/* * Copyright (C) 1999-2000 Harri Porten (porten@kde.org) * Copyright (C) 2006, 2007 Apple Inc. All rights reserved. * * The Original Code is Mozilla Communicator client code, released * March 31, 1998. * * The Initial Developer of the Original Code is * Netscape Communications Corporation. * Portions created by the Initial Developer are Copyright (C) 1998 * the Initial Developer. All Rights Reserved. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Alternatively, the contents of this file may be used under the terms * of either the Mozilla Public License Version 1.1, found at * http://www.mozilla.org/MPL/ (the "MPL") or the GNU General Public * License Version 2.0, found at http://www.fsf.org/copyleft/gpl.html * (the "GPL"), in which case the provisions of the MPL or the GPL are * applicable instead of those above. If you wish to allow use of your * version of this file only under the terms of one of those two * licenses (the MPL or the GPL) and not to allow others to use your * version of this file under the LGPL, indicate your decision by * deletingthe provisions above and replace them with the notice and * other provisions required by the MPL or the GPL, as the case may be. * If you do not delete the provisions above, a recipient may use your * version of this file under any of the LGPL, the MPL or the GPL. */ #include "config.h" #include "DateMath.h" #include #include #include #include #if PLATFORM(DARWIN) #include #endif #if HAVE(SYS_TIME_H) #include #endif #if HAVE(SYS_TIMEB_H) #include #endif namespace KJS { /* Constants */ static const double minutesPerDay = 24.0 * 60.0; static const double secondsPerDay = 24.0 * 60.0 * 60.0; static const double secondsPerYear = 24.0 * 60.0 * 60.0 * 365.0; static const double usecPerSec = 1000000.0; static const double maxUnixTime = 2145859200.0; // 12/31/2037 // Day of year for the first day of each month, where index 0 is January, and day 0 is January 1. // First for non-leap years, then for leap years. static const int firstDayOfMonth[2][12] = { {0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334}, {0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335} }; static inline bool isLeapYear(int year) { if (year % 4 != 0) return false; if (year % 400 == 0) return true; if (year % 100 == 0) return false; return true; } static inline int daysInYear(int year) { return 365 + isLeapYear(year); } static inline double daysFrom1970ToYear(int year) { return 365.0 * (year - 1970) + floor((year - 1969) / 4.0) - floor((year - 1901) / 100.0) + floor((year - 1601) / 400.0); } static inline double msFrom1970ToYear(int year) { return msPerDay * daysFrom1970ToYear(year); } static inline double msToDays(double ms) { return floor(ms / msPerDay); } static inline int msToYear(double ms) { int y = static_cast(floor(ms / (msPerDay * 365.2425)) + 1970); double t2 = msFrom1970ToYear(y); if (t2 > ms) { y--; } else { if (t2 + msPerDay * daysInYear(y) <= ms) y++; } return y; } static inline bool isInLeapYear(double ms) { return isLeapYear(msToYear(ms)); } static inline int dayInYear(double ms, int year) { return static_cast(msToDays(ms) - daysFrom1970ToYear(year)); } static inline double msToMilliseconds(double ms) { double result = fmod(ms, msPerDay); if (result < 0) result += msPerDay; return result; } // 0: Sunday, 1: Monday, etc. static inline int msToWeekDay(double ms) { int wd = (static_cast(msToDays(ms)) + 4) % 7; if (wd < 0) wd += 7; return wd; } static inline int msToSeconds(double ms) { double result = fmod(floor(ms / msPerSecond), secondsPerMinute); if (result < 0) result += secondsPerMinute; return static_cast(result); } static inline int msToMinutes(double ms) { double result = fmod(floor(ms / msPerMinute), minutesPerHour); if (result < 0) result += minutesPerHour; return static_cast(result); } static inline int msToHours(double ms) { double result = fmod(floor(ms/msPerHour), hoursPerDay); if (result < 0) result += hoursPerDay; return static_cast(result); } static inline int msToMonth(double ms) { int step; int year = msToYear(ms); int d = dayInYear(ms, year); if (d < (step = 31)) return 0; step += (isInLeapYear(ms) ? 29 : 28); if (d < step) return 1; if (d < (step += 31)) return 2; if (d < (step += 30)) return 3; if (d < (step += 31)) return 4; if (d < (step += 30)) return 5; if (d < (step += 31)) return 6; if (d < (step += 31)) return 7; if (d < (step += 30)) return 8; if (d < (step += 31)) return 9; if (d < (step += 30)) return 10; return 11; } static inline int msToDayInMonth(double ms) { int step, next; int year = msToYear(ms); int d = dayInYear(ms, year); if (d <= (next = 30)) return d + 1; step = next; next += (isInLeapYear(ms) ? 29 : 28); if (d <= next) return d - step; step = next; if (d <= (next += 31)) return d - step; step = next; if (d <= (next += 30)) return d - step; step = next; if (d <= (next += 31)) return d - step; step = next; if (d <= (next += 30)) return d - step; step = next; if (d <= (next += 31)) return d - step; step = next; if (d <= (next += 31)) return d - step; step = next; if (d <= (next += 30)) return d - step; step = next; if (d <= (next += 31)) return d - step; step = next; if (d <= (next += 30)) return d - step; step = next; return d - step; } static inline int monthToDayInYear(int month, bool isLeapYear) { return firstDayOfMonth[isLeapYear][month]; } static inline double timeToMS(double hour, double min, double sec, double ms) { return (((hour * minutesPerHour + min) * secondsPerMinute + sec) * msPerSecond + ms); } static int dateToDayInYear(int year, int month, int day) { year += month / 12; month %= 12; if (month < 0) { month += 12; --year; } int yearday = static_cast(floor(msFrom1970ToYear(year) / msPerDay)); int monthday = monthToDayInYear(month, isLeapYear(year)); return yearday + monthday + day - 1; } double getCurrentUTCTime() { #if PLATFORM(WIN_OS) #if COMPILER(BORLAND) struct timeb timebuffer; ftime(&timebuffer); #else struct _timeb timebuffer; _ftime(&timebuffer); #endif double utc = timebuffer.time * msPerSecond + timebuffer.millitm; #else struct timeval tv; gettimeofday(&tv, 0); double utc = floor(tv.tv_sec * msPerSecond + tv.tv_usec / 1000); #endif return utc; } // There is a hard limit at 2038 that we currently do not have a workaround // for (rdar://problem/5052975). static inline int maximumYearForDST() { return 2037; } // It is ok if the cached year is not the current year (e.g. Dec 31st) // so long as the rules for DST did not change between the two years, if it does // the app would need to be restarted. static int mimimumYearForDST() { // Because of the 2038 issue (see maximumYearForDST) if the current year is // greater than the max year minus 27 (2010), we want to use the max year // minus 27 instead, to ensure there is a range of 28 years that all years // can map to. static int minYear = std::min(msToYear(getCurrentUTCTime()), maximumYearForDST()-27) ; return minYear; } /* * Find an equivalent year for the one given, where equivalence is deterined by * the two years having the same leapness and the first day of the year, falling * on the same day of the week. * * This function returns a year between this current year and 2037, however this * function will potentially return incorrect results if the current year is after * 2010, (rdar://problem/5052975), if the year passed in is before 1900 or after * 2100, (rdar://problem/5055038). */ int equivalentYearForDST(int year) { static int minYear = mimimumYearForDST(); static int maxYear = maximumYearForDST(); int difference; if (year > maxYear) difference = minYear - year; else if (year < minYear) difference = maxYear - year; else return year; int quotient = difference / 28; int product = (quotient) * 28; year += product; ASSERT((year >= minYear && year <= maxYear) || (product - year == static_cast(NaN))); return year; } /* * Get the difference in milliseconds between this time zone and UTC (GMT) * NOT including DST. */ double getUTCOffset() { #if PLATFORM(DARWIN) // Register for a notification whenever the time zone changes. static bool triedToRegister = false; static bool haveNotificationToken = false; static int notificationToken; if (!triedToRegister) { triedToRegister = true; uint32_t status = notify_register_check("com.apple.system.timezone", ¬ificationToken); if (status == NOTIFY_STATUS_OK) haveNotificationToken = true; } // If we can verify that we have not received a time zone notification, // then use the cached offset from the last time this function was called. static bool haveCachedOffset = false; static double cachedOffset; if (haveNotificationToken && haveCachedOffset) { int notified; uint32_t status = notify_check(notificationToken, ¬ified); if (status == NOTIFY_STATUS_OK && !notified) return cachedOffset; } #endif tm localt; memset(&localt, 0, sizeof(localt)); // get the difference between this time zone and UTC on Jan 01, 2000 12:00:00 AM localt.tm_mday = 1; localt.tm_year = 100; double utcOffset = 946684800.0 - mktime(&localt); utcOffset *= msPerSecond; #if PLATFORM(DARWIN) haveCachedOffset = true; cachedOffset = utcOffset; #endif return utcOffset; } /* * Get the DST offset for the time passed in. Takes * seconds (not milliseconds) and cannot handle dates before 1970 * on some OS' */ static double getDSTOffsetSimple(double localTimeSeconds) { if (localTimeSeconds > maxUnixTime) localTimeSeconds = maxUnixTime; else if(localTimeSeconds < 0) // Go ahead a day to make localtime work (does not work with 0) localTimeSeconds += secondsPerDay; //input is UTC so we have to shift back to local time to determine DST thus the + getUTCOffset() double offsetTime = (localTimeSeconds * msPerSecond) + getUTCOffset(); // Offset from UTC but doesn't include DST obviously int offsetHour = msToHours(offsetTime); int offsetMinute = msToMinutes(offsetTime); // FIXME: time_t has a potential problem in 2038 time_t localTime = static_cast(localTimeSeconds); tm localTM; #if PLATFORM(QT) // ### this is not threadsafe but we don't use multiple threads anyway // in the Qt build #if USE(MULTIPLE_THREADS) #error Mulitple threads are currently not supported in the Qt/mingw build #endif localTM = *localtime(&localTime); #elif PLATFORM(WIN_OS) #if COMPILER(MSVC7) localTM = *localtime(&localTime); #else localtime_s(&localTM, &localTime); #endif #else localtime_r(&localTime, &localTM); #endif double diff = ((localTM.tm_hour - offsetHour) * secondsPerHour) + ((localTM.tm_min - offsetMinute) * 60); if(diff < 0) diff += secondsPerDay; return (diff * msPerSecond); } // Get the DST offset, given a time in UTC static double getDSTOffset(double ms) { // On Mac OS X, the call to localtime (see getDSTOffsetSimple) will return historically accurate // DST information (e.g. New Zealand did not have DST from 1946 to 1974) however the JavaScript // standard explicitly dictates that historical information should not be considered when // determining DST. For this reason we shift away from years that localtime can handle but would // return historically accurate information. int year = msToYear(ms); int equvalentYear = equivalentYearForDST(year); if (year != equvalentYear) { int day = dateToDayInYear(equvalentYear, msToMonth(ms), msToDayInMonth(ms)); ms = (day * msPerDay) + msToMilliseconds(ms); } return getDSTOffsetSimple(ms / msPerSecond); } double gregorianDateTimeToMS(const GregorianDateTime& t, double milliSeconds, bool inputIsUTC) { int day = dateToDayInYear(t.year + 1900, t.month, t.monthDay); double ms = timeToMS(t.hour, t.minute, t.second, milliSeconds); double result = (day * msPerDay) + ms; if (!inputIsUTC) { // convert to UTC result -= getUTCOffset(); result -= getDSTOffset(result); } return result; } void msToGregorianDateTime(double ms, bool outputIsUTC, GregorianDateTime& tm) { // input is UTC double dstOff = 0.0; if (!outputIsUTC) { // convert to local time dstOff = getDSTOffset(ms); ms += dstOff + getUTCOffset(); } tm.second = msToSeconds(ms); tm.minute = msToMinutes(ms); tm.hour = msToHours(ms); tm.weekDay = msToWeekDay(ms); tm.monthDay = msToDayInMonth(ms); tm.yearDay = dayInYear(ms, msToYear(ms)); tm.month = msToMonth(ms); tm.year = msToYear(ms) - 1900; tm.isDST = dstOff != 0.0; tm.utcOffset = static_cast((dstOff + getUTCOffset()) / msPerSecond); tm.timeZone = NULL; } } // namespace KJS