CompetitiveProgrammingCpp
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Test/DataStructure/RunLengthEncoding.test.cpp
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- Last update: 2025-07-06 21:41:14+09:00
- Problem: https://yukicoder.me/problems/no/1469
Depends on
- Library/DataStructure/RunLengthEncoding.hpp
- Library/Range/istream.hpp
- Library/Utility/Tuple.hpp
- Library/Utility/io.hpp
Code
#define PROBLEM "https://yukicoder.me/problems/no/1469"
// begin:tag includes
#include "../../Library/DataStructure/RunLengthEncoding.hpp"
#include "../../Library/Range/istream.hpp"
// end:tag includes
int main() {
std::cin.tie(0);
std::ios::sync_with_stdio(0);
auto [s] = mtd::io::in<std::string>();
auto rle = mtd::RunLengthEncoding(s);
for (auto [c, _] : rle) { std::cout << c; }
std::cout << std::endl;
}#line 1 "Test/DataStructure/RunLengthEncoding.test.cpp"
#define PROBLEM "https://yukicoder.me/problems/no/1469"
// begin:tag includes
#line 2 "Library/DataStructure/RunLengthEncoding.hpp"
#include <ranges>
#include <vector>
namespace mtd {
template <std::ranges::range _R>
class RunLengthEncoding {
using T = std::iter_value_t<std::ranges::iterator_t<_R>>;
const std::vector<std::tuple<T, int>> r;
static constexpr auto construct_rle(const _R& r) {
std::vector<std::tuple<T, int>> rle;
if (r.empty()) { return rle; }
T now = *r.begin();
int cnt = 1;
for (const auto& x : r | std::views::drop(1)) {
if (x == now) {
++cnt;
} else {
rle.emplace_back(now, cnt);
cnt = 1;
now = x;
}
}
rle.emplace_back(now, cnt);
return rle;
}
public:
constexpr RunLengthEncoding(const _R& _r) : r(construct_rle(_r)) {}
constexpr auto begin() const { return r.begin(); }
constexpr auto end() const { return r.end(); }
};
} // namespace mtd
#line 5 "Test/DataStructure/RunLengthEncoding.test.cpp"
#line 2 "Library/Range/istream.hpp"
#line 4 "Library/Range/istream.hpp"
#line 2 "Library/Utility/io.hpp"
#include <iostream>
#line 5 "Library/Utility/io.hpp"
#include <type_traits>
#line 7 "Library/Utility/io.hpp"
#line 2 "Library/Utility/Tuple.hpp"
#include <functional>
namespace mtd {
namespace util {
template <class F, class T>
constexpr auto tuple_transform(F&& f, T&& t) {
return std::apply(
[&]<class... Ts>(Ts&&... elems) {
return std::tuple<std::invoke_result_t<F&, Ts>...>(
std::invoke(f, std::forward<Ts>(elems))...);
},
std::forward<T>(t));
}
template <class F, class T>
constexpr auto tuple_for_each(F&& f, T&& t) {
std::apply(
[&]<class... Ts>(Ts&&... elems) {
(std::invoke(f, std::forward<Ts>(elems)), ...);
},
std::forward<T>(t));
}
} // namespace util
} // namespace mtd
#line 9 "Library/Utility/io.hpp"
namespace mtd {
namespace io {
namespace __details {
template <typename T>
concept is_vec = std::same_as<
T, std::vector<typename T::value_type, typename T::allocator_type>>;
template <typename T>
concept is_mat = is_vec<T> && is_vec<typename T::value_type>;
} // namespace __details
template <class T>
constexpr auto _input() {
T x;
std::cin >> x;
return x;
}
template <typename T>
requires requires { typename std::tuple_size<T>::type; }
constexpr auto _input() {
T x;
util::tuple_for_each([](auto&& i) { std::cin >> i; }, x);
return x;
}
template <__details::is_vec T>
constexpr auto _input(int n) {
std::vector<typename T::value_type> v;
v.reserve(n);
for (auto i : std::views::iota(0, n)) {
v.emplace_back(_input<typename T::value_type>());
}
return v;
}
template <__details::is_mat T>
constexpr auto _input(int h, int w) {
T mat;
mat.reserve(h);
for (auto i : std::views::iota(0, h)) {
mat.emplace_back(_input<typename T::value_type>(w));
}
return mat;
}
template <int N, class Tuple, class T, class... Args, class... Sizes>
constexpr auto _tuple_input(Tuple& t, Sizes... sizes);
template <int N, class Tuple, __details::is_vec T, class... Args,
class Size, class... Sizes>
constexpr auto _tuple_input(Tuple& t, Size size, Sizes... sizes);
template <int N, class Tuple, __details::is_mat T, class... Args,
class Size, class... Sizes>
constexpr auto _tuple_input(Tuple& t, Size size_h, Size size_w,
Sizes... sizes);
template <int N, class Tuple, class T, class... Args, class... Sizes>
constexpr auto _tuple_input(Tuple& t, Sizes... sizes) {
std::get<N>(t) = _input<T>();
if constexpr (sizeof...(Args) > 0) {
_tuple_input<N + 1, Tuple, Args...>(t, sizes...);
}
}
template <int N, class Tuple, __details::is_vec T, class... Args,
class Size, class... Sizes>
constexpr auto _tuple_input(Tuple& t, Size size, Sizes... sizes) {
std::get<N>(t) = _input<T>(size);
if constexpr (sizeof...(Args) > 0) {
_tuple_input<N + 1, Tuple, Args...>(t, sizes...);
}
}
template <int N, class Tuple, __details::is_mat T, class... Args,
class Size, class... Sizes>
constexpr auto _tuple_input(Tuple& t, Size size_h, Size size_w,
Sizes... sizes) {
std::get<N>(t) = _input<T>(size_h, size_w);
if constexpr (sizeof...(Args) > 0) {
_tuple_input<N + 1, Tuple, Args...>(t, sizes...);
}
}
template <class... Args, class... Sizes>
requires(std::convertible_to<Sizes, size_t>&&...) constexpr auto in(
Sizes... sizes) {
auto base = std::tuple<Args...>();
_tuple_input<0, decltype(base), Args...>(base, sizes...);
return base;
}
} // namespace io
} // namespace mtd
#line 6 "Library/Range/istream.hpp"
namespace mtd {
namespace ranges {
constexpr int _inf = 1e9;
template <class... Args>
struct istream_view
: public std::ranges::view_interface<istream_view<Args...>> {
class iterator {
int count;
std::tuple<Args...> val;
public:
using difference_type = int;
using value_type = decltype(val);
using iterator_concept = std::input_iterator_tag;
constexpr iterator() = default;
constexpr explicit iterator(int _count) : count(_count) {
operator++();
}
constexpr auto operator*() const { return val; }
constexpr auto& operator++() {
--count;
if (count >= 0) { val = io::in<Args...>(); }
return *this;
}
constexpr auto operator++(int) { return ++*this; }
constexpr auto operator==(const iterator& s) const {
return count == s.count;
}
constexpr auto operator==(std::default_sentinel_t) const {
return count < 0 || std::cin.eof() || std::cin.fail() ||
std::cin.bad();
}
constexpr friend auto operator==(std::default_sentinel_t s,
const iterator& li) {
return li == s;
}
};
int count;
public:
constexpr explicit istream_view(int _count) : count(_count) {}
constexpr explicit istream_view() : istream_view(_inf) {}
constexpr auto begin() const { return iterator(count); }
constexpr auto end() const { return std::default_sentinel; }
};
} // namespace ranges
namespace views {
namespace __detail {
template <typename... _Args>
concept __can_istream_view = requires {
ranges::istream_view(std::declval<_Args>()...);
};
} // namespace __detail
template <class... Args>
struct _Istream {
template <class... _Tp>
requires __detail::__can_istream_view<_Tp...>
constexpr auto operator() [[nodiscard]] (_Tp&&... __e) const {
return ranges::istream_view<Args...>(std::forward<_Tp>(__e)...);
}
};
template <class... Args>
inline constexpr _Istream<Args...> istream{};
} // namespace views
} // namespace mtd
#line 7 "Test/DataStructure/RunLengthEncoding.test.cpp"
// end:tag includes
int main() {
std::cin.tie(0);
std::ios::sync_with_stdio(0);
auto [s] = mtd::io::in<std::string>();
auto rle = mtd::RunLengthEncoding(s);
for (auto [c, _] : rle) { std::cout << c; }
std::cout << std::endl;
}