#ifndef ranges_hh_INCLUDED #define ranges_hh_INCLUDED #include #include #include #include #include "constexpr_utils.hh" namespace Kakoune { template struct ViewFactory { Func func; }; template ViewFactory> make_view_factory(Func&& func) { return {std::forward(func)}; } template decltype(auto) operator| (Range&& range, ViewFactory factory) { return factory.func(std::forward(range)); } template struct decay_range_impl { using type = std::decay_t; }; template struct decay_range_impl { using type = Range&; }; template using decay_range = typename decay_range_impl::type; template struct ReverseView { decltype(auto) begin() { return m_range.rbegin(); } decltype(auto) end() { return m_range.rend(); } Range m_range; }; inline auto reverse() { return make_view_factory([](auto&& range) { using Range = decltype(range); return ReverseView>{std::forward(range)}; }); } template using IteratorOf = decltype(std::begin(std::declval())); template using ValueOf = typename Range::value_type; template struct FilterView { using RangeIt = IteratorOf; struct Iterator : std::iterator::value_type> { Iterator(const FilterView& view, RangeIt it, RangeIt end) : m_it{std::move(it)}, m_end{std::move(end)}, m_view{&view} { do_filter(); } decltype(auto) operator*() { return *m_it; } Iterator& operator++() { ++m_it; do_filter(); return *this; } Iterator operator++(int) { auto copy = *this; ++(*this); return copy; } friend bool operator==(const Iterator& lhs, const Iterator& rhs) { return lhs.m_it == rhs.m_it; } friend bool operator!=(const Iterator& lhs, const Iterator& rhs) { return not (lhs == rhs); } const RangeIt& base() const { return m_it; } private: void do_filter() { while (m_it != m_end and not m_view->m_filter(*m_it)) ++m_it; } RangeIt m_it; RangeIt m_end; const FilterView* m_view; }; Iterator begin() const { return {*this, std::begin(m_range), std::end(m_range)}; } Iterator end() const { return {*this, std::end(m_range), std::end(m_range)}; } Range m_range; mutable Filter m_filter; }; template inline auto filter(Filter f) { return make_view_factory([f = std::move(f)](auto&& range) { using Range = decltype(range); return FilterView, Filter>{std::forward(range), std::move(f)}; }); } template struct TransformView { using RangeIt = IteratorOf; using ResType = decltype(std::declval()(*std::declval())); struct Iterator : std::iterator> { Iterator(const TransformView& view, RangeIt it) : m_it{std::move(it)}, m_view{&view} {} decltype(auto) operator*() { return m_view->m_transform(*m_it); } Iterator& operator++() { ++m_it; return *this; } Iterator operator++(int) { auto copy = *this; ++m_it; return copy; } friend bool operator==(const Iterator& lhs, const Iterator& rhs) { return lhs.m_it == rhs.m_it; } friend bool operator!=(const Iterator& lhs, const Iterator& rhs) { return not (lhs == rhs); } RangeIt base() const { return m_it; } private: RangeIt m_it; const TransformView* m_view; }; Iterator begin() const { return {*this, std::begin(m_range)}; } Iterator end() const { return {*this, std::end(m_range)}; } Range m_range; mutable Transform m_transform; }; template inline auto transform(Transform t) { return make_view_factory([t = std::move(t)](auto&& range) { using Range = decltype(range); return TransformView, Transform>{std::forward(range), std::move(t)}; }); } template, typename ValueTypeParam = void> struct SplitView { using RangeIt = IteratorOf; using ValueType = std::conditional_t::value, std::pair, IteratorOf>, ValueTypeParam>; struct Iterator : std::iterator { Iterator(RangeIt pos, const RangeIt& end, Element separator, Element escaper) : done{pos == end}, pos{pos}, sep{pos}, end(end), separator{std::move(separator)}, escaper{std::move(escaper)} { bool escaped = false; while (sep != end and (escaped or *sep != separator)) { escaped = escape and not escaped and *sep == escaper; ++sep; } } Iterator& operator++() { advance(); return *this; } Iterator operator++(int) { auto copy = *this; advance(); return copy; } bool operator==(const Iterator& other) const { return pos == other.pos and done == other.done; } bool operator!=(const Iterator& other) const { return pos != other.pos or done != other.done; } ValueType operator*() { return {pos, sep}; } private: void advance() { if (sep == end) { pos = end; done = true; return; } pos = sep+1; bool escaped = escape and *sep == escaper; for (sep = pos; sep != end; ++sep) { if (not escaped and *sep == separator) break; escaped = escape and not escaped and *sep == escaper; } } bool done; RangeIt pos; RangeIt sep; RangeIt end; Element separator; Element escaper; }; Iterator begin() const { return {std::begin(m_range), std::end(m_range), m_separator, m_escaper}; } Iterator end() const { return {std::end(m_range), std::end(m_range), m_separator, m_escaper}; } Range m_range; Element m_separator; Element m_escaper; }; template auto split(Element separator) { return make_view_factory([s = std::move(separator)](auto&& range) { using Range = decltype(range); return SplitView, false, Element, ValueType>{std::forward(range), std::move(s), {}}; }); } template auto split(Element separator, Element escaper) { return make_view_factory([s = std::move(separator), e = std::move(escaper)](auto&& range) { using Range = decltype(range); return SplitView, true, Element, ValueType>{std::forward(range), std::move(s), std::move(e)}; }); } template struct ConcatView { using RangeIt1 = decltype(std::declval().begin()); using RangeIt2 = decltype(std::declval().begin()); using ValueType = typename std::common_type_t::value_type, typename std::iterator_traits::value_type>; struct Iterator : std::iterator { static_assert(std::is_convertible::value_type, ValueType>::value, ""); static_assert(std::is_convertible::value_type, ValueType>::value, ""); Iterator(RangeIt1 it1, RangeIt1 end1, RangeIt2 it2) : m_it1(std::move(it1)), m_end1(std::move(end1)), m_it2(std::move(it2)) {} decltype(auto) operator*() { return is2() ? *m_it2 : *m_it1; } Iterator& operator++() { if (is2()) ++m_it2; else ++m_it1; return *this; } Iterator operator++(int) { auto copy = *this; ++*this; return copy; } friend bool operator==(const Iterator& lhs, const Iterator& rhs) { return lhs.m_it1 == rhs.m_it1 and lhs.m_end1 == rhs.m_end1 and lhs.m_it2 == rhs.m_it2; } friend bool operator!=(const Iterator& lhs, const Iterator& rhs) { return not (lhs == rhs); } private: bool is2() const { return m_it1 == m_end1; } RangeIt1 m_it1; RangeIt1 m_end1; RangeIt2 m_it2; }; ConcatView(Range1& range1, Range2& range2) : m_range1(range1), m_range2(range2) {} Iterator begin() const { return {m_range1.begin(), m_range1.end(), m_range2.begin()}; } Iterator end() const { return {m_range1.end(), m_range1.end(), m_range2.end()}; } private: Range1 m_range1; Range2 m_range2; }; template ConcatView, decay_range> concatenated(Range1&& range1, Range2&& range2) { return {range1, range2}; } template auto find(Range&& range, const T& value) { using std::begin; using std::end; return std::find(begin(range), end(range), value); } template auto find_if(Range&& range, T op) { using std::begin; using std::end; return std::find_if(begin(range), end(range), op); } template bool contains(Range&& range, const T& value) { using std::end; return find(range, value) != end(range); } template bool contains_that(Range&& range, T op) { using std::end; return find_if(range, op) != end(range); } template void unordered_erase(Range&& vec, U&& value) { auto it = find(vec, std::forward(value)); if (it != vec.end()) { using std::swap; swap(vec.back(), *it); vec.pop_back(); } } template Init accumulate(Range&& c, Init&& init, BinOp&& op) { using std::begin; using std::end; return std::accumulate(begin(c), end(c), init, op); } template auto gather() { return make_view_factory([](auto&& range) { using std::begin; using std::end; return Container(begin(range), end(range)); }); } template auto elements(bool exact_size = false) { return make_view_factory([=] (auto&& range) { using std::begin; using std::end; auto it = begin(range), end_it = end(range); size_t i = 0; auto elem = [&](size_t index) { for (; i < index; ++i) if (++it == end_it) throw ExceptionType{i}; return *it; }; // Note that initializer lists elements are guaranteed to be sequenced Array, sizeof...(Indexes)> res{{elem(Indexes)...}}; if (exact_size and ++it != end_it) throw ExceptionType{++i}; return res; }); } template auto static_gather_impl(std::index_sequence) { return elements(true); } template auto static_gather() { return static_gather_impl(std::make_index_sequence()); } } #endif // ranges_hh_INCLUDED