概要
列 $A$ を変数に持つ多項式 $\displaystyle f(A)=\sum_{i=0}^{M-1} C_i \cdot A^i$ を評価します.ここで,$A^i$ はある畳み込み演算 $\ast$ に対して以下で定義されるものとします.
\[A^i = \underbrace{A \ast A \ast \cdots \ast A}_{i}\]また,$\ast$ に対してある正則な変換行列 $\mathcal{F}$ が存在して,任意の列 $X,Y$ に対して
\[\mathcal{F}[X] \odot \mathcal{F}[Y]=\mathcal{F}[X\ast Y]\]を満たす必要があります.ここで,$\odot$ は各点積をとる演算です.このとき,$f(A)$ は次のように計算されます.
\[\begin{aligned} f(A) &=\mathcal{F}^{-1}\left[\sum_{i=0}^{M-1}C_i\cdot \left(\underbrace{\mathcal{F}[A]\odot\cdots\odot\mathcal{F}[A]}_{i}\right)\right]\\ &=\mathcal{F}^{-1}\left[\begin{pmatrix} f(\mathcal{F}[A]_0)\\ f(\mathcal{F}[A]_1)\\ \vdots\\ f(\mathcal{F}[A]_{\vert A\vert-1})\\ \end{pmatrix}\right] \end{aligned}\]上式における $\mathcal{F}$ と $\mathcal{F}^{-1}$ による変換を与えるのがテンプレート引数
transformおよびtransform_invであり,$f(\cdot)$ を評価するのが引数fです. -
テンプレート引数
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T: 列の要素の型. -
transform: 列に対して inplace に線形変換 $\mathcal{F}$ を施す関数 -
transform_inv: 逆変換 $\mathcal{F}^{-1}$ を施す関数 -
F:T型の要素 $x$ に対して $\displaystyle f(x)=\sum_{i=0}^{N-1}C_i \cdot x^i$ を計算する関数の型です.F型のインスタンスfはxを引数に取る関数呼び出しf(x)によって $f(x)$ を計算できなければなりません.
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引数
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a: 列 $A$ -
f: $f(x)$ を評価する関数
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返り値
$f(A)$
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時間計算量
列 $A$ の長さを $N$,
transformの計算量を $\Theta(f(N))$,transform_invの計算量を $\Theta(g(N))$,fの計算量を $O(h(M))$ として,$\Theta(f(N)+g(N)+N\cdot h(M))$ です.
Depends on
Verified with
Code
#ifndef SUISEN_APPLY_POLYNOMIAL
#define SUISEN_APPLY_POLYNOMIAL
#include <vector>
#include "library/type_traits/type_traits.hpp"
namespace suisen {
template <typename T, auto transform, auto transform_inv, typename F, constraints_t<std::is_invocable_r<T, F, T>> = nullptr>
std::vector<T> polynomial_eval(std::vector<T> &&a, F f) {
transform(a);
for (auto &x : a) x = f(x);
transform_inv(a);
return a;
}
template <typename T, auto transform, auto transform_inv, typename F, constraints_t<std::is_invocable_r<T, F, T>> = nullptr>
std::vector<T> polynomial_eval(const std::vector<T> &a, F f) {
return polynomial_eval<T, transform, transform_inv>(std::vector<T>(a), f);
}
} // namespace suisen
#endif // SUISEN_APPLY_POLYNOMIAL#line 1 "library/convolution/polynomial_eval.hpp"
#include <vector>
#line 1 "library/type_traits/type_traits.hpp"
#include <limits>
#include <iostream>
#include <type_traits>
namespace suisen {
template <typename ...Constraints> using constraints_t = std::enable_if_t<std::conjunction_v<Constraints...>, std::nullptr_t>;
template <typename T, typename = std::nullptr_t> struct bitnum { static constexpr int value = 0; };
template <typename T> struct bitnum<T, constraints_t<std::is_integral<T>>> { static constexpr int value = std::numeric_limits<std::make_unsigned_t<T>>::digits; };
template <typename T> static constexpr int bitnum_v = bitnum<T>::value;
template <typename T, size_t n> struct is_nbit { static constexpr bool value = bitnum_v<T> == n; };
template <typename T, size_t n> static constexpr bool is_nbit_v = is_nbit<T, n>::value;
template <typename T, typename = std::nullptr_t> struct safely_multipliable { using type = T; };
template <typename T> struct safely_multipliable<T, constraints_t<std::is_signed<T>, is_nbit<T, 32>>> { using type = long long; };
template <typename T> struct safely_multipliable<T, constraints_t<std::is_signed<T>, is_nbit<T, 64>>> { using type = __int128_t; };
template <typename T> struct safely_multipliable<T, constraints_t<std::is_unsigned<T>, is_nbit<T, 32>>> { using type = unsigned long long; };
template <typename T> struct safely_multipliable<T, constraints_t<std::is_unsigned<T>, is_nbit<T, 64>>> { using type = __uint128_t; };
template <typename T> using safely_multipliable_t = typename safely_multipliable<T>::type;
template <typename T, typename = void> struct rec_value_type { using type = T; };
template <typename T> struct rec_value_type<T, std::void_t<typename T::value_type>> {
using type = typename rec_value_type<typename T::value_type>::type;
};
template <typename T> using rec_value_type_t = typename rec_value_type<T>::type;
template <typename T> class is_iterable {
template <typename T_> static auto test(T_ e) -> decltype(e.begin(), e.end(), std::true_type{});
static std::false_type test(...);
public:
static constexpr bool value = decltype(test(std::declval<T>()))::value;
};
template <typename T> static constexpr bool is_iterable_v = is_iterable<T>::value;
template <typename T> class is_writable {
template <typename T_> static auto test(T_ e) -> decltype(std::declval<std::ostream&>() << e, std::true_type{});
static std::false_type test(...);
public:
static constexpr bool value = decltype(test(std::declval<T>()))::value;
};
template <typename T> static constexpr bool is_writable_v = is_writable<T>::value;
template <typename T> class is_readable {
template <typename T_> static auto test(T_ e) -> decltype(std::declval<std::istream&>() >> e, std::true_type{});
static std::false_type test(...);
public:
static constexpr bool value = decltype(test(std::declval<T>()))::value;
};
template <typename T> static constexpr bool is_readable_v = is_readable<T>::value;
} // namespace suisen
#line 7 "library/convolution/polynomial_eval.hpp"
namespace suisen {
template <typename T, auto transform, auto transform_inv, typename F, constraints_t<std::is_invocable_r<T, F, T>> = nullptr>
std::vector<T> polynomial_eval(std::vector<T> &&a, F f) {
transform(a);
for (auto &x : a) x = f(x);
transform_inv(a);
return a;
}
template <typename T, auto transform, auto transform_inv, typename F, constraints_t<std::is_invocable_r<T, F, T>> = nullptr>
std::vector<T> polynomial_eval(const std::vector<T> &a, F f) {
return polynomial_eval<T, transform, transform_inv>(std::vector<T>(a), f);
}
} // namespace suisen