libcxx/src/filesystem/time_utils.h - external/github.com/llvm/llvm-project.git - Git at Google

 //===----------------------------------------------------------------------===////
 //
 // 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 FILESYSTEM_TIME_UTILS_H
 #define FILESYSTEM_TIME_UTILS_H

 #include <__config>
 #include <array>
 #include <chrono>
 #include <filesystem>
 #include <limits>
 #include <ratio>
 #include <system_error>
 #include <type_traits>
 #include <utility>

 #include "error.h"
 #include "format_string.h"

 #if defined(_LIBCPP_WIN32API)
 #  define WIN32_LEAN_AND_MEAN
 #  define NOMINMAX
 #  include <windows.h>
 #else
 #  include <fcntl.h>
 #  include <sys/stat.h>
 #  include <sys/time.h> // for ::utimes as used in __last_write_time
 #endif

 // We can use the presence of UTIME_OMIT to detect platforms that provide utimensat.
 #if defined(UTIME_OMIT)
 #  define _LIBCPP_USE_UTIMENSAT
 #endif

 _LIBCPP_BEGIN_NAMESPACE_FILESYSTEM

 namespace detail {

 #if defined(_LIBCPP_WIN32API)
 // Various C runtime versions (UCRT, or the legacy msvcrt.dll used by
 // some mingw toolchains) provide different stat function implementations,
 // with a number of limitations with respect to what we want from the
 // stat function. Instead provide our own which does exactly what we want,
 // along with our own stat structure and flag macros.

 struct TimeSpec {
   int64_t tv_sec;
   int64_t tv_nsec;
 };
 struct StatT {
   unsigned st_mode;
   TimeSpec st_atim;
   TimeSpec st_mtim;
   uint64_t st_dev; // FILE_ID_INFO::VolumeSerialNumber
   struct FileIdStruct {
     unsigned char id[16]; // FILE_ID_INFO::FileId
     bool operator==(const FileIdStruct& other) const {
       for (int i = 0; i < 16; i++)
         if (id[i] != other.id[i])
           return false;
       return true;
     }
   } st_ino;
   uint32_t st_nlink;
   uintmax_t st_size;
 };

 // There were 369 years and 89 leap days from the Windows epoch
 // (1601) to the Unix epoch (1970).
 #  define FILE_TIME_OFFSET_SECS (uint64_t(369 * 365 + 89) * (24 * 60 * 60))

 inline TimeSpec filetime_to_timespec(LARGE_INTEGER li) {
   TimeSpec ret;
   ret.tv_sec  = li.QuadPart / 10000000 - FILE_TIME_OFFSET_SECS;
   ret.tv_nsec = (li.QuadPart % 10000000) * 100;
   return ret;
 }

 inline TimeSpec filetime_to_timespec(FILETIME ft) {
   LARGE_INTEGER li;
   li.LowPart  = ft.dwLowDateTime;
   li.HighPart = ft.dwHighDateTime;
   return filetime_to_timespec(li);
 }

 inline FILETIME timespec_to_filetime(TimeSpec ts) {
   LARGE_INTEGER li;
   li.QuadPart = ts.tv_nsec / 100 + (ts.tv_sec + FILE_TIME_OFFSET_SECS) * 10000000;
   FILETIME ft;
   ft.dwLowDateTime  = li.LowPart;
   ft.dwHighDateTime = li.HighPart;
   return ft;
 }

 #else
 using TimeSpec = struct timespec;
 using TimeVal  = struct timeval;
 using StatT    = struct stat;

 inline TimeVal make_timeval(TimeSpec const& ts) {
   using namespace chrono;
   auto Convert = [](long nsec) {
     using int_type = decltype(std::declval<TimeVal>().tv_usec);
     auto dur       = duration_cast<microseconds>(nanoseconds(nsec)).count();
     return static_cast<int_type>(dur);
   };
   TimeVal TV = {};
   TV.tv_sec  = ts.tv_sec;
   TV.tv_usec = Convert(ts.tv_nsec);
   return TV;
 }
 #endif

 using chrono::duration;
 using chrono::duration_cast;

 template <class FileTimeT, class TimeT, bool IsFloat = is_floating_point<typename FileTimeT::rep>::value>
 struct time_util_base {
   using rep             = typename FileTimeT::rep;
   using fs_duration     = typename FileTimeT::duration;
   using fs_seconds      = duration<rep>;
   using fs_nanoseconds  = duration<rep, nano>;
   using fs_microseconds = duration<rep, micro>;

   static constexpr rep max_seconds = duration_cast<fs_seconds>(FileTimeT::duration::max()).count();

   static constexpr rep max_nsec =
       duration_cast<fs_nanoseconds>(FileTimeT::duration::max() - fs_seconds(max_seconds)).count();

   static constexpr rep min_seconds = duration_cast<fs_seconds>(FileTimeT::duration::min()).count();

   static constexpr rep min_nsec_timespec =
       duration_cast<fs_nanoseconds>((FileTimeT::duration::min() - fs_seconds(min_seconds)) + fs_seconds(1)).count();

 private:
   static constexpr fs_duration get_min_nsecs() {
     return duration_cast<fs_duration>(fs_nanoseconds(min_nsec_timespec) - duration_cast<fs_nanoseconds>(fs_seconds(1)));
   }
   // Static assert that these values properly round trip.
   static_assert(fs_seconds(min_seconds) + get_min_nsecs() == FileTimeT::duration::min(), "value doesn't roundtrip");

   static constexpr bool check_range() {
     // This kinda sucks, but it's what happens when we don't have __int128_t.
     if (sizeof(TimeT) == sizeof(rep)) {
       typedef duration<long long, ratio<3600 * 24 * 365> > Years;
       return duration_cast<Years>(fs_seconds(max_seconds)) > Years(250) &&
              duration_cast<Years>(fs_seconds(min_seconds)) < Years(-250);
     }
     return max_seconds >= numeric_limits<TimeT>::max() && min_seconds <= numeric_limits<TimeT>::min();
   }
 #if _LIBCPP_STD_VER >= 14
   static_assert(check_range(), "the representable range is unacceptable small");
 #endif
 };

 template <class FileTimeT, class TimeT>
 struct time_util_base<FileTimeT, TimeT, true> {
   using rep             = typename FileTimeT::rep;
   using fs_duration     = typename FileTimeT::duration;
   using fs_seconds      = duration<rep>;
   using fs_nanoseconds  = duration<rep, nano>;
   using fs_microseconds = duration<rep, micro>;

   static const rep max_seconds;
   static const rep max_nsec;
   static const rep min_seconds;
   static const rep min_nsec_timespec;
 };

 template <class FileTimeT, class TimeT>
 const typename FileTimeT::rep time_util_base<FileTimeT, TimeT, true>::max_seconds =
     duration_cast<fs_seconds>(FileTimeT::duration::max()).count();

 template <class FileTimeT, class TimeT>
 const typename FileTimeT::rep time_util_base<FileTimeT, TimeT, true>::max_nsec =
     duration_cast<fs_nanoseconds>(FileTimeT::duration::max() - fs_seconds(max_seconds)).count();

 template <class FileTimeT, class TimeT>
 const typename FileTimeT::rep time_util_base<FileTimeT, TimeT, true>::min_seconds =
     duration_cast<fs_seconds>(FileTimeT::duration::min()).count();

 template <class FileTimeT, class TimeT>
 const typename FileTimeT::rep time_util_base<FileTimeT, TimeT, true>::min_nsec_timespec =
     duration_cast<fs_nanoseconds>((FileTimeT::duration::min() - fs_seconds(min_seconds)) + fs_seconds(1)).count();

 template <class FileTimeT, class TimeT, class TimeSpecT>
 struct time_util : time_util_base<FileTimeT, TimeT> {
   using Base = time_util_base<FileTimeT, TimeT>;
   using Base::max_nsec;
   using Base::max_seconds;
   using Base::min_nsec_timespec;
   using Base::min_seconds;

   using typename Base::fs_duration;
   using typename Base::fs_microseconds;
   using typename Base::fs_nanoseconds;
   using typename Base::fs_seconds;

 public:
   template <class CType, class ChronoType>
   static constexpr bool checked_set(CType* out, ChronoType time) {
     using Lim = numeric_limits<CType>;
     if (time > Lim::max() || time < Lim::min())
       return false;
     *out = static_cast<CType>(time);
     return true;
   }

   static constexpr bool is_representable(TimeSpecT tm) {
     if (tm.tv_sec >= 0) {
       return tm.tv_sec < max_seconds || (tm.tv_sec == max_seconds && tm.tv_nsec <= max_nsec);
     } else if (tm.tv_sec == (min_seconds - 1)) {
       return tm.tv_nsec >= min_nsec_timespec;
     } else {
       return tm.tv_sec >= min_seconds;
     }
   }

   static constexpr bool is_representable(FileTimeT tm) {
     auto secs  = duration_cast<fs_seconds>(tm.time_since_epoch());
     auto nsecs = duration_cast<fs_nanoseconds>(tm.time_since_epoch() - secs);
     if (nsecs.count() < 0) {
       secs  = secs + fs_seconds(1);
       nsecs = nsecs + fs_seconds(1);
     }
     using TLim = numeric_limits<TimeT>;
     if (secs.count() >= 0)
       return secs.count() <= TLim::max();
     return secs.count() >= TLim::min();
   }

   static constexpr FileTimeT convert_from_timespec(TimeSpecT tm) {
     if (tm.tv_sec >= 0 || tm.tv_nsec == 0) {
       return FileTimeT(fs_seconds(tm.tv_sec) + duration_cast<fs_duration>(fs_nanoseconds(tm.tv_nsec)));
     } else { // tm.tv_sec < 0
       auto adj_subsec = duration_cast<fs_duration>(fs_seconds(1) - fs_nanoseconds(tm.tv_nsec));
       auto Dur        = fs_seconds(tm.tv_sec + 1) - adj_subsec;
       return FileTimeT(Dur);
     }
   }

   template <class SubSecT>
   static constexpr bool set_times_checked(TimeT* sec_out, SubSecT* subsec_out, FileTimeT tp) {
     auto dur        = tp.time_since_epoch();
     auto sec_dur    = duration_cast<fs_seconds>(dur);
     auto subsec_dur = duration_cast<fs_nanoseconds>(dur - sec_dur);
     // The tv_nsec and tv_usec fields must not be negative so adjust accordingly
     if (subsec_dur.count() < 0) {
       if (sec_dur.count() > min_seconds) {
         sec_dur    = sec_dur - fs_seconds(1);
         subsec_dur = subsec_dur + fs_seconds(1);
       } else {
         subsec_dur = fs_nanoseconds::zero();
       }
     }
     return checked_set(sec_out, sec_dur.count()) && checked_set(subsec_out, subsec_dur.count());
   }
   static constexpr bool convert_to_timespec(TimeSpecT& dest, FileTimeT tp) {
     if (!is_representable(tp))
       return false;
     return set_times_checked(&dest.tv_sec, &dest.tv_nsec, tp);
   }
 };

 #if defined(_LIBCPP_WIN32API)
 using fs_time = time_util<file_time_type, int64_t, TimeSpec>;
 #else
 using fs_time = time_util<file_time_type, time_t, TimeSpec>;
 #endif

 #if defined(__APPLE__)
 inline TimeSpec extract_mtime(StatT const& st) { return st.st_mtimespec; }
 inline TimeSpec extract_atime(StatT const& st) { return st.st_atimespec; }
 #elif defined(__MVS__)
 inline TimeSpec extract_mtime(StatT const& st) {
   TimeSpec TS = {st.st_mtime, 0};
   return TS;
 }
 inline TimeSpec extract_atime(StatT const& st) {
   TimeSpec TS = {st.st_atime, 0};
   return TS;
 }
 #elif defined(_AIX)
 inline TimeSpec extract_mtime(StatT const& st) {
   TimeSpec TS = {st.st_mtime, st.st_mtime_n};
   return TS;
 }
 inline TimeSpec extract_atime(StatT const& st) {
   TimeSpec TS = {st.st_atime, st.st_atime_n};
   return TS;
 }
 #else
 inline TimeSpec extract_mtime(StatT const& st) { return st.st_mtim; }
 inline TimeSpec extract_atime(StatT const& st) { return st.st_atim; }
 #endif

 #ifndef _LIBCPP_HAS_NO_FILESYSTEM

 #  if !defined(_LIBCPP_WIN32API)
 inline bool posix_utimes(const path& p, std::array<TimeSpec, 2> const& TS, error_code& ec) {
   TimeVal ConvertedTS[2] = {make_timeval(TS[0]), make_timeval(TS[1])};
   if (::utimes(p.c_str(), ConvertedTS) == -1) {
     ec = capture_errno();
     return true;
   }
   return false;
 }

 #    if defined(_LIBCPP_USE_UTIMENSAT)
 inline bool posix_utimensat(const path& p, std::array<TimeSpec, 2> const& TS, error_code& ec) {
   if (::utimensat(AT_FDCWD, p.c_str(), TS.data(), 0) == -1) {
     ec = capture_errno();
     return true;
   }
   return false;
 }
 #    endif

 inline bool set_file_times(const path& p, std::array<TimeSpec, 2> const& TS, error_code& ec) {
 #    if !defined(_LIBCPP_USE_UTIMENSAT)
   return posix_utimes(p, TS, ec);
 #    else
   return posix_utimensat(p, TS, ec);
 #    endif
 }

 #  endif // !_LIBCPP_WIN32API

 inline file_time_type __extract_last_write_time(const path& p, const StatT& st, error_code* ec) {
   using detail::fs_time;
   ErrorHandler<file_time_type> err("last_write_time", ec, &p);

   auto ts = detail::extract_mtime(st);
   if (!fs_time::is_representable(ts))
     return err.report(errc::value_too_large);

   return fs_time::convert_from_timespec(ts);
 }

 #endif // !_LIBCPP_HAS_NO_FILESYSTEM

 } // namespace detail

 _LIBCPP_END_NAMESPACE_FILESYSTEM

 #endif // FILESYSTEM_TIME_UTILS_H
	//===----------------------------------------------------------------------===////
	//
	// 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 FILESYSTEM_TIME_UTILS_H
	#define FILESYSTEM_TIME_UTILS_H

	#include <__config>
	#include <array>
	#include <chrono>
	#include <filesystem>
	#include <limits>
	#include <ratio>
	#include <system_error>
	#include <type_traits>
	#include <utility>

	#include "error.h"
	#include "format_string.h"

	#if defined(_LIBCPP_WIN32API)
	# define WIN32_LEAN_AND_MEAN
	# define NOMINMAX
	# include <windows.h>
	#else
	# include <fcntl.h>
	# include <sys/stat.h>
	# include <sys/time.h> // for ::utimes as used in __last_write_time
	#endif

	// We can use the presence of UTIME_OMIT to detect platforms that provide utimensat.
	#if defined(UTIME_OMIT)
	# define _LIBCPP_USE_UTIMENSAT
	#endif

	_LIBCPP_BEGIN_NAMESPACE_FILESYSTEM

	namespace detail {

	#if defined(_LIBCPP_WIN32API)
	// Various C runtime versions (UCRT, or the legacy msvcrt.dll used by
	// some mingw toolchains) provide different stat function implementations,
	// with a number of limitations with respect to what we want from the
	// stat function. Instead provide our own which does exactly what we want,
	// along with our own stat structure and flag macros.

	struct TimeSpec {
	int64_t tv_sec;
	int64_t tv_nsec;
	};
	struct StatT {
	unsigned st_mode;
	TimeSpec st_atim;
	TimeSpec st_mtim;
	uint64_t st_dev; // FILE_ID_INFO::VolumeSerialNumber
	struct FileIdStruct {
	unsigned char id[16]; // FILE_ID_INFO::FileId
	bool operator==(const FileIdStruct& other) const {
	for (int i = 0; i < 16; i++)
	if (id[i] != other.id[i])
	return false;
	return true;
	}
	} st_ino;
	uint32_t st_nlink;
	uintmax_t st_size;
	};

	// There were 369 years and 89 leap days from the Windows epoch
	// (1601) to the Unix epoch (1970).
	# define FILE_TIME_OFFSET_SECS (uint64_t(369 * 365 + 89) * (24 * 60 * 60))

	inline TimeSpec filetime_to_timespec(LARGE_INTEGER li) {
	TimeSpec ret;
	ret.tv_sec = li.QuadPart / 10000000 - FILE_TIME_OFFSET_SECS;
	ret.tv_nsec = (li.QuadPart % 10000000) * 100;
	return ret;
	}

	inline TimeSpec filetime_to_timespec(FILETIME ft) {
	LARGE_INTEGER li;
	li.LowPart = ft.dwLowDateTime;
	li.HighPart = ft.dwHighDateTime;
	return filetime_to_timespec(li);
	}

	inline FILETIME timespec_to_filetime(TimeSpec ts) {
	LARGE_INTEGER li;
	li.QuadPart = ts.tv_nsec / 100 + (ts.tv_sec + FILE_TIME_OFFSET_SECS) * 10000000;
	FILETIME ft;
	ft.dwLowDateTime = li.LowPart;
	ft.dwHighDateTime = li.HighPart;
	return ft;
	}

	#else
	using TimeSpec = struct timespec;
	using TimeVal = struct timeval;
	using StatT = struct stat;

	inline TimeVal make_timeval(TimeSpec const& ts) {
	using namespace chrono;
	auto Convert = [](long nsec) {
	using int_type = decltype(std::declval<TimeVal>().tv_usec);
	auto dur = duration_cast<microseconds>(nanoseconds(nsec)).count();
	return static_cast<int_type>(dur);
	};
	TimeVal TV = {};
	TV.tv_sec = ts.tv_sec;
	TV.tv_usec = Convert(ts.tv_nsec);
	return TV;
	}
	#endif

	using chrono::duration;
	using chrono::duration_cast;

	template <class FileTimeT, class TimeT, bool IsFloat = is_floating_point<typename FileTimeT::rep>::value>
	struct time_util_base {
	using rep = typename FileTimeT::rep;
	using fs_duration = typename FileTimeT::duration;
	using fs_seconds = duration<rep>;
	using fs_nanoseconds = duration<rep, nano>;
	using fs_microseconds = duration<rep, micro>;

	static constexpr rep max_seconds = duration_cast<fs_seconds>(FileTimeT::duration::max()).count();

	static constexpr rep max_nsec =
	duration_cast<fs_nanoseconds>(FileTimeT::duration::max() - fs_seconds(max_seconds)).count();

	static constexpr rep min_seconds = duration_cast<fs_seconds>(FileTimeT::duration::min()).count();

	static constexpr rep min_nsec_timespec =
	duration_cast<fs_nanoseconds>((FileTimeT::duration::min() - fs_seconds(min_seconds)) + fs_seconds(1)).count();

	private:
	static constexpr fs_duration get_min_nsecs() {
	return duration_cast<fs_duration>(fs_nanoseconds(min_nsec_timespec) - duration_cast<fs_nanoseconds>(fs_seconds(1)));
	}
	// Static assert that these values properly round trip.
	static_assert(fs_seconds(min_seconds) + get_min_nsecs() == FileTimeT::duration::min(), "value doesn't roundtrip");

	static constexpr bool check_range() {
	// This kinda sucks, but it's what happens when we don't have __int128_t.
	if (sizeof(TimeT) == sizeof(rep)) {
	typedef duration<long long, ratio<3600 * 24 * 365> > Years;
	return duration_cast<Years>(fs_seconds(max_seconds)) > Years(250) &&
	duration_cast<Years>(fs_seconds(min_seconds)) < Years(-250);
	}
	return max_seconds >= numeric_limits<TimeT>::max() && min_seconds <= numeric_limits<TimeT>::min();
	}
	#if _LIBCPP_STD_VER >= 14
	static_assert(check_range(), "the representable range is unacceptable small");
	#endif
	};

	template <class FileTimeT, class TimeT>
	struct time_util_base<FileTimeT, TimeT, true> {
	using rep = typename FileTimeT::rep;
	using fs_duration = typename FileTimeT::duration;
	using fs_seconds = duration<rep>;
	using fs_nanoseconds = duration<rep, nano>;
	using fs_microseconds = duration<rep, micro>;

	static const rep max_seconds;
	static const rep max_nsec;
	static const rep min_seconds;
	static const rep min_nsec_timespec;
	};

	template <class FileTimeT, class TimeT>
	const typename FileTimeT::rep time_util_base<FileTimeT, TimeT, true>::max_seconds =
	duration_cast<fs_seconds>(FileTimeT::duration::max()).count();

	template <class FileTimeT, class TimeT>
	const typename FileTimeT::rep time_util_base<FileTimeT, TimeT, true>::max_nsec =
	duration_cast<fs_nanoseconds>(FileTimeT::duration::max() - fs_seconds(max_seconds)).count();

	template <class FileTimeT, class TimeT>
	const typename FileTimeT::rep time_util_base<FileTimeT, TimeT, true>::min_seconds =
	duration_cast<fs_seconds>(FileTimeT::duration::min()).count();

	template <class FileTimeT, class TimeT>
	const typename FileTimeT::rep time_util_base<FileTimeT, TimeT, true>::min_nsec_timespec =
	duration_cast<fs_nanoseconds>((FileTimeT::duration::min() - fs_seconds(min_seconds)) + fs_seconds(1)).count();

	template <class FileTimeT, class TimeT, class TimeSpecT>
	struct time_util : time_util_base<FileTimeT, TimeT> {
	using Base = time_util_base<FileTimeT, TimeT>;
	using Base::max_nsec;
	using Base::max_seconds;
	using Base::min_nsec_timespec;
	using Base::min_seconds;

	using typename Base::fs_duration;
	using typename Base::fs_microseconds;
	using typename Base::fs_nanoseconds;
	using typename Base::fs_seconds;

	public:
	template <class CType, class ChronoType>
	static constexpr bool checked_set(CType* out, ChronoType time) {
	using Lim = numeric_limits<CType>;
	if (time > Lim::max() \|\| time < Lim::min())
	return false;
	*out = static_cast<CType>(time);
	return true;
	}

	static constexpr bool is_representable(TimeSpecT tm) {
	if (tm.tv_sec >= 0) {
	return tm.tv_sec < max_seconds \|\| (tm.tv_sec == max_seconds && tm.tv_nsec <= max_nsec);
	} else if (tm.tv_sec == (min_seconds - 1)) {
	return tm.tv_nsec >= min_nsec_timespec;
	} else {
	return tm.tv_sec >= min_seconds;
	}
	}

	static constexpr bool is_representable(FileTimeT tm) {
	auto secs = duration_cast<fs_seconds>(tm.time_since_epoch());
	auto nsecs = duration_cast<fs_nanoseconds>(tm.time_since_epoch() - secs);
	if (nsecs.count() < 0) {
	secs = secs + fs_seconds(1);
	nsecs = nsecs + fs_seconds(1);
	}
	using TLim = numeric_limits<TimeT>;
	if (secs.count() >= 0)
	return secs.count() <= TLim::max();
	return secs.count() >= TLim::min();
	}

	static constexpr FileTimeT convert_from_timespec(TimeSpecT tm) {
	if (tm.tv_sec >= 0 \|\| tm.tv_nsec == 0) {
	return FileTimeT(fs_seconds(tm.tv_sec) + duration_cast<fs_duration>(fs_nanoseconds(tm.tv_nsec)));
	} else { // tm.tv_sec < 0
	auto adj_subsec = duration_cast<fs_duration>(fs_seconds(1) - fs_nanoseconds(tm.tv_nsec));
	auto Dur = fs_seconds(tm.tv_sec + 1) - adj_subsec;
	return FileTimeT(Dur);
	}
	}

	template <class SubSecT>
	static constexpr bool set_times_checked(TimeT* sec_out, SubSecT* subsec_out, FileTimeT tp) {
	auto dur = tp.time_since_epoch();
	auto sec_dur = duration_cast<fs_seconds>(dur);
	auto subsec_dur = duration_cast<fs_nanoseconds>(dur - sec_dur);
	// The tv_nsec and tv_usec fields must not be negative so adjust accordingly
	if (subsec_dur.count() < 0) {
	if (sec_dur.count() > min_seconds) {
	sec_dur = sec_dur - fs_seconds(1);
	subsec_dur = subsec_dur + fs_seconds(1);
	} else {
	subsec_dur = fs_nanoseconds::zero();
	}
	}
	return checked_set(sec_out, sec_dur.count()) && checked_set(subsec_out, subsec_dur.count());
	}
	static constexpr bool convert_to_timespec(TimeSpecT& dest, FileTimeT tp) {
	if (!is_representable(tp))
	return false;
	return set_times_checked(&dest.tv_sec, &dest.tv_nsec, tp);
	}
	};

	#if defined(_LIBCPP_WIN32API)
	using fs_time = time_util<file_time_type, int64_t, TimeSpec>;
	#else
	using fs_time = time_util<file_time_type, time_t, TimeSpec>;
	#endif

	#if defined(__APPLE__)
	inline TimeSpec extract_mtime(StatT const& st) { return st.st_mtimespec; }
	inline TimeSpec extract_atime(StatT const& st) { return st.st_atimespec; }
	#elif defined(__MVS__)
	inline TimeSpec extract_mtime(StatT const& st) {
	TimeSpec TS = {st.st_mtime, 0};
	return TS;
	}
	inline TimeSpec extract_atime(StatT const& st) {
	TimeSpec TS = {st.st_atime, 0};
	return TS;
	}
	#elif defined(_AIX)
	inline TimeSpec extract_mtime(StatT const& st) {
	TimeSpec TS = {st.st_mtime, st.st_mtime_n};
	return TS;
	}
	inline TimeSpec extract_atime(StatT const& st) {
	TimeSpec TS = {st.st_atime, st.st_atime_n};
	return TS;
	}
	#else
	inline TimeSpec extract_mtime(StatT const& st) { return st.st_mtim; }
	inline TimeSpec extract_atime(StatT const& st) { return st.st_atim; }
	#endif

	#ifndef _LIBCPP_HAS_NO_FILESYSTEM

	# if !defined(_LIBCPP_WIN32API)
	inline bool posix_utimes(const path& p, std::array<TimeSpec, 2> const& TS, error_code& ec) {
	TimeVal ConvertedTS[2] = {make_timeval(TS[0]), make_timeval(TS[1])};
	if (::utimes(p.c_str(), ConvertedTS) == -1) {
	ec = capture_errno();
	return true;
	}
	return false;
	}

	# if defined(_LIBCPP_USE_UTIMENSAT)
	inline bool posix_utimensat(const path& p, std::array<TimeSpec, 2> const& TS, error_code& ec) {
	if (::utimensat(AT_FDCWD, p.c_str(), TS.data(), 0) == -1) {
	ec = capture_errno();
	return true;
	}
	return false;
	}
	# endif

	inline bool set_file_times(const path& p, std::array<TimeSpec, 2> const& TS, error_code& ec) {
	# if !defined(_LIBCPP_USE_UTIMENSAT)
	return posix_utimes(p, TS, ec);
	# else
	return posix_utimensat(p, TS, ec);
	# endif
	}

	# endif // !_LIBCPP_WIN32API

	inline file_time_type __extract_last_write_time(const path& p, const StatT& st, error_code* ec) {
	using detail::fs_time;
	ErrorHandler<file_time_type> err("last_write_time", ec, &p);

	auto ts = detail::extract_mtime(st);
	if (!fs_time::is_representable(ts))
	return err.report(errc::value_too_large);

	return fs_time::convert_from_timespec(ts);
	}

	#endif // !_LIBCPP_HAS_NO_FILESYSTEM

	} // namespace detail

	_LIBCPP_END_NAMESPACE_FILESYSTEM

	#endif // FILESYSTEM_TIME_UTILS_H