flang/runtime/time-intrinsic.cpp - llvm-project - Git at Google

 //===-- runtime/time-intrinsic.cpp ----------------------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 // Implements time-related intrinsic subroutines.

 #include "flang/Runtime/time-intrinsic.h"
 #include "terminator.h"
 #include "tools.h"
 #include "flang/Runtime/cpp-type.h"
 #include "flang/Runtime/descriptor.h"
 #include <algorithm>
 #include <cstdint>
 #include <cstdio>
 #include <cstdlib>
 #include <cstring>
 #include <ctime>
 #ifdef _WIN32
 #include "flang/Common/windows-include.h"
 #else
 #include <sys/time.h> // gettimeofday
 #include <sys/times.h>
 #include <unistd.h>
 #endif

 // CPU_TIME (Fortran 2018 16.9.57)
 // SYSTEM_CLOCK (Fortran 2018 16.9.168)
 //
 // We can use std::clock() from the <ctime> header as a fallback implementation
 // that should be available everywhere. This may not provide the best resolution
 // and is particularly troublesome on (some?) POSIX systems where CLOCKS_PER_SEC
 // is defined as 10^6 regardless of the actual precision of std::clock().
 // Therefore, we will usually prefer platform-specific alternatives when they
 // are available.
 //
 // We can use SFINAE to choose a platform-specific alternative. To do so, we
 // introduce a helper function template, whose overload set will contain only
 // implementations relying on interfaces which are actually available. Each
 // overload will have a dummy parameter whose type indicates whether or not it
 // should be preferred. Any other parameters required for SFINAE should have
 // default values provided.
 namespace {
 // Types for the dummy parameter indicating the priority of a given overload.
 // We will invoke our helper with an integer literal argument, so the overload
 // with the highest priority should have the type int.
 using fallback_implementation = double;
 using preferred_implementation = int;

 // This is the fallback implementation, which should work everywhere.
 template <typename Unused = void> double GetCpuTime(fallback_implementation) {
   std::clock_t timestamp{std::clock()};
   if (timestamp != static_cast<std::clock_t>(-1)) {
     return static_cast<double>(timestamp) / CLOCKS_PER_SEC;
   }
   // Return some negative value to represent failure.
   return -1.0;
 }

 #if defined __MINGW32__
 // clock_gettime is implemented in the pthread library for MinGW.
 // Using it here would mean that all programs that link libFortranRuntime are
 // required to also link to pthread. Instead, don't use the function.
 #undef CLOCKID_CPU_TIME
 #undef CLOCKID_ELAPSED_TIME
 #else
 // Determine what clock to use for CPU time.
 #if defined CLOCK_PROCESS_CPUTIME_ID
 #define CLOCKID_CPU_TIME CLOCK_PROCESS_CPUTIME_ID
 #elif defined CLOCK_THREAD_CPUTIME_ID
 #define CLOCKID_CPU_TIME CLOCK_THREAD_CPUTIME_ID
 #else
 #undef CLOCKID_CPU_TIME
 #endif

 // Determine what clock to use for elapsed time.
 #if defined CLOCK_MONOTONIC
 #define CLOCKID_ELAPSED_TIME CLOCK_MONOTONIC
 #elif defined CLOCK_REALTIME
 #define CLOCKID_ELAPSED_TIME CLOCK_REALTIME
 #else
 #undef CLOCKID_ELAPSED_TIME
 #endif
 #endif

 #ifdef CLOCKID_CPU_TIME
 // POSIX implementation using clock_gettime. This is only enabled where
 // clock_gettime is available.
 template <typename T = int, typename U = struct timespec>
 double GetCpuTime(preferred_implementation,
     // We need some dummy parameters to pass to decltype(clock_gettime).
     T ClockId = 0, U *Timespec = nullptr,
     decltype(clock_gettime(ClockId, Timespec)) *Enabled = nullptr) {
   struct timespec tspec;
   if (clock_gettime(CLOCKID_CPU_TIME, &tspec) == 0) {
     return tspec.tv_nsec * 1.0e-9 + tspec.tv_sec;
   }
   // Return some negative value to represent failure.
   return -1.0;
 }
 #endif // CLOCKID_CPU_TIME

 using count_t = std::int64_t;
 using unsigned_count_t = std::uint64_t;

 // POSIX implementation using clock_gettime where available.  The clock_gettime
 // result is in nanoseconds, which is converted as necessary to
 //  - deciseconds for kind 1
 //  - milliseconds for kinds 2, 4
 //  - nanoseconds for kinds 8, 16
 constexpr unsigned_count_t DS_PER_SEC{10u};
 constexpr unsigned_count_t MS_PER_SEC{1'000u};
 constexpr unsigned_count_t NS_PER_SEC{1'000'000'000u};

 // Computes HUGE(INT(0,kind)) as an unsigned integer value.
 static constexpr inline unsigned_count_t GetHUGE(int kind) {
   if (kind > 8) {
     kind = 8;
   }
   return (unsigned_count_t{1} << ((8 * kind) - 1)) - 1;
 }

 // Function converts a std::timespec_t into the desired count to
 // be returned by the timing functions in accordance with the requested
 // kind at the call site.
 count_t ConvertTimeSpecToCount(int kind, const struct timespec &tspec) {
   const unsigned_count_t huge{GetHUGE(kind)};
   unsigned_count_t sec{static_cast<unsigned_count_t>(tspec.tv_sec)};
   unsigned_count_t nsec{static_cast<unsigned_count_t>(tspec.tv_nsec)};
   if (kind >= 8) {
     return (sec * NS_PER_SEC + nsec) % (huge + 1);
   } else if (kind >= 2) {
     return (sec * MS_PER_SEC + (nsec / (NS_PER_SEC / MS_PER_SEC))) % (huge + 1);
   } else { // kind == 1
     return (sec * DS_PER_SEC + (nsec / (NS_PER_SEC / DS_PER_SEC))) % (huge + 1);
   }
 }

 #ifndef _AIX
 // This is the fallback implementation, which should work everywhere.
 template <typename Unused = void>
 count_t GetSystemClockCount(int kind, fallback_implementation) {
   struct timespec tspec;

   if (timespec_get(&tspec, TIME_UTC) < 0) {
     // Return -HUGE(COUNT) to represent failure.
     return -static_cast<count_t>(GetHUGE(kind));
   }

   // Compute the timestamp as seconds plus nanoseconds in accordance
   // with the requested kind at the call site.
   return ConvertTimeSpecToCount(kind, tspec);
 }
 #endif

 template <typename Unused = void>
 count_t GetSystemClockCountRate(int kind, fallback_implementation) {
   return kind >= 8 ? NS_PER_SEC : kind >= 2 ? MS_PER_SEC : DS_PER_SEC;
 }

 template <typename Unused = void>
 count_t GetSystemClockCountMax(int kind, fallback_implementation) {
   unsigned_count_t maxCount{GetHUGE(kind)};
   return maxCount;
 }

 #ifdef CLOCKID_ELAPSED_TIME
 template <typename T = int, typename U = struct timespec>
 count_t GetSystemClockCount(int kind, preferred_implementation,
     // We need some dummy parameters to pass to decltype(clock_gettime).
     T ClockId = 0, U *Timespec = nullptr,
     decltype(clock_gettime(ClockId, Timespec)) *Enabled = nullptr) {
   struct timespec tspec;
   const unsigned_count_t huge{GetHUGE(kind)};
   if (clock_gettime(CLOCKID_ELAPSED_TIME, &tspec) != 0) {
     return -huge; // failure
   }

   // Compute the timestamp as seconds plus nanoseconds in accordance
   // with the requested kind at the call site.
   return ConvertTimeSpecToCount(kind, tspec);
 }
 #endif // CLOCKID_ELAPSED_TIME

 template <typename T = int, typename U = struct timespec>
 count_t GetSystemClockCountRate(int kind, preferred_implementation,
     // We need some dummy parameters to pass to decltype(clock_gettime).
     T ClockId = 0, U *Timespec = nullptr,
     decltype(clock_gettime(ClockId, Timespec)) *Enabled = nullptr) {
   return kind >= 8 ? NS_PER_SEC : kind >= 2 ? MS_PER_SEC : DS_PER_SEC;
 }

 template <typename T = int, typename U = struct timespec>
 count_t GetSystemClockCountMax(int kind, preferred_implementation,
     // We need some dummy parameters to pass to decltype(clock_gettime).
     T ClockId = 0, U *Timespec = nullptr,
     decltype(clock_gettime(ClockId, Timespec)) *Enabled = nullptr) {
   return GetHUGE(kind);
 }

 // DATE_AND_TIME (Fortran 2018 16.9.59)

 // Helper to set an integer value to -HUGE
 template <int KIND> struct StoreNegativeHugeAt {
   void operator()(
       const Fortran::runtime::Descriptor &result, std::size_t at) const {
     *result.ZeroBasedIndexedElement<Fortran::runtime::CppTypeFor<
         Fortran::common::TypeCategory::Integer, KIND>>(at) =
         -std::numeric_limits<Fortran::runtime::CppTypeFor<
             Fortran::common::TypeCategory::Integer, KIND>>::max();
   }
 };

 // Default implementation when date and time information is not available (set
 // strings to blanks and values to -HUGE as defined by the standard).
 static void DateAndTimeUnavailable(Fortran::runtime::Terminator &terminator,
     char *date, std::size_t dateChars, char *time, std::size_t timeChars,
     char *zone, std::size_t zoneChars,
     const Fortran::runtime::Descriptor *values) {
   if (date) {
     std::memset(date, static_cast<int>(' '), dateChars);
   }
   if (time) {
     std::memset(time, static_cast<int>(' '), timeChars);
   }
   if (zone) {
     std::memset(zone, static_cast<int>(' '), zoneChars);
   }
   if (values) {
     auto typeCode{values->type().GetCategoryAndKind()};
     RUNTIME_CHECK(terminator,
         values->rank() == 1 && values->GetDimension(0).Extent() >= 8 &&
             typeCode &&
             typeCode->first == Fortran::common::TypeCategory::Integer);
     // DATE_AND_TIME values argument must have decimal range > 4. Do not accept
     // KIND 1 here.
     int kind{typeCode->second};
     RUNTIME_CHECK(terminator, kind != 1);
     for (std::size_t i = 0; i < 8; ++i) {
       Fortran::runtime::ApplyIntegerKind<StoreNegativeHugeAt, void>(
           kind, terminator, *values, i);
     }
   }
 }

 #ifndef _WIN32
 #ifdef _AIX
 // Compute the time difference from GMT/UTC to get around the behavior of
 // strfname on AIX that requires setting an environment variable for numeric
 // value for ZONE.
 // The ZONE and the VALUES(4) arguments of the DATE_AND_TIME intrinsic has
 // the resolution to the minute.
 static int computeUTCDiff(const tm &localTime, bool *err) {
   tm utcTime;
   const time_t timer{mktime(const_cast<tm *>(&localTime))};
   if (timer < 0) {
     *err = true;
     return 0;
   }

   // Get the GMT/UTC time
   if (gmtime_r(&timer, &utcTime) == nullptr) {
     *err = true;
     return 0;
   }

   // Adjust for day difference
   auto dayDiff{localTime.tm_mday - utcTime.tm_mday};
   auto localHr{localTime.tm_hour};
   if (dayDiff > 0) {
     if (dayDiff == 1) {
       localHr += 24;
     } else {
       utcTime.tm_hour += 24;
     }
   } else if (dayDiff < 0) {
     if (dayDiff == -1) {
       utcTime.tm_hour += 24;
     } else {
       localHr += 24;
     }
   }
   return (localHr * 60 + localTime.tm_min) -
       (utcTime.tm_hour * 60 + utcTime.tm_min);
 }
 #endif

 static std::size_t getUTCOffsetToBuffer(
     char *buffer, const std::size_t &buffSize, tm *localTime) {
 #ifdef _AIX
   // format: +HHMM or -HHMM
   bool err{false};
   auto utcOffset{computeUTCDiff(*localTime, &err)};
   auto hour{utcOffset / 60};
   auto hrMin{hour * 100 + (utcOffset - hour * 60)};
   auto n{sprintf(buffer, "%+05d", hrMin)};
   return err ? 0 : n + 1;
 #else
   return std::strftime(buffer, buffSize, "%z", localTime);
 #endif
 }

 // SFINAE helper to return the struct tm.tm_gmtoff which is not a POSIX standard
 // field.
 template <int KIND, typename TM = struct tm>
 Fortran::runtime::CppTypeFor<Fortran::common::TypeCategory::Integer, KIND>
 GetGmtOffset(const TM &tm, preferred_implementation,
     decltype(tm.tm_gmtoff) *Enabled = nullptr) {
   // Returns the GMT offset in minutes.
   return tm.tm_gmtoff / 60;
 }
 template <int KIND, typename TM = struct tm>
 Fortran::runtime::CppTypeFor<Fortran::common::TypeCategory::Integer, KIND>
 GetGmtOffset(const TM &tm, fallback_implementation) {
   // tm.tm_gmtoff is not available, there may be platform dependent alternatives
   // (such as using timezone from <time.h> when available), but so far just
   // return -HUGE to report that this information is not available.
   const auto negHuge{-std::numeric_limits<Fortran::runtime::CppTypeFor<
       Fortran::common::TypeCategory::Integer, KIND>>::max()};
 #ifdef _AIX
   bool err{false};
   auto diff{computeUTCDiff(tm, &err)};
   if (err) {
     return negHuge;
   } else {
     return diff;
   }
 #else
   return negHuge;
 #endif
 }
 template <typename TM = struct tm> struct GmtOffsetHelper {
   template <int KIND> struct StoreGmtOffset {
     void operator()(const Fortran::runtime::Descriptor &result, std::size_t at,
         TM &tm) const {
       *result.ZeroBasedIndexedElement<Fortran::runtime::CppTypeFor<
           Fortran::common::TypeCategory::Integer, KIND>>(at) =
           GetGmtOffset<KIND>(tm, 0);
     }
   };
 };

 // Dispatch to posix implementation where gettimeofday and localtime_r are
 // available.
 static void GetDateAndTime(Fortran::runtime::Terminator &terminator, char *date,
     std::size_t dateChars, char *time, std::size_t timeChars, char *zone,
     std::size_t zoneChars, const Fortran::runtime::Descriptor *values) {

   timeval t;
   if (gettimeofday(&t, nullptr) != 0) {
     DateAndTimeUnavailable(
         terminator, date, dateChars, time, timeChars, zone, zoneChars, values);
     return;
   }
   time_t timer{t.tv_sec};
   tm localTime;
   localtime_r(&timer, &localTime);
   std::intmax_t ms{t.tv_usec / 1000};

   static constexpr std::size_t buffSize{16};
   char buffer[buffSize];
   auto copyBufferAndPad{
       [&](char *dest, std::size_t destChars, std::size_t len) {
         auto copyLen{std::min(len, destChars)};
         std::memcpy(dest, buffer, copyLen);
         for (auto i{copyLen}; i < destChars; ++i) {
           dest[i] = ' ';
         }
       }};
   if (date) {
     auto len = std::strftime(buffer, buffSize, "%Y%m%d", &localTime);
     copyBufferAndPad(date, dateChars, len);
   }
   if (time) {
     auto len{std::snprintf(buffer, buffSize, "%02d%02d%02d.%03jd",
         localTime.tm_hour, localTime.tm_min, localTime.tm_sec, ms)};
     copyBufferAndPad(time, timeChars, len);
   }
   if (zone) {
     // Note: this may leave the buffer empty on many platforms. Classic flang
     // has a much more complex way of doing this (see __io_timezone in classic
     // flang).
     auto len{getUTCOffsetToBuffer(buffer, buffSize, &localTime)};
     copyBufferAndPad(zone, zoneChars, len);
   }
   if (values) {
     auto typeCode{values->type().GetCategoryAndKind()};
     RUNTIME_CHECK(terminator,
         values->rank() == 1 && values->GetDimension(0).Extent() >= 8 &&
             typeCode &&
             typeCode->first == Fortran::common::TypeCategory::Integer);
     // DATE_AND_TIME values argument must have decimal range > 4. Do not accept
     // KIND 1 here.
     int kind{typeCode->second};
     RUNTIME_CHECK(terminator, kind != 1);
     auto storeIntegerAt = [&](std::size_t atIndex, std::int64_t value) {
       Fortran::runtime::ApplyIntegerKind<Fortran::runtime::StoreIntegerAt,
           void>(kind, terminator, *values, atIndex, value);
     };
     storeIntegerAt(0, localTime.tm_year + 1900);
     storeIntegerAt(1, localTime.tm_mon + 1);
     storeIntegerAt(2, localTime.tm_mday);
     Fortran::runtime::ApplyIntegerKind<
         GmtOffsetHelper<struct tm>::StoreGmtOffset, void>(
         kind, terminator, *values, 3, localTime);
     storeIntegerAt(4, localTime.tm_hour);
     storeIntegerAt(5, localTime.tm_min);
     storeIntegerAt(6, localTime.tm_sec);
     storeIntegerAt(7, ms);
   }
 }

 #else
 // Fallback implementation where gettimeofday or localtime_r are not both
 // available (e.g. windows).
 static void GetDateAndTime(Fortran::runtime::Terminator &terminator, char *date,
     std::size_t dateChars, char *time, std::size_t timeChars, char *zone,
     std::size_t zoneChars, const Fortran::runtime::Descriptor *values) {
   // TODO: An actual implementation for non Posix system should be added.
   // So far, implement as if the date and time is not available on those
   // platforms.
   DateAndTimeUnavailable(
       terminator, date, dateChars, time, timeChars, zone, zoneChars, values);
 }
 #endif
 } // namespace

 namespace Fortran::runtime {
 extern "C" {

 double RTNAME(CpuTime)() { return GetCpuTime(0); }

 std::int64_t RTNAME(SystemClockCount)(int kind) {
   return GetSystemClockCount(kind, 0);
 }

 std::int64_t RTNAME(SystemClockCountRate)(int kind) {
   return GetSystemClockCountRate(kind, 0);
 }

 std::int64_t RTNAME(SystemClockCountMax)(int kind) {
   return GetSystemClockCountMax(kind, 0);
 }

 void RTNAME(DateAndTime)(char *date, std::size_t dateChars, char *time,
     std::size_t timeChars, char *zone, std::size_t zoneChars,
     const char *source, int line, const Descriptor *values) {
   Fortran::runtime::Terminator terminator{source, line};
   return GetDateAndTime(
       terminator, date, dateChars, time, timeChars, zone, zoneChars, values);
 }

 void RTNAME(Etime)(const Descriptor *values, const Descriptor *time,
     const char *sourceFile, int line) {
   Fortran::runtime::Terminator terminator{sourceFile, line};

   double usrTime = -1.0, sysTime = -1.0, realTime = -1.0;

 #ifdef _WIN32
   FILETIME creationTime;
   FILETIME exitTime;
   FILETIME kernelTime;
   FILETIME userTime;

   if (GetProcessTimes(GetCurrentProcess(), &creationTime, &exitTime,
           &kernelTime, &userTime) == 0) {
     ULARGE_INTEGER userSystemTime;
     ULARGE_INTEGER kernelSystemTime;

     memcpy(&userSystemTime, &userTime, sizeof(FILETIME));
     memcpy(&kernelSystemTime, &kernelTime, sizeof(FILETIME));

     usrTime = ((double)(userSystemTime.QuadPart)) / 10000000.0;
     sysTime = ((double)(kernelSystemTime.QuadPart)) / 10000000.0;
     realTime = usrTime + sysTime;
   }
 #else
   struct tms tms;
   if (times(&tms) != (clock_t)-1) {
     usrTime = ((double)(tms.tms_utime)) / sysconf(_SC_CLK_TCK);
     sysTime = ((double)(tms.tms_stime)) / sysconf(_SC_CLK_TCK);
     realTime = usrTime + sysTime;
   }
 #endif

   if (values) {
     auto typeCode{values->type().GetCategoryAndKind()};
     // ETIME values argument must have decimal range == 2.
     RUNTIME_CHECK(terminator,
         values->rank() == 1 && typeCode &&
             typeCode->first == Fortran::common::TypeCategory::Real);
     // Only accept KIND=4 here.
     int kind{typeCode->second};
     RUNTIME_CHECK(terminator, kind == 4);
     auto extent{values->GetDimension(0).Extent()};
     if (extent >= 1) {
       ApplyFloatingPointKind<StoreFloatingPointAt, void>(
           kind, terminator, *values, /* atIndex = */ 0, usrTime);
     }
     if (extent >= 2) {
       ApplyFloatingPointKind<StoreFloatingPointAt, void>(
           kind, terminator, *values, /* atIndex = */ 1, sysTime);
     }
   }

   if (time) {
     auto typeCode{time->type().GetCategoryAndKind()};
     // ETIME time argument must have decimal range == 0.
     RUNTIME_CHECK(terminator,
         time->rank() == 0 && typeCode &&
             typeCode->first == Fortran::common::TypeCategory::Real);
     // Only accept KIND=4 here.
     int kind{typeCode->second};
     RUNTIME_CHECK(terminator, kind == 4);

     ApplyFloatingPointKind<StoreFloatingPointAt, void>(
         kind, terminator, *time, /* atIndex = */ 0, realTime);
   }
 }

 } // extern "C"
 } // namespace Fortran::runtime
	//===-- runtime/time-intrinsic.cpp ----------------------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	// Implements time-related intrinsic subroutines.

	#include "flang/Runtime/time-intrinsic.h"
	#include "terminator.h"
	#include "tools.h"
	#include "flang/Runtime/cpp-type.h"
	#include "flang/Runtime/descriptor.h"
	#include <algorithm>
	#include <cstdint>
	#include <cstdio>
	#include <cstdlib>
	#include <cstring>
	#include <ctime>
	#ifdef _WIN32
	#include "flang/Common/windows-include.h"
	#else
	#include <sys/time.h> // gettimeofday
	#include <sys/times.h>
	#include <unistd.h>
	#endif

	// CPU_TIME (Fortran 2018 16.9.57)
	// SYSTEM_CLOCK (Fortran 2018 16.9.168)
	//
	// We can use std::clock() from the <ctime> header as a fallback implementation
	// that should be available everywhere. This may not provide the best resolution
	// and is particularly troublesome on (some?) POSIX systems where CLOCKS_PER_SEC
	// is defined as 10^6 regardless of the actual precision of std::clock().
	// Therefore, we will usually prefer platform-specific alternatives when they
	// are available.
	//
	// We can use SFINAE to choose a platform-specific alternative. To do so, we
	// introduce a helper function template, whose overload set will contain only
	// implementations relying on interfaces which are actually available. Each
	// overload will have a dummy parameter whose type indicates whether or not it
	// should be preferred. Any other parameters required for SFINAE should have
	// default values provided.
	namespace {
	// Types for the dummy parameter indicating the priority of a given overload.
	// We will invoke our helper with an integer literal argument, so the overload
	// with the highest priority should have the type int.
	using fallback_implementation = double;
	using preferred_implementation = int;

	// This is the fallback implementation, which should work everywhere.
	template <typename Unused = void> double GetCpuTime(fallback_implementation) {
	std::clock_t timestamp{std::clock()};
	if (timestamp != static_cast<std::clock_t>(-1)) {
	return static_cast<double>(timestamp) / CLOCKS_PER_SEC;
	}
	// Return some negative value to represent failure.
	return -1.0;
	}

	#if defined __MINGW32__
	// clock_gettime is implemented in the pthread library for MinGW.
	// Using it here would mean that all programs that link libFortranRuntime are
	// required to also link to pthread. Instead, don't use the function.
	#undef CLOCKID_CPU_TIME
	#undef CLOCKID_ELAPSED_TIME
	#else
	// Determine what clock to use for CPU time.
	#if defined CLOCK_PROCESS_CPUTIME_ID
	#define CLOCKID_CPU_TIME CLOCK_PROCESS_CPUTIME_ID
	#elif defined CLOCK_THREAD_CPUTIME_ID
	#define CLOCKID_CPU_TIME CLOCK_THREAD_CPUTIME_ID
	#else
	#undef CLOCKID_CPU_TIME
	#endif

	// Determine what clock to use for elapsed time.
	#if defined CLOCK_MONOTONIC
	#define CLOCKID_ELAPSED_TIME CLOCK_MONOTONIC
	#elif defined CLOCK_REALTIME
	#define CLOCKID_ELAPSED_TIME CLOCK_REALTIME
	#else
	#undef CLOCKID_ELAPSED_TIME
	#endif
	#endif

	#ifdef CLOCKID_CPU_TIME
	// POSIX implementation using clock_gettime. This is only enabled where
	// clock_gettime is available.
	template <typename T = int, typename U = struct timespec>
	double GetCpuTime(preferred_implementation,
	// We need some dummy parameters to pass to decltype(clock_gettime).
	T ClockId = 0, U *Timespec = nullptr,
	decltype(clock_gettime(ClockId, Timespec)) *Enabled = nullptr) {
	struct timespec tspec;
	if (clock_gettime(CLOCKID_CPU_TIME, &tspec) == 0) {
	return tspec.tv_nsec * 1.0e-9 + tspec.tv_sec;
	}
	// Return some negative value to represent failure.
	return -1.0;
	}
	#endif // CLOCKID_CPU_TIME

	using count_t = std::int64_t;
	using unsigned_count_t = std::uint64_t;

	// POSIX implementation using clock_gettime where available. The clock_gettime
	// result is in nanoseconds, which is converted as necessary to
	// - deciseconds for kind 1
	// - milliseconds for kinds 2, 4
	// - nanoseconds for kinds 8, 16
	constexpr unsigned_count_t DS_PER_SEC{10u};
	constexpr unsigned_count_t MS_PER_SEC{1'000u};
	constexpr unsigned_count_t NS_PER_SEC{1'000'000'000u};

	// Computes HUGE(INT(0,kind)) as an unsigned integer value.
	static constexpr inline unsigned_count_t GetHUGE(int kind) {
	if (kind > 8) {
	kind = 8;
	}
	return (unsigned_count_t{1} << ((8 * kind) - 1)) - 1;
	}

	// Function converts a std::timespec_t into the desired count to
	// be returned by the timing functions in accordance with the requested
	// kind at the call site.
	count_t ConvertTimeSpecToCount(int kind, const struct timespec &tspec) {
	const unsigned_count_t huge{GetHUGE(kind)};
	unsigned_count_t sec{static_cast<unsigned_count_t>(tspec.tv_sec)};
	unsigned_count_t nsec{static_cast<unsigned_count_t>(tspec.tv_nsec)};
	if (kind >= 8) {
	return (sec * NS_PER_SEC + nsec) % (huge + 1);
	} else if (kind >= 2) {
	return (sec * MS_PER_SEC + (nsec / (NS_PER_SEC / MS_PER_SEC))) % (huge + 1);
	} else { // kind == 1
	return (sec * DS_PER_SEC + (nsec / (NS_PER_SEC / DS_PER_SEC))) % (huge + 1);
	}
	}

	#ifndef _AIX
	// This is the fallback implementation, which should work everywhere.
	template <typename Unused = void>
	count_t GetSystemClockCount(int kind, fallback_implementation) {
	struct timespec tspec;

	if (timespec_get(&tspec, TIME_UTC) < 0) {
	// Return -HUGE(COUNT) to represent failure.
	return -static_cast<count_t>(GetHUGE(kind));
	}

	// Compute the timestamp as seconds plus nanoseconds in accordance
	// with the requested kind at the call site.
	return ConvertTimeSpecToCount(kind, tspec);
	}
	#endif

	template <typename Unused = void>
	count_t GetSystemClockCountRate(int kind, fallback_implementation) {
	return kind >= 8 ? NS_PER_SEC : kind >= 2 ? MS_PER_SEC : DS_PER_SEC;
	}

	template <typename Unused = void>
	count_t GetSystemClockCountMax(int kind, fallback_implementation) {
	unsigned_count_t maxCount{GetHUGE(kind)};
	return maxCount;
	}

	#ifdef CLOCKID_ELAPSED_TIME
	template <typename T = int, typename U = struct timespec>
	count_t GetSystemClockCount(int kind, preferred_implementation,
	// We need some dummy parameters to pass to decltype(clock_gettime).
	T ClockId = 0, U *Timespec = nullptr,
	decltype(clock_gettime(ClockId, Timespec)) *Enabled = nullptr) {
	struct timespec tspec;
	const unsigned_count_t huge{GetHUGE(kind)};
	if (clock_gettime(CLOCKID_ELAPSED_TIME, &tspec) != 0) {
	return -huge; // failure
	}

	// Compute the timestamp as seconds plus nanoseconds in accordance
	// with the requested kind at the call site.
	return ConvertTimeSpecToCount(kind, tspec);
	}
	#endif // CLOCKID_ELAPSED_TIME

	template <typename T = int, typename U = struct timespec>
	count_t GetSystemClockCountRate(int kind, preferred_implementation,
	// We need some dummy parameters to pass to decltype(clock_gettime).
	T ClockId = 0, U *Timespec = nullptr,
	decltype(clock_gettime(ClockId, Timespec)) *Enabled = nullptr) {
	return kind >= 8 ? NS_PER_SEC : kind >= 2 ? MS_PER_SEC : DS_PER_SEC;
	}

	template <typename T = int, typename U = struct timespec>
	count_t GetSystemClockCountMax(int kind, preferred_implementation,
	// We need some dummy parameters to pass to decltype(clock_gettime).
	T ClockId = 0, U *Timespec = nullptr,
	decltype(clock_gettime(ClockId, Timespec)) *Enabled = nullptr) {
	return GetHUGE(kind);
	}

	// DATE_AND_TIME (Fortran 2018 16.9.59)

	// Helper to set an integer value to -HUGE
	template <int KIND> struct StoreNegativeHugeAt {
	void operator()(
	const Fortran::runtime::Descriptor &result, std::size_t at) const {
	*result.ZeroBasedIndexedElement<Fortran::runtime::CppTypeFor<
	Fortran::common::TypeCategory::Integer, KIND>>(at) =
	-std::numeric_limits<Fortran::runtime::CppTypeFor<
	Fortran::common::TypeCategory::Integer, KIND>>::max();
	}
	};

	// Default implementation when date and time information is not available (set
	// strings to blanks and values to -HUGE as defined by the standard).
	static void DateAndTimeUnavailable(Fortran::runtime::Terminator &terminator,
	char date, std::size_t dateChars, char time, std::size_t timeChars,
	char *zone, std::size_t zoneChars,
	const Fortran::runtime::Descriptor *values) {
	if (date) {
	std::memset(date, static_cast<int>(' '), dateChars);
	}
	if (time) {
	std::memset(time, static_cast<int>(' '), timeChars);
	}
	if (zone) {
	std::memset(zone, static_cast<int>(' '), zoneChars);
	}
	if (values) {
	auto typeCode{values->type().GetCategoryAndKind()};
	RUNTIME_CHECK(terminator,
	values->rank() == 1 && values->GetDimension(0).Extent() >= 8 &&
	typeCode &&
	typeCode->first == Fortran::common::TypeCategory::Integer);
	// DATE_AND_TIME values argument must have decimal range > 4. Do not accept
	// KIND 1 here.
	int kind{typeCode->second};
	RUNTIME_CHECK(terminator, kind != 1);
	for (std::size_t i = 0; i < 8; ++i) {
	Fortran::runtime::ApplyIntegerKind<StoreNegativeHugeAt, void>(
	kind, terminator, *values, i);
	}
	}
	}

	#ifndef _WIN32
	#ifdef _AIX
	// Compute the time difference from GMT/UTC to get around the behavior of
	// strfname on AIX that requires setting an environment variable for numeric
	// value for ZONE.
	// The ZONE and the VALUES(4) arguments of the DATE_AND_TIME intrinsic has
	// the resolution to the minute.
	static int computeUTCDiff(const tm &localTime, bool *err) {
	tm utcTime;
	const time_t timer{mktime(const_cast<tm *>(&localTime))};
	if (timer < 0) {
	*err = true;
	return 0;
	}

	// Get the GMT/UTC time
	if (gmtime_r(&timer, &utcTime) == nullptr) {
	*err = true;
	return 0;
	}

	// Adjust for day difference
	auto dayDiff{localTime.tm_mday - utcTime.tm_mday};
	auto localHr{localTime.tm_hour};
	if (dayDiff > 0) {
	if (dayDiff == 1) {
	localHr += 24;
	} else {
	utcTime.tm_hour += 24;
	}
	} else if (dayDiff < 0) {
	if (dayDiff == -1) {
	utcTime.tm_hour += 24;
	} else {
	localHr += 24;
	}
	}
	return (localHr * 60 + localTime.tm_min) -
	(utcTime.tm_hour * 60 + utcTime.tm_min);
	}
	#endif

	static std::size_t getUTCOffsetToBuffer(
	char buffer, const std::size_t &buffSize, tm localTime) {
	#ifdef _AIX
	// format: +HHMM or -HHMM
	bool err{false};
	auto utcOffset{computeUTCDiff(*localTime, &err)};
	auto hour{utcOffset / 60};
	auto hrMin{hour * 100 + (utcOffset - hour * 60)};
	auto n{sprintf(buffer, "%+05d", hrMin)};
	return err ? 0 : n + 1;
	#else
	return std::strftime(buffer, buffSize, "%z", localTime);
	#endif
	}

	// SFINAE helper to return the struct tm.tm_gmtoff which is not a POSIX standard
	// field.
	template <int KIND, typename TM = struct tm>
	Fortran::runtime::CppTypeFor<Fortran::common::TypeCategory::Integer, KIND>
	GetGmtOffset(const TM &tm, preferred_implementation,
	decltype(tm.tm_gmtoff) *Enabled = nullptr) {
	// Returns the GMT offset in minutes.
	return tm.tm_gmtoff / 60;
	}
	template <int KIND, typename TM = struct tm>
	Fortran::runtime::CppTypeFor<Fortran::common::TypeCategory::Integer, KIND>
	GetGmtOffset(const TM &tm, fallback_implementation) {
	// tm.tm_gmtoff is not available, there may be platform dependent alternatives
	// (such as using timezone from <time.h> when available), but so far just
	// return -HUGE to report that this information is not available.
	const auto negHuge{-std::numeric_limits<Fortran::runtime::CppTypeFor<
	Fortran::common::TypeCategory::Integer, KIND>>::max()};
	#ifdef _AIX
	bool err{false};
	auto diff{computeUTCDiff(tm, &err)};
	if (err) {
	return negHuge;
	} else {
	return diff;
	}
	#else
	return negHuge;
	#endif
	}
	template <typename TM = struct tm> struct GmtOffsetHelper {
	template <int KIND> struct StoreGmtOffset {
	void operator()(const Fortran::runtime::Descriptor &result, std::size_t at,
	TM &tm) const {
	*result.ZeroBasedIndexedElement<Fortran::runtime::CppTypeFor<
	Fortran::common::TypeCategory::Integer, KIND>>(at) =
	GetGmtOffset<KIND>(tm, 0);
	}
	};
	};

	// Dispatch to posix implementation where gettimeofday and localtime_r are
	// available.
	static void GetDateAndTime(Fortran::runtime::Terminator &terminator, char *date,
	std::size_t dateChars, char time, std::size_t timeChars, char zone,
	std::size_t zoneChars, const Fortran::runtime::Descriptor *values) {

	timeval t;
	if (gettimeofday(&t, nullptr) != 0) {
	DateAndTimeUnavailable(
	terminator, date, dateChars, time, timeChars, zone, zoneChars, values);
	return;
	}
	time_t timer{t.tv_sec};
	tm localTime;
	localtime_r(&timer, &localTime);
	std::intmax_t ms{t.tv_usec / 1000};

	static constexpr std::size_t buffSize{16};
	char buffer[buffSize];
	auto copyBufferAndPad{
	[&](char *dest, std::size_t destChars, std::size_t len) {
	auto copyLen{std::min(len, destChars)};
	std::memcpy(dest, buffer, copyLen);
	for (auto i{copyLen}; i < destChars; ++i) {
	dest[i] = ' ';
	}
	}};
	if (date) {
	auto len = std::strftime(buffer, buffSize, "%Y%m%d", &localTime);
	copyBufferAndPad(date, dateChars, len);
	}
	if (time) {
	auto len{std::snprintf(buffer, buffSize, "%02d%02d%02d.%03jd",
	localTime.tm_hour, localTime.tm_min, localTime.tm_sec, ms)};
	copyBufferAndPad(time, timeChars, len);
	}
	if (zone) {
	// Note: this may leave the buffer empty on many platforms. Classic flang
	// has a much more complex way of doing this (see __io_timezone in classic
	// flang).
	auto len{getUTCOffsetToBuffer(buffer, buffSize, &localTime)};
	copyBufferAndPad(zone, zoneChars, len);
	}
	if (values) {
	auto typeCode{values->type().GetCategoryAndKind()};
	RUNTIME_CHECK(terminator,
	values->rank() == 1 && values->GetDimension(0).Extent() >= 8 &&
	typeCode &&
	typeCode->first == Fortran::common::TypeCategory::Integer);
	// DATE_AND_TIME values argument must have decimal range > 4. Do not accept
	// KIND 1 here.
	int kind{typeCode->second};
	RUNTIME_CHECK(terminator, kind != 1);
	auto storeIntegerAt = [&](std::size_t atIndex, std::int64_t value) {
	Fortran::runtime::ApplyIntegerKind<Fortran::runtime::StoreIntegerAt,
	void>(kind, terminator, *values, atIndex, value);
	};
	storeIntegerAt(0, localTime.tm_year + 1900);
	storeIntegerAt(1, localTime.tm_mon + 1);
	storeIntegerAt(2, localTime.tm_mday);
	Fortran::runtime::ApplyIntegerKind<
	GmtOffsetHelper<struct tm>::StoreGmtOffset, void>(
	kind, terminator, *values, 3, localTime);
	storeIntegerAt(4, localTime.tm_hour);
	storeIntegerAt(5, localTime.tm_min);
	storeIntegerAt(6, localTime.tm_sec);
	storeIntegerAt(7, ms);
	}
	}

	#else
	// Fallback implementation where gettimeofday or localtime_r are not both
	// available (e.g. windows).
	static void GetDateAndTime(Fortran::runtime::Terminator &terminator, char *date,
	std::size_t dateChars, char time, std::size_t timeChars, char zone,
	std::size_t zoneChars, const Fortran::runtime::Descriptor *values) {
	// TODO: An actual implementation for non Posix system should be added.
	// So far, implement as if the date and time is not available on those
	// platforms.
	DateAndTimeUnavailable(
	terminator, date, dateChars, time, timeChars, zone, zoneChars, values);
	}
	#endif
	} // namespace

	namespace Fortran::runtime {
	extern "C" {

	double RTNAME(CpuTime)() { return GetCpuTime(0); }

	std::int64_t RTNAME(SystemClockCount)(int kind) {
	return GetSystemClockCount(kind, 0);
	}

	std::int64_t RTNAME(SystemClockCountRate)(int kind) {
	return GetSystemClockCountRate(kind, 0);
	}

	std::int64_t RTNAME(SystemClockCountMax)(int kind) {
	return GetSystemClockCountMax(kind, 0);
	}

	void RTNAME(DateAndTime)(char date, std::size_t dateChars, char time,
	std::size_t timeChars, char *zone, std::size_t zoneChars,
	const char source, int line, const Descriptor values) {
	Fortran::runtime::Terminator terminator{source, line};
	return GetDateAndTime(
	terminator, date, dateChars, time, timeChars, zone, zoneChars, values);
	}

	void RTNAME(Etime)(const Descriptor values, const Descriptor time,
	const char *sourceFile, int line) {
	Fortran::runtime::Terminator terminator{sourceFile, line};

	double usrTime = -1.0, sysTime = -1.0, realTime = -1.0;

	#ifdef _WIN32
	FILETIME creationTime;
	FILETIME exitTime;
	FILETIME kernelTime;
	FILETIME userTime;

	if (GetProcessTimes(GetCurrentProcess(), &creationTime, &exitTime,
	&kernelTime, &userTime) == 0) {
	ULARGE_INTEGER userSystemTime;
	ULARGE_INTEGER kernelSystemTime;

	memcpy(&userSystemTime, &userTime, sizeof(FILETIME));
	memcpy(&kernelSystemTime, &kernelTime, sizeof(FILETIME));

	usrTime = ((double)(userSystemTime.QuadPart)) / 10000000.0;
	sysTime = ((double)(kernelSystemTime.QuadPart)) / 10000000.0;
	realTime = usrTime + sysTime;
	}
	#else
	struct tms tms;
	if (times(&tms) != (clock_t)-1) {
	usrTime = ((double)(tms.tms_utime)) / sysconf(_SC_CLK_TCK);
	sysTime = ((double)(tms.tms_stime)) / sysconf(_SC_CLK_TCK);
	realTime = usrTime + sysTime;
	}
	#endif

	if (values) {
	auto typeCode{values->type().GetCategoryAndKind()};
	// ETIME values argument must have decimal range == 2.
	RUNTIME_CHECK(terminator,
	values->rank() == 1 && typeCode &&
	typeCode->first == Fortran::common::TypeCategory::Real);
	// Only accept KIND=4 here.
	int kind{typeCode->second};
	RUNTIME_CHECK(terminator, kind == 4);
	auto extent{values->GetDimension(0).Extent()};
	if (extent >= 1) {
	ApplyFloatingPointKind<StoreFloatingPointAt, void>(
	kind, terminator, values, / atIndex = */ 0, usrTime);
	}
	if (extent >= 2) {
	ApplyFloatingPointKind<StoreFloatingPointAt, void>(
	kind, terminator, values, / atIndex = */ 1, sysTime);
	}
	}

	if (time) {
	auto typeCode{time->type().GetCategoryAndKind()};
	// ETIME time argument must have decimal range == 0.
	RUNTIME_CHECK(terminator,
	time->rank() == 0 && typeCode &&
	typeCode->first == Fortran::common::TypeCategory::Real);
	// Only accept KIND=4 here.
	int kind{typeCode->second};
	RUNTIME_CHECK(terminator, kind == 4);

	ApplyFloatingPointKind<StoreFloatingPointAt, void>(
	kind, terminator, time, / atIndex = */ 0, realTime);
	}
	}

	} // extern "C"
	} // namespace Fortran::runtime