結果
問題 | No.786 京都大学の過去問 |
ユーザー | taotao54321 |
提出日時 | 2019-08-17 01:47:39 |
言語 | C++17 (gcc 12.3.0 + boost 1.83.0) |
結果 |
AC
|
実行時間 | 2 ms / 2,000 ms |
コード長 | 21,988 bytes |
コンパイル時間 | 2,073 ms |
コンパイル使用メモリ | 206,516 KB |
実行使用メモリ | 6,944 KB |
最終ジャッジ日時 | 2024-09-24 18:05:19 |
合計ジャッジ時間 | 2,503 ms |
ジャッジサーバーID (参考情報) |
judge1 / judge4 |
(要ログイン)
テストケース
テストケース表示入力 | 結果 | 実行時間 実行使用メモリ |
---|---|---|
testcase_00 | AC | 2 ms
6,816 KB |
testcase_01 | AC | 2 ms
6,940 KB |
testcase_02 | AC | 2 ms
6,940 KB |
testcase_03 | AC | 2 ms
6,944 KB |
testcase_04 | AC | 2 ms
6,940 KB |
ソースコード
/** * */ // header {{{ #include <bits/stdc++.h> using namespace std; #define CPP_STR(x) CPP_STR_I(x) #define CPP_CAT(x,y) CPP_CAT_I(x,y) #define CPP_STR_I(args...) #args #define CPP_CAT_I(x,y) x ## y #define SFINAE(pred...) std::enable_if_t<(pred), std::nullptr_t> = nullptr #define ASSERT(expr...) assert((expr)) using i8 = int8_t; using u8 = uint8_t; using i16 = int16_t; using u16 = uint16_t; using i32 = int32_t; using u32 = uint32_t; using i64 = int64_t; using u64 = uint64_t; using f32 = float; using f64 = double; using f80 = __float80; // }}} constexpr i64 INF = INT64_C(1'010'000'000'000'000'017); constexpr f64 FINF = 1e100; constexpr i64 MOD = INT64_C(1'000'000'007); constexpr f64 EPS = 1e-12; constexpr f64 PI = 3.14159265358979323846; // util {{{ #define FOR(i, start, end) for(i64 i = (start), CPP_CAT(i,xxxx_end)=(end); i < CPP_CAT(i,xxxx_end); ++i) #define REP(i, n) FOR(i, 0, n) #define ALL(f,c,...) (([&](decltype((c)) cccc) { return (f)(std::begin(cccc), std::end(cccc), ## __VA_ARGS__); })(c)) #define LIFT(f) ([](auto&&... args) -> decltype(auto) { return (f)(std::forward<decltype(args)>(args)...); }) template<typename C> constexpr i64 SIZE(const C& c) noexcept { return static_cast<i64>(c.size()); } template<typename T, size_t N> constexpr i64 SIZE(const T (&)[N]) noexcept { return static_cast<i64>(N); } template<typename T, typename U, typename Comp=less<>> constexpr bool chmax(T& xmax, const U& x, Comp comp={}) noexcept { if(comp(xmax, x)) { xmax = x; return true; } return false; } template<typename T, typename U, typename Comp=less<>> constexpr bool chmin(T& xmin, const U& x, Comp comp={}) noexcept { if(comp(x, xmin)) { xmin = x; return true; } return false; } template<typename BinaryFunc, typename UnaryFunc> auto ON(BinaryFunc&& bf, UnaryFunc&& uf) { return [bf=forward<BinaryFunc>(bf),uf=forward<UnaryFunc>(uf)](const auto& x, const auto& y) { return bf(uf(x), uf(y)); }; } template<typename F> auto LT_ON(F&& f) { return ON(less<>{}, forward<F>(f)); } template<typename F> auto GT_ON(F&& f) { return ON(greater<>{}, forward<F>(f)); } template<typename F> auto EQ_ON(F&& f) { return ON(equal_to<>{}, forward<F>(f)); } template<typename F> auto NE_ON(F&& f) { return ON(not_equal_to<>{}, forward<F>(f)); } // tuple {{{ template<i64 I=0, typename F, typename... TS, SFINAE(sizeof...(TS) == I)> void tuple_enumerate(tuple<TS...>&, F&&) {} template<i64 I=0, typename F, typename... TS, SFINAE(sizeof...(TS) > I)> void tuple_enumerate(tuple<TS...>& t, F&& f) { f(I, get<I>(t)); tuple_enumerate<I+1>(t, forward<F>(f)); } template<i64 I=0, typename F, typename... TS, SFINAE(sizeof...(TS) == I)> void tuple_enumerate(const tuple<TS...>&, F&&) {} template<i64 I=0, typename F, typename... TS, SFINAE(sizeof...(TS) > I)> void tuple_enumerate(const tuple<TS...>& t, F&& f) { f(I, get<I>(t)); tuple_enumerate<I+1>(t, forward<F>(f)); } // }}} // container {{{ template<typename T> struct is_container : false_type {}; template<typename T, size_t N> struct is_container<array<T,N>> : true_type {}; template<typename... Args> struct is_container<vector<Args...>> : true_type {}; template<typename... Args> struct is_container<deque<Args...>> : true_type {}; template<typename... Args> struct is_container<list<Args...>> : true_type {}; template<typename... Args> struct is_container<forward_list<Args...>> : true_type {}; template<typename... Args> struct is_container<set<Args...>> : true_type {}; template<typename... Args> struct is_container<multiset<Args...>> : true_type {}; template<typename... Args> struct is_container<unordered_set<Args...>> : true_type {}; template<typename... Args> struct is_container<unordered_multiset<Args...>> : true_type {}; template<typename... Args> struct is_container<map<Args...>> : true_type {}; template<typename... Args> struct is_container<multimap<Args...>> : true_type {}; template<typename... Args> struct is_container<unordered_map<Args...>> : true_type {}; template<typename... Args> struct is_container<unordered_multimap<Args...>> : true_type {}; template<typename T, typename Enable=void> struct ProconHash { size_t operator()(const T& x) const noexcept { return hash<T>{}(x); } }; template<typename T> size_t procon_hash_value(const T& x) noexcept { return ProconHash<T>{}(x); } size_t procon_hash_combine(size_t h1, size_t h2) noexcept { constexpr size_t M = UINT64_C(0xc6a4a7935bd1e995); constexpr int R = 47; h2 *= M; h2 ^= h2 >> R; h2 *= M; h1 ^= h2; h1 *= M; h1 += 0xe6546b64; return h1; } template<typename T1, typename T2> struct ProconHash<pair<T1,T2>> { size_t operator()(const pair<T1,T2>& p) const noexcept { size_t h1 = procon_hash_value(p.first); size_t h2 = procon_hash_value(p.second); return procon_hash_combine(h1, h2); } }; template<typename... TS> struct ProconHash<tuple<TS...>> { size_t operator()(const tuple<TS...>& t) const noexcept { size_t h = 0; tuple_enumerate(t, [&h](const auto& e) { h = procon_hash_combine(h, procon_hash_value(e)); }); return h; } }; template<typename C> struct ProconHash<C,enable_if_t<is_container<C>::value>> { size_t operator()(const C& c) const noexcept { size_t h = 0; for(const auto& e : c) h = procon_hash_combine(h, procon_hash_value(e)); return h; } }; template<typename T, typename Hash=ProconHash<T>, typename Eq=equal_to<T>> using HashSet = unordered_set<T,Hash,Eq>; template<typename K, typename V, typename Hash=ProconHash<K>, typename Eq=equal_to<K>> using HashMap = unordered_map<K,V,Hash,Eq>; template<typename T, typename Hash=ProconHash<T>, typename Eq=equal_to<T>> using HashMultiset = unordered_multiset<T,Hash,Eq>; template<typename K, typename V, typename Hash=ProconHash<K>, typename Eq=equal_to<K>> using HashMultimap = unordered_multimap<K,V,Hash,Eq>; template<typename T> auto vec_make(i64 n, T x) { return vector<T>(n, x); } template<typename T, typename... Args, SFINAE(sizeof...(Args) >= 2)> auto vec_make(i64 n, Args... args) { auto inner = vec_make<T>(args...); return vector<decltype(inner)>(n, inner); } template<typename T> auto vec_reserve(i64 cap) { vector<T> res; res.reserve(cap); return res; } template<typename T=i64> auto vec_iota(i64 n, T init={}) { vector<i64> res(n); ALL(iota, res, init); return res; } template<typename T, typename Comp, typename Cont=vector<T>> auto priority_queue_make(const Comp& comp, Cont&& cont={}) { return priority_queue<T,remove_reference_t<Cont>,Comp>(comp, forward<Cont>(cont)); } template<typename T, typename Comp> auto priority_queue_reserve(const Comp& comp, i64 cap) { return priority_queue<T,vector<T>,Comp>(comp, vec_reserve<T>(cap)); } template<typename T, size_t N, size_t... NS> struct ArrayType { using type = array<typename ArrayType<T,NS...>::type,N>; }; template<typename T, size_t N> struct ArrayType<T,N> { using type = array<T,N>; }; template<typename T, size_t... NS> using Array = typename ArrayType<T,NS...>::type; template<typename T, size_t N> T& array_at(Array<T,N>& ary, i64 i) { return ary[i]; } template<typename T, size_t N, size_t... NS, typename... Args> T& array_at(Array<T,N,NS...>& ary, i64 i, Args... args) { return array_at<T,NS...>(ary[i], args...); } template<typename T, size_t N> const T& array_at(const Array<T,N>& ary, i64 i) { return ary[i]; } template<typename T, size_t N, size_t... NS, typename... Args> const T& array_at(const Array<T,N,NS...>& ary, i64 i, Args... args) { return array_at<T,NS...>(ary[i], args...); } template<typename T, typename C> T POP(stack<T,C>& stk) { T x = stk.top(); stk.pop(); return x; } template<typename T, typename C> T POP(queue<T,C>& que) { T x = que.front(); que.pop(); return x; } template<typename T, typename C, typename Comp> T POP(priority_queue<T,C,Comp>& que) { T x = que.top(); que.pop(); return x; } // }}} // fixpoint {{{ template<typename F> class FixPoint { public: explicit constexpr FixPoint(F&& f) : f_(forward<F>(f)) {} template<typename... Args> constexpr decltype(auto) operator()(Args&&... args) const { return f_(*this, forward<Args>(args)...); } private: F f_; }; template<typename F> constexpr decltype(auto) FIX(F&& f) { return FixPoint<F>(forward<F>(f)); } template<typename F, size_t... NS> class FixPointMemo { public: explicit FixPointMemo(F&& f) : f_(forward<F>(f)) {} template<typename... Args> decltype(auto) operator()(Args... args) const { using R = decltype(f_(*this,args...)); static Array<bool,NS...> done {}; static Array<R,NS...> memo; if(!array_at<bool,NS...>(done,args...)) { array_at<R,NS...>(memo,args...) = f_(*this,args...); array_at<bool,NS...>(done,args...) = true; } return array_at<R,NS...>(memo,args...); } private: F f_; }; template<size_t... NS, typename F> decltype(auto) FIXMEMO(F&& f) { return FixPointMemo<F,NS...>(forward<F>(f)); } // }}} // string {{{ auto str_reserve(i64 cap) { string res; res.reserve(cap); return res; } // }}} // input {{{ template<typename T, typename Enable=void> struct Scan { static T scan(istream& in) { T res; in >> res; return res; } }; template<typename T, typename Enable=void> struct Scan1; template<typename T> struct Scan1<T,enable_if_t<is_integral<T>::value && !is_same<T,bool>::value>> { static T scan1(istream& in) { return Scan<T>::scan(in) - 1; } }; template<typename T1, typename T2> struct Scan<pair<T1,T2>> { static pair<T1,T2> scan(istream& in) { T1 x = Scan<T1>::scan(in); T2 y = Scan<T2>::scan(in); return {x,y}; } }; template<typename T1, typename T2> struct Scan1<pair<T1,T2>> { static pair<T1,T2> scan1(istream& in) { T1 x = Scan1<T1>::scan1(in); T2 y = Scan1<T2>::scan1(in); return {x,y}; } }; template<typename... TS> struct Scan<tuple<TS...>> { static tuple<TS...> scan(istream& in) { return scan_impl<0>(in); } private: template<i64 I, SFINAE(sizeof...(TS) == I)> static auto scan_impl(istream&) { return make_tuple(); } template<i64 I, SFINAE(sizeof...(TS) > I)> static auto scan_impl(istream& in) { using T = tuple_element_t<I,tuple<TS...>>; auto head = make_tuple(Scan<T>::scan(in)); return tuple_cat(head, scan_impl<I+1>(in)); } }; template<typename... TS> struct Scan1<tuple<TS...>> { static tuple<TS...> scan1(istream& in) { return scan1_impl<0>(in); } private: template<i64 I, SFINAE(sizeof...(TS) == I)> static auto scan1_impl(istream&) { return make_tuple(); } template<i64 I, SFINAE(sizeof...(TS) > I)> static auto scan1_impl(istream& in) { using T = tuple_element_t<I,tuple<TS...>>; auto head = make_tuple(Scan1<T>::scan1(in)); return tuple_cat(head, scan1_impl<I+1>(in)); } }; template<typename T=i64> T RD() { return Scan<T>::scan(cin); } template<typename T=i64> T RD1() { return Scan1<T>::scan1(cin); } template<typename T=i64> auto RD_VEC(i64 n) { auto res = vec_reserve<T>(n); REP(_, n) { res.emplace_back(RD<T>()); } return res; } template<typename T=i64> auto RD1_VEC(i64 n) { auto res = vec_reserve<T>(n); REP(_, n) { res.emplace_back(RD1<T>()); } return res; } template<typename T=i64> auto RD_VEC2(i64 h, i64 w) { auto res = vec_reserve<vector<T>>(h); REP(_, h) { res.emplace_back(RD_VEC<T>(w)); } return res; } template<typename T=i64> auto RD1_VEC2(i64 h, i64 w) { auto res = vec_reserve<vector<T>>(h); REP(_, h) { res.emplace_back(RD1_VEC<T>(w)); } return res; } // }}} // output {{{ template<typename T, typename Enable=void> struct Fmt { static void fmt(ostream& out, const T& x) { out << x; } }; template<typename T> void fmt_write(ostream& out, const T& x) { Fmt<T>::fmt(out, x); } template<typename... TS> struct Fmt<tuple<TS...>> { static void fmt(ostream& out, const tuple<TS...>& t) { tuple_enumerate(t, [&out](i64 i, const auto& e) { if(i != 0) out << ' '; fmt_write(out, e); }); } }; template<typename T1, typename T2> struct Fmt<pair<T1,T2>> { static void fmt(ostream& out, const pair<T1,T2>& p) { return fmt_write(out, make_tuple(p.first,p.second)); } }; template<typename C> struct Fmt<C,enable_if_t<is_container<C>::value>> { static void fmt(ostream& out, const C& c) { for(auto it = begin(c); it != end(c); ++it) { if(it != begin(c)) out << ' '; fmt_write(out, *it); } } }; void PRINT() {} template<typename T, typename... TS> void PRINT(const T& x, const TS&... args) { fmt_write(cout, x); if(sizeof...(args) > 0) { cout << ' '; PRINT(args...); } } template<typename... TS> void PRINTLN(const TS&... args) { PRINT(args...); cout << '\n'; } // }}} // debug {{{ template<typename T, typename Enable=void> struct Dbg { static void dbg(ostream& out, const T& x) { out << x; } }; template<typename T> void dbg_write(ostream& out, const T& x) { return Dbg<T>::dbg(out, x); } template<> struct Dbg<i64> { static void dbg(ostream& out, i64 x) { if(x == INF) out << "INF"; else if(x == -INF) out << "-INF"; else out << x; } }; template<> struct Dbg<f64> { static void dbg(ostream& out, f64 x) { #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wfloat-equal" if(x == FINF) out << "FINF"; else if(x == -FINF) out << "-FINF"; else out << x; #pragma GCC diagnostic pop } }; template<typename T, size_t N> struct Dbg<T[N]> { static void dbg(ostream& out, const T (&ary)[N]) { out << "["; REP(i, N) { if(i != 0) out << ","; dbg_write(out, ary[i]); } out << "]"; } }; template<typename... TS> struct Dbg<tuple<TS...>> { static void dbg(ostream& out, const tuple<TS...>& t) { out << "("; tuple_enumerate(t, [&out](i64 i, const auto& e) { if(i != 0) out << ","; dbg_write(out, e); }); out << ")"; } }; template<typename T1, typename T2> struct Dbg<pair<T1,T2>> { static void dbg(ostream& out, const pair<T1,T2>& p) { return dbg_write(out, make_tuple(p.first,p.second)); } }; template<typename C> struct Dbg<C,enable_if_t<is_container<C>::value>> { static void dbg(ostream& out, const C& c) { out << "["; for(auto it = begin(c); it != end(c); ++it) { if(it != begin(c)) out << ","; dbg_write(out, *it); } out << "]"; } }; template<typename T, typename C> struct Dbg<stack<T,C>> { static void dbg(ostream& out, stack<T,C> stk) { out << "["; while(!stk.empty()) { dbg_write(out,stk.top()); stk.pop(); if(!stk.empty()) out << ","; } out << "]"; } }; template<typename T, typename C> struct Dbg<queue<T,C>> { static void dbg(ostream& out, queue<T,C> que) { out << "["; while(!que.empty()) { dbg_write(out,que.front()); que.pop(); if(!que.empty()) out << ","; } out << "]"; } }; template<typename T, typename C, typename Comp> struct Dbg<priority_queue<T,C,Comp>> { static void dbg(ostream& out, priority_queue<T,C,Comp> que) { out << "["; while(!que.empty()) { dbg_write(out,que.top()); que.pop(); if(!que.empty()) out << ","; } out << "]"; } }; template<typename T> void DBG_IMPL(i64 line, const char* expr, const T& value) { cerr << "[L " << line << "]: "; cerr << expr << " = "; dbg_write(cerr, value); cerr << "\n"; } void DBG_IMPL_HELPER() {} template<typename T, typename... TS> void DBG_IMPL_HELPER(const T& x, const TS&... args) { dbg_write(cerr, x); if(sizeof...(args) > 0) { cerr << ","; DBG_IMPL_HELPER(args...); } } template<typename... TS> void DBG_IMPL(i64 line, const char* expr, const TS&... value) { cerr << "[L " << line << "]: "; cerr << "(" << expr << ") = ("; DBG_IMPL_HELPER(value...); cerr << ")\n"; } template<size_t N, typename T, SFINAE(rank<T>::value == 0)> void DBG_DP_IMPL_HELPER(ostream& out, const T& x, const array<i64,N>&, const array<i64,N>&) { dbg_write(out, x); } template<size_t N, typename T, SFINAE(rank<T>::value > 0)> void DBG_DP_IMPL_HELPER(ostream& out, const T& x, const array<i64,N>& sizes, const array<i64,N>& offs) { i64 k = N - rank<T>::value; i64 off = offs[k]; i64 siz = sizes[k]; if(siz == 0) siz = extent<T>::value - off; out << "["; FOR(i, off, off+siz) { if(i != off) out << ","; DBG_DP_IMPL_HELPER(out, x[i], sizes, offs); } out << "]"; } template<typename T, SFINAE(rank<T>::value > 0)> void DBG_DP_IMPL(i64 line, const char* expr, const T& dp, const array<i64,rank<T>::value>& sizes={}, const array<i64,rank<T>::value>& offs={}) { cerr << "[L " << line << "]: "; cerr << expr << " = "; DBG_DP_IMPL_HELPER<rank<T>::value>(cerr, dp, sizes, offs); cerr << "\n"; } template<typename T> void DBG_GRID_IMPL(i64 line, const char* expr, const vector<T>& grid) { cerr << "[L " << line << "]: "; cerr << expr << ":\n"; for(const auto& row : grid) { dbg_write(cerr, row); cerr << "\n"; } cerr << "\n"; } #ifdef PROCON_LOCAL #define DBG(args...) DBG_IMPL(__LINE__, CPP_STR_I(args), args) #define DBG_DP(args...) DBG_DP_IMPL(__LINE__, CPP_STR_I(args), args) #define DBG_GRID(args...) DBG_GRID_IMPL(__LINE__, CPP_STR_I(args), args) #else #define DBG(args...) #define DBG_DP(args...) #define DBG_GRID(args...) #endif // }}} // modint {{{ template<i64 M> struct ModIntT { static_assert(M >= 2, ""); i64 v_; // [0,M) ModIntT() : v_(0) {} ModIntT(i64 v) { i64 r = v % M; v_ = r >= 0 ? r : r+M; } ModIntT operator-() const { return ModIntT(-v_); } ModIntT& operator+=(ModIntT rhs) { v_ += rhs.v_; v_ %= M; return *this; } ModIntT& operator-=(ModIntT rhs) { v_ += M; v_ -= rhs.v_; v_ %= M; return *this; } ModIntT& operator*=(ModIntT rhs) { v_ *= rhs.v_; v_ %= M; return *this; } ModIntT& operator++() { return *this += 1; } ModIntT& operator--() { return *this -= 1; } ModIntT operator++(int) { return exchange(*this, *this+1); } ModIntT operator--(int) { return exchange(*this, *this-1); } explicit operator i64() const { return v_; } }; template<i64 M> ModIntT<M> operator+(ModIntT<M> lhs, ModIntT<M> rhs) { return ModIntT<M>(lhs) += rhs; } template<i64 M> ModIntT<M> operator+(ModIntT<M> lhs, i64 rhs) { return ModIntT<M>(lhs) += rhs; } template<i64 M> ModIntT<M> operator+(i64 lhs, ModIntT<M> rhs) { return ModIntT<M>(rhs) += lhs; } template<i64 M> ModIntT<M> operator-(ModIntT<M> lhs, ModIntT<M> rhs) { return ModIntT<M>(lhs) -= rhs; } template<i64 M> ModIntT<M> operator-(ModIntT<M> lhs, i64 rhs) { return ModIntT<M>(lhs) -= rhs; } template<i64 M> ModIntT<M> operator-(i64 lhs, ModIntT<M> rhs) { return ModIntT<M>(rhs) -= lhs; } template<i64 M> ModIntT<M> operator*(ModIntT<M> lhs, ModIntT<M> rhs) { return ModIntT<M>(lhs) *= rhs; } template<i64 M> ModIntT<M> operator*(ModIntT<M> lhs, i64 rhs) { return ModIntT<M>(lhs) *= rhs; } template<i64 M> ModIntT<M> operator*(i64 lhs, ModIntT<M> rhs) { return ModIntT<M>(rhs) *= lhs; } template<i64 M> bool operator==(ModIntT<M> lhs, ModIntT<M> rhs) { return lhs.v_ == rhs.v_; } template<i64 M> bool operator==(ModIntT<M> lhs, i64 rhs) { return lhs == ModIntT<M>(rhs); } template<i64 M> bool operator==(i64 lhs, ModIntT<M> rhs) { return ModIntT<M>(lhs) == rhs; } template<i64 M> bool operator!=(ModIntT<M> lhs, ModIntT<M> rhs) { return !(lhs == rhs); } template<i64 M> bool operator!=(ModIntT<M> lhs, i64 rhs) { return !(lhs == rhs); } template<i64 M> bool operator!=(i64 lhs, ModIntT<M> rhs) { return !(lhs == rhs); } template<i64 M> struct Scan<ModIntT<M>> { static ModIntT<M> scan(istream& in) { return Scan<i64>::scan(in); } }; template<i64 M> struct Fmt<ModIntT<M>> { static void fmt(ostream& out, ModIntT<M> x) { fmt_write(out, x.v_); } }; template<i64 M> struct Dbg<ModIntT<M>> { static void dbg(ostream& out, ModIntT<M> x) { dbg_write(out, x.v_); } }; using ModInt = ModIntT<MOD>; // }}} // }}} // init {{{ struct ProconInit { static constexpr int IOS_PREC = 15; static constexpr bool AUTOFLUSH = false; ProconInit() { cin.tie(nullptr); ios::sync_with_stdio(false); cin.exceptions(ios::failbit | ios::badbit); cout << fixed << setprecision(IOS_PREC); #ifdef PROCON_LOCAL cerr << fixed << setprecision(IOS_PREC); #endif if(AUTOFLUSH) cout << unitbuf; } } PROCON_INIT; // }}} //-------------------------------------------------------------------- void solve() { i64 N = RD(); auto f = FIXMEMO<51>([](auto&& self, i64 i) -> i64 { if(i == 0) return 1; i64 res = 0; res += self(i-1); if(i-2 >= 0) res += self(i-2); return res; }); i64 ans = f(N); PRINTLN(ans); } signed main() { solve(); return 0; }