24 Ranges library [ranges]

24.7 Range adaptors [range.adaptors]

24.7.1 General [range.adaptors.general]

1
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Subclause [range.adaptors] defines range adaptors, which are utilities that transform a range into a view with custom behaviors.
These adaptors can be chained to create pipelines of range transformations that evaluate lazily as the resulting view is iterated.
2
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Range adaptors are declared in namespace std​::​ranges​::​views.
3
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The bitwise OR operator is overloaded for the purpose of creating adaptor chain pipelines.
The adaptors also support function call syntax with equivalent semantics.
4
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[Example 1: vector<int> ints{0,1,2,3,4,5}; auto even = [](int i){ return 0 == i % 2; }; auto square = [](int i) { return i * i; }; for (int i : ints | views::filter(even) | views::transform(square)) { cout << i << ' '; // prints: 0 4 16 } assert(ranges::equal(ints | views::filter(even), views::filter(ints, even))); — end example]

24.7.2 Range adaptor objects [range.adaptor.object]

1
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A range adaptor closure object is a unary function object that accepts a viewable_­range argument and returns a view.
For a range adaptor closure object C and an expression R such that decltype((R)) models viewable_­range, the following expressions are equivalent and yield a view: C(R) R | C
Given an additional range adaptor closure object D, the expression C | D is well-formed and produces another range adaptor closure object such that the following two expressions are equivalent: R | C | D R | (C | D)
2
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A range adaptor object is a customization point object ([customization.point.object]) that accepts a viewable_­range as its first argument and returns a view.
3
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If a range adaptor object accepts only one argument, then it is a range adaptor closure object.
4
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If a range adaptor object accepts more than one argument, then the following expressions are equivalent: adaptor(range, args...) adaptor(args...)(range) range | adaptor(args...)
In this case, adaptor(args...) is a range adaptor closure object.

24.7.3 Semiregular wrapper [range.semi.wrap]

1
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Many types in this subclause are specified in terms of an exposition-only class template semiregular-box.
semiregular-box<T> behaves exactly like optional<T> with the following differences:
  • (1.1)
    semiregular-box<T> constrains its type parameter T with copy_­constructible<T> && is_­object_­v<T>.
  • (1.2)
    If T models default_­initializable, the default constructor of semiregular-box<T> is equivalent to: constexpr semiregular-box() noexcept(is_nothrow_default_constructible_v<T>) : semiregular-box{in_place} { }
  • (1.3)
    If assignable_­from<T&, const T&> is not modeled, the copy assignment operator is equivalent to: semiregular-box& operator=(const semiregular-box& that) noexcept(is_nothrow_copy_constructible_v<T>) { if (that) emplace(*that); else reset(); return *this; }
  • (1.4)
    If assignable_­from<T&, T> is not modeled, the move assignment operator is equivalent to: semiregular-box& operator=(semiregular-box&& that) noexcept(is_nothrow_move_constructible_v<T>) { if (that) emplace(std::move(*that)); else reset(); return *this; }

24.7.4 All view [range.all]

24.7.4.1 General [range.all.general]

1
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views​::​all returns a view that includes all elements of its range argument.
2
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The name views​::​all denotes a range adaptor object ([range.adaptor.object]).
Given a subexpression E, the expression views​::​all(E) is expression-equivalent to:
  • (2.1)
    decay-copy(E) if the decayed type of E models view.
  • (2.2)
    Otherwise, ref_­view{E} if that expression is well-formed.
  • (2.3)
    Otherwise, subrange{E}.

24.7.4.2 Class template ref_­view [range.ref.view]

1
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ref_­view is a view of the elements of some other range.
namespace std::ranges { template<range R> requires is_object_v<R> class ref_view : public view_interface<ref_view<R>> { private: R* r_ = nullptr; // exposition only public: constexpr ref_view() noexcept = default; template<not-same-as<ref_view> T> requires see below constexpr ref_view(T&& t); constexpr R& base() const { return *r_; } constexpr iterator_t<R> begin() const { return ranges::begin(*r_); } constexpr sentinel_t<R> end() const { return ranges::end(*r_); } constexpr bool empty() const requires requires { ranges::empty(*r_); } { return ranges::empty(*r_); } constexpr auto size() const requires sized_­range<R> { return ranges::size(*r_); } constexpr auto data() const requires contiguous_­range<R> { return ranges::data(*r_); } }; template<class R> ref_view(R&) -> ref_view<R>; }
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template<not-same-as<ref_view> T> requires see below constexpr ref_view(T&& t);
2
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Effects: Initializes r_­ with addressof(static_­cast<R&>(std​::​forward<T>(t))).
3
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Remarks: Let FUN denote the exposition-only functions void FUN(R&); void FUN(R&&) = delete;
The expression in the requires-clause is equivalent to: convertible_­to<T, R&> && requires { FUN(declval<T>()); }

24.7.5 Filter view [range.filter]

24.7.5.1 Overview [range.filter.overview]

1
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filter_­view presents a view of the elements of an underlying sequence that satisfy a predicate.
2
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The name views​::​filter denotes a range adaptor object ([range.adaptor.object]).
Given subexpressions E and P, the expression views​::​filter(E, P) is expression-equivalent to filter_­view{E, P}.
3
#
[Example 1: vector<int> is{ 0, 1, 2, 3, 4, 5, 6 }; filter_view evens{is, [](int i) { return 0 == i % 2; }}; for (int i : evens) cout << i << ' '; // prints: 0 2 4 6 — end example]

24.7.5.2 Class template filter_­view [range.filter.view]

namespace std::ranges { template<input_­range V, indirect_­unary_­predicate<iterator_t<V>> Pred> requires view<V> && is_object_v<Pred> class filter_view : public view_interface<filter_view<V, Pred>> { private: V base_ = V(); // exposition only semiregular-box<Pred> pred_; // exposition only // [range.filter.iterator], class filter_­view​::​iterator class iterator; // exposition only // [range.filter.sentinel], class filter_­view​::​sentinel class sentinel; // exposition only public: filter_view() = default; constexpr filter_view(V base, Pred pred); constexpr V base() const& requires copy_constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr const Pred& pred() const; constexpr iterator begin(); constexpr auto end() { if constexpr (common_range<V>) return iterator{*this, ranges::end(base_)}; else return sentinel{*this}; } }; template<class R, class Pred> filter_view(R&&, Pred) -> filter_view<views::all_t<R>, Pred>; }
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constexpr filter_view(V base, Pred pred);
1
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Effects: Initializes base_­ with std​::​move(base) and initializes pred_­ with std​::​move(pred).
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constexpr const Pred& pred() const;
2
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Effects: Equivalent to: return *pred_­;
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constexpr iterator begin();
3
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Preconditions: pred_­.has_­value().
4
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Returns: {*this, ranges​::​find_­if(base_­, ref(*pred_­))}.
5
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Remarks: In order to provide the amortized constant time complexity required by the range concept when filter_­view models forward_­range, this function caches the result within the filter_­view for use on subsequent calls.

24.7.5.3 Class filter_­view​::​iterator [range.filter.iterator]

namespace std::ranges { template<input_­range V, indirect_­unary_­predicate<iterator_t<V>> Pred> requires view<V> && is_object_v<Pred> class filter_view<V, Pred>::iterator { private: iterator_t<V> current_ = iterator_t<V>(); // exposition only filter_view* parent_ = nullptr; // exposition only public: using iterator_concept = see below; using iterator_category = see below; using value_type = range_value_t<V>; using difference_type = range_difference_t<V>; iterator() = default; constexpr iterator(filter_view& parent, iterator_t<V> current); constexpr iterator_t<V> base() const & requires copyable<iterator_t<V>>; constexpr iterator_t<V> base() &&; constexpr range_reference_t<V> operator*() const; constexpr iterator_t<V> operator->() const requires has-arrow<iterator_t<V>> && copyable<iterator_t<V>>; constexpr iterator& operator++(); constexpr void operator++(int); constexpr iterator operator++(int) requires forward_­range<V>; constexpr iterator& operator--() requires bidirectional_­range<V>; constexpr iterator operator--(int) requires bidirectional_­range<V>; friend constexpr bool operator==(const iterator& x, const iterator& y) requires equality_comparable<iterator_t<V>>; friend constexpr range_rvalue_reference_t<V> iter_move(const iterator& i) noexcept(noexcept(ranges::iter_move(i.current_))); friend constexpr void iter_swap(const iterator& x, const iterator& y) noexcept(noexcept(ranges::iter_swap(x.current_, y.current_))) requires indirectly_­swappable<iterator_t<V>>; }; }
1
#
Modification of the element a filter_­view​::​iterator denotes is permitted, but results in undefined behavior if the resulting value does not satisfy the filter predicate.
2
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iterator​::​iterator_­concept is defined as follows:
  • (2.1)
    If V models bidirectional_­range, then iterator_­concept denotes bidirectional_­iterator_­tag.
  • (2.2)
    Otherwise, if V models forward_­range, then iterator_­concept denotes forward_­iterator_­tag.
  • (2.3)
    Otherwise, iterator_­concept denotes input_­iterator_­tag.
3
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iterator​::​iterator_­category is defined as follows:
  • (3.1)
    Let C denote the type iterator_­traits<iterator_­t<V>>​::​iterator_­category.
  • (3.2)
    If C models derived_­from<bidirectional_­iterator_­tag>, then iterator_­category denotes bidirectional_­iterator_­tag.
  • (3.3)
    Otherwise, if C models derived_­from<forward_­iterator_­tag>, then iterator_­category denotes forward_­iterator_­tag.
  • (3.4)
    Otherwise, iterator_­category denotes C.
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constexpr iterator(filter_view& parent, iterator_t<V> current);
4
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Effects: Initializes current_­ with std​::​move(current) and parent_­ with addressof(parent).
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constexpr iterator_t<V> base() const & requires copyable<iterator_t<V>>;
5
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Effects: Equivalent to: return current_­;
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constexpr iterator_t<V> base() &&;
6
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Effects: Equivalent to: return std​::​move(current_­);
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constexpr range_reference_t<V> operator*() const;
7
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Effects: Equivalent to: return *current_­;
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constexpr iterator_t<V> operator->() const requires has-arrow<iterator_t<V>> && copyable<iterator_t<V>>;
8
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Effects: Equivalent to: return current_­;
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constexpr iterator& operator++();
9
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Effects: Equivalent to: current_ = ranges::find_if(std::move(++current_), ranges::end(parent_->base_), ref(*parent_->pred_)); return *this;
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constexpr void operator++(int);
10
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Effects: Equivalent to ++*this.
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constexpr iterator operator++(int) requires forward_­range<V>;
11
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Effects: Equivalent to: auto tmp = *this; ++*this; return tmp;
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constexpr iterator& operator--() requires bidirectional_­range<V>;
12
#
Effects: Equivalent to: do --current_; while (!invoke(*parent_->pred_, *current_)); return *this;
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constexpr iterator operator--(int) requires bidirectional_­range<V>;
13
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Effects: Equivalent to: auto tmp = *this; --*this; return tmp;
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friend constexpr bool operator==(const iterator& x, const iterator& y) requires equality_comparable<iterator_t<V>>;
14
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Effects: Equivalent to: return x.current_­ == y.current_­;
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friend constexpr range_rvalue_reference_t<V> iter_move(const iterator& i) noexcept(noexcept(ranges::iter_move(i.current_­)));
15
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Effects: Equivalent to: return ranges​::​iter_­move(i.current_­);
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friend constexpr void iter_swap(const iterator& x, const iterator& y) noexcept(noexcept(ranges::iter_swap(x.current_­, y.current_­))) requires indirectly_­swappable<iterator_t<V>>;
16
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Effects: Equivalent to ranges​::​iter_­swap(x.current_­, y.current_­).

24.7.5.4 Class filter_­view​::​sentinel [range.filter.sentinel]

namespace std::ranges { template<input_­range V, indirect_­unary_­predicate<iterator_t<V>> Pred> requires view<V> && is_object_v<Pred> class filter_view<V, Pred>::sentinel { private: sentinel_t<V> end_ = sentinel_t<V>(); // exposition only public: sentinel() = default; constexpr explicit sentinel(filter_view& parent); constexpr sentinel_t<V> base() const; friend constexpr bool operator==(const iterator& x, const sentinel& y); }; }
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constexpr explicit sentinel(filter_view& parent);
1
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Effects: Initializes end_­ with ranges​::​end(parent.base_­).
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constexpr sentinel_t<V> base() const;
2
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Effects: Equivalent to: return end_­;
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friend constexpr bool operator==(const iterator& x, const sentinel& y);
3
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Effects: Equivalent to: return x.current_­ == y.end_­;

24.7.6 Transform view [range.transform]

24.7.6.1 Overview [range.transform.overview]

1
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transform_­view presents a view of an underlying sequence after applying a transformation function to each element.
2
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The name views​::​transform denotes a range adaptor object ([range.adaptor.object]).
Given subexpressions E and F, the expression views​::​transform(E, F) is expression-equivalent to transform_­view{E, F}.
3
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[Example 1: vector<int> is{ 0, 1, 2, 3, 4 }; transform_view squares{is, [](int i) { return i * i; }}; for (int i : squares) cout << i << ' '; // prints: 0 1 4 9 16 — end example]

24.7.6.2 Class template transform_­view [range.transform.view]

namespace std::ranges { template<input_­range V, copy_­constructible F> requires view<V> && is_object_v<F> && regular_invocable<F&, range_reference_t<V>> && can-reference<invoke_result_t<F&, range_reference_t<V>>> class transform_view : public view_interface<transform_view<V, F>> { private: // [range.transform.iterator], class template transform_­view​::​iterator template<bool> struct iterator; // exposition only // [range.transform.sentinel], class template transform_­view​::​sentinel template<bool> struct sentinel; // exposition only V base_ = V(); // exposition only semiregular-box<F> fun_; // exposition only public: transform_view() = default; constexpr transform_view(V base, F fun); constexpr V base() const& requires copy_constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr iterator<false> begin(); constexpr iterator<true> begin() const requires range<const V> && regular_invocable<const F&, range_reference_t<const V>>; constexpr sentinel<false> end(); constexpr iterator<false> end() requires common_range<V>; constexpr sentinel<true> end() const requires range<const V> && regular_invocable<const F&, range_reference_t<const V>>; constexpr iterator<true> end() const requires common_range<const V> && regular_invocable<const F&, range_reference_t<const V>>; constexpr auto size() requires sized_­range<V> { return ranges::size(base_); } constexpr auto size() const requires sized_­range<const V> { return ranges::size(base_); } }; template<class R, class F> transform_view(R&&, F) -> transform_view<views::all_t<R>, F>; }
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constexpr transform_view(V base, F fun);
1
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Effects: Initializes base_­ with std​::​move(base) and fun_­ with std​::​move(fun).
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constexpr iterator<false> begin();
2
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Effects: Equivalent to: return iterator<false>{*this, ranges::begin(base_)};
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constexpr iterator<true> begin() const requires range<const V> && regular_invocable<const F&, range_reference_t<const V>>;
3
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Effects: Equivalent to: return iterator<true>{*this, ranges::begin(base_)};
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constexpr sentinel<false> end();
4
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Effects: Equivalent to: return sentinel<false>{ranges::end(base_)};
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constexpr iterator<false> end() requires common_range<V>;
5
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Effects: Equivalent to: return iterator<false>{*this, ranges::end(base_)};
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constexpr sentinel<true> end() const requires range<const V> && regular_invocable<const F&, range_reference_t<const V>>;
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Effects: Equivalent to: return sentinel<true>{ranges::end(base_)};
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constexpr iterator<true> end() const requires common_range<const V> && regular_invocable<const F&, range_reference_t<const V>>;
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Effects: Equivalent to: return iterator<true>{*this, ranges::end(base_)};

24.7.6.3 Class template transform_­view​::​iterator [range.transform.iterator]

namespace std::ranges { template<input_­range V, copy_­constructible F> requires view<V> && is_object_v<F> && regular_invocable<F&, range_reference_t<V>> && can-reference<invoke_result_t<F&, range_reference_t<V>>> template<bool Const> class transform_view<V, F>::iterator { private: using Parent = // exposition only conditional_t<Const, const transform_view, transform_view>; using Base = // exposition only conditional_t<Const, const V, V>; iterator_t<Base> current_ = // exposition only iterator_t<Base>(); Parent* parent_ = nullptr; // exposition only public: using iterator_concept = see below; using iterator_category = see below; using value_type = remove_cvref_t<invoke_result_t<F&, range_reference_t<Base>>>; using difference_type = range_difference_t<Base>; iterator() = default; constexpr iterator(Parent& parent, iterator_t<Base> current); constexpr iterator(iterator<!Const> i) requires Const && convertible_­to<iterator_t<V>, iterator_t<Base>>; constexpr iterator_t<Base> base() const & requires copyable<iterator_t<Base>>; constexpr iterator_t<Base> base() &&; constexpr decltype(auto) operator*() const { return invoke(*parent_->fun_, *current_); } constexpr iterator& operator++(); constexpr void operator++(int); constexpr iterator operator++(int) requires forward_­range<Base>; constexpr iterator& operator--() requires bidirectional_­range<Base>; constexpr iterator operator--(int) requires bidirectional_­range<Base>; constexpr iterator& operator+=(difference_type n) requires random_­access_­range<Base>; constexpr iterator& operator-=(difference_type n) requires random_­access_­range<Base>; constexpr decltype(auto) operator[](difference_type n) const requires random_­access_­range<Base> { return invoke(*parent_->fun_, current_[n]); } friend constexpr bool operator==(const iterator& x, const iterator& y) requires equality_­comparable<iterator_t<Base>>; friend constexpr bool operator<(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr bool operator>(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr bool operator<=(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr bool operator>=(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr auto operator<=>(const iterator& x, const iterator& y) requires random_­access_­range<Base> && three_­way_­comparable<iterator_t<Base>>; friend constexpr iterator operator+(iterator i, difference_type n) requires random_­access_­range<Base>; friend constexpr iterator operator+(difference_type n, iterator i) requires random_­access_­range<Base>; friend constexpr iterator operator-(iterator i, difference_type n) requires random_­access_­range<Base>; friend constexpr difference_type operator-(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr decltype(auto) iter_move(const iterator& i) noexcept(noexcept(invoke(*i.parent_->fun_, *i.current_))) { if constexpr (is_lvalue_reference_v<decltype(*i)>) return std::move(*i); else return *i; } friend constexpr void iter_swap(const iterator& x, const iterator& y) noexcept(noexcept(ranges::iter_swap(x.current_, y.current_))) requires indirectly_­swappable<iterator_t<Base>>; }; }
1
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iterator​::​iterator_­concept is defined as follows:
2
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iterator​::​iterator_­category is defined as follows: Let C denote the type iterator_­traits<iterator_­t<Base>>​::​iterator_­category.
  • (2.1)
    If is_­lvalue_­reference_­v<invoke_­result_­t<F&, range_­reference_­t<Base>>> is true, then
    • (2.1.1)
      if C models derived_­from<contiguous_­iterator_­tag>, iterator_­category denotes random_­access_­iterator_­tag;
    • (2.1.2)
      otherwise, iterator_­category denotes C.
  • (2.2)
    Otherwise, iterator_­category denotes input_­iterator_­tag.
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constexpr iterator(Parent& parent, iterator_t<Base> current);
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Effects: Initializes current_­ with std​::​move(current) and parent_­ with addressof(parent).
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constexpr iterator(iterator<!Const> i) requires Const && convertible_­to<iterator_t<V>, iterator_t<Base>>;
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Effects: Initializes current_­ with std​::​move(i.current_­) and parent_­ with i.parent_­.
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constexpr iterator_t<Base> base() const & requires copyable<iterator_t<Base>>;
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Effects: Equivalent to: return current_­;
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constexpr iterator_t<Base> base() &&;
6
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Effects: Equivalent to: return std​::​move(current_­);
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constexpr iterator& operator++();
7
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Effects: Equivalent to: ++current_; return *this;
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constexpr void operator++(int);
8
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Effects: Equivalent to ++current_­.
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constexpr iterator operator++(int) requires forward_­range<Base>;
9
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Effects: Equivalent to: auto tmp = *this; ++*this; return tmp;
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constexpr iterator& operator--() requires bidirectional_­range<Base>;
10
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Effects: Equivalent to: --current_; return *this;
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constexpr iterator operator--(int) requires bidirectional_­range<Base>;
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Effects: Equivalent to: auto tmp = *this; --*this; return tmp;
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constexpr iterator& operator+=(difference_type n) requires random_­access_­range<Base>;
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Effects: Equivalent to: current_ += n; return *this;
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constexpr iterator& operator-=(difference_type n) requires random_­access_­range<Base>;
13
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Effects: Equivalent to: current_ -= n; return *this;
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friend constexpr bool operator==(const iterator& x, const iterator& y) requires equality_comparable<iterator_t<Base>>;
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Effects: Equivalent to: return x.current_­ == y.current_­;
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friend constexpr bool operator<(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
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Effects: Equivalent to: return x.current_­ < y.current_­;
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friend constexpr bool operator>(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
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Effects: Equivalent to: return y < x;
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friend constexpr bool operator<=(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
17
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Effects: Equivalent to: return !(y < x);
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friend constexpr bool operator>=(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
18
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Effects: Equivalent to: return !(x < y);
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friend constexpr auto operator<=>(const iterator& x, const iterator& y) requires random_­access_­range<Base> && three_­way_­comparable<iterator_t<Base>>;
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Effects: Equivalent to: return x.current_­ <=> y.current_­;
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friend constexpr iterator operator+(iterator i, difference_type n) requires random_­access_­range<Base>; friend constexpr iterator operator+(difference_type n, iterator i) requires random_­access_­range<Base>;
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Effects: Equivalent to: return iterator{*i.parent_­, i.current_­ + n};
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friend constexpr iterator operator-(iterator i, difference_type n) requires random_­access_­range<Base>;
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Effects: Equivalent to: return iterator{*i.parent_­, i.current_­ - n};
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friend constexpr difference_type operator-(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
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Effects: Equivalent to: return x.current_­ - y.current_­;
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friend constexpr void iter_swap(const iterator& x, const iterator& y) noexcept(noexcept(ranges::iter_swap(x.current_­, y.current_­))) requires indirectly_­swappable<iterator_t<Base>>;
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Effects: Equivalent to ranges​::​iter_­swap(x.current_­, y.current_­).

24.7.6.4 Class template transform_­view​::​sentinel [range.transform.sentinel]

namespace std::ranges { template<input_­range V, copy_­constructible F> requires view<V> && is_object_v<F> && regular_invocable<F&, range_reference_t<V>> && can-reference<invoke_result_t<F&, range_reference_t<V>>> template<bool Const> class transform_view<V, F>::sentinel { private: using Parent = // exposition only conditional_t<Const, const transform_view, transform_view>; using Base = conditional_t<Const, const V, V>; // exposition only sentinel_t<Base> end_ = sentinel_t<Base>(); // exposition only public: sentinel() = default; constexpr explicit sentinel(sentinel_t<Base> end); constexpr sentinel(sentinel<!Const> i) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>; constexpr sentinel_t<Base> base() const; friend constexpr bool operator==(const iterator<Const>& x, const sentinel& y); friend constexpr range_difference_t<Base> operator-(const iterator<Const>& x, const sentinel& y) requires sized_­sentinel_­for<sentinel_t<Base>, iterator_t<Base>>; friend constexpr range_difference_t<Base> operator-(const sentinel& y, const iterator<Const>& x) requires sized_­sentinel_­for<sentinel_t<Base>, iterator_t<Base>>; }; }
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constexpr explicit sentinel(sentinel_t<Base> end);
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Effects: Initializes end_­ with end.
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constexpr sentinel(sentinel<!Const> i) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>;
2
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Effects: Initializes end_­ with std​::​move(i.end_­).
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constexpr sentinel_t<Base> base() const;
3
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Effects: Equivalent to: return end_­;
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friend constexpr bool operator==(const iterator<Const>& x, const sentinel& y);
4
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Effects: Equivalent to: return x.current_­ == y.end_­;
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friend constexpr range_difference_t<Base> operator-(const iterator<Const>& x, const sentinel& y) requires sized_­sentinel_­for<sentinel_t<Base>, iterator_t<Base>>;
5
#
Effects: Equivalent to: return x.current_­ - y.end_­;
🔗
friend constexpr range_difference_t<Base> operator-(const sentinel& y, const iterator<Const>& x) requires sized_­sentinel_­for<sentinel_t<Base>, iterator_t<Base>>;
6
#
Effects: Equivalent to: return y.end_­ - x.current_­;

24.7.7 Take view [range.take]

24.7.7.1 Overview [range.take.overview]

1
#
take_­view produces a view of the first N elements from another view, or all the elements if the adapted view contains fewer than N.
2
#
The name views​::​take denotes a range adaptor object ([range.adaptor.object]).
Let E and F be expressions, let T be remove_­cvref_­t<decltype((E))>, and let D be range_­difference_­t<decltype((E))>.
If decltype((F)) does not model convertible_­to<D>, views​::​take(E, F) is ill-formed.
Otherwise, the expression views​::​take(E, F) is expression-equivalent to:
3
#
[Example 1: vector<int> is{0,1,2,3,4,5,6,7,8,9}; take_view few{is, 5}; for (int i : few) cout << i << ' '; // prints: 0 1 2 3 4 — end example]

24.7.7.2 Class template take_­view [range.take.view]

namespace std::ranges { template<view V> class take_view : public view_interface<take_view<V>> { private: V base_ = V(); // exposition only range_difference_t<V> count_ = 0; // exposition only // [range.take.sentinel], class template take_­view​::​sentinel template<bool> struct sentinel; // exposition only public: take_view() = default; constexpr take_view(V base, range_difference_t<V> count); constexpr V base() const& requires copy_constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr auto begin() requires (!simple-view<V>) { if constexpr (sized_­range<V>) { if constexpr (random_­access_­range<V>) return ranges::begin(base_); else { auto sz = size(); return counted_iterator{ranges::begin(base_), sz}; } } else return counted_iterator{ranges::begin(base_), count_}; } constexpr auto begin() const requires range<const V> { if constexpr (sized_­range<const V>) { if constexpr (random_­access_­range<const V>) return ranges::begin(base_); else { auto sz = size(); return counted_iterator{ranges::begin(base_), sz}; } } else return counted_iterator{ranges::begin(base_), count_}; } constexpr auto end() requires (!simple-view<V>) { if constexpr (sized_­range<V>) { if constexpr (random_­access_­range<V>) return ranges::begin(base_) + size(); else return default_sentinel; } else return sentinel<false>{ranges::end(base_)}; } constexpr auto end() const requires range<const V> { if constexpr (sized_­range<const V>) { if constexpr (random_­access_­range<const V>) return ranges::begin(base_) + size(); else return default_sentinel; } else return sentinel<true>{ranges::end(base_)}; } constexpr auto size() requires sized_­range<V> { auto n = ranges::size(base_); return ranges::min(n, static_cast<decltype(n)>(count_)); } constexpr auto size() const requires sized_­range<const V> { auto n = ranges::size(base_); return ranges::min(n, static_cast<decltype(n)>(count_)); } }; template<range R> take_view(R&&, range_difference_t<R>) -> take_view<views::all_t<R>>; }
🔗
constexpr take_view(V base, range_difference_t<V> count);
1
#
Effects: Initializes base_­ with std​::​move(base) and count_­ with count.

24.7.7.3 Class template take_­view​::​sentinel [range.take.sentinel]

namespace std::ranges { template<view V> template<bool Const> class take_view<V>::sentinel { private: using Base = conditional_t<Const, const V, V>; // exposition only using CI = counted_iterator<iterator_t<Base>>; // exposition only sentinel_t<Base> end_ = sentinel_t<Base>(); // exposition only public: sentinel() = default; constexpr explicit sentinel(sentinel_t<Base> end); constexpr sentinel(sentinel<!Const> s) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>; constexpr sentinel_t<Base> base() const; friend constexpr bool operator==(const CI& y, const sentinel& x); }; }
🔗
constexpr explicit sentinel(sentinel_t<Base> end);
1
#
Effects: Initializes end_­ with end.
🔗
constexpr sentinel(sentinel<!Const> s) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>;
2
#
Effects: Initializes end_­ with std​::​move(s.end_­).
🔗
constexpr sentinel_t<Base> base() const;
3
#
Effects: Equivalent to: return end_­;
🔗
friend constexpr bool operator==(const CI& y, const sentinel& x);
4
#
Effects: Equivalent to: return y.count() == 0 || y.base() == x.end_­;

24.7.8 Take while view [range.take.while]

24.7.8.1 Overview [range.take.while.overview]

1
#
Given a unary predicate pred and a view r, take_­while_­view produces a view of the range [begin(r), ranges​::​find_­if_­not(r, pred)).
2
#
The name views​::​take_­while denotes a range adaptor object ([range.adaptor.object]).
Given subexpressions E and F, the expression views​::​take_­while(E, F) is expression-equivalent to take_­while_­view{E, F}.
3
#
[Example 1: auto input = istringstream{"0 1 2 3 4 5 6 7 8 9"}; auto small = [](const auto x) noexcept { return x < 5; }; auto small_ints = istream_view<int>(input) | views::take_while(small); for (const auto i : small_ints) { cout << i << ' '; // prints 0 1 2 3 4 } auto i = 0; input >> i; cout << i; // prints 6 — end example]

24.7.8.2 Class template take_­while_­view [range.take.while.view]

namespace std::ranges { template<view V, class Pred> requires input_­range<V> && is_object_v<Pred> && indirect_­unary_­predicate<const Pred, iterator_t<V>> class take_while_view : public view_interface<take_while_view<V, Pred>> { // [range.take.while.sentinel], class template take_­while_­view​::​sentinel template<bool> class sentinel; // exposition only V base_ = V(); // exposition only semiregular-box<Pred> pred_; // exposition only public: take_while_view() = default; constexpr take_while_view(V base, Pred pred); constexpr V base() const& requires copy_constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr const Pred& pred() const; constexpr auto begin() requires (!simple-view<V>) { return ranges::begin(base_); } constexpr auto begin() const requires range<const V> { return ranges::begin(base_); } constexpr auto end() requires (!simple-view<V>) { return sentinel<false>(ranges::end(base_), addressof(*pred_)); } constexpr auto end() const requires range<const V> { return sentinel<true>(ranges::end(base_), addressof(*pred_)); } }; template<class R, class Pred> take_while_view(R&&, Pred) -> take_while_view<views::all_t<R>, Pred>; }
🔗
constexpr take_while_view(V base, Pred pred);
1
#
Effects: Initializes base_­ with std​::​move(base) and pred_­ with std​::​move(pred).
🔗
constexpr const Pred& pred() const;
2
#
Effects: Equivalent to: return *pred_­;

24.7.8.3 Class template take_­while_­view​::​sentinel [range.take.while.sentinel]

namespace std::ranges { template<view V, class Pred> requires input_­range<V> && is_object_v<Pred> && indirect_­unary_­predicate<const Pred, iterator_t<V>> template<bool Const> class take_while_view<V, Pred>::sentinel { // exposition only using Base = conditional_t<Const, const V, V>; // exposition only sentinel_t<Base> end_ = sentinel_t<Base>(); // exposition only const Pred* pred_ = nullptr; // exposition only public: sentinel() = default; constexpr explicit sentinel(sentinel_t<Base> end, const Pred* pred); constexpr sentinel(sentinel<!Const> s) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>; constexpr sentinel_t<Base> base() const { return end_; } friend constexpr bool operator==(const iterator_t<Base>& x, const sentinel& y); }; }
🔗
constexpr explicit sentinel(sentinel_t<Base> end, const Pred* pred);
1
#
Effects: Initializes end_­ with end and pred_­ with pred.
🔗
constexpr sentinel(sentinel<!Const> s) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>;
2
#
Effects: Initializes end_­ with s.end_­ and pred_­ with s.pred_­.
🔗
friend constexpr bool operator==(const iterator_t<Base>& x, const sentinel& y);
3
#
Effects: Equivalent to: return y.end_­ == x || !invoke(*y.pred_­, *x);

24.7.9 Drop view [range.drop]

24.7.9.1 Overview [range.drop.overview]

1
#
drop_­view produces a view excluding the first N elements from another view, or an empty range if the adapted view contains fewer than N elements.
2
#
The name views​::​drop denotes a range adaptor object ([range.adaptor.object]).
Let E and F be expressions, let T be remove_­cvref_­t<decltype((E))>, and let D be range_­difference_­t<decltype((E))>.
If decltype((F)) does not model convertible_­to<D>, views​::​drop(E, F) is ill-formed.
Otherwise, the expression views​::​drop(E, F) is expression-equivalent to:
3
#
[Example 1: auto ints = views::iota(0) | views::take(10); auto latter_half = drop_view{ints, 5}; for (auto i : latter_half) { cout << i << ' '; // prints 5 6 7 8 9 } — end example]

24.7.9.2 Class template drop_­view [range.drop.view]

namespace std::ranges { template<view V> class drop_view : public view_interface<drop_view<V>> { public: drop_view() = default; constexpr drop_view(V base, range_difference_t<V> count); constexpr V base() const& requires copy_constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr auto begin() requires (!(simple-view<V> && random_­access_­range<V>)); constexpr auto begin() const requires random_­access_­range<const V>; constexpr auto end() requires (!simple-view<V>) { return ranges::end(base_); } constexpr auto end() const requires range<const V> { return ranges::end(base_); } constexpr auto size() requires sized_­range<V> { const auto s = ranges::size(base_); const auto c = static_cast<decltype(s)>(count_); return s < c ? 0 : s - c; } constexpr auto size() const requires sized_­range<const V> { const auto s = ranges::size(base_); const auto c = static_cast<decltype(s)>(count_); return s < c ? 0 : s - c; } private: V base_ = V(); // exposition only range_difference_t<V> count_ = 0; // exposition only }; template<class R> drop_view(R&&, range_difference_t<R>) -> drop_view<views::all_t<R>>; }
🔗
constexpr drop_view(V base, range_difference_t<V> count);
1
#
Preconditions: count >= 0 is true.
2
#
Effects: Initializes base_­ with std​::​move(base) and count_­ with count.
🔗
constexpr auto begin() requires (!(simple-view<V> && random_­access_­range<V>)); constexpr auto begin() const requires random_access_range<const V>;
3
#
Returns: ranges​::​next(ranges​::​begin(base_­), count_­, ranges​::​end(base_­)).
4
#
Remarks: In order to provide the amortized constant-time complexity required by the range concept when drop_­view models forward_­range, the first overload caches the result within the drop_­view for use on subsequent calls.
[Note 1:
Without this, applying a reverse_­view over a drop_­view would have quadratic iteration complexity.
— end note]

24.7.10 Drop while view [range.drop.while]

24.7.10.1 Overview [range.drop.while.overview]

1
#
Given a unary predicate pred and a view r, drop_­while_­view produces a view of the range [ranges​::​find_­if_­not(r, pred), ranges​::​end(r)).
2
#
The name views​::​drop_­while denotes a range adaptor object ([range.adaptor.object]).
Given subexpressions E and F, the expression views​::​drop_­while(E, F) is expression-equivalent to drop_­while_­view{E, F}.
3
#
[Example 1: constexpr auto source = " \t \t \t hello there"; auto is_invisible = [](const auto x) { return x == ' ' || x == '\t'; }; auto skip_ws = drop_while_view{source, is_invisible}; for (auto c : skip_ws) { cout << c; // prints hello there with no leading space } — end example]

24.7.10.2 Class template drop_­while_­view [range.drop.while.view]

namespace std::ranges { template<view V, class Pred> requires input_­range<V> && is_object_v<Pred> && indirect_­unary_­predicate<const Pred, iterator_t<V>> class drop_while_view : public view_interface<drop_while_view<V, Pred>> { public: drop_while_view() = default; constexpr drop_while_view(V base, Pred pred); constexpr V base() const& requires copy_constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr const Pred& pred() const; constexpr auto begin(); constexpr auto end() { return ranges::end(base_); } private: V base_ = V(); // exposition only semiregular-box<Pred> pred_; // exposition only }; template<class R, class Pred> drop_while_view(R&&, Pred) -> drop_while_view<views::all_t<R>, Pred>; }
🔗
constexpr drop_while_view(V base, Pred pred);
1
#
Effects: Initializes base_­ with std​::​move(base) and pred_­ with std​::​move(pred).
🔗
constexpr const Pred& pred() const;
2
#
Effects: Equivalent to: return *pred_­;
🔗
constexpr auto begin();
3
#
Returns: ranges​::​find_­if_­not(base_­, cref(*pred_­)).
4
#
Remarks: In order to provide the amortized constant-time complexity required by the range concept when drop_­while_­view models forward_­range, the first call caches the result within the drop_­while_­view for use on subsequent calls.
[Note 1:
Without this, applying a reverse_­view over a drop_­while_­view would have quadratic iteration complexity.
— end note]

24.7.11 Join view [range.join]

24.7.11.1 Overview [range.join.overview]

1
#
join_­view flattens a view of ranges into a view.
2
#
The name views​::​join denotes a range adaptor object ([range.adaptor.object]).
Given a subexpression E, the expression views​::​join(E) is expression-equivalent to join_­view{E}.
3
#
[Example 1: vector<string> ss{"hello", " ", "world", "!"}; join_view greeting{ss}; for (char ch : greeting) cout << ch; // prints: hello world! — end example]

24.7.11.2 Class template join_­view [range.join.view]

namespace std::ranges { template<input_­range V> requires view<V> && input_­range<range_reference_t<V>> && (is_reference_v<range_reference_t<V>> || view<range_value_t<V>>) class join_view : public view_interface<join_view<V>> { private: using InnerRng = // exposition only range_reference_t<V>; // [range.join.iterator], class template join_­view​::​iterator template<bool Const> struct iterator; // exposition only // [range.join.sentinel], class template join_­view​::​sentinel template<bool Const> struct sentinel; // exposition only V base_ = V(); // exposition only views::all_t<InnerRng> inner_ = // exposition only, present only when !is_­reference_­v<InnerRng> views::all_t<InnerRng>(); public: join_view() = default; constexpr explicit join_view(V base); constexpr V base() const& requires copy_­constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr auto begin() { constexpr bool use_const = simple-view<V> && is_reference_v<range_reference_t<V>>; return iterator<use_const>{*this, ranges::begin(base_)}; } constexpr auto begin() const requires input_­range<const V> && is_reference_v<range_reference_t<const V>> { return iterator<true>{*this, ranges::begin(base_)}; } constexpr auto end() { if constexpr (forward_­range<V> && is_reference_v<InnerRng> && forward_­range<InnerRng> && common_range<V> && common_range<InnerRng>) return iterator<simple-view<V>>{*this, ranges::end(base_)}; else return sentinel<simple-view<V>>{*this}; } constexpr auto end() const requires input_­range<const V> && is_reference_v<range_reference_t<const V>> { if constexpr (forward_­range<const V> && is_reference_v<range_reference_t<const V>> && forward_­range<range_reference_t<const V>> && common_range<const V> && common_range<range_reference_t<const V>>) return iterator<true>{*this, ranges::end(base_)}; else return sentinel<true>{*this}; } }; template<class R> explicit join_view(R&&) -> join_view<views::all_t<R>>; }
🔗
constexpr explicit join_view(V base);
1
#
Effects: Initializes base_­ with std​::​move(base).

24.7.11.3 Class template join_­view​::​iterator [range.join.iterator]

namespace std::ranges { template<input_­range V> requires view<V> && input_­range<range_reference_t<V>> && (is_reference_v<range_reference_t<V>> || view<range_value_t<V>>) template<bool Const> struct join_view<V>::iterator { private: using Parent = // exposition only conditional_t<Const, const join_view, join_view>; using Base = conditional_t<Const, const V, V>; // exposition only static constexpr bool ref-is-glvalue = // exposition only is_reference_v<range_reference_t<Base>>; iterator_t<Base> outer_ = iterator_t<Base>(); // exposition only iterator_t<range_reference_t<Base>> inner_ = // exposition only iterator_t<range_reference_t<Base>>(); Parent* parent_ = nullptr; // exposition only constexpr void satisfy(); // exposition only public: using iterator_concept = see below; using iterator_category = see below; using value_type = range_value_t<range_reference_t<Base>>; using difference_type = see below; iterator() = default; constexpr iterator(Parent& parent, iterator_t<Base> outer); constexpr iterator(iterator<!Const> i) requires Const && convertible_­to<iterator_t<V>, iterator_t<Base>> && convertible_­to<iterator_t<InnerRng>, iterator_t<range_reference_t<Base>>>; constexpr decltype(auto) operator*() const { return *inner_; } constexpr iterator_t<Base> operator->() const requires has-arrow<iterator_t<Base>> && copyable<iterator_t<Base>>; constexpr iterator& operator++(); constexpr void operator++(int); constexpr iterator operator++(int) requires ref-is-glvalue && forward_­range<Base> && forward_­range<range_reference_t<Base>>; constexpr iterator& operator--() requires ref-is-glvalue && bidirectional_­range<Base> && bidirectional_­range<range_reference_t<Base>> && common_range<range_reference_t<Base>>; constexpr iterator operator--(int) requires ref-is-glvalue && bidirectional_­range<Base> && bidirectional_­range<range_reference_t<Base>> && common_range<range_reference_t<Base>>; friend constexpr bool operator==(const iterator& x, const iterator& y) requires ref-is-glvalue && equality_­comparable<iterator_t<Base>> && equality_­comparable<iterator_t<range_reference_t<Base>>>; friend constexpr decltype(auto) iter_move(const iterator& i) noexcept(noexcept(ranges::iter_move(i.inner_))) { return ranges::iter_move(i.inner_); } friend constexpr void iter_swap(const iterator& x, const iterator& y) noexcept(noexcept(ranges::iter_swap(x.inner_, y.inner_))); }; }
1
#
iterator​::​iterator_­concept is defined as follows:
  • (1.1)
    If ref-is-glvalue is true and Base and range_­reference_­t<Base> each model bidirectional_­range, then iterator_­concept denotes bidirectional_­iterator_­tag.
  • (1.2)
    Otherwise, if ref-is-glvalue is true and Base and range_­reference_­t<Base> each model forward_­range, then iterator_­concept denotes forward_­iterator_­tag.
  • (1.3)
    Otherwise, iterator_­concept denotes input_­iterator_­tag.
2
#
iterator​::​iterator_­category is defined as follows:
  • (2.1)
    Let OUTERC denote iterator_­traits<iterator_­t<Base>>​::​iterator_­category, and let INNERC denote iterator_­traits<iterator_­t<range_­reference_­t<Base>>>​::​iterator_­category.
  • (2.2)
    If ref-is-glvalue is true and OUTERC and INNERC each model derived_­from<bidirectional_­iterator_­tag>, iterator_­category denotes bidirectional_­iterator_­tag.
  • (2.3)
    Otherwise, if ref-is-glvalue is true and OUTERC and INNERC each model derived_­from<forward_­iterator_­tag>, iterator_­category denotes forward_­iterator_­tag.
  • (2.4)
    Otherwise, if OUTERC and INNERC each model derived_­from<input_­iterator_­tag>, iterator_­category denotes input_­iterator_­tag.
  • (2.5)
    Otherwise, iterator_­category denotes output_­iterator_­tag.
3
#
iterator​::​difference_­type denotes the type: common_type_t< range_difference_t<Base>, range_difference_t<range_reference_t<Base>>>
4
#
join_­view iterators use the satisfy function to skip over empty inner ranges.
🔗
constexpr void satisfy(); // exposition only
5
#
Effects: Equivalent to: auto update_inner = [this](range_reference_t<Base> x) -> auto& { if constexpr (ref-is-glvalue) // x is a reference return x; else return (parent_->inner_ = views::all(std::move(x))); }; for (; outer_ != ranges::end(parent_->base_); ++outer_) { auto& inner = update_inner(*outer_); inner_ = ranges::begin(inner); if (inner_ != ranges::end(inner)) return; } if constexpr (ref-is-glvalue) inner_ = iterator_t<range_reference_t<Base>>();
🔗
constexpr iterator(Parent& parent, iterator_t<Base> outer);
6
#
Effects: Initializes outer_­ with std​::​move(outer) and parent_­ with addressof(parent); then calls satisfy().
🔗
constexpr iterator(iterator<!Const> i) requires Const && convertible_­to<iterator_t<V>, iterator_t<Base>> && convertible_­to<iterator_t<InnerRng>, iterator_t<range_reference_t<Base>>>;
7
#
Effects: Initializes outer_­ with std​::​move(i.outer_­), inner_­ with std​::​move(i.inner_­), and parent_­ with i.parent_­.
🔗
constexpr iterator_t<Base> operator->() const requires has-arrow<iterator_t<Base>> && copyable<iterator_t<Base>>;
8
#
Effects: Equivalent to return inner_­;
🔗
constexpr iterator& operator++();
9
#
Let inner-range be:
  • (9.1)
    If ref-is-glvalue is true, *outer_­.
  • (9.2)
    Otherwise, parent_­->inner_­.
10
#
Effects: Equivalent to: auto&& inner_rng = inner-range; if (++inner_ == ranges::end(inner_rng)) { ++outer_; satisfy(); } return *this;
🔗
constexpr void operator++(int);
11
#
Effects: Equivalent to: ++*this.
🔗
constexpr iterator operator++(int) requires ref-is-glvalue && forward_­range<Base> && forward_­range<range_reference_t<Base>>;
12
#
Effects: Equivalent to: auto tmp = *this; ++*this; return tmp;
🔗
constexpr iterator& operator--() requires ref-is-glvalue && bidirectional_­range<Base> && bidirectional_­range<range_reference_t<Base>> && common_range<range_reference_t<Base>>;
13
#
Effects: Equivalent to: if (outer_ == ranges::end(parent_->base_)) inner_ = ranges::end(*--outer_); while (inner_ == ranges::begin(*outer_)) inner_ = ranges::end(*--outer_); --inner_; return *this;
🔗
constexpr iterator operator--(int) requires ref-is-glvalue && bidirectional_­range<Base> && bidirectional_­range<range_reference_t<Base>> && common_range<range_reference_t<Base>>;
14
#
Effects: Equivalent to: auto tmp = *this; --*this; return tmp;
🔗
friend constexpr bool operator==(const iterator& x, const iterator& y) requires ref-is-glvalue && equality_comparable<iterator_t<Base>> && equality_comparable<iterator_t<range_reference_t<Base>>>;
15
#
Effects: Equivalent to: return x.outer_­ == y.outer_­ && x.inner_­ == y.inner_­;
🔗
friend constexpr void iter_swap(const iterator& x, const iterator& y) noexcept(noexcept(ranges::iter_swap(x.inner_­, y.inner_­)));
16
#
Effects: Equivalent to: return ranges​::​iter_­swap(x.inner_­, y.inner_­);

24.7.11.4 Class template join_­view​::​sentinel [range.join.sentinel]

namespace std::ranges { template<input_­range V> requires view<V> && input_­range<range_reference_t<V>> && (is_reference_v<range_reference_t<V>> || view<range_value_t<V>>) template<bool Const> struct join_view<V>::sentinel { private: using Parent = // exposition only conditional_t<Const, const join_view, join_view>; using Base = conditional_t<Const, const V, V>; // exposition only sentinel_t<Base> end_ = sentinel_t<Base>(); // exposition only public: sentinel() = default; constexpr explicit sentinel(Parent& parent); constexpr sentinel(sentinel<!Const> s) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>; friend constexpr bool operator==(const iterator<Const>& x, const sentinel& y); }; }
🔗
constexpr explicit sentinel(Parent& parent);
1
#
Effects: Initializes end_­ with ranges​::​end(parent.base_­).
🔗
constexpr sentinel(sentinel<!Const> s) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>;
2
#
Effects: Initializes end_­ with std​::​move(s.end_­).
🔗
friend constexpr bool operator==(const iterator<Const>& x, const sentinel& y);
3
#
Effects: Equivalent to: return x.outer_­ == y.end_­;

24.7.12 Split view [range.split]

24.7.12.1 Overview [range.split.overview]

1
#
split_­view takes a view and a delimiter, and splits the view into subranges on the delimiter.
The delimiter can be a single element or a view of elements.
2
#
The name views​::​split denotes a range adaptor object ([range.adaptor.object]).
Given subexpressions E and F, the expression views​::​split(E, F) is expression-equivalent to split_­view{E, F}.
3
#
[Example 1: string str{"the quick brown fox"}; split_view sentence{str, ' '}; for (auto word : sentence) { for (char ch : word) cout << ch; cout << '*'; } // The above prints: the*quick*brown*fox* — end example]

24.7.12.2 Class template split_­view [range.split.view]

namespace std::ranges { template<auto> struct require-constant; // exposition only template<class R> concept tiny-range = // exposition only sized_range<R> && requires { typename require-constant<remove_reference_t<R>::size()>; } && (remove_reference_t<R>::size() <= 1); template<input_­range V, forward_­range Pattern> requires view<V> && view<Pattern> && indirectly_­comparable<iterator_t<V>, iterator_t<Pattern>, ranges::equal_to> && (forward_­range<V> || tiny-range<Pattern>) class split_view : public view_interface<split_view<V, Pattern>> { private: V base_ = V(); // exposition only Pattern pattern_ = Pattern(); // exposition only iterator_t<V> current_ = iterator_t<V>(); // exposition only, present only if !forward_­range<V> // [range.split.outer], class template split_­view​::​outer-iterator template<bool> struct outer-iterator; // exposition only // [range.split.inner], class template split_­view​::​inner-iterator template<bool> struct inner-iterator; // exposition only public: split_view() = default; constexpr split_view(V base, Pattern pattern); template<input_­range R> requires constructible_­from<V, views::all_t<R>> && constructible_­from<Pattern, single_view<range_value_t<R>>> constexpr split_view(R&& r, range_value_t<R> e); constexpr V base() const& requires copy_constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr auto begin() { if constexpr (forward_­range<V>) return outer-iterator<simple-view<V>>{*this, ranges::begin(base_)}; else { current_ = ranges::begin(base_); return outer-iterator<false>{*this}; } } constexpr auto begin() const requires forward_­range<V> && forward_­range<const V> { return outer-iterator<true>{*this, ranges::begin(base_)}; } constexpr auto end() requires forward_­range<V> && common_range<V> { return outer-iterator<simple-view<V>>{*this, ranges::end(base_)}; } constexpr auto end() const { if constexpr (forward_­range<V> && forward_­range<const V> && common_range<const V>) return outer-iterator<true>{*this, ranges::end(base_)}; else return default_sentinel; } }; template<class R, class P> split_view(R&&, P&&) -> split_view<views::all_t<R>, views::all_t<P>>; template<input_­range R> split_view(R&&, range_value_t<R>) -> split_view<views::all_t<R>, single_view<range_value_t<R>>>; }
🔗
constexpr split_view(V base, Pattern pattern);
1
#
Effects: Initializes base_­ with std​::​move(base), and pattern_­ with std​::​move(pattern).
🔗
template<input_­range R> requires constructible_­from<V, views::all_t<R>> && constructible_­from<Pattern, single_view<range_value_t<R>>> constexpr split_view(R&& r, range_value_t<R> e);
2
#
Effects: Initializes base_­ with views​::​all(std​::​forward<R>(r)), and pattern_­ with single_­view{​std​::​move(e)}.

24.7.12.3 Class template split_­view​::​outer-iterator [range.split.outer]

namespace std::ranges { template<input_­range V, forward_­range Pattern> requires view<V> && view<Pattern> && indirectly_­comparable<iterator_t<V>, iterator_t<Pattern>, ranges::equal_to> && (forward_­range<V> || tiny-range<Pattern>) template<bool Const> struct split_view<V, Pattern>::outer-iterator { private: using Parent = // exposition only conditional_t<Const, const split_view, split_view>; using Base = // exposition only conditional_t<Const, const V, V>; Parent* parent_ = nullptr; // exposition only iterator_t<Base> current_ = // exposition only, present only if V models forward_­range iterator_t<Base>(); public: using iterator_concept = conditional_t<forward_­range<Base>, forward_iterator_tag, input_iterator_tag>; using iterator_category = input_iterator_tag; // [range.split.outer.value], class split_­view​::​outer-iterator​::​value_­type struct value_type; using difference_type = range_difference_t<Base>; outer-iterator() = default; constexpr explicit outer-iterator(Parent& parent) requires (!forward_­range<Base>); constexpr outer-iterator(Parent& parent, iterator_t<Base> current) requires forward_­range<Base>; constexpr outer-iterator(outer-iterator<!Const> i) requires Const && convertible_­to<iterator_t<V>, iterator_t<Base>>; constexpr value_type operator*() const; constexpr outer-iterator& operator++(); constexpr decltype(auto) operator++(int) { if constexpr (forward_­range<Base>) { auto tmp = *this; ++*this; return tmp; } else ++*this; } friend constexpr bool operator==(const outer-iterator& x, const outer-iterator& y) requires forward_­range<Base>; friend constexpr bool operator==(const outer-iterator& x, default_sentinel_t); }; }
1
#
Many of the following specifications refer to the notional member current of outer-iterator.
current is equivalent to current_­ if V models forward_­range, and parent_­->current_­ otherwise.
🔗
constexpr explicit outer-iterator(Parent& parent) requires (!forward_­range<Base>);
2
#
Effects: Initializes parent_­ with addressof(parent).
🔗
constexpr outer-iterator(Parent& parent, iterator_t<Base> current) requires forward_­range<Base>;
3
#
Effects: Initializes parent_­ with addressof(parent) and current_­ with std​::​move(current).
🔗
constexpr outer-iterator(outer-iterator<!Const> i) requires Const && convertible_­to<iterator_t<V>, iterator_t<Base>>;
4
#
Effects: Initializes parent_­ with i.parent_­ and current_­ with std​::​move(i.current_­).
🔗
constexpr value_type operator*() const;
5
#
Effects: Equivalent to: return value_­type{*this};
🔗
constexpr outer-iterator& operator++();
6
#
Effects: Equivalent to: const auto end = ranges::end(parent_->base_); if (current == end) return *this; const auto [pbegin, pend] = subrange{parent_->pattern_}; if (pbegin == pend) ++current; else { do { auto [b, p] = ranges::mismatch(std::move(current), end, pbegin, pend); current = std::move(b); if (p == pend) { break; // The pattern matched; skip it } } while (++current != end); } return *this;
🔗
friend constexpr bool operator==(const outer-iterator& x, const outer-iterator& y) requires forward_­range<Base>;
7
#
Effects: Equivalent to: return x.current_­ == y.current_­;
🔗
friend constexpr bool operator==(const outer-iterator& x, default_sentinel_t);
8
#
Effects: Equivalent to: return x.current == ranges​::​end(x.parent_­->base_­);

24.7.12.4 Class split_­view​::​outer-iterator​::​value_­type [range.split.outer.value]

namespace std::ranges { template<input_­range V, forward_­range Pattern> requires view<V> && view<Pattern> && indirectly_­comparable<iterator_t<V>, iterator_t<Pattern>, ranges::equal_to> && (forward_­range<V> || tiny-range<Pattern>) template<bool Const> struct split_view<V, Pattern>::outer-iterator<Const>::value_type : view_interface<value_type> { private: outer-iterator i_ = outer-iterator(); // exposition only public: value_type() = default; constexpr explicit value_type(outer-iterator i); constexpr inner-iterator<Const> begin() const requires copyable<outer-iterator>; constexpr inner-iterator<Const> begin() requires (!copyable<outer-iterator>); constexpr default_sentinel_t end() const; }; }
🔗
constexpr explicit value_type(outer-iterator i);
1
#
Effects: Initializes i_­ with std​::​move(i).
🔗
constexpr inner-iterator<Const> begin() const requires copyable<outer-iterator>;
2
#
Effects: Equivalent to: return inner-iterator<Const>{i_­};
🔗
constexpr inner-iterator<Const> begin() requires (!copyable<outer-iterator>);
3
#
Effects: Equivalent to: return inner-iterator<Const>{std​::​move(i_­)};
🔗
constexpr default_sentinel_t end() const;
4
#
Effects: Equivalent to: return default_­sentinel;

24.7.12.5 Class template split_­view​::​inner-iterator [range.split.inner]

namespace std::ranges { template<input_­range V, forward_­range Pattern> requires view<V> && view<Pattern> && indirectly_­comparable<iterator_t<V>, iterator_t<Pattern>, ranges::equal_to> && (forward_­range<V> || tiny-range<Pattern>) template<bool Const> struct split_view<V, Pattern>::inner-iterator { private: using Base = conditional_t<Const, const V, V>; // exposition only outer-iterator<Const> i_ = outer-iterator<Const>(); // exposition only bool incremented_ = false; // exposition only public: using iterator_concept = typename outer-iterator<Const>::iterator_concept; using iterator_category = see below; using value_type = range_value_t<Base>; using difference_type = range_difference_t<Base>; inner-iterator() = default; constexpr explicit inner-iterator(outer-iterator<Const> i); constexpr decltype(auto) operator*() const { return *i_.current; } constexpr inner-iterator& operator++(); constexpr decltype(auto) operator++(int) { if constexpr (forward_­range<V>) { auto tmp = *this; ++*this; return tmp; } else ++*this; } friend constexpr bool operator==(const inner-iterator& x, const inner-iterator& y) requires forward_­range<Base>; friend constexpr bool operator==(const inner-iterator& x, default_sentinel_t); friend constexpr decltype(auto) iter_move(const inner-iterator& i) noexcept(noexcept(ranges::iter_move(i.i_.current))) { return ranges::iter_move(i.i_.current); } friend constexpr void iter_swap(const inner-iterator& x, const inner-iterator& y) noexcept(noexcept(ranges::iter_swap(x.i_.current, y.i_.current))) requires indirectly_­swappable<iterator_t<Base>>; }; }
1
#
The typedef-name iterator_­category denotes:
  • (1.1)
    forward_­iterator_­tag if iterator_­traits<iterator_­t<Base>>​::​iterator_­category models
    derived_­from<forward_­iterator_­tag>;
  • (1.2)
    otherwise, iterator_­traits<iterator_­t<Base>>​::​iterator_­category.
🔗
constexpr explicit inner-iterator(outer-iterator<Const> i);
2
#
Effects: Initializes i_­ with std​::​move(i).
🔗
constexpr inner-iterator& operator++();
3
#
Effects: Equivalent to: incremented_ = true; if constexpr (!forward_­range<Base>) { if constexpr (Pattern::size() == 0) { return *this; } } ++i_.current; return *this;
🔗
friend constexpr bool operator==(const inner-iterator& x, const inner-iterator& y) requires forward_­range<Base>;
4
#
Effects: Equivalent to: return x.i_­.current == y.i_­.current;
🔗
friend constexpr bool operator==(const inner-iterator& x, default_sentinel_t);
5
#
Effects: Equivalent to: auto [pcur, pend] = subrange{x.i_.parent_->pattern_}; auto end = ranges::end(x.i_.parent_->base_); if constexpr (tiny-range<Pattern>) { const auto & cur = x.i_.current; if (cur == end) return true; if (pcur == pend) return x.incremented_; return *cur == *pcur; } else { auto cur = x.i_.current; if (cur == end) return true; if (pcur == pend) return x.incremented_; do { if (*cur != *pcur) return false; if (++pcur == pend) return true; } while (++cur != end); return false; }
🔗
friend constexpr void iter_swap(const inner-iterator& x, const inner-iterator& y) noexcept(noexcept(ranges::iter_swap(x.i_­.current, y.i_­.current))) requires indirectly_­swappable<iterator_t<Base>>;
6
#
Effects: Equivalent to ranges​::​iter_­swap(x.i_­.current, y.i_­.current).

24.7.13 Counted view [range.counted]

1
#
A counted view presents a view of the elements of the counted range ([iterator.requirements.general]) for an iterator i and non-negative integer n.
2
#
The name views​::​counted denotes a customization point object ([customization.point.object]).
Let E and F be expressions, let T be decay_­t<decltype((E))>, and let D be iter_­difference_­t<T>.
If decltype((F)) does not model convertible_­to<D>, views​::​counted(E, F) is ill-formed.
[Note 1:
This case can result in substitution failure when views​::​counted(E, F) appears in the immediate context of a template instantiation.
— end note]
Otherwise, views​::​counted(E, F) is expression-equivalent to:

24.7.14 Common view [range.common]

24.7.14.1 Overview [range.common.overview]

1
#
common_­view takes a view which has different types for its iterator and sentinel and turns it into a view of the same elements with an iterator and sentinel of the same type.
2
#
[Note 1:
common_­view is useful for calling legacy algorithms that expect a range's iterator and sentinel types to be the same.
— end note]
3
#
The name views​::​common denotes a range adaptor object ([range.adaptor.object]).
Given a subexpression E, the expression views​::​common(E) is expression-equivalent to:
  • (3.1)
    views​::​all(E), if decltype((E)) models common_­range and views​::​all(E) is a well-formed expression.
  • (3.2)
    Otherwise, common_­view{E}.
4
#
[Example 1: // Legacy algorithm: template<class ForwardIterator> size_t count(ForwardIterator first, ForwardIterator last); template<forward_­range R> void my_algo(R&& r) { auto&& common = common_view{r}; auto cnt = count(common.begin(), common.end()); // ... } — end example]

24.7.14.2 Class template common_­view [range.common.view]

namespace std::ranges { template<view V> requires (!common_range<V> && copyable<iterator_t<V>>) class common_view : public view_interface<common_view<V>> { private: V base_ = V(); // exposition only public: common_view() = default; constexpr explicit common_view(V r); template<viewable_­range R> requires (!common_range<R> && constructible_­from<V, views::all_t<R>>) constexpr explicit common_view(R&& r); constexpr V base() const& requires copy_­constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr auto begin() { if constexpr (random_­access_­range<V> && sized_­range<V>) return ranges::begin(base_); else return common_iterator<iterator_t<V>, sentinel_t<V>>(ranges::begin(base_)); } constexpr auto begin() const requires range<const V> { if constexpr (random_­access_­range<const V> && sized_­range<const V>) return ranges::begin(base_); else return common_iterator<iterator_t<const V>, sentinel_t<const V>>(ranges::begin(base_)); } constexpr auto end() { if constexpr (random_­access_­range<V> && sized_­range<V>) return ranges::begin(base_) + ranges::size(base_); else return common_iterator<iterator_t<V>, sentinel_t<V>>(ranges::end(base_)); } constexpr auto end() const requires range<const V> { if constexpr (random_­access_­range<const V> && sized_­range<const V>) return ranges::begin(base_) + ranges::size(base_); else return common_iterator<iterator_t<const V>, sentinel_t<const V>>(ranges::end(base_)); } constexpr auto size() requires sized_range<V> { return ranges::size(base_); } constexpr auto size() const requires sized_range<const V> { return ranges::size(base_); } }; template<class R> common_view(R&&) -> common_view<views::all_t<R>>; }
🔗
constexpr explicit common_view(V base);
1
#
Effects: Initializes base_­ with std​::​move(base).
🔗
template<viewable_range R> requires (!common_range<R> && constructible_­from<V, views::all_t<R>>) constexpr explicit common_view(R&& r);
2
#
Effects: Initializes base_­ with views​::​all(std​::​forward<R>(r)).

24.7.15 Reverse view [range.reverse]

24.7.15.1 Overview [range.reverse.overview]

1
#
reverse_­view takes a bidirectional view and produces another view that iterates the same elements in reverse order.
2
#
The name views​::​reverse denotes a range adaptor object ([range.adaptor.object]).
Given a subexpression E, the expression views​::​reverse(E) is expression-equivalent to:
  • (2.1)
    If the type of E is a (possibly cv-qualified) specialization of reverse_­view, equivalent to E.base().
  • (2.2)
    Otherwise, if the type of E is cv subrange<reverse_­iterator<I>, reverse_­iterator<I>, K> for some iterator type I and value K of type subrange_­kind,
    • (2.2.1)
      if K is subrange_­kind​::​sized, equivalent to: subrange<I, I, K>(E.end().base(), E.begin().base(), E.size())
    • (2.2.2)
      otherwise, equivalent to: subrange<I, I, K>(E.end().base(), E.begin().base())
    However, in either case E is evaluated only once.
  • (2.3)
    Otherwise, equivalent to reverse_­view{E}.
3
#
[Example 1: vector<int> is {0,1,2,3,4}; reverse_view rv {is}; for (int i : rv) cout << i << ' '; // prints: 4 3 2 1 0 — end example]

24.7.15.2 Class template reverse_­view [range.reverse.view]

namespace std::ranges { template<view V> requires bidirectional_­range<V> class reverse_view : public view_interface<reverse_view<V>> { private: V base_ = V(); // exposition only public: reverse_view() = default; constexpr explicit reverse_view(V r); constexpr V base() const& requires copy_­constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr reverse_iterator<iterator_t<V>> begin(); constexpr reverse_iterator<iterator_t<V>> begin() requires common_range<V>; constexpr auto begin() const requires common_range<const V>; constexpr reverse_iterator<iterator_t<V>> end(); constexpr auto end() const requires common_range<const V>; constexpr auto size() requires sized_­range<V> { return ranges::size(base_); } constexpr auto size() const requires sized_­range<const V> { return ranges::size(base_); } }; template<class R> reverse_view(R&&) -> reverse_view<views::all_t<R>>; }
🔗
constexpr explicit reverse_view(V base);
1
#
Effects: Initializes base_­ with std​::​move(base).
🔗
constexpr reverse_iterator<iterator_t<V>> begin();
2
#
Returns: make_reverse_iterator(ranges::next(ranges::begin(base_), ranges::end(base_)))
3
#
Remarks: In order to provide the amortized constant time complexity required by the range concept, this function caches the result within the reverse_­view for use on subsequent calls.
🔗
constexpr reverse_iterator<iterator_t<V>> begin() requires common_range<V>; constexpr auto begin() const requires common_range<const V>;
4
#
Effects: Equivalent to: return make_­reverse_­iterator(ranges​::​end(base_­));
🔗
constexpr reverse_iterator<iterator_t<V>> end(); constexpr auto end() const requires common_range<const V>;
5
#
Effects: Equivalent to: return make_­reverse_­iterator(ranges​::​begin(base_­));

24.7.16 Elements view [range.elements]

24.7.16.1 Overview [range.elements.overview]

1
#
elements_­view takes a view of tuple-like values and a size_­t, and produces a view with a value-type of the element of the adapted view's value-type.
2
#
The name views​::​elements<N> denotes a range adaptor object ([range.adaptor.object]).
Given a subexpression E and constant expression N, the expression views​::​elements<N>(E) is expression-equivalent to elements_­view<views​::​all_­t<decltype((E))>, N>{E}.
[Example 1: auto historical_figures = map{ {"Lovelace"sv, 1815}, {"Turing"sv, 1912}, {"Babbage"sv, 1791}, {"Hamilton"sv, 1936} }; auto names = historical_figures | views::elements<0>; for (auto&& name : names) { cout << name << ' '; // prints Babbage Hamilton Lovelace Turing } auto birth_years = historical_figures | views::elements<1>; for (auto&& born : birth_years) { cout << born << ' '; // prints 1791 1936 1815 1912 } — end example]
3
#
keys_­view is an alias for elements_­view<views​::​all_­t<R>, 0>, and is useful for extracting keys from associative containers.
[Example 2: auto names = keys_view{historical_figures}; for (auto&& name : names) { cout << name << ' '; // prints Babbage Hamilton Lovelace Turing } — end example]
4
#
values_­view is an alias for elements_­view<views​::​all_­t<R>, 1>, and is useful for extracting values from associative containers.
[Example 3: auto is_even = [](const auto x) { return x % 2 == 0; }; cout << ranges::count_if(values_view{historical_figures}, is_even); // prints 2 — end example]

24.7.16.2 Class template elements_­view [range.elements.view]

namespace std::ranges { template<class T, size_t N> concept has-tuple-element = // exposition only requires(T t) { typename tuple_size<T>::type; requires N < tuple_size_v<T>; typename tuple_element_t<N, T>; { get<N>(t) } -> convertible_to<const tuple_element_t<N, T>&>; }; template<input_range V, size_t N> requires view<V> && has-tuple-element<range_value_t<V>, N> && has-tuple-element<remove_reference_t<range_reference_t<V>>, N> class elements_view : public view_interface<elements_view<V, N>> { public: elements_view() = default; constexpr explicit elements_view(V base); constexpr V base() const& requires copy_constructible<V> { return base_; } constexpr V base() && { return std::move(base_); } constexpr auto begin() requires (!simple-view<V>) { return iterator<false>(ranges::begin(base_)); } constexpr auto begin() const requires simple-view<V> { return iterator<true>(ranges::begin(base_)); } constexpr auto end() { return sentinel<false>{ranges::end(base_)}; } constexpr auto end() requires common_range<V> { return iterator<false>{ranges::end(base_)}; } constexpr auto end() const requires range<const V> { return sentinel<true>{ranges::end(base_)}; } constexpr auto end() const requires common_range<const V> { return iterator<true>{ranges::end(base_)}; } constexpr auto size() requires sized_range<V> { return ranges::size(base_); } constexpr auto size() const requires sized_range<const V> { return ranges::size(base_); } private: // [range.elements.iterator], class template elements_­view​::​iterator template<bool> struct iterator; // exposition only // [range.elements.sentinel], class template elements_­view​::​sentinel template<bool> struct sentinel; // exposition only V base_ = V(); // exposition only }; }
🔗
constexpr explicit elements_view(V base);
1
#
Effects: Initializes base_­ with std​::​move(base).

24.7.16.3 Class template elements_­view​::​iterator [range.elements.iterator]

namespace std::ranges { template<input_range V, size_t N> requires view<V> && has-tuple-element<range_value_t<V>, N> && has-tuple-element<remove_reference_t<range_reference_t<V>>, N> template<bool Const> class elements_view<V, N>::iterator { // exposition only using Base = conditional_t<Const, const V, V>; // exposition only iterator_t<Base> current_ = iterator_t<Base>(); public: using iterator_category = typename iterator_traits<iterator_t<Base>>::iterator_category; using value_type = remove_cvref_t<tuple_element_t<N, range_value_t<Base>>>; using difference_type = range_difference_t<Base>; iterator() = default; constexpr explicit iterator(iterator_t<Base> current); constexpr iterator(iterator<!Const> i) requires Const && convertible_­to<iterator_t<V>, iterator_t<Base>>; constexpr iterator_t<Base> base() const& requires copyable<iterator_t<Base>>; constexpr iterator_t<Base> base() &&; constexpr decltype(auto) operator*() const { return get<N>(*current_); } constexpr iterator& operator++(); constexpr void operator++(int) requires (!forward_­range<Base>); constexpr iterator operator++(int) requires forward_­range<Base>; constexpr iterator& operator--() requires bidirectional_­range<Base>; constexpr iterator operator--(int) requires bidirectional_­range<Base>; constexpr iterator& operator+=(difference_type x) requires random_­access_­range<Base>; constexpr iterator& operator-=(difference_type x) requires random_­access_­range<Base>; constexpr decltype(auto) operator[](difference_type n) const requires random_­access_­range<Base> { return get<N>(*(current_ + n)); } friend constexpr bool operator==(const iterator& x, const iterator& y) requires equality_­comparable<iterator_t<Base>>; friend constexpr bool operator<(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr bool operator>(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr bool operator<=(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr bool operator>=(const iterator& x, const iterator& y) requires random_­access_­range<Base>; friend constexpr auto operator<=>(const iterator& x, const iterator& y) requires random_­access_­range<Base> && three_­way_­comparable<iterator_t<Base>>; friend constexpr iterator operator+(const iterator& x, difference_type y) requires random_­access_­range<Base>; friend constexpr iterator operator+(difference_type x, const iterator& y) requires random_­access_­range<Base>; friend constexpr iterator operator-(const iterator& x, difference_type y) requires random_­access_­range<Base>; friend constexpr difference_type operator-(const iterator& x, const iterator& y) requires random_­access_­range<Base>; }; }
🔗
constexpr explicit iterator(iterator_t<Base> current);
1
#
Effects: Initializes current_­ with std​::​move(current).
🔗
constexpr iterator(iterator<!Const> i) requires Const && convertible_­to<iterator_t<V>, iterator_t<Base>>;
2
#
Effects: Initializes current_­ with std​::​move(i.current_­).
🔗
constexpr iterator_t<Base> base() const& requires copyable<iterator_t<Base>>;
3
#
Effects: Equivalent to: return current_­;
🔗
constexpr iterator_t<Base> base() &&;
4
#
Effects: Equivalent to: return std​::​move(current_­);
🔗
constexpr iterator& operator++();
5
#
Effects: Equivalent to: ++current_; return *this;
🔗
constexpr void operator++(int) requires (!forward_­range<Base>);
6
#
Effects: Equivalent to: ++current_­.
🔗
constexpr iterator operator++(int) requires forward_­range<Base>;
7
#
Effects: Equivalent to: auto temp = *this; ++current_; return temp;
🔗
constexpr iterator& operator--() requires bidirectional_­range<Base>;
8
#
Effects: Equivalent to: --current_; return *this;
🔗
constexpr iterator operator--(int) requires bidirectional_­range<Base>;
9
#
Effects: Equivalent to: auto temp = *this; --current_; return temp;
🔗
constexpr iterator& operator+=(difference_type n); requires random_­access_­range<Base>;
10
#
Effects: Equivalent to: current_ += n; return *this;
🔗
constexpr iterator& operator-=(difference_type n) requires random_­access_­range<Base>;
11
#
Effects: Equivalent to: current_ -= n; return *this;
🔗
friend constexpr bool operator==(const iterator& x, const iterator& y) requires equality_comparable<Base>;
12
#
Effects: Equivalent to: return x.current_­ == y.current_­;
🔗
friend constexpr bool operator<(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
13
#
Effects: Equivalent to: return x.current_­ < y.current_­;
🔗
friend constexpr bool operator>(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
14
#
Effects: Equivalent to: return y < x;
🔗
friend constexpr bool operator<=(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
15
#
Effects: Equivalent to: return !(y < x);
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friend constexpr bool operator>=(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
16
#
Effects: Equivalent to: return !(x < y);
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friend constexpr auto operator<=>(const iterator& x, const iterator& y) requires random_­access_­range<Base> && three_­way_­comparable<iterator_t<Base>>;
17
#
Effects: Equivalent to: return x.current_­ <=> y.current_­;
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friend constexpr iterator operator+(const iterator& x, difference_type y) requires random_­access_­range<Base>;
18
#
Effects: Equivalent to: return iterator{x} += y;
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friend constexpr iterator operator+(difference_type x, const iterator& y) requires random_­access_­range<Base>;
19
#
Effects: Equivalent to: return y + x;
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friend constexpr iterator operator-(const iterator& x, difference_type y) requires random_­access_­range<Base>;
20
#
Effects: Equivalent to: return iterator{x} -= y;
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friend constexpr difference_type operator-(const iterator& x, const iterator& y) requires random_­access_­range<Base>;
21
#
Effects: Equivalent to: return x.current_­ - y.current_­;

24.7.16.4 Class template elements_­view​::​sentinel [range.elements.sentinel]

namespace std::ranges { template<input_range V, size_t N> requires view<V> && has-tuple-element<range_value_t<V>, N> && has-tuple-element<remove_reference_t<range_reference_t<V>>, N> template<bool Const> class elements_view<V, N>::sentinel { // exposition only private: using Base = conditional_t<Const, const V, V>; // exposition only sentinel_t<Base> end_ = sentinel_t<Base>(); // exposition only public: sentinel() = default; constexpr explicit sentinel(sentinel_t<Base> end); constexpr sentinel(sentinel<!Const> other) requires Const && convertible_to<sentinel_t<V>, sentinel_t<Base>>; constexpr sentinel_t<Base> base() const; friend constexpr bool operator==(const iterator<Const>& x, const sentinel& y); friend constexpr range_difference_t<Base> operator-(const iterator<Const>& x, const sentinel& y) requires sized_sentinel_for<sentinel_t<Base>, iterator_t<Base>>; friend constexpr range_difference_t<Base> operator-(const sentinel& x, const iterator<Const>& y) requires sized_sentinel_for<sentinel_t<Base>, iterator_t<Base>>; }; }
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constexpr explicit sentinel(sentinel_t<Base> end);
1
#
Effects: Initializes end_­ with end.
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constexpr sentinel(sentinel<!Const> other) requires Const && convertible_­to<sentinel_t<V>, sentinel_t<Base>>;
2
#
Effects: Initializes end_­ with std​::​move(other.end_­).
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constexpr sentinel_t<Base> base() const;
3
#
Effects: Equivalent to: return end_­;
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friend constexpr bool operator==(const iterator<Const>& x, const sentinel& y);
4
#
Effects: Equivalent to: return x.current_­ == y.end_­;
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friend constexpr range_difference_t<Base> operator-(const iterator<Const>& x, const sentinel& y) requires sized_sentinel_for<sentinel_t<Base>, iterator_t<Base>>;
5
#
Effects: Equivalent to: return x.current_­ - y.end_­;
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friend constexpr range_difference_t<Base> operator-(const sentinel& x, const iterator<Const>& y) requires sized_sentinel_for<sentinel_t<Base>, iterator_t<Base>>;
6
#
Effects: Equivalent to: return x.end_­ - y.current_­;