src/third_party/mozjs-45/js/src/vm/Time.cpp - cobalt - Git at Google

 /* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
  * vim: set ts=8 sts=4 et sw=4 tw=99:
  * This Source Code Form is subject to the terms of the Mozilla Public
  * License, v. 2.0. If a copy of the MPL was not distributed with this
  * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

 /* PR time code. */

 #include "vm/Time.h"

 #include "mozilla/DebugOnly.h"
 #include "mozilla/MathAlgorithms.h"

 #ifdef SOLARIS
 #define _REENTRANT 1
 #endif
 #include <string.h>

 #if defined(STARBOARD)
 #include "starboard/time.h"
 #endif

 // TODO: Don't include this on starboard.
 #include <time.h>

 #include "jstypes.h"
 #include "jsutil.h"

 #ifdef XP_WIN
 #include <windef.h>
 #include <winbase.h>
 #include <crtdbg.h>   /* for _CrtSetReportMode */
 #include <mmsystem.h> /* for timeBegin/EndPeriod */
 #include <stdlib.h>   /* for _set_invalid_parameter_handler */

 #include "prinit.h"

 #endif

 #ifdef XP_UNIX

 #ifdef _SVID_GETTOD   /* Defined only on Solaris, see Solaris <sys/types.h> */
 extern int gettimeofday(struct timeval* tv);
 #endif

 #include <sys/time.h>

 #endif /* XP_UNIX */

 using mozilla::DebugOnly;

 #if defined(STARBOARD)

 int64_t
 PRMJ_Now(void)
 {
     // SbTime is in microseconds since the Starboard/Windows epoch, and PRMJ_Now
     // should return microseconds since the Posix epoch.
     return SbTimeToPosix(SbTimeGetNow());
 }

 #elif defined(XP_UNIX)
 int64_t
 PRMJ_Now()
 {
     struct timeval tv;

 #ifdef _SVID_GETTOD   /* Defined only on Solaris, see Solaris <sys/types.h> */
     gettimeofday(&tv);
 #else
     gettimeofday(&tv, 0);
 #endif /* _SVID_GETTOD */

     return int64_t(tv.tv_sec) * PRMJ_USEC_PER_SEC + int64_t(tv.tv_usec);
 }

 #else

 // Returns the number of microseconds since the Unix epoch.
 static double
 FileTimeToUnixMicroseconds(const FILETIME& ft)
 {
     // Get the time in 100ns intervals.
     int64_t t = (int64_t(ft.dwHighDateTime) << 32) | int64_t(ft.dwLowDateTime);

     // The Windows epoch is around 1600. The Unix epoch is around 1970.
     // Subtract the difference.
     static const int64_t TimeToEpochIn100ns = 0x19DB1DED53E8000;
     t -= TimeToEpochIn100ns;

     // Divide by 10 to convert to microseconds.
     return double(t) * 0.1;
 }

 struct CalibrationData {
     double freq;         /* The performance counter frequency */
     double offset;       /* The low res 'epoch' */
     double timer_offset; /* The high res 'epoch' */

     bool calibrated;

     CRITICAL_SECTION data_lock;
 };

 static CalibrationData calibration = { 0 };

 static void
 NowCalibrate()
 {
     MOZ_ASSERT(calibration.freq > 0);

     // By wrapping a timeBegin/EndPeriod pair of calls around this loop,
     // the loop seems to take much less time (1 ms vs 15ms) on Vista.
     timeBeginPeriod(1);
     FILETIME ft, ftStart;
     GetSystemTimeAsFileTime(&ftStart);
     do {
         GetSystemTimeAsFileTime(&ft);
     } while (memcmp(&ftStart, &ft, sizeof(ft)) == 0);
     timeEndPeriod(1);

     LARGE_INTEGER now;
     QueryPerformanceCounter(&now);

     calibration.offset = FileTimeToUnixMicroseconds(ft);
     calibration.timer_offset = double(now.QuadPart);
     calibration.calibrated = true;
 }

 static const unsigned DataLockSpinCount = 4096;

 static void (WINAPI* pGetSystemTimePreciseAsFileTime)(LPFILETIME) = nullptr;

 void
 PRMJ_NowInit()
 {
     memset(&calibration, 0, sizeof(calibration));

     // According to the documentation, QueryPerformanceFrequency will never
     // return false or return a non-zero frequency on systems that run
     // Windows XP or later. Also, the frequency is fixed so we only have to
     // query it once.
     LARGE_INTEGER liFreq;
     DebugOnly<BOOL> res = QueryPerformanceFrequency(&liFreq);
     MOZ_ASSERT(res);
     calibration.freq = double(liFreq.QuadPart);
     MOZ_ASSERT(calibration.freq > 0.0);

     InitializeCriticalSectionAndSpinCount(&calibration.data_lock, DataLockSpinCount);

     // Windows 8 has a new API function we can use.
     if (HMODULE h = GetModuleHandle("kernel32.dll")) {
         pGetSystemTimePreciseAsFileTime =
             (void (WINAPI*)(LPFILETIME))GetProcAddress(h, "GetSystemTimePreciseAsFileTime");
     }
 }

 void
 PRMJ_NowShutdown()
 {
     DeleteCriticalSection(&calibration.data_lock);
 }

 #define MUTEX_LOCK(m) EnterCriticalSection(m)
 #define MUTEX_UNLOCK(m) LeaveCriticalSection(m)
 #define MUTEX_SETSPINCOUNT(m, c) SetCriticalSectionSpinCount((m),(c))

 // Please see bug 363258 for why the win32 timing code is so complex.
 int64_t
 PRMJ_Now()
 {
     if (pGetSystemTimePreciseAsFileTime) {
         // Windows 8 has a new API function that does all the work.
         FILETIME ft;
         pGetSystemTimePreciseAsFileTime(&ft);
         return int64_t(FileTimeToUnixMicroseconds(ft));
     }

     bool calibrated = false;
     bool needsCalibration = !calibration.calibrated;
     double cachedOffset = 0.0;
     while (true) {
         if (needsCalibration) {
             MUTEX_LOCK(&calibration.data_lock);

             // Recalibrate only if no one else did before us.
             if (calibration.offset == cachedOffset) {
                 // Since calibration can take a while, make any other
                 // threads immediately wait.
                 MUTEX_SETSPINCOUNT(&calibration.data_lock, 0);

                 NowCalibrate();

                 calibrated = true;

                 // Restore spin count.
                 MUTEX_SETSPINCOUNT(&calibration.data_lock, DataLockSpinCount);
             }

             MUTEX_UNLOCK(&calibration.data_lock);
         }

         // Calculate a low resolution time.
         FILETIME ft;
         GetSystemTimeAsFileTime(&ft);
         double lowresTime = FileTimeToUnixMicroseconds(ft);

         // Grab high resolution time.
         LARGE_INTEGER now;
         QueryPerformanceCounter(&now);
         double highresTimerValue = double(now.QuadPart);

         MUTEX_LOCK(&calibration.data_lock);
         double highresTime = calibration.offset +
             PRMJ_USEC_PER_SEC * (highresTimerValue - calibration.timer_offset) / calibration.freq;
         cachedOffset = calibration.offset;
         MUTEX_UNLOCK(&calibration.data_lock);

         // Assume the NT kernel ticks every 15.6 ms. Unfortunately there's no
         // good way to determine this (NtQueryTimerResolution is an undocumented
         // API), but 15.6 ms seems to be the max possible value. Hardcoding 15.6
         // means we'll recalibrate if the highres and lowres timers diverge by
         // more than 30 ms.
         static const double KernelTickInMicroseconds = 15625.25;

         // Check for clock skew.
         double diff = lowresTime - highresTime;

         // For some reason that I have not determined, the skew can be
         // up to twice a kernel tick. This does not seem to happen by
         // itself, but I have only seen it triggered by another program
         // doing some kind of file I/O. The symptoms are a negative diff
         // followed by an equally large positive diff.
         if (mozilla::Abs(diff) <= 2 * KernelTickInMicroseconds) {
             // No detectable clock skew.
             return int64_t(highresTime);
         }

         if (calibrated) {
             // If we already calibrated once this instance, and the
             // clock is still skewed, then either the processor(s) are
             // wildly changing clockspeed or the system is so busy that
             // we get switched out for long periods of time. In either
             // case, it would be infeasible to make use of high
             // resolution results for anything, so let's resort to old
             // behavior for this call. It's possible that in the
             // future, the user will want the high resolution timer, so
             // we don't disable it entirely.
             return int64_t(lowresTime);
         }

         // It is possible that when we recalibrate, we will return a
         // value less than what we have returned before; this is
         // unavoidable. We cannot tell the different between a
         // faulty QueryPerformanceCounter implementation and user
         // changes to the operating system time. Since we must
         // respect user changes to the operating system time, we
         // cannot maintain the invariant that Date.now() never
         // decreases; the old implementation has this behavior as
         // well.
         needsCalibration = true;
     }
 }
 #endif

 #ifdef XP_WIN
 static void
 PRMJ_InvalidParameterHandler(const wchar_t* expression,
                              const wchar_t* function,
                              const wchar_t* file,
                              unsigned int   line,
                              uintptr_t      pReserved)
 {
     /* empty */
 }
 #endif

 /* Format a time value into a buffer. Same semantics as strftime() */
 size_t
 PRMJ_FormatTime(char* buf, int buflen, const char* fmt, PRMJTime* prtm)
 {
     size_t result = 0;
     // Use this for Starboard until Internationalization API is enabled.
 #if defined(XP_UNIX) || defined(XP_WIN) || defined(STARBOARD)
     struct tm a;
     int fake_tm_year = 0;
 #ifdef XP_WIN
     _invalid_parameter_handler oldHandler;
     int oldReportMode;
 #endif

     memset(&a, 0, sizeof(struct tm));

     a.tm_sec = prtm->tm_sec;
     a.tm_min = prtm->tm_min;
     a.tm_hour = prtm->tm_hour;
     a.tm_mday = prtm->tm_mday;
     a.tm_mon = prtm->tm_mon;
     a.tm_wday = prtm->tm_wday;

     /*
      * On systems where |struct tm| has members tm_gmtoff and tm_zone, we
      * must fill in those values, or else strftime will return wrong results
      * (e.g., bug 511726, bug 554338).
      */
 #if defined(HAVE_LOCALTIME_R) && defined(HAVE_TM_ZONE_TM_GMTOFF)
     {
         /*
          * Fill out |td| to the time represented by |prtm|, leaving the
          * timezone fields zeroed out. localtime_r will then fill in the
          * timezone fields for that local time according to the system's
          * timezone parameters.
          */
         struct tm td;
         memset(&td, 0, sizeof(td));
         td.tm_sec = prtm->tm_sec;
         td.tm_min = prtm->tm_min;
         td.tm_hour = prtm->tm_hour;
         td.tm_mday = prtm->tm_mday;
         td.tm_mon = prtm->tm_mon;
         td.tm_wday = prtm->tm_wday;
         td.tm_year = prtm->tm_year - 1900;
         td.tm_yday = prtm->tm_yday;
         td.tm_isdst = prtm->tm_isdst;
         time_t t = mktime(&td);
         localtime_r(&t, &td);

         a.tm_gmtoff = td.tm_gmtoff;
         a.tm_zone = td.tm_zone;
     }
 #endif

     /*
      * Years before 1900 and after 9999 cause strftime() to abort on Windows.
      * To avoid that we replace it with FAKE_YEAR_BASE + year % 100 and then
      * replace matching substrings in the strftime() result with the real year.
      * Note that FAKE_YEAR_BASE should be a multiple of 100 to make 2-digit
      * year formats (%y) work correctly (since we won't find the fake year
      * in that case).
      * e.g. new Date(1873, 0).toLocaleFormat('%Y %y') => "1873 73"
      * See bug 327869.
      */
 #define FAKE_YEAR_BASE 9900
     if (prtm->tm_year < 1900 || prtm->tm_year > 9999) {
         fake_tm_year = FAKE_YEAR_BASE + prtm->tm_year % 100;
         a.tm_year = fake_tm_year - 1900;
     }
     else {
         a.tm_year = prtm->tm_year - 1900;
     }
     a.tm_yday = prtm->tm_yday;
     a.tm_isdst = prtm->tm_isdst;

     /*
      * Even with the above, SunOS 4 seems to detonate if tm_zone and tm_gmtoff
      * are null.  This doesn't quite work, though - the timezone is off by
      * tzoff + dst.  (And mktime seems to return -1 for the exact dst
      * changeover time.)
      */

 #ifdef XP_WIN
     oldHandler = _set_invalid_parameter_handler(PRMJ_InvalidParameterHandler);
     oldReportMode = _CrtSetReportMode(_CRT_ASSERT, 0);
 #endif

     result = strftime(buf, buflen, fmt, &a);

 #ifdef XP_WIN
     _set_invalid_parameter_handler(oldHandler);
     _CrtSetReportMode(_CRT_ASSERT, oldReportMode);
 #endif

     if (fake_tm_year && result) {
         char real_year[16];
         char fake_year[16];
         size_t real_year_len;
         size_t fake_year_len;
         char* p;

         sprintf(real_year, "%d", prtm->tm_year);
         real_year_len = strlen(real_year);
         sprintf(fake_year, "%d", fake_tm_year);
         fake_year_len = strlen(fake_year);

         /* Replace the fake year in the result with the real year. */
         for (p = buf; (p = strstr(p, fake_year)); p += real_year_len) {
             size_t new_result = result + real_year_len - fake_year_len;
             if ((int)new_result >= buflen) {
                 return 0;
             }
             memmove(p + real_year_len, p + fake_year_len, strlen(p + fake_year_len));
             memcpy(p, real_year, real_year_len);
             result = new_result;
             *(buf + result) = '\0';
         }
     }
 #endif
     return result;
 }
	/* -- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 --
	* vim: set ts=8 sts=4 et sw=4 tw=99:
	* This Source Code Form is subject to the terms of the Mozilla Public
	* License, v. 2.0. If a copy of the MPL was not distributed with this
	* file, You can obtain one at http://mozilla.org/MPL/2.0/. */

	/* PR time code. */

	#include "vm/Time.h"

	#include "mozilla/DebugOnly.h"
	#include "mozilla/MathAlgorithms.h"

	#ifdef SOLARIS
	#define _REENTRANT 1
	#endif
	#include <string.h>

	#if defined(STARBOARD)
	#include "starboard/time.h"
	#endif

	// TODO: Don't include this on starboard.
	#include <time.h>

	#include "jstypes.h"
	#include "jsutil.h"

	#ifdef XP_WIN
	#include <windef.h>
	#include <winbase.h>
	#include <crtdbg.h> /* for _CrtSetReportMode */
	#include <mmsystem.h> /* for timeBegin/EndPeriod */
	#include <stdlib.h> /* for _set_invalid_parameter_handler */

	#include "prinit.h"

	#endif

	#ifdef XP_UNIX

	#ifdef _SVID_GETTOD /* Defined only on Solaris, see Solaris <sys/types.h> */
	extern int gettimeofday(struct timeval* tv);
	#endif

	#include <sys/time.h>

	#endif /* XP_UNIX */

	using mozilla::DebugOnly;

	#if defined(STARBOARD)

	int64_t
	PRMJ_Now(void)
	{
	// SbTime is in microseconds since the Starboard/Windows epoch, and PRMJ_Now
	// should return microseconds since the Posix epoch.
	return SbTimeToPosix(SbTimeGetNow());
	}

	#elif defined(XP_UNIX)
	int64_t
	PRMJ_Now()
	{
	struct timeval tv;

	#ifdef _SVID_GETTOD /* Defined only on Solaris, see Solaris <sys/types.h> */
	gettimeofday(&tv);
	#else
	gettimeofday(&tv, 0);
	#endif /* _SVID_GETTOD */

	return int64_t(tv.tv_sec) * PRMJ_USEC_PER_SEC + int64_t(tv.tv_usec);
	}

	#else

	// Returns the number of microseconds since the Unix epoch.
	static double
	FileTimeToUnixMicroseconds(const FILETIME& ft)
	{
	// Get the time in 100ns intervals.
	int64_t t = (int64_t(ft.dwHighDateTime) << 32) \| int64_t(ft.dwLowDateTime);

	// The Windows epoch is around 1600. The Unix epoch is around 1970.
	// Subtract the difference.
	static const int64_t TimeToEpochIn100ns = 0x19DB1DED53E8000;
	t -= TimeToEpochIn100ns;

	// Divide by 10 to convert to microseconds.
	return double(t) * 0.1;
	}

	struct CalibrationData {
	double freq; /* The performance counter frequency */
	double offset; /* The low res 'epoch' */
	double timer_offset; /* The high res 'epoch' */

	bool calibrated;

	CRITICAL_SECTION data_lock;
	};

	static CalibrationData calibration = { 0 };

	static void
	NowCalibrate()
	{
	MOZ_ASSERT(calibration.freq > 0);

	// By wrapping a timeBegin/EndPeriod pair of calls around this loop,
	// the loop seems to take much less time (1 ms vs 15ms) on Vista.
	timeBeginPeriod(1);
	FILETIME ft, ftStart;
	GetSystemTimeAsFileTime(&ftStart);
	do {
	GetSystemTimeAsFileTime(&ft);
	} while (memcmp(&ftStart, &ft, sizeof(ft)) == 0);
	timeEndPeriod(1);

	LARGE_INTEGER now;
	QueryPerformanceCounter(&now);

	calibration.offset = FileTimeToUnixMicroseconds(ft);
	calibration.timer_offset = double(now.QuadPart);
	calibration.calibrated = true;
	}

	static const unsigned DataLockSpinCount = 4096;

	static void (WINAPI* pGetSystemTimePreciseAsFileTime)(LPFILETIME) = nullptr;

	void
	PRMJ_NowInit()
	{
	memset(&calibration, 0, sizeof(calibration));

	// According to the documentation, QueryPerformanceFrequency will never
	// return false or return a non-zero frequency on systems that run
	// Windows XP or later. Also, the frequency is fixed so we only have to
	// query it once.
	LARGE_INTEGER liFreq;
	DebugOnly<BOOL> res = QueryPerformanceFrequency(&liFreq);
	MOZ_ASSERT(res);
	calibration.freq = double(liFreq.QuadPart);
	MOZ_ASSERT(calibration.freq > 0.0);

	InitializeCriticalSectionAndSpinCount(&calibration.data_lock, DataLockSpinCount);

	// Windows 8 has a new API function we can use.
	if (HMODULE h = GetModuleHandle("kernel32.dll")) {
	pGetSystemTimePreciseAsFileTime =
	(void (WINAPI*)(LPFILETIME))GetProcAddress(h, "GetSystemTimePreciseAsFileTime");
	}
	}

	void
	PRMJ_NowShutdown()
	{
	DeleteCriticalSection(&calibration.data_lock);
	}

	#define MUTEX_LOCK(m) EnterCriticalSection(m)
	#define MUTEX_UNLOCK(m) LeaveCriticalSection(m)
	#define MUTEX_SETSPINCOUNT(m, c) SetCriticalSectionSpinCount((m),(c))

	// Please see bug 363258 for why the win32 timing code is so complex.
	int64_t
	PRMJ_Now()
	{
	if (pGetSystemTimePreciseAsFileTime) {
	// Windows 8 has a new API function that does all the work.
	FILETIME ft;
	pGetSystemTimePreciseAsFileTime(&ft);
	return int64_t(FileTimeToUnixMicroseconds(ft));
	}

	bool calibrated = false;
	bool needsCalibration = !calibration.calibrated;
	double cachedOffset = 0.0;
	while (true) {
	if (needsCalibration) {
	MUTEX_LOCK(&calibration.data_lock);

	// Recalibrate only if no one else did before us.
	if (calibration.offset == cachedOffset) {
	// Since calibration can take a while, make any other
	// threads immediately wait.
	MUTEX_SETSPINCOUNT(&calibration.data_lock, 0);

	NowCalibrate();

	calibrated = true;

	// Restore spin count.
	MUTEX_SETSPINCOUNT(&calibration.data_lock, DataLockSpinCount);
	}

	MUTEX_UNLOCK(&calibration.data_lock);
	}

	// Calculate a low resolution time.
	FILETIME ft;
	GetSystemTimeAsFileTime(&ft);
	double lowresTime = FileTimeToUnixMicroseconds(ft);

	// Grab high resolution time.
	LARGE_INTEGER now;
	QueryPerformanceCounter(&now);
	double highresTimerValue = double(now.QuadPart);

	MUTEX_LOCK(&calibration.data_lock);
	double highresTime = calibration.offset +
	PRMJ_USEC_PER_SEC * (highresTimerValue - calibration.timer_offset) / calibration.freq;
	cachedOffset = calibration.offset;
	MUTEX_UNLOCK(&calibration.data_lock);

	// Assume the NT kernel ticks every 15.6 ms. Unfortunately there's no
	// good way to determine this (NtQueryTimerResolution is an undocumented
	// API), but 15.6 ms seems to be the max possible value. Hardcoding 15.6
	// means we'll recalibrate if the highres and lowres timers diverge by
	// more than 30 ms.
	static const double KernelTickInMicroseconds = 15625.25;

	// Check for clock skew.
	double diff = lowresTime - highresTime;

	// For some reason that I have not determined, the skew can be
	// up to twice a kernel tick. This does not seem to happen by
	// itself, but I have only seen it triggered by another program
	// doing some kind of file I/O. The symptoms are a negative diff
	// followed by an equally large positive diff.
	if (mozilla::Abs(diff) <= 2 * KernelTickInMicroseconds) {
	// No detectable clock skew.
	return int64_t(highresTime);
	}

	if (calibrated) {
	// If we already calibrated once this instance, and the
	// clock is still skewed, then either the processor(s) are
	// wildly changing clockspeed or the system is so busy that
	// we get switched out for long periods of time. In either
	// case, it would be infeasible to make use of high
	// resolution results for anything, so let's resort to old
	// behavior for this call. It's possible that in the
	// future, the user will want the high resolution timer, so
	// we don't disable it entirely.
	return int64_t(lowresTime);
	}

	// It is possible that when we recalibrate, we will return a
	// value less than what we have returned before; this is
	// unavoidable. We cannot tell the different between a
	// faulty QueryPerformanceCounter implementation and user
	// changes to the operating system time. Since we must
	// respect user changes to the operating system time, we
	// cannot maintain the invariant that Date.now() never
	// decreases; the old implementation has this behavior as
	// well.
	needsCalibration = true;
	}
	}
	#endif

	#ifdef XP_WIN
	static void
	PRMJ_InvalidParameterHandler(const wchar_t* expression,
	const wchar_t* function,
	const wchar_t* file,
	unsigned int line,
	uintptr_t pReserved)
	{
	/* empty */
	}
	#endif

	/* Format a time value into a buffer. Same semantics as strftime() */
	size_t
	PRMJ_FormatTime(char* buf, int buflen, const char* fmt, PRMJTime* prtm)
	{
	size_t result = 0;
	// Use this for Starboard until Internationalization API is enabled.
	#if defined(XP_UNIX) \|\| defined(XP_WIN) \|\| defined(STARBOARD)
	struct tm a;
	int fake_tm_year = 0;
	#ifdef XP_WIN
	_invalid_parameter_handler oldHandler;
	int oldReportMode;
	#endif

	memset(&a, 0, sizeof(struct tm));

	a.tm_sec = prtm->tm_sec;
	a.tm_min = prtm->tm_min;
	a.tm_hour = prtm->tm_hour;
	a.tm_mday = prtm->tm_mday;
	a.tm_mon = prtm->tm_mon;
	a.tm_wday = prtm->tm_wday;

	/*
	* On systems where \|struct tm\| has members tm_gmtoff and tm_zone, we
	* must fill in those values, or else strftime will return wrong results
	* (e.g., bug 511726, bug 554338).
	*/
	#if defined(HAVE_LOCALTIME_R) && defined(HAVE_TM_ZONE_TM_GMTOFF)
	{
	/*
	* Fill out \|td\| to the time represented by \|prtm\|, leaving the
	* timezone fields zeroed out. localtime_r will then fill in the
	* timezone fields for that local time according to the system's
	* timezone parameters.
	*/
	struct tm td;
	memset(&td, 0, sizeof(td));
	td.tm_sec = prtm->tm_sec;
	td.tm_min = prtm->tm_min;
	td.tm_hour = prtm->tm_hour;
	td.tm_mday = prtm->tm_mday;
	td.tm_mon = prtm->tm_mon;
	td.tm_wday = prtm->tm_wday;
	td.tm_year = prtm->tm_year - 1900;
	td.tm_yday = prtm->tm_yday;
	td.tm_isdst = prtm->tm_isdst;
	time_t t = mktime(&td);
	localtime_r(&t, &td);

	a.tm_gmtoff = td.tm_gmtoff;
	a.tm_zone = td.tm_zone;
	}
	#endif

	/*
	* Years before 1900 and after 9999 cause strftime() to abort on Windows.
	* To avoid that we replace it with FAKE_YEAR_BASE + year % 100 and then
	* replace matching substrings in the strftime() result with the real year.
	* Note that FAKE_YEAR_BASE should be a multiple of 100 to make 2-digit
	* year formats (%y) work correctly (since we won't find the fake year
	* in that case).
	* e.g. new Date(1873, 0).toLocaleFormat('%Y %y') => "1873 73"
	* See bug 327869.
	*/
	#define FAKE_YEAR_BASE 9900
	if (prtm->tm_year < 1900 \|\| prtm->tm_year > 9999) {
	fake_tm_year = FAKE_YEAR_BASE + prtm->tm_year % 100;
	a.tm_year = fake_tm_year - 1900;
	}
	else {
	a.tm_year = prtm->tm_year - 1900;
	}
	a.tm_yday = prtm->tm_yday;
	a.tm_isdst = prtm->tm_isdst;

	/*
	* Even with the above, SunOS 4 seems to detonate if tm_zone and tm_gmtoff
	* are null. This doesn't quite work, though - the timezone is off by
	* tzoff + dst. (And mktime seems to return -1 for the exact dst
	* changeover time.)
	*/

	#ifdef XP_WIN
	oldHandler = _set_invalid_parameter_handler(PRMJ_InvalidParameterHandler);
	oldReportMode = _CrtSetReportMode(_CRT_ASSERT, 0);
	#endif

	result = strftime(buf, buflen, fmt, &a);

	#ifdef XP_WIN
	_set_invalid_parameter_handler(oldHandler);
	_CrtSetReportMode(_CRT_ASSERT, oldReportMode);
	#endif

	if (fake_tm_year && result) {
	char real_year[16];
	char fake_year[16];
	size_t real_year_len;
	size_t fake_year_len;
	char* p;

	sprintf(real_year, "%d", prtm->tm_year);
	real_year_len = strlen(real_year);
	sprintf(fake_year, "%d", fake_tm_year);
	fake_year_len = strlen(fake_year);

	/* Replace the fake year in the result with the real year. */
	for (p = buf; (p = strstr(p, fake_year)); p += real_year_len) {
	size_t new_result = result + real_year_len - fake_year_len;
	if ((int)new_result >= buflen) {
	return 0;
	}
	memmove(p + real_year_len, p + fake_year_len, strlen(p + fake_year_len));
	memcpy(p, real_year, real_year_len);
	result = new_result;
	*(buf + result) = '\0';
	}
	}
	#endif
	return result;
	}