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//===----------------------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#ifndef SUPPORT_TEST_ITERATORS_H
#define SUPPORT_TEST_ITERATORS_H
#include <cassert>
#include <concepts>
#include <iterator>
#include <ranges>
#include <stdexcept>
#include <type_traits>
#include <utility>
#include "test_macros.h"
#include "type_algorithms.h"
// This iterator meets C++20's Cpp17OutputIterator requirements, as described
// in Table 90 ([output.iterators]).
template <class It>
class cpp17_output_iterator
{
It it_;
template <class U> friend class cpp17_output_iterator;
public:
typedef std::output_iterator_tag iterator_category;
typedef void value_type;
typedef typename std::iterator_traits<It>::difference_type difference_type;
typedef It pointer;
typedef typename std::iterator_traits<It>::reference reference;
TEST_CONSTEXPR explicit cpp17_output_iterator(It it) : it_(std::move(it)) {}
template <class U>
TEST_CONSTEXPR cpp17_output_iterator(const cpp17_output_iterator<U>& u) : it_(u.it_) {}
template <class U, class = typename std::enable_if<std::is_default_constructible<U>::value>::type>
TEST_CONSTEXPR_CXX14 cpp17_output_iterator(cpp17_output_iterator<U>&& u) : it_(u.it_) { u.it_ = U(); }
TEST_CONSTEXPR reference operator*() const {return *it_;}
TEST_CONSTEXPR_CXX14 cpp17_output_iterator& operator++() {++it_; return *this;}
TEST_CONSTEXPR_CXX14 cpp17_output_iterator operator++(int) {return cpp17_output_iterator(it_++);}
friend TEST_CONSTEXPR It base(const cpp17_output_iterator& i) { return i.it_; }
template <class T>
void operator,(T const &) = delete;
};
#if TEST_STD_VER > 14
template <class It>
cpp17_output_iterator(It) -> cpp17_output_iterator<It>;
#endif
#if TEST_STD_VER > 17
static_assert(std::output_iterator<cpp17_output_iterator<int*>, int>);
#endif
// This iterator meets C++20's Cpp17InputIterator requirements, as described
// in Table 89 ([input.iterators]).
template <class It, class ItTraits = It>
class cpp17_input_iterator
{
typedef std::iterator_traits<ItTraits> Traits;
It it_;
template <class U, class T> friend class cpp17_input_iterator;
public:
typedef std::input_iterator_tag iterator_category;
typedef typename Traits::value_type value_type;
typedef typename Traits::difference_type difference_type;
typedef It pointer;
typedef typename Traits::reference reference;
TEST_CONSTEXPR explicit cpp17_input_iterator(It it) : it_(it) {}
template <class U, class T>
TEST_CONSTEXPR cpp17_input_iterator(const cpp17_input_iterator<U, T>& u) : it_(u.it_) {}
template <class U, class T, class = typename std::enable_if<std::is_default_constructible<U>::value>::type>
TEST_CONSTEXPR_CXX14 cpp17_input_iterator(cpp17_input_iterator<U, T>&& u) : it_(u.it_) { u.it_ = U(); }
TEST_CONSTEXPR reference operator*() const {return *it_;}
TEST_CONSTEXPR_CXX14 cpp17_input_iterator& operator++() {++it_; return *this;}
TEST_CONSTEXPR_CXX14 cpp17_input_iterator operator++(int) {return cpp17_input_iterator(it_++);}
friend TEST_CONSTEXPR bool operator==(const cpp17_input_iterator& x, const cpp17_input_iterator& y) {return x.it_ == y.it_;}
friend TEST_CONSTEXPR bool operator!=(const cpp17_input_iterator& x, const cpp17_input_iterator& y) {return x.it_ != y.it_;}
friend TEST_CONSTEXPR It base(const cpp17_input_iterator& i) { return i.it_; }
template <class T>
void operator,(T const &) = delete;
};
#if TEST_STD_VER > 14
template <class It>
cpp17_input_iterator(It) -> cpp17_input_iterator<It>;
#endif
#if TEST_STD_VER > 17
static_assert(std::input_iterator<cpp17_input_iterator<int*>>);
#endif
template <class It>
class forward_iterator
{
It it_;
template <class U> friend class forward_iterator;
public:
typedef std::forward_iterator_tag iterator_category;
typedef typename std::iterator_traits<It>::value_type value_type;
typedef typename std::iterator_traits<It>::difference_type difference_type;
typedef It pointer;
typedef typename std::iterator_traits<It>::reference reference;
TEST_CONSTEXPR forward_iterator() : it_() {}
TEST_CONSTEXPR explicit forward_iterator(It it) : it_(it) {}
template <class U>
TEST_CONSTEXPR forward_iterator(const forward_iterator<U>& u) : it_(u.it_) {}
template <class U, class = typename std::enable_if<std::is_default_constructible<U>::value>::type>
TEST_CONSTEXPR_CXX14 forward_iterator(forward_iterator<U>&& other) : it_(other.it_) { other.it_ = U(); }
TEST_CONSTEXPR reference operator*() const {return *it_;}
TEST_CONSTEXPR_CXX14 forward_iterator& operator++() {++it_; return *this;}
TEST_CONSTEXPR_CXX14 forward_iterator operator++(int) {return forward_iterator(it_++);}
friend TEST_CONSTEXPR bool operator==(const forward_iterator& x, const forward_iterator& y) {return x.it_ == y.it_;}
friend TEST_CONSTEXPR bool operator!=(const forward_iterator& x, const forward_iterator& y) {return x.it_ != y.it_;}
friend TEST_CONSTEXPR It base(const forward_iterator& i) { return i.it_; }
template <class T>
void operator,(T const &) = delete;
};
#if TEST_STD_VER > 14
template <class It>
forward_iterator(It) -> forward_iterator<It>;
#endif
template <class It>
class bidirectional_iterator
{
It it_;
template <class U> friend class bidirectional_iterator;
public:
typedef std::bidirectional_iterator_tag iterator_category;
typedef typename std::iterator_traits<It>::value_type value_type;
typedef typename std::iterator_traits<It>::difference_type difference_type;
typedef It pointer;
typedef typename std::iterator_traits<It>::reference reference;
TEST_CONSTEXPR bidirectional_iterator() : it_() {}
TEST_CONSTEXPR explicit bidirectional_iterator(It it) : it_(it) {}
template <class U>
TEST_CONSTEXPR bidirectional_iterator(const bidirectional_iterator<U>& u) : it_(u.it_) {}
template <class U, class = typename std::enable_if<std::is_default_constructible<U>::value>::type>
TEST_CONSTEXPR_CXX14 bidirectional_iterator(bidirectional_iterator<U>&& u) : it_(u.it_) { u.it_ = U(); }
TEST_CONSTEXPR reference operator*() const {return *it_;}
TEST_CONSTEXPR_CXX14 bidirectional_iterator& operator++() {++it_; return *this;}
TEST_CONSTEXPR_CXX14 bidirectional_iterator& operator--() {--it_; return *this;}
TEST_CONSTEXPR_CXX14 bidirectional_iterator operator++(int) {return bidirectional_iterator(it_++);}
TEST_CONSTEXPR_CXX14 bidirectional_iterator operator--(int) {return bidirectional_iterator(it_--);}
friend TEST_CONSTEXPR bool operator==(const bidirectional_iterator& x, const bidirectional_iterator& y) {return x.it_ == y.it_;}
friend TEST_CONSTEXPR bool operator!=(const bidirectional_iterator& x, const bidirectional_iterator& y) {return x.it_ != y.it_;}
friend TEST_CONSTEXPR It base(const bidirectional_iterator& i) { return i.it_; }
template <class T>
void operator,(T const &) = delete;
};
#if TEST_STD_VER > 14
template <class It>
bidirectional_iterator(It) -> bidirectional_iterator<It>;
#endif
template <class It>
class random_access_iterator
{
It it_;
template <class U> friend class random_access_iterator;
public:
typedef std::random_access_iterator_tag iterator_category;
typedef typename std::iterator_traits<It>::value_type value_type;
typedef typename std::iterator_traits<It>::difference_type difference_type;
typedef It pointer;
typedef typename std::iterator_traits<It>::reference reference;
TEST_CONSTEXPR random_access_iterator() : it_() {}
TEST_CONSTEXPR explicit random_access_iterator(It it) : it_(it) {}
template <class U>
TEST_CONSTEXPR random_access_iterator(const random_access_iterator<U>& u) : it_(u.it_) {}
template <class U, class = typename std::enable_if<std::is_default_constructible<U>::value>::type>
TEST_CONSTEXPR_CXX14 random_access_iterator(random_access_iterator<U>&& u) : it_(u.it_) { u.it_ = U(); }
TEST_CONSTEXPR_CXX14 reference operator*() const {return *it_;}
TEST_CONSTEXPR_CXX14 reference operator[](difference_type n) const {return it_[n];}
TEST_CONSTEXPR_CXX14 random_access_iterator& operator++() {++it_; return *this;}
TEST_CONSTEXPR_CXX14 random_access_iterator& operator--() {--it_; return *this;}
TEST_CONSTEXPR_CXX14 random_access_iterator operator++(int) {return random_access_iterator(it_++);}
TEST_CONSTEXPR_CXX14 random_access_iterator operator--(int) {return random_access_iterator(it_--);}
TEST_CONSTEXPR_CXX14 random_access_iterator& operator+=(difference_type n) {it_ += n; return *this;}
TEST_CONSTEXPR_CXX14 random_access_iterator& operator-=(difference_type n) {it_ -= n; return *this;}
friend TEST_CONSTEXPR_CXX14 random_access_iterator operator+(random_access_iterator x, difference_type n) {x += n; return x;}
friend TEST_CONSTEXPR_CXX14 random_access_iterator operator+(difference_type n, random_access_iterator x) {x += n; return x;}
friend TEST_CONSTEXPR_CXX14 random_access_iterator operator-(random_access_iterator x, difference_type n) {x -= n; return x;}
friend TEST_CONSTEXPR difference_type operator-(random_access_iterator x, random_access_iterator y) {return x.it_ - y.it_;}
friend TEST_CONSTEXPR bool operator==(const random_access_iterator& x, const random_access_iterator& y) {return x.it_ == y.it_;}
friend TEST_CONSTEXPR bool operator!=(const random_access_iterator& x, const random_access_iterator& y) {return x.it_ != y.it_;}
friend TEST_CONSTEXPR bool operator< (const random_access_iterator& x, const random_access_iterator& y) {return x.it_ < y.it_;}
friend TEST_CONSTEXPR bool operator<=(const random_access_iterator& x, const random_access_iterator& y) {return x.it_ <= y.it_;}
friend TEST_CONSTEXPR bool operator> (const random_access_iterator& x, const random_access_iterator& y) {return x.it_ > y.it_;}
friend TEST_CONSTEXPR bool operator>=(const random_access_iterator& x, const random_access_iterator& y) {return x.it_ >= y.it_;}
friend TEST_CONSTEXPR It base(const random_access_iterator& i) { return i.it_; }
template <class T>
void operator,(T const &) = delete;
};
#if TEST_STD_VER > 14
template <class It>
random_access_iterator(It) -> random_access_iterator<It>;
#endif
#if TEST_STD_VER > 17
template <std::random_access_iterator It>
class cpp20_random_access_iterator {
It it_;
template <std::random_access_iterator>
friend class cpp20_random_access_iterator;
public:
using iterator_category = std::input_iterator_tag;
using iterator_concept = std::random_access_iterator_tag;
using value_type = typename std::iterator_traits<It>::value_type;
using difference_type = typename std::iterator_traits<It>::difference_type;
constexpr cpp20_random_access_iterator() : it_() {}
constexpr explicit cpp20_random_access_iterator(It it) : it_(it) {}
template <class U>
constexpr cpp20_random_access_iterator(const cpp20_random_access_iterator<U>& u) : it_(u.it_) {}
template <class U>
constexpr cpp20_random_access_iterator(cpp20_random_access_iterator<U>&& u) : it_(u.it_) {
u.it_ = U();
}
constexpr decltype(auto) operator*() const { return *it_; }
constexpr decltype(auto) operator[](difference_type n) const { return it_[n]; }
constexpr cpp20_random_access_iterator& operator++() {
++it_;
return *this;
}
constexpr cpp20_random_access_iterator& operator--() {
--it_;
return *this;
}
constexpr cpp20_random_access_iterator operator++(int) { return cpp20_random_access_iterator(it_++); }
constexpr cpp20_random_access_iterator operator--(int) { return cpp20_random_access_iterator(it_--); }
constexpr cpp20_random_access_iterator& operator+=(difference_type n) {
it_ += n;
return *this;
}
constexpr cpp20_random_access_iterator& operator-=(difference_type n) {
it_ -= n;
return *this;
}
friend constexpr cpp20_random_access_iterator operator+(cpp20_random_access_iterator x, difference_type n) {
x += n;
return x;
}
friend constexpr cpp20_random_access_iterator operator+(difference_type n, cpp20_random_access_iterator x) {
x += n;
return x;
}
friend constexpr cpp20_random_access_iterator operator-(cpp20_random_access_iterator x, difference_type n) {
x -= n;
return x;
}
friend constexpr difference_type operator-(cpp20_random_access_iterator x, cpp20_random_access_iterator y) {
return x.it_ - y.it_;
}
friend constexpr bool operator==(const cpp20_random_access_iterator& x, const cpp20_random_access_iterator& y) {
return x.it_ == y.it_;
}
friend constexpr bool operator!=(const cpp20_random_access_iterator& x, const cpp20_random_access_iterator& y) {
return x.it_ != y.it_;
}
friend constexpr bool operator<(const cpp20_random_access_iterator& x, const cpp20_random_access_iterator& y) {
return x.it_ < y.it_;
}
friend constexpr bool operator<=(const cpp20_random_access_iterator& x, const cpp20_random_access_iterator& y) {
return x.it_ <= y.it_;
}
friend constexpr bool operator>(const cpp20_random_access_iterator& x, const cpp20_random_access_iterator& y) {
return x.it_ > y.it_;
}
friend constexpr bool operator>=(const cpp20_random_access_iterator& x, const cpp20_random_access_iterator& y) {
return x.it_ >= y.it_;
}
friend constexpr It base(const cpp20_random_access_iterator& i) { return i.it_; }
template <class T>
void operator,(T const&) = delete;
};
template <class It>
cpp20_random_access_iterator(It) -> cpp20_random_access_iterator<It>;
static_assert(std::random_access_iterator<cpp20_random_access_iterator<int*>>);
template <class It>
class contiguous_iterator
{
static_assert(std::is_pointer_v<It>, "Things probably break in this case");
It it_;
template <class U> friend class contiguous_iterator;
public:
typedef std::contiguous_iterator_tag iterator_category;
typedef typename std::iterator_traits<It>::value_type value_type;
typedef typename std::iterator_traits<It>::difference_type difference_type;
typedef It pointer;
typedef typename std::iterator_traits<It>::reference reference;
typedef typename std::remove_pointer<It>::type element_type;
TEST_CONSTEXPR_CXX14 It base() const {return it_;}
TEST_CONSTEXPR_CXX14 contiguous_iterator() : it_() {}
TEST_CONSTEXPR_CXX14 explicit contiguous_iterator(It it) : it_(it) {}
template <class U>
TEST_CONSTEXPR_CXX14 contiguous_iterator(const contiguous_iterator<U>& u) : it_(u.it_) {}
template <class U, class = typename std::enable_if<std::is_default_constructible<U>::value>::type>
constexpr contiguous_iterator(contiguous_iterator<U>&& u) : it_(u.it_) { u.it_ = U(); }
TEST_CONSTEXPR reference operator*() const {return *it_;}
TEST_CONSTEXPR pointer operator->() const {return it_;}
TEST_CONSTEXPR reference operator[](difference_type n) const {return it_[n];}
TEST_CONSTEXPR_CXX14 contiguous_iterator& operator++() {++it_; return *this;}
TEST_CONSTEXPR_CXX14 contiguous_iterator& operator--() {--it_; return *this;}
TEST_CONSTEXPR_CXX14 contiguous_iterator operator++(int) {return contiguous_iterator(it_++);}
TEST_CONSTEXPR_CXX14 contiguous_iterator operator--(int) {return contiguous_iterator(it_--);}
TEST_CONSTEXPR_CXX14 contiguous_iterator& operator+=(difference_type n) {it_ += n; return *this;}
TEST_CONSTEXPR_CXX14 contiguous_iterator& operator-=(difference_type n) {it_ -= n; return *this;}
friend TEST_CONSTEXPR_CXX14 contiguous_iterator operator+(contiguous_iterator x, difference_type n) {x += n; return x;}
friend TEST_CONSTEXPR_CXX14 contiguous_iterator operator+(difference_type n, contiguous_iterator x) {x += n; return x;}
friend TEST_CONSTEXPR_CXX14 contiguous_iterator operator-(contiguous_iterator x, difference_type n) {x -= n; return x;}
friend TEST_CONSTEXPR difference_type operator-(contiguous_iterator x, contiguous_iterator y) {return x.it_ - y.it_;}
friend TEST_CONSTEXPR bool operator==(const contiguous_iterator& x, const contiguous_iterator& y) {return x.it_ == y.it_;}
friend TEST_CONSTEXPR bool operator!=(const contiguous_iterator& x, const contiguous_iterator& y) {return x.it_ != y.it_;}
friend TEST_CONSTEXPR bool operator< (const contiguous_iterator& x, const contiguous_iterator& y) {return x.it_ < y.it_;}
friend TEST_CONSTEXPR bool operator<=(const contiguous_iterator& x, const contiguous_iterator& y) {return x.it_ <= y.it_;}
friend TEST_CONSTEXPR bool operator> (const contiguous_iterator& x, const contiguous_iterator& y) {return x.it_ > y.it_;}
friend TEST_CONSTEXPR bool operator>=(const contiguous_iterator& x, const contiguous_iterator& y) {return x.it_ >= y.it_;}
friend TEST_CONSTEXPR It base(const contiguous_iterator& i) { return i.it_; }
template <class T>
void operator,(T const &) = delete;
};
template <class It>
contiguous_iterator(It) -> contiguous_iterator<It>;
template <class It>
class three_way_contiguous_iterator
{
static_assert(std::is_pointer_v<It>, "Things probably break in this case");
It it_;
template <class U> friend class three_way_contiguous_iterator;
public:
typedef std::contiguous_iterator_tag iterator_category;
typedef typename std::iterator_traits<It>::value_type value_type;
typedef typename std::iterator_traits<It>::difference_type difference_type;
typedef It pointer;
typedef typename std::iterator_traits<It>::reference reference;
typedef typename std::remove_pointer<It>::type element_type;
constexpr It base() const {return it_;}
constexpr three_way_contiguous_iterator() : it_() {}
constexpr explicit three_way_contiguous_iterator(It it) : it_(it) {}
template <class U>
constexpr three_way_contiguous_iterator(const three_way_contiguous_iterator<U>& u) : it_(u.it_) {}
template <class U, class = typename std::enable_if<std::is_default_constructible<U>::value>::type>
constexpr three_way_contiguous_iterator(three_way_contiguous_iterator<U>&& u) : it_(u.it_) { u.it_ = U(); }
constexpr reference operator*() const {return *it_;}
constexpr pointer operator->() const {return it_;}
constexpr reference operator[](difference_type n) const {return it_[n];}
constexpr three_way_contiguous_iterator& operator++() {++it_; return *this;}
constexpr three_way_contiguous_iterator& operator--() {--it_; return *this;}
constexpr three_way_contiguous_iterator operator++(int) {return three_way_contiguous_iterator(it_++);}
constexpr three_way_contiguous_iterator operator--(int) {return three_way_contiguous_iterator(it_--);}
constexpr three_way_contiguous_iterator& operator+=(difference_type n) {it_ += n; return *this;}
constexpr three_way_contiguous_iterator& operator-=(difference_type n) {it_ -= n; return *this;}
friend constexpr three_way_contiguous_iterator operator+(three_way_contiguous_iterator x, difference_type n) {x += n; return x;}
friend constexpr three_way_contiguous_iterator operator+(difference_type n, three_way_contiguous_iterator x) {x += n; return x;}
friend constexpr three_way_contiguous_iterator operator-(three_way_contiguous_iterator x, difference_type n) {x -= n; return x;}
friend constexpr difference_type operator-(three_way_contiguous_iterator x, three_way_contiguous_iterator y) {return x.it_ - y.it_;}
friend constexpr auto operator<=>(const three_way_contiguous_iterator& x, const three_way_contiguous_iterator& y) {return x.it_ <=> y.it_;}
friend constexpr bool operator==(const three_way_contiguous_iterator& x, const three_way_contiguous_iterator& y) {return x.it_ == y.it_;}
template <class T>
void operator,(T const &) = delete;
};
template <class It>
three_way_contiguous_iterator(It) -> three_way_contiguous_iterator<It>;
#endif // TEST_STD_VER > 17
template <class Iter> // ADL base() for everything else (including pointers)
TEST_CONSTEXPR Iter base(Iter i) { return i; }
template <typename T>
struct ThrowingIterator {
typedef std::bidirectional_iterator_tag iterator_category;
typedef std::ptrdiff_t difference_type;
typedef const T value_type;
typedef const T * pointer;
typedef const T & reference;
enum ThrowingAction { TAIncrement, TADecrement, TADereference, TAAssignment, TAComparison };
TEST_CONSTEXPR ThrowingIterator()
: begin_(nullptr), end_(nullptr), current_(nullptr), action_(TADereference), index_(0) {}
TEST_CONSTEXPR explicit ThrowingIterator(const T* first, const T* last, int index = 0,
ThrowingAction action = TADereference)
: begin_(first), end_(last), current_(first), action_(action), index_(index) {}
TEST_CONSTEXPR ThrowingIterator(const ThrowingIterator &rhs)
: begin_(rhs.begin_), end_(rhs.end_), current_(rhs.current_), action_(rhs.action_), index_(rhs.index_) {}
TEST_CONSTEXPR_CXX14 ThrowingIterator& operator=(const ThrowingIterator& rhs) {
if (action_ == TAAssignment && --index_ < 0) {
#ifndef TEST_HAS_NO_EXCEPTIONS
throw std::runtime_error("throw from iterator assignment");
#else
assert(false);
#endif
}
begin_ = rhs.begin_;
end_ = rhs.end_;
current_ = rhs.current_;
action_ = rhs.action_;
index_ = rhs.index_;
return *this;
}
TEST_CONSTEXPR_CXX14 reference operator*() const {
if (action_ == TADereference && --index_ < 0) {
#ifndef TEST_HAS_NO_EXCEPTIONS
throw std::runtime_error("throw from iterator dereference");
#else
assert(false);
#endif
}
return *current_;
}
TEST_CONSTEXPR_CXX14 ThrowingIterator& operator++() {
if (action_ == TAIncrement && --index_ < 0) {
#ifndef TEST_HAS_NO_EXCEPTIONS
throw std::runtime_error("throw from iterator increment");
#else
assert(false);
#endif
}
++current_;
return *this;
}
TEST_CONSTEXPR_CXX14 ThrowingIterator operator++(int) {
ThrowingIterator temp = *this;
++(*this);
return temp;
}
TEST_CONSTEXPR_CXX14 ThrowingIterator& operator--() {
if (action_ == TADecrement && --index_ < 0) {
#ifndef TEST_HAS_NO_EXCEPTIONS
throw std::runtime_error("throw from iterator decrement");
#else
assert(false);
#endif
}
--current_;
return *this;
}
TEST_CONSTEXPR_CXX14 ThrowingIterator operator--(int) {
ThrowingIterator temp = *this;
--(*this);
return temp;
}
TEST_CONSTEXPR_CXX14 friend bool operator==(const ThrowingIterator& a, const ThrowingIterator& b) {
if (a.action_ == TAComparison && --a.index_ < 0) {
#ifndef TEST_HAS_NO_EXCEPTIONS
throw std::runtime_error("throw from iterator comparison");
#else
assert(false);
#endif
}
bool atEndL = a.current_ == a.end_;
bool atEndR = b.current_ == b.end_;
if (atEndL != atEndR) return false; // one is at the end (or empty), the other is not.
if (atEndL) return true; // both are at the end (or empty)
return a.current_ == b.current_;
}
TEST_CONSTEXPR friend bool operator!=(const ThrowingIterator& a, const ThrowingIterator& b) {
return !(a == b);
}
template <class T2>
void operator,(T2 const &) = delete;
private:
const T* begin_;
const T* end_;
const T* current_;
ThrowingAction action_;
mutable int index_;
};
template <typename T>
struct NonThrowingIterator {
typedef std::bidirectional_iterator_tag iterator_category;
typedef std::ptrdiff_t difference_type;
typedef const T value_type;
typedef const T * pointer;
typedef const T & reference;
NonThrowingIterator()
: begin_(nullptr), end_(nullptr), current_(nullptr) {}
explicit NonThrowingIterator(const T *first, const T *last)
: begin_(first), end_(last), current_(first) {}
NonThrowingIterator(const NonThrowingIterator& rhs)
: begin_(rhs.begin_), end_(rhs.end_), current_(rhs.current_) {}
NonThrowingIterator& operator=(const NonThrowingIterator& rhs) TEST_NOEXCEPT {
begin_ = rhs.begin_;
end_ = rhs.end_;
current_ = rhs.current_;
return *this;
}
reference operator*() const TEST_NOEXCEPT {
return *current_;
}
NonThrowingIterator& operator++() TEST_NOEXCEPT {
++current_;
return *this;
}
NonThrowingIterator operator++(int) TEST_NOEXCEPT {
NonThrowingIterator temp = *this;
++(*this);
return temp;
}
NonThrowingIterator & operator--() TEST_NOEXCEPT {
--current_;
return *this;
}
NonThrowingIterator operator--(int) TEST_NOEXCEPT {
NonThrowingIterator temp = *this;
--(*this);
return temp;
}
friend bool operator==(const NonThrowingIterator& a, const NonThrowingIterator& b) TEST_NOEXCEPT {
bool atEndL = a.current_ == a.end_;
bool atEndR = b.current_ == b.end_;
if (atEndL != atEndR) return false; // one is at the end (or empty), the other is not.
if (atEndL) return true; // both are at the end (or empty)
return a.current_ == b.current_;
}
friend bool operator!=(const NonThrowingIterator& a, const NonThrowingIterator& b) TEST_NOEXCEPT {
return !(a == b);
}
template <class T2>
void operator,(T2 const &) = delete;
private:
const T *begin_;
const T *end_;
const T *current_;
};
#if TEST_STD_VER > 17
template <class It>
class cpp20_input_iterator
{
It it_;
public:
using value_type = std::iter_value_t<It>;
using difference_type = std::iter_difference_t<It>;
using iterator_concept = std::input_iterator_tag;
constexpr explicit cpp20_input_iterator(It it) : it_(it) {}
cpp20_input_iterator(cpp20_input_iterator&&) = default;
cpp20_input_iterator& operator=(cpp20_input_iterator&&) = default;
constexpr decltype(auto) operator*() const { return *it_; }
constexpr cpp20_input_iterator& operator++() { ++it_; return *this; }
constexpr void operator++(int) { ++it_; }
friend constexpr It base(const cpp20_input_iterator& i) { return i.it_; }
template <class T>
void operator,(T const &) = delete;
};
template <class It>
cpp20_input_iterator(It) -> cpp20_input_iterator<It>;
static_assert(std::input_iterator<cpp20_input_iterator<int*>>);
template<std::input_or_output_iterator>
struct iter_value_or_void { using type = void; };
template<std::input_iterator I>
struct iter_value_or_void<I> {
using type = std::iter_value_t<I>;
};
template <class It>
class cpp20_output_iterator {
It it_;
public:
using difference_type = std::iter_difference_t<It>;
constexpr explicit cpp20_output_iterator(It it) : it_(it) {}
cpp20_output_iterator(cpp20_output_iterator&&) = default;
cpp20_output_iterator& operator=(cpp20_output_iterator&&) = default;
constexpr decltype(auto) operator*() const { return *it_; }
constexpr cpp20_output_iterator& operator++() {
++it_;
return *this;
}
constexpr cpp20_output_iterator operator++(int) { return cpp20_output_iterator(it_++); }
friend constexpr It base(const cpp20_output_iterator& i) { return i.it_; }
template <class T>
void operator,(T const&) = delete;
};
template <class It>
cpp20_output_iterator(It) -> cpp20_output_iterator<It>;
static_assert(std::output_iterator<cpp20_output_iterator<int*>, int>);
# if TEST_STD_VER >= 20
// An `input_iterator` that can be used in a `std::ranges::common_range`
template <class Base>
struct common_input_iterator {
Base it_;
using value_type = std::iter_value_t<Base>;
using difference_type = std::intptr_t;
using iterator_concept = std::input_iterator_tag;
constexpr common_input_iterator() = default;
constexpr explicit common_input_iterator(Base it) : it_(it) {}
constexpr common_input_iterator& operator++() {
++it_;
return *this;
}
constexpr void operator++(int) { ++it_; }
constexpr decltype(auto) operator*() const { return *it_; }
friend constexpr bool operator==(common_input_iterator const&, common_input_iterator const&) = default;
};
# endif // TEST_STD_VER >= 20
// Iterator adaptor that counts the number of times the iterator has had a successor/predecessor
// operation or an equality comparison operation called. Has three recorders:
// * `stride_count`, which records the total number of calls to an op++, op--, op+=, or op-=.
// * `stride_displacement`, which records the displacement of the calls. This means that both
// op++/op+= will increase the displacement counter by 1, and op--/op-= will decrease the
// displacement counter by 1.
// * `equals_count`, which records the total number of calls to an op== or op!=. If compared
// against a sentinel object, that sentinel object must call the `record_equality_comparison`
// function so that the comparison is counted correctly.
template <class It>
class stride_counting_iterator {
public:
using value_type = typename iter_value_or_void<It>::type;
using difference_type = std::iter_difference_t<It>;
using iterator_concept =
std::conditional_t<std::contiguous_iterator<It>, std::contiguous_iterator_tag,
std::conditional_t<std::random_access_iterator<It>, std::random_access_iterator_tag,
std::conditional_t<std::bidirectional_iterator<It>, std::bidirectional_iterator_tag,
std::conditional_t<std::forward_iterator<It>, std::forward_iterator_tag,
std::conditional_t<std::input_iterator<It>, std::input_iterator_tag,
/* else */ std::output_iterator_tag
>>>>>;
stride_counting_iterator() requires std::default_initializable<It> = default;
constexpr explicit stride_counting_iterator(It const& it) : base_(base(it)) { }
friend constexpr It base(stride_counting_iterator const& it) { return It(it.base_); }
constexpr difference_type stride_count() const { return stride_count_; }
constexpr difference_type stride_displacement() const { return stride_displacement_; }
constexpr difference_type equals_count() const { return equals_count_; }
constexpr decltype(auto) operator*() const { return *It(base_); }
constexpr decltype(auto) operator[](difference_type n) const { return It(base_)[n]; }
constexpr stride_counting_iterator& operator++() {
It tmp(base_);
base_ = base(++tmp);
++stride_count_;
++stride_displacement_;
return *this;
}
constexpr void operator++(int) { ++*this; }
constexpr stride_counting_iterator operator++(int)
requires std::forward_iterator<It>
{
auto temp = *this;
++*this;
return temp;
}
constexpr stride_counting_iterator& operator--()
requires std::bidirectional_iterator<It>
{
It tmp(base_);
base_ = base(--tmp);
++stride_count_;
--stride_displacement_;
return *this;
}
constexpr stride_counting_iterator operator--(int)
requires std::bidirectional_iterator<It>
{
auto temp = *this;
--*this;
return temp;
}
constexpr stride_counting_iterator& operator+=(difference_type const n)
requires std::random_access_iterator<It>
{
It tmp(base_);
base_ = base(tmp += n);
++stride_count_;
++stride_displacement_;
return *this;
}
constexpr stride_counting_iterator& operator-=(difference_type const n)
requires std::random_access_iterator<It>
{
It tmp(base_);
base_ = base(tmp -= n);
++stride_count_;
--stride_displacement_;
return *this;
}
friend constexpr stride_counting_iterator operator+(stride_counting_iterator it, difference_type n)
requires std::random_access_iterator<It>
{
return it += n;
}
friend constexpr stride_counting_iterator operator+(difference_type n, stride_counting_iterator it)
requires std::random_access_iterator<It>
{
return it += n;
}
friend constexpr stride_counting_iterator operator-(stride_counting_iterator it, difference_type n)
requires std::random_access_iterator<It>
{
return it -= n;
}
friend constexpr difference_type operator-(stride_counting_iterator const& x, stride_counting_iterator const& y)
requires std::sized_sentinel_for<It, It>
{
return base(x) - base(y);
}
constexpr void record_equality_comparison() const { ++equals_count_; }
constexpr bool operator==(stride_counting_iterator const& other) const
requires std::sentinel_for<It, It>
{
record_equality_comparison();
return It(base_) == It(other.base_);
}
friend constexpr bool operator<(stride_counting_iterator const& x, stride_counting_iterator const& y)
requires std::random_access_iterator<It>
{
return It(x.base_) < It(y.base_);
}
friend constexpr bool operator>(stride_counting_iterator const& x, stride_counting_iterator const& y)
requires std::random_access_iterator<It>
{
return It(x.base_) > It(y.base_);
}
friend constexpr bool operator<=(stride_counting_iterator const& x, stride_counting_iterator const& y)
requires std::random_access_iterator<It>
{
return It(x.base_) <= It(y.base_);
}
friend constexpr bool operator>=(stride_counting_iterator const& x, stride_counting_iterator const& y)
requires std::random_access_iterator<It>
{
return It(x.base_) >= It(y.base_);
}
template <class T>
void operator,(T const &) = delete;
private:
decltype(base(std::declval<It>())) base_;
difference_type stride_count_ = 0;
difference_type stride_displacement_ = 0;
mutable difference_type equals_count_ = 0;
};
template <class It>
stride_counting_iterator(It) -> stride_counting_iterator<It>;
#endif // TEST_STD_VER > 17
#if TEST_STD_VER > 17
template <class It>
class sentinel_wrapper {
public:
explicit sentinel_wrapper() = default;
constexpr explicit sentinel_wrapper(const It& it) : base_(base(it)) {}
constexpr bool operator==(const It& other) const {
// If supported, record statistics about the equality operator call
// inside `other`.
if constexpr (requires { other.record_equality_comparison(); }) {
other.record_equality_comparison();
}
return base_ == base(other);
}
friend constexpr It base(const sentinel_wrapper& s) { return It(s.base_); }
private:
decltype(base(std::declval<It>())) base_;
};
template <class It>
sentinel_wrapper(It) -> sentinel_wrapper<It>;
template <class It>
class sized_sentinel {
public:
explicit sized_sentinel() = default;
constexpr explicit sized_sentinel(const It& it) : base_(base(it)) {}
constexpr bool operator==(const It& other) const { return base_ == base(other); }
friend constexpr auto operator-(const sized_sentinel& s, const It& i) { return s.base_ - base(i); }
friend constexpr auto operator-(const It& i, const sized_sentinel& s) { return base(i) - s.base_; }
friend constexpr It base(const sized_sentinel& s) { return It(s.base_); }
private:
decltype(base(std::declval<It>())) base_;
};
template <class It>
sized_sentinel(It) -> sized_sentinel<It>;
namespace adl {
class Iterator {
public:
using value_type = int;
using reference = int&;
using difference_type = std::ptrdiff_t;
private:
value_type* ptr_ = nullptr;
int* iter_moves_ = nullptr;
int* iter_swaps_ = nullptr;
constexpr Iterator(int* p, int* iter_moves, int* iter_swaps)
: ptr_(p)
, iter_moves_(iter_moves)
, iter_swaps_(iter_swaps) {}
public:
constexpr Iterator() = default;
static constexpr Iterator TrackMoves(int* p, int& iter_moves) {
return Iterator(p, &iter_moves, /*iter_swaps=*/nullptr);
}
static constexpr Iterator TrackSwaps(int& iter_swaps) {
return Iterator(/*p=*/nullptr, /*iter_moves=*/nullptr, &iter_swaps);
}
static constexpr Iterator TrackSwaps(int* p, int& iter_swaps) {
return Iterator(p, /*iter_moves=*/nullptr, &iter_swaps);
}
constexpr int iter_moves() const { assert(iter_moves_); return *iter_moves_; }
constexpr int iter_swaps() const { assert(iter_swaps_); return *iter_swaps_; }
constexpr value_type& operator*() const { return *ptr_; }
constexpr reference operator[](difference_type n) const { return ptr_[n]; }
friend constexpr Iterator operator+(Iterator i, difference_type n) {
return Iterator(i.ptr_ + n, i.iter_moves_, i.iter_swaps_);
}
friend constexpr Iterator operator+(difference_type n, Iterator i) {
return i + n;
}
constexpr Iterator operator-(difference_type n) const {
return Iterator(ptr_ - n, iter_moves_, iter_swaps_);
}
constexpr difference_type operator-(Iterator rhs) const {
return ptr_ - rhs.ptr_;
}
constexpr Iterator& operator+=(difference_type n) {
ptr_ += n;
return *this;
}
constexpr Iterator& operator-=(difference_type n) {
ptr_ -= n;
return *this;
}
constexpr Iterator& operator++() { ++ptr_; return *this; }
constexpr Iterator operator++(int) {
Iterator prev = *this;
++ptr_;
return prev;
}
constexpr Iterator& operator--() { --ptr_; return *this; }
constexpr Iterator operator--(int) {
Iterator prev = *this;
--ptr_;
return prev;
}
constexpr friend void iter_swap(Iterator a, Iterator b) {
std::swap(a.ptr_, b.ptr_);
if (a.iter_swaps_) {
++(*a.iter_swaps_);
}
}
constexpr friend value_type&& iter_move(Iterator iter) {
if (iter.iter_moves_) {
++(*iter.iter_moves_);
}
return std::move(*iter);
}
constexpr friend bool operator==(const Iterator& lhs, const Iterator& rhs) {
return lhs.ptr_ == rhs.ptr_;
}
constexpr friend auto operator<=>(const Iterator& lhs, const Iterator& rhs) {
return lhs.ptr_ <=> rhs.ptr_;
}
};
} // namespace adl
template <class T>
class rvalue_iterator {
public:
using iterator_category = std::input_iterator_tag;
using iterator_concept = std::random_access_iterator_tag;
using difference_type = std::ptrdiff_t;
using reference = T&&;
using value_type = T;
rvalue_iterator() = default;
constexpr rvalue_iterator(T* it) : it_(it) {}
constexpr reference operator*() const { return std::move(*it_); }
constexpr rvalue_iterator& operator++() {
++it_;
return *this;
}
constexpr rvalue_iterator operator++(int) {
auto tmp = *this;
++it_;
return tmp;
}
constexpr rvalue_iterator& operator--() {
--it_;
return *this;
}
constexpr rvalue_iterator operator--(int) {
auto tmp = *this;
--it_;
return tmp;
}
constexpr rvalue_iterator operator+(difference_type n) const {
auto tmp = *this;
tmp.it += n;
return tmp;
}
constexpr friend rvalue_iterator operator+(difference_type n, rvalue_iterator iter) {
iter += n;
return iter;
}
constexpr rvalue_iterator operator-(difference_type n) const {
auto tmp = *this;
tmp.it -= n;
return tmp;
}
constexpr difference_type operator-(const rvalue_iterator& other) const { return it_ - other.it_; }
constexpr rvalue_iterator& operator+=(difference_type n) {
it_ += n;
return *this;
}
constexpr rvalue_iterator& operator-=(difference_type n) {
it_ -= n;
return *this;
}
constexpr reference operator[](difference_type n) const { return std::move(it_[n]); }
auto operator<=>(const rvalue_iterator&) const noexcept = default;
private:
T* it_;
};
template <class T>
rvalue_iterator(T*) -> rvalue_iterator<T>;
static_assert(std::random_access_iterator<rvalue_iterator<int*>>);
// Proxy
// ======================================================================
// Proxy that can wrap a value or a reference. It simulates C++23's tuple
// but simplified to just hold one argument.
// Note that unlike tuple, this class deliberately doesn't have special handling
// of swap to cause a compilation error if it's used in an algorithm that relies
// on plain swap instead of ranges::iter_swap.
// This class is useful for testing that if algorithms support proxy iterator
// properly, i.e. calling ranges::iter_swap and ranges::iter_move instead of
// plain swap and std::move.
template <class T>
struct Proxy;
template <class T>
inline constexpr bool IsProxy = false;
template <class T>
inline constexpr bool IsProxy<Proxy<T>> = true;
template <class T>
struct Proxy {
T data;
constexpr T& getData() & { return data; }
constexpr const T& getData() const& { return data; }
constexpr T&& getData() && { return static_cast<T&&>(data); }
constexpr const T&& getData() const&& { return static_cast<const T&&>(data); }
template <class U>
requires std::constructible_from<T, U&&>
constexpr Proxy(U&& u) : data{std::forward<U>(u)} {}
// This constructor covers conversion from cvref of Proxy<U>, including non-const/const versions of copy/move constructor
template <class Other>
requires(IsProxy<std::decay_t<Other>> && std::constructible_from<T, decltype(std::declval<Other>().getData())>)
constexpr Proxy(Other&& other) : data{std::forward<Other>(other).getData()} {}
template <class Other>
requires(IsProxy<std::decay_t<Other>> && std::assignable_from<T&, decltype(std::declval<Other>().getData())>)
constexpr Proxy& operator=(Other&& other) {
data = std::forward<Other>(other).getData();
return *this;
}
// const assignment required to make ProxyIterator model std::indirectly_writable
template <class Other>
requires(IsProxy<std::decay_t<Other>> && std::assignable_from<const T&, decltype(std::declval<Other>().getData())>)
constexpr const Proxy& operator=(Other&& other) const {
data = std::forward<Other>(other).getData();
return *this;
}
// If `T` is a reference type, the implicitly-generated assignment operator will be deleted (and would take precedence
// over the templated `operator=` above because it's a better match).
constexpr Proxy& operator=(const Proxy& rhs) {
data = rhs.data;
return *this;
}
// no specialised swap function that takes const Proxy& and no specialised const member swap
// Calling swap(Proxy<T>{}, Proxy<T>{}) would fail (pass prvalues)
// Compare operators are defined for the convenience of the tests
friend constexpr bool operator==(const Proxy&, const Proxy&)
requires (std::equality_comparable<T> && !std::is_reference_v<T>)
= default;
// Helps compare e.g. `Proxy<int>` and `Proxy<int&>`. Note that the default equality comparison operator is deleted
// when `T` is a reference type.
template <class U>
friend constexpr bool operator==(const Proxy& lhs, const Proxy<U>& rhs)
requires std::equality_comparable_with<std::decay_t<T>, std::decay_t<U>> {
return lhs.data == rhs.data;
}
friend constexpr auto operator<=>(const Proxy&, const Proxy&)
requires (std::three_way_comparable<T> && !std::is_reference_v<T>)
= default;
// Helps compare e.g. `Proxy<int>` and `Proxy<int&>`. Note that the default 3-way comparison operator is deleted when
// `T` is a reference type.
template <class U>
friend constexpr auto operator<=>(const Proxy& lhs, const Proxy<U>& rhs)
requires std::three_way_comparable_with<std::decay_t<T>, std::decay_t<U>> {
return lhs.data <=> rhs.data;
}
};
// This is to make ProxyIterator model `std::indirectly_readable`
template <class T, class U, template <class> class TQual, template <class> class UQual>
requires requires { typename std::common_reference_t<TQual<T>, UQual<U>>; }
struct std::basic_common_reference<Proxy<T>, Proxy<U>, TQual, UQual> {
using type = Proxy<std::common_reference_t<TQual<T>, UQual<U>>>;
};
template <class T, class U>
requires requires { typename std::common_type_t<T, U>; }
struct std::common_type<Proxy<T>, Proxy<U>> {
using type = Proxy<std::common_type_t<T, U>>;
};
// ProxyIterator
// ======================================================================
// It wraps `Base` iterator and when dereferenced it returns a Proxy<ref>
// It simulates C++23's zip_view::iterator but simplified to just wrap
// one base iterator.
// Note it forwards value_type, iter_move, iter_swap. e.g if the base
// iterator is int*,
// operator* -> Proxy<int&>
// iter_value_t -> Proxy<int>
// iter_move -> Proxy<int&&>
template <class Base>
struct ProxyIteratorBase {};
template <class Base>
requires std::derived_from<
typename std::iterator_traits<Base>::iterator_category,
std::input_iterator_tag>
struct ProxyIteratorBase<Base> {
using iterator_category = std::input_iterator_tag;
};
template <std::input_iterator Base>
consteval auto get_iterator_concept() {
if constexpr (std::random_access_iterator<Base>) {
return std::random_access_iterator_tag{};
} else if constexpr (std::bidirectional_iterator<Base>) {
return std::bidirectional_iterator_tag{};
} else if constexpr (std::forward_iterator<Base>) {
return std::forward_iterator_tag{};
} else {
return std::input_iterator_tag{};
}
}
template <std::input_iterator Base>
struct ProxyIterator : ProxyIteratorBase<Base> {
Base base_;
using iterator_concept = decltype(get_iterator_concept<Base>());
using value_type = Proxy<std::iter_value_t<Base>>;
using difference_type = std::iter_difference_t<Base>;
ProxyIterator()
requires std::default_initializable<Base>
= default;
constexpr ProxyIterator(Base base) : base_{std::move(base)} {}
template <class T>
requires std::constructible_from<Base, T&&>
constexpr ProxyIterator(T&& t) : base_{std::forward<T>(t)} {}
friend constexpr decltype(auto) base(const ProxyIterator& p) { return base(p.base_); }
// Specialization of iter_move
// If operator* returns Proxy<Foo&>, iter_move will return Proxy<Foo&&>
// Note std::move(*it) returns Proxy<Foo&>&&, which is not what we want as
// it will likely result in a copy rather than a move
friend constexpr Proxy<std::iter_rvalue_reference_t<Base>> iter_move(const ProxyIterator& p) noexcept {
return {std::ranges::iter_move(p.base_)};
}
// Specialization of iter_swap
// Note std::swap(*x, *y) would fail to compile as operator* returns prvalues
// and std::swap takes non-const lvalue references
friend constexpr void iter_swap(const ProxyIterator& x, const ProxyIterator& y) noexcept {
std::ranges::iter_swap(x.base_, y.base_);
}
// to satisfy input_iterator
constexpr Proxy<std::iter_reference_t<Base>> operator*() const { return {*base_}; }
constexpr ProxyIterator& operator++() {
++base_;
return *this;
}
constexpr void operator++(int) { ++*this; }
friend constexpr bool operator==(const ProxyIterator& x, const ProxyIterator& y)
requires std::equality_comparable<Base> {
return x.base_ == y.base_;
}
// to satisfy forward_iterator
constexpr ProxyIterator operator++(int)
requires std::forward_iterator<Base> {
auto tmp = *this;
++*this;
return tmp;
}
// to satisfy bidirectional_iterator
constexpr ProxyIterator& operator--()
requires std::bidirectional_iterator<Base> {
--base_;
return *this;
}
constexpr ProxyIterator operator--(int)
requires std::bidirectional_iterator<Base> {
auto tmp = *this;
--*this;
return tmp;
}
// to satisfy random_access_iterator
constexpr ProxyIterator& operator+=(difference_type n)
requires std::random_access_iterator<Base> {
base_ += n;
return *this;
}
constexpr ProxyIterator& operator-=(difference_type n)
requires std::random_access_iterator<Base> {
base_ -= n;
return *this;
}
constexpr Proxy<std::iter_reference_t<Base>> operator[](difference_type n) const
requires std::random_access_iterator<Base> {
return {base_[n]};
}
friend constexpr bool operator<(const ProxyIterator& x, const ProxyIterator& y)
requires std::random_access_iterator<Base> {
return x.base_ < y.base_;
}
friend constexpr bool operator>(const ProxyIterator& x, const ProxyIterator& y)
requires std::random_access_iterator<Base> {
return x.base_ > y.base_;
}
friend constexpr bool operator<=(const ProxyIterator& x, const ProxyIterator& y)
requires std::random_access_iterator<Base> {
return x.base_ <= y.base_;
}
friend constexpr bool operator>=(const ProxyIterator& x, const ProxyIterator& y)
requires std::random_access_iterator<Base> {
return x.base_ >= y.base_;
}
friend constexpr auto operator<=>(const ProxyIterator& x, const ProxyIterator& y)
requires(std::random_access_iterator<Base> && std::three_way_comparable<Base>) {
return x.base_ <=> y.base_;
}
friend constexpr ProxyIterator operator+(const ProxyIterator& x, difference_type n)
requires std::random_access_iterator<Base> {
return ProxyIterator{x.base_ + n};
}
friend constexpr ProxyIterator operator+(difference_type n, const ProxyIterator& x)
requires std::random_access_iterator<Base> {
return ProxyIterator{n + x.base_};
}
friend constexpr ProxyIterator operator-(const ProxyIterator& x, difference_type n)
requires std::random_access_iterator<Base> {
return ProxyIterator{x.base_ - n};
}
friend constexpr difference_type operator-(const ProxyIterator& x, const ProxyIterator& y)
requires std::random_access_iterator<Base> {
return x.base_ - y.base_;
}
};
template <class Base>
ProxyIterator(Base) -> ProxyIterator<Base>;
static_assert(std::indirectly_readable<ProxyIterator<int*>>);
static_assert(std::indirectly_writable<ProxyIterator<int*>, Proxy<int>>);
static_assert(std::indirectly_writable<ProxyIterator<int*>, Proxy<int&>>);
template <class Iter>
using Cpp20InputProxyIterator = ProxyIterator<cpp20_input_iterator<Iter>>;
template <class Iter>
using ForwardProxyIterator = ProxyIterator<forward_iterator<Iter>>;
template <class Iter>
using BidirectionalProxyIterator = ProxyIterator<bidirectional_iterator<Iter>>;
template <class Iter>
using RandomAccessProxyIterator = ProxyIterator<random_access_iterator<Iter>>;
template <class Iter>
using ContiguousProxyIterator = ProxyIterator<contiguous_iterator<Iter>>;
template <class BaseSent>
struct ProxySentinel {
BaseSent base_;
ProxySentinel() = default;
constexpr ProxySentinel(BaseSent base) : base_{std::move(base)} {}
template <class Base>
requires std::equality_comparable_with<Base, BaseSent>
friend constexpr bool operator==(const ProxyIterator<Base>& p, const ProxySentinel& sent) {
return p.base_ == sent.base_;
}
};
template <class BaseSent>
ProxySentinel(BaseSent) -> ProxySentinel<BaseSent>;
template <std::ranges::input_range Base>
requires std::ranges::view<Base>
struct ProxyRange {
Base base_;
constexpr auto begin() { return ProxyIterator{std::ranges::begin(base_)}; }
constexpr auto end() { return ProxySentinel{std::ranges::end(base_)}; }
constexpr auto begin() const
requires std::ranges::input_range<const Base> {
return ProxyIterator{std::ranges::begin(base_)};
}
constexpr auto end() const
requires std::ranges::input_range<const Base> {
return ProxySentinel{std::ranges::end(base_)};
}
};
template <std::ranges::input_range R>
requires std::ranges::viewable_range<R&&>
ProxyRange(R&&) -> ProxyRange<std::views::all_t<R&&>>;
#endif // TEST_STD_VER > 17
#if TEST_STD_VER >= 17
namespace util {
template <class Derived, class Iter>
class iterator_wrapper {
Iter iter_;
using iter_traits = std::iterator_traits<Iter>;
public:
using iterator_category = typename iter_traits::iterator_category;
using value_type = typename iter_traits::value_type;
using difference_type = typename iter_traits::difference_type;
using pointer = typename iter_traits::pointer;
using reference = typename iter_traits::reference;
constexpr iterator_wrapper() : iter_() {}
constexpr explicit iterator_wrapper(Iter iter) : iter_(iter) {}
decltype(*iter_) operator*() { return *iter_; }
decltype(*iter_) operator*() const { return *iter_; }
decltype(iter_[0]) operator[](difference_type v) const {
return iter_[v];
}
Derived& operator++() {
++iter_;
return static_cast<Derived&>(*this);
}
Derived operator++(int) {
auto tmp = static_cast<Derived&>(*this);
++(*this);
return tmp;
}
Derived& operator--() {
--iter_;
return static_cast<Derived&>(*this);
}
Derived operator--(int) {
auto tmp = static_cast<Derived&>(*this);
--(*this);
return tmp;
}
Derived& operator+=(difference_type i) {
iter_ += i;
return static_cast<Derived&>(*this);
}
Derived& operator-=(difference_type i) {
iter_ -= i;
return static_cast<Derived&>(*this);
}
friend decltype(iter_ - iter_) operator-(const iterator_wrapper& lhs, const iterator_wrapper& rhs) {
return lhs.iter_ - rhs.iter_;
}
friend Derived operator-(Derived iter, difference_type i) {
iter.iter_ -= i;
return iter;
}
friend Derived operator+(Derived iter, difference_type i) {
iter.iter_ += i;
return iter;
}
friend Derived operator+(difference_type i, Derived iter) { return iter + i; }
friend bool operator==(const iterator_wrapper& lhs, const iterator_wrapper& rhs) { return lhs.iter_ == rhs.iter_; }
friend bool operator!=(const iterator_wrapper& lhs, const iterator_wrapper& rhs) { return lhs.iter_ != rhs.iter_; }
friend bool operator>(const iterator_wrapper& lhs, const iterator_wrapper& rhs) { return lhs.iter_ > rhs.iter_; }
friend bool operator<(const iterator_wrapper& lhs, const iterator_wrapper& rhs) { return lhs.iter_ < rhs.iter_; }
friend bool operator<=(const iterator_wrapper& lhs, const iterator_wrapper& rhs) { return lhs.iter_ <= rhs.iter_; }
friend bool operator>=(const iterator_wrapper& lhs, const iterator_wrapper& rhs) { return lhs.iter_ >= rhs.iter_; }
};
class iterator_error : std::runtime_error {
public:
iterator_error(const char* what) : std::runtime_error(what) {}
};
#ifndef TEST_HAS_NO_EXCEPTIONS
template <class Iter>
class throw_on_move_iterator : public iterator_wrapper<throw_on_move_iterator<Iter>, Iter> {
using base = iterator_wrapper<throw_on_move_iterator<Iter>, Iter>;
int moves_until_throw_ = 0;
public:
using difference_type = typename base::difference_type;
using value_type = typename base::value_type;
using iterator_category = typename base::iterator_category;
throw_on_move_iterator() = default;
throw_on_move_iterator(Iter iter, int moves_until_throw)
: base(std::move(iter)), moves_until_throw_(moves_until_throw) {}
throw_on_move_iterator(const throw_on_move_iterator& other) : base(other) {}
throw_on_move_iterator& operator=(const throw_on_move_iterator& other) {
static_cast<base&>(*this) = other;
return *this;
}
throw_on_move_iterator(throw_on_move_iterator&& other)
: base(std::move(other)), moves_until_throw_(other.moves_until_throw_ - 1) {
if (moves_until_throw_ == -1)
throw iterator_error("throw_on_move_iterator");
}
throw_on_move_iterator& operator=(throw_on_move_iterator&& other) {
moves_until_throw_ = other.moves_until_throw_ - 1;
if (moves_until_throw_ == -1)
throw iterator_error("throw_on_move_iterator");
return *this;
}
};
template <class Iter>
throw_on_move_iterator(Iter) -> throw_on_move_iterator<Iter>;
#endif // TEST_HAS_NO_EXCEPTIONS
} // namespace util
#endif // TEST_STD_VER >= 17
namespace types {
template <class Ptr>
using random_access_iterator_list =
type_list<Ptr,
#if TEST_STD_VER >= 20
contiguous_iterator<Ptr>,
#endif
random_access_iterator<Ptr> >;
template <class Ptr>
using bidirectional_iterator_list =
concatenate_t<random_access_iterator_list<Ptr>, type_list<bidirectional_iterator<Ptr> > >;
template <class Ptr>
using forward_iterator_list = concatenate_t<bidirectional_iterator_list<Ptr>, type_list<forward_iterator<Ptr> > >;
template <class Ptr>
using cpp17_input_iterator_list = concatenate_t<forward_iterator_list<Ptr>, type_list<cpp17_input_iterator<Ptr> > >;
#if TEST_STD_VER >= 20
template <class Ptr>
using cpp20_input_iterator_list =
concatenate_t<forward_iterator_list<Ptr>, type_list<cpp20_input_iterator<Ptr>, cpp17_input_iterator<Ptr>>>;
#endif
} // namespace types
#endif // SUPPORT_TEST_ITERATORS_H