結果
問題 | No.1860 Magnets |
ユーザー | risujiroh |
提出日時 | 2022-03-04 22:29:05 |
言語 | C++17 (gcc 12.3.0 + boost 1.83.0) |
結果 |
CE
(最新)
AC
(最初)
|
実行時間 | - |
コード長 | 30,884 bytes |
コンパイル時間 | 2,886 ms |
コンパイル使用メモリ | 299,808 KB |
最終ジャッジ日時 | 2024-11-15 02:10:07 |
合計ジャッジ時間 | 3,418 ms |
ジャッジサーバーID (参考情報) |
judge3 / judge4 |
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コンパイルエラー時のメッセージ・ソースコードは、提出者また管理者しか表示できないようにしております。(リジャッジ後のコンパイルエラーは公開されます)
ただし、clay言語の場合は開発者のデバッグのため、公開されます。
ただし、clay言語の場合は開発者のデバッグのため、公開されます。
コンパイルメッセージ
In file included from main.cpp:3: main.cpp:395:18: error: redefinition of default argument for 'char <anonymous>' 395 | template <char = 0> | ^ main.cpp:383:18: note: original definition appeared here 383 | template <char = 0> | ^
ソースコード
#if __INCLUDE_LEVEL__ == 0 #include __FILE__ void r7h::main(int) { i64 a, b; scan(a, b); if (b < a) { swap(a, b); } i64 ans = a + b; ans += max(b - a - 1, 0ll); println(ans); } #else #define MULTI_CASES 0 #define INTERACTIVE 0 #ifndef LOCAL #define LOCAL 0 #endif #if !LOCAL #define NDEBUG #endif #ifndef __GLIBCXX_TYPE_INT_N_0 #define __GLIBCXX_TYPE_INT_N_0 __int128 #endif #include <bits/stdc++.h> #include <unistd.h> #include <x86intrin.h> namespace r7h { using namespace std; void main(int); } // namespace r7h #if LOCAL #include <utility/dump.hpp> #else #define DUMP(...) void(0) #endif #define LIFT(FN) \ []<class... Ts_>(Ts_&&... xs_) -> decltype(auto) { return FN(static_cast<Ts_&&>(xs_)...); } #define LAMBDA(...) \ [&]<class T1_ = void*, class T2_ = void*>([[maybe_unused]] T1_&& _1 = nullptr, [[maybe_unused]] T2_&& _2 = nullptr) \ -> decltype(auto) { \ return __VA_ARGS__; \ } namespace r7h { template <class F> class fix : F { public: explicit fix(F f) : F(move(f)) {} template <class... Ts> decltype(auto) operator()(Ts&&... xs) const { return F::operator()(ref(*this), forward<Ts>(xs)...); } }; template <class T> decay_t<T> decay_copy(T&& x) { return forward<T>(x); } template <class T> auto ref_or_move(remove_reference_t<T>& x) { if constexpr (is_reference_v<T> && !is_placeholder_v<decay_t<T>>) { return ref(x); } else { return move(x); } } template <class T, class D = decay_t<T>> bool const is_lambda_expr = is_placeholder_v<D> || is_bind_expression_v<D>; #define UNARY_LAMBDA(OP) \ template <class T, enable_if_t<is_lambda_expr<T>>* = nullptr> \ auto operator OP(T&& x) { \ return bind([]<class T_>(T_&& x_) -> decltype(auto) { return OP forward<T_>(x_); }, ref_or_move<T>(x)); \ } #define BINARY_LAMBDA(OP) \ template <class T1, class T2, enable_if_t<is_lambda_expr<T1> || is_lambda_expr<T2>>* = nullptr> \ auto operator OP(T1&& x, T2&& y) { \ auto f = []<class T1_, class T2_>(T1_&& x_, T2_&& y_) -> decltype(auto) { \ return forward<T1_>(x_) OP forward<T2_>(y_); \ }; \ return bind(move(f), ref_or_move<T1>(x), ref_or_move<T2>(y)); \ } BINARY_LAMBDA(+=) BINARY_LAMBDA(-=) BINARY_LAMBDA(*=) BINARY_LAMBDA(/=) BINARY_LAMBDA(%=) BINARY_LAMBDA(&=) BINARY_LAMBDA(|=) BINARY_LAMBDA(^=) BINARY_LAMBDA(<<=) BINARY_LAMBDA(>>=) UNARY_LAMBDA(++) UNARY_LAMBDA(--) UNARY_LAMBDA(+) UNARY_LAMBDA(-) BINARY_LAMBDA(+) BINARY_LAMBDA(-) BINARY_LAMBDA(*) BINARY_LAMBDA(/) BINARY_LAMBDA(%) UNARY_LAMBDA(~) BINARY_LAMBDA(&) BINARY_LAMBDA(|) BINARY_LAMBDA(^) BINARY_LAMBDA(<<) BINARY_LAMBDA(>>) BINARY_LAMBDA(==) BINARY_LAMBDA(!=) BINARY_LAMBDA(<) BINARY_LAMBDA(>) BINARY_LAMBDA(<=) BINARY_LAMBDA(>=) UNARY_LAMBDA(!) BINARY_LAMBDA(&&) BINARY_LAMBDA(||) #undef UNARY_LAMBDA #undef BINARY_LAMBDA using namespace placeholders; using i8 = signed char; using u8 = unsigned char; using i16 = short; using u16 = unsigned short; using i32 = int; using u32 = unsigned; using i64 = long long; using u64 = unsigned long long; using i128 = __int128; using u128 = unsigned __int128; template <int> struct signed_int; template <int> struct unsigned_int; #define INT_TYPE(N) \ template <> struct signed_int<N> { using type = i##N; }; \ template <> struct unsigned_int<N> { using type = u##N; }; INT_TYPE(8) INT_TYPE(16) INT_TYPE(32) INT_TYPE(64) INT_TYPE(128) #undef INT_TYPE template <int N> using signed_int_t = typename signed_int<N>::type; template <int N> using unsigned_int_t = typename unsigned_int<N>::type; template <class T> auto operator++(T& x, int) -> decltype(++x, T(x)) { T ret = x; ++x; return ret; } template <class T> auto operator--(T& x, int) -> decltype(--x, T(x)) { T ret = x; --x; return ret; } #define BINARY_ARITH_OP(OP) \ template <class T1, class T2, class T = common_type_t<T1, T2>> \ auto operator OP(T1 const& x, T2 const& y) -> decltype(declval<T&>() OP##= y, T(x)) { \ T ret = T(x); \ ret OP##= y; \ return ret; \ } BINARY_ARITH_OP(+) BINARY_ARITH_OP(-) BINARY_ARITH_OP(*) BINARY_ARITH_OP(/) BINARY_ARITH_OP(%) BINARY_ARITH_OP(&) BINARY_ARITH_OP(|) BINARY_ARITH_OP(^) BINARY_ARITH_OP(<<) BINARY_ARITH_OP(>>) #undef BINARY_ARITH_OP #define COMPARISON_OP(OP, E) \ template <class T1, class T2> \ auto operator OP(T1 const& x, T2 const& y) -> decltype(E) { \ return E; \ } COMPARISON_OP(!=, !(x == y)) COMPARISON_OP(>, y < x) COMPARISON_OP(<=, !(y < x)) COMPARISON_OP(>=, !(x < y)) #undef COMPARISON_OP namespace scan_impl { #if INTERACTIVE || LOCAL bool scan(char& c) { return scanf(" %c", &c) != EOF; } bool scan(string& s) { char c; if (!scan(c)) { return false; } for (s = c;; s += c) { c = char(getchar()); if (c <= ' ') { ungetc(c, stdin); break; } } return true; } template <class T> enable_if_t<is_integral_v<T>, bool> scan(T& x) { char c; if (!scan(c)) { return false; } make_unsigned_t<decltype(+x)> u = (c == '-' ? getchar() : c) & 15; while (true) { if (int t = getchar(); '0' <= t && t <= '9') { (u *= 10) += t & 15; } else { ungetc(t, stdin); break; } } x = T(c == '-' ? -u : u); return true; } template <class T> enable_if_t<is_floating_point_v<T>, bool> scan(T& x) { return scanf(is_same_v<T, float> ? "%f" : is_same_v<T, double> ? "%lf" : "%Lf", &x) != EOF; } #else char buf[1 << 15]; char* ptr = buf; char* last = buf; bool scan(char& c) { for (;; ++ptr) { if (last - ptr < 64) { last = move(ptr, last, buf); ptr = buf; last += read(STDIN_FILENO, last, end(buf) - last - 1); *last = '\0'; } if (ptr == last) { return false; } if (' ' < *ptr) { c = *ptr++; return true; } } } bool scan(string& s) { char c; if (!scan(c)) { return false; } for (s = c; ' ' < *ptr; s += c) { scan(c); } return true; } template <class T> enable_if_t<is_integral_v<T>, bool> scan(T& x) { char c; if (!scan(c)) { return false; } make_unsigned_t<decltype(+x)> u = (c == '-' ? *ptr++ : c) & 15; while ('0' <= *ptr && *ptr <= '9') { (u *= 10) += *ptr++ & 15; } x = T(c == '-' ? -u : u); return true; } template <class T> enable_if_t<is_floating_point_v<T>, bool> scan(T& x) { char c; if (!scan(c)) { return false; } int n; sscanf(--ptr, is_same_v<T, float> ? "%f%n" : is_same_v<T, double> ? "%lf%n" : "%Lf%n", &x, &n); ptr += n; return true; } #endif template <class R> auto scan(R&& r) -> decltype(begin(r), end(r), true) { return all_of(begin(r), end(r), LIFT(scan)); } template <class... Ts> enable_if_t<sizeof...(Ts) != 1, bool> scan(Ts&&... xs) { return (... && scan(forward<Ts>(xs))); } } // namespace scan_impl using scan_impl::scan; namespace print_impl { #if INTERACTIVE || LOCAL template <char = 0> void print(char c) { if (c) { putchar(c); } if (c == '\n') { fflush(stdout); } } template <char = 0, class T> enable_if_t<is_integral_v<T>> print(T x) { char buf[64]; char* ptr = to_chars(buf, end(buf), +x).ptr; for_each(buf, ptr, LIFT(print)); } template <char = 0, class T> enable_if_t<is_floating_point_v<T>> print(T x) { printf(is_same_v<T, float> ? "%.6f" : is_same_v<T, double> ? "%.15f" : "%.18Lf", x); } #else char buf[1 << 15]; char* ptr = buf; __attribute__((destructor)) void flush() { if (write(STDOUT_FILENO, buf, ptr - buf) == -1) { abort(); } ptr = buf; } template <char = 0> void print(char c) { if (end(buf) - ptr < 64) { flush(); } if (c) { *ptr++ = c; } } template <char = 0, class T> enable_if_t<is_integral_v<T>> print(T x) { print('\0'); ptr = to_chars(ptr, end(buf), +x).ptr; } template <char = 0, class T> enable_if_t<is_floating_point_v<T>> print(T x) { print('\0'); ptr += snprintf(ptr, end(buf) - ptr, is_same_v<T, float> ? "%.6f" : is_same_v<T, double> ? "%.15f" : "%.18Lf", x); } #endif template <char = 0> void print(char const*); template <char Sep = ' ', class R> auto print(R&& r) -> void_t<decltype(begin(r), end(r))> { [[maybe_unused]] char c = '\0'; for (auto&& e : r) { if constexpr (!is_same_v<decay_t<decltype(e)>, char>) { print(exchange(c, Sep)); } print(e); } } template <char = 0> void print(char const* s) { print(string_view(s)); } template <char Sep = ' ', class... Ts> enable_if_t<sizeof...(Ts) != 1> print(Ts&&... xs) { [[maybe_unused]] char c = '\0'; (..., (print(exchange(c, Sep)), print(forward<Ts>(xs)))); } } // namespace print_impl using print_impl::print; template <char Sep = ' ', char End = '\n', class... Ts> void println(Ts&&... xs) { print<Sep>(forward<Ts>(xs)...); print(End); } template <class T, class N, class Op> T power1(T x, N n, Op op) { assert(1 <= n); for (; ~n & 1; n >>= 1) { x = op(x, x); } T ret = x; while (n >>= 1) { x = op(x, x); if (n & 1) { ret = op(move(ret), x); } } return ret; } template <class T, class N> T power(T x, N n) { if (n == 0) { return T{1}; } if (n < 0) { return T{1} / power1(move(x), -n, multiplies()); } return power1(move(x), n, multiplies()); } template <class T> T div_floor(T x, T y) { return T(x / y - ((x ^ y) < 0 && x % y)); } template <class T> T div_ceil(T x, T y) { return T(x / y + (0 <= (x ^ y) && x % y)); } template <class T, class U = T> bool chmin(T& x, U&& y) { return y < x ? x = forward<U>(y), true : false; } template <class T, class U = T> bool chmax(T& x, U&& y) { return x < y ? x = forward<U>(y), true : false; } template <class T> T const inf_v = numeric_limits<T>::max() / 2; int const inf = inf_v<int>; mt19937_64 mt(_rdtsc()); template <class T> T rand(T a, T b) { if constexpr (is_integral_v<T>) { return uniform_int_distribution(a, b)(mt); } else { return uniform_real_distribution(a, b)(mt); } } #define TC(...) template <class __VA_ARGS__> #define IIT input_iterator_tag #define FIT forward_iterator_tag #define BIT bidirectional_iterator_tag #define RAIT random_access_iterator_tag TC(D, class C, class R) class iter_base { D& derived() & { return static_cast<D&>(*this); } D const& derived() const& { return static_cast<D const&>(*this); } public: using iterator_category = C; using value_type = decay_t<R>; using difference_type = int; using pointer = void; using reference = R; #define REQUIRE(IT) TC(C_ = C, enable_if_t<is_convertible_v<C_, IT>>* = nullptr) R operator*() const { return derived().deref(); } REQUIRE(RAIT) R operator[](int n) const { return *(derived() + n); } D& operator++() & { derived().inc(); return derived(); } REQUIRE(BIT) D& operator--() & { derived().dec(); return derived(); } REQUIRE(RAIT) D& operator+=(int n) & { derived().advance(n); return derived(); } REQUIRE(RAIT) D& operator-=(int n) & { derived().advance(-n); return derived(); } REQUIRE(RAIT) friend D operator+(D const& x, int n) { D ret = x; ret += n; return ret; } REQUIRE(RAIT) friend D operator+(int n, D const& x) { return x + n; } REQUIRE(RAIT) friend D operator-(D const& x, int n) { D ret = x; ret -= n; return ret; } REQUIRE(RAIT) friend int operator-(D const& x, D const& y) { return y.dist_to(x); } friend bool operator==(D const& x, D const& y) { return x.equal(y); } REQUIRE(RAIT) friend bool operator<(D const& x, D const& y) { return x - y < 0; } #undef REQUIRE }; struct int_iter : iter_base<int_iter, RAIT, int> { int v; int_iter() = default; int_iter(int v) : v(v) {} int deref() const { return v; } bool equal(int_iter const& x) const { return v == x.v; } void inc() & { ++v; } void dec() & { --v; } void advance(int n) & { v += n; } int dist_to(int_iter const& x) const { return x.v - v; } }; template <class R> auto sz(R&& r) -> decltype(int(size(forward<R>(r)))) { return int(size(forward<R>(r))); } TC(R) using iter_t = decltype(begin(declval<R const&>())); TC(R) using range_cat = typename iterator_traits<iter_t<R>>::iterator_category; TC(R) using range_ref = typename iterator_traits<iter_t<R>>::reference; TC() class view_base; #define VIEW(CLS, ...) \ class CLS : public view_base<CLS<__VA_ARGS__>> { \ friend class CLS::view_base; #define VIEW_END(...) \ __VA_OPT__(int size() const { return __VA_ARGS__; }) \ }; TC(R, class F) VIEW(filtered, R, F) struct iter : iter_base<iter, common_type_t<range_cat<R>, BIT>, range_ref<R>> { filtered const* p; iter_t<R> i; range_ref<R> deref() const { return *i; } bool equal(iter const& x) const { return i == x.i; } void inc() & { do { ++i; } while (i != end(p->r) && !invoke(p->f, *i)); } void dec() & { do { --i; } while (!invoke(p->f, *i)); } }; R r; [[no_unique_address]] F f; iter b() const { return {{}, this, find_if(begin(r), end(r), ref(f))}; } iter e() const { return {{}, this, end(r)}; } public: explicit filtered(R&& r, F f) : r(forward<R>(r)), f(move(f)) {} VIEW_END() TC(R, class F) filtered(R&&, F) -> filtered<R, F>; TC(R, class F) VIEW(mapped, R, F) using ref = invoke_result_t<F const&, range_ref<R>>; struct iter : iter_base<iter, common_type_t<range_cat<R>, RAIT>, ref> { mapped const* p; iter_t<R> i; ref deref() const { return invoke(p->f, *i); } bool equal(iter const& x) const { return i == x.i; } void inc() & { ++i; } void dec() & { --i; } void advance(int n) & { i += n; } int dist_to(iter const& x) const { return int(x.i - i); } }; R r; [[no_unique_address]] F f; iter b() const { return {{}, this, begin(r)}; } iter e() const { return {{}, this, end(r)}; } public: explicit mapped(R&& r, F f) : r(forward<R>(r)), f(move(f)) {} VIEW_END(sz(r)) TC(R, class F) mapped(R&&, F) -> mapped<R, F>; TC(R) VIEW(taken, R) struct iter : iter_base<iter, common_type_t<range_cat<R>, FIT>, range_ref<R>> { iter_t<R> i; int n; range_ref<R> deref() const { return *i; } bool equal(iter const& x) const { return n == x.n; } void inc() & { --n; if (n) { ++i; } } }; R r; int n; auto b() const { if constexpr (is_convertible_v<range_cat<R>, RAIT>) { return begin(r); } else { return iter{{}, n ? begin(r) : end(r), n}; } } auto e() const { if constexpr (is_convertible_v<range_cat<R>, RAIT>) { return begin(r) + size(); } else { return iter{{}, end(r), 0}; } } public: explicit taken(R&& r, int n) : r(forward<R>(r)), n(max<int>(n, 0)) { assert(0 <= n); } VIEW_END(min(n, sz(r))) TC(R) taken(R&&, int) -> taken<R>; TC(R, class F) VIEW(taken_while, R, F) static_assert(is_convertible_v<range_cat<R>, FIT>); struct iter : iter_base<iter, common_type_t<range_cat<R>, FIT>, range_ref<R>> { taken_while const* p; iter_t<R> i; range_ref<R> deref() const { return *i; } bool equal(iter const& x) const { return i == x.i; } void inc() & { ++i; if (i != end(p->r) && !invoke(p->f, *i)) { i = end(p->r); } } }; R r; [[no_unique_address]] F f; iter b() const { return {{}, this, begin(r) == end(r) || !invoke(f, *begin(r)) ? end(r) : begin(r)}; } iter e() const { return {{}, this, end(r)}; } public: explicit taken_while(R&& r, F f) : r(forward<R>(r)), f(move(f)) {} VIEW_END() TC(R, class F) taken_while(R&&, F) -> taken_while<R, F>; TC(R) VIEW(dropped, R) R r; int n; auto b() const { if constexpr (is_convertible_v<range_cat<R>, RAIT>) { return begin(r) + min(n, sz(r)); } else { auto ret = begin(r); for (int t = n; t-- && ret != end(r);) { ++ret; } return ret; } } auto e() const { return end(r); } public: explicit dropped(R&& r, int n) : r(forward<R>(r)), n(max<int>(n, 0)) { assert(0 <= n); } VIEW_END(max(sz(r), n) - n) TC(R) dropped(R&&, int) -> dropped<R>; TC(R, class F) VIEW(dropped_while, R, F) R r; [[no_unique_address]] F f; auto b() const { return find_if_not(begin(r), end(r), ref(f)); } auto e() const { return end(r); } public: explicit dropped_while(R&& r, F f) : r(forward<R>(r)), f(move(f)) {} VIEW_END() TC(R, class F) dropped_while(R&&, F) -> dropped_while<R, F>; TC(R) VIEW(reversed, R) R r; auto b() const { return make_reverse_iterator(end(r)); } auto e() const { return make_reverse_iterator(begin(r)); } public: explicit reversed(R&& r) : r(forward<R>(r)) {} VIEW_END(sz(r)) TC(R) reversed(R&&) -> reversed<R>; TC(R) reversed(reversed<R>&) -> reversed<reversed<R>&>; TC(R) reversed(reversed<R> const&) -> reversed<reversed<R> const&>; TC(R) reversed(reversed<R>&&) -> reversed<reversed<R>>; TC(R) VIEW(sliced, R) static_assert(is_convertible_v<range_cat<R>, FIT>); R r; int start; int stop; auto b() const { return next(begin(r), start); } auto e() const { return next(begin(r), stop); } public: explicit sliced(R&& r, int start, int stop) : r(forward<R>(r)) { int n = sz(this->r); if (start < 0) { start += n; } if (stop < 0) { stop += n; } this->start = clamp<int>(start, 0, n); this->stop = clamp(stop, this->start, n); } VIEW_END(stop - start) TC(R) sliced(R&&, int, int) -> sliced<R>; TC(R) VIEW(strided, R) struct iter : iter_base<iter, range_cat<R>, range_ref<R>> { strided const* p; iter_t<R> i; range_ref<R> deref() const { return *i; } bool equal(iter const& x) const { return i == x.i; } void inc() & { if constexpr (is_convertible_v<range_cat<R>, RAIT>) { i += min(p->s, int(end(p->r) - i)); } else { for (int t = p->s; t-- && i != end(p->r);) { ++i; } } } void dec() & { if (i == end(p->r)) { int n = sz(p->r); std::advance(i, (n - 1) / p->s * p->s - n); } else { std::advance(i, -p->s); } } void advance(int n) & { if (n < 0) { dec(); ++n; } i += min(p->s * n, int(end(p->r) - i)); } int dist_to(iter const& x) const { int d = int(x.i - i); return d < 0 ? div_floor(d, p->s) : div_ceil(d, p->s); } }; R r; int s; iter b() const { return {{}, this, begin(r)}; } iter e() const { return {{}, this, end(r)}; } public: explicit strided(R&& r, int s) : r(forward<R>(r)), s(max<int>(s, 1)) { assert(1 <= s); } VIEW_END(div_ceil(sz(r), s)) TC(R) strided(R&&, int) -> strided<R>; TC(R, class T, class Op) VIEW(scanned, R, T, Op) static_assert(is_convertible_v<range_cat<R>, FIT>); struct iter : iter_base<iter, common_type_t<range_cat<R>, FIT>, T> { scanned const* p; T v; iter_t<R> i; T deref() const { return v; } bool equal(iter const& x) const { return i == x.i && p == x.p; } void inc() & { if (i == end(p->r)) { p = nullptr; } else { v = invoke(p->op, move(v), *i); ++i; } } }; R r; T init; [[no_unique_address]] Op op; iter b() const { return {{}, this, init, begin(r)}; } iter e() const { return {{}, nullptr, {}, end(r)}; } public: explicit scanned(R&& r, T init, Op op) : r(forward<R>(r)), init(move(init)), op(move(op)) {} VIEW_END(sz(r) + 1) TC(R, class T, class Op) scanned(R&&, T, Op) -> scanned<R, T, Op>; TC(R) VIEW(sampled, R) struct iter : iter_base<iter, common_type_t<range_cat<R>, IIT>, range_ref<R>> { iter_t<R> i; int rest; int n; range_ref<R> deref() const { return *i; } bool equal(iter const& x) const { return i == x.i; } void skip() & { while (rest && n <= rand<int>(0, --rest)) { ++i; } --n; } void inc() & { ++i; skip(); } }; R r; int n; iter b() const { iter ret{{}, begin(r), sz(r), n}; ret.skip(); return ret; } iter e() const { return {{}, end(r), 0, 0}; } public: explicit sampled(R&& r, int n) : r(forward<R>(r)), n(clamp<int>(n, 0, sz(this->r))) { assert(0 <= n); } VIEW_END(min(n, sz(r))) TC(R) sampled(R&&, int) -> sampled<R>; TC(D) class view_base { D const& derived() const { return static_cast<D const&>(*this); } public: auto begin() const { return derived().b(); } auto end() const { return derived().e(); } bool empty() const { return begin() == end(); } explicit operator bool() const { return begin() != end(); } int size() const { return int(end() - begin()); } decltype(auto) front() const { return *begin(); } decltype(auto) back() const { return *prev(end()); } decltype(auto) operator[](int n) const { return begin()[n]; } #define WRAP(SIG, CLS, ...) \ SIG const& { return CLS(derived() __VA_OPT__(,) __VA_ARGS__); } \ SIG && { return CLS(static_cast<D&&>(*this) __VA_OPT__(,) __VA_ARGS__); } WRAP(TC(F) auto filter(F f), filtered, move(f)) WRAP(TC(F) auto map(F f), mapped, move(f)) WRAP(template <int N> auto elements(), mapped, LIFT(get<N>)) WRAP(auto keys(), mapped, LIFT(get<0>)) WRAP(auto values(), mapped, LIFT(get<1>)) WRAP(auto take(int n), taken, n) WRAP(TC(F) auto take_while(F f), taken_while, move(f)) WRAP(auto drop(int n), dropped, n) WRAP(TC(F) auto drop_while(F f), dropped_while, move(f)) WRAP(auto rev(), reversed) WRAP(auto slice(int l, int r), sliced, l, r) WRAP(auto stride(int s), strided, s) WRAP(TC(T, class Op = plus<>) auto scan(T init, Op op = {}), scanned, move(init), move(op)) WRAP(auto sample(int n), sampled, n) #undef WRAP #define WRAP(SIG, FN, ...) \ SIG const { \ using Res = decltype(std::FN(begin(), end() __VA_OPT__(,) __VA_ARGS__)); \ if constexpr (is_void_v<Res>) { \ std::FN(begin(), end() __VA_OPT__(,) __VA_ARGS__); \ return derived(); \ } else { \ auto res = std::FN(begin(), end() __VA_OPT__(,) __VA_ARGS__); \ if constexpr (is_same_v<decltype(res), iter_t<D>>) { \ return int(distance(begin(), move(res))); \ } else { \ return res; \ } \ } \ } WRAP(TC(F) bool all_of(F f), all_of, ref(f)) WRAP(TC(F) bool any_of(F f), any_of, ref(f)) WRAP(TC(F) int count(F f), count_if, ref(f)) WRAP(TC(F) int find(F f), find_if, ref(f)) WRAP(TC(F) int adjacent_find(F f), adjacent_find, ref(f)) WRAP(TC(F) int remove(F f), remove_if, ref(f)) WRAP(D const& reverse(), reverse) WRAP(D const& shuffle(), shuffle, mt) WRAP(TC(C = equal_to<>) int unique(C comp = {}), unique, ref(comp)) WRAP(TC(F) bool is_partitioned(F f), is_partitioned, ref(f)) WRAP(TC(F) int partition(F f), partition, ref(f)) WRAP(TC(F) int stable_partition(F f), stable_partition, ref(f)) WRAP(TC(F) int partition_point(F f), partition_point, ref(f)) WRAP(TC(C = less<>) bool is_sorted(C comp = {}), is_sorted, ref(comp)) WRAP(TC(C = less<>) int is_sorted_until(C comp = {}), is_sorted_until, ref(comp)) WRAP(TC(C = less<>) D const& sort(C comp = {}), sort, ref(comp)) WRAP(TC(C = less<>) D const& stable_sort(C comp = {}), stable_sort, ref(comp)) WRAP(TC(T, class C = less<>) int lower_bound(T const& val, C comp = {}), lower_bound, val, ref(comp)) WRAP(TC(T, class C = less<>) int upper_bound(T const& val, C comp = {}), upper_bound, val, ref(comp)) WRAP(TC(T) bool binary_search(T const& val), binary_search, val) WRAP(int min_element(), min_element) WRAP(int max_element(), max_element) WRAP(bool next_permutation(), next_permutation) WRAP(bool prev_permutation(), prev_permutation) WRAP(TC(T, class Op = plus<>) T fold(T init, Op op = {}), accumulate, move(init), ref(op)) #undef WRAP TC(F) D const& each(F f) const { for (auto&& e : derived()) { if constexpr (is_invocable_v<F&, decltype(e)>) { invoke(f, e); } else { invoke(f); } } return derived(); } TC(F) auto max_right(F f) const { return *prev(std::partition_point(next(begin()), end(), ref(f))); } TC(F) auto min_left(F f) const { return *std::partition_point(begin(), prev(end()), not_fn(ref(f))); } TC(Op = plus<>) auto fold1(Op op = {}) const { return accumulate(next(begin()), end(), front(), ref(op)); } template <TC(...) class C = vector> auto to() const { return C(begin(), end()); } TC(C) auto to() const { return C(begin(), end()); } }; TC(D1, class D2) bool operator==(view_base<D1> const& x, view_base<D2> const& y) { return equal(begin(x), end(x), begin(y), end(y)); } TC(D1, class D2) bool operator<(view_base<D1> const& x, view_base<D2> const& y) { return lexicographical_compare(begin(x), end(x), begin(y), end(y)); } TC(R) VIEW(all, R) R r; auto b() const { return begin(r); } auto e() const { return end(r); } public: explicit all(R&& r) : r(forward<R>(r)) {} VIEW_END(sz(r)) TC(R) all(R&&) -> all<R>; TC(T) all(initializer_list<T>) -> all<initializer_list<T>>; TC(I) VIEW(range, I) I first; I last; I b() const { return first; } I e() const { return last; } public: explicit range(I first, I last) : first(move(first)), last(move(last)) {} VIEW_END() TC(G) VIEW(generation, G) using T = decay_t<invoke_result_t<G const&>>; struct iter : iter_base<iter, IIT, T> { generation const* p; T v; T deref() const { return v; } bool equal(iter const& x) const { return p == x.p; } void inc() & { v = invoke(p->gen); } }; [[no_unique_address]] G gen; iter b() const { return {{}, this, invoke(gen)}; } iter e() const { return {{}, nullptr, {}}; } public: explicit generation(G gen) : gen(move(gen)) {} VIEW_END(numeric_limits<int>::max()) TC(T) auto rand_view(T a, T b) { return generation([a, b] { return rand(a, b); }); } TC(T, class F) VIEW(iteration, T, F) struct iter : iter_base<iter, FIT, T> { iteration const* p; T v; T deref() const { return v; } bool equal(iter const& x) const { return p == x.p; } void inc() & { v = invoke(p->f, move(v)); } }; T init; [[no_unique_address]] F f; iter b() const { return {{}, this, init}; } iter e() const { return {{}, nullptr, {}}; } public: explicit iteration(T init, F f) : init(move(init)), f(move(f)) {} VIEW_END(numeric_limits<int>::max()) #undef TC #undef IIT #undef FIT #undef BIT #undef RAIT #undef VIEW #undef VIEW_END auto rep(int l, int r) { return range<int_iter>(min(l, r), r); } auto rep(int n) { return rep(0, n); } auto rep(int l, int r, int s) { assert(1 <= s); return iteration(l, _1 + decay_copy(s)).take_while(_1 < decay_copy(r)); } auto rep1(int l, int r) { return rep(l, r + 1); } auto rep1(int n) { return rep(1, n + 1); } auto rep1(int l, int r, int s) { assert(1 <= s); return rep(l, r + 1, s); } template <int D> auto mdrep(array<int, D> l, array<int, D> r) { assert(rep(D).all_of(LAMBDA(l[_1] < r[_1]))); auto f = [l, r](auto i) { for (int d = D - 1; ++i[d] == r[d] && d; --d) { i[d] = l[d]; } return i; }; return iteration(l, move(f)).take_while([r = r[0]](auto&& i) { return i[0] < r; }); } template <int D> auto mdrep(array<int, D> n) { assert(all(n).all_of(0 < _1)); return mdrep<D>({}, n); } template <class T> class vla { int n; T* a; public: vla() : n(0), a(nullptr) {} explicit vla(int n) : n(n), a(new T[n]) {} explicit vla(int n, T const& val) : vla(n) { fill_n(a, n, val); } explicit vla(initializer_list<T> il) : vla(sz(il)) { copy_n(il.begin(), n, a); } template <class R> explicit vla(R&& r, bool reverse = false) : vla(sz(r)) { using std::begin; if (reverse) { copy_n(begin(r), n, rbegin()); } else { copy_n(begin(r), n, a); } } ~vla() { delete[] a; } vla(vla const& x) : vla(x.n) { copy_n(x.a, n, a); } vla(vla&& x) noexcept : vla() { *this = move(x); } vla& operator=(vla const& x) { return *this = vla(x); } vla& operator=(vla&& x) noexcept { swap(n, x.n); swap(a, x.a); return *this; } T& operator[](int i) { assert(0 <= i && i < n); return a[i]; } T const& operator[](int i) const { assert(0 <= i && i < n); return a[i]; } template <class U, enable_if_t<is_lambda_expr<U>>* = nullptr> auto operator[](U&& x) { return bind([](vla& a, int i) -> T& { return a[i]; }, ref(*this), ref_or_move<U>(x)); } template <class U, enable_if_t<is_lambda_expr<U>>* = nullptr> auto operator[](U&& x) const { return bind([](vla const& a, int i) -> T const& { return a[i]; }, ref(*this), ref_or_move<U>(x)); } T* begin() { return a; } T const* begin() const { return a; } T* end() { return a + n; } T const* end() const { return a + n; } auto rbegin() { return make_reverse_iterator(a + n); } auto rbegin() const { return make_reverse_iterator(a + n); } auto rend() { return make_reverse_iterator(a); } auto rend() const { return make_reverse_iterator(a); } int size() const { return n; } }; template <class R> vla(R&&, bool = false) -> vla<decay_t<range_ref<R>>>; template <class T> class vla2 { template <bool Const> struct iter : iter_base<iter<Const>, random_access_iterator_tag, range<conditional_t<Const, T const, T>*>> { conditional_t<Const, vla2 const, vla2>* p; int i; auto deref() const { return (*p)[i]; } bool equal(iter const& x) const { return i == x.i; } void inc() & { ++i; } void dec() & { --i; } void advance(int n) & { i += n; } int dist_to(iter const& x) const { return x.i - i; } }; vla<int> pos; vla<T> a; vector<pair<int, T>> buf; public: vla2() = default; explicit vla2(int n, int m = 0) : pos(n + 1, 0) { buf.reserve(pos[n] = m); } template <class... Rs> explicit vla2(int n, Rs&&... rs) : pos(n + 1, 0) { (..., [&](auto&& r) { for (auto&& [i, e] : r) { ++pos[i]; } }(rs)); partial_sum(pos.begin(), pos.end(), pos.begin()); a = vla<T>(exchange(pos[n], 0)); if (n) { rotate(pos.begin(), pos.end() - 2, pos.end()); } pos[0] = 0; (..., [&](auto&& r) { for (auto&& [i, e] : r) { a[pos[i + 1]++] = e; } }(rs)); } void add(int i, T val) { assert(0 <= i && i < size()); ++pos[i]; buf.emplace_back(i, move(val)); if (sz(buf) == pos[size()]) { pos[size()] = 0; build(); } } void build() { partial_sum(pos.begin(), pos.end(), pos.begin()); for (a = vla<T>(sz(buf)); !empty(buf); buf.pop_back()) { a[--pos[buf.back().first]] = move(buf.back().second); } vector<pair<int, T>>().swap(buf); } auto operator[](int i) { assert(0 <= i && i < size()); return range(a.begin() + pos[i], a.begin() + pos[i + 1]); } auto operator[](int i) const { assert(0 <= i && i < size()); return range(a.begin() + pos[i], a.begin() + pos[i + 1]); } iter<false> begin() { return {{}, this, 0}; } iter<true> begin() const { return {{}, this, 0}; } iter<false> end() { return {{}, this, size()}; } iter<true> end() const { return {{}, this, size()}; } int size() const { return sz(pos) - 1; } }; template <class... Rs> vla2(int, Rs&&...) -> vla2<common_type_t<tuple_element_t<1, decay_t<range_ref<Rs>>>...>>; } // namespace r7h int main() { int t = 1; if (MULTI_CASES) { r7h::scan(t); } r7h::rep(t).each(r7h::main); assert(!r7h::scan(t)); } #endif