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// Utilities for representing and manipulating ranges -*- C++ -*-
// Copyright (C) 2019-2021 Free Software Foundation, Inc.
//
// This file is part of the GNU ISO C++ Library. This library is free
// software; you can redistribute it and/or modify it under the
// terms of the GNU General Public License as published by the
// Free Software Foundation; either version 3, or (at your option)
// any later version.
// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// Under Section 7 of GPL version 3, you are granted additional
// permissions described in the GCC Runtime Library Exception, version
// 3.1, as published by the Free Software Foundation.
// You should have received a copy of the GNU General Public License and
// a copy of the GCC Runtime Library Exception along with this program;
// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
// <http://www.gnu.org/licenses/>.
/** @file bits/ranges_util.h
* This is an internal header file, included by other library headers.
* Do not attempt to use it directly. @headername{ranges}
*/
#ifndef _RANGES_UTIL_H
#define _RANGES_UTIL_H 1
#if __cplusplus > 201703L
# include <bits/ranges_base.h>
#ifdef __cpp_lib_ranges
namespace std _GLIBCXX_VISIBILITY(default)
{
_GLIBCXX_BEGIN_NAMESPACE_VERSION
namespace ranges
{
// C++20 24.5 [range.utility] Range utilities
namespace __detail
{
template<typename _Range>
concept __simple_view = view<_Range> && range<const _Range>
&& same_as<iterator_t<_Range>, iterator_t<const _Range>>
&& same_as<sentinel_t<_Range>, sentinel_t<const _Range>>;
template<typename _It>
concept __has_arrow = input_iterator<_It>
&& (is_pointer_v<_It> || requires(_It __it) { __it.operator->(); });
template<typename _Tp, typename _Up>
concept __not_same_as
= !same_as<remove_cvref_t<_Tp>, remove_cvref_t<_Up>>;
} // namespace __detail
/// The ranges::view_interface class template
template<typename _Derived>
requires is_class_v<_Derived> && same_as<_Derived, remove_cv_t<_Derived>>
class view_interface : public view_base
{
private:
constexpr _Derived& _M_derived() noexcept
{
static_assert(derived_from<_Derived, view_interface<_Derived>>);
static_assert(view<_Derived>);
return static_cast<_Derived&>(*this);
}
constexpr const _Derived& _M_derived() const noexcept
{
static_assert(derived_from<_Derived, view_interface<_Derived>>);
static_assert(view<_Derived>);
return static_cast<const _Derived&>(*this);
}
public:
constexpr bool
empty() requires forward_range<_Derived>
{ return ranges::begin(_M_derived()) == ranges::end(_M_derived()); }
constexpr bool
empty() const requires forward_range<const _Derived>
{ return ranges::begin(_M_derived()) == ranges::end(_M_derived()); }
constexpr explicit
operator bool() requires requires { ranges::empty(_M_derived()); }
{ return !ranges::empty(_M_derived()); }
constexpr explicit
operator bool() const requires requires { ranges::empty(_M_derived()); }
{ return !ranges::empty(_M_derived()); }
constexpr auto
data() requires contiguous_iterator<iterator_t<_Derived>>
{ return to_address(ranges::begin(_M_derived())); }
constexpr auto
data() const
requires range<const _Derived>
&& contiguous_iterator<iterator_t<const _Derived>>
{ return to_address(ranges::begin(_M_derived())); }
constexpr auto
size()
requires forward_range<_Derived>
&& sized_sentinel_for<sentinel_t<_Derived>, iterator_t<_Derived>>
{ return ranges::end(_M_derived()) - ranges::begin(_M_derived()); }
constexpr auto
size() const
requires forward_range<const _Derived>
&& sized_sentinel_for<sentinel_t<const _Derived>,
iterator_t<const _Derived>>
{ return ranges::end(_M_derived()) - ranges::begin(_M_derived()); }
constexpr decltype(auto)
front() requires forward_range<_Derived>
{
__glibcxx_assert(!empty());
return *ranges::begin(_M_derived());
}
constexpr decltype(auto)
front() const requires forward_range<const _Derived>
{
__glibcxx_assert(!empty());
return *ranges::begin(_M_derived());
}
constexpr decltype(auto)
back()
requires bidirectional_range<_Derived> && common_range<_Derived>
{
__glibcxx_assert(!empty());
return *ranges::prev(ranges::end(_M_derived()));
}
constexpr decltype(auto)
back() const
requires bidirectional_range<const _Derived>
&& common_range<const _Derived>
{
__glibcxx_assert(!empty());
return *ranges::prev(ranges::end(_M_derived()));
}
template<random_access_range _Range = _Derived>
constexpr decltype(auto)
operator[](range_difference_t<_Range> __n)
{ return ranges::begin(_M_derived())[__n]; }
template<random_access_range _Range = const _Derived>
constexpr decltype(auto)
operator[](range_difference_t<_Range> __n) const
{ return ranges::begin(_M_derived())[__n]; }
};
namespace __detail
{
template<typename _From, typename _To>
concept __uses_nonqualification_pointer_conversion
= is_pointer_v<_From> && is_pointer_v<_To>
&& !convertible_to<remove_pointer_t<_From>(*)[],
remove_pointer_t<_To>(*)[]>;
template<typename _From, typename _To>
concept __convertible_to_non_slicing = convertible_to<_From, _To>
&& !__uses_nonqualification_pointer_conversion<decay_t<_From>,
decay_t<_To>>;
template<typename _Tp>
concept __pair_like
= !is_reference_v<_Tp> && requires(_Tp __t)
{
typename tuple_size<_Tp>::type;
requires derived_from<tuple_size<_Tp>, integral_constant<size_t, 2>>;
typename tuple_element_t<0, remove_const_t<_Tp>>;
typename tuple_element_t<1, remove_const_t<_Tp>>;
{ get<0>(__t) } -> convertible_to<const tuple_element_t<0, _Tp>&>;
{ get<1>(__t) } -> convertible_to<const tuple_element_t<1, _Tp>&>;
};
template<typename _Tp, typename _Up, typename _Vp>
concept __pair_like_convertible_from
= !range<_Tp> && __pair_like<_Tp>
&& constructible_from<_Tp, _Up, _Vp>
&& __convertible_to_non_slicing<_Up, tuple_element_t<0, _Tp>>
&& convertible_to<_Vp, tuple_element_t<1, _Tp>>;
} // namespace __detail
enum class subrange_kind : bool { unsized, sized };
/// The ranges::subrange class template
template<input_or_output_iterator _It, sentinel_for<_It> _Sent = _It,
subrange_kind _Kind = sized_sentinel_for<_Sent, _It>
? subrange_kind::sized : subrange_kind::unsized>
requires (_Kind == subrange_kind::sized || !sized_sentinel_for<_Sent, _It>)
class subrange : public view_interface<subrange<_It, _Sent, _Kind>>
{
private:
// XXX: gcc complains when using constexpr here
static const bool _S_store_size
= _Kind == subrange_kind::sized && !sized_sentinel_for<_Sent, _It>;
_It _M_begin = _It();
[[no_unique_address]] _Sent _M_end = _Sent();
using __size_type
= __detail::__make_unsigned_like_t<iter_difference_t<_It>>;
template<typename, bool = _S_store_size>
struct _Size
{ };
template<typename _Tp>
struct _Size<_Tp, true>
{ _Tp _M_size; };
[[no_unique_address]] _Size<__size_type> _M_size = {};
public:
subrange() requires default_initializable<_It> = default;
constexpr
subrange(__detail::__convertible_to_non_slicing<_It> auto __i, _Sent __s)
requires (!_S_store_size)
: _M_begin(std::move(__i)), _M_end(__s)
{ }
constexpr
subrange(__detail::__convertible_to_non_slicing<_It> auto __i, _Sent __s,
__size_type __n)
requires (_Kind == subrange_kind::sized)
: _M_begin(std::move(__i)), _M_end(__s)
{
if constexpr (_S_store_size)
_M_size._M_size = __n;
}
template<__detail::__not_same_as<subrange> _Rng>
requires borrowed_range<_Rng>
&& __detail::__convertible_to_non_slicing<iterator_t<_Rng>, _It>
&& convertible_to<sentinel_t<_Rng>, _Sent>
constexpr
subrange(_Rng&& __r) requires _S_store_size && sized_range<_Rng>
: subrange(__r, ranges::size(__r))
{ }
template<__detail::__not_same_as<subrange> _Rng>
requires borrowed_range<_Rng>
&& __detail::__convertible_to_non_slicing<iterator_t<_Rng>, _It>
&& convertible_to<sentinel_t<_Rng>, _Sent>
constexpr
subrange(_Rng&& __r) requires (!_S_store_size)
: subrange(ranges::begin(__r), ranges::end(__r))
{ }
template<borrowed_range _Rng>
requires __detail::__convertible_to_non_slicing<iterator_t<_Rng>, _It>
&& convertible_to<sentinel_t<_Rng>, _Sent>
constexpr
subrange(_Rng&& __r, __size_type __n)
requires (_Kind == subrange_kind::sized)
: subrange{ranges::begin(__r), ranges::end(__r), __n}
{ }
template<__detail::__not_same_as<subrange> _PairLike>
requires __detail::__pair_like_convertible_from<_PairLike, const _It&,
const _Sent&>
constexpr
operator _PairLike() const
{ return _PairLike(_M_begin, _M_end); }
constexpr _It
begin() const requires copyable<_It>
{ return _M_begin; }
[[nodiscard]] constexpr _It
begin() requires (!copyable<_It>)
{ return std::move(_M_begin); }
constexpr _Sent end() const { return _M_end; }
constexpr bool empty() const { return _M_begin == _M_end; }
constexpr __size_type
size() const requires (_Kind == subrange_kind::sized)
{
if constexpr (_S_store_size)
return _M_size._M_size;
else
return __detail::__to_unsigned_like(_M_end - _M_begin);
}
[[nodiscard]] constexpr subrange
next(iter_difference_t<_It> __n = 1) const &
requires forward_iterator<_It>
{
auto __tmp = *this;
__tmp.advance(__n);
return __tmp;
}
[[nodiscard]] constexpr subrange
next(iter_difference_t<_It> __n = 1) &&
{
advance(__n);
return std::move(*this);
}
[[nodiscard]] constexpr subrange
prev(iter_difference_t<_It> __n = 1) const
requires bidirectional_iterator<_It>
{
auto __tmp = *this;
__tmp.advance(-__n);
return __tmp;
}
constexpr subrange&
advance(iter_difference_t<_It> __n)
{
// _GLIBCXX_RESOLVE_LIB_DEFECTS
// 3433. subrange::advance(n) has UB when n < 0
if constexpr (bidirectional_iterator<_It>)
if (__n < 0)
{
ranges::advance(_M_begin, __n);
if constexpr (_S_store_size)
_M_size._M_size += __detail::__to_unsigned_like(-__n);
return *this;
}
__glibcxx_assert(__n >= 0);
auto __d = __n - ranges::advance(_M_begin, __n, _M_end);
if constexpr (_S_store_size)
_M_size._M_size -= __detail::__to_unsigned_like(__d);
return *this;
}
};
template<input_or_output_iterator _It, sentinel_for<_It> _Sent>
subrange(_It, _Sent) -> subrange<_It, _Sent>;
template<input_or_output_iterator _It, sentinel_for<_It> _Sent>
subrange(_It, _Sent,
__detail::__make_unsigned_like_t<iter_difference_t<_It>>)
-> subrange<_It, _Sent, subrange_kind::sized>;
template<borrowed_range _Rng>
subrange(_Rng&&)
-> subrange<iterator_t<_Rng>, sentinel_t<_Rng>,
(sized_range<_Rng>
|| sized_sentinel_for<sentinel_t<_Rng>, iterator_t<_Rng>>)
? subrange_kind::sized : subrange_kind::unsized>;
template<borrowed_range _Rng>
subrange(_Rng&&,
__detail::__make_unsigned_like_t<range_difference_t<_Rng>>)
-> subrange<iterator_t<_Rng>, sentinel_t<_Rng>, subrange_kind::sized>;
template<size_t _Num, class _It, class _Sent, subrange_kind _Kind>
requires (_Num < 2)
constexpr auto
get(const subrange<_It, _Sent, _Kind>& __r)
{
if constexpr (_Num == 0)
return __r.begin();
else
return __r.end();
}
template<size_t _Num, class _It, class _Sent, subrange_kind _Kind>
requires (_Num < 2)
constexpr auto
get(subrange<_It, _Sent, _Kind>&& __r)
{
if constexpr (_Num == 0)
return __r.begin();
else
return __r.end();
}
template<input_or_output_iterator _It, sentinel_for<_It> _Sent,
subrange_kind _Kind>
inline constexpr bool
enable_borrowed_range<subrange<_It, _Sent, _Kind>> = true;
template<range _Range>
using borrowed_subrange_t = conditional_t<borrowed_range<_Range>,
subrange<iterator_t<_Range>>,
dangling>;
} // namespace ranges
// The following ranges algorithms are used by <ranges>, and are defined here
// so that <ranges> can avoid including all of <bits/ranges_algo.h>.
namespace ranges
{
struct __find_fn
{
template<input_iterator _Iter, sentinel_for<_Iter> _Sent, typename _Tp,
typename _Proj = identity>
requires indirect_binary_predicate<ranges::equal_to,
projected<_Iter, _Proj>, const _Tp*>
constexpr _Iter
operator()(_Iter __first, _Sent __last,
const _Tp& __value, _Proj __proj = {}) const
{
while (__first != __last
&& !(std::__invoke(__proj, *__first) == __value))
++__first;
return __first;
}
template<input_range _Range, typename _Tp, typename _Proj = identity>
requires indirect_binary_predicate<ranges::equal_to,
projected<iterator_t<_Range>, _Proj>,
const _Tp*>
constexpr borrowed_iterator_t<_Range>
operator()(_Range&& __r, const _Tp& __value, _Proj __proj = {}) const
{
return (*this)(ranges::begin(__r), ranges::end(__r),
__value, std::move(__proj));
}
};
inline constexpr __find_fn find{};
struct __find_if_fn
{
template<input_iterator _Iter, sentinel_for<_Iter> _Sent,
typename _Proj = identity,
indirect_unary_predicate<projected<_Iter, _Proj>> _Pred>
constexpr _Iter
operator()(_Iter __first, _Sent __last,
_Pred __pred, _Proj __proj = {}) const
{
while (__first != __last
&& !(bool)std::__invoke(__pred, std::__invoke(__proj, *__first)))
++__first;
return __first;
}
template<input_range _Range, typename _Proj = identity,
indirect_unary_predicate<projected<iterator_t<_Range>, _Proj>>
_Pred>
constexpr borrowed_iterator_t<_Range>
operator()(_Range&& __r, _Pred __pred, _Proj __proj = {}) const
{
return (*this)(ranges::begin(__r), ranges::end(__r),
std::move(__pred), std::move(__proj));
}
};
inline constexpr __find_if_fn find_if{};
struct __find_if_not_fn
{
template<input_iterator _Iter, sentinel_for<_Iter> _Sent,
typename _Proj = identity,
indirect_unary_predicate<projected<_Iter, _Proj>> _Pred>
constexpr _Iter
operator()(_Iter __first, _Sent __last,
_Pred __pred, _Proj __proj = {}) const
{
while (__first != __last
&& (bool)std::__invoke(__pred, std::__invoke(__proj, *__first)))
++__first;
return __first;
}
template<input_range _Range, typename _Proj = identity,
indirect_unary_predicate<projected<iterator_t<_Range>, _Proj>>
_Pred>
constexpr borrowed_iterator_t<_Range>
operator()(_Range&& __r, _Pred __pred, _Proj __proj = {}) const
{
return (*this)(ranges::begin(__r), ranges::end(__r),
std::move(__pred), std::move(__proj));
}
};
inline constexpr __find_if_not_fn find_if_not{};
template<typename _Iter1, typename _Iter2>
struct in_in_result
{
[[no_unique_address]] _Iter1 in1;
[[no_unique_address]] _Iter2 in2;
template<typename _IIter1, typename _IIter2>
requires convertible_to<const _Iter1&, _IIter1>
&& convertible_to<const _Iter2&, _IIter2>
constexpr
operator in_in_result<_IIter1, _IIter2>() const &
{ return {in1, in2}; }
template<typename _IIter1, typename _IIter2>
requires convertible_to<_Iter1, _IIter1>
&& convertible_to<_Iter2, _IIter2>
constexpr
operator in_in_result<_IIter1, _IIter2>() &&
{ return {std::move(in1), std::move(in2)}; }
};
template<typename _Iter1, typename _Iter2>
using mismatch_result = in_in_result<_Iter1, _Iter2>;
struct __mismatch_fn
{
template<input_iterator _Iter1, sentinel_for<_Iter1> _Sent1,
input_iterator _Iter2, sentinel_for<_Iter2> _Sent2,
typename _Pred = ranges::equal_to,
typename _Proj1 = identity, typename _Proj2 = identity>
requires indirectly_comparable<_Iter1, _Iter2, _Pred, _Proj1, _Proj2>
constexpr mismatch_result<_Iter1, _Iter2>
operator()(_Iter1 __first1, _Sent1 __last1,
_Iter2 __first2, _Sent2 __last2, _Pred __pred = {},
_Proj1 __proj1 = {}, _Proj2 __proj2 = {}) const
{
while (__first1 != __last1 && __first2 != __last2
&& (bool)std::__invoke(__pred,
std::__invoke(__proj1, *__first1),
std::__invoke(__proj2, *__first2)))
{
++__first1;
++__first2;
}
return { std::move(__first1), std::move(__first2) };
}
template<input_range _Range1, input_range _Range2,
typename _Pred = ranges::equal_to,
typename _Proj1 = identity, typename _Proj2 = identity>
requires indirectly_comparable<iterator_t<_Range1>, iterator_t<_Range2>,
_Pred, _Proj1, _Proj2>
constexpr mismatch_result<iterator_t<_Range1>, iterator_t<_Range2>>
operator()(_Range1&& __r1, _Range2&& __r2, _Pred __pred = {},
_Proj1 __proj1 = {}, _Proj2 __proj2 = {}) const
{
return (*this)(ranges::begin(__r1), ranges::end(__r1),
ranges::begin(__r2), ranges::end(__r2),
std::move(__pred),
std::move(__proj1), std::move(__proj2));
}
};
inline constexpr __mismatch_fn mismatch{};
struct __search_fn
{
template<forward_iterator _Iter1, sentinel_for<_Iter1> _Sent1,
forward_iterator _Iter2, sentinel_for<_Iter2> _Sent2,
typename _Pred = ranges::equal_to,
typename _Proj1 = identity, typename _Proj2 = identity>
requires indirectly_comparable<_Iter1, _Iter2, _Pred, _Proj1, _Proj2>
constexpr subrange<_Iter1>
operator()(_Iter1 __first1, _Sent1 __last1,
_Iter2 __first2, _Sent2 __last2, _Pred __pred = {},
_Proj1 __proj1 = {}, _Proj2 __proj2 = {}) const
{
if (__first1 == __last1 || __first2 == __last2)
return {__first1, __first1};
for (;;)
{
for (;;)
{
if (__first1 == __last1)
return {__first1, __first1};
if (std::__invoke(__pred,
std::__invoke(__proj1, *__first1),
std::__invoke(__proj2, *__first2)))
break;
++__first1;
}
auto __cur1 = __first1;
auto __cur2 = __first2;
for (;;)
{
if (++__cur2 == __last2)
return {__first1, ++__cur1};
if (++__cur1 == __last1)
return {__cur1, __cur1};
if (!(bool)std::__invoke(__pred,
std::__invoke(__proj1, *__cur1),
std::__invoke(__proj2, *__cur2)))
{
++__first1;
break;
}
}
}
}
template<forward_range _Range1, forward_range _Range2,
typename _Pred = ranges::equal_to,
typename _Proj1 = identity, typename _Proj2 = identity>
requires indirectly_comparable<iterator_t<_Range1>, iterator_t<_Range2>,
_Pred, _Proj1, _Proj2>
constexpr borrowed_subrange_t<_Range1>
operator()(_Range1&& __r1, _Range2&& __r2, _Pred __pred = {},
_Proj1 __proj1 = {}, _Proj2 __proj2 = {}) const
{
return (*this)(ranges::begin(__r1), ranges::end(__r1),
ranges::begin(__r2), ranges::end(__r2),
std::move(__pred),
std::move(__proj1), std::move(__proj2));
}
};
inline constexpr __search_fn search{};
} // namespace ranges
using ranges::get;
template<typename _Iter, typename _Sent, ranges::subrange_kind _Kind>
struct tuple_size<ranges::subrange<_Iter, _Sent, _Kind>>
: integral_constant<size_t, 2>
{ };
template<typename _Iter, typename _Sent, ranges::subrange_kind _Kind>
struct tuple_element<0, ranges::subrange<_Iter, _Sent, _Kind>>
{ using type = _Iter; };
template<typename _Iter, typename _Sent, ranges::subrange_kind _Kind>
struct tuple_element<1, ranges::subrange<_Iter, _Sent, _Kind>>
{ using type = _Sent; };
template<typename _Iter, typename _Sent, ranges::subrange_kind _Kind>
struct tuple_element<0, const ranges::subrange<_Iter, _Sent, _Kind>>
{ using type = _Iter; };
template<typename _Iter, typename _Sent, ranges::subrange_kind _Kind>
struct tuple_element<1, const ranges::subrange<_Iter, _Sent, _Kind>>
{ using type = _Sent; };
_GLIBCXX_END_NAMESPACE_VERSION
} // namespace std
#endif // library concepts
#endif // C++20
#endif // _RANGES_UTIL_H
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