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:heavy_check_mark: verify/yosupo-judge/range_reverse_range_sum/0000.test.cpp

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/*
 * @uni_kakurenbo
 * https://github.com/uni-kakurenbo/competitive-programming-workspace
 *
 * CC0 1.0  http://creativecommons.org/publicdomain/zero/1.0/deed.ja
 */
/* #language C++ 20 GCC */

#define PROBLEM "https://judge.yosupo.jp/problem/range_reverse_range_sum"


#include <iostream>
#include "snippet/aliases.hpp"
#include "snippet/fast_io.hpp"
#include "snippet/iterations.hpp"
#include "adaptor/io.hpp"
#include "data_structure/dynamic_sequence.hpp"
#include "action/range_sum.hpp"
#include "action/helpers.hpp"

uni::i32 main() {
    uni::i32 n, q; input >> n >> q;
    uni::valarray<uni::i64> a(n); input >> a;
    uni::dynamic_sequence<uni::actions::make_full_t<uni::actions::range_sum<uni::i64>>> data(a);

    REP(q) {
        uni::i32 t, l, r; input >> t >> l >> r;
        if(t == 0) {
            data.reverse(l, r);
        }
        if(t == 1) {
            print(data(l, r).fold());
        }
    }
}
#line 1 "verify/yosupo-judge/range_reverse_range_sum/0000.test.cpp"
/*
 * @uni_kakurenbo
 * https://github.com/uni-kakurenbo/competitive-programming-workspace
 *
 * CC0 1.0  http://creativecommons.org/publicdomain/zero/1.0/deed.ja
 */
/* #language C++ 20 GCC */

#define PROBLEM "https://judge.yosupo.jp/problem/range_reverse_range_sum"


#include <iostream>
#line 2 "snippet/aliases.hpp"


#include <cstdint>
#include <utility>
#include <vector>
#include <ranges>


#line 2 "internal/dev_env.hpp"


#ifdef LOCAL_JUDGE
    inline constexpr bool DEV_ENV = true;
    inline constexpr bool NO_EXCEPT = false;
#else
    inline constexpr bool DEV_ENV = false;
    inline constexpr bool NO_EXCEPT = true;
#endif // LOCAL_JUDGE


#if __cplusplus >= 202100L
    #define CPP20 true
    #define CPP23 true
#elif __cplusplus >= 202002L
    #define CPP20 true
    #define CPP23 false
#else
    #define CPP20 false
    #define CPP23 false
#endif
#line 2 "snippet/internal/types.hpp"

#line 4 "snippet/internal/types.hpp"

namespace uni {


using i16 = std::int16_t;
using u16 = std::uint16_t;

using i32 = std::int32_t;
using u32 = std::uint32_t;

using i64 = std::int64_t;
using u64 = std::uint64_t;

#ifdef __GNUC__

using i128 = __int128_t;
using u128 = __uint128_t;

using f128 = __float128;

#endif

using uint = unsigned;
using ll = long long;
using ull = unsigned long long;
using ld = long double;


} // namespace uni
#line 12 "snippet/aliases.hpp"


#define until(...) while(!(__VA_ARGS__))

#define CONTINUE(...) { __VA_ARGS__; continue; }
#define BREAK(...) { __VA_ARGS__; break; }

#define ALL(x) std::ranges::begin((x)),std::ranges::end((x))
#define RALL(x) std::ranges::rbegin((x)),std::ranges::rend((x))


#define $F first
#define $S second


namespace uni {


constexpr char LN = '\n';
constexpr char SPC = ' ';


constexpr std::pair<int,int> DIRS4[] = { { -1, 0 }, { 0, 1 }, { 1, 0 }, { 0, -1 } };
constexpr std::pair<int,int> DIRS4P[] = { { -1, 0 }, { 0, 1 }, { 1, 0 }, { 0, -1 }, { 0, 0 } };
constexpr std::pair<int,int> DIRS8[] = { { -1, 0 }, { -1, 1 }, { 0, 1 }, { 1, 1 }, { 1, 0 }, { 1, -1 }, { 0, -1 }, { -1, -1 } };
constexpr std::pair<int,int> DIRS8P[] = { { -1, 0 }, { -1, 1 }, { 0, 1 }, { 1, 1 }, { 1, 0 }, { 1, -1 }, { 0, -1 }, { -1, -1 }, { 0, 0 } };


template<class T> using spair = std::pair<T,T>;


}  // namespace uni


namespace std {

using bit_reference = std::vector<bool>::reference;

bit_reference operator |= (bit_reference a, const bool b) noexcept(NO_EXCEPT) { return a = a | b; }
bit_reference operator &= (bit_reference a, const bool b) noexcept(NO_EXCEPT) { return a = a & b; }

}
#line 2 "snippet/fast_io.hpp"


#line 5 "snippet/fast_io.hpp"

#line 7 "snippet/fast_io.hpp"


#ifdef __GNUC__

__attribute__((constructor)) inline void fast_io() noexcept(NO_EXCEPT) { std::ios::sync_with_stdio(false), std::cin.tie(nullptr); }

#else

inline void fast_io() noexcept(NO_EXCEPT) { std::ios::sync_with_stdio(false), std::cin.tie(nullptr); }

#endif
#line 2 "snippet/iterations.hpp"

#include <type_traits>
#line 2 "macro/overload.hpp"

#define $OVERLOAD2(arg0, arg1, cmd, ...) cmd
#define $OVERLOAD3(arg0, arg1, arg2, cmd, ...) cmd
#define $OVERLOAD4(arg0, arg1, arg2, arg3, cmd, ...) cmd
#define $OVERLOAD5(arg0, arg1, arg2, arg3, arg4, cmd, ...) cmd
#define $OVERLOAD6(arg0, arg1, arg2, arg3, arg4, arg5, cmd, ...) cmd
#line 2 "macro/basic.hpp"

#define TO_STRING_AUX(x) #x
#define TO_STRING(x) TO_STRING_AUX(x)

#define CONCAT_AUX(x, y) x##y
#define CONCAT(x, y) CONCAT_AUX(x, y)

#define UNPAREN_AUX(...) __VA_ARGS__
#define UNPAREN(...) __VA_ARGS__
#line 6 "snippet/iterations.hpp"


#define LOOP(n) REPI(CONCAT(_$, __COUNTER__), n)

#define REPI(i,n) for(std::remove_cvref_t<decltype(n)> i=0, CONCAT(i, $)=(n); i<CONCAT(i, $); ++i)
#define REPF(i,l,r) for(std::common_type_t<std::remove_cvref_t<decltype(l)>,std::remove_cvref_t<decltype(r)>> i=(l), CONCAT(i, $)=(r); i<CONCAT(i, $); ++i)
#define REPIS(i,l,r,s) for(std::common_type_t<std::remove_cvref_t<decltype(l)>,std::remove_cvref_t<decltype(r)>,std::remove_cvref_t<decltype(s)>> i=(l), CONCAT(i, $)=(r); i<CONCAT(i, $); i+=(s))

#define REPR(i,n) for(auto i=(n); --i>=0;)
#define REPB(i,l,r) for(std::common_type_t<std::remove_cvref_t<decltype(l)>,std::remove_cvref_t<decltype(r)>> i=(r), CONCAT(i, $)=(l); --i>=CONCAT(i, $);)
#define REPRS(i,l,r,s) for(std::common_type_t<std::remove_cvref_t<decltype(l)>,std::remove_cvref_t<decltype(r)>,std::remove_cvref_t<decltype(s)>> i=(l)+((r)-(l)-1)/(s)*(s), CONCAT(i, $)=(l); i>=CONCAT(i, $); (i-=(s)))

#define REP(...) $OVERLOAD4(__VA_ARGS__, REPIS, REPF, REPI, LOOP)(__VA_ARGS__)
#define REPD(...) $OVERLOAD4(__VA_ARGS__, REPRS, REPB, REPR)(__VA_ARGS__)

#define FORO(i,n) for(int i=0, CONCAT(i, $)=static_cast<int>(n); i<=CONCAT(i, $); ++i)
#define FORI(i,l,r) for(std::common_type_t<std::remove_cvref_t<decltype(l)>,std::remove_cvref_t<decltype(r)>> i=(l), CONCAT(i, $)=(r); i<=CONCAT(i, $); ++i)
#define FORIS(i,l,r,s) for(std::common_type_t<std::remove_cvref_t<decltype(l)>,std::remove_cvref_t<decltype(r)>,std::remove_cvref_t<decltype(s)>> i=(l), CONCAT(i, $)=(r); i<=CONCAT(i, $); i+=(s))

#define FORRO(i,n) for(auto i=(n); i>=0; --i)
#define FORR(i,l,r) for(std::common_type_t<std::remove_cvref_t<decltype(l)>,std::remove_cvref_t<decltype(r)>> i=(r), CONCAT(i, $)=(l); i>=CONCAT(i, $); --i)
#define FORRS(i,l,r,s) for(std::common_type_t<std::remove_cvref_t<decltype(l)>,std::remove_cvref_t<decltype(r)>,std::remove_cvref_t<decltype(s)>> i=(l)+((r)-(l))/(s)*(s), CONCAT(i, $)=(l); i>=CONCAT(i, $); i-=(s))

#define FOR(...) $OVERLOAD4(__VA_ARGS__, FORIS, FORI, FORO)(__VA_ARGS__)
#define FORD(...) $OVERLOAD4(__VA_ARGS__, FORRS, FORR, FORRO)(__VA_ARGS__)

#define ITR1(e0,v) for(const auto &e0 : (v))
#define ITRP1(e0,v) for(auto e0 : (v))
#define ITRR1(e0,v) for(auto &e0 : (v))

#define ITR2(e0,e1,v) for(const auto [e0, e1] : (v))
#define ITRP2(e0,e1,v) for(auto [e0, e1] : (v))
#define ITRR2(e0,e1,v) for(auto &[e0, e1] : (v))

#define ITR3(e0,e1,e2,v) for(const auto [e0, e1, e2] : (v))
#define ITRP3(e0,e1,e2,v) for(auto [e0, e1, e2] : (v))
#define ITRR3(e0,e1,e2,v) for(auto &[e0, e1, e2] : (v))

#define ITR4(e0,e1,e2,e3,v) for(const auto [e0, e1, e2, e3] : (v))
#define ITRP4(e0,e1,e2,e3,v) for(auto [e0, e1, e2, e3] : (v))
#define ITRR4(e0,e1,e2,e3,v) for(auto &[e0, e1, e2, e3] : (v))

#define ITR5(e0,e1,e2,e3,e4,v) for(const auto [e0, e1, e2, e3, e4] : (v))
#define ITRP5(e0,e1,e2,e3,e4,v) for(auto [e0, e1, e2, e3, e4] : (v))
#define ITRR5(e0,e1,e2,e3,e4,v) for(auto &[e0, e1, e2, e3, e4] : (v))

#define ITR(...) $OVERLOAD6(__VA_ARGS__, ITR5, ITR4, ITR3, ITR2, ITR1)(__VA_ARGS__)
#define ITRP(...) $OVERLOAD6(__VA_ARGS__, ITRP5, ITRP4, ITRP3, ITRP2, ITRP1)(__VA_ARGS__)
#define ITRR(...) $OVERLOAD6(__VA_ARGS__, ITRR5, ITRR4, ITRR3, ITRR2, ITRR1)(__VA_ARGS__)
#line 2 "adaptor/io.hpp"

#include <regex>

#line 2 "adaptor/internal/input.hpp"


#line 5 "adaptor/internal/input.hpp"
#include <string>
#line 7 "adaptor/internal/input.hpp"
#include <iterator>
#line 9 "adaptor/internal/input.hpp"
#include <tuple>
#line 11 "adaptor/internal/input.hpp"
#include <concepts>


#line 15 "adaptor/internal/input.hpp"

#line 2 "internal/resolving_rank.hpp"


namespace uni {

namespace internal {


template<int P> struct resolving_rank : resolving_rank<P-1> {};
template<> struct resolving_rank<0> {};


} // namespace internal

} // namespace uni
#line 18 "adaptor/internal/input.hpp"

#line 2 "utility/functional.hpp"


#include <functional>
#line 7 "utility/functional.hpp"
#include <optional>

#line 2 "internal/type_traits.hpp"


#line 7 "internal/type_traits.hpp"
#include <algorithm>
#line 9 "internal/type_traits.hpp"


#line 12 "internal/type_traits.hpp"


namespace uni {

namespace internal {


template<class... Ts> struct tuple_or_pair { using type = std::tuple<Ts...>; };
template<class T, class U> struct tuple_or_pair<T,U> { using type = std::pair<T, U>; };
template <class... Ts> using tuple_or_pair_t = typename tuple_or_pair<Ts...>::type;

template<class T>
constexpr std::underlying_type_t<T> to_underlying(const T& v) noexcept(NO_EXCEPT) {
    return static_cast<std::underlying_type_t<T>>(v);
}


template<class T, class... Ts>
using are_same = std::conjunction<std::is_same<T, Ts>...>;

template<class T, class... Ts>
inline constexpr bool are_same_v = are_same<T, Ts...>::value;


template<class T, class... Ts>
using is_same_as_any_of = std::disjunction<std::is_same<T, Ts>...>;

template<class T, class... Ts>
inline constexpr bool is_same_as_any_of_v = is_same_as_any_of<T, Ts...>::value;

template<class T, class... Ts>
concept same_as_any_of = is_same_as_any_of_v<T, Ts...>;


template<class Base, class... Derived>
using is_base_of_all = std::conjunction<std::is_base_of<Base, Derived>...>;

template<class Base, class... Derived>
inline constexpr bool is_base_of_all_v = is_base_of_all<Base, Derived...>::value;


template<class Base, class... Derived>
using is_base_of_any = std::disjunction<std::is_base_of<Base, Derived>...>;

template<class Base, class... Derived>
inline constexpr bool is_base_of_any_v = is_base_of_any<Base, Derived...>::value;


template<class T> struct remove_cvref {
  using type = typename std::remove_cv_t<std::remove_reference_t<T>>;
};

template<class T> using remove_cvref_t = typename remove_cvref<T>::type;


template<class T> struct literal_operator { static constexpr const char* value = ""; };

template<> struct literal_operator<unsigned> { static constexpr const char* value = "U"; };
template<> struct literal_operator<long> { static constexpr const char* value = "L"; };
template<> struct literal_operator<unsigned long> { static constexpr const char* value = "UL"; };
template<> struct literal_operator<long long> { static constexpr const char* value = "LL"; };
template<> struct literal_operator<unsigned long long> { static constexpr const char* value = "ULL"; };


template<> struct literal_operator<float> { static constexpr const char* value = "F"; };
template<> struct literal_operator<double> { static constexpr const char* value = "D"; };
template<> struct literal_operator<long double> { static constexpr const char* value = "LD"; };

#ifdef __SIZEOF_INT128__

template<> struct literal_operator<__int128_t> { static constexpr const char* value = "LLL"; };
template<> struct literal_operator<__uint128_t> { static constexpr const char* value = "ULLL"; };

#endif

template<class T> inline constexpr auto literal_operator_v = literal_operator<T>::value;


template <std::size_t N, typename... Types>
struct nth_type {};

template <class Head, class... Tail>
struct nth_type<0, Head, Tail...> {
	using type = Head;
};

template <std::size_t N, class Head, class... Tail>
struct nth_type<N, Head, Tail...> : public nth_type<N - 1, Tail...> {};

template <std::size_t N, typename... Types>
using nth_type_t = typename nth_type<N, Types...>::type;


template<template <class...> class, class> struct is_template_of : std::false_type {};
template<template <class...> class Template, class... Args> struct is_template_of<Template, Template<Args...>> : std::true_type {};

template<template <class...> class Template, class Type>
inline constexpr bool is_template_of_v = is_template_of<Template, Type>::value;

template<class Type, template <class...> class Template>
concept substituted_from = is_template_of_v<Template, Type>;

template<template <class...> class Base, class Derived>
struct _is_basic_tempalte_of
{
    template<class... Ts>
    static constexpr std::true_type  test(const Base<Ts...> *);

    static constexpr std::false_type test(...);

    using type = decltype(test(std::declval<Derived*>()));
};


template<template <class...> class Base, class Derived>
using is_basic_tempalte_of = _is_basic_tempalte_of<Base, Derived>::type;

template<template <class...> class Base, class Derived>
inline constexpr bool is_basic_tempalte_of_v = is_basic_tempalte_of<Base, Derived>::value;

template<class Derived, template <class...> class Base>
concept derived_from_template = is_basic_tempalte_of_v<Base, Derived>;


template<class T> struct is_loggable {
    template<class U>
    static constexpr auto External(U &&v) -> decltype(_debug(v), std::true_type());
    static constexpr std::false_type External(...);

    template<class U>
    static constexpr auto Member(U &&v) -> decltype(v._debug(), std::true_type());
    static constexpr std::false_type Member(...);

    static constexpr bool value = (
      decltype(External(std::declval<T>()))::value ||
      decltype(Member(std::declval<T>()))::value
    );

};

template<class T>
inline constexpr auto is_loggable_v = is_loggable<T>::value;

template<class T>
concept loggable = is_loggable_v<T>;


template<class T> struct _has_iterator {
    template<class U>
    static constexpr auto ADL(U &&v) -> decltype(begin(v), end(v), std::true_type());
    static constexpr std::false_type ADL(...);

    template<class U>
    static constexpr auto STL(U &&v) -> decltype(std::begin(v), std::end(v), std::true_type());
    static constexpr std::false_type STL(...);

    template<class U>
    static constexpr auto Member(U &&v) -> decltype(v.begin(), v.end(), std::true_type());
    static constexpr std::false_type Member(...);
};

template<class T> struct has_iterator {
    struct ADL : decltype(_has_iterator<T>::ADL(std::declval<T>())) {};
    struct STL : decltype(_has_iterator<T>::STL(std::declval<T>())) {};
    struct Member : decltype(_has_iterator<T>::Member(std::declval<T>())) {};

    static constexpr auto adl_v = ADL::value;
    static constexpr auto stl_v = STL::value;
    static constexpr auto member_v = Member::value;
};


template<class T>
struct is_iterable {
    static constexpr bool value =  has_iterator<T>::adl_v || has_iterator<T>::stl_v || has_iterator<T>::member_v;
};

template<class T>
inline constexpr auto is_iterable_v = is_iterable<T>::value;

template<class T>
concept iterable = is_iterable_v<T>;

namespace iterator_resolver {


template<class T>
inline constexpr auto begin(T&& v) noexcept(NO_EXCEPT) {
    static_assert(is_iterable_v<T>);
    if constexpr(has_iterator<T>::member_v) {
        return v.begin();
    }
    else {  // ADL
        using std::begin;
        return begin(std::forward<T>(v));
    }
}

template<class T>
inline constexpr auto end(T&& v) noexcept(NO_EXCEPT) {
    static_assert(is_iterable_v<T>);
    if constexpr(has_iterator<T>::member_v) {
        return v.end();
    }
    else {  // ADL
        using std::end;
        return end(std::forward<T>(v));
    }
}


};


template<class C> using iterator_t = decltype(iterator_resolver::begin(std::declval<C&>()));

template<class C> using container_size_t = decltype(std::size(std::declval<C&>()));


template<bool Const, class T>
using maybe_const_t = std::conditional_t<Const, const T, T>;


template<class T> using with_ref = T&;
template<class T> concept can_reference = requires { typename with_ref<T>; };


} // namespace internal

}  // namespace uni
#line 11 "utility/functional.hpp"

#line 2 "utility/internal/functional_base.hpp"


namespace uni {


template<class P>
    requires
        requires(P p) {
            p.first;
            p.second;
        }
inline P swapped(P& pair) {
    return P{ pair.second, pair.first };
}


} // namespace uni
#line 13 "utility/functional.hpp"

#line 2 "numeric/internal/mod.hpp"


#line 2 "internal/concepts.hpp"


#line 7 "internal/concepts.hpp"
#include <limits>
#line 9 "internal/concepts.hpp"


namespace uni {

namespace internal {


template<class R, class T>
concept convertibel_range = std::convertible_to<std::ranges::range_value_t<R>, T>;


template<class T, class V>
concept item_or_convertible_range = std::convertible_to<T, V> || convertibel_range<T, V>;


template<class Structure>
concept available =
    requires () {
        typename Structure;
    };

template<
    template<class...> class Structure,
    class... TemplateParameters
>
concept available_with = available<Structure<TemplateParameters...>>;


template<class T> concept arithmetic = std::is_arithmetic_v<T>;
template<class T> concept pointer = std::is_pointer_v<T>;
template<class T> concept structural = std::is_class_v<T>;


template<class Large, class Small>
concept has_double_digits_of = (std::numeric_limits<Large>::digits == 2 * std::numeric_limits<Small>::digits);


template<class Large, class Small>
concept has_more_digits_than = (std::numeric_limits<Large>::digits > std::numeric_limits<Small>::digits);

template<class Large, class Small>
concept has_or_more_digits_than = (std::numeric_limits<Large>::digits >= std::numeric_limits<Small>::digits);


template<class T>
concept has_static_zero = requires { T::zero; };

template<class T>
concept has_static_one = requires { T::one; };


template<class L, class R = L>
concept weakly_bitand_calcurable = requires (L lhs, R rhs) { lhs & rhs; };

template<class L, class R = L>
concept weakly_bitor_calcurable = requires (L lhs, R rhs) { lhs | rhs; };

template<class L, class R = L>
concept weakly_bitxor_calcurable = requires (L lhs, R rhs) { lhs ^ rhs; };

template<class L, class R = L>
concept weakly_addable = requires (L lhs, R rhs) { lhs + rhs; };

template<class L, class R = L>
concept weakly_subtractable = requires (L lhs, R rhs) { lhs - rhs; };

template<class L, class R = L>
concept weakly_multipliable = requires (L lhs, R rhs) { lhs * rhs; };

template<class L, class R = L>
concept weakly_divisable = requires (L lhs, R rhs) { lhs / rhs; };

template<class L, class R = L>
concept weakly_remainder_calculable = requires (L lhs, R rhs) { lhs % rhs; };


template<class L, class R = L>
concept weakly_bitand_assignable = requires (L lhs, R rhs) { lhs += rhs; };

template<class L, class R = L>
concept weakly_bitor_assignable = requires (L lhs, R rhs) { lhs |= rhs; };

template<class L, class R = L>
concept weakly_bitxor_assignable = requires (L lhs, R rhs) { lhs ^= rhs; };

template<class L, class R = L>
concept weakly_addition_assignable = requires (L lhs, R rhs) { lhs += rhs; };

template<class L, class R = L>
concept weakly_subtraction_assignable = requires (L lhs, R rhs) { lhs -= rhs; };

template<class L, class R = L>
concept weakly_multipliation_assignalbe = requires (L lhs, R rhs) { lhs *= rhs; };

template<class L, class R = L>
concept weakly_division_assignable = requires (L lhs, R rhs) { lhs /= rhs; };

template<class L, class R = L>
concept weakly_remainder_assignable = requires (L lhs, R rhs) { lhs /= rhs; };


template<class L, class R = L>
concept bitand_calculable =
    weakly_bitand_calcurable<L, R> &&
    weakly_bitand_calcurable<std::invoke_result_t<std::bit_and<>&, L, R>, R> &&
    weakly_bitand_calcurable<L, std::invoke_result_t<std::bit_and<>&, L, R>> &&
    weakly_bitand_calcurable<std::invoke_result_t<std::bit_and<>&, L, R>, std::invoke_result_t<std::bit_and<>&, L, R>>;

template<class L, class R = L>
concept bitor_calculable =
    weakly_bitor_calcurable<L, R> &&
    weakly_bitor_calcurable<std::invoke_result_t<std::bit_or<>&, L, R>, R> &&
    weakly_bitor_calcurable<L, std::invoke_result_t<std::bit_or<>&, L, R>> &&
    weakly_bitor_calcurable<std::invoke_result_t<std::bit_or<>&, L, R>, std::invoke_result_t<std::bit_or<>&, L, R>>;

template<class L, class R = L>
concept bitxor_calculable =
    weakly_bitxor_calcurable<L, R> &&
    weakly_bitxor_calcurable<std::invoke_result_t<std::bit_xor<>&, L, R>, R> &&
    weakly_bitxor_calcurable<L, std::invoke_result_t<std::bit_xor<>&, L, R>> &&
    weakly_bitxor_calcurable<std::invoke_result_t<std::bit_xor<>&, L, R>, std::invoke_result_t<std::bit_xor<>&, L, R>>;

template<class L, class R = L>
concept addable =
    weakly_addable<L, R> &&
    weakly_addable<std::invoke_result_t<std::plus<>&, L, R>, R> &&
    weakly_addable<L, std::invoke_result_t<std::plus<>&, L, R>> &&
    weakly_addable<std::invoke_result_t<std::plus<>&, L, R>, std::invoke_result_t<std::plus<>&, L, R>>;

template<class L, class R = L>
concept subtractable =
    weakly_subtractable<L, R> &&
    weakly_subtractable<std::invoke_result_t<std::minus<>&, L, R>, R> &&
    weakly_subtractable<L, std::invoke_result_t<std::minus<>&, L, R>> &&
    weakly_subtractable<std::invoke_result_t<std::minus<>&, L, R>, std::invoke_result_t<std::minus<>&, L, R>>;

template<class L, class R = L>
concept multipliable =
    weakly_multipliable<L, R> &&
    weakly_multipliable<std::invoke_result_t<std::multiplies<>&, L, R>, R> &&
    weakly_multipliable<L, std::invoke_result_t<std::multiplies<>&, L, R>> &&
    weakly_multipliable<std::invoke_result_t<std::multiplies<>&, L, R>, std::invoke_result_t<std::multiplies<>&, L, R>>;

template<class L, class R = L>
concept divisable =
    weakly_divisable<L, R> &&
    weakly_divisable<std::invoke_result_t<std::divides<>&, L, R>, R> &&
    weakly_divisable<L, std::invoke_result_t<std::divides<>&, L, R>> &&
    weakly_divisable<std::invoke_result_t<std::divides<>&, L, R>, std::invoke_result_t<std::divides<>&, L, R>>;

template<class L, class R = L>
concept remainder_calculable =
    weakly_remainder_calculable<L, R> &&
    weakly_remainder_calculable<std::invoke_result_t<std::modulus<>&, L, R>, R> &&
    weakly_remainder_calculable<L, std::invoke_result_t<std::modulus<>&, L, R>> &&
    weakly_remainder_calculable<std::invoke_result_t<std::modulus<>&, L, R>, std::invoke_result_t<std::modulus<>&, L, R>>;


template<class L, class R = L>
concept bitand_assignable =
    weakly_bitand_assignable<L, R> &&
    weakly_bitand_assignable<std::invoke_result_t<std::bit_and<>&, L, R>, R> &&
    weakly_bitand_assignable<L, std::invoke_result_t<std::bit_and<>&, L, R>> &&
    weakly_bitand_assignable<std::invoke_result_t<std::bit_and<>&, L, R>, std::invoke_result_t<std::bit_and<>&, L, R>>;

template<class L, class R = L>
concept bitor_assignable =
    weakly_bitor_calcurable<L, R> &&
    weakly_bitor_calcurable<std::invoke_result_t<std::bit_or<>&, L, R>, R> &&
    weakly_bitor_calcurable<L, std::invoke_result_t<std::bit_or<>&, L, R>> &&
    weakly_bitor_calcurable<std::invoke_result_t<std::bit_or<>&, L, R>, std::invoke_result_t<std::bit_or<>&, L, R>>;

template<class L, class R = L>
concept bitxor_assignable =
    weakly_bitxor_calcurable<L, R> &&
    weakly_bitxor_calcurable<std::invoke_result_t<std::bit_xor<>&, L, R>, R> &&
    weakly_bitxor_calcurable<L, std::invoke_result_t<std::bit_xor<>&, L, R>> &&
    weakly_bitxor_calcurable<std::invoke_result_t<std::bit_xor<>&, L, R>, std::invoke_result_t<std::bit_xor<>&, L, R>>;

template<class L, class R = L>
concept addition_assignable =
    weakly_addition_assignable<L, R> &&
    weakly_addition_assignable<std::remove_cvref_t<std::invoke_result_t<std::plus<>&, L, R>>, R> &&
    weakly_addition_assignable<L, std::invoke_result_t<std::plus<>&, L, R>> &&
    weakly_addition_assignable<std::remove_cvref_t<std::invoke_result_t<std::plus<>&, L, R>>, std::invoke_result_t<std::plus<>&, L, R>>;

template<class L, class R = L>
concept subtraction_assignable =
    weakly_subtraction_assignable<L, R> &&
    weakly_subtraction_assignable<std::remove_cvref_t<std::invoke_result_t<std::minus<>&, L, R>>, R> &&
    weakly_subtraction_assignable<L, std::invoke_result_t<std::minus<>&, L, R>> &&
    weakly_subtraction_assignable<std::remove_cvref_t<std::invoke_result_t<std::minus<>&, L, R>>, std::invoke_result_t<std::minus<>&, L, R>>;

template<class L, class R = L>
concept multipliation_assignalbe =
    weakly_multipliation_assignalbe<L, R> &&
    weakly_multipliation_assignalbe<std::remove_cvref_t<std::invoke_result_t<std::multiplies<>&, L, R>>, R> &&
    weakly_multipliation_assignalbe<L, std::invoke_result_t<std::multiplies<>&, L, R>> &&
    weakly_multipliation_assignalbe<std::remove_cvref_t<std::invoke_result_t<std::multiplies<>&, L, R>>, std::invoke_result_t<std::multiplies<>&, L, R>>;

template<class L, class R = L>
concept division_assignable =
    weakly_division_assignable<L, R> &&
    weakly_division_assignable<std::remove_cvref_t<std::invoke_result_t<std::divides<>&, L, R>>, R> &&
    weakly_division_assignable<L, std::invoke_result_t<std::divides<>&, L, R>> &&
    weakly_division_assignable<std::remove_cvref_t<std::invoke_result_t<std::divides<>&, L, R>>, std::invoke_result_t<std::divides<>&, L, R>>;

template<class L, class R = L>
concept remainder_assignable =
    weakly_remainder_assignable<L, R> &&
    weakly_remainder_assignable<std::remove_cvref_t<std::invoke_result_t<std::modulus<>&, L, R>>, R> &&
    weakly_remainder_assignable<L, std::invoke_result_t<std::modulus<>&, L, R>> &&
    weakly_remainder_assignable<std::remove_cvref_t<std::invoke_result_t<std::modulus<>&, L, R>>, std::invoke_result_t<std::modulus<>&, L, R>>;


template<class T>
concept weakly_incrementable =
    std::movable<T> &&
    requires (T v) {
        { ++v } -> std::same_as<T&>;
        v++;
    };

template<class T>
concept weakly_decrementable =
    std::movable<T> &&
    requires (T v) {
        { --v } -> std::same_as<T&>;
        v--;
    };


template<class T>
concept incrementable =
    std::regular<T> &&
    weakly_incrementable<T> &&
    requires (T v) {
        { v++ } -> std::same_as<T>;
    };

template<class T>
concept decrementable =
    std::regular<T> &&
    weakly_decrementable<T> &&
    requires (T v) {
        { v-- } -> std::same_as<T>;
    };


template<class L, class R = L>
concept weakly_arithmetic_operable =
    weakly_addable<L, R> &&
    weakly_subtractable<L, R> &&
    weakly_multipliable<L, R> &&
    weakly_divisable<L, R>;

template<class L, class R = L>
concept weakly_arithmetic_operation_assignable =
    weakly_addition_assignable<L, R> &&
    weakly_subtraction_assignable<L, R> &&
    weakly_multipliation_assignalbe<L, R> &&
    weakly_division_assignable<L, R>;

template<class L, class R = L>
concept arithmetic_operable =
    weakly_arithmetic_operable<L, R> &&
    addable<L, R> &&
    subtractable<L, R> &&
    multipliable<L, R> &&
    divisable<L, R>;

template<class L, class R = L>
concept arithmetic_operation_assignable =
    weakly_arithmetic_operation_assignable<L, R> &&
    addition_assignable<L, R> &&
    subtraction_assignable<L, R> &&
    multipliation_assignalbe<L, R> &&
    division_assignable<L, R>;


template<class T>
concept unary_addable =
    requires (T v) {
        { +v } -> std::same_as<T>;
    };

template<class T>
concept unary_subtractable =
    requires (T v) {
        { -v } -> std::same_as<T>;
    };


template<class T>
concept numeric =
    std::regular<T> &&
    arithmetic_operable<T> &&
    arithmetic_operation_assignable<T> &&
    weakly_incrementable<T> &&
    unary_addable<T> &&
    unary_subtractable<T>;


} // namespace internal

} // namespace uni
#line 6 "numeric/internal/mod.hpp"


namespace uni {


template<class T, class R>
    requires
        internal::remainder_calculable<T, R> &&
        internal::subtractable<T, R> &&
        internal::unary_subtractable<T>
inline T mod(T x, const R& r) noexcept(NO_EXCEPT) {
    if(x >= 0) return x % r;
    x = -x % r;
    if(x != 0) x = r - x;
    return x;
}


} // namespace uni
#line 2 "numeric/arithmetic.hpp"


#include <cassert>
#include <cstring>
#line 13 "numeric/arithmetic.hpp"
#include <bit>


#include <atcoder/math>


#line 21 "numeric/arithmetic.hpp"

#line 2 "internal/types.hpp"

#line 4 "internal/types.hpp"

namespace uni {

namespace internal {


using size_t = std::int64_t;

using int128_t = __int128_t;
using uint128_t = __uint128_t;


} // namesapce internal

} // namespace uni
#line 25 "numeric/arithmetic.hpp"

#line 27 "numeric/arithmetic.hpp"

#line 2 "numeric/internal/number_base.hpp"


#line 5 "numeric/internal/number_base.hpp"
#include <cstddef>
#include <string_view>
#line 14 "numeric/internal/number_base.hpp"


#line 18 "numeric/internal/number_base.hpp"

#line 2 "adaptor/string.hpp"


#line 6 "adaptor/string.hpp"

#line 2 "adaptor/internal/advanced_container.hpp"


#line 8 "adaptor/internal/advanced_container.hpp"

#line 11 "adaptor/internal/advanced_container.hpp"

#line 15 "adaptor/internal/advanced_container.hpp"

#line 2 "iterable/internal/operation_base.hpp"


#line 6 "iterable/internal/operation_base.hpp"
#include <sstream>
#include <numeric>


#line 11 "iterable/internal/operation_base.hpp"


namespace uni {


template<std::input_iterator I, std::sentinel_for<I> S>
std::string join(I first, S last, const char* sep = "") noexcept(NO_EXCEPT) {
    if(first == last) return "";
    std::ostringstream res;
    while(true) {
        res << *first;
        std::ranges::advance(first, 1);
        if(first == last) break;
        res << sep;
    }
    return res.str();
}


template<std::ranges::input_range R>
std::string join(R&& range, const char* sep = "") noexcept(NO_EXCEPT) {
    return join(ALL(range), sep);
}


template<class I, class T = std::iter_value_t<I>>
    requires std::sentinel_for<I, I>
T sum(I first, I last, const T& base = T()) noexcept(NO_EXCEPT) {
    return std::accumulate(first, last, base);
}

template<std::ranges::input_range R, class T = std::ranges::range_value_t<R>>
auto sum(R&& range, T base = T()) noexcept(NO_EXCEPT) {
    auto&& r = range | std::views::common;
    return sum(ALL(r), base);
}


} // namesapce uni
#line 18 "adaptor/internal/advanced_container.hpp"


#define UNI_ADVANCED_CONTAINER_OPERATOR(op_assign, op, concepts) \
    auto& operator op_assign(const value_type& v) noexcept(NO_EXCEPT) \
        requires concepts<value_type> \
    { \
        if constexpr(concepts<Base, value_type>) { \
            this->Base::operator op_assign(v); \
        } \
        else { \
            REP(itr, ALL(*this)) *itr op_assign v; \
        } \
        return *this; \
    } \
    \
    auto& operator op_assign(const advanced_container& rhs) noexcept(NO_EXCEPT) \
        requires concepts<value_type> \
    { \
        if constexpr(concepts<Base>) { \
            this->Base::operator op_assign(*rhs._base()); \
        } \
        else { \
            auto itr = std::ranges::begin(*this), rhs_itr = std::ranges::begin(rhs); \
            auto end = std::ranges::end(*this); \
            for(; itr != end; ++itr, ++rhs_itr) { \
                *itr op_assign *rhs_itr; \
            } \
        } \
        return *this; \
    } \
    \
    template<class T = value_type> \
        requires \
            concepts<value_type> && \
            (std::convertible_to<T, value_type> || std::same_as<T, advanced_container>) \
    friend auto operator op(advanced_container lhs, const T& rhs) noexcept(NO_EXCEPT) { \
        return lhs op_assign rhs; \
    } \
    \
    template<class T = value_type> \
        requires \
            concepts<value_type> && std::convertible_to<T, value_type> \
    friend auto operator op(const T& lhs, advanced_container rhs) noexcept(NO_EXCEPT) { \
        return advanced_container(rhs.size(), lhs) op_assign rhs; \
    }


namespace uni {

namespace internal {


template<class Base>
struct advanced_container : Base {
  private:
    inline Base* _base() noexcept(NO_EXCEPT) {
        return static_cast<Base*>(this);
    }
    inline const Base* _base() const noexcept(NO_EXCEPT) {
        return static_cast<const Base*>(this);
    }

  public:
    using Base::Base;

    advanced_container(const Base& base) : Base(base) {}

    using size_type = decltype(std::ranges::size(std::declval<Base>()));
    using value_type = Base::value_type;

    inline auto ssize() const noexcept(NO_EXCEPT) { return std::ranges::ssize(*this->_base()); }


    inline const auto& operator[](internal::size_t p) const noexcept(NO_EXCEPT) {
        p = p < 0 ? p + this->size() : p;
        assert(0 <= p && p < this->ssize());
        return this->Base::operator[](p);
    }

    inline auto& operator[](internal::size_t p) noexcept(NO_EXCEPT) {
        p = p < 0 ? p + this->size() : p;
        assert(0 <= p && p < this->ssize());
        return this->Base::operator[](p);
    }


    inline auto& fill(const value_type& v) noexcept(NO_EXCEPT) {
        std::ranges::fill(*this, v);
        return *this;
    }

    inline auto& swap(const size_type i, const size_type j) noexcept(NO_EXCEPT) {
        std::swap(this->operator[](i), this->operator[](j));
        return *this;
    }

    inline auto& sort() noexcept(NO_EXCEPT) {
        std::ranges::sort(*this);
        return *this;
    }

    template<class F>
    inline auto& sort(F&& f) noexcept(NO_EXCEPT) {
        std::ranges::sort(*this, std::forward<F>(f));
        return *this;
    }

    inline auto& stable_sort() noexcept(NO_EXCEPT) {
        std::ranges::stable_sort(*this);
        return *this;
    }

    template<class F>
    inline auto& stable_sort(F&& f) noexcept(NO_EXCEPT) {
        std::ranges::stable_sort(*this, std::forward<F>(f));
        return *this;
    }

    inline auto& reverse() noexcept(NO_EXCEPT) {
        std::ranges::reverse(*this);
        return *this;
    }

    inline auto count(const value_type& v) const noexcept(NO_EXCEPT) {
        return std::ranges::count(*this, v);
    }

    template<class F>
    inline auto count_if(F&& f) const noexcept(NO_EXCEPT) {
        return std::ranges::count_if(*this, std::forward<F>(f));
    }

    inline auto& resize(const size_type k) noexcept(NO_EXCEPT) {
        this->Base::resize(k);
        return *this;
    }
    inline auto& resize(const size_type k, const value_type v) noexcept(NO_EXCEPT) {
        this->Base::resize(k, v);
        return *this;
    }

    template<class F>
    inline auto& shuffle(F&& f) noexcept(NO_EXCEPT) {
        std::ranges::shuffle(*this, std::forward<F>(f));
        return *this;
    }

    inline auto& unique() noexcept(NO_EXCEPT) {
        const auto rest = std::ranges::unique(*this);
        this->erase(ALL(rest));
        return *this;
    }

    template<class T>
    inline auto binary_search(const T& v) noexcept(NO_EXCEPT) {
        return std::ranges::binary_search(*this, v);
    }

    template<class T>
    inline auto lower_bound(const T& v) noexcept(NO_EXCEPT) {
        return std::ranges::lower_bound(*this, v);
    }

    template<class T>
    inline auto upper_bound(const T& v) noexcept(NO_EXCEPT) {
        return std::ranges::upper_bound(*this, v);
    }

    inline auto join(const char* sep = "") noexcept(NO_EXCEPT) {
        return uni::join(*this, sep);
    }


    inline auto sum() const noexcept(NO_EXCEPT) { return uni::sum(*this); }


    inline auto max() const noexcept(NO_EXCEPT) { return std::ranges::max(*this->_base()); }
    inline auto min() const noexcept(NO_EXCEPT) { return std::ranges::min(*this); }


    inline auto begin() noexcept(NO_EXCEPT) { return std::ranges::begin(*this->_base()); }
    inline auto begin() const noexcept(NO_EXCEPT) { return std::ranges::begin(*this->_base()); }

    inline auto end() noexcept(NO_EXCEPT) { return std::ranges::end(*this->_base()); }
    inline auto end() const noexcept(NO_EXCEPT) { return std::ranges::end(*this->_base()); }


    UNI_ADVANCED_CONTAINER_OPERATOR(+=, +, internal::weakly_addition_assignable)
    UNI_ADVANCED_CONTAINER_OPERATOR(-=, -, internal::weakly_subtraction_assignable)
    UNI_ADVANCED_CONTAINER_OPERATOR(*=, *, internal::weakly_multipliation_assignalbe)
    UNI_ADVANCED_CONTAINER_OPERATOR(/=, /, internal::weakly_division_assignable)
    UNI_ADVANCED_CONTAINER_OPERATOR(%=, %, internal::weakly_remainder_assignable)
    UNI_ADVANCED_CONTAINER_OPERATOR(&=, &, internal::weakly_bitand_assignable)
    UNI_ADVANCED_CONTAINER_OPERATOR(|=, |, internal::weakly_bitor_assignable)
    UNI_ADVANCED_CONTAINER_OPERATOR(^=, ^, internal::weakly_bitxor_assignable)
};


} // namespace internal

} // namespace uni

#undef UNI_ADVANCED_CONTAINER_OPERATOR
#line 8 "adaptor/string.hpp"


namespace uni {


using string = internal::advanced_container<std::string>;


} // namespace uni


namespace std {


template<>
struct hash<uni::string> {
    inline auto operator()(const uni::string& key) const noexcept(NO_EXCEPT) {
        return std::hash<std::string>{}(static_cast<std::string>(key));
    }
};



}
#line 2 "adaptor/vector.hpp"


#line 6 "adaptor/vector.hpp"


#line 9 "adaptor/vector.hpp"


namespace uni {


template<class... Args>
using vector = internal::advanced_container<std::vector<Args...>>;


} // namespace uni
#line 21 "numeric/internal/number_base.hpp"


namespace uni {


template<std::size_t B, class T>
uni::string to_base_n_string(T v) noexcept(NO_EXCEPT) {
    constexpr std::string_view CHARS = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ";
    static_assert(0 < B and B <= std::ranges::size(CHARS));
    assert(0 <= v);

    uni::string res;
    while(v > 0) {
        res += CHARS[v%B];
        v /= B;
    }
    std::reverse(ALL(res));

    return res;
}


template<class T>
uni::string to_base_n_string(T v, const uni::internal::size_t b) noexcept(NO_EXCEPT) {
    constexpr std::string_view CHARS = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ";
    assert(1 < b && b <= std::ranges::ssize(CHARS));
    assert(0 <= v);

    if(v == 0) return "0";

    uni::string res;

    while(v > 0) {
        res += CHARS[v % b];
        v /= b;
    }
    std::reverse(ALL(res));

    return res;
}

template<class T>
uni::vector<T> to_base_n_vector(T v, const uni::internal::size_t b) noexcept(NO_EXCEPT) {
    assert(1 < b);
    assert(0 <= v);

    uni::vector<T> res;

    while(v > 0) {
        res.push_back(v%b);
        v /= b;
    }


    return res;
}

template<std::bidirectional_iterator I, class T = typename std::iterator_traits<I>::value_type>
T from_base_n_sequence(I begin, I end, const uni::internal::size_t b) noexcept(NO_EXCEPT) {
    assert(1 < b);

    if(begin == end) return 0;

    T res = 0;
    for(auto itr=end; itr-- != begin; ) {
        res *= b;
        res += *itr;
    }

    return res;
}

template<class T, std::forward_iterator I>
T from_base_n_string(I begin, I end, const uni::internal::size_t b) noexcept(NO_EXCEPT) {
    assert(1 < b);

    if(begin == end) return 0;

    T sgn = 1;
    if(*begin == '-') {
        sgn = -1;
        ++begin;
    }

    T res = 0;
    for(auto itr=begin; itr != end; ++itr) {
        res *= b;
        if('0' <= *itr && *itr <= '9') {
            res += *itr - '0';
        }
        else if('a' <= *itr && *itr <= 'z') {
            res += *itr - 'a' + 10;
        }
        else if('A' <= *itr && *itr <= 'Z'){
            res += *itr - 'A' + 10;
        }
        else {
            assert(false);
        }
    }

    return res * sgn;
}


template<std::ranges::bidirectional_range R, class T = std::ranges::range_value_t<R>>
    requires std::ranges::common_range<R>
T from_base_n_sequence(R range, const uni::internal::size_t b) noexcept(NO_EXCEPT) {
    return from_base_n_sequence(std::ranges::begin(range), std::ranges::end(range), b);
}

template<class T, std::ranges::bidirectional_range R>
    requires std::ranges::common_range<R>
T from_base_n_string(R range, const uni::internal::size_t b) noexcept(NO_EXCEPT) {
    return from_base_n_string<T>(std::ranges::begin(range), std::ranges::end(range), b);
}



} // namespace uni
#line 29 "numeric/arithmetic.hpp"

#line 2 "iterable/operation.hpp"


#line 6 "iterable/operation.hpp"
#include <initializer_list>
#line 9 "iterable/operation.hpp"
#include <valarray>
#line 17 "iterable/operation.hpp"


#line 21 "iterable/operation.hpp"

#line 2 "internal/exception.hpp"


namespace uni {

namespace internal {


template<class... T> inline constexpr bool EXCEPTION_ON_TYPE = false;
template<auto T> inline constexpr bool EXCEPTION_ON_VALUE = false;


} // namespace internal

} // namespace uni
#line 2 "internal/iterator.hpp"


#line 7 "internal/iterator.hpp"
#include <variant>
#include <compare>
#line 10 "internal/iterator.hpp"


#line 13 "internal/iterator.hpp"

#line 16 "internal/iterator.hpp"


namespace uni {

namespace internal {


template<class T>
struct iterator_interface {
    using iterator_category = std::output_iterator_tag;

    using difference_type = size_t;
    using value_type = T;

    using pointer = T*;
    using reference = T&;

    // virtual T operator*() const noexcept(NO_EXCEPT) { return 0; };
};

template<class T>
struct forward_iterator : iterator_interface<T> {
    using iterator_category = std::forward_iterator_tag;

    // virtual bidirectional_iterator_interface& operator++() = 0;
};

template<class T>
struct bidirectional_iterator_interface : forward_iterator<T> {
    using iterator_category = std::bidirectional_iterator_tag;

    // virtual bidirectional_iterator_interface& operator--() = 0;
};

template<class T>
struct random_access_iterator_base : bidirectional_iterator_interface<T> {
    using iterator_category = std::random_access_iterator_tag;
    using difference_type = typename bidirectional_iterator_interface<T>::difference_type;

  public:
    // virtual random_access_iterator_base& operator+=(const difference_type count) = 0;
    // virtual random_access_iterator_base& operator-=(const difference_type count) = 0;

    friend inline random_access_iterator_base operator+(random_access_iterator_base itr, const difference_type count) noexcept(NO_EXCEPT) { return itr += count, itr; }
    friend inline random_access_iterator_base operator-(random_access_iterator_base itr, const difference_type count) noexcept(NO_EXCEPT) { return itr -= count, itr; }

};

template<class T, class Container, class Derived>
struct container_iterator_interface : random_access_iterator_base<T> {
    using difference_type = std::make_signed_t<typename Container::size_type>;

  private:
    using derived = std::remove_cvref_t<Derived>;

    Container* _ref;
    difference_type _pos;

    static_assert(std::three_way_comparable<difference_type>);

    inline auto* _derived() noexcept(NO_EXCEPT) {
        return static_cast<derived*>(this);
    }
    inline const auto* _derived() const noexcept(NO_EXCEPT) {
        return static_cast<const derived*>(this);
    }

  public:
    container_iterator_interface() noexcept = default;
    container_iterator_interface(Container *const ref, const difference_type pos) noexcept(NO_EXCEPT) : _ref(ref), _pos(pos) {}

    inline auto ref() const noexcept(NO_EXCEPT) { return this->_ref; }

    inline auto pos() const noexcept(NO_EXCEPT) { return this->_pos; }
    inline auto& pos() { return this->_pos; }

    inline auto& operator++() noexcept(NO_EXCEPT) { return ++this->_pos, *this->_derived(); }
    inline auto& operator--() noexcept(NO_EXCEPT) { return --this->_pos, *this->_derived(); }

    inline auto operator++(int) noexcept(NO_EXCEPT) { auto res = *this->_derived(); return ++this->_pos, res; }
    inline auto operator--(int) noexcept(NO_EXCEPT) { auto res = *this->_derived(); return --this->_pos, res; }

    inline auto& operator+=(const difference_type count) noexcept(NO_EXCEPT) { return this->_pos += count, *this->_derived(); }
    inline auto& operator-=(const difference_type count) noexcept(NO_EXCEPT) { return this->_pos -= count, *this->_derived(); }

    inline auto operator*() const noexcept(NO_EXCEPT) { return this->ref()->get(this->_pos); }
    inline auto operator[](const difference_type count) const noexcept(NO_EXCEPT) { return *(*this->_derived() + count); }

    inline auto operator-(const derived& other) const noexcept(NO_EXCEPT) { return this->_pos - other._pos; }


    friend inline bool operator==(const derived& lhs, const derived& rhs) noexcept(NO_EXCEPT) {
        if(lhs.ref() == rhs.ref()) return lhs._pos == rhs._pos;
        return false;
    }

    friend inline std::partial_ordering operator<=>(const derived& lhs, const derived& rhs) noexcept(NO_EXCEPT) {
        if(lhs.ref() != rhs.ref()) return std::partial_ordering::unordered;
        return lhs._pos <=> rhs._pos;
    }
};


namespace iterator_impl {


template<class... Tags>
using is_all_random_access_iterator = is_base_of_all<std::random_access_iterator_tag,Tags...>;

template<class... Tags>
using is_all_bidirectional_iterator = is_base_of_all<std::bidirectional_iterator_tag,Tags...>;

template<class... Tags>
using is_all_forward_iterator = is_base_of_all<std::forward_iterator_tag,Tags...>;

template<class... Tags>
using is_all_input_iterator = is_base_of_all<std::input_iterator_tag,Tags...>;


template<class... Tags>
constexpr auto _most_primitive_iterator_tag() {
    if constexpr(is_all_random_access_iterator<Tags...>::value) {
        return std::random_access_iterator_tag{};
    }
    else if constexpr(is_all_bidirectional_iterator<Tags...>::value) {
        return std::bidirectional_iterator_tag{};
    }
    else if constexpr(is_all_forward_iterator<Tags...>::value) {
        return std::forward_iterator_tag{};
    }
    else {
        return std::input_iterator_tag{};
    }
}


} // namespace iterator_impl


template<class... Tags>
using most_primitive_iterator_tag = decltype(iterator_impl::_most_primitive_iterator_tag<Tags...>());


template<class T, class = void>
struct is_iterator {
   static constexpr bool value = false;
};

template<class T>
struct is_iterator<T, typename std::enable_if<!std::is_same<typename std::iterator_traits<T>::value_type, void>::value>::type> {
   static constexpr bool value = true;
};

template<class T>
inline constexpr bool is_iterator_v = is_iterator<T>::value;

template<class T>
using is_iterator_t = std::enable_if_t<is_iterator_v<T>>;

template<class T>
using iota_diff_t = std::make_signed_t<T>;


} // namespace internal

} // namespace uni
#line 2 "internal/ranges.hpp"


#line 7 "internal/ranges.hpp"


#line 11 "internal/ranges.hpp"


namespace uni {

namespace internal {


template<class Range>
concept resizable_range
  = std::ranges::range<Range> &&
    requires (Range& r) { r.resize(0); };

template<class range>
concept simple_view
  = std::ranges::view<range> && std::ranges::range<const range> &&
    std::same_as<std::ranges::iterator_t<range>, std::ranges::iterator_t<const range>> &&
    std::same_as<std::ranges::sentinel_t<range>, std::ranges::sentinel_t<const range>>;


template<class... Ranges>
concept zip_is_common = (sizeof...(Ranges) == 1 && (std::ranges::common_range<Ranges> && ...))
    || (!(std::ranges::bidirectional_range<Ranges> && ...) && (std::ranges::common_range<Ranges> && ...))
    || ((std::ranges::random_access_range<Ranges> && ...) && (std::ranges::sized_range<Ranges> && ...));


template<bool Const, class... Views>
concept all_contiguous = (std::ranges::contiguous_range<maybe_const_t<Const, Views>> && ...);

template<bool Const, class... Views>
concept all_random_access = (std::ranges::random_access_range<maybe_const_t<Const, Views>> && ...);

template<bool Const, class... Views>
concept all_bidirectional = (std::ranges::bidirectional_range<maybe_const_t<Const, Views>> && ...);

template<bool Const, class... Views>
concept all_forward = (std::ranges::forward_range<maybe_const_t<Const, Views>> && ...);


template<bool Const, class... Views> struct zip_view_iterator_category {};

template<bool Const, class... Views>
    requires all_forward<Const, Views...>
struct zip_view_iterator_category<Const, Views...> {
    using iterator_category = std::input_iterator_tag;
};


template<bool Const, class... Views>
static auto _most_primitive_iterator_concept() noexcept(NO_EXCEPT) {
    if constexpr(all_random_access<Const, Views...>)
        return std::random_access_iterator_tag{};
    else if constexpr(all_bidirectional<Const, Views...>)
        return std::bidirectional_iterator_tag{};
    else if constexpr(all_forward<Const, Views...>)
        return std::forward_iterator_tag{};
    else
        return std::input_iterator_tag{};
}

template<bool Const, class... Views>
using most_primitive_iterator_concept = decltype(_most_primitive_iterator_concept<Const, Views...>());


template<class Range, bool Const>
using range_iterator_category = typename std::iterator_traits<
        std::ranges::iterator_t<maybe_const_t<Const, Range>>
    >::iterator_category;



template<class Range>
static constexpr auto _iterator_concept() noexcept(NO_EXCEPT) {
    if constexpr(std::ranges::random_access_range<Range>)
        return std::random_access_iterator_tag{};
    else if constexpr(std::ranges::bidirectional_range<Range>)
        return std::bidirectional_iterator_tag{};
    else if constexpr(std::ranges::forward_range<Range>)
        return std::forward_iterator_tag{};
    else
        return std::input_iterator_tag{};
}

template<class Range>
using iterator_concept = decltype(_iterator_concept<Range>());



template<std::ranges::range Range> struct cached_position {
    constexpr bool has_value() const { return false; }

    constexpr std::ranges::iterator_t<Range> get(const Range&) const {
        __builtin_unreachable();
    }

    constexpr void set(const Range &, const std::ranges::iterator_t<Range> &) const {}
};

template<std::ranges::forward_range Range>
struct cached_position<Range> : protected std::optional<std::ranges::iterator_t<Range>> {
    using std::optional<std::ranges::iterator_t<Range>>::optioanl;
    using std::optional<std::ranges::iterator_t<Range>>::has_value;

    constexpr std::ranges::iterator_t<Range> get(const Range&) const {
        assert(this->has_value());
        return **this;
    }

    constexpr void set(const Range&, const std::ranges::iterator_t<Range>& itr) {
        assert(!this->has_value());
        this->emplace(*itr);
    }
};


template<std::ranges::random_access_range Range>
    requires(sizeof(std::ranges::range_difference_t<Range>) <= sizeof(std::ranges::iterator_t<Range>))
struct cached_position<Range> {
  private:
    std::ranges::range_difference_t<Range> _offset = -1;

  public:
    cached_position() = default;

    constexpr cached_position(const cached_position &) = default;

    constexpr cached_position(cached_position &&other) noexcept {
        *this = std::move(other);
    }

    constexpr cached_position &operator=(const cached_position &) = default;

    constexpr cached_position &operator=(cached_position &&other) noexcept {
        // Propagate the cached offset, but invalidate the source.
        this->_offset = other._offset;
        other._offset = -1;
        return *this;
    }

    constexpr bool has_value() const { return this->_offset >= 0; }

    constexpr std::ranges::iterator_t<Range> get(Range& range) const {
        assert(this->has_value());
        return std::ranges::begin(range) + this->_offset;
    }

    constexpr void set(Range &range, const std::ranges::iterator_t<Range> &itr) {
        assert(!this->has_value());
        this->_offset = itr - std::ranges::begin(range);
    }
};


template<typename T, int Disc>
struct absent { };

template<bool PRESENT, class T, int Disc = 0>
using maybe_present_t = std::conditional_t<PRESENT, T, absent<T, Disc>>;


} // namespace internal


namespace views::adaptor {


template<class Adaptor, class... Args>
concept adaptor_invocable = requires { std::declval<Adaptor>()(std::declval<Args>()...); };

template<class Adaptor, class... Args>
concept adaptor_partial_app_viable =
    (Adaptor::arity > 1) && (sizeof...(Args) == Adaptor::arity - 1) &&
    (std::constructible_from<std::remove_cvref_t<Args>, Args> && ...);

template<class Adaptor, class... Args> struct partial;

template<class, class> struct pipe;


template<class Derived> struct range_adaptor_closure {};


template<class T, class U>
    requires(!std::same_as<T, range_adaptor_closure<U>>)
void is_range_adaptor_closure_fn(const T &, const range_adaptor_closure<U> &);


template<class T>
concept is_range_adaptor_closure = requires(T t) { adaptor::is_range_adaptor_closure_fn(t, t); };


template<class Self, class Range>
    requires is_range_adaptor_closure<Self> && adaptor_invocable<Self, Range>
constexpr auto operator|(Range&& range, Self&& self) {
    return std::forward<Self>(self)(std::forward<Range>(range));
}


template<class Lhs, class Rhs>
    requires is_range_adaptor_closure<Lhs> && is_range_adaptor_closure<Rhs>
constexpr auto operator|(Lhs&& lhs, Rhs&& rhs) {
    return pipe<std::remove_cvref_t<Lhs>, std::remove_cvref_t<Rhs>>{ std::forward<Lhs>(lhs), std::forward<Rhs>(rhs)};
}


template<class Derived> struct range_adaptor {
    template<class... Args>
        requires adaptor_partial_app_viable<Derived, Args...>
    inline constexpr auto operator()(Args&& ..._args) const noexcept(NO_EXCEPT) {
        return partial<Derived, std::remove_cvref_t<Args>...>{
            std::forward<Args>(_args)...
        };
    }
};

template<class Adaptor>
concept closure_has_simple_call_op = Adaptor::has_simple_call_op;

template<class Adaptor, class... Args>
concept adaptor_has_simple_extra_args =
    Adaptor::has_simple_extra_args ||
    Adaptor::template has_simple_extra_args<Args...>;

template<class Adaptor, class... Args>
struct partial : range_adaptor_closure<partial<Adaptor, Args...>> {
    std::tuple<Args...> args;

    constexpr partial(Args... _args) noexcept(NO_EXCEPT) : args(std::move(_args)...) {}

    template<class Range>
        requires adaptor_invocable<Adaptor, Range, const Args &...>
    inline constexpr auto operator()(Range&& range) const & noexcept(NO_EXCEPT) {
        const auto forwarder = [&range](const auto &..._args) constexpr noexcept(NO_EXCEPT) {
            return Adaptor{}(std::forward<Range>(range), _args...);
        };
        return std::apply(forwarder, this->args);
    }

    template<class Range>
        requires adaptor_invocable<Adaptor, Range, Args...>
    inline constexpr auto operator()(Range&& range) && noexcept(NO_EXCEPT) {
        const auto forwarder = [&range](auto &..._args) constexpr noexcept(NO_EXCEPT) {
            return Adaptor{}(std::forward<Range>(range), std::move(_args)...);
        };
        return std::apply(forwarder, this->args);
    }

    template<class Range>
    inline constexpr auto operator()(Range&& range) const && = delete;
};

template<class Adaptor, class Arg>
struct partial<Adaptor, Arg> : range_adaptor_closure<partial<Adaptor, Arg>> {
    Arg arg;

    constexpr partial(Arg _arg) noexcept(NO_EXCEPT) : arg(std::move(_arg)) {}

    template<class Range>
        requires adaptor_invocable<Adaptor, Range, const Arg &>
    inline constexpr auto operator()(Range&& range) const & noexcept(NO_EXCEPT) {
        return Adaptor{}(std::forward<Range>(range), this->arg);
    }

    template<class Range>
        requires adaptor_invocable<Adaptor, Range, Arg>
    inline constexpr auto operator()(Range&& range) && noexcept(NO_EXCEPT) {
        return Adaptor{}(std::forward<Range>(range), std::move(this->arg));
    }

    template<class Range>
    inline constexpr auto operator()(Range&& range) const && = delete;
};

template<class Adaptor, class... Args>
    requires adaptor_has_simple_extra_args<Adaptor, Args...> && (std::is_trivially_copyable_v<Args> && ...)
struct partial<Adaptor, Args...> : range_adaptor_closure<partial<Adaptor, Args...>> {
    std::tuple<Args...> args;

    constexpr partial(Args... _args) noexcept(NO_EXCEPT) : args(std::move(_args)...) {}

    template<class Range>
        requires adaptor_invocable<Adaptor, Range, const Args &...>
    inline constexpr auto operator()(Range&& range) const noexcept(NO_EXCEPT) {
        const auto forwarder = [&range](const auto &..._args) constexpr noexcept(NO_EXCEPT) {
            return Adaptor{}(std::forward<Range>(range), _args...);
        };
        return std::apply(forwarder, this->args);
    }

    static constexpr bool has_simple_call_op = true;
};

template<class Adaptor, class Arg>
    requires adaptor_has_simple_extra_args<Adaptor, Arg> &&
             std::is_trivially_copyable_v<Arg>
struct partial<Adaptor, Arg> : range_adaptor_closure<partial<Adaptor, Arg>> {
    Arg arg;

    constexpr partial(Arg _arg) noexcept(NO_EXCEPT) : arg(std::move(_arg)) {}

    template<class Range>
        requires adaptor_invocable<Adaptor, Range, const Arg &>
    inline constexpr auto operator()(Range&& range) const noexcept(NO_EXCEPT) {
        return Adaptor{}(std::forward<Range>(range), this->arg);
    }

    static constexpr bool has_simple_call_op = true;
};

template<class Lhs, class Rhs, class Range>
concept pipe_invocable = requires {
    std::declval<Rhs>()(std::declval<Lhs>()(std::declval<Range>()));
};

template<class Lhs, class Rhs> struct pipe : range_adaptor_closure<pipe<Lhs, Rhs>> {
    [[no_unique_address]] Lhs lhs;
    [[no_unique_address]] Rhs rhs;

    constexpr pipe(Lhs _lhs, Rhs _rhs) noexcept(NO_EXCEPT) : lhs(std::move(_lhs)), rhs(std::move(_rhs)) {}

    template<class Range>
        requires pipe_invocable<const Lhs &, const Rhs &, Range>
    inline constexpr auto operator()(Range&& range) const & noexcept(NO_EXCEPT) {
        return rhs(lhs(std::forward<Range>(range)));
    }

    template<class Range>
        requires pipe_invocable<Lhs, Rhs, Range>
    inline constexpr auto operator()(Range&& range) && noexcept(NO_EXCEPT) {
        return std::move(rhs)(std::move(lhs)(std::forward<Range>(range)));
    }

    template<class Range>
    inline constexpr auto operator()(Range&& range) const && = delete;
};


template<class Lhs, class Rhs>
    requires closure_has_simple_call_op<Lhs> && closure_has_simple_call_op<Rhs>
struct pipe<Lhs, Rhs> : range_adaptor_closure<pipe<Lhs, Rhs>> {
    [[no_unique_address]] Lhs lhs;
    [[no_unique_address]] Rhs rhs;

    constexpr pipe(Lhs _lhs, Rhs _rhs) noexcept(NO_EXCEPT) : lhs(std::move(_lhs)), rhs(std::move(_rhs)) {}

    template<class Range>
        requires pipe_invocable<const Lhs &, const Rhs &, Range>
    inline constexpr auto operator()(Range&& range) const noexcept(NO_EXCEPT) {
        return rhs(lhs(std::forward<Range>(range)));
    }

    static constexpr bool has_simple_call_op = true;
};


} // namespace views::adaptor


} // namespace uni
#line 28 "iterable/operation.hpp"

#line 2 "iterable/z_array.hpp"


#line 6 "iterable/z_array.hpp"


#line 9 "iterable/z_array.hpp"

#line 2 "adaptor/valarray.hpp"


#line 11 "adaptor/valarray.hpp"

#line 14 "adaptor/valarray.hpp"

#line 16 "adaptor/valarray.hpp"


namespace uni {


template<class T> struct valarray : internal::advanced_container<std::valarray<T>> {
  private:
    using base = internal::advanced_container<std::valarray<T>>;

  public:
    using size_type = internal::size_t;

    using iterator = T*;
    using const_iterator = const T*;

  protected:
    inline bool _validate_index_in_right_open([[maybe_unused]] const size_type p) const noexcept(NO_EXCEPT) {
        return 0 <= p and p < this->size();
    }
    inline bool _validate_index_in_closed([[maybe_unused]] const size_type p) const noexcept(NO_EXCEPT) {
        return 0 <= p and p <= this->size();
    }
    inline bool _validate_rigth_open_interval([[maybe_unused]] const size_type l, [[maybe_unused]] const size_type r) const noexcept(NO_EXCEPT) {
        return 0 <= l and l <= r and r <= this->size();
    }

    inline size_type _positivize_index(const size_type p) const noexcept(NO_EXCEPT) {
        return p < 0 ? this->size() + p : p;
    }

  public:
    valarray() noexcept(NO_EXCEPT) {}

    explicit valarray(const std::size_t length, const T& val = T{}) noexcept(NO_EXCEPT) : base(val, length) {}

    template<std::input_iterator I, std::sentinel_for<I> S>
    valarray(I first, S last) noexcept(NO_EXCEPT) : base(std::ranges::distance(first, last)) { std::ranges::copy(first, last, std::ranges::begin(*this)); }

    template<class U> valarray(const U* pointer, const size_t n) noexcept(NO_EXCEPT) : base(pointer, n) {};

    valarray(const std::slice_array<T>& arr) noexcept(NO_EXCEPT) : base(arr) {};
    valarray(const std::gslice_array<T>& arr) noexcept(NO_EXCEPT) : base(arr) {};
    valarray(const std::mask_array<T>& arr) noexcept(NO_EXCEPT) : base(arr) {};
    valarray(const std::indirect_array<T>& arr) noexcept(NO_EXCEPT) : base(arr) {};
    valarray(const std::initializer_list<T>& init) noexcept(NO_EXCEPT) : base(init) {}
    valarray(const internal::advanced_container<std::valarray<T>>& arr) noexcept(NO_EXCEPT) : base(arr) {}

  #ifdef __GNUC__
    template<class Dom> valarray(const std::_Expr<Dom,T>& expr) noexcept(NO_EXCEPT) : base(expr) {}
  #endif

    inline auto size() const noexcept(NO_EXCEPT) { return static_cast<size_type>(this->base::size()); }

    inline void reserve(const size_type) noexcept(NO_EXCEPT) { /* do nothing */ }

    template<std::input_iterator I, std::sentinel_for<I> S>
    inline void assign(I first, S last) noexcept(NO_EXCEPT) {
        this->resize(std::ranges::distance(first, last));
        std::ranges::copy(first, last, std::ranges::begin(*this));
    }

    inline void assign(const std::size_t length, const T& val = T{}) noexcept(NO_EXCEPT) {
        this->base::resize(length, val);
    }

    inline void resize(const std::size_t length, const T& val = T{}) noexcept(NO_EXCEPT) {
        base temp = *this;
        this->assign(length, val);
        std::move(std::begin(temp), std::min(std::end(temp), std::next(std::begin(temp), length)), std::begin(*this));
    }

    inline const T& operator[](size_type pos) const noexcept(NO_EXCEPT) {
        pos = this->_positivize_index(pos), assert(this->_validate_index_in_right_open(pos));
        return this->base::operator[](pos);
    }
    inline T& operator[](size_type pos) noexcept(NO_EXCEPT) {
        pos = this->_positivize_index(pos), assert(this->_validate_index_in_right_open(pos));
        return this->base::operator[](pos);
    }

    inline const T& back() const noexcept(NO_EXCEPT) { return *std::prev(this->end()); }
    inline T& back() noexcept(NO_EXCEPT) { return *std::prev(this->end()); }

    inline const T& front() const noexcept(NO_EXCEPT) { return *this->begin(); }
    inline T& front() noexcept(NO_EXCEPT) { return *this->begin(); }

    inline auto rbegin() noexcept(NO_EXCEPT) { return std::make_reverse_iterator(std::ranges::end(*this)); }
    inline auto rend() noexcept(NO_EXCEPT) { return std::make_reverse_iterator(std::ranges::begin(*this)); }

    inline auto rbegin() const noexcept(NO_EXCEPT) { return std::make_reverse_iterator(std::ranges::end(*this)); }
    inline auto rend() const noexcept(NO_EXCEPT) { return std::make_reverse_iterator(std::ranges::begin(*this)); }
};


} // namespace uni
#line 11 "iterable/z_array.hpp"


namespace uni {


// Thanks to: atcoder::z_algorithm
template<class SizeType = internal::size_t, class Container = valarray<SizeType>>
struct z_array : Container {
    using size_type = SizeType;

    template<std::input_iterator I, std::sentinel_for<I> S>
    z_array(I first, S last) : Container(std::ranges::distance(first, last), {}) {
        const size_type n = static_cast<size_type>(std::ranges::distance(first, last));
        if(n == 0) return;
        for(size_type i = 1, j = 0; i < n; ++i) {
            size_type& k = this->operator[](i);
            k = (j + this->operator[](j) <= i) ? 0 : std::ranges::min(j + this->operator[](j) - i, this->operator[](i - j));
            while(i + k < n and first[k] == first[i + k]) ++k;
            if(j + this->operator[](j) < i + this->operator[](i)) j = i;
        }
        *this->begin() = n;
    }

    template<std::ranges::input_range R>
    explicit z_array(R&& range) : z_array(ALL(range)) {}
};


} // namespace uni
#line 31 "iterable/operation.hpp"

#line 2 "view/concat.hpp"


#line 11 "view/concat.hpp"


#line 18 "view/concat.hpp"



namespace uni {

namespace internal {

namespace view_impl {


template<std::ranges::input_range V0, std::ranges::input_range V1>
    requires std::ranges::view<V0> && std::ranges::view<V1>
struct concat_view : std::ranges::view_interface<concat_view<V0, V1>> {
  private:
    V0 _b0;
    V1 _b1;

    template<bool Const> using B0 = internal::maybe_const_t<Const, V0>;
    template<bool Const> using B1 = internal::maybe_const_t<Const, V1>;

    template<bool Const> struct iterator_tag {};

    template<bool Const>
        requires std::ranges::forward_range<B0<Const>> && std::ranges::forward_range<B1<Const>>
    struct iterator_tag<Const> {
      public:
        using iterator_category = uni::internal::most_primitive_iterator_tag<
            typename std::iterator_traits<std::ranges::iterator_t<B0<Const>>>::iterator_category,
            typename std::iterator_traits<std::ranges::iterator_t<B1<Const>>>::iterator_category
        >;
    };

  public:
    template<bool> class iterator;

    constexpr explicit concat_view(V0 v0, V1 v1) noexcept(NO_EXCEPT)
      : _b0(std::move(v0)), _b1(std::move(v1))
    {}

    inline constexpr std::pair<V0, V1> base() const & noexcept(NO_EXCEPT)
        requires std::copy_constructible<V0> && std::copy_constructible<V0>
    {
        return { this->_b0, this->_b1 };
    }

    inline constexpr std::pair<V0,V1> base() && noexcept(NO_EXCEPT) {
        return { std::move(this->_b0), std::move(this->_b1) };
    }

    inline constexpr auto begin() noexcept(NO_EXCEPT)
        requires (!internal::simple_view<V0> && !internal::simple_view<V1>)
    {
        return iterator<false>(this, std::ranges::begin(this->_b0), std::ranges::begin(this->_b1), 0);
    }

    inline constexpr auto begin() const noexcept(NO_EXCEPT)
        requires std::ranges::range<const V0> && std::ranges::range<const V1>
    {
        return iterator<true>(this, std::ranges::begin(this->_b0), std::ranges::begin(this->_b1), 0);
    }

    inline constexpr auto end() noexcept(NO_EXCEPT)
        requires (!internal::simple_view<V0> && !internal::simple_view<V1>)
    {
        if constexpr(std::ranges::common_range<V0> && std::ranges::common_range<V1>) {
            return iterator<false>(this, std::ranges::end(this->_b0), std::ranges::end(this->_b1), 1);
        }
        else {
            return std::default_sentinel;
        }
    }

    inline constexpr auto end() const noexcept(NO_EXCEPT)
        requires std::ranges::range<const V0> && std::ranges::range<const V1>
    {
        if constexpr(std::ranges::common_range<const V0> && std::ranges::common_range<const V1>) {
            return iterator<true>(this, std::ranges::end(this->_b0), std::ranges::end(this->_b1), 1);
        }
        else {
            return std::default_sentinel;
        }
    }

    inline constexpr auto size() noexcept(NO_EXCEPT)
        requires std::ranges::sized_range<V0> && std::ranges::sized_range<V1>
    {
        return static_cast<std::size_t>(std::ranges::distance(this->_b0) + std::ranges::distance(this->_b1));
    }

    inline constexpr auto size() const noexcept(NO_EXCEPT)
        requires std::ranges::sized_range<const V0> && std::ranges::sized_range<const V1>
    {
        return static_cast<std::size_t>(std::ranges::distance(this->_b0) + std::ranges::distance(this->_b1));
    }
};

template<std::ranges::input_range V0, std::ranges::input_range V1>
    requires std::ranges::view<V0> && std::ranges::view<V1>
template<bool Const>
struct concat_view<V0, V1>::iterator : iterator_tag<Const> {
  private:
    using Parent = internal::maybe_const_t<Const, concat_view>;

    using B0 = concat_view::B0<Const>;
    using B1 = concat_view::B1<Const>;

    std::ranges::iterator_t<B0> _c0 = std::ranges::iterator_t<B0>();
    std::ranges::iterator_t<B0> _b0 = std::ranges::iterator_t<B0>();
    std::ranges::sentinel_t<B0> _e0 = std::ranges::sentinel_t<B0>();

    std::ranges::iterator_t<B1> _c1 = std::ranges::iterator_t<B1>();
    std::ranges::iterator_t<B1> _b1 = std::ranges::iterator_t<B1>();
    std::ranges::sentinel_t<B1> _e1 = std::ranges::sentinel_t<B1>();

    int _block = 0;

    constexpr iterator(Parent *const parent, const std::ranges::iterator_t<B0> c0, const std::ranges::iterator_t<B1> c1, const int block) noexcept(NO_EXCEPT)
      : _c0(std::move(c0)), _b0(std::ranges::begin(parent->_b0)), _e0(std::ranges::end(parent->_b0)),
        _c1(std::move(c1)), _b1(std::ranges::begin(parent->_b1)), _e1(std::ranges::end(parent->_b1)),
        _block(block || std::ranges::empty(parent->_b0))
    {}

    friend concat_view;

  public:
    using difference_type = std::common_type_t<std::ranges::range_difference_t<B0>, std::ranges::range_difference_t<B1>>;

    using value_type = std::common_type_t<std::ranges::range_value_t<B0>, std::ranges::range_value_t<B1>>;
    using reference_type = std::common_reference_t<std::ranges::range_reference_t<B0>, std::ranges::range_reference_t<B1>>;

    using iterator_concept = most_primitive_iterator_concept<Const, V0, V1>;

    iterator() noexcept(NO_EXCEPT)
        requires std::default_initializable<std::ranges::iterator_t<B0>> &&
                 std::default_initializable<std::ranges::iterator_t<B0>>
    = default;

    constexpr iterator(iterator<!Const> itr) noexcept(NO_EXCEPT)
        requires
            Const &&
            std::convertible_to<std::ranges::iterator_t<V0>, std::ranges::iterator_t<B0>> &&
            std::convertible_to<std::ranges::sentinel_t<V0>, std::ranges::sentinel_t<B0>> &&
            std::convertible_to<std::ranges::iterator_t<V1>, std::ranges::iterator_t<B1>> &&
            std::convertible_to<std::ranges::sentinel_t<V1>, std::ranges::sentinel_t<B1>>
      : _c0(std::move(itr._c0)), _b0(std::move(itr._b0)), _e0(std::move(itr._e0)),
        _c1(std::move(itr._c0)), _b1(std::move(itr._b0)), _e1(std::move(itr._e1)),
        _block(itr._block)
    {}

    inline constexpr std::variant<std::ranges::iterator_t<B0>, std::ranges::iterator_t<B1>>
    base() && noexcept(NO_EXCEPT) {
        if(this->_block == 0) return std::move(this->_c0);
        else return std::move(this->_C1);
    }

    inline constexpr
        std::variant<
            std::reference_wrapper<const std::ranges::iterator_t<B0>>,
            std::reference_wrapper<const std::ranges::iterator_t<B1>>
        >
    base() const & noexcept {
        if(this->_block == 0) return std::move(this->_c0);
        else return std::move(this->_c1);
    }

    inline constexpr reference_type operator*() const noexcept(NO_EXCEPT)
    {

        if(this->_block == 0) return *this->_c0;
        else return *this->_c1;
    }

    inline constexpr iterator& operator++() noexcept(NO_EXCEPT)
    {
        assert(this->_c0 != this->_e0 or this->_c1 != this->_e1);

        if(this->_block == 0) {
            if(++this->_c0 == this->_e0) {
                this->_block = 1;
                assert(this->_c1 == this->_b1);
            }
        }
        else {
            ++this->_c1;
        }

        return *this;
    }

    inline constexpr void operator++(int) noexcept(NO_EXCEPT) { ++*this; }

    inline constexpr iterator operator++(int) noexcept(NO_EXCEPT)
        requires std::ranges::forward_range<B0> && std::ranges::forward_range<B1>
    {
        const auto res = *this; ++*this; return res;
    }

    inline constexpr iterator& operator--() noexcept(NO_EXCEPT)
        requires
            std::ranges::bidirectional_range<B0> && std::ranges::bidirectional_range<B1> &&
            std::bidirectional_iterator<std::ranges::sentinel_t<B0>>
    {
        if(this->_block == 1) {
            if(this->_c1 == this->_b1) {
                this->_block = 0;
                this->_c0 = std::ranges::prev(this->_e0);
            }
            else {
                --this->_c1;
            }
        }
        else {
            --this->_c0;
        }

        return *this;
    }

    inline constexpr iterator operator--(int) noexcept(NO_EXCEPT)
        requires std::ranges::bidirectional_range<B0> && std::ranges::bidirectional_range<B1>
    {
        const auto res = *this; --*this; return res;
    }

    inline constexpr iterator& operator+=(const difference_type diff) noexcept(NO_EXCEPT)
        requires
            std::ranges::random_access_range<B0> && std::ranges::random_access_range<B1>
    {
        if(diff > 0) {
            if(this->_block == 0) {
                const auto missing = std::ranges::advance(this->_c0, diff, this->_e0);
                if(this->_c0 == this->_e0) {
                    this->_block = 1;
                    assert(this->_c1 == this->_b1);
                    std::ranges::advance(this->_c1, missing, this->_e1);
                }
            }
            else {
                std::ranges::advance(this->_c1, diff, this->_e1);
            }
        }
        if(diff < 0) {
            if(this->_block == 1) {
                const auto missing = std::ranges::advance(this->_c1, diff, this->_b1);
                if(missing < 0) {
                    this->_block = 0;
                    assert(this->_c0 == this->_e0);
                    std::ranges::advance(this->_c0, missing, this->_b0);
                }
            }
            else {
                std::ranges::advance(this->_c0, diff, this->_b0);
            }
        }

        return *this;
    }

    inline constexpr iterator& operator-=(const difference_type diff) noexcept(NO_EXCEPT)
        requires std::ranges::random_access_range<B0> && std::ranges::random_access_range<B1>
    {
        return *this += -diff;
    }

    inline constexpr decltype(auto) operator[](const difference_type diff) const noexcept(NO_EXCEPT)
        requires std::ranges::random_access_range<B0> && std::ranges::random_access_range<B1>
    {
        return *(*this + diff);
    }

    friend inline constexpr bool operator==(const iterator& lhs, std::default_sentinel_t) noexcept(NO_EXCEPT)
    {
        if(lhs._block == 0) return false;
        if(lhs._block == 1) return lhs._c1 == lhs._e1;
        assert(false);
    }

    friend inline constexpr bool operator==(const iterator& lhs, const iterator& rhs) noexcept(NO_EXCEPT)
        requires
            std::equality_comparable<std::ranges::iterator_t<B0>> &&
            std::equality_comparable<std::ranges::iterator_t<B1>>
    {
        if(lhs._block != rhs._block) return false;
        return lhs._block == 0 ? lhs._c0 == rhs._c0 : lhs._c1 == rhs._c1;
    }

    friend inline constexpr auto operator<=>(const iterator& lhs, const iterator& rhs) noexcept(NO_EXCEPT)
        requires std::ranges::random_access_range<B0> && std::ranges::random_access_range<B1>
    {
        if(lhs._block != rhs._block) return lhs._block <=> rhs._block;
        return lhs._block == 0 ? lhs._c0 <=> rhs._c0 : lhs._c1 <=> rhs._c1;
    }

    friend inline constexpr iterator operator+(const iterator& itr, const difference_type diff) noexcept(NO_EXCEPT)
        requires std::ranges::random_access_range<B0> && std::ranges::random_access_range<B1>
    {
        auto res = itr; res += diff; return res;
    }

    friend inline constexpr iterator operator+(const difference_type diff, const iterator& itr) noexcept(NO_EXCEPT)
        requires std::ranges::random_access_range<B0> && std::ranges::random_access_range<B1>
    {
        return itr + diff;
    }

    friend inline constexpr iterator operator-(const iterator& itr, const difference_type diff) noexcept(NO_EXCEPT)
        requires std::ranges::random_access_range<B0> && std::ranges::random_access_range<B1>
    {
        auto res = itr; res -= diff; return res;
    }

    friend inline constexpr const difference_type operator-(const iterator& lhs, const iterator& rhs) noexcept(NO_EXCEPT)
        requires
            std::sized_sentinel_for<std::ranges::iterator_t<B0>, std::ranges::iterator_t<B0>> &&
            std::sized_sentinel_for<std::ranges::iterator_t<B1>, std::ranges::iterator_t<B1>>
    {
        if(lhs._block == rhs._block) {
            return lhs._block == 0 ? std::ranges::distance(rhs._c0, lhs._c0) : std::ranges::distance(rhs._c1, lhs._c1);
        }
        if(lhs._block > rhs._block) return std::ranges::distance(rhs._c0, rhs._e0) + std::ranges::distance(lhs._b1, lhs._c1);
        if(lhs._block < rhs._block) return -(rhs - lhs);
        assert(false);
    }

    friend inline constexpr const difference_type operator-(std::default_sentinel_t, const iterator& rhs) noexcept(NO_EXCEPT)
        requires
            std::sized_sentinel_for<std::ranges::sentinel_t<B0>, std::ranges::iterator_t<B0>> &&
            std::sized_sentinel_for<std::ranges::sentinel_t<B1>, std::ranges::iterator_t<B1>>
    {
        if(rhs._block == 0) return std::ranges::distance(rhs._c0, rhs._e0) + std::ranges::distance(rhs._b1, rhs._e1);
        if(rhs._block == 1) return std::ranges::distance(rhs._c1, rhs._e1);
        assert(false);
    }

    friend inline constexpr const difference_type operator-(const iterator& lhs, std::default_sentinel_t rhs) noexcept(NO_EXCEPT)
        requires
            std::sized_sentinel_for<std::ranges::sentinel_t<B0>, std::ranges::iterator_t<B0>> &&
            std::sized_sentinel_for<std::ranges::sentinel_t<B1>, std::ranges::iterator_t<B1>>
    {
        return -(rhs - lhs);
    }

    friend inline constexpr
    std::common_reference_t<
        std::ranges::range_rvalue_reference_t<B0>,
        std::ranges::range_rvalue_reference_t<B1>
    >
    iter_move(const iterator& itr) noexcept(NO_EXCEPT)
    {
        if(itr._block == 0) return std::ranges::iter_move(itr._c0);
        if(itr._block == 1) return std::ranges::iter_move(itr._c1);
        assert(false);
    }

    friend inline constexpr void iter_swap(const iterator& lhs, const iterator& rhs) noexcept(NO_EXCEPT)
        requires
            std::indirectly_swappable<std::ranges::iterator_t<B0>> &&
            std::indirectly_swappable<std::ranges::iterator_t<B1>> &&
            std::indirectly_swappable<std::ranges::iterator_t<B0>, std::ranges::iterator_t<B1>>
    {
        if(lhs._block == 0 && rhs._block == 0) std::ranges::iter_swap(lhs._c0, rhs._c0);
        if(lhs._block == 0 && rhs._block == 1) std::ranges::iter_swap(lhs._c0, rhs._c1);
        if(lhs._block == 1 && rhs._block == 0) std::ranges::iter_swap(lhs._c1, rhs._c0);
        if(lhs._block == 1 && rhs._block == 1) std::ranges::iter_swap(lhs._c1, rhs._c1);
        assert(false);
    }
};


} // namespace view_impl

} // namespace internal


template<class...> struct concat_view;

template<class T>
struct concat_view<T> : std::views::all_t<T> {
    using std::views::all_t<T>::all_t;
};

template<class T0, class T1>
struct concat_view<T0, T1> : internal::view_impl::concat_view<std::views::all_t<T0>, std::views::all_t<T1>> {
    explicit concat_view(T0&& v0, T1&& v1) noexcept(NO_EXCEPT)
      : internal::view_impl::concat_view<std::views::all_t<T0>, std::views::all_t<T1>>(std::forward<T0>(v0), std::forward<T1>(v1))
    {}
};

template<class T0, class T1, class... Ts>
struct concat_view<T0, T1, Ts...> : concat_view<concat_view<T0, T1>, Ts...> {
    explicit concat_view(T0&& v0, T1&& v1, Ts&&... vs) noexcept(NO_EXCEPT)
      : concat_view<concat_view<T0, T1>, Ts...>(
            concat_view<T0, T1>(std::forward<T0>(v0), std::forward<T1>(v1)), std::forward<Ts>(vs)...
        )
    {}
};

namespace views {

namespace internal {


template<class... Ts>
concept can_concat_view = requires { concat_view<Ts...>(std::declval<Ts>()...); };


} // namespace internal


struct Concat {
    template<class... Ts>
        requires (sizeof...(Ts) == 0 || internal::can_concat_view<Ts...>)
    inline constexpr auto operator() [[nodiscard]] (Ts&&... vs) const {
        if constexpr(sizeof...(Ts) == 0) return std::views::empty<std::nullptr_t>;
        else return concat_view<std::views::all_t<Ts>...>(std::forward<Ts>(vs)...);
    }
};


inline constexpr Concat concat;


} // namespace views

} // namespace uni.


namespace std::ranges {


template<class... Views>
inline constexpr bool enable_borrowed_range<uni::concat_view<Views...>> = (enable_borrowed_range<Views> && ...);


}
#line 2 "global/constants.hpp"


#line 7 "global/constants.hpp"
#include <cmath>


#line 11 "global/constants.hpp"

#line 14 "global/constants.hpp"

#line 2 "numeric/limits.hpp"


#line 6 "numeric/limits.hpp"


#line 9 "numeric/limits.hpp"

#line 11 "numeric/limits.hpp"


namespace uni {


template<class T>
struct numeric_limits : std::numeric_limits<T> {
    static constexpr long double FLOAT_EPSILON = 1E-14;

    static constexpr T arithmetic_infinity() noexcept(NO_EXCEPT) {
        return std::numeric_limits<T>::max() / 2 - 1;
    }

    static constexpr T arithmetic_negative_infinity() noexcept(NO_EXCEPT) {
        return std::numeric_limits<T>::lowest() / 2 + 1;
    }

    static constexpr T arithmetic_epsilon() noexcept(NO_EXCEPT) {
        if constexpr(std::is_floating_point_v<T>) {
            return numeric_limits::FLOAT_EPSILON;
        }
        else {
            return 0;
        }
    }
};


constexpr i32 INF32 = numeric_limits<i32>::arithmetic_infinity();
constexpr i64 INF64 = numeric_limits<i64>::arithmetic_infinity();

template<class T>
constexpr T INF = numeric_limits<T>::arithmetic_infinity();

template<class T>
constexpr T EPSILON = numeric_limits<T>::arithmetic_epsilon();


} // namespace uni
#line 16 "global/constants.hpp"


namespace uni {


namespace internal {
    template<class T>
    consteval auto get_pi() {
        if constexpr(std::integral<T>) {
            return static_cast<T>(3);
        }
        else if constexpr(std::same_as<T, float>) {
            return M_PIf;
        }
        else if constexpr(std::same_as<T, double>) {
            return M_PI;
        }
        else if constexpr(std::same_as<T, ld>) {
            return M_PIl;
        }
        else {
            static_assert(EXCEPTION_ON_TYPE<T>);
        }
    }
} // namespace internal


template<class T = ld>
constexpr auto PI = internal::get_pi<T>();


enum class comparison : std::uint8_t {
    equal_to,
    not_equal_to,

    equals = equal_to,
    eq = equal_to,

    under,
    over,
    or_under,
    or_over,

    less = under,
    more = over,

    less_than = under,
    more_than = over,
    not_less_than = or_over,
    not_more_than = or_under,

    leq = or_under,
    geq = or_over
};


enum class interval_notation : std::uint8_t {
    right_open,
    left_open,
    open,
    closed,
};


enum class replacement_policy : std::uint8_t {
    insert_sync,
    overwrite_sync,
    overwrite_async
};


enum class rotation : std::int8_t {
    clockwise,

    counter_clockwise,
    anti_clockwise = counter_clockwise,
};


enum class positional_relation : std::int8_t {
    clockwise,

    counter_clockwise,
    anti_clockwise = counter_clockwise,

    backward,
    forward,

    in,
    on,
    out,

    included = in,
    inscribed,
    intersecting,
    circumscribed,
    distant,
};


enum class alignment : std::int8_t {
    left,
    center,
    right
};


} // namespace uni
#line 35 "iterable/operation.hpp"


namespace uni {


template<std::ranges::input_range R0, std::ranges::input_range R1>
    requires std::constructible_from<
        R0, std::common_type_t<std::ranges::range_size_t<R0>,std::ranges::range_size_t<R1>>
    >
R0 concat(R0&& r0, R1&& r1) noexcept(NO_EXCEPT) {
    R0 res(std::ranges::size(r0) + std::ranges::size(r1));
    std::ranges::copy(r0, std::ranges::begin(res));
    std::ranges::copy(r1, std::ranges::next(std::ranges::begin(res), std::ranges::size(r0)));
    return res;
}

template<std::ranges::input_range R, std::ranges::input_range... Rs>
R concat(R&& range, Rs&&... tails) noexcept(NO_EXCEPT) {
    return uni::concat(range, uni::concat(tails...));
}


template<std::ranges::input_range R>
    requires
        requires(R r) {
            r.erase(std::ranges::unique(ALL(r)), std::ranges::end(r));
        }
inline auto unique(R range) noexcept(NO_EXCEPT) {
    std::ranges::sort(range);
    range.erase(std::ranges::unique(ALL(range)), std::ranges::end(range));
    return range;
}


template<
    std::input_iterator I,
    std::sentinel_for<I> S,
    class T = std::iter_value_t<I>
>
T mex(I first, S last, const T& base = T()) noexcept(NO_EXCEPT) {
    std::vector<T> val(first, last);
    std::ranges::sort(val);
    {
        auto range = std::ranges::unique(val);
        val.erase(ALL(range));
    }
    val.erase(val.begin(), std::ranges::lower_bound(val, base));

    T i = 0;
    while(i < std::ranges::ssize(val) && val[i] == i + base) ++i;

    return T{i} + base;
}

template<std::ranges::input_range R>
auto mex(R&& range, const std::ranges::range_value_t<R>& base = std::ranges::range_value_t<R>()) noexcept(NO_EXCEPT) {
    return mex(ALL(range), base);
}

template<class T>
auto mex(const std::initializer_list<T> v, const T& base = T()) noexcept(NO_EXCEPT) {
    return mex(ALL(v), base);
}


template<std::input_iterator I, std::sentinel_for<I> S, class T>
inline constexpr auto gcd(I first, S last) noexcept(NO_EXCEPT) {
    T res = T{0};
    for(auto itr=first; itr!=last; ++itr) res = std::gcd(res, *itr);
    return res;
}

template<std::input_iterator I, std::sentinel_for<I> S, class T>
inline constexpr auto lcm(I first, S last) noexcept(NO_EXCEPT) {
    T res = T{1};
    for(auto itr=first; itr!=last; ++itr) res = std::lcm(res, *itr);
    return res;
}


template<std::ranges::input_range R, class T = std::ranges::range_value_t<R>>
auto mex(R&& range, const T& base) noexcept(NO_EXCEPT) {
    return mex(ALL(range), base);
}


template<std::ranges::input_range R>
auto gcd(R&& range) noexcept(NO_EXCEPT) {
    return gcd(ALL(range));
}

template<std::ranges::input_range R>
auto lcm(R&& range) noexcept(NO_EXCEPT) {
    return lcm(ALL(range));
}


template<class R, std::input_iterator I, std::sentinel_for<I> S, class D>
    requires
        requires (R r, I itr) {
            r.emplace_back(itr, itr);
        }
auto split(I first, S last, const D& delim = ' ') noexcept(NO_EXCEPT) {
    R res;

    for(auto itr=first, fnd=first; ; itr=std::ranges::next(fnd)) {
        fnd = std::find(itr, last, delim);
        res.emplace_back(itr, fnd);
        if(fnd == last) break;
    }

    return res;
}


template<class R, std::ranges::input_range V, class D>
    requires (!std::ranges::input_range<D>)
auto split(V&& v, D&& d) noexcept(NO_EXCEPT) { return split<R>(ALL(v), d); }


template<class R, std::ranges::input_range V, std::ranges::input_range Ds>
auto split(V&& v, Ds&& ds) noexcept(NO_EXCEPT) {
    R res = { v };
    ITR(d, ds) {
        R tmp;
        ITR(p, res) tmp = concat(tmp, split<R>(p, d));
        res = std::move(tmp);
    }
    return res;
}


template<class R, std::ranges::input_range V, class T>
auto split(V&& v, const std::initializer_list<T> ds) noexcept(NO_EXCEPT){
    return split<R,V>(v, std::vector<T>(ALL(ds)));
}


template<std::ranges::sized_range Source, std::ranges::sized_range Qeury>
auto find(Source&& source,  Qeury&& query) noexcept(NO_EXCEPT) {
    z_array z_arr(views::concat(query, source));
    const auto query_size = std::ranges::ssize(query);

    vector<std::ranges::iterator_t<Source>> res;
    {
        auto itr = std::ranges::begin(source);
        REP(i, query_size, std::ranges::size(z_arr)) {
            if(z_arr[i] >= query_size) res.push_back(itr);
            ++itr;
        }
    }

    return res;
}


template<
    replacement_policy POLICY,
    std::ranges::sized_range R,
    std::ranges::sized_range From,
    std::ranges::sized_range To
>
auto replaced(R&& source, From&& from, To&& to) noexcept(NO_EXCEPT) {
    std::remove_cvref_t<R> res;

    if constexpr(POLICY == replacement_policy::insert_sync) {
        const auto found = find(source, from);
        auto itr = std::ranges::begin(source);
        ITRR(fn, found) {
            std::ranges::copy(itr, fn, std::back_inserter(res));
            std::ranges::copy(ALL(to), std::back_inserter(res));
            itr = std::ranges::next(fn, std::ranges::size(from));
        }
        std::ranges::copy(itr, std::ranges::end(source), std::back_inserter(res));
    }
    else {
        res = source;
        res.resize(std::ranges::size(source) + std::ranges::size(to));

        const auto found = find(res, from);
        auto prev = std::ranges::begin(res);
        ITRR(fn, found) {
            if constexpr(POLICY == replacement_policy::overwrite_sync) {
                if(prev <= fn) prev = std::ranges::copy(to, fn);
            }
            else {
                std::ranges::copy(to, fn);
            }
        }

        res.resize(std::ranges::size(source));
    }

    return res;
}

template<
    std::ranges::sized_range R,
    std::ranges::sized_range From,
    std::ranges::sized_range To
>
inline auto replaced(R&& source, From&& from, To&& to) noexcept(NO_EXCEPT) {
    return replaced<replacement_policy::insert_sync, R, From, To>(std::forward<R>(source), std::forward<From>(from), std::forward<To>(to));
}


template<alignment ALIGNMENT, internal::resizable_range R, class T = std::ranges::range_value_t<R>>
auto align(R&& source, const internal::size_t size, const T& v = T()) noexcept(NO_EXCEPT) {
    if(std::ssize(source) >= size) return source;

    if(ALIGNMENT == alignment::left) {
        R left, right;
        left = source;
        right.resize(size - std::size(left), v);
        return R(ALL(uni::views::concat(left, right)));
    }

    if(ALIGNMENT == alignment::center) {
        R left, center, right;
        center = source;
        left.resize((size - std::size(center)) / 2, v);
        right.resize(size - std::size(center) - std::size(left), v);
        return R(ALL(uni::views::concat(left, center, right)));
    }

    if(ALIGNMENT == alignment::right) {
        R left, right;
        right = source;
        left.resize(size - std::size(right), v);
        return R(ALL(uni::views::concat(left, right)));
    }
    assert(false);
}


template<internal::resizable_range R, class T = std::ranges::range_value_t<R>>
auto ljust(R&& source, const internal::size_t size, const T& v = T()) noexcept(NO_EXCEPT) {
    return align<alignment::left>(source, size, v);
}

template<internal::resizable_range R, class T = std::ranges::range_value_t<R>>
auto cjust(R&& source, const internal::size_t size, const T& v = T()) noexcept(NO_EXCEPT) {
    return align<alignment::center>(source, size, v);
}

template<internal::resizable_range R, class T = std::ranges::range_value_t<R>>
auto rjust(R&& source, const internal::size_t size, const T& v = T()) noexcept(NO_EXCEPT) {
    return align<alignment::right>(source, size, v);
}


template<
    class Res,
    std::ranges::random_access_range Target,
    std::ranges::forward_range Order
>
    requires std::ranges::output_range<Res, std::ranges::range_value_t<Target>>
Res ordered_by(Target&& target, Order&& order) noexcept(NO_EXCEPT) {
    const auto target_size = std::ranges::ssize(target);
    const auto order_size = std::ranges::ssize(order);
    Res res(order_size);

    {
        auto res_itr = std::ranges::begin(res);
        auto order_itr = std::ranges::begin(order);
        const auto order_end = std::ranges::end(std::forward<Order>(order));

        for(; order_itr != order_end; ++res_itr, ++order_itr) {
            if constexpr(std::signed_integral<std::ranges::range_value_t<Order>>) assert(0 <= *order_itr);
            assert(*order_itr < target_size);
            *res_itr = target[*order_itr];
        }
    }

    return res;
}


template<
    std::ranges::random_access_range Target,
    std::ranges::forward_range Order
>
auto ordered_by(Target&& target, Order&& order) noexcept(NO_EXCEPT) {
    return ordered_by<std::remove_cvref_t<Target>, Target, Order>(std::forward<Target>(target), std::forward<Order>(order));
}


template<std::ranges::input_range Target, std::ranges::input_range Source>
    requires std::equality_comparable_with<std::ranges::range_value_t<Target>, std::ranges::range_value_t<Source>>
auto is_subsequence_of(Target&& target, Source&& source) noexcept(NO_EXCEPT) {
    auto target_itr = std::ranges::begin(source);
    auto source_itr = std::ranges::begin(source);

    const auto target_end = std::ranges::end(source);
    const auto source_end = std::ranges::end(source);

    for(; source_itr != source_end; ++source_itr) {
        if(*target_itr == *source_itr) ++target_itr;
    }

    return target_itr == target_end;
}


template<std::ranges::input_range Target, std::ranges::input_range Source>
    requires std::equality_comparable_with<std::ranges::range_value_t<Target>, std::ranges::range_value_t<Source>>
auto is_continuous_subsequence_of(Target&& target, Source&& source) noexcept(NO_EXCEPT) {
    auto found = find(source, target);
    return found.size() > 0;
}


} // namespace uni
#line 31 "numeric/arithmetic.hpp"


namespace uni {


template<class T>
inline constexpr T div_floor(const T& x, const T& d) noexcept(NO_EXCEPT) {
    if constexpr(std::is_integral_v<T>) {
        return x / d - (x % d && ((x < 0) ^ (d < 0)));
    }
    else {
        return std::floor(x / d);
    }
}

template<class T>
inline constexpr T div_ceil(const T& x, const T& d) noexcept(NO_EXCEPT) {
    if constexpr(std::is_integral_v<T>) {
        return div_floor(x + d - 1, d);
    }
    else {
        return std::ceil(x / d);
    }
}

template<class T>
inline constexpr T div_round(const T& x, const T& d) noexcept(NO_EXCEPT) {
    if constexpr(std::is_integral_v<T>) {
        return div_round<ld>(x, d);
    }
    else {
        return std::round(x / d);
    }
}


template<class T>
inline constexpr std::make_signed_t<T> to_signed(const T& x) noexcept(NO_EXCEPT) {
    return std::bit_cast<std::make_signed_t<T>>(x);
}

template<class T>
inline constexpr std::make_unsigned_t<T> to_unsigned(const T& x) noexcept(NO_EXCEPT) {
    return std::bit_cast<std::make_unsigned_t<T>>(x);
}


namespace internal {


template<class T>
inline constexpr auto perm(const T& n, const T& r) noexcept(NO_EXCEPT) {
    T res = 1;
    REP(i, r) res *= n - i;
    return res;
}

template<class T>
inline constexpr auto comb(const T& n, T r) noexcept(NO_EXCEPT) {
    if(n < 2 * r) r = n - r;

    T p = 1, q = 1;
    REP(i, r) p *= n - i, q *= r - i;

    return p / q;
}


} // namespace internal


template<class T0, std::common_with<T0> T1>
inline constexpr auto perm(const T0& n, const T1& r) noexcept(NO_EXCEPT) {
    assert(n >= 0), assert(r >= 0);
    using T = std::common_type_t<T0, T1>;
    if(n < r) return static_cast<T>(0);
    return internal::perm<T>(n, r);
}

template<class T0, std::common_with<T0> T1>
inline constexpr auto comb(const T0& n, const T1& r) noexcept(NO_EXCEPT) {
    assert(n >= 0), assert(r >= 0);
    using T = std::common_type_t<T0, T1>;
    if(n < r) return static_cast<T>(0);
    if(n == r) return static_cast<T>(1);
    return internal::comb<T>(n, r);
}



template<class T, class U, std::invocable<T, T> F = std::multiplies<>>
constexpr T pow(T x, U n, F mul = F(), T one = static_cast<T>(1)) noexcept(NO_EXCEPT) {
    if(n == 0) return one;
    if(n == 1 || x == one) return x;

    T res = one;

    while(true) {
        if(n & 1) res = mul(res, x);
        x = mul(x, x);
        if(n == 0) return res;
        n >>= 1;
    }

    assert(false);
}


using atcoder::pow_mod;
using atcoder::inv_mod;
using atcoder::crt;


template<class T> inline constexpr T sign(const T& x) noexcept(NO_EXCEPT) {
    if(x == 0) return 0;
    return (x > 0) ? 1 : -1;
}

template<class T, T FROM_MIN, T FROM_MAX, T TO_MIN, T TO_MAX> inline constexpr T mapping(const T x) {
    return (x - FROM_MIN) * (TO_MAX - TO_MIN) / (FROM_MAX - FROM_MIN) + TO_MIN;
}
template<class T> inline constexpr T mapping(const T x, const T from_min, const T from_max, const T to_min, const T to_max) {
    return (x - from_min) * (to_max - to_min) / (from_max - from_min) + to_min;
}

template<class... Args>
inline constexpr std::common_type_t<Args...> min(const Args&... args) noexcept(NO_EXCEPT) {
    return std::min({ static_cast<std::common_type_t<Args...>>(args)... });
}

template<class... Args>
inline constexpr std::common_type_t<Args...> max(const Args&... args) noexcept(NO_EXCEPT) {
    return std::max({ static_cast<std::common_type_t<Args...>>(args)... });
}


template<class T>
inline constexpr T gcd(const std::initializer_list<T> args) noexcept(NO_EXCEPT) {
    return gcd(ALL(args));
}

template<class... Args>
inline constexpr std::common_type_t<Args...> gcd(const Args&... args) noexcept(NO_EXCEPT) {
    return gcd({ static_cast<std::common_type_t<Args...>>(args)... });
}


template<class T>
inline constexpr T lcm(const std::initializer_list<T> args) noexcept(NO_EXCEPT) {
    return lcm(ALL(args));
}

template<class... Args>
inline constexpr std::common_type_t<Args...> lcm(const Args&... args) noexcept(NO_EXCEPT) {
    return lcm({ static_cast<std::common_type_t<Args...>>(args)... });
}


template<std::integral T0, std::integral T1>
inline constexpr std::optional<std::common_type_t<T0, T1>> add_overflow(const T0& a, const T1& b) noexcept(NO_EXCEPT) {
    std::common_type_t<T0, T1> res;
    if(__builtin_add_overflow(a, b, &res)) return {};
    return res;
}

template<std::integral T0, std::integral T1>
inline constexpr std::optional<std::common_type_t<T0, T1>> sub_overflow(const T0& a, const T1& b) noexcept(NO_EXCEPT) {
    std::common_type_t<T0, T1> res;
    if(__builtin_sub_overflow(a, b, &res)) return {};
    return res;
}

template<std::integral T0, std::integral T1>
inline constexpr std::optional<std::common_type_t<T0, T1>> mul_overflow(const T0& a, const T1& b) noexcept(NO_EXCEPT) {
    std::common_type_t<T0, T1> res;
    if(__builtin_mul_overflow(a, b, &res)) return {};
    return res;
}

template<std::integral T0, std::integral T1, std::integral Limit>
inline auto add_clamp(const T0 x, const T1 y, const Limit inf, const Limit sup) noexcept(NO_EXCEPT) {
    using Common = std::common_type_t<T0, T1, Limit>;
    const auto res = add_overflow<Common>(x, y);
    if(!res) {
        if(x < 0 && y < 0) return inf;
        if(x > 0 && y > 0) return sup;
        assert(false);
    }
    return std::clamp<Common>(*res, inf, sup);
}

template<std::integral T0, std::integral T1, std::integral Limit>
inline auto sub_clamp(const T0 x, const T1 y, const Limit inf, const Limit sup) noexcept(NO_EXCEPT) {
    using Common = std::common_type_t<T0, T1, Limit>;
    const auto res = sub_overflow<Common>(x, y);
    if(!res) {
        if(x < 0 && y > 0) return inf;
        if(x > 0 && y < 0) return sup;
        assert(false);
    }
    return std::clamp<Common>(*res, inf, sup);
}

template<std::integral T0, std::integral T1, std::integral Limit>
inline auto mul_clamp(const T0 x, const T1 y, const Limit inf, const Limit sup) noexcept(NO_EXCEPT) {
    using Common = std::common_type_t<T0, T1, Limit>;
    const auto res = mul_overflow<Common>(x, y);
    if(!res) {
        if((x > 0) xor (y > 0)) return inf;
        else return sup;
        assert(false);
    }
    return std::clamp<Common>(*res, inf, sup);
}


template<class T>
inline constexpr T sqrt_floor(const T x) noexcept(NO_EXCEPT) {
    return static_cast<T>(std::sqrt(static_cast<long double>(x)));
}

template<class T>
inline constexpr T sqrt_ceil(const T x) noexcept(NO_EXCEPT) {
    T res = sqrt_floor(x);

    if constexpr(std::is_floating_point_v<T>) {
        while(res * res < x) res += 1;
    }
    else {
        while(mul_overflow(res, res).value_or(std::numeric_limits<T>::max()) < x) ++res;
    }

    return res;
}

template<class T, std::integral K>
inline constexpr T kth_root_floor(T x, const K k) noexcept(NO_EXCEPT) {
    assert(x >= 0);
    if(std::signed_integral<K>) assert(k > 0);

    if(x <= 1 or k == 1) return x;

    constexpr auto DIGITS = std::numeric_limits<T>::digits;
    if(k >= DIGITS) return T{1};
    if(k == 2) return sqrt_floor(x);

    constexpr auto MAX = std::numeric_limits<T>::max();
    if(x == MAX) --x;

    auto pow = [&](T t, i64 p) {
        if(p == 0) return T{1};
        T res = 1;
        while(p) {
            if(p & 1) {
                res = mul_overflow(res, t).value_or(MAX);
            }
            t = mul_overflow(t, t).value_or(MAX);
            p >>= 1;
        }
        return res;
    };

    auto res = static_cast<T>(std::pow(x, std::nextafter(1 / static_cast<double>(k), 0)));
    while(pow(res + 1, k) <= x) ++res;

    return res;
}


template<std::integral T>
T inline constexpr extended_gcd(const T& a, const T& b, T& x, T& y) noexcept {
    if(b == 0) {
        x = 1;
        y = 0;
        return a;
    }

    const T d = extended_gcd(b, a%b, y, x);

    y -= a / b * x;
    return d;
};

template<std::integral T>
std::pair<T, spair<T>> inline constexpr extended_gcd(const T& a, const T& b) noexcept {
    T x, y;
    const T d = extended_gcd(a, b, x, y);
    return { d, spair<T>{ x, y } };
};


template<std::integral T>
std::optional<spair<T>> inline constexpr bezout_equation(const T& a, const T& b, const T& c) noexcept {
    if(a == 0) {
        if(b == 0) {
            if(c == 0) return spair<T>{ 0, 0 };
            else { };
        }
        if(c % b == 0) return spair<T>{ 0, c / b };
        return {};
    }

    if(b == 0) {
        const auto ans = bezout_equation(b, a, c);
        if(ans.has_value()) return swapped(ans.value());
        return {};
    }

    T x, y;
    const T gcd = extended_gcd(a, b, x, y);

    if(c % gcd != 0) return {};

    const T p = c / gcd;
    return spair<T>{ x * p, y * p };
};


} // namespace uni
#line 16 "utility/functional.hpp"

#line 18 "utility/functional.hpp"


namespace uni {

namespace internal {


template<class T> constexpr T plus(const T a, const T b) noexcept(NO_EXCEPT) { return std::plus<T>{}(a, b); }
template<class T> constexpr T minus(const T a, const T b) noexcept(NO_EXCEPT) { return std::minus<T>{}(a, b); }

template<class T> constexpr T bit_xor(const T a, const T b) noexcept(NO_EXCEPT) { return a xor b; }


} // namespace internal


template<class T, class U> inline auto to_optional_if_equal(const T& v, const U& ill) noexcept(NO_EXCEPT) -> std::optional<T> {
    return v == ill ? std::optional<T>{} : std::optional<T>(v);
}
template<class T, class U> inline auto to_optional_if_over(const T& v, const U& ill) noexcept(NO_EXCEPT) -> std::optional<T> {
    return v > ill ? std::optional<T>{} : std::optional<T>(v);
}
template<class T, class U> inline auto to_optional_if_or_over(const T& v, const U& ill) noexcept(NO_EXCEPT) -> std::optional<T> {
    return v >= ill ? std::optional<T>{} : std::optional<T>(v);
}
template<class T, class U> inline auto to_optional_if_under(const T& v, const U& ill) noexcept(NO_EXCEPT) -> std::optional<T> {
    return v < ill ? std::optional<T>{} : std::optional<T>(v);
}
template<class T, class U> inline auto to_optional_if_or_under(const T& v, const U& ill) noexcept(NO_EXCEPT) -> std::optional<T> {
    return v <= ill ? std::optional<T>{} : std::optional<T>(v);
}

template<class T, class F> inline auto to_optional_if(const T& v, F&& f) noexcept(NO_EXCEPT) -> decltype(f(v), std::optional<T>{}){
    return f(v) ? std::optional<T>{} : std::optional<T>(v);
}

template<class T, class U> inline bool chmin(T &a, const U& b) noexcept(NO_EXCEPT) { return (a>b ? a=b, true : false); }
template<class T, class U> inline bool chmax(T &a, const U& b) noexcept(NO_EXCEPT) { return (a<b ? a=b, true : false); }

template<class T, class... Ts> inline bool chmin(T &a, Ts... b) noexcept(NO_EXCEPT) { return chmin(a, min(b...)); }
template<class T, class... Ts> inline bool chmax(T &a, Ts... b) noexcept(NO_EXCEPT) { return chmax(a, max(b...)); }

template<class... Ts>
inline constexpr std::common_type_t<Ts...> tuple_sum(const std::tuple<Ts...>& tuple, const std::common_type_t<Ts...>& base = std::common_type_t<Ts...>()) noexcept(NO_EXCEPT) {
    std::common_type_t<Ts...> res = base;
    tuple_for_each(tuple, [&](const auto& v) constexpr { res += v; });
    return res;
}

template<class... Ts>
inline constexpr std::common_type_t<Ts...> min_element(const std::tuple<Ts...>& tuple) noexcept(NO_EXCEPT) {
    return std::apply([&](auto&&... v) constexpr { return min(v...); }, tuple);
}


template<class... Ts>
inline constexpr std::common_type_t<Ts...> max_element(const std::tuple<Ts...>& tuple) noexcept(NO_EXCEPT) {;
    return std::apply([&](auto&&... v) constexpr { return max(v...); }, tuple);
}


template<interval_notation INTERVAL, class T0, class T1, class T2>
inline constexpr bool in_range(const T0& x, const T1& l, const T2& r) noexcept(NO_EXCEPT) {
    if constexpr(INTERVAL == interval_notation::right_open) return l <= x and x < r;
    else if constexpr(INTERVAL == interval_notation::left_open) return l < x and x <= r;
    else if constexpr(INTERVAL == interval_notation::open) return l < x and x < r;
    return l <= x and x <= r;
}

template<class F, class Tuple>
constexpr void tuple_for_each(F&& f, Tuple&& tuple) {
    std::apply(
        [&]<class... Ts>(Ts&&... elems) {
            (std::invoke(f, std::forward<Ts>(elems)), ...);
        },
        std::forward<Tuple>(tuple)
    );
}


template<class F, class Tuple>
constexpr auto tuple_transform(F&& f, Tuple&& tuple) {
    return std::apply(
        [&]<class...Ts>(Ts&&... elems) {
            return internal::tuple_or_pair_t<std::invoke_result_t<F&,Ts>...>(
                std::invoke(f, std::forward<Ts>(elems))...
            );
        },
        std::forward<Tuple>(tuple)
    );
}


} // namespace uni
#line 20 "adaptor/internal/input.hpp"

#line 2 "numeric/modular/modint_interface.hpp"


#line 6 "numeric/modular/modint_interface.hpp"


#line 9 "numeric/modular/modint_interface.hpp"

#line 11 "numeric/modular/modint_interface.hpp"

#line 2 "numeric/modular/builtin_reduction.hpp"


#line 5 "numeric/modular/builtin_reduction.hpp"


#line 8 "numeric/modular/builtin_reduction.hpp"

#line 10 "numeric/modular/builtin_reduction.hpp"

#line 12 "numeric/modular/builtin_reduction.hpp"


namespace uni {

namespace internal {


template<std::unsigned_integral Value, std::unsigned_integral Large>
    requires has_double_digits_of<Large, Value>
struct builtin_reduction {
    using value_type = Value;
    using large_type = Large;

  private:
    value_type _mod;

  public:
    static constexpr int digits = std::numeric_limits<value_type>::digits;
    static constexpr value_type max() noexcept { return std::numeric_limits<value_type>::max(); }

    inline constexpr value_type mod() const noexcept(NO_EXCEPT) { return this->_mod; }

    constexpr builtin_reduction() noexcept = default;

    constexpr builtin_reduction(const value_type mod) noexcept(NO_EXCEPT) : _mod(mod) {
        assert(0 < mod && mod < builtin_reduction::max());
    }


    inline constexpr value_type reduce(const large_type v) const noexcept(NO_EXCEPT) { return v % this->_mod; }


    inline constexpr value_type add(value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        if(x >= this->_mod - y) x -= this->_mod;
        x += y;
        return x;
    }

    inline constexpr value_type subtract(value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        if(x < y) x += this->_mod;
        x -= y;
        return x;
    }


    inline constexpr value_type multiply(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return this->reduce(static_cast<large_type>(x) * static_cast<large_type>(y));
    }

    template<std::integral K>
    inline constexpr value_type pow(const value_type v, const K p) const noexcept(NO_EXCEPT) {
        if constexpr(std::signed_integral<K>) assert(p >= 0);

        if(this->_mod == 0) return 0;
        return uni::pow(v, p, [this](const value_type x, const value_type y) { return this->multiply(x, y); });
    }


    inline constexpr auto compare(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return x <=> y;
    }


    constexpr value_type convert_raw(const value_type v) const noexcept(NO_EXCEPT) { return v; }

    template<std::integral T>
    constexpr value_type convert(T v) const noexcept(NO_EXCEPT) {
        using common_type = std::common_type_t<T, value_type>;
        const common_type mod = static_cast<common_type>(this->_mod);

        if(std::is_constant_evaluated()) {
            v %= mod;

            if constexpr(std::signed_integral<T>) {
                if(v < 0) v += mod;
            }
        }
        else {
            if(v > 0 && static_cast<common_type>(v) >= mod) {
                v %= mod;
            }

            if constexpr(std::signed_integral<T>) {
                if(v < 0) {
                    if(static_cast<common_type>(-v) <= mod) v += mod;
                    else {
                        v %= mod;
                        if(v != 0) v += mod;
                    }
                }
            }
        }

        return static_cast<value_type>(v);
    }

    constexpr value_type revert(const value_type v) const noexcept(NO_EXCEPT) { return this->_mod == 1 ? 0 : v; }
};


} // namespace internal


using builtin_reduction_32bit = internal::builtin_reduction<u32, u64>;
using builtin_reduction_64bit = internal::builtin_reduction<u64, u128>;


} // namespace uni
#line 2 "numeric/modular/binary_reduction.hpp"


#line 7 "numeric/modular/binary_reduction.hpp"


#line 10 "numeric/modular/binary_reduction.hpp"

#line 13 "numeric/modular/binary_reduction.hpp"

#line 2 "numeric/bit.hpp"


#include <immintrin.h>

#line 13 "numeric/bit.hpp"


#line 16 "numeric/bit.hpp"

#line 18 "numeric/bit.hpp"


namespace uni {


template<std::unsigned_integral T>
constexpr T multiply_high(const T x, const T y) noexcept(NO_EXCEPT) {
    constexpr int digits = std::numeric_limits<T>::digits;

    if constexpr(digits <= 16) {
        return static_cast<T>((static_cast<u32>(x) * static_cast<u32>(y)) >> digits);
    }
    else if constexpr(digits <= 32) {
        return static_cast<T>((static_cast<u64>(x) * static_cast<u64>(y)) >> digits);
    }
    else if constexpr(digits <= 64) {
        return static_cast<T>((static_cast<u128>(x) * static_cast<u128>(y)) >> digits);
    }
    else {
        constexpr int h_digits = digits / 2;
        constexpr T mask = (T{ 1 } << h_digits) - 1;

        const T xh = x >> h_digits, yh = y >> h_digits;
        const T xl = x & mask, yl = y & mask;
        const T ph = xh * yh, pl = xl * yl;

        return (((pl >> h_digits) + (xh + xl) * (yh + yl) - (ph + pl)) >> h_digits) + ph;
    }
}


template<std::unsigned_integral T>
inline constexpr int highest_bit_pos(const T v) noexcept(NO_EXCEPT) {
    return (int)std::bit_width(v) - 1; // cast to int for GCC12
}

template<std::unsigned_integral T>
inline constexpr int lowest_bit_pos(const T v) noexcept(NO_EXCEPT) {
    if(v == 0) return -1;
    return std::countr_zero(v);
}


template<std::unsigned_integral T, std::integral I = int>
__attribute__((target("bmi2")))
inline constexpr T clear_higher_bits(const T v, const I p) {
    if constexpr(std::signed_integral<I>) assert(0 <= p);

    constexpr int DIGITS = std::numeric_limits<T>::digits;
    assert(p <= DIGITS);

    if constexpr(DIGITS <= 32) return _bzhi_u32(v, static_cast<u32>(p));
    if constexpr(DIGITS <= 64) return _bzhi_u64(v, static_cast<u64>(p));
    else {
        static_assert(DIGITS <= 128);

        constexpr std::uint64_t MAX64 = std::numeric_limits<std::uint64_t>::max();

        const std::uint64_t high = v >> 64;
        const std::uint64_t low = v & MAX64;

        if(p < 64) return _bzhi_u64(low, p);
        return low | (T{_bzhi_u64(high, p - 64)} << 64);
    }
}


template<std::unsigned_integral T, std::integral I = int> constexpr T shiftl(const T, const I = 1);
template<std::unsigned_integral T, std::integral I = int> constexpr T shiftr(const T, const I = 1);

template<std::unsigned_integral T, std::integral I>
constexpr T shiftl(const T x, const I n) {
    constexpr int DIGITS = std::numeric_limits<T>::digits;
    if constexpr(std::signed_integral<I>) {
        if(n < 0) return shiftr(x, -n);
    }
    if(n >= DIGITS) return 0;
    return x << n;
}

template<std::unsigned_integral T, std::integral I>
constexpr T shiftr(const T x, const I n) {
    constexpr int DIGITS = std::numeric_limits<T>::digits;
    if constexpr(std::signed_integral<I>) {
        if(n < 0) return shiftl(x, -n);
    }
    if(n >= DIGITS) return 0;
    return x >> n;
}


template<std::unsigned_integral T, std::integral I = int>
inline constexpr bool bit(const T x, const I p) {
    if constexpr(std::signed_integral<I>) assert(0 <= p);
    assert(p < std::numeric_limits<T>::digits);

    return shiftr(x, p) & T{1};
}


template<std::unsigned_integral T, std::integral I = int>
inline constexpr auto reset_bit(const T x, const I p) {
    if constexpr(std::signed_integral<I>) assert(0 <= p);
    assert(p < std::numeric_limits<T>::digits);

    return x & ~(T{1} << p);
}


template<std::unsigned_integral T, std::integral I = int>
inline constexpr auto set_bit(const T x, const I p, const bool bit = true) {
    if constexpr(std::signed_integral<I>) assert(0 <= p);
    assert(p < std::numeric_limits<T>::digits);

    if(!bit) return reset_bit(x, p);
    return x | (T{1} << p);
}


template<std::unsigned_integral T, std::integral I = int>
inline constexpr T lower_bits(const T x, const I digits) {
    if constexpr(std::signed_integral<I>) assert(0 <= digits);
    assert(digits <= std::numeric_limits<T>::digits);

    return x & (uni::shiftl(x, digits) - 1);
}


// Thanks to: https://noshi91.github.io/Library/other/select64.cpp
constexpr int select64(const u64 x0, u32 k) {
    const u64 x1 = (x0 & UINT64_C(0x5555555555555555)) + (x0 >> 1 & UINT64_C(0x5555555555555555));
    const u64 x2 = (x1 & UINT64_C(0x3333333333333333)) + (x1 >> 2 & UINT64_C(0x3333333333333333));
    const u64 x3 = (x2 & UINT64_C(0x0F0F0F0F0F0F0F0F)) + (x2 >> 4 & UINT64_C(0x0F0F0F0F0F0F0F0F));
    const u64 x4 = (x3 & UINT64_C(0x00FF00FF00FF00FF)) + (x3 >> 8 & UINT64_C(0x00FF00FF00FF00FF));
    const u64 x5 = (x4 & UINT64_C(0x0000FFFF0000FFFF)) + (x4 >> 16 & UINT64_C(0x0000FFFF0000FFFF));

    int res = 0;

    u32 t;

    t = x5 & 0xFFFFFFFF;
    if(t <= k) k -= t, res += 32;

    t = x4 >> res & 0xFFFF;
    if(t <= k) k -= t, res += 16;

    t = x3 >> res & 0xFF;
    if(t <= k) k -= t, res += 8;

    t = x2 >> res & 0xF;
    if(t <= k) k -= t, res += 4;

    t = x1 >> res & 0x3;
    if(t <= k) k -= t, res += 2;

    t = x0 >> res & 0x1;
    if(t <= k) k -= t, res += 1;

    return res;
}


namespace internal {


template<std::unsigned_integral T>
constexpr T binary_gcd(T a, T b) noexcept(NO_EXCEPT) {
    if(!a || !b) return a | b;
    T t, s = std::countr_zero(a | b);
    a >>= std::countr_zero(a);
    do {
        b >>= std::countr_zero(b);
        if(a > b) t = a, a = b, b = t;
        b -= a;
    } while(b);
    return a << s;
}


template<std::signed_integral T>
inline constexpr T binary_gcd(const T a, const T b) noexcept(NO_EXCEPT) {
    return binary_gcd(a < 0 ? -a : a, b < 0 ? -b : b);
}


} // namespace internal


template<std::integral T0, std::integral T1>
inline constexpr auto binary_gcd(T0 v0, T1 v1) noexcept(NO_EXCEPT) {
    using common_type = std::common_type_t<T0, T1>;
    return internal::binary_gcd(static_cast<common_type>(v0), static_cast<common_type>(v1));
}


template<std::unsigned_integral T, std::unsigned_integral S>
inline constexpr bool is_subset_of(T target, S superset) noexcept(NO_EXCEPT) {
    return (target & ~superset) == 0;
}

template<std::unsigned_integral T, std::unsigned_integral S>
inline constexpr bool is_superset_of(T target, S subset) noexcept(NO_EXCEPT) {
    return (~target & subset) == 0;
}


template<std::unsigned_integral S0, std::unsigned_integral S1>
inline constexpr auto comapre_as_bitset(S0 s0, S1 s1) noexcept(NO_EXCEPT) {
    if(s0 == s1) return std::partial_ordering::equivalent;
    if(is_subset_of(s0, s1)) return std::partial_ordering::less;
    if(is_superset_of(s0, s1)) return std::partial_ordering::greater;
    return std::partial_ordering::unordered;
}


} // namespace uni
#line 16 "numeric/modular/binary_reduction.hpp"


namespace uni {

namespace internal {


template<std::unsigned_integral Value>
struct binary_reduction {
    using value_type = Value;

  private:
    value_type _mask;

  public:
    static constexpr int digits = std::numeric_limits<value_type>::digits;
    static constexpr value_type max() noexcept { return std::numeric_limits<value_type>::max(); }

    inline constexpr value_type mod() const noexcept(NO_EXCEPT) { return this->_mask + 1; }

    constexpr binary_reduction() noexcept = default;

    constexpr explicit inline binary_reduction(const value_type mod) noexcept(NO_EXCEPT) : _mask(mod - 1) {
        assert(std::has_single_bit(mod));
    }

    inline constexpr value_type reduce(const value_type v) const noexcept(NO_EXCEPT) { return v; }


    inline constexpr value_type add(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return x + y;
    }

    inline constexpr value_type subtract(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return x - y;
    }


    inline constexpr value_type multiply(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return x * y;
    }

    template<std::integral K>
    inline constexpr value_type pow(const value_type v, const K p) const noexcept(NO_EXCEPT) {
        if constexpr(std::signed_integral<K>) assert(p >= 0);

        if(this->_mask == 0) return 0;
        return uni::pow(v, p);
    }


    inline constexpr auto compare(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return this->revert(x) <=> this->revert(y);
    }


    constexpr value_type convert_raw(const value_type v) const noexcept(NO_EXCEPT) {
        return v;
    }

    template<std::integral T>
    constexpr value_type convert(T v) const noexcept(NO_EXCEPT) {
        return static_cast<value_type>(v);
    }


    constexpr value_type revert(const value_type v) const noexcept(NO_EXCEPT) {
        return v & this->_mask;
    }
};


} // namespace internal


using binary_reduction_32bit = internal::binary_reduction<u32>;
using binary_reduction_64bit = internal::binary_reduction<u64>;
using binary_reduction_128bit = internal::binary_reduction<u128>;


} // namespace uni
#line 2 "numeric/modular/barrett_reduction.hpp"


#line 8 "numeric/modular/barrett_reduction.hpp"


#line 11 "numeric/modular/barrett_reduction.hpp"

#line 14 "numeric/modular/barrett_reduction.hpp"

#line 2 "template/debug.hpp"


#ifdef LOCAL_JUDGE

#define DEBUGGER_ENABLED
#define DEBUGGER_COLORED_OUTPUT 1

#endif

#line 2 "debugger/debug.hpp"


#line 9 "debugger/debug.hpp"
#include <array>
#line 13 "debugger/debug.hpp"
#include <bitset>
#include <deque>
#include <queue>
#include <stack>
#include <set>
#include <unordered_set>
#include <map>
#include <unordered_map>
#line 22 "debugger/debug.hpp"
#include <iomanip>
#line 26 "debugger/debug.hpp"


#line 2 "numeric/int128.hpp"


#include <cctype>
#line 9 "numeric/int128.hpp"

#line 12 "numeric/int128.hpp"

#line 14 "numeric/int128.hpp"


namespace std {


template<class C, class S>
auto& operator>>(std::basic_istream<C, S>& in, uni::i128& v) noexcept(NO_EXCEPT) {
    std::string str; in >> str;
    v = 0;
    bool negative = (str[0] == '-');
    REP(d, std::ranges::next(str.begin(), negative), str.end()) {
        assert(std::isdigit(*d));
        v = v * 10 + *d - '0';
    }
    if(negative) v *= -1;
    return in;
}


template<class C, class S>
auto& operator>>(std::basic_istream<C, S>& in, uni::u128& v) noexcept(NO_EXCEPT) {
    std::string str; in >> str;
    v = 0U;
    assert(str[0] != '-');
    REP(d, str.begin(), str.end()) {
        assert(std::isdigit(*d));
        v = v * 10U + *d - '0';
    }
    return in;
}

template<class C, class S>
auto& operator<<(std::basic_ostream<C, S>& out, uni::i128 v) noexcept(NO_EXCEPT) {
    if(v == 0) return out << 0;
    if(v < 0) out << '-', v *= -1;
    std::string str;
    while(v > 0) str += static_cast<char>(v%10) + '0', v /= 10;
    std::reverse(str.begin(), str.end());
    return out << str;
}

template<class C, class S>
auto& operator<<(std::basic_ostream<C, S>& out, uni::u128 v) noexcept(NO_EXCEPT) {
    if(v == 0) return out << 0U;
    std::string str;
    while(v > 0) str += static_cast<char>(v%10U) + '0', v /= 10U;
    std::reverse(str.begin(), str.end());
    return out << str;
}


}
#line 29 "debugger/debug.hpp"

#line 34 "debugger/debug.hpp"

#include <typeinfo>
#include <cxxabi.h>


namespace debugger {


template<class T>
auto _debug (T&& val) -> decltype(val._debug()) {
    return val._debug();
}


std::ostream *cdebug = &std::clog;


#ifdef DEBUGGER_COLORED_OUTPUT

constexpr std::string COLOR_LINE = "\033[3;35m";
constexpr std::string COLOR_IDENTIFIER = "\033[32m";
constexpr std::string COLOR_INIT = "\033[m";
constexpr std::string COLOR_STRING = "\033[33m";
constexpr std::string COLOR_TYPE = "\033[34m";
constexpr std::string COLOR_NUMERIC = "\033[36m";
constexpr std::string COLOR_LITERAL_OPERATOR = "\033[31m";

#else

constexpr std::string COLOR_LINE = "";
constexpr std::string COLOR_IDENTIFIER = "";
constexpr std::string COLOR_INIT = "";
constexpr std::string COLOR_STRING = "";
constexpr std::string COLOR_TYPE = "";
constexpr std::string COLOR_NUMERIC = "";
constexpr std::string COLOR_LITERAL_OPERATOR = "";

#endif

using Brackets = std::pair<std::string, std::string>;


template<class T>
std::string dump(T&&);


template<class T>
const std::string get_type_name(T&& val) {
    const char* const name = typeid(std::forward<T>(val)).name();
    int status = -4;
    char* const demangled_name = abi::__cxa_demangle(name, NULL, NULL, &status);
    std::string res{name};
    if (status == 0) {
        res = std::string(demangled_name);
        free(demangled_name);
    }

    return COLOR_TYPE + res + COLOR_INIT;
}

struct debug_t : std::string {
    using std::string::string;
    debug_t(const std::string& str) {
        this->assign(str);
    }
};


template<size_t N, class T>
void dump_tuple_impl([[maybe_unused]] T&& val, std::stringstream &res) {
    if constexpr(N < std::tuple_size_v<std::remove_cvref_t<T>>) {
        res << dump(std::get<N>(val));
        if constexpr(N < std::tuple_size_v<std::remove_cvref_t<T>> - 1) res << ", ";
        dump_tuple_impl<N + 1>(std::forward<T>(val), res);
    }
}


template<std::ranges::input_range R>
std::string dump_range_impl(R&& range, const Brackets& brcs = { "[", "]" }, const std::string& spl = ", ") {
    std::stringstream res;

    res << brcs.first << " ";

    auto itr = std::ranges::begin(range);
    auto end = std::ranges::end(std::forward<R>(range));

    while(itr != end) {
        if(std::ranges::next(itr) == end) res << dump(*itr) << " ";
        else res << dump(*itr) << spl;
        ++itr;
    }

    res << brcs.second ;

    return res.str();
}


std::string dump_debug_t(debug_t info) {
    return info;
}


struct dump_primitive_like {
    std::string operator()(std::nullptr_t) const {
        return COLOR_INIT;
    }

    template<uni::internal::pointer T>
    std::string operator()(const T ptr) const {
        return dump(*ptr);
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::basic_string>
    std::string operator()(T&& val) const {
        std::stringstream res;
        res << COLOR_STRING << "`" << val << "`" << COLOR_INIT;
        return res.str();
    }

    std::string operator()(const char val) const {
        std::stringstream res;
        res << COLOR_STRING << "\'" << val << "\'" << COLOR_INIT;
        return res.str();
    }

    std::string operator()(const char val[]) const {
        std::stringstream res;
        res << COLOR_STRING << "\"" << val << "\"" <<  COLOR_INIT;
        return res.str();
    }

    std::string operator()(const unsigned char val) const {
        std::stringstream res;
        res << COLOR_NUMERIC << static_cast<int>(val) << COLOR_INIT;
        return res.str();
    }


    std::string operator()(const bool val) const {
        std::stringstream res;
        res << COLOR_NUMERIC << (val ? "true" : "false" ) << COLOR_INIT;
        return res.str();
    }


    template<uni::internal::arithmetic T>
    std::string operator()(const T val) const {
        std::stringstream res;
        res << std::setprecision(std::numeric_limits<T>::digits10) << val;

        auto str = res.str();

        std::string dst = "";
        while(str.length() > 3) {
            dst = ',' + str.substr(str.length() - 3, 3) + dst;
            str = str.substr(0, str.length() - 3);
        }

        return COLOR_NUMERIC + str + dst + COLOR_LITERAL_OPERATOR + uni::internal::literal_operator_v<T> + COLOR_INIT;
    };

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::optional>
    std::string operator()(T&& val) const {
        if(val.has_value()) return dump(*val);
        return COLOR_TYPE + "invalid" + COLOR_INIT;
    }
};


struct dump_bitset {
    template<std::size_t N>
    std::string operator()(const std::bitset<N>& val) const {
        std::stringstream res;
        res << COLOR_NUMERIC << val.to_string() << COLOR_INIT;
        return res.str();
    }
};


struct dump_has_val {
    template<class T>
        requires requires (T val) { val.val(); }
    std::string operator()(T&& val) const {
        return dump(val.val());
    }
};


struct dump_iterator {
    template<std::input_or_output_iterator I>
    std::string operator()(I&& itr) const {
        return COLOR_TYPE + "<iterator> " + COLOR_INIT+ dump(*itr);
    }
};


struct dump_wrapper {
    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::map>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("{", "}"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::multimap>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("{", "}"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::unordered_map>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("{", "}"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::unordered_multimap>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("{", "}"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::set>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("{", "}"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::multiset>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("{", "}"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::unordered_set>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("{", "}"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::unordered_multiset>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("{", "}"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::valarray>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("[", "]"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::vector>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("[", "]"));
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::deque>
    std::string operator()(T&& val) const {
        return dump_range_impl(val, Brackets("[", "]"));
    }


    template<uni::internal::derived_from_template<std::queue> T>
    std::string operator()(T val) const {
        std::vector<typename T::value_type> vec;

        while(!val.empty()) vec.emplace_back(val.front()), val.pop();

        return dump_range_impl(vec, Brackets("<", ">"));
    }

    template<uni::internal::derived_from_template<std::stack> T>
    std::string operator()(T val) const {
        std::vector<typename T::value_type> vec;

        while(!val.empty()) vec.emplace_back(val.top()), val.pop();
        std::ranges::reverse(vec);

        return dump_range_impl(vec, Brackets("<", ">"));
    }

    template<uni::internal::derived_from_template<std::priority_queue> T>
    std::string operator()(T val) const {
        std::vector<typename T::value_type> vec;

        while(!val.empty()) vec.emplace_back(val.top()), val.pop();

        return dump_range_impl(vec, Brackets("<", ">"));
    }


    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::pair>
    std::string operator()(T&& val) const {
        std::stringstream res;
        res << "( " << dump(val.first) << ", " << dump(val.second) << " )";
        return res.str();
    }

    template<class T>
        requires uni::internal::derived_from_template<std::remove_cvref_t<T>, std::tuple>
    std::string operator()(T&& val) const {
        std::stringstream res;
        res << "( ";
        dump_tuple_impl<0>(val, res);
        res << " )";
        return res.str();
    }
};


struct dump_range {
    template<std::ranges::input_range T>
    std::string operator()(T&& val) const {
        return dump_range_impl(val);
    }
};


struct dump_loggable {
    template<uni::internal::loggable T>
    std::string operator()(T&& val) const {
        auto res = _debug(val);

        if constexpr(std::same_as<decltype(res), debug_t>) {
            return res;
        }
        else {
            return dump(res);
        }
    }
};


template<class T>
std::string dump(T&& val) {
    if constexpr(std::same_as<std::remove_cvref_t<T>, debug_t>) {
        // return "debug_t";
        return dump_debug_t(std::forward<T>(val));
    }

    if constexpr(std::invocable<dump_primitive_like, T>) {
        // return "primitive";
        return dump_primitive_like{}(std::forward<T>(val));
    }
    if constexpr(std::invocable<dump_loggable, T>) {
        // return "loggable";
        return dump_loggable{}(std::forward<T>(val));
    }
    if constexpr(std::invocable<dump_has_val, T>) {
        // return "has val";
        return dump_has_val{}(std::forward<T>(val));
    }

    if constexpr(std::invocable<dump_bitset, T>) {
        // return "bitset";
        return dump_bitset{}(std::forward<T>(val));
    }
    if constexpr(std::invocable<dump_iterator, T>) {
        // return "iterator";
        return dump_iterator{}(std::forward<T>(val));
    }

    if constexpr(std::invocable<dump_wrapper, T>) {
        // return "wrapper";
        return dump_wrapper{}(std::forward<T>(val));
    }

    if constexpr(std::invocable<dump_range, T>) {;
        // return "range";
        return dump_range{}(std::forward<T>(val));
    }

    return "== dump error ==";
}


template<class T> void debug(T&& val, const std::string& endl) {
    *cdebug << dump(val) << endl << std::flush;
}


constexpr std::string_view WHITESPACES = " \n\r\t\f\v";

std::string ltrim(const std::string &s)
{
    size_t start = s.find_first_not_of(WHITESPACES);
    return (start == std::string::npos) ? "" : s.substr(start);
}

std::string rtrim(const std::string &s)
{
    size_t end = s.find_last_not_of(WHITESPACES);
    return (end == std::string::npos) ? "" : s.substr(0, end + 1);
}

std::string trim(const std::string &s) {
    return rtrim(ltrim(s));
}

std::vector<std::string> split(const std::string& str) {
    static constexpr char SEPARATOR = ',';
    static constexpr char ESCAPE = '\\';
    static constexpr std::string_view QUOTATIONS = "\"\'";
    static constexpr std::string_view PARENTHESES = "()[]{}<>";
    static constexpr auto PARENTHESES_KINDS = std::ranges::size(PARENTHESES);
    static_assert(PARENTHESES_KINDS % 2 == 0);

    std::vector<std::string> res = { "" };

    bool quoted = false;
    std::array<int,(PARENTHESES_KINDS / 2)> enclosed = { 0 };

    for(auto itr = std::ranges::begin(str); itr != std::ranges::end(str); ++itr) {
        if(std::ranges::find(QUOTATIONS, *itr) != std::ranges::end(QUOTATIONS)) {
            if(itr == std::ranges::begin(str) or *std::ranges::prev(itr) != ESCAPE) {
                quoted ^= true;
            }
        }

        if(const auto found = std::ranges::find(PARENTHESES, *itr); found != std::ranges::end(PARENTHESES)) {
            if(not quoted) {
                auto& target = enclosed[std::ranges::distance(std::begin(PARENTHESES), found) / 2];
                target = std::max(0, target - static_cast<int>((std::ranges::distance(std::begin(PARENTHESES), found) % 2) * 2) + 1);

            }
        }

        if(
            not quoted
            and static_cast<std::size_t>(std::ranges::count(enclosed, 0)) == std::ranges::size(enclosed)
            and *itr == SEPARATOR
        ) {
            res.push_back("");
        }
        else {
            res.back() += *itr;
        }
    }

    for(auto&& v : res) v = trim(v);

    return res;
}

template<class Arg> void raw(std::nullptr_t, Arg&& arg) { *cdebug << std::forward<Arg>(arg) << std::flush; }
template<class Arg> void raw(Arg&& arg) { *cdebug << dump(std::forward<Arg>(arg)) << std::flush; }

void debug(const std::vector<std::string>, const size_t, const int, const std::string) { debug(nullptr, COLOR_INIT + "\n"); }


std::map<std::pair<std::string, int>, int> count;

template<class Head, class... Tail>
void debug(
    const std::vector<std::string> args, const size_t idx,
    const int line, const std::string path,
    Head&& H, Tail&&... T
) {
    if(idx == 0) {
        std::string file = path.substr(path.find_last_of("/") + 1);
        debug(nullptr, COLOR_LINE + file + " #" + std::to_string(line) + " (" + std::to_string(count[{ file, line }]++) + ")" + COLOR_INIT);
    }
    debug(nullptr, "\n - ");


    const std::string content = dump(H);
    const std::string type_name = get_type_name(std::forward<Head>(H));


    debug(nullptr, COLOR_IDENTIFIER + args[idx]  + COLOR_INIT + " : ");
    debug(nullptr, content);

    if(type_name.size() + content.size() >= 300) debug(nullptr, "\n   ");

    debug(nullptr, " " + type_name);

    debug(args, idx + 1, 0, path, std::forward<Tail>(T)...);
}


} // namespace debugger
#line 13 "template/debug.hpp"


#ifdef DEBUGGER_ENABLED


#define debug(...) debugger::debug(debugger::split(#__VA_ARGS__), 0, __LINE__, __FILE__, __VA_ARGS__)
#define debug_(...) do { const std::string file = __FILE__; debugger::raw(nullptr, debugger::COLOR_LINE + file.substr(file.find_last_of("/") + 1) + " #" + std::to_string(__LINE__) + debugger::COLOR_INIT + "  "); debugger::raw(__VA_ARGS__); debugger::raw(nullptr, debugger::COLOR_INIT + "\n"); } while(0);
#define DEBUG if constexpr(true)


#else


#define debug(...) ({ ; })
#define debug_(...) ({ ; })
#define DEBUG if constexpr(false)


#endif
#line 18 "numeric/modular/barrett_reduction.hpp"

namespace uni {

namespace internal {


template<std::unsigned_integral Value, std::unsigned_integral Large>
    requires has_double_digits_of<Large, Value>
struct barrett_reduction {
    using value_type = Value;
    using large_type = Large;

  private:
    large_type _mod = 0, _mi;

    inline constexpr std::pair<large_type,value_type> _reduce(const large_type v) const noexcept(NO_EXCEPT) {
        large_type x = multiply_high(v, this->_mi);
        return { x, static_cast<value_type>(v - x * this->_mod) };
    }

  public:
    static constexpr int digits = std::numeric_limits<value_type>::digits - 1;
    static constexpr value_type max() noexcept { return (value_type{ 1 } << barrett_reduction::digits) - 1; }

    inline constexpr value_type mod() const noexcept(NO_EXCEPT) { return this->_mod; }

    constexpr barrett_reduction() noexcept = default;

    constexpr explicit inline barrett_reduction(const value_type mod)
      : _mod(mod), _mi(std::numeric_limits<large_type>::max() / mod + 1)
    {
        assert(0 < mod && mod <= barrett_reduction::max());
    }


    inline constexpr large_type quotient(const large_type v) const noexcept(NO_EXCEPT) {
        const auto [ x, r ] = this->_reduce(v);
        return static_cast<large_type>(this->_mod <= r ? x - 1 : x);
    }

    inline constexpr value_type reduce(const large_type v) const noexcept(NO_EXCEPT) {
        const auto [ x, r ] = this->_reduce(v);
        return static_cast<value_type>(this->_mod <= r ? r + this->_mod : r);
    }

    inline constexpr std::pair<large_type,value_type> divide(const large_type v) const noexcept(NO_EXCEPT) {
        const auto [ x, r ] = this->_reduce(v);
        if(this->_mod <= r) return { static_cast<large_type>(x - 1), static_cast<value_type>(r + this->_mod) };
        return { static_cast<large_type>(x), static_cast<value_type>(r) };
    }


    inline constexpr value_type add(value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        x += y;
        if(x >= this->_mod) x -= this->_mod;
        return x;
    }

    inline constexpr value_type subtract(value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        if(x < y) x += this->_mod;
        x -= y;
        return x;
    }


    inline constexpr value_type multiply(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return this->reduce(static_cast<large_type>(x) * static_cast<large_type>(y));
    }

    template<std::integral K>
    inline constexpr value_type pow(const large_type v, const K p) const noexcept(NO_EXCEPT) {
        if constexpr(std::signed_integral<K>) assert(p >= 0);

        if(this->_mod == 1) return 0;
        return uni::pow(
            this->reduce(v), p,
            [&](const value_type x, const value_type y) noexcept(NO_EXCEPT) { return this->multiply(x, y); }
        );
    }


    inline constexpr auto compare(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return x <=> y;
    }


    constexpr value_type convert_raw(const value_type v) const noexcept(NO_EXCEPT) { return v; }

    template<std::integral T>
    constexpr value_type convert(T v) const noexcept(NO_EXCEPT) {
        using common_type = std::common_type_t<T, value_type>;
        const common_type mod = static_cast<common_type>(this->_mod);

        if(v > 0 && static_cast<common_type>(v) >= mod) {
            if(static_cast<common_type>(v) <= barrett_reduction::max()) v = this->reduce(v);
            else v %= mod;
        }

        if constexpr(std::signed_integral<T>) {
            if(v < 0) {
                if(static_cast<common_type>(-v) <= mod) v += mod;
                else if(static_cast<common_type>(-v) <= barrett_reduction::max()) {
                    v = mod - this->reduce(static_cast<value_type>(-v - 1)) - 1;
                }
                else {
                    v %= mod;
                    if(v != 0) v += mod;
                }
            }
        }

        return static_cast<value_type>(v);
    }

    constexpr value_type revert(const value_type v) const noexcept(NO_EXCEPT) { return this->reduce(v); }
};


} // namespace internal


using barrett_reduction_32bit = internal::barrett_reduction<u32, u64>;
using barrett_reduction_64bit = internal::barrett_reduction<u64, u128>;


} // namespace uni
#line 2 "numeric/modular/montgomery_reduction.hpp"


#line 7 "numeric/modular/montgomery_reduction.hpp"


#line 10 "numeric/modular/montgomery_reduction.hpp"

#line 16 "numeric/modular/montgomery_reduction.hpp"


namespace uni {

namespace internal {


template<std::unsigned_integral Value, std::unsigned_integral Large>
    requires has_double_digits_of<Large, Value>
struct montgomery_reduction {
    using value_type = Value;
    using large_type = Large;

  private:
    value_type _mod = 0, _r2, _mp;

    constexpr value_type _inv() const noexcept(NO_EXCEPT) {
        value_type res = this->_mod;
        while(this->_mod * res != 1) res *= value_type{ 2 } - this->_mod * res;
        return res;
    }

  public:

    static constexpr int digits = std::numeric_limits<value_type>::digits - 2;
    static constexpr value_type max() noexcept { return (value_type{ 1 } << montgomery_reduction::digits) - 1; }

    inline constexpr value_type mod() const noexcept(NO_EXCEPT) { return this->_mod; }


    value_type zero = 0;
    value_type one;


    constexpr montgomery_reduction() noexcept = default;

    constexpr montgomery_reduction(const value_type mod) noexcept(NO_EXCEPT)
      : _mod(mod), _r2(static_cast<value_type>(-static_cast<large_type>(mod) % mod)),
        _mp(-this->_inv()), one(this->reduce(this->_r2))
    {
        assert((mod & 1) == 1);
        assert(mod <= montgomery_reduction::max());
    }


    constexpr value_type reduce(const large_type v) const noexcept(NO_EXCEPT) {
        return
            static_cast<value_type>(
                (
                    v + static_cast<large_type>(static_cast<value_type>(v) * this->_mp) * this->_mod
                ) >> std::numeric_limits<value_type>::digits
            );
    }


    inline constexpr value_type add(value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        x += y;
        if(x >= (this->_mod << 1)) x -= (this->_mod << 1);
        return x;
    }

    inline constexpr value_type subtract(value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        if(x < y) x += (this->_mod << 1);
        x -= y;
        return x;
    }


    inline constexpr value_type multiply(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return this->reduce(static_cast<large_type>(x) * static_cast<large_type>(y));
    }

    template<std::integral K>
    inline constexpr value_type pow(const large_type v, const K p) const noexcept(NO_EXCEPT) {
        if constexpr(std::signed_integral<K>) assert(p >= 0);

        if(this->_mod == 1) return 0;
        return uni::pow(
            v, p,
            [&](const value_type x, const value_type y) noexcept(NO_EXCEPT) { return this->multiply(x, y); },
            static_cast<large_type>(this->one)
        );
    }


    inline constexpr value_type normalize(const value_type v) const noexcept(NO_EXCEPT) {
        assert(0 <= v && v < (this->_mod << 1));
        if(v < this->_mod) return v;
        return v - this->_mod;
    }

    inline constexpr auto compare(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return this->normalize(x) <=> this->normalize(y);
    }


    inline constexpr value_type convert_raw(const value_type v) const noexcept(NO_EXCEPT) {
        if(v == 1) return this->one;
        return this->multiply(v, this->_r2);
    }

    template<std::integral T>
    constexpr value_type convert(T v) const noexcept(NO_EXCEPT) {
        if(v == 1) return this->one;

        using common_type = std::common_type_t<T, value_type>;
        const common_type mod2 = static_cast<common_type>(this->_mod << 1);

        if(v > 0 && static_cast<common_type>(v) >= mod2) {
            v %= mod2;
        }

        if constexpr(std::is_signed_v<T>) {
            if(v < 0 && static_cast<common_type>(-v) >= mod2) {
                v %= mod2;
                if(v != 0) v += mod2;
            }
        }

        return this->multiply(v, this->_r2);
    }


    constexpr value_type revert(const value_type v) const noexcept(NO_EXCEPT) {
        return this->normalize(this->reduce(v));
    }
};

// Thanks to: https://www.mathenachia.blog/even-mod-montgomery-impl/
template<std::unsigned_integral Value, std::unsigned_integral Large>
    requires has_double_digits_of<Large, Value>
struct arbitrary_montgomery_reduction {
    using value_type = Value;
    using large_type = Large;

  private:
    using context = arbitrary_montgomery_reduction;
    static constexpr int width = std::numeric_limits<value_type>::digits;

    value_type _mod = 0;
    int _tz;
    value_type _m0;
    large_type _m0i, _mask;
    value_type _r2;

    constexpr large_type _inv() const noexcept(NO_EXCEPT) {
        large_type res = this->_m0;
        while(((this->_m0 * res) & this->_mask) != 1) res *= large_type{ 2 } - this->_m0 * res;
        return res & this->_mask;
    }

    constexpr value_type _m0ip() const noexcept(NO_EXCEPT) {
        if(this->_tz == 0) return 0;
        value_type res = this->_m0;
        const value_type mask = (value_type{ 1 } << this->_tz) - 1;
        while(((this->_m0 * res) & mask) != 1) res *= value_type{ 2 } - this->_m0 * res;
        return res & mask;
    }

  public:
    static constexpr int digits = std::numeric_limits<value_type>::digits - 2;
    static constexpr value_type max() noexcept { return (value_type{ 1 } << context::digits) - 1; }

    inline constexpr value_type mod() const noexcept(NO_EXCEPT) { return this->_mod; }

    value_type one;


    constexpr arbitrary_montgomery_reduction() noexcept = default;

    constexpr arbitrary_montgomery_reduction(value_type m) noexcept(NO_EXCEPT) {
        assert(0 < m);

        if(this->_mod == m) return;

        this->_mod = m;
        this->_tz = std::countr_zero(m);
        this->_m0 = m >> this->_tz;

        assert(this->_mod < context::max());

        this->_mask = (large_type{ 1 } << (context::width + this->_tz)) - 1;
        this->_m0i = this->_inv();

        {
            const value_type x = (std::numeric_limits<large_type>::max() % this->_m0) + 1;
            const value_type mask = (value_type{ 1 } << this->_tz) - 1;
            this->_r2 = (x + ((((large_type{ 1 } - x) * this->_m0ip()) & mask) * this->_m0));
        }

        this->one = this->reduce(this->_r2);
    }


    constexpr value_type reduce(const large_type v) const noexcept(NO_EXCEPT) {
        const value_type res =
            static_cast<value_type>(
                (
                    v +
                    this->_m0 *
                    ((((v << std::numeric_limits<value_type>::digits) - v) * this->_m0i) & this->_mask)
                ) >> std::numeric_limits<value_type>::digits
            );
        return res;
    }


    inline constexpr value_type add(value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        x += y;
        if(x >= (this->_mod << 1)) x -= (this->_mod << 1);
        return x;
    }

    inline constexpr value_type subtract(value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        if(x < y) x += (this->_mod << 1);
        x -= y;
        return x;
    }



    inline constexpr value_type multiply(const value_type x, const value_type y) const noexcept(NO_EXCEPT) {
        return this->reduce(static_cast<large_type>(x) * static_cast<large_type>(y));
    }

    template<std::integral K>
    inline constexpr value_type pow(const large_type v, K p) const noexcept(NO_EXCEPT) {
        if constexpr(std::signed_integral<K>) assert(p >= 0);

        if(this->_mod == 1) return 0;
        return uni::pow(
            v, p,
            [&](const value_type x, const value_type y) noexcept(NO_EXCEPT) { return this->multiply(x, y); },
            static_cast<large_type>(this->one)
        );
    }

    inline constexpr value_type normalize(const value_type v) const noexcept(NO_EXCEPT) {
        assert(0 <= v && v < (this->_mod << 1));
        if(v < this->_mod) return v;
        return v - this->_mod;
    }

    inline constexpr auto compare(const large_type x, const large_type y) const noexcept(NO_EXCEPT) {
        return this->normalize(x) <=> this->normalize(y);
    }


    inline constexpr value_type convert_raw(const value_type v) const noexcept(NO_EXCEPT) {
        if(v == 1) return this->one;
        return this->multiply(v, this->_r2);
    }

    template<std::integral T>
    constexpr value_type convert(T v) const noexcept(NO_EXCEPT) {
        if(v == 1) return this->one;

        using common_type = std::common_type_t<T, value_type>;
        const common_type mod2 = static_cast<common_type>(this->_mod << 1);

        if(v > 0 && static_cast<common_type>(v) >= mod2) {
            v %= mod2;
        }

        if constexpr(std::signed_integral<T>) {
            if(v < 0) {
                if(static_cast<common_type>(-v) >= mod2) v %= mod2;
                if(v < 0) v += mod2;
            }
        }

        return this->multiply(v, this->_r2);
    }


    constexpr value_type revert(const value_type v) const noexcept(NO_EXCEPT) {
        return this->normalize(this->reduce(v));
    }
};


} // namespace internal


using montgomery_reduction_32bit = internal::montgomery_reduction<u32, u64>;
using montgomery_reduction_64bit = internal::montgomery_reduction<u64, u128>;

using arbitrary_montgomery_reduction_32bit = internal::arbitrary_montgomery_reduction<u32, u64>;
using arbitrary_montgomery_reduction_64bit = internal::arbitrary_montgomery_reduction<u64, u128>;

} // namespace uni
#line 16 "numeric/modular/modint_interface.hpp"


namespace uni {

namespace internal {


template<class T>
concept modint_family =
    numeric<T> &&
    has_static_one<T> && has_static_zero<T> &&
    requires (T v, i64 p, typename T::value_type x) {
        { v.pow(p) } -> std::same_as<T>;
        { v.inv() } -> std::same_as<T>;
        { T::raw(x) } -> std::same_as<T>;

        { v.val() } -> std::same_as<typename T::value_type>;
        { T::mod() } -> std::same_as<typename T::value_type>;
        { T::max() } -> std::same_as<typename T::value_type>;
        T::digits;

        T::context::dynamic;
    };


template<class T>
concept dynamic_modint_family =
    modint_family<T> &&
    T::context::dynamic &&
    requires (typename T::value_type v) {
        T::set_mod(v);
    };


template<class T>
concept static_modint_family =
    modint_family<T> &&
    (!T::context::dynamic); //&&
    // requires {
    //     T::is_prime;
    // };


template<class T>
concept modular_reduction =
    std::default_initializable<T> &&
    std::constructible_from<T, typename T::value_type> &&
    requires (T v, typename T::value_type x, i64 p) {
        typename T::value_type;

        T::digits;
        { T::max() } -> std::same_as<typename T::value_type>;
        { v.mod() } -> std::same_as<typename T::value_type>;

        { v.reduce(x) } -> std::same_as<typename T::value_type>;

        { v.add(x, x) } -> std::same_as<typename T::value_type>;
        { v.subtract(x, x) } -> std::same_as<typename T::value_type>;
        { v.multiply(x, x) } -> std::same_as<typename T::value_type>;
        { v.multiply(x, x) } -> std::same_as<typename T::value_type>;
        { v.pow(x, p) } -> std::same_as<typename T::value_type>;

        { v.convert_raw(x) } -> std::same_as<typename T::value_type>;
        { v.convert(x) } -> std::same_as<typename T::value_type>;
        { v.revert(x) } -> std::same_as<typename T::value_type>;

        v.compare(x, x);
    };


template<class T>
concept modular_context =
    requires {
        typename T::reductor;
        typename T::value_type;
        T::reduction;
    };


} // namespace internal


template<internal::modular_reduction Reduction, typename Reduction::value_type Mod>
struct static_modular_context {
    using reductor = Reduction;
    using value_type = typename reductor::value_type;

    static constexpr bool dynamic = false;

    static constexpr reductor reduction = reductor(Mod);

  private:
    using context = static_modular_context;
};


template<internal::modular_reduction Reduction, i64 Id>
struct dynamic_modular_context {
    using reductor = Reduction;
    using value_type = typename reductor::value_type;

    static constexpr bool dynamic = true;

    static inline reductor reduction;

  private:
    using context = dynamic_modular_context;

  public:
    static constexpr void set_mod(const value_type mod) noexcept(NO_EXCEPT) { context::reduction = reductor(mod); }
};


template<internal::modular_context> struct modint;


template<u32 Mod> using static_builtin_modular_context_32bit = static_modular_context<builtin_reduction_32bit, Mod>;
template<u64 Mod> using static_builtin_modular_context_64bit = static_modular_context<builtin_reduction_64bit, Mod>;

template<u32 Mod> using static_barrett_modular_context_32bit = static_modular_context<barrett_reduction_32bit, Mod>;
template<u64 Mod> using static_barrett_modular_context_64bit = static_modular_context<barrett_reduction_64bit, Mod>;

template<u32 Mod> using static_montgomery_modular_context_32bit = static_modular_context<montgomery_reduction_32bit, Mod>;
template<u64 Mod> using static_montgomery_modular_context_64bit = static_modular_context<montgomery_reduction_64bit, Mod>;

template<u32 Mod> using static_arbitrary_montgomery_modular_context_32bit = static_modular_context<arbitrary_montgomery_reduction_32bit, Mod>;
template<u64 Mod> using static_arbitrary_montgomery_modular_context_64bit = static_modular_context<arbitrary_montgomery_reduction_64bit, Mod>;

template<u32 Mod> using static_binary_modular_context_32bit = static_modular_context<binary_reduction_32bit, Mod>;
template<u64 Mod> using static_binary_modular_context_64bit = static_modular_context<binary_reduction_64bit, Mod>;
template<u128 Mod> using static_binary_modular_context_128bit = static_modular_context<binary_reduction_128bit, Mod>;


template<u32 Mod> using static_builtin_modint_32bit = modint<static_builtin_modular_context_32bit<Mod>>;
template<u64 Mod> using static_builtin_modint_64bit = modint<static_builtin_modular_context_64bit<Mod>>;

template<u32 Mod> using static_barrett_modint_32bit = modint<static_barrett_modular_context_32bit<Mod>>;
template<u64 Mod> using static_barrett_modint_64bit = modint<static_barrett_modular_context_64bit<Mod>>;

template<u32 Mod> using static_montgomery_modint_32bit = modint<static_montgomery_modular_context_32bit<Mod>>;
template<u64 Mod> using static_montgomery_modint_64bit = modint<static_montgomery_modular_context_64bit<Mod>>;

template<u32 Mod> using static_arbitrary_montgomery_modint_32bit = modint<static_arbitrary_montgomery_modular_context_32bit<Mod>>;
template<u64 Mod> using static_arbitrary_montgomery_modint_64bit = modint<static_arbitrary_montgomery_modular_context_64bit<Mod>>;

template<u32 Mod> using static_binary_modint_32bit = modint<static_binary_modular_context_32bit<Mod>>;
template<u64 Mod> using static_binary_modint_64bit = modint<static_binary_modular_context_64bit<Mod>>;
template<u128 Mod> using static_binary_modint_128bit = modint<static_binary_modular_context_128bit<Mod>>;


template<i64 Id> using dynamic_builtin_modular_context_32bit = dynamic_modular_context<builtin_reduction_32bit, Id>;
template<i64 Id> using dynamic_builtin_modular_context_64bit = dynamic_modular_context<builtin_reduction_64bit, Id>;

template<i64 Id> using dynamic_barrett_modular_context_32bit = dynamic_modular_context<barrett_reduction_32bit, Id>;
template<i64 Id> using dynamic_barrett_modular_context_64bit = dynamic_modular_context<barrett_reduction_64bit, Id>;

template<i64 Id> using dynamic_montgomery_modular_context_32bit = dynamic_modular_context<montgomery_reduction_32bit, Id>;
template<i64 Id> using dynamic_montgomery_modular_context_64bit = dynamic_modular_context<montgomery_reduction_64bit, Id>;

template<i64 Id> using dynamic_arbitrary_montgomery_modular_context_32bit = dynamic_modular_context<arbitrary_montgomery_reduction_32bit, Id>;
template<i64 Id> using dynamic_arbitrary_montgomery_modular_context_64bit = dynamic_modular_context<arbitrary_montgomery_reduction_64bit, Id>;

template<i64 Id> using dynamic_binary_modular_context_32bit = dynamic_modular_context<binary_reduction_32bit, Id>;
template<i64 Id> using dynamic_binary_modular_context_64bit = dynamic_modular_context<binary_reduction_64bit, Id>;
template<i64 Id> using dynamic_binary_modular_context_128bit = dynamic_modular_context<binary_reduction_128bit, Id>;


template<i64 Id> using dynamic_builtin_modint_32bit = modint<dynamic_builtin_modular_context_32bit<Id>>;
template<i64 Id> using dynamic_builtin_modint_64bit = modint<dynamic_builtin_modular_context_64bit<Id>>;

template<i64 Id> using dynamic_barrett_modint_32bit = modint<dynamic_barrett_modular_context_32bit<Id>>;
template<i64 Id> using dynamic_barrett_modint_64bit = modint<dynamic_barrett_modular_context_64bit<Id>>;

template<i64 Id> using dynamic_montgomery_modint_32bit = modint<dynamic_montgomery_modular_context_32bit<Id>>;
template<i64 Id> using dynamic_montgomery_modint_64bit = modint<dynamic_montgomery_modular_context_64bit<Id>>;

template<i64 Id> using dynamic_arbitrary_montgomery_modint_32bit = modint<dynamic_arbitrary_montgomery_modular_context_32bit<Id>>;
template<i64 Id> using dynamic_arbitrary_montgomery_modint_64bit = modint<dynamic_arbitrary_montgomery_modular_context_64bit<Id>>;

template<i64 Id> using dynamic_binary_modint_32bit = modint<dynamic_binary_modular_context_32bit<Id>>;
template<i64 Id> using dynamic_binary_modint_64bit = modint<dynamic_binary_modular_context_64bit<Id>>;
template<i64 Id> using dynamic_binary_modint_128bit = modint<dynamic_binary_modular_context_128bit<Id>>;


template<u32 Mod> using static_modint_32bit = static_builtin_modint_32bit<Mod>;
template<u64 Mod> using static_modint_64bit = static_builtin_modint_64bit<Mod>;


using modint998244353 = static_modint_32bit<998244353>;
using modint1000000007 = static_modint_32bit<1000000007>;

using modint_32 = dynamic_barrett_modint_32bit<-1>;
using modint_64 = dynamic_barrett_modint_64bit<-1>;


template<const unsigned Val, const unsigned Mod = 998244353>
const uni::static_modint_32bit<Mod> MINT = Val;

template<const unsigned Val, const unsigned Mod = 998244353>
const unsigned INV = uni::static_modint_32bit<Mod>{ Val }.inv().val();

template<const unsigned Val, const unsigned Mod = 998244353>
const int SINV = uni::static_modint_32bit<Mod>{ Val }.inv().val();


} // namespace uni
#line 22 "adaptor/internal/input.hpp"

#line 24 "adaptor/internal/input.hpp"


namespace uni {


template<std::derived_from<std::ios_base> Source = std::istream>
struct input_adaptor {
    using source_type = Source;

  private:
    template<class T>
        requires std::derived_from<T, std::valarray<typename T::value_type>>
    auto _set(uni::internal::resolving_rank<6>, T& val) noexcept(NO_EXCEPT) -> int {
        this->operator()(ALL(val));
        return 0;
    }

    template<class T>
        requires
            requires (source_type& in, T& val) {
                in >> val;
            }
    int _set(uni::internal::resolving_rank<5>, T& val) noexcept(NO_EXCEPT) {
        *this->in >> val;
        return 0;
    }

    template<std::ranges::range T>
    int _set(uni::internal::resolving_rank<4>, T& val) noexcept(NO_EXCEPT) {
        this->operator()(std::ranges::begin(val), std::ranges::end(val));
        return 0;
    }

    template<class T>
        requires
            requires (T& val) {
                val.first;
                val.second;
            }
    int _set(uni::internal::resolving_rank<3>, T& val) noexcept(NO_EXCEPT) {
        *this >> val.first >> val.second;
        return 0;
    }

    template<class T>
        requires
            requires (T& val) {
                std::get<0>(val);
            }
    int _set(uni::internal::resolving_rank<2>, T& val) noexcept(NO_EXCEPT) {
        tuple_for_each([this](auto&& v) { *this >> v; }, val);
        return 0;
    }

    template<uni::internal::modint_family T>
    int _set(uni::internal::resolving_rank<1>, T& val) noexcept(NO_EXCEPT) {
        std::int64_t v; std::cin >> v;
        val = { v };
        return 0;
    }

    template<class T>
        requires
            requires {
                typename T::value_type;
            }
    int _set(uni::internal::resolving_rank<0>, T& val) noexcept(NO_EXCEPT) {
        typename T::value_type v; *this >> v;
        val = { v };
        return 0;
    }

  protected:
    template<class T>
    source_type *set(T& val) noexcept(NO_EXCEPT) {
        this->_set(uni::internal::resolving_rank<10>{}, val);
        return this->in;
    }

    template<class T>
    source_type *set(T&& _val) noexcept(NO_EXCEPT) {
        T val = _val;
        this->_set(uni::internal::resolving_rank<10>{}, val);
        return this->in;
    }

  public:
    using char_type = typename source_type::char_type;

    source_type *in;

    input_adaptor(source_type *_in = &std::cin) noexcept(NO_EXCEPT) : in(_in) {}

    template<class T>
    inline input_adaptor& operator>>(T&& s) noexcept(NO_EXCEPT) {
        this->set(std::forward<T>(s));
        return *this;
    }

    template<class T>
    inline T one() noexcept(NO_EXCEPT) {
        T val; *this >> val;
        return val;
    }

    template<class T>
    inline auto& operator()(T& val) noexcept(NO_EXCEPT) {
        *this >> val;
        return *this;
    }

    template<class T, class... Args>
    inline auto& operator()(T& head, Args&... tail) noexcept(NO_EXCEPT) {
        *this >> head;
        this->operator()(tail...);
        return *this;
    }

    template<std::input_or_output_iterator I, std::sentinel_for<I> S>
    inline auto& operator()(I first, S last) noexcept(NO_EXCEPT) {
        for(I itr=first; itr!=last; ++itr) *this >> *itr;
        return *this;
    }

    explicit operator bool() const noexcept(NO_EXCEPT) { return (bool)*this->in; }
};


} // namespace uni
#line 2 "adaptor/internal/output.hpp"


#line 11 "adaptor/internal/output.hpp"


#line 15 "adaptor/internal/output.hpp"


namespace uni {


template<class Destination = std::ostream>
struct output_adaptor {
    using destination_type = Destination;

  private:
    template<class T>
        requires
            requires (destination_type& out, T val) {
                out << val;
            }
    int _put(uni::internal::resolving_rank<5>, T&& val) noexcept(NO_EXCEPT) {
        *this->out << std::forward<T>(val);
        return 0;
    }

    template<class T>
        requires
            requires (T&& val) {
                val.val();
            }
    int _put(uni::internal::resolving_rank<4>, T&& val) noexcept(NO_EXCEPT) {
        this->put(val.val());
        return 0;
    }

    template<std::ranges::input_range T>
    int _put(uni::internal::resolving_rank<3>, T&& val) noexcept(NO_EXCEPT) {
        (*this)(std::ranges::begin(val), std::ranges::end(val), false);
        return 0;
    }

    template<class T>
        requires
            requires (T&& val) {
                val.first;
                val.second;
            }
    int _put(uni::internal::resolving_rank<2>, T&& val) noexcept(NO_EXCEPT) {
        *this << val.first, this->put_separator();
        *this << val.second;
        return 0;
    }

    template<class T>
        requires
            requires (T&& val) {
                std::get<0>(val);
            }
    auto _put(uni::internal::resolving_rank<1>, T&& val) noexcept(NO_EXCEPT) {
        std::apply([this](const auto&... args) constexpr { ((*this << args, this->put_separator()), ...); }, std::forward<T>(val));
        return 0;
    }

    template<std::input_or_output_iterator T>
    int _put(uni::internal::resolving_rank<0>, T&& val) noexcept(NO_EXCEPT) {
        (*this)(*std::forward<T>(val));
        return 0;
    }


  protected:
    template<class T>
    destination_type* put(T&& val) noexcept(NO_EXCEPT){
        this->_put(uni::internal::resolving_rank<10>{}, std::forward<T>(val));
        return this->out;
    }

  public:
    using char_type = typename destination_type::char_type;

    static constexpr auto sendl = std::endl<char_type,std::char_traits<char_type>>;
    static constexpr auto sflush = std::flush<char_type,std::char_traits<char_type>>;

  protected:
    using sfunc_type = std::remove_const_t<decltype(output_adaptor::sendl)>;

  public:
    using separator_type = std::variant<std::string,sfunc_type>;

    destination_type *out;
    separator_type endline;
    separator_type separator;

  protected:
    void put_separator() noexcept(NO_EXCEPT) {
        if(this->separator.index() == 0) *this->out << std::get<std::string>(this->separator);
        if(this->separator.index() == 1) *this->out << std::get<sfunc_type>(this->separator);
    }
    void put_endline() noexcept(NO_EXCEPT) {
        if(this->endline.index() == 0) *this->out << std::get<std::string>(this->endline);
        if(this->endline.index() == 1) *this->out << std::get<sfunc_type>(this->endline);
    }

  public:
    template<class Terminator = std::string, class Separator = std::string>
    output_adaptor(destination_type *des = &std::cout, Terminator endl = "\n", Separator sep = " ") noexcept(NO_EXCEPT)
      : out(des), endline(endl), separator(sep)
    {
        *this << std::fixed << std::setprecision(20);
    }

    inline auto& seekp(const typename destination_type::off_type off, const std::ios_base::seekdir dir = std::ios_base::cur) noexcept(NO_EXCEPT) {
        this->out->seekp(off, dir); return *this;
    };

    template<class T> inline output_adaptor& operator<<(T&& s) noexcept(NO_EXCEPT){
        this->put(std::forward<T>(s));
        return *this;
    }

    template<class T = std::string>
    inline auto& operator()(T&& val = "") noexcept(NO_EXCEPT){
        *this << std::forward<T>(val), this->put_endline();
        return *this;
    }

    template<class T, class ...Args>
    inline auto& operator()(T&& head, Args&& ...tail) noexcept(NO_EXCEPT){
        *this << std::forward<T>(head), this->put_separator();
        (*this)(std::forward<Args>(tail)...);
        return *this;
    }

    template<std::forward_iterator I, std::sentinel_for<I> S>
    inline auto& operator()(I first, S last, const bool terminate = true) noexcept(NO_EXCEPT) {
        for(I itr=first; itr!=last;) {
            *this << *itr;
            if(++itr == last) {
                if(terminate) this->put_endline();
            }
            else this->put_separator();
        }

        return *this;
    }

    template<class T>
    inline auto& operator()(const std::initializer_list<T> vals) noexcept(NO_EXCEPT) {
        std::vector wrapped(vals.begin(), vals.end());
        (*this)(wrapped.begin(), wrapped.end());
        return *this;
    }

    template<class T0, class T1>
    inline auto& conditional(const bool cond, const T0& a, const T1& b) noexcept(NO_EXCEPT) {
        if(cond) (*this)(a);
        else (*this)(b);
        return *this;
    }

    inline auto& yesno(const bool cond) noexcept(NO_EXCEPT) {
        if(cond) this->yes();
        else this->no();
        return *this;
    }

    inline auto yes() noexcept(NO_EXCEPT) {
        *this->out << "Yes";
        this->put_endline();
        return *this;
    }

    inline auto no() noexcept(NO_EXCEPT) {
        *this->out << "No";
        this->put_endline();
        return *this;
    }


    inline auto flush() noexcept(NO_EXCEPT) {
        *this->out << std::flush;
        return *this;
    }
};


} // namespace uni
#line 7 "adaptor/io.hpp"


namespace uni {


uni::input_adaptor _input;
uni::output_adaptor _print;


}


#define input uni::_input
#define print uni::_print
#line 2 "data_structure/dynamic_sequence.hpp"


#line 8 "data_structure/dynamic_sequence.hpp"
#include <random>
#line 12 "data_structure/dynamic_sequence.hpp"

#line 15 "data_structure/dynamic_sequence.hpp"

#line 2 "internal/uncopyable.hpp"


namespace uni {

namespace internal {


struct uncopyable {
    uncopyable() noexcept {}
    uncopyable(const uncopyable&) = delete;
    uncopyable& operator=(const uncopyable&) = delete;
};


} // namespace internal

} // namespace uni
#line 22 "data_structure/dynamic_sequence.hpp"

#line 2 "internal/point_reference.hpp"


#line 6 "internal/point_reference.hpp"


#line 9 "internal/point_reference.hpp"

#line 11 "internal/point_reference.hpp"


namespace uni {

namespace internal {


template<class Super, std::integral SizeType = typename Super::size_type>
struct point_reference {
    using size_type = SizeType;
    using iterator = typename Super::iterator;

  protected:
    Super *const _super;
    const size_type _pos;

    point_reference(Super *const super, const size_type pos) noexcept(NO_EXCEPT) : _super(super), _pos(pos) {}

    inline auto index() noexcept(NO_EXCEPT) { return this->_pos; }
};


} // namespace internal

} // namespace uni
#line 2 "internal/range_reference.hpp"


#line 8 "internal/range_reference.hpp"


#line 11 "internal/range_reference.hpp"

#line 13 "internal/range_reference.hpp"


namespace uni {

namespace internal {


template<class Super, std::integral SizeType = typename Super::size_type>
struct range_reference {
    using size_type = SizeType;
    using iterator = Super::iterator;

  protected:
    Super *const _super;
    const size_type _begin, _end;

    range_reference(Super *const super, const size_type begin, const size_type end) noexcept(NO_EXCEPT) : _super(super), _begin(begin), _end(end) {}

  public:
    inline auto begin() const noexcept(NO_EXCEPT) { return std::ranges::next(std::ranges::begin(*this->_super), this->_begin); }
    inline auto end() const noexcept(NO_EXCEPT) { return std::ranges::next(std::ranges::begin(*this->_super), this->_end); }

    inline auto size() const noexcept(NO_EXCEPT) { return this->_end - this->_begin; }

    inline auto interval() const noexcept(NO_EXCEPT) { return std::make_pair(this->_begin, this->_end); }

  protected:
    inline auto sub_range(size_type l, size_type r) const noexcept(NO_EXCEPT) {
        l = _super->_positivize_index(l), r = _super->_positivize_index(r);
        assert(0 <= l and l <= r and r <= this->size());

        return range_reference(_super, this->_begin + l, this->_begin + r);
    }

  public:
    template<uni::interval_notation rng = uni::interval_notation::right_open>
    inline auto range(const size_type l, const size_type r) const noexcept(NO_EXCEPT) {
        if constexpr(rng == uni::interval_notation::right_open) return this->sub_range(l, r);
        if constexpr(rng == uni::interval_notation::left_open) return this->sub_range(l+1, r+1);
        if constexpr(rng == uni::interval_notation::open) return this->sub_range(l+1, r);
        if constexpr(rng == uni::interval_notation::closed) return this->sub_range(l, r+1);
    }
    inline auto range() const noexcept(NO_EXCEPT) { return range_reference(this->_begin, this->_end); }

    inline auto operator()(const size_type l, const size_type r) const noexcept(NO_EXCEPT) { return this->sub_range(l, r); }

    inline auto subseq(const size_type p, const size_type c) const noexcept(NO_EXCEPT) { return this->sub_range(p, p+c); }
    inline auto subseq(const size_type p) const noexcept(NO_EXCEPT) { return this->sub_range(p, this->size()); }
};


} // namespace internal

} // namespace uni
#line 25 "data_structure/dynamic_sequence.hpp"

#line 27 "data_structure/dynamic_sequence.hpp"

#line 2 "data_structure/internal/basic_tree_concept.hpp"


#line 6 "data_structure/internal/basic_tree_concept.hpp"

#line 8 "data_structure/internal/basic_tree_concept.hpp"


namespace uni {

namespace internal {


template<class T>
concept basic_tree =
    std::default_initializable<T> &&
    std::integral<typename T::size_type> &&
    requires (T base, typename T::size_type key, typename T::node_pointer tree, const typename T::node_pointer const_tree) {
        base.split(const_tree, key, tree, tree);
        base.merge(tree, const_tree, const_tree);
    };


} // namespace internal


} // namespace name
#line 2 "data_structure/internal/tree_dumper.hpp"


#line 5 "data_structure/internal/tree_dumper.hpp"


#line 9 "data_structure/internal/tree_dumper.hpp"


namespace uni {

namespace internal {


template<class Derived, class Core, bool LEAF_ONLY>
struct dumpable_tree {
  private:
    using node_handler = Core::node_handler;
    using node_pointer = Core::node_pointer;

    using size_type = Core::size_type;

    inline auto _push(const node_pointer& tree) {
        return static_cast<Derived*>(this)->_impl.push(tree);
        // return static_cast<Derived*>(this)->push(tree);
    }

  public:
    debugger::debug_t dump_rich(node_pointer tree, const std::string prefix, const int dir, size_type& index)
        requires (!LEAF_ONLY)
    {
        if(!tree || tree == node_handler::nil) return prefix + "\n";

        this->_push(tree);

        // debug(tree->priority >= tree->left->priority, tree->priority, tree->left->priority);
        // debug(tree->priority >= tree->right->priority, tree->priority, tree->right->priority);
        assert(tree->priority >= tree->left->priority);
        assert(tree->priority >= tree->right->priority);

        const auto left = this->dump_rich(tree->left, prefix + (dir == 1 ? "| " : "  "), -1, index);
        const auto here =
            prefix + "--+ [" +
            debugger::dump(index) + ", " + debugger::dump(index + tree->length) + ") : " +
            "<" + debugger::dump(tree->priority) + "> " +
            debugger::dump(tree->data) + " [" + debugger::dump(tree->length) + "]\n";
        index += tree->length;

        const auto right = this->dump_rich(tree->right, prefix + (dir == -1 ? "| " : "  "), 1, index);

        return left + here + right;
    }

    debugger::debug_t dump_rich(node_pointer tree, const std::string prefix, const int dir, size_type& index)
        requires
            (
                LEAF_ONLY &&
                requires {
                    typename Core::node_colors;
                }
            )
    {
        if(!tree || tree == node_handler::nil) return prefix + "\n";

        this->_push(tree);

        const auto left = this->dump_rich(tree->left, prefix + (dir == 1 ? "| " : "  "), -1, index);
        const auto right = this->dump_rich(tree->right, prefix + (dir == -1 ? "| " : "  "), 1, index);


        const auto color = tree->color == Core::node_colors::BLACK ? "<->" : "<+>";

        const auto here = [&]() -> std::string {
            if(tree->is_leaf()) {
                index += tree->size;

                return
                    prefix + "--+ [" +
                    debugger::dump(index - tree->size) + ", " + debugger::dump(index) + ") : " +
                    debugger::COLOR_STRING + color + debugger::COLOR_INIT + " " +
                    debugger::dump(tree->data) + " [" + debugger::dump(tree->size) + "]\n";
            }
            return "";
        }();

        return left + here + right;
    }


    inline debugger::debug_t dump_rich(const node_pointer& tree, const std::string prefix = "   ", const int dir = 0) {
        size_type index = 0;
        return this->dump_rich(tree, prefix, dir, index);
    }


    debugger::debug_t _debug(node_pointer tree)
        requires (!LEAF_ONLY)
    {
        if(!tree || tree == node_handler::nil) return "";

        this->_push(tree);

        return
            "(" +
            this->_debug(tree->left) + " " +
            debugger::dump(tree->data) + " [" +
            debugger::dump(tree->length) + "] " +
            this->_debug(tree->right) +
            ")";
    }

    debugger::debug_t _debug(node_pointer tree)
        requires LEAF_ONLY
    {
        if(!tree || tree == node_handler::nil) return "";

        this->_push(tree);

        return
            "(" +
            this->_debug(tree->left) + " " +
            (
                tree->is_leaf()
                    ?
                        debugger::dump(tree->data) + " [" +
                        debugger::dump(tree->size) + "] "
                    :
                        ""
            ) +
            this->_debug(tree->right) +
            ")";
    }
};


} // namespace internal


} // namespace uni
#line 2 "data_structure/internal/dynamic_tree.hpp"


#line 6 "data_structure/internal/dynamic_tree.hpp"


#line 9 "data_structure/internal/dynamic_tree.hpp"

#line 2 "internal/dummy.hpp"


namespace uni {

namespace internal {


struct dummy {};


} // namespace internal

} // namespace uni
#line 12 "data_structure/internal/dynamic_tree.hpp"

#line 2 "action/base.hpp"


#line 6 "action/base.hpp"


#line 11 "action/base.hpp"

#line 2 "algebraic/internal/concepts.hpp"


#line 6 "algebraic/internal/concepts.hpp"


#line 9 "algebraic/internal/concepts.hpp"

#line 2 "algebraic/base.hpp"


#line 6 "algebraic/base.hpp"


#line 10 "algebraic/base.hpp"


namespace uni {

namespace algebraic {


template<class Derived>
struct scalar_multipliable {
    struct identity {
        template<std::integral Scalar>
        friend inline Derived operator*(const Scalar, const Derived& val) noexcept(NO_EXCEPT) {
            return val;
        }
    };


    struct automatic {
        template<std::integral Scalar>
        friend inline Derived operator*(const Scalar k, const Derived& val) noexcept(NO_EXCEPT) {
            return uni::pow<Derived, Scalar, std::plus<Derived>>(val, k, {}, {});
        }
    };
};



template<class T>
struct base {
    using value_type = T;

  protected:
    value_type _value;

  public:
    template<class... Args>
        requires std::constructible_from<value_type, Args...>
    base(Args&&... args) noexcept(NO_EXCEPT) : _value(std::forward<Args>(args)...) {}

    inline explicit operator value_type() const noexcept(NO_EXCEPT) { return this->_value; }
    inline auto val() const noexcept(NO_EXCEPT) { return this->_value; };

    inline const value_type* operator->() const noexcept(NO_EXCEPT) { return &this->_value; };
    inline value_type* operator->() noexcept(NO_EXCEPT) { return &this->_value; };


    friend inline auto operator<=>(const base& lhs, const base& rhs) noexcept(NO_EXCEPT) {
        return lhs._value <=> rhs._value;
    };

    friend inline bool operator==(const base& lhs, const base& rhs) noexcept(NO_EXCEPT) {
        return lhs._value == rhs._value;
    }
};

struct associative {};

struct commutative {};


} // namespace algebraic

} // namespace uni
#line 11 "algebraic/internal/concepts.hpp"


namespace uni {

namespace algebraic {

namespace internal {


template<class T>
concept magma =
    uni::internal::addable<T> &&
    requires {
        typename T::value_type;
    };


template<class T>
concept associative = std::is_base_of_v<algebraic::associative, T>;

template<class T>
concept commutative = std::is_base_of_v<algebraic::commutative, T>;

template<class T>
concept invertible = uni::internal::unary_subtractable<T>;


template<class T>
concept semigroup = magma<T> && associative<T>;

template<class T>
concept monoid = semigroup<T> && std::default_initializable<T>;

template<class T>
concept group = monoid<T> && invertible<T>;


} // namespace internal

} // namespace algebraic

} // namespace uni
#line 13 "action/base.hpp"


namespace uni {

namespace actions {


template<class operation = uni::internal::dummy>
    requires algebraic::internal::monoid<operation> || std::same_as<operation, uni::internal::dummy>
struct base {
    static operation power(const operation& x, const uni::internal::size_t) noexcept(NO_EXCEPT) { return x; }
};


namespace internal {


template<class T>
concept operatable_action = algebraic::internal::magma<typename T::operand>;

template<class T>
concept effective_action =
    algebraic::internal::magma<typename T::operation> &&
    requires (const typename T::operation& f, const uni::internal::size_t length) {
        { T::power(f, length) } -> std::same_as<typename T::operation>;
    };

template<class T>
concept operand_only_action = operatable_action<T> && (!effective_action<T>);

template<class T>
concept effect_only_action = effective_action<T> && (!operatable_action<T>);

template<class T>
concept full_action =
    operatable_action<T> && effective_action<T> &&
    requires (typename T::operation f, typename T::operand v) {
        { T::mapping(f, v) } -> std::same_as<typename T::operand>;
    };

template<class T>
concept action = operatable_action<T> || effective_action<T>;


} // namespace internal

} // namespace actions

} // namespace uni
#line 15 "data_structure/internal/dynamic_tree.hpp"

#line 17 "data_structure/internal/dynamic_tree.hpp"




namespace uni {

namespace internal {

namespace dynamic_tree_impl {

namespace internal {



template<class T>
consteval auto to_val() {
    if constexpr(actions::internal::operatable_action<T>) return typename T::operand{};
    else return T{};
}

template<class T>
consteval auto to_acc() {
    if constexpr(actions::internal::operatable_action<T>) return typename T::operand{};
    else return dummy{};
}

template<class T>
consteval auto to_lazy() {
    if constexpr(actions::internal::effective_action<T>) return typename T::operation{};
    else return dummy{};
}


template<class T, bool LEAF_ONLY, bool MAY_BE_LAZY = true>
struct data_type {
    using val_t = decltype(to_val<T>());
    using acc_t = decltype(to_acc<T>());
    using lazy_t = decltype(to_lazy<T>());

    val_t val;
    [[no_unique_address]] acc_t acc;
    [[no_unique_address]] std::conditional_t<MAY_BE_LAZY, lazy_t, dummy> lazy;

    bool rev = false;

    data_type() noexcept = default;
    data_type(const val_t& _val) noexcept(NO_EXCEPT) : val(_val) {}

    auto _debug() const { return this->val; }


    friend bool operator==(const data_type& lhs, const data_type& rhs) noexcept(NO_EXCEPT) {
        return lhs.val == rhs.val;
    }

    friend auto operator<=>(const data_type& lhs, const data_type& rhs) noexcept(NO_EXCEPT) {
        return lhs.val <=> rhs.val;
    }
};



template<class ActionOrValue, class Derived, class Context>
struct basic_core
  : Context::substance<Derived, internal::data_type<ActionOrValue, Context::LEAF_ONLY>>
{
    using data_type = internal::data_type<ActionOrValue, Context::LEAF_ONLY>;

  private:
    using base = typename Context::substance<Derived, data_type>;
    static_assert(basic_tree<base>);

  public:
    using base::base;

    using node_handler = typename base::node_handler;
    using node_pointer = typename base::node_pointer;

    using size_type = typename base::size_type;

    using operand = data_type::val_t;
    using operation = data_type::lazy_t;


    inline auto val(const node_pointer& node) const noexcept(NO_EXCEPT) {
        if constexpr(Context::LEAF_ONLY) {
            if(node->is_leaf()) return node->size * node->data.val;
            return node->data.val;
        }
        else {
            return node->data.acc;
        }
    }


    using base::split;
    using base::merge;


    inline void split(const node_pointer tree, const size_type l, const size_type r, node_pointer& t0, node_pointer& t1, node_pointer& t2) noexcept(NO_EXCEPT) {
        // See: https://twitter.com/KakurenboUni/status/1784576244321018209
        this->split(tree, l, t0, t1);
        this->split(t1, r - l, t1, t2);
    }

    inline void split(
        const node_pointer tree,
        const size_type l, const size_type m, const size_type r,
        node_pointer& t0, node_pointer& t1, node_pointer& t2, node_pointer& t3
    ) noexcept(NO_EXCEPT) {
        // See: https://twitter.com/KakurenboUni/status/1784576244321018209
        this->split(tree, l, m, t0, t1, t2);
        this->split(t2, r - m, t2, t3);
    }

    inline void merge(node_pointer& tree, node_pointer t0, const node_pointer t1, const node_pointer t2) noexcept(NO_EXCEPT) {
        this->merge(t0, t0, t1);
        this->merge(tree, t0, t2);
    }



    void erase(node_pointer& tree, const size_type l, const size_type r) noexcept(NO_EXCEPT) {
        assert(l <= r);
        node_pointer t0, t1, t2;

        this->split(tree, l, r, t0, t1, t2);
        this->dispose(t1);
        this->merge(tree, t0, t2);
    }


    auto pop(node_pointer& tree, const size_type pos, const size_type count = 1) noexcept(NO_EXCEPT) {
        assert(0 <= count);

        if(count == 0) return operand{};

        node_pointer t0, t1, t2;

        this->split(tree, pos, pos + count, t0, t1, t2);

        const auto res = this->val(t1);

        this->dispose(t1);
        this->merge(tree, t0, t2);

        return res;
    }


    operand get(node_pointer tree, const size_type pos) noexcept(NO_EXCEPT) {
        if(tree == node_handler::nil || pos < 0 || pos >= tree->size) return {};

        this->base::push(tree);

        const auto lower_bound = tree->left->size;
        const auto upper_bound = tree->size - tree->right->size;

        if(pos < lower_bound) {
            return this->get(tree->left, pos);
        }
        else if(pos >= upper_bound) {
            return this->get(tree->right, pos - upper_bound);
        }
        else {
            return tree->data.val;
        }
    }



    template<std::forward_iterator I>
        requires std::output_iterator<I, operand>
    void enumerate(node_pointer tree, I& itr) noexcept(NO_EXCEPT) {
        if(tree == node_handler::nil) return;

        this->base::push(tree);

        this->enumerate(tree->left, itr);

        if constexpr(Context::LEAF_ONLY) {
            if(tree->is_leaf()) {
                REP(tree->size) *(itr++) = tree->data.val;
            }
        }
        else {
            REP(tree->length) *(itr++) = tree->data.val;
        }

        this->enumerate(tree->right, itr);
    }

    auto fold(node_pointer& tree, size_type l, size_type r) noexcept(NO_EXCEPT) {
        assert(l <= r);
        if(l == r) return operand{};

        node_pointer t0, t1, t2;

        this->split(tree, l, r, t0, t1, t2);

        const operand res = this->val(t1);

        this->merge(tree, t0, t1, t2);

        return res;
    }
};


} // namespace internal

} // namespace dynamic_tree_impl

} // namespace internal

} // namespace uni
#line 31 "data_structure/dynamic_sequence.hpp"

#line 2 "data_structure/treap.hpp"


#include <memory>
#include <memory_resource>
#line 13 "data_structure/treap.hpp"


#line 17 "data_structure/treap.hpp"

#line 23 "data_structure/treap.hpp"

#line 2 "data_structure/internal/node_handler.hpp"


#line 5 "data_structure/internal/node_handler.hpp"

#line 7 "data_structure/internal/node_handler.hpp"


namespace uni {

namespace node_handlers {

namespace internal {


template<class Allocator, class NodeType>
struct base_handler {
    using allocator_type = Allocator;

  protected:
    using allocator_traits = std::allocator_traits<allocator_type>;

    using node_allocator_type = allocator_traits::template rebind_alloc<NodeType>;
    using node_allocator_traits = std::allocator_traits<node_allocator_type>;

    [[no_unique_address]] node_allocator_type _allocator;

  public:
    base_handler(const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT)
        : _allocator(allocator)
    {}

    base_handler(const base_handler& source) noexcept(NO_EXCEPT)
        : _allocator(node_allocator_traits::select_on_container_copy_construction(source._allocator))
    {}

    base_handler(base_handler&& source) noexcept = default;

    auto& operator=(const base_handler& source) noexcept(NO_EXCEPT) {
        if(&source != this) {
            if constexpr(allocator_traits::propagate_on_container_copy_assignment::value) {
                this->_allocator = source._allocator;
            }
        }
        return *this;
    }

    auto& operator=(base_handler&& source) noexcept(NO_EXCEPT) {
        if(&source != this) {
            if constexpr(allocator_traits::propagate_on_container_move_assignment::value) {
                this->_allocator = source._allocator;
            }
        }
        return *this;
    }
};


} // namespace internal


template<class Allocator>
struct cloneable {
    template<class NodeType>
    struct handler : internal::base_handler<Allocator, NodeType> {
        using internal::base_handler<Allocator, NodeType>::base_handler;

        using node_type = NodeType;
        using node_pointer = std::shared_ptr<node_type>;

        inline static node_pointer nil = std::make_shared<node_type>();

        template<class... Args>
        inline auto create(Args&&... args) noexcept(NO_EXCEPT) {
            return std::allocate_shared<node_type>(this->_allocator, std::forward<Args>(args)...);
        }

        inline auto clone(const node_pointer& ptr) noexcept(NO_EXCEPT) {
            return this->create(*ptr);
        }

        inline constexpr bool disposable(const node_pointer&) const noexcept { return false; }
        inline constexpr void dispose(const node_pointer&) const noexcept {}
    };
};


template<class Allocator>
struct reusing {
    template<class NodeType>
    struct handler : internal::base_handler<Allocator, NodeType> {
        using node_type = NodeType;
        using node_pointer = std::add_pointer_t<node_type>;

      private:
        using base = internal::base_handler<Allocator, NodeType>;
        using node_allocator_traits = typename base::node_allocator_traits;

        inline static int _instance_count = 0;

      public:
        using base::base;

        using allocator_type = typename base::allocator_type;


        inline static node_pointer nil;


        handler(const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT) : base(allocator) {
            if(handler::_instance_count++ == 0) {
                handler::nil = new node_type{};
            }
        }

        ~handler() noexcept {
            if(--handler::_instance_count == 0) {
                delete handler::nil;
            }
        }


        template<class... Args>
        inline auto create(Args&&... args) noexcept(NO_EXCEPT) {
            node_pointer node = node_allocator_traits::allocate(this->_allocator, 1);
            node_allocator_traits::construct(this->_allocator, node, std::forward<Args>(args)...);

            return node;
        }

        inline auto clone(const node_pointer ptr) const noexcept { return ptr; }

        inline bool disposable(const node_pointer node) const noexcept(NO_EXCEPT) {
            return node != handler::nil;
        }

        inline void dispose(const node_pointer node) noexcept(NO_EXCEPT) {
            node_allocator_traits::destroy(this->_allocator, node);
            node_allocator_traits::deallocate(this->_allocator, node, 1);
        }
    };
};


} // namespace node_handlers

} // namespace uni
#line 25 "data_structure/treap.hpp"

#line 27 "data_structure/treap.hpp"

#line 2 "random/engine.hpp"


#line 7 "random/engine.hpp"

#line 9 "random/engine.hpp"


#line 12 "random/engine.hpp"

#line 14 "random/engine.hpp"

#line 2 "hash/general_hasher.hpp"


#line 7 "hash/general_hasher.hpp"


#line 11 "hash/general_hasher.hpp"

#line 13 "hash/general_hasher.hpp"


namespace uni {


template<std::unsigned_integral R, std::integral T>
constexpr R shrink(T x) noexcept(NO_EXCEPT) {
    constexpr int DIGITS_R = std::numeric_limits<R>::digits;
    constexpr int DIGITS_T = std::numeric_limits<R>::digits;

    REPD(digits, DIGITS_R, DIGITS_T, DIGITS_R) {
        x = (x >> digits) ^ uni::lower_bits(x, digits);
    }

    return x;
}


// Thanks to: https://gist.github.com/badboy/6267743
template<class T>
constexpr u32 hash32(T x) {
    if constexpr(std::integral<T>) {
        if constexpr(std::signed_integral<T>) return hash32(to_unsigned(x));

        constexpr int DIGITS_T = std::numeric_limits<T>::digits;

        if constexpr(DIGITS_T <= 32) {
            auto h = static_cast<u32>(x);

            h = ~h + (h << 15);
            h ^= (h >> 12);
            h += (h << 2);
            h ^= (h >> 4);
            h *= 2057;
            h ^= (h >> 16);

            return h;
        }
        else if constexpr(DIGITS_T <= 64) {
            auto h = static_cast<u64>(x);

            h = (~h) + (h << 18);
            h ^= (h >> 31);
            h *= 21;
            h ^= (h >> 11);
            h += (h << 6);
            h ^= (h >> 22);

            return static_cast<u32>(h);
        }
        else {
            return hash32(hash64(x));
        }
    }
    else {
        return hash32(std::hash<T>{}(x));
    }
}


template<class T>
constexpr u64 hash64(T x) {
    if constexpr(std::integral<T>) {
        if constexpr(std::signed_integral<T>) return hash64(to_unsigned(x));

        constexpr int DIGITS_T = std::numeric_limits<T>::digits;

        if constexpr(DIGITS_T <= 64) {
            auto h = static_cast<u64>(x);

            h = (~h) + (h << 21);
            h ^= (h >> 24);
            h *= 265;
            h ^= (h >> 14);
            h *= 21;
            h ^= (h >> 28);
            h += h << 31;

            return h;
        }
        else {
            return hash64(shrink<u64>(x));
        }
    }
    else {
        return hash64(std::hash<T>{}(x));
    }
}


template<class T>
struct hash {
    inline constexpr auto operator()(const T& key) const noexcept(NO_EXCEPT) {
        return static_cast<std::size_t>(uni::hash64(key));
    }
};


} // namespace uni
#line 16 "random/engine.hpp"


// Thanks to: https://prng.di.unimi.it/
namespace uni {


namespace internal {


template<class Derived, class ResultType>
struct random_engine {
    using result_type = ResultType;

    static constexpr result_type MIN = std::numeric_limits<result_type>::min();
    static constexpr result_type MAX = std::numeric_limits<result_type>::max();

    static constexpr result_type min() noexcept(NO_EXCEPT) { return MIN; }
    static constexpr result_type max() noexcept(NO_EXCEPT) { return MAX; }


    template<std::unsigned_integral T = result_type>
    constexpr random_engine(const T _seed = 0) noexcept(NO_EXCEPT) {
        static_cast<Derived*>(this)->seed(_seed);
    };


    inline constexpr result_type operator()() noexcept(NO_EXCEPT) {
        return static_cast<Derived*>(this)->next();
    }
};


const i64 INTERNAL_RANDOM_GENERATOR_ID = -(1UL << 60);


};  // namespace internal


constexpr float to_float(const std::uint32_t x) noexcept(NO_EXCEPT) {
        return float(x >> 8) * 0x1.0p-24f;
}

constexpr double to_double(const std::uint64_t x) noexcept(NO_EXCEPT) {
    return double(x >> 11) * 0x1.0p-53;
}


struct mulberry32 : internal::random_engine<mulberry32, std::uint32_t> {
    using internal::random_engine<mulberry32, std::uint32_t>::random_engine;

  private:
    std::uint32_t _x;

  public:
    template<std::unsigned_integral T>
    inline constexpr void seed(const T x) noexcept(NO_EXCEPT) { this->_x = x; }

    inline constexpr std::uint32_t next() noexcept(NO_EXCEPT) {
        std::uint32_t z = (this->_x += 0x6D2B79F5U);
        z = (z ^ (z >> 15)) * (z | 1U);
        z ^= z + (z ^ (z >> 7)) * (z | 61U);
        return static_cast<std::uint32_t>(z ^ (z >> 14));
    }
};


struct splitmix64 : internal::random_engine<splitmix64, std::uint64_t> {
    using internal::random_engine<splitmix64, std::uint64_t>::random_engine;

  private:
    std::uint64_t _x;

  public:
    template<std::unsigned_integral T>
    inline constexpr void seed(const T x) noexcept(NO_EXCEPT) { this->_x = x; }

    inline constexpr std::uint64_t next() noexcept(NO_EXCEPT) {
        std::uint64_t z = (this->_x += 0x9e3779b97f4a7c15);
        z = (z ^ (z >> 30)) * 0xbf58476d1ce4e5b9;
        z = (z ^ (z >> 27)) * 0x94d049bb133111eb;
        return z ^ (z >> 31);
    }
};



// xoroshiro64**
struct xoroshiro64ss : internal::random_engine<xoroshiro64ss, std::uint32_t> {
    using internal::random_engine<xoroshiro64ss, std::uint32_t>::random_engine;

  private:
    std::uint32_t s[2];

  public:
    template<std::unsigned_integral T>
    inline constexpr void seed(const T _seed) noexcept(NO_EXCEPT) {
        mulberry32 gen32(hash32(_seed));
        this->s[0] = gen32();
        this->s[1] = gen32();
    }

    inline constexpr std::uint32_t next() noexcept(NO_EXCEPT) {
        const std::uint32_t s0 = this->s[0];
        std::uint32_t s1 = this->s[1];

        const std::uint32_t res = std::rotl(s0 * 0x9E3779BBU, 5) * 5;

        s1 ^= s0;
        this->s[0] = std::rotl(s0, 26) ^ s1 ^ (s1 << 9);
        this->s[1] = std::rotl(s1, 13);

        return res;
    }
};



struct xoroshiro128ss : internal::random_engine<xoroshiro128ss, std::uint64_t> {
    using internal::random_engine<xoroshiro128ss, std::uint64_t>::random_engine;

  private:
    std::uint64_t s[2];

  public:
    template<std::unsigned_integral T>
    inline constexpr void seed(const T _seed) noexcept(NO_EXCEPT) {
        splitmix64 gen64(hash32(_seed));
        this->s[0] = gen64();
        this->s[1] = gen64();
    }

    inline constexpr std::uint64_t next() noexcept(NO_EXCEPT) {
        const uint64_t s0 = this->s[0];
        uint64_t s1 = this->s[1];
        const uint64_t res = std::rotl(s0 * 5, 7) * 9;

        s1 ^= s0;
        this->s[0] = std::rotl(s0, 24) ^ s1 ^ (s1 << 16);
        this->s[1] = std::rotl(s1, 37);

        return res;
    }
};


struct xoroshiro128pp : internal::random_engine<xoroshiro128pp, std::uint64_t> {
    using internal::random_engine<xoroshiro128pp, std::uint64_t>::random_engine;

  private:
    std::uint64_t s[2];

  public:
    template<std::unsigned_integral T>
    inline constexpr void seed(const T _seed) noexcept(NO_EXCEPT) {
        splitmix64 gen64(hash32(_seed));
        this->s[0] = gen64();
        this->s[1] = gen64();
    }

    inline constexpr std::uint64_t next() noexcept(NO_EXCEPT) {
        const std::uint64_t s0 = this->s[0];
        std::uint64_t s1 = this->s[1];
        const std::uint64_t res = std::rotl(s0 + s1, 17) + s0;

        s1 ^= s0;
        this->s[0] = std::rotl(s0, 49) ^ s1 ^ (s1 << 21); // a, b
        this->s[1] = std::rotl(s1, 28); // c

        return res;
    }
};


// xoroshiro128+
struct xoroshiro128p : internal::random_engine<xoroshiro128p, std::uint64_t> {
    using internal::random_engine<xoroshiro128p, std::uint64_t>::random_engine;

  private:
    std::uint64_t s[2];

  public:
    template<std::unsigned_integral T>
    inline constexpr void seed(const T _seed) noexcept(NO_EXCEPT) {
        splitmix64 gen64(hash64(_seed));
        this->s[0] = gen64();
        this->s[1] = gen64();
    }

    inline constexpr std::uint64_t next() noexcept(NO_EXCEPT) {
        const std::uint64_t s0 = this->s[0];
        std::uint64_t s1 = this->s[1];
        const std::uint64_t res = s0 + s1;

        s1 ^= s0;
        this->s[0] = std::rotl(s0, 24) ^ s1 ^ (s1 << 16);
        this->s[1] = std::rotl(s1, 37);

        return res;
    }
};


struct xoroshiro64s : internal::random_engine<xoroshiro64s, std::uint32_t> {
    using internal::random_engine<xoroshiro64s, std::uint32_t>::random_engine;

  private:
    std::uint32_t s[2];

  public:
    template<std::unsigned_integral T>
    inline constexpr void seed(const T _seed) noexcept(NO_EXCEPT) {
        mulberry32 gen32(hash32(_seed));
        this->s[0] = gen32();
        this->s[1] = gen32();
    }

    inline constexpr std::uint32_t next() noexcept(NO_EXCEPT) {
        const std::uint32_t s0 = s[0];
        std::uint32_t s1 = s[1];
        const std::uint32_t res = s0 * 0x9E3779BB;

        s1 ^= s0;
        s[0] = std::rotl(s0, 26) ^ s1 ^ (s1 << 9);
        s[1] = std::rotl(s1, 13);

        return res;
    }
};


using random_engine_32bit = xoroshiro64ss;

using random_engine_64bit = xoroshiro128pp;

using random_engine_float = xoroshiro64s;

using random_engine_double = xoroshiro128p;



random_engine_32bit randi32;
random_engine_64bit randi64;

float randf() {
    static random_engine_float gen;
    return to_float(gen());
}

double randd() {
    static random_engine_double gen;
    return to_double(gen());
}


} // namespace uni
#line 29 "data_structure/treap.hpp"


#line 32 "data_structure/treap.hpp"


namespace uni {

namespace internal {


// Thanks to: https://github.com/xuzijian629/library2/blob/master/treap/implicit_treap.cpp
template<class Allocator, class Derived, std::integral SizeType, class ValueType, i64 Id>
struct treap_impl : private uncopyable {
    using size_type = SizeType;
    using value_type = ValueType;

    struct node_type;
    using node_handler = typename uni::node_handlers::reusing<Allocator>::template handler<node_type>;

    using allocator_type = typename node_handler::allocator_type;
    using node_pointer = typename node_handler::node_pointer;

  private:
    using derived = Derived;

    inline auto* _derived() noexcept(NO_EXCEPT) {
        return static_cast<derived*>(this);
    }
    inline const auto* _derived() const noexcept(NO_EXCEPT) {
        return static_cast<const derived*>(this);
    }

    [[no_unique_address]] node_handler _node_handler;


    static inline random_engine_32bit _rand;

    using priority_type = random_engine_32bit::result_type;

  public:
    void pull(const node_pointer tree) noexcept(NO_EXCEPT) {
        if(tree == node_handler::nil) return;
        tree->size = tree->left->size + tree->length + tree->right->size;
        this->_derived()->pull(tree);
    }

    void push(const node_pointer tree) noexcept(NO_EXCEPT) {
        if(tree == node_handler::nil) return;
        this->_derived()->push(tree);
    }


    node_pointer create(const value_type& val, const size_type size) noexcept(NO_EXCEPT) {
        if(size == 0) return node_handler::nil;
        return this->_node_handler.create(val, size);
    }

    void dispose(node_pointer tree) noexcept(NO_EXCEPT) {
        if(this->_node_handler.disposable(tree)) {
            this->dispose(tree->left);
            this->dispose(tree->right);

            this->_node_handler.dispose(tree);
        }
    }

    template<class... Args>
    inline void constexpr clone(Args&&...) const noexcept {}

  private:
    void _rotate_right(node_pointer& tree) noexcept(NO_EXCEPT) {  // push ommitted
        auto t = tree->left;

        tree->left = t->right;
        this->pull(tree);

        t->right = tree;
        this->pull(t);

        tree = std::move(t);
    }


    void _rectify(const node_pointer tree) const noexcept(NO_EXCEPT) {
        if(tree->size == 0) return;

        std::vector<priority_type> priorities(tree->size);
        std::ranges::generate(priorities, treap_impl::_rand);
        std::ranges::make_heap(priorities);

        std::queue<node_pointer> queue;
        queue.push(tree);

        auto itr = std::ranges::begin(priorities);
        while(!queue.empty()) {
            node_pointer node = queue.front();
            queue.pop();

            node->priority = *(itr++);

            if(node->left != node_handler::nil) queue.push(node->left);
            if(node->right != node_handler::nil) queue.push(node->right);
        }
    }


    template<std::random_access_iterator I, std::sized_sentinel_for<I> S>
        requires std::constructible_from<value_type, std::iter_value_t<I>>
    node_pointer _build(I first, S last) noexcept(NO_EXCEPT) {
        if(first == last) return node_handler::nil;

        const auto length = std::ranges::distance(first, last);
        const auto middle = std::ranges::next(first, length >> 1);

        node_pointer tree = this->create(value_type{ *middle }, 1);
        tree->left = this->_build(first, middle);
        tree->right = this->_build(std::ranges::next(middle), last);

        this->pull(tree);

        return tree;
    }


    template<std::random_access_iterator I, std::sized_sentinel_for<I> S>
        requires
            std::constructible_from<value_type, typename std::iter_value_t<I>::first_type> &&
            std::integral<typename std::iter_value_t<I>::second_type>
    node_pointer _build(I first, S last) noexcept(NO_EXCEPT) {
        if(first == last) return node_handler::nil;

        const auto length = std::ranges::distance(first, last);
        const auto middle = std::ranges::next(first, length >> 1);

        node_pointer tree = this->create(value_type{ middle->first }, middle->second );
        tree->left = this->_build(first, middle);
        tree->right = this->_build(std::ranges::next(middle), last);

        this->pull(tree);

        return tree;
    }

    void _split(node_pointer tree, const size_type pos, node_pointer& left, node_pointer& right) noexcept(NO_EXCEPT) {
        if(tree == node_handler::nil) {
            left = right = node_handler::nil;
            return;
        }

        this->push(tree);

        const auto lower_bound = tree->left->size;
        const auto upper_bound = tree->size - tree->right->size;

        if(pos <= lower_bound) {
            node_pointer t;
            this->split(tree->left, pos, left, t);
            tree->left = t;

            if(tree->priority < t->priority) this->_rotate_right(tree);

            right = std::move(tree);
            this->pull(right);
        }
        else if(pos >= upper_bound) {
            this->split(tree->right, pos - upper_bound, tree->right, right);

            left = std::move(tree);
            this->pull(left);
        }
        else {
            tree->length = pos - lower_bound;
            this->merge(tree->right, this->create(tree->data, upper_bound - pos), tree->right);

            this->split(tree->right, 0, tree->right, right), left = std::move(tree);
            this->pull(left);
        }
    }

  public:
    explicit treap_impl(const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT) : _node_handler(allocator) {}

    template<std::random_access_iterator I, std::sized_sentinel_for<I> S>
    node_pointer build(I first, S last) {
        const auto tree = this->_build(first, last);
        this->_rectify(tree);
        return tree;
    }

    struct node_type {
        priority_type priority = std::numeric_limits<priority_type>::lowest();

        node_pointer left = node_handler::nil, right = node_handler::nil;

        size_type length, size;
        [[no_unique_address]] value_type data;

        node_type() noexcept = default;

        node_type(const value_type& _data, const size_type _size) noexcept(NO_EXCEPT)
            : priority(treap_impl::_rand()), length(_size), size(_size), data(_data)
        {}
    };


    template<bool STRICT = false, bool RETURN_EXISTENCE = false>
    void split(const node_pointer tree, const value_type& val, node_pointer& left, node_pointer& right, bool* exist = nullptr) noexcept(NO_EXCEPT) {
        if(tree == node_handler::nil) {
            left = right = node_handler::nil;
            return;
        }

        this->push(tree);

        if constexpr(RETURN_EXISTENCE) *exist |= val == tree->data;

        if(val < tree->data || (!STRICT && val == tree->data)) {
            this->template split<STRICT, RETURN_EXISTENCE>(tree->left, val, left, tree->left, exist);

            right = std::move(tree);
            this->pull(right);
        }
        else {
            this->template split<STRICT, RETURN_EXISTENCE>(tree->right, val, tree->right, right, exist);

            left = std::move(tree);
            this->pull(left);
        }
    }


    void split(const node_pointer tree, const size_type pos, node_pointer& left, node_pointer& right) noexcept(NO_EXCEPT) {
        if(pos <= 0) {
            left = node_handler::nil;
            this->merge(right, this->create(value_type{}, -pos), std::move(tree));
        }
        else if(tree->size <= pos) {
            right = node_handler::nil;
            this->merge(left, std::move(tree), this->create(value_type{}, pos - tree->size));
        }
        else {
            this->_split(std::move(tree), pos, left, right);
        }
    }


    void merge(node_pointer& tree, const node_pointer left, const node_pointer right) noexcept(NO_EXCEPT) {
        this->push(left);
        this->push(right);

        if(left == node_handler::nil || right == node_handler::nil) {
            tree = left == node_handler::nil ? right : left;
        }
        else if(left->priority < right->priority) {
            this->merge(right->left, left, right->left), tree = std::move(right);
        }
        else {
            this->merge(left->right, left->right, right), tree = std::move(left);
        }

        this->pull(tree);
    }
};


} // namespace internal


template<std::integral SizeType = i64, class Allocator = std::allocator<SizeType>, i64 Id = -1>
struct treap_context {
    static constexpr bool LEAF_ONLY = false;

    template<class Derived, class ValueType = internal::dummy>
    using substance = internal::treap_impl<Allocator, Derived, SizeType, ValueType, Id>;
};


namespace pmr {


template<std::integral SizeType = i64, i64 Id = -1>
using treap_context = uni::treap_context<SizeType, std::pmr::polymorphic_allocator<SizeType>, Id>;


} // namespace pmr


} // namespace uni
#line 33 "data_structure/dynamic_sequence.hpp"

#line 35 "data_structure/dynamic_sequence.hpp"

#line 2 "action/helpers.hpp"

#line 5 "action/helpers.hpp"


#line 2 "algebraic/null.hpp"


#line 5 "algebraic/null.hpp"


#line 9 "algebraic/null.hpp"

#line 12 "algebraic/null.hpp"


namespace uni {

namespace algebraic {


template<class T = uni::internal::dummy>
struct null : base<T>, scalar_multipliable<null<T>>::identity, associative, commutative {
    using base<T>::base;

    friend inline null operator+(const null& lhs, const null& rhs) noexcept(NO_EXCEPT) {
        if(lhs == null()) return rhs;
        return lhs;
    }

    inline null operator-() const noexcept(NO_EXCEPT)
        requires internal::invertible<T>
    {
        return -*this;
    }
};


} // namespace algebraic

} // namespace uni
#line 2 "algebraic/helper.hpp"


#line 7 "algebraic/helper.hpp"


namespace uni {

namespace algebraic {


template<class T, auto op, auto e, class... Tags>
struct helper : uni::algebraic::base<T>, uni::algebraic::scalar_multipliable<helper<T, op, e, Tags...>>::automatic, Tags... {
    static_assert(std::same_as<std::invoke_result_t<decltype(op), T, T>, T>);
    static_assert(std::same_as<std::invoke_result_t<decltype(e)>, T>);

    using uni::algebraic::base<T>::base;

    helper() : helper(e()) {}

    friend inline helper operator+(const helper& lhs, const helper& rhs) noexcept(NO_EXCEPT) {
        return op(lhs.val(), rhs.val());
    }
};


template<class T, auto op, auto e>
using monoid_helper = helper<T, op, e, associative>;


template<class T>
struct make_magma {
    using type = null<T>;

    static_assert(internal::magma<type>);
};


template<internal::magma T>
struct make_magma<T> {
    using type = T;
};

template<class T>
using make_magma_t = typename make_magma<T>::type;



} // namespace algebraic

} // namespace uni
#line 2 "action/null.hpp"


#line 6 "action/null.hpp"

#line 8 "action/null.hpp"

#line 2 "algebraic/addition.hpp"


#line 7 "algebraic/addition.hpp"


namespace uni {

namespace algebraic {


template<class T>
struct addition : base<T>, associative, commutative {
    using base<T>::base;

    friend inline addition operator+(const addition& lhs, const addition& rhs) noexcept(NO_EXCEPT) {
        return lhs.val() + rhs.val();
    }

    template<std::integral Scalar>
    friend inline addition operator*(const Scalar k, const addition& rhs) noexcept(NO_EXCEPT) {
        return k * rhs.val();
    }

    inline addition operator-() const noexcept(NO_EXCEPT)
        requires internal::invertible<T>
    {
        return -this->val();
    }
};


} // namespace algebraic

} // namespace uni
#line 11 "action/null.hpp"


namespace uni {

namespace actions {


template<class T>
struct null : base<algebraic::null<T>> {
    using operand = algebraic::null<T>;
    using operation = algebraic::null<T>;

    static operand mapping(const operation&, const operand& x) noexcept(NO_EXCEPT) { return x; }
};


} // namespace actions

} // namespace uni
#line 11 "action/helpers.hpp"

namespace uni {

namespace actions {


template<class S, auto op, auto e, class F, auto _mapping, auto composition, auto id, auto _power = nullptr>
struct helper {
    static_assert(std::same_as<std::invoke_result_t<decltype(_mapping), F, S>, S>);
    // static_assert(std::same_as<std::invoke_result_t<decltype(_power), F, uni::internal::size_t>, F>);

    using operand = algebraic::monoid_helper<S, op, e>;
    using operation = algebraic::monoid_helper<F, composition, id>;

    static operand mapping(const operation& f, const operand& x) noexcept(NO_EXCEPT) {
        return _mapping(f.val(), x.val());
    }

    static operation power(const operation& x, [[maybe_unused]] const uni::internal::size_t length) noexcept(NO_EXCEPT) {
        if constexpr(_power == nullptr) return x;
        else return _power(x.val(), length);
    }
};


template<class S, class F, auto _mapping, auto _power = nullptr>
struct mixer {
    static_assert(std::same_as<std::invoke_result_t<decltype(_mapping), F, S>, S>);
    static_assert(std::same_as<std::invoke_result_t<decltype(_power), F, uni::internal::size_t>, F>);

    using operand = S;
    using operation = F;

    static operand mapping(const operation& f, const operand& x) noexcept(NO_EXCEPT) {
        return _mapping(f.val(), x.val());
    }
    static operation power(const operation& x, [[maybe_unused]] const uni::internal::size_t length) noexcept(NO_EXCEPT) {
        if constexpr(_power == nullptr) return x;
        return _power(x.val(), length);
    }
};



template<class S>
struct amplifier {
    using operand = S;
    using operation = S;

    static operand mapping(const operation& f, const operand& x) noexcept(NO_EXCEPT) {
        return f + x;
    }

    static operation power(const operation& x, [[maybe_unused]] const uni::internal::size_t length) noexcept(NO_EXCEPT) {
        return length * x;
    }
};


template<algebraic::internal::magma Magma>
struct make_operatable {
    struct type {
        using operand = Magma;
    };

    static_assert(internal::operatable_action<type>);
};

template<class T>
using make_operatable_t = typename make_operatable<T>::type;


template<algebraic::internal::magma Magma>
struct make_effective {
    struct type : base<Magma> {
        using operation = Magma;
    };

    static_assert(internal::effective_action<type>);
};

template<class T>
using make_effective_t = typename make_effective<T>::type;


template<class T>
struct make_full {
    using type = null<T>;

    static_assert(internal::full_action<type>);
};

template<algebraic::internal::magma Magma>
struct make_full<Magma> {
    using type = make_full<make_operatable_t<Magma>>::type;
};

template<internal::full_action Action>
struct make_full<Action> {
    using type = Action;
};

template<internal::operand_only_action Action>
struct make_full<Action> {
    using base = Action;
    struct type : actions::base<algebraic::null<typename base::operand::value_type>> {
        using operand = typename base::operand;
        using operation = algebraic::null<typename base::operand::value_type>;

        using actions::base<algebraic::null<typename base::operand::value_type>>::base;

        static operand mapping(const operation&, const operand& x) noexcept(NO_EXCEPT) { return x; }
    };

    static_assert(internal::full_action<type>);
};

template<internal::effect_only_action Action>
struct make_full<Action> {
    using base = Action;

    struct type : base {
        using operand = typename base::operation;
        using operation = typename base::operation;

        using base::base;

        static operand mapping(const operation& f, const operand& x) noexcept(NO_EXCEPT) { return f + x; }
    };

    static_assert(internal::full_action<type>);
};


template<class T>
using make_full_t = typename make_full<T>::type;


} // namespace actions

} // namespace uni
#line 38 "data_structure/dynamic_sequence.hpp"

#line 40 "data_structure/dynamic_sequence.hpp"


namespace uni {

namespace internal {

namespace dynamic_tree_impl {


template<class ActionOrValue, class Context>
struct sequence_core
  : internal::basic_core<ActionOrValue, sequence_core<ActionOrValue, Context>, Context>
//   ,
    // dumpable_tree<
    //     sequence_core<ActionOrValue, Context>,
    //     internal::basic_core<ActionOrValue, sequence_core<ActionOrValue, Context>, Context>,
    //     Context::LEAF_ONLY
    // >
{
  private:
    using base = typename internal::basic_core<ActionOrValue, sequence_core, Context>;

  public:
    static constexpr bool ACC = actions::internal::operatable_action<ActionOrValue>;
    static constexpr bool LAZY = actions::internal::effective_action<ActionOrValue>;

    using base::base;

    using data_type = base::data_type;

    using operand = base::operand;
    using operation = base::operation;


    using node_handler = typename base::node_handler;

    using node_type = typename base::node_type;
    using node_pointer = typename base::node_pointer;


    using size_type = typename base::size_type;


    inline void pull(const node_pointer& tree) const noexcept(NO_EXCEPT) {
        if constexpr(ACC) {
            if constexpr(Context::LEAF_ONLY) {
                tree->data.val = this->val(tree->left) + this->val(tree->right);
            }
            else {
                tree->data.acc = tree->left->data.acc + tree->length * tree->data.val + tree->right->data.acc;
            }
        }
    }

    inline void push(const node_pointer& tree) noexcept(NO_EXCEPT) {
        if(tree->data.rev) {
            tree->data.rev = false;

            std::swap(tree->left, tree->right);

            if(tree->left != node_handler::nil) {
                this->clone(tree->left);
                tree->left->data.rev ^= 1;
            }
            if(tree->right != node_handler::nil) {
                this->clone(tree->right);
                tree->right->data.rev ^= 1;
            }
        }

        if constexpr(LAZY) {
            if(tree->data.lazy != operation{}) {
                if constexpr(Context::LEAF_ONLY) {
                    if(tree->left != node_handler::nil) {
                        this->clone(tree->left);
                        if(tree->left->is_leaf()) {
                            tree->left->data.val = ActionOrValue::mapping(tree->data.lazy, tree->left->data.val);
                        }
                        else {
                            tree->left->data.lazy = tree->data.lazy + tree->left->data.lazy;
                            tree->left->data.val = ActionOrValue::mapping(ActionOrValue::power(tree->data.lazy, tree->left->size), tree->left->data.val);
                        }
                    }

                    if(tree->right != node_handler::nil) {
                        this->clone(tree->right);
                        if(tree->right->is_leaf()) {
                            tree->right->data.val = ActionOrValue::mapping(tree->data.lazy, tree->right->data.val);
                        }
                        else {
                            tree->right->data.lazy = tree->data.lazy + tree->right->data.lazy;
                            tree->right->data.val = ActionOrValue::mapping(ActionOrValue::power(tree->data.lazy, tree->right->size), tree->right->data.val);
                        }
                    }
                }
                else {
                    if(tree->left != node_handler::nil) {
                        tree->left->data.lazy = tree->data.lazy + tree->left->data.lazy;
                        tree->left->data.acc = ActionOrValue::mapping(ActionOrValue::power(tree->data.lazy, tree->left->size), tree->left->data.acc);
                    }

                    if(tree->right != node_handler::nil) {
                        tree->right->data.lazy = tree->data.lazy + tree->right->data.lazy;
                        tree->right->data.acc = ActionOrValue::mapping(ActionOrValue::power(tree->data.lazy, tree->right->size), tree->right->data.acc);
                    }
                }

                tree->data.val = ActionOrValue::mapping(tree->data.lazy, tree->data.val);
                tree->data.lazy = operation{};
            }
        }
    }


    inline void update(node_pointer& tree) noexcept(NO_EXCEPT) {
        if(tree == node_handler::nil) return;
        this->base::push(tree);
        this->base::pull(tree);
    }



    void insert(node_pointer& tree, const size_type pos, const operand& val, const size_type count = 1) noexcept(NO_EXCEPT) {
        assert(count >= 0);
        if(count == 0) return;

        node_pointer t0, t1;

        this->split(tree, pos, t0, t1);
        this->merge(tree, t0, this->create(val, count), t1);
    }

    template<std::input_iterator I, std::sized_sentinel_for<I> S>
    void insert(node_pointer& tree, const size_type pos, I first, S last) noexcept(NO_EXCEPT) {
        node_pointer t0, t1;

        this->split(tree, pos, t0, t1);
        this->merge(tree, t0, this->build(first, last), t1);
    }


    void add(node_pointer& tree, const size_type pos, const operand& val) noexcept(NO_EXCEPT) {
        node_pointer t0, t1, t2;

        this->split(tree, pos, t0, t1);
        this->split(t1, 1, t1, t2);

        const auto prev = this->val(t1);
        this->dispose(t1);
        t1 = this->create(data_type{ prev + val }, 1);

        this->merge(tree, t0, t1, t2);
    }


    void fill(node_pointer& tree, const size_type l, const size_type r, const operand& val) noexcept(NO_EXCEPT) {
        assert(l <= r);
        if(l == r) return;

        node_pointer t0, t1, t2;
        this->split(tree, l, r, t0, t1, t2);

        // this->split(tree, l, r, t0, t1, t2);

        // this->split(tree, l, t0, t1);
        // debug(this->dump_rich(t0), this->dump_rich(t1));

        // this->split(t1, r - l, t1, t2);
        // debug(this->dump_rich(t1), this->dump_rich(t2));

        this->dispose(t1);
        t1 = this->create(val, r - l);

        this->merge(tree, t0, t1, t2);

        // this->merge(t0, t0, t1);
        // debug(this->dump_rich(t0));

        // this->merge(tree, t0, t2);
        // debug(this->dump_rich(tree));
    }

    template<std::input_iterator I, std::sized_sentinel_for<I> S>
    void fill(node_pointer& tree, const size_type pos, I first, S last) noexcept(NO_EXCEPT) {
        node_pointer t0, t1, t2;

        this->split(tree, pos, pos + std::ranges::distance(first, last), t0, t1, t2);
        this->dispose(t1);
        this->merge(tree, t0, this->build(first, last), t2);
    }


    void apply(node_pointer& tree, const size_type l, const size_type r, const operation& val) noexcept(NO_EXCEPT)
        requires LAZY
    {
        assert(l <= r);
        if(l == r) return;

        node_pointer t0, t1, t2;

        this->split(tree, l, r, t0, t1, t2);

        if(t1 == node_handler::nil) t1 = this->create(data_type{}, r - l);
        t1->data.lazy = val + t1->data.lazy;

        this->merge(tree, t0, t1, t2);
    }

    void reverse(node_pointer& tree, const size_type l, const size_type r) noexcept(NO_EXCEPT) {
        assert(l <= r);
        if(l == r) return;

        node_pointer t0, t1, t2;

        this->split(tree, l, r, t0, t1, t2);

        if(t1 != node_handler::nil) t1->data.rev ^= 1;

        this->merge(tree, t0, t1, t2);
    }


    void shift_left(node_pointer& tree, const size_type l, const size_type r, const size_type count = 1) noexcept(NO_EXCEPT) {
        assert(l <= r);

        if(count < 0) return this->shift_right(tree, l, r, -count);

        if(count == 0) return;
        if(count >= r - l) return this->fill(tree, l, r, {});

        node_pointer t0, t1, t2, t3;

        this->split(tree, l, l + count, r, t0, t1, t2, t3);

        this->dispose(t1);

        this->merge(t2, t2, this->create({}, count));
        this->merge(tree, t0, t2, t3);
    }

    void shift_right(node_pointer& tree, const size_type l, const size_type r, const size_type count = 1) noexcept(NO_EXCEPT) {
        assert(l <= r);

        if(count < 0) return this->shift_left(tree, l, r, -count);

        if(count == 0) return;
        if(count >= r - l) return this->fill(tree, l, r, {});

        node_pointer t0, t1, t2, t3;

        this->split(tree, l, r - count, r, t0, t1, t2, t3);

        this->dispose(t2);

        this->merge(t1, this->create({}, count), t1);
        this->merge(tree, t0, t1, t3);
    }

    void rotate(node_pointer& tree, const size_type l, const size_type m, const size_type r) noexcept(NO_EXCEPT) {
        assert(l <= m && m < r);
        if(l == m) return;

        node_pointer t0, t1, t2, t3;

        this->split(tree, l, m, r, t0, t1, t2, t3);
        this->merge(t2, t2, t1);
        this->merge(tree, t0, t2, t3);
    }


    template<bool LEFT>
    size_type find(const node_pointer& tree, operand& val, const size_type offset) noexcept(NO_EXCEPT) {
        if(tree->data.acc + val == val) {
            return -1;
        }

        if constexpr(LEFT) {
            if(tree->left != node_handler::nil and tree->left->data.acc + val != val) {
                return this->find<true>(tree->left, val, offset);
            }
            else {
                return tree->data.val + val != val ? offset + tree->left->size : this->find<true>(tree->right, val, offset + tree->left->size + 1);
            }
        }
        else {
            if(tree->right != node_handler::nil and tree->right->data.acc + val != val) {
                return this->find<false>(tree->right, val, offset + tree->left->size + 1);
            }
            else {
                return tree->data.val + val != val ? offset + tree->left->size : this->find<false>(tree->left, val, offset);
            }
        }
    }

    template<bool LEFT>
    inline size_type find(node_pointer& tree, const size_type l, const size_type r, const operand& val) noexcept(NO_EXCEPT) {
        if(l == r) return -1;

        node_pointer t0, t1, t2;

        this->split(tree, l, r, t0, t1, t2);

        const size_type res = this->find<LEFT>(t1, val, l);

        this->merge(tree, t0, t1, t2);

        return res;
    }
};



} // namespace dynamic_tree_impl

} // namespace internal


template<class ActionOrValue, class Context = treap_context<>>
    requires internal::available_with<internal::dynamic_tree_impl::sequence_core, ActionOrValue, Context>
struct dynamic_sequence
  : private internal::dumpable_tree<
        dynamic_sequence<ActionOrValue, Context>,
        internal::dynamic_tree_impl::sequence_core<ActionOrValue, Context>,
        Context::LEAF_ONLY
    >
{
  private:
    using sequence_core = internal::dynamic_tree_impl::sequence_core<ActionOrValue, Context>;

    template<class T>
    static consteval auto _to_operator() {
        if constexpr(requires { typename T::value_type; }) return typename T::value_type{};
        else return T{};
    }

  public:
    using operand = typename sequence_core::operand;
    using operation = typename sequence_core::operation;

    using value_type = operand;
    using operator_type = decltype(_to_operator<operation>());

    using node_handler = typename sequence_core::node_handler;
    using allocator_type = typename sequence_core::allocator_type;

    using node_type = typename sequence_core::node_type;
    using node_pointer = typename sequence_core::node_pointer;

    using size_type = typename sequence_core::size_type;

  private:
    using dumper = internal::dumpable_tree<dynamic_sequence, sequence_core, Context::LEAF_ONLY>;
    friend dumper;

    sequence_core _impl;

    node_pointer _root = node_handler::nil;

    size_type _offset = 0;


    template<std::same_as<size_type>... SizeTypes>
    inline void _normalize_index(SizeTypes&... indices) noexcept(NO_EXCEPT) {
        const auto min_index = std::min({ indices... });
        ((indices -= this->_offset), ...);
        if(min_index < this->_offset) this->_offset = min_index;
    }


  public:
    ~dynamic_sequence() { this->_impl.dispose(this->_root); }

    dynamic_sequence(const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT) : _impl(allocator) {};

    dynamic_sequence(const node_pointer& root, const size_type offset = 0, const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT)
      : _impl(allocator), _root(root), _offset(offset)
    {};

    template<std::input_iterator I, std::sized_sentinel_for<I> S>
    dynamic_sequence(I first, S last, const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT)
      : _impl(allocator)
    {
        this->assign(first, last);
    }


    explicit dynamic_sequence(const size_type size, const value_type& val, const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT)
      : _impl(allocator)
    {
        this->assign(size, val);
    }

    explicit dynamic_sequence(const size_type size, const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT)
      : dynamic_sequence(size, value_type{}, allocator)
    {}

    template<std::ranges::input_range R>
        requires (!std::same_as<std::remove_cvref_t<R>, dynamic_sequence>)
    explicit dynamic_sequence(R&& range, const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT)
      : dynamic_sequence(ALL(range), allocator)
    {}

    template<std::convertible_to<value_type> T>
    dynamic_sequence(const std::initializer_list<T>& values, const allocator_type& allocator = allocator_type()) noexcept(NO_EXCEPT)
      : dynamic_sequence(values, allocator)
    {}

    inline auto offset() const noexcept(NO_EXCEPT) { return this->_offset; }

    inline auto& root() noexcept(NO_EXCEPT) { return this->_root; }
    inline const auto& root() const noexcept(NO_EXCEPT) { return this->_root; }

    inline auto size() const noexcept(NO_EXCEPT) { return this->_root->size; }

    inline bool empty() const noexcept(NO_EXCEPT) { return this->size() == 0; }


    template<internal::resizable_range Container>
    inline auto to() noexcept(NO_EXCEPT) {
        Container res;
        res.resize(this->size());

        auto itr = std::ranges::begin(res);
        this->_impl.enumerate(this->_root, itr);

        return res;
    }


    inline void clear() noexcept(NO_EXCEPT) {
        this->_impl.dispose(this->_root);
        this->_root = node_handler::nil;
        this->_offset = 0;
    }


    inline auto clone() const noexcept { return *this; }

    inline auto clone(size_type l, size_type r) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        node_pointer t0, t1, t2;
        this->_impl.split(this->_root, l, r, t0, t1, t2);
        this->_impl.merge(this->_root, t0, t1, t2);
        return dynamic_sequence(t1, this->_offset);
    }

    inline auto split(size_type pos) noexcept(NO_EXCEPT) {
        this->_normalize_index(pos);
        node_pointer t0, t1;
        this->_impl.split(this->_root, pos, t0, t1);
        return std::make_pair(dynamic_sequence(t0, this->_offset), dynamic_sequence(t1, this->_offset));
    }

    inline auto extract(size_type l, size_type r) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        node_pointer t0, t1, t2;
        this->_impl.split(this->_root, l, r, t0, t1, t2);
        this->_impl.merge(this->_root, t0, t2);
        return dynamic_sequence(t1, this->_offset);
    }

    inline auto& insert(size_type pos, const dynamic_sequence& other) noexcept(NO_EXCEPT) {
        this->_normalize_index(pos);
        node_pointer t0, t1;
        this->_impl.split(this->_root, pos, t0, t1);
        this->_impl.merge(this->_root, t0, other._root, t1);
        return *this;
    }

    inline auto& replace(size_type l, size_type r, const dynamic_sequence& other) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        node_pointer t0, t1, t2;
        this->_impl.split(this->_root, l, r, t0, t1, t2);
        this->_impl.merge(this->_root, t0, other._root, t2);
        return *this;
    }

    inline auto& merge(const dynamic_sequence& other) noexcept(NO_EXCEPT) {
        this->_impl.merge(this->_root, this->_root, other._root);
        return *this;
    }


    template<std::input_iterator I, std::sized_sentinel_for<I> S>
    inline auto& assign(I first, S last) noexcept(NO_EXCEPT) {
        this->clear();
        this->_root = this->_impl.build(first, last);
        return *this;
    }

    inline auto& assign(const size_type size, const value_type& val = value_type{}) noexcept(NO_EXCEPT) {
        this->clear();
        this->_impl.insert(this->_root, 0, val, size);
        return *this;
    }

    template<std::ranges::input_range R>
    inline auto& assign(R&& range) noexcept(NO_EXCEPT) {
        return this->assign(ALL(range));
    }

    template<std::convertible_to<value_type> T>
    inline auto& assign(const std::initializer_list<T>& values) noexcept(NO_EXCEPT) {
        return this->assign(values);
    }


    inline auto& resize(const size_type size, const value_type& val = value_type{}) noexcept(NO_EXCEPT) {
        if(this->size() > size) this->_impl.erase(this->_root, size, this->size());
        if(this->size() < size) this->push_back(val, size - this->size());
        return *this;
    }


    inline auto& expand(size_type l, size_type r) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        node_pointer t0, t1, t2;
        this->_impl.split(this->_root, l, r, t0, t1, t2);
        this->_impl.merge(this->_root, t0, t1, t2);
        return *this;
    }

    inline auto& expand(size_type pos) noexcept(NO_EXCEPT) {
        this->_normalize_index(pos);
        node_pointer t0, t1;
        this->_impl.split(this->_root, pos, t0, t1);
        this->_impl.merge(this->_root, t0, t1);
        return *this;
    }


    inline auto& fill(const value_type& val) noexcept(NO_EXCEPT) {
        this->_impl.fill(this->_root, 0, this->size(), val);
        return *this;
    }

    inline auto fold() noexcept(NO_EXCEPT) {
        return this->_impl.val(this->_root);
    }

    inline auto& apply(const operator_type& val) noexcept(NO_EXCEPT) {
        this->_root->data.lazy = this->_root->data.lazy + val;
        this->update(this->_root);
        return *this;
    }

    inline auto front() noexcept(NO_EXCEPT) {
        return this->_impl.fold(this->_root, 0, 1);
    }

    inline auto back() noexcept(NO_EXCEPT) {
        return this->_impl.fold(this->_root, this->size() - 1, this->size());
    }


    inline auto& push_front(const value_type& val, const size_type count = 1) noexcept(NO_EXCEPT) {
        this->_impl.insert(this->_root, 0, val, count);
        return *this;
    }

    inline auto& push_back(const value_type& val, const size_type count = 1) noexcept(NO_EXCEPT) {
        this->_impl.insert(this->_root, this->size(), val, count);
        return *this;
    }

    inline auto& reverse() noexcept(NO_EXCEPT) {
        this->_root->data.rev ^= 1;
        this->_impl.update(this->_root);
        return *this;
    }

    inline auto& shift_left(const size_type count = 1) noexcept(NO_EXCEPT) {
        this->_impl.shift_left(this->_root, 0, this->size(), count);
        return *this;
    }

    inline auto& shift_right(const size_type count = 1) noexcept(NO_EXCEPT) {
        this->_impl.shift_right(this->_root, 0, this->size(), count);
        return *this;
    }

    // Same usage as: std::rotate(:m:)
    inline auto& rotate(size_type m) noexcept(NO_EXCEPT) {
        this->_normalize_index(m);
        this->_impl.rotate(this->_root, 0, m, this->size());
        return *this;
    }

    // Same usage as: std::rotate(:m:)
    inline auto& rotate_left(const size_type count = 1) noexcept(NO_EXCEPT) {
        assert(!this->empty());
        this->_impl.rotate(this->_root, 0, uni::mod(count, this->size()), this->size());
        return *this;
    }

    // Same usage as: std::rotate(:m:)
    inline auto& rotate_right(const size_type count = 1) noexcept(NO_EXCEPT) {
        assert(!this->empty());
        this->_impl.rotate(this->_root, 0, uni::mod(-count, this->size()), this->size());
        return *this;
    }


    template<std::input_iterator I, std::sized_sentinel_for<I> S>
    inline auto& insert(size_type pos, I first, S last) noexcept(NO_EXCEPT) {
        this->_normalize_index(pos);
        this->_impl.insert(this->_root, pos, first, last);
        return *this;
    }

    inline auto& insert(size_type pos, const operand& val, const size_type count = 1) noexcept(NO_EXCEPT) {
        this->_normalize_index(pos);
        this->_impl.insert(this->_root, pos, val, count);
        return *this;
    }

    inline auto& erase(size_type l, size_type r) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        this->_impl.erase(this->_root, l, r);
        return *this;
    }

    inline auto& erase(const size_type pos) noexcept(NO_EXCEPT) {
        return this->erase(pos, pos + 1);
    }

    inline auto pop(size_type pos, const size_type count = 1) noexcept(NO_EXCEPT) {
        this->_normalize_index(pos);
        return this->_impl.pop(this->_root, pos, count);
    }

    inline auto get(size_type pos) noexcept(NO_EXCEPT) {
        this->_normalize_index(pos);
        return this->_impl.get(this->_root, pos);
    }

    inline auto& add(size_type pos, const value_type& val) noexcept(NO_EXCEPT) {
        this->_normalize_index(pos);
        this->_impl.add(this->_root, pos, val);
        return *this;
    }

    inline auto& fill(size_type l, size_type r, const value_type& val) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        this->_impl.fill(this->_root, l, r, val);
        return *this;
    }

    inline auto fold(size_type l, size_type r) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        return this->_impl.fold(this->_root, l, r);
    }

    inline auto& apply(size_type l, size_type r, const operation& val) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        this->_impl.apply(this->_root, l, r, val);
        return *this;
    }

    inline auto& reverse(size_type l, size_type r) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        this->_impl.reverse(this->_root, l, r);
        return *this;
    }

    inline auto& rotate(size_type l, size_type m, size_type r) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, m, r);
        this->_impl.rotate(this->_root, l, m, r);
        return *this;
    }

    inline auto& shift_left(size_type l, size_type r, const size_type count = 1) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        this->_impl.shift_left(this->_root, l, r, count);
        return *this;
    }

    inline auto& shift_right(size_type l, size_type r, const size_type count = 1) noexcept(NO_EXCEPT) {
        this->_normalize_index(l, r);
        this->_impl.shift_right(this->_root, l, r, count);
        return *this;
    }

    inline auto pop_front(const size_type count = 1) noexcept(NO_EXCEPT) {
        return this->_impl.pop(this->_root, 0, count);
    }

    inline auto pop_back(const size_type count = 1) noexcept(NO_EXCEPT) {
        return this->_impl.pop(this->_root, this->size() - count, count);
    }


    template<std::ranges::input_range R>
        requires (!std::same_as<std::remove_cvref_t<R>, dynamic_sequence>)
    inline auto& insert(const size_type pos, R&& range) noexcept(NO_EXCEPT) {
        return this->insert(pos, ALL(range));
    }


    inline auto& set(const size_type pos, const value_type& val) noexcept(NO_EXCEPT) {
        return this->fill(pos, pos + 1, val);
    }


    inline auto& apply(const size_type pos, const operator_type& val) noexcept(NO_EXCEPT) {
        return this->apply(pos, pos + 1, val);
    }


    inline auto& rotate_left(const size_type l, const size_type r, const size_type count = 1) noexcept(NO_EXCEPT) {
        assert(l < r);
        return this->rotate(l, l + uni::mod(count, r - l), r);
    }

    inline auto& rotate_right(const size_type l, const size_type r, const size_type count = 1) noexcept(NO_EXCEPT) {
        assert(l < r);
        return this->rotate(l, l + uni::mod(-count, r - l), r);
    }


    // Find the min / max k in [l, r) that satisfies (this[k] + x) != x.
    // If no such k is found, return -1.
    template<bool LEFT = true>
    inline auto find(const size_type l, const size_type r, const value_type& val) noexcept(NO_EXCEPT) {
        return this->template find<LEFT>(l, r - 1, r);
    }

    // Find the min / max k in whole that satisfies (this[k] + x) != x.
    // If no such k is found, return -1.
    template<bool LEFT = true>
    inline auto find(const value_type& val) noexcept(NO_EXCEPT) {
        return this->find<LEFT>(0, this->size(), val);
    }


    struct point_reference : internal::point_reference<dynamic_sequence, size_type> {
        point_reference(dynamic_sequence *const super, const size_type pos) noexcept(NO_EXCEPT)
          : internal::point_reference<dynamic_sequence, size_type>(super, pos)
        {}

        operator value_type() noexcept(NO_EXCEPT) { return this->_super->get(this->_pos); }
        auto val() noexcept(NO_EXCEPT) { return this->_super->get(this->_pos); }


        inline auto& operator=(const value_type& val) noexcept(NO_EXCEPT) {
            this->_super->set(this->_pos, val);
            return *this;
        }

        inline auto& operator+=(const value_type& val) noexcept(NO_EXCEPT) {
            this->_super->add(this->_pos, val);
            return *this;
        }

        inline auto& operator*=(const operator_type& val) noexcept(NO_EXCEPT) {
            this->_super->apply(this->_pos, val);
            return *this;
        }
    };


    struct range_reference : internal::range_reference<dynamic_sequence, size_type> {
        range_reference(dynamic_sequence *const super, const size_type l, const size_type r) noexcept(NO_EXCEPT)
          : internal::range_reference<dynamic_sequence, size_type>(super, l, r)
        {}

        inline auto clone() noexcept(NO_EXCEPT) {
            return this->_super->clone(this->_begin, this->_end);
        }

        inline auto fold() noexcept(NO_EXCEPT) {
            return this->_super->fold(this->_begin, this->_end);
        }

        inline auto& operator=(const value_type& val) noexcept(NO_EXCEPT) {
            this->_super->fill(this->_begin, this->_end, val);
            return *this;
        }

        inline auto& operator*=(const operator_type& val) noexcept(NO_EXCEPT) {
            this->_super->apply(this->_begin, this->_end, val);
            return *this;
        }

        // Find the min / max k in [l, r) that satisfies (this[k] + x) != x.
        // If no such k is found, return -1.
        template<bool LEFT = true>
        inline auto find(const value_type& val) noexcept(NO_EXCEPT) {
            return this->_super->template find<LEFT>(this->_begin, this->_end, val);
        }
    };


    inline auto operator[](const size_type pos) noexcept(NO_EXCEPT) { return point_reference(this, pos); }
    inline auto operator()(const size_type l, const size_type r) noexcept(NO_EXCEPT) { return range_reference(this, l, r); }


    struct iterator;

  protected:
    using iterator_interface = internal::container_iterator_interface<value_type, dynamic_sequence, iterator>;

  public:
    struct iterator : iterator_interface {
        using iterator_interface::iterator_interface;
    };

    inline auto begin() noexcept(NO_EXCEPT) { return iterator(this, 0); }
    inline auto end() noexcept(NO_EXCEPT) { return iterator(this, this->size()); }

    inline auto rbegin() noexcept(NO_EXCEPT) { return std::make_reverse_iterator(this->end()); }
    inline auto rend() noexcept(NO_EXCEPT) { return std::make_reverse_iterator(this->begin()); }

    inline auto traverse() const noexcept(NO_EXCEPT) { return typename sequence_core::traverser(this->_root); }


    using dumper::dump_rich;
    using dumper::_debug;


    debugger::debug_t dump_rich(const std::string prefix = "   ") {
        return "\n" + this->dump_rich(this->_root, prefix);
    }


    debugger::debug_t _debug() {
        return "[ " + this->_debug(this->_root) + " ]";
    }

};


} // namespace uni
#line 2 "action/range_sum.hpp"


#line 6 "action/range_sum.hpp"

#line 8 "action/range_sum.hpp"


namespace uni {

namespace actions {


template<class T>
using range_sum = make_operatable_t<uni::algebraic::addition<T>>;

static_assert(internal::operand_only_action<range_sum<int>>);


} // namespace actions

} // namespace uni
#line 20 "verify/yosupo-judge/range_reverse_range_sum/0000.test.cpp"

uni::i32 main() {
    uni::i32 n, q; input >> n >> q;
    uni::valarray<uni::i64> a(n); input >> a;
    uni::dynamic_sequence<uni::actions::make_full_t<uni::actions::range_sum<uni::i64>>> data(a);

    REP(q) {
        uni::i32 t, l, r; input >> t >> l >> r;
        if(t == 0) {
            data.reverse(l, r);
        }
        if(t == 1) {
            print(data(l, r).fold());
        }
    }
}
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