/* gdatetime.c * * Copyright (C) 2009-2010 Christian Hergert * Copyright (C) 2010 Thiago Santos * Copyright (C) 2010 Emmanuele Bassi * Copyright © 2010 Codethink Limited * * 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 * licence, or (at your option) any later version. * * This 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 St, Fifth Floor, Boston, MA 02110-1301 * USA. * * Authors: Christian Hergert * Thiago Santos * Emmanuele Bassi * Ryan Lortie */ /* Algorithms within this file are based on the Calendar FAQ by * Claus Tondering. It can be found at * http://www.tondering.dk/claus/cal/calendar29.txt * * Copyright and disclaimer * ------------------------ * This document is Copyright (C) 2008 by Claus Tondering. * E-mail: claus@tondering.dk. (Please include the word * "calendar" in the subject line.) * The document may be freely distributed, provided this * copyright notice is included and no money is charged for * the document. * * This document is provided "as is". No warranties are made as * to its correctness. */ /* Prologue {{{1 */ #include "config.h" #include #include #ifdef HAVE_UNISTD_H #include #endif #ifdef HAVE_LANGINFO_TIME #include #endif #include "gdatetime.h" #include "gslice.h" #include "gatomic.h" #include "gfileutils.h" #include "ghash.h" #include "gmain.h" #include "gmappedfile.h" #include "gstrfuncs.h" #include "gtestutils.h" #include "gthread.h" #include "gtimezone.h" #include "glibintl.h" #ifndef G_OS_WIN32 #include #include #endif /* !G_OS_WIN32 */ /** * SECTION:date-time * @title: GDateTime * @short_description: A structure representing Date and Time * @see_also: #GTimeZone * * #GDateTime is a structure that combines a Gregorian date and time * into a single structure. It provides many conversion and methods to * manipulate dates and times. Time precision is provided down to * microseconds and the time can range (proleptically) from 0001-01-01 * 00:00:00 to 9999-12-31 23:59:59.999999. #GDateTime follows POSIX * time in the sense that it is oblivious to leap seconds. * * #GDateTime is an immutable object; once it has been created it cannot * be modified further. All modifiers will create a new #GDateTime. * Nearly all such functions can fail due to the date or time going out * of range, in which case %NULL will be returned. * * #GDateTime is reference counted: the reference count is increased by calling * g_date_time_ref() and decreased by calling g_date_time_unref(). When the * reference count drops to 0, the resources allocated by the #GDateTime * structure are released. * * Many parts of the API may produce non-obvious results. As an * example, adding two months to January 31st will yield March 31st * whereas adding one month and then one month again will yield either * March 28th or March 29th. Also note that adding 24 hours is not * always the same as adding one day (since days containing daylight * savings time transitions are either 23 or 25 hours in length). * * #GDateTime is available since GLib 2.26. */ struct _GDateTime { /* 1 is 0001-01-01 in Proleptic Gregorian */ gint32 days; /* Microsecond timekeeping within Day */ guint64 usec; /* TimeZone information */ GTimeZone *tz; gint interval; volatile gint ref_count; }; /* Time conversion {{{1 */ #define UNIX_EPOCH_START 719163 #define INSTANT_TO_UNIX(instant) \ ((instant)/USEC_PER_SECOND - UNIX_EPOCH_START * SEC_PER_DAY) #define UNIX_TO_INSTANT(unix) \ (((unix) + UNIX_EPOCH_START * SEC_PER_DAY) * USEC_PER_SECOND) #define DAYS_IN_4YEARS 1461 /* days in 4 years */ #define DAYS_IN_100YEARS 36524 /* days in 100 years */ #define DAYS_IN_400YEARS 146097 /* days in 400 years */ #define USEC_PER_SECOND (G_GINT64_CONSTANT (1000000)) #define USEC_PER_MINUTE (G_GINT64_CONSTANT (60000000)) #define USEC_PER_HOUR (G_GINT64_CONSTANT (3600000000)) #define USEC_PER_MILLISECOND (G_GINT64_CONSTANT (1000)) #define USEC_PER_DAY (G_GINT64_CONSTANT (86400000000)) #define SEC_PER_DAY (G_GINT64_CONSTANT (86400)) #define SECS_PER_MINUTE (60) #define SECS_PER_HOUR (60 * SECS_PER_MINUTE) #define SECS_PER_DAY (24 * SECS_PER_HOUR) #define SECS_PER_YEAR (365 * SECS_PER_DAY) #define SECS_PER_JULIAN (DAYS_PER_PERIOD * SECS_PER_DAY) #define GREGORIAN_LEAP(y) ((((y) % 4) == 0) && (!((((y) % 100) == 0) && (((y) % 400) != 0)))) #define JULIAN_YEAR(d) ((d)->julian / 365.25) #define DAYS_PER_PERIOD (G_GINT64_CONSTANT (2914695)) static const guint16 days_in_months[2][13] = { { 0, 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 }, { 0, 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 } }; static const guint16 days_in_year[2][13] = { { 0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334, 365 }, { 0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335, 366 } }; #ifdef HAVE_LANGINFO_TIME #define GET_AMPM(d) ((g_date_time_get_hour (d) < 12) ? \ nl_langinfo (AM_STR) : \ nl_langinfo (PM_STR)) #define PREFERRED_DATE_TIME_FMT nl_langinfo (D_T_FMT) #define PREFERRED_DATE_FMT nl_langinfo (D_FMT) #define PREFERRED_TIME_FMT nl_langinfo (T_FMT) #define PREFERRED_TIME_FMT nl_langinfo (T_FMT) #define PREFERRED_12HR_TIME_FMT nl_langinfo (T_FMT_AMPM) static const gint weekday_item[2][7] = { { ABDAY_2, ABDAY_3, ABDAY_4, ABDAY_5, ABDAY_6, ABDAY_7, ABDAY_1 }, { DAY_2, DAY_3, DAY_4, DAY_5, DAY_6, DAY_7, DAY_1 } }; static const gint month_item[2][12] = { { ABMON_1, ABMON_2, ABMON_3, ABMON_4, ABMON_5, ABMON_6, ABMON_7, ABMON_8, ABMON_9, ABMON_10, ABMON_11, ABMON_12 }, { MON_1, MON_2, MON_3, MON_4, MON_5, MON_6, MON_7, MON_8, MON_9, MON_10, MON_11, MON_12 }, }; #define WEEKDAY_ABBR(d) nl_langinfo (weekday_item[0][g_date_time_get_day_of_week (d) - 1]) #define WEEKDAY_FULL(d) nl_langinfo (weekday_item[1][g_date_time_get_day_of_week (d) - 1]) #define MONTH_ABBR(d) nl_langinfo (month_item[0][g_date_time_get_month (d) - 1]) #define MONTH_FULL(d) nl_langinfo (month_item[1][g_date_time_get_month (d) - 1]) #else #define GET_AMPM(d) ((g_date_time_get_hour (d) < 12) \ /* Translators: 'before midday' indicator */ \ ? C_("GDateTime", "AM") \ /* Translators: 'after midday' indicator */ \ : C_("GDateTime", "PM")) /* Translators: this is the preferred format for expressing the date and the time */ #define PREFERRED_DATE_TIME_FMT C_("GDateTime", "%a %b %e %H:%M:%S %Y") /* Translators: this is the preferred format for expressing the date */ #define PREFERRED_DATE_FMT C_("GDateTime", "%m/%d/%y") /* Translators: this is the preferred format for expressing the time */ #define PREFERRED_TIME_FMT C_("GDateTime", "%H:%M:%S") /* Translators: this is the preferred format for expressing 12 hour time */ #define PREFERRED_12HR_TIME_FMT C_("GDateTime", "%I:%M:%S %p") #define WEEKDAY_ABBR(d) (get_weekday_name_abbr (g_date_time_get_day_of_week (d))) #define WEEKDAY_FULL(d) (get_weekday_name (g_date_time_get_day_of_week (d))) #define MONTH_ABBR(d) (get_month_name_abbr (g_date_time_get_month (d))) #define MONTH_FULL(d) (get_month_name (g_date_time_get_month (d))) static const gchar * get_month_name (gint month) { switch (month) { case 1: return C_("full month name", "January"); case 2: return C_("full month name", "February"); case 3: return C_("full month name", "March"); case 4: return C_("full month name", "April"); case 5: return C_("full month name", "May"); case 6: return C_("full month name", "June"); case 7: return C_("full month name", "July"); case 8: return C_("full month name", "August"); case 9: return C_("full month name", "September"); case 10: return C_("full month name", "October"); case 11: return C_("full month name", "November"); case 12: return C_("full month name", "December"); default: g_warning ("Invalid month number %d", month); } return NULL; } static const gchar * get_month_name_abbr (gint month) { switch (month) { case 1: return C_("abbreviated month name", "Jan"); case 2: return C_("abbreviated month name", "Feb"); case 3: return C_("abbreviated month name", "Mar"); case 4: return C_("abbreviated month name", "Apr"); case 5: return C_("abbreviated month name", "May"); case 6: return C_("abbreviated month name", "Jun"); case 7: return C_("abbreviated month name", "Jul"); case 8: return C_("abbreviated month name", "Aug"); case 9: return C_("abbreviated month name", "Sep"); case 10: return C_("abbreviated month name", "Oct"); case 11: return C_("abbreviated month name", "Nov"); case 12: return C_("abbreviated month name", "Dec"); default: g_warning ("Invalid month number %d", month); } return NULL; } static const gchar * get_weekday_name (gint day) { switch (day) { case 1: return C_("full weekday name", "Monday"); case 2: return C_("full weekday name", "Tuesday"); case 3: return C_("full weekday name", "Wednesday"); case 4: return C_("full weekday name", "Thursday"); case 5: return C_("full weekday name", "Friday"); case 6: return C_("full weekday name", "Saturday"); case 7: return C_("full weekday name", "Sunday"); default: g_warning ("Invalid week day number %d", day); } return NULL; } static const gchar * get_weekday_name_abbr (gint day) { switch (day) { case 1: return C_("abbreviated weekday name", "Mon"); case 2: return C_("abbreviated weekday name", "Tue"); case 3: return C_("abbreviated weekday name", "Wed"); case 4: return C_("abbreviated weekday name", "Thu"); case 5: return C_("abbreviated weekday name", "Fri"); case 6: return C_("abbreviated weekday name", "Sat"); case 7: return C_("abbreviated weekday name", "Sun"); default: g_warning ("Invalid week day number %d", day); } return NULL; } #endif /* HAVE_LANGINFO_TIME */ static inline gint ymd_to_days (gint year, gint month, gint day) { gint64 days; days = (year - 1) * 365 + ((year - 1) / 4) - ((year - 1) / 100) + ((year - 1) / 400); days += days_in_year[0][month - 1]; if (GREGORIAN_LEAP (year) && month > 2) day++; days += day; return days; } static void g_date_time_get_week_number (GDateTime *datetime, gint *week_number, gint *day_of_week, gint *day_of_year) { gint a, b, c, d, e, f, g, n, s, month, day, year; g_date_time_get_ymd (datetime, &year, &month, &day); if (month <= 2) { a = g_date_time_get_year (datetime) - 1; b = (a / 4) - (a / 100) + (a / 400); c = ((a - 1) / 4) - ((a - 1) / 100) + ((a - 1) / 400); s = b - c; e = 0; f = day - 1 + (31 * (month - 1)); } else { a = year; b = (a / 4) - (a / 100) + (a / 400); c = ((a - 1) / 4) - ((a - 1) / 100) + ((a - 1) / 400); s = b - c; e = s + 1; f = day + (((153 * (month - 3)) + 2) / 5) + 58 + s; } g = (a + b) % 7; d = (f + g - e) % 7; n = f + 3 - d; if (week_number) { if (n < 0) *week_number = 53 - ((g - s) / 5); else if (n > 364 + s) *week_number = 1; else *week_number = (n / 7) + 1; } if (day_of_week) *day_of_week = d + 1; if (day_of_year) *day_of_year = f + 1; } /* Lifecycle {{{1 */ static GDateTime * g_date_time_alloc (GTimeZone *tz) { GDateTime *datetime; datetime = g_slice_new0 (GDateTime); datetime->tz = g_time_zone_ref (tz); datetime->ref_count = 1; return datetime; } /** * g_date_time_ref: * @datetime: a #GDateTime * * Atomically increments the reference count of @datetime by one. * * Return value: the #GDateTime with the reference count increased * * Since: 2.26 */ GDateTime * g_date_time_ref (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, NULL); g_return_val_if_fail (datetime->ref_count > 0, NULL); g_atomic_int_inc (&datetime->ref_count); return datetime; } /** * g_date_time_unref: * @datetime: a #GDateTime * * Atomically decrements the reference count of @datetime by one. * * When the reference count reaches zero, the resources allocated by * @datetime are freed * * Since: 2.26 */ void g_date_time_unref (GDateTime *datetime) { g_return_if_fail (datetime != NULL); g_return_if_fail (datetime->ref_count > 0); if (g_atomic_int_dec_and_test (&datetime->ref_count)) { g_time_zone_unref (datetime->tz); g_slice_free (GDateTime, datetime); } } /* Internal state transformers {{{1 */ /*< internal > * g_date_time_to_instant: * @datetime: a #GDateTime * * Convert a @datetime into an instant. * * An instant is a number that uniquely describes a particular * microsecond in time, taking time zone considerations into account. * (ie: "03:00 -0400" is the same instant as "02:00 -0500"). * * An instant is always positive but we use a signed return value to * avoid troubles with C. */ static gint64 g_date_time_to_instant (GDateTime *datetime) { gint64 offset; offset = g_time_zone_get_offset (datetime->tz, datetime->interval); offset *= USEC_PER_SECOND; return datetime->days * USEC_PER_DAY + datetime->usec - offset; } /*< internal > * g_date_time_from_instant: * @tz: a #GTimeZone * @instant: a instant in time * * Creates a #GDateTime from a time zone and an instant. * * This might fail if the time ends up being out of range. */ static GDateTime * g_date_time_from_instant (GTimeZone *tz, gint64 instant) { GDateTime *datetime; gint64 offset; if (instant < 0 || instant > G_GINT64_CONSTANT (1000000000000000000)) return NULL; datetime = g_date_time_alloc (tz); datetime->interval = g_time_zone_find_interval (tz, G_TIME_TYPE_UNIVERSAL, INSTANT_TO_UNIX (instant)); offset = g_time_zone_get_offset (datetime->tz, datetime->interval); offset *= USEC_PER_SECOND; instant += offset; datetime->days = instant / USEC_PER_DAY; datetime->usec = instant % USEC_PER_DAY; if (datetime->days < 1 || 3652059 < datetime->days) { g_date_time_unref (datetime); datetime = NULL; } return datetime; } /*< internal > * g_date_time_deal_with_date_change: * @datetime: a #GDateTime * * This function should be called whenever the date changes by adding * days, months or years. It does three things. * * First, we ensure that the date falls between 0001-01-01 and * 9999-12-31 and return %FALSE if it does not. * * Next we update the ->interval field. * * Finally, we ensure that the resulting date and time pair exists (by * ensuring that our time zone has an interval containing it) and * adjusting as required. For example, if we have the time 02:30:00 on * March 13 2010 in Toronto and we add 1 day to it, we would end up with * 2:30am on March 14th, which doesn't exist. In that case, we bump the * time up to 3:00am. */ static gboolean g_date_time_deal_with_date_change (GDateTime *datetime) { GTimeType was_dst; gint64 full_time; gint64 usec; if (datetime->days < 1 || datetime->days > 3652059) return FALSE; was_dst = g_time_zone_is_dst (datetime->tz, datetime->interval); full_time = datetime->days * USEC_PER_DAY + datetime->usec; usec = full_time % USEC_PER_SECOND; full_time /= USEC_PER_SECOND; full_time -= UNIX_EPOCH_START * SEC_PER_DAY; datetime->interval = g_time_zone_adjust_time (datetime->tz, was_dst, &full_time); full_time += UNIX_EPOCH_START * SEC_PER_DAY; full_time *= USEC_PER_SECOND; full_time += usec; datetime->days = full_time / USEC_PER_DAY; datetime->usec = full_time % USEC_PER_DAY; /* maybe daylight time caused us to shift to a different day, * but it definitely didn't push us into a different year */ return TRUE; } static GDateTime * g_date_time_replace_days (GDateTime *datetime, gint days) { GDateTime *new; new = g_date_time_alloc (datetime->tz); new->interval = datetime->interval; new->usec = datetime->usec; new->days = days; if (!g_date_time_deal_with_date_change (new)) { g_date_time_unref (new); new = NULL; } return new; } /* now/unix/timeval Constructors {{{1 */ /*< internal > * g_date_time_new_from_timeval: * @tz: a #GTimeZone * @tv: a #GTimeVal * * Creates a #GDateTime corresponding to the given #GTimeVal @tv in the * given time zone @tz. * * The time contained in a #GTimeVal is always stored in the form of * seconds elapsed since 1970-01-01 00:00:00 UTC, regardless of the * given time zone. * * This call can fail (returning %NULL) if @tv represents a time outside * of the supported range of #GDateTime. * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ static GDateTime * g_date_time_new_from_timeval (GTimeZone *tz, const GTimeVal *tv) { return g_date_time_from_instant (tz, tv->tv_usec + UNIX_TO_INSTANT (tv->tv_sec)); } /*< internal > * g_date_time_new_from_unix: * @tz: a #GTimeZone * @t: the Unix time * * Creates a #GDateTime corresponding to the given Unix time @t in the * given time zone @tz. * * Unix time is the number of seconds that have elapsed since 1970-01-01 * 00:00:00 UTC, regardless of the time zone given. * * This call can fail (returning %NULL) if @t represents a time outside * of the supported range of #GDateTime. * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ static GDateTime * g_date_time_new_from_unix (GTimeZone *tz, gint64 secs) { return g_date_time_from_instant (tz, UNIX_TO_INSTANT (secs)); } /** * g_date_time_new_now: * @tz: a #GTimeZone * * Creates a #GDateTime corresponding to this exact instant in the given * time zone @tz. The time is as accurate as the system allows, to a * maximum accuracy of 1 microsecond. * * This function will always succeed unless the system clock is set to * truly insane values (or unless GLib is still being used after the * year 9999). * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_new_now (GTimeZone *tz) { GTimeVal tv; g_get_current_time (&tv); return g_date_time_new_from_timeval (tz, &tv); } /** * g_date_time_new_now_local: * * Creates a #GDateTime corresponding to this exact instant in the local * time zone. * * This is equivalent to calling g_date_time_new_now() with the time * zone returned by g_time_zone_new_local(). * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_new_now_local (void) { GDateTime *datetime; GTimeZone *local; local = g_time_zone_new_local (); datetime = g_date_time_new_now (local); g_time_zone_unref (local); return datetime; } /** * g_date_time_new_now_utc: * * Creates a #GDateTime corresponding to this exact instant in UTC. * * This is equivalent to calling g_date_time_new_now() with the time * zone returned by g_time_zone_new_utc(). * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_new_now_utc (void) { GDateTime *datetime; GTimeZone *utc; utc = g_time_zone_new_utc (); datetime = g_date_time_new_now (utc); g_time_zone_unref (utc); return datetime; } /** * g_date_time_new_from_unix_local: * @t: the Unix time * * Creates a #GDateTime corresponding to the given Unix time @t in the * local time zone. * * Unix time is the number of seconds that have elapsed since 1970-01-01 * 00:00:00 UTC, regardless of the local time offset. * * This call can fail (returning %NULL) if @t represents a time outside * of the supported range of #GDateTime. * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_new_from_unix_local (gint64 t) { GDateTime *datetime; GTimeZone *local; local = g_time_zone_new_local (); datetime = g_date_time_new_from_unix (local, t); g_time_zone_unref (local); return datetime; } /** * g_date_time_new_from_unix_utc: * @t: the Unix time * * Creates a #GDateTime corresponding to the given Unix time @t in UTC. * * Unix time is the number of seconds that have elapsed since 1970-01-01 * 00:00:00 UTC. * * This call can fail (returning %NULL) if @t represents a time outside * of the supported range of #GDateTime. * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_new_from_unix_utc (gint64 t) { GDateTime *datetime; GTimeZone *utc; utc = g_time_zone_new_utc (); datetime = g_date_time_new_from_unix (utc, t); g_time_zone_unref (utc); return datetime; } /** * g_date_time_new_from_timeval_local: * @tv: a #GTimeVal * * Creates a #GDateTime corresponding to the given #GTimeVal @tv in the * local time zone. * * The time contained in a #GTimeVal is always stored in the form of * seconds elapsed since 1970-01-01 00:00:00 UTC, regardless of the * local time offset. * * This call can fail (returning %NULL) if @tv represents a time outside * of the supported range of #GDateTime. * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_new_from_timeval_local (const GTimeVal *tv) { GDateTime *datetime; GTimeZone *local; local = g_time_zone_new_local (); datetime = g_date_time_new_from_timeval (local, tv); g_time_zone_unref (local); return datetime; } /** * g_date_time_new_from_timeval_utc: * @tv: a #GTimeVal * * Creates a #GDateTime corresponding to the given #GTimeVal @tv in UTC. * * The time contained in a #GTimeVal is always stored in the form of * seconds elapsed since 1970-01-01 00:00:00 UTC. * * This call can fail (returning %NULL) if @tv represents a time outside * of the supported range of #GDateTime. * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_new_from_timeval_utc (const GTimeVal *tv) { GDateTime *datetime; GTimeZone *utc; utc = g_time_zone_new_utc (); datetime = g_date_time_new_from_timeval (utc, tv); g_time_zone_unref (utc); return datetime; } /* full new functions {{{1 */ /** * g_date_time_new: * @tz: a #GTimeZone * @year: the year component of the date * @month: the month component of the date * @day: the day component of the date * @hour: the hour component of the date * @minute: the minute component of the date * @seconds: the number of seconds past the minute * * Creates a new #GDateTime corresponding to the given date and time in * the time zone @tz. * * The @year must be between 1 and 9999, @month between 1 and 12 and @day * between 1 and 28, 29, 30 or 31 depending on the month and the year. * * @hour must be between 0 and 23 and @minute must be between 0 and 59. * * @seconds must be at least 0.0 and must be strictly less than 60.0. * It will be rounded down to the nearest microsecond. * * If the given time is not representable in the given time zone (for * example, 02:30 on March 14th 2010 in Toronto, due to daylight savings * time) then the time will be rounded up to the nearest existing time * (in this case, 03:00). If this matters to you then you should verify * the return value for containing the same as the numbers you gave. * * In the case that the given time is ambiguous in the given time zone * (for example, 01:30 on November 7th 2010 in Toronto, due to daylight * savings time) then the time falling within standard (ie: * non-daylight) time is taken. * * It not considered a programmer error for the values to this function * to be out of range, but in the case that they are, the function will * return %NULL. * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_new (GTimeZone *tz, gint year, gint month, gint day, gint hour, gint minute, gdouble seconds) { GDateTime *datetime; gint64 full_time; datetime = g_date_time_alloc (tz); datetime->days = ymd_to_days (year, month, day); datetime->usec = (hour * USEC_PER_HOUR) + (minute * USEC_PER_MINUTE) + (gint64) (seconds * USEC_PER_SECOND); full_time = SEC_PER_DAY * (ymd_to_days (year, month, day) - UNIX_EPOCH_START) + SECS_PER_HOUR * hour + SECS_PER_MINUTE * minute + (int) seconds; datetime->interval = g_time_zone_adjust_time (datetime->tz, G_TIME_TYPE_STANDARD, &full_time); full_time += UNIX_EPOCH_START * SEC_PER_DAY; datetime->days = full_time / SEC_PER_DAY; datetime->usec = (full_time % SEC_PER_DAY) * USEC_PER_SECOND; datetime->usec += ((int) (seconds * USEC_PER_SECOND)) % USEC_PER_SECOND; return datetime; } /** * g_date_time_new_local: * @year: the year component of the date * @month: the month component of the date * @day: the day component of the date * @hour: the hour component of the date * @minute: the minute component of the date * @seconds: the number of seconds past the minute * * Creates a new #GDateTime corresponding to the given date and time in * the local time zone. * * This call is equivalent to calling g_date_time_new() with the time * zone returned by g_time_zone_new_local(). * * Returns: a #GDateTime, or %NULL * * Since: 2.26. **/ GDateTime * g_date_time_new_local (gint year, gint month, gint day, gint hour, gint minute, gdouble seconds) { GDateTime *datetime; GTimeZone *local; local = g_time_zone_new_local (); datetime = g_date_time_new (local, year, month, day, hour, minute, seconds); g_time_zone_unref (local); return datetime; } /** * g_date_time_new_utc: * @year: the year component of the date * @month: the month component of the date * @day: the day component of the date * @hour: the hour component of the date * @minute: the minute component of the date * @seconds: the number of seconds past the minute * * Creates a new #GDateTime corresponding to the given date and time in * UTC. * * This call is equivalent to calling g_date_time_new() with the time * zone returned by g_time_zone_new_utc(). * * Returns: a #GDateTime, or %NULL * * Since: 2.26. **/ GDateTime * g_date_time_new_utc (gint year, gint month, gint day, gint hour, gint minute, gdouble seconds) { GDateTime *datetime; GTimeZone *utc; utc = g_time_zone_new_utc (); datetime = g_date_time_new (utc, year, month, day, hour, minute, seconds); g_time_zone_unref (utc); return datetime; } /* Adders {{{1 */ /** * g_date_time_add: * @datetime: a #GDateTime * @timespan: a #GTimeSpan * * Creates a copy of @datetime and adds the specified timespan to the copy. * * Return value: the newly created #GDateTime which should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime* g_date_time_add (GDateTime *datetime, GTimeSpan timespan) { return g_date_time_from_instant (datetime->tz, timespan + g_date_time_to_instant (datetime)); } /** * g_date_time_add_years: * @datetime: a #GDateTime * @years: the number of years * * Creates a copy of @datetime and adds the specified number of years to the * copy. * * Return value: the newly created #GDateTime which should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime * g_date_time_add_years (GDateTime *datetime, gint years) { gint year, month, day; g_return_val_if_fail (datetime != NULL, NULL); if (years < -10000 || years > 10000) return NULL; g_date_time_get_ymd (datetime, &year, &month, &day); year += years; /* only possible issue is if we've entered a year with no February 29 */ if (month == 2 && day == 29 && !GREGORIAN_LEAP (year)) day = 28; return g_date_time_replace_days (datetime, ymd_to_days (year, month, day)); } /** * g_date_time_add_months: * @datetime: a #GDateTime * @months: the number of months * * Creates a copy of @datetime and adds the specified number of months to the * copy. * * Return value: the newly created #GDateTime which should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime* g_date_time_add_months (GDateTime *datetime, gint months) { gint year, month, day; g_return_val_if_fail (datetime != NULL, NULL); g_date_time_get_ymd (datetime, &year, &month, &day); if (months < -120000 || months > 120000) return NULL; year += months / 12; month += months % 12; if (month < 1) { month += 12; year--; } else if (month > 12) { month -= 12; year++; } day = MIN (day, days_in_months[GREGORIAN_LEAP (year)][month]); return g_date_time_replace_days (datetime, ymd_to_days (year, month, day)); } /** * g_date_time_add_weeks: * @datetime: a #GDateTime * @weeks: the number of weeks * * Creates a copy of @datetime and adds the specified number of weeks to the * copy. * * Return value: the newly created #GDateTime which should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime* g_date_time_add_weeks (GDateTime *datetime, gint weeks) { g_return_val_if_fail (datetime != NULL, NULL); return g_date_time_add_days (datetime, weeks * 7); } /** * g_date_time_add_days: * @datetime: a #GDateTime * @days: the number of days * * Creates a copy of @datetime and adds the specified number of days to the * copy. * * Return value: the newly created #GDateTime which should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime* g_date_time_add_days (GDateTime *datetime, gint days) { g_return_val_if_fail (datetime != NULL, NULL); if (days < -3660000 || days > 3660000) return NULL; return g_date_time_replace_days (datetime, datetime->days + days); } /** * g_date_time_add_hours: * @datetime: a #GDateTime * @hours: the number of hours to add * * Creates a copy of @datetime and adds the specified number of hours * * Return value: the newly created #GDateTime which should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime* g_date_time_add_hours (GDateTime *datetime, gint hours) { return g_date_time_add (datetime, hours * USEC_PER_HOUR); } /** * g_date_time_add_minutes: * @datetime: a #GDateTime * @minutes: the number of minutes to add * * Creates a copy of @datetime adding the specified number of minutes. * * Return value: the newly created #GDateTime which should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime* g_date_time_add_minutes (GDateTime *datetime, gint minutes) { return g_date_time_add (datetime, minutes * USEC_PER_MINUTE); } /** * g_date_time_add_seconds: * @datetime: a #GDateTime * @seconds: the number of seconds to add * * Creates a copy of @datetime and adds the specified number of seconds. * * Return value: the newly created #GDateTime which should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime* g_date_time_add_seconds (GDateTime *datetime, gdouble seconds) { return g_date_time_add (datetime, seconds * USEC_PER_SECOND); } /** * g_date_time_add_full: * @datetime: a #GDateTime * @years: the number of years to add * @months: the number of months to add * @days: the number of days to add * @hours: the number of hours to add * @minutes: the number of minutes to add * @seconds: the number of seconds to add * * Creates a new #GDateTime adding the specified values to the current date and * time in @datetime. * * Return value: the newly created #GDateTime that should be freed with * g_date_time_unref(). * * Since: 2.26 */ GDateTime * g_date_time_add_full (GDateTime *datetime, gint years, gint months, gint days, gint hours, gint minutes, gdouble seconds) { gint year, month, day; gint64 full_time; GDateTime *new; gint interval; g_return_val_if_fail (datetime != NULL, NULL); g_date_time_get_ymd (datetime, &year, &month, &day); months += years * 12; if (months < -120000 || months > 120000) return NULL; if (days < -3660000 || days > 3660000) return NULL; year += months / 12; month += months % 12; if (month < 1) { month += 12; year--; } else if (month > 12) { month -= 12; year++; } day = MIN (day, days_in_months[GREGORIAN_LEAP (year)][month]); /* full_time is now in unix (local) time */ full_time = datetime->usec / USEC_PER_SECOND + SEC_PER_DAY * (ymd_to_days (year, month, day) + days - UNIX_EPOCH_START); interval = g_time_zone_adjust_time (datetime->tz, g_time_zone_is_dst (datetime->tz, datetime->interval), &full_time); /* move to UTC unix time */ full_time -= g_time_zone_get_offset (datetime->tz, interval); /* convert back to an instant, add back fractional seconds */ full_time += UNIX_EPOCH_START * SEC_PER_DAY; full_time = full_time * USEC_PER_SECOND + datetime->usec % USEC_PER_SECOND; /* do the actual addition now */ full_time += (hours * USEC_PER_HOUR) + (minutes * USEC_PER_MINUTE) + (gint64) (seconds * USEC_PER_SECOND); /* find the new interval */ interval = g_time_zone_find_interval (datetime->tz, G_TIME_TYPE_UNIVERSAL, INSTANT_TO_UNIX (full_time)); /* convert back into local time */ full_time += USEC_PER_SECOND * g_time_zone_get_offset (datetime->tz, interval); /* split into days and usec of a new datetime */ new = g_date_time_alloc (datetime->tz); new->interval = interval; new->days = full_time / USEC_PER_DAY; new->usec = full_time % USEC_PER_DAY; /* XXX validate */ return new; } /* Compare, difference, hash, equal {{{1 */ /** * g_date_time_compare: * @dt1: first #GDateTime to compare * @dt2: second #GDateTime to compare * * A comparison function for #GDateTimes that is suitable * as a #GCompareFunc. Both #GDateTimes must be non-%NULL. * * Return value: -1, 0 or 1 if @dt1 is less than, equal to or greater * than @dt2. * * Since: 2.26 */ gint g_date_time_compare (gconstpointer dt1, gconstpointer dt2) { gint64 difference; difference = g_date_time_difference ((GDateTime *) dt1, (GDateTime *) dt2); if (difference < 0) return -1; else if (difference > 0) return 1; else return 0; } /** * g_date_time_difference: * @end: a #GDateTime * @begin: a #GDateTime * * Calculates the difference in time between @end and @begin. The * #GTimeSpan that is returned is effectively @end - @begin (ie: * positive if the first simparameter is larger). * * Return value: the difference between the two #GDateTime, as a time * span expressed in microseconds. * * Since: 2.26 */ GTimeSpan g_date_time_difference (GDateTime *end, GDateTime *begin) { g_return_val_if_fail (begin != NULL, 0); g_return_val_if_fail (end != NULL, 0); return g_date_time_to_instant (end) - g_date_time_to_instant (begin); } /** * g_date_time_hash: * @datetime: a #GDateTime * * Hashes @datetime into a #guint, suitable for use within #GHashTable. * * Return value: a #guint containing the hash * * Since: 2.26 */ guint g_date_time_hash (gconstpointer datetime) { return g_date_time_to_instant ((GDateTime *) datetime); } /** * g_date_time_equal: * @dt1: a #GDateTime * @dt2: a #GDateTime * * Checks to see if @dt1 and @dt2 are equal. * * Equal here means that they represent the same moment after converting * them to the same time zone. * * Return value: %TRUE if @dt1 and @dt2 are equal * * Since: 2.26 */ gboolean g_date_time_equal (gconstpointer dt1, gconstpointer dt2) { return g_date_time_difference ((GDateTime *) dt1, (GDateTime *) dt2) == 0; } /* Year, Month, Day Getters {{{1 */ /** * g_date_time_get_ymd: * @datetime: a #GDateTime. * @year: (out): the return location for the gregorian year, or %NULL. * @month: (out): the return location for the month of the year, or %NULL. * @day: (out): the return location for the day of the month, or %NULL. * * Retrieves the Gregorian day, month, and year of a given #GDateTime. * * Since: 2.26 **/ void g_date_time_get_ymd (GDateTime *datetime, gint *year, gint *month, gint *day) { gint the_year; gint the_month; gint the_day; gint remaining_days; gint y100_cycles; gint y4_cycles; gint y1_cycles; gint preceding; gboolean leap; g_return_if_fail (datetime != NULL); remaining_days = datetime->days; /* * We need to convert an offset in days to its year/month/day representation. * Leap years makes this a little trickier than it should be, so we use * 400, 100 and 4 years cycles here to get to the correct year. */ /* Our days offset starts sets 0001-01-01 as day 1, if it was day 0 our * math would be simpler, so let's do it */ remaining_days--; the_year = (remaining_days / DAYS_IN_400YEARS) * 400 + 1; remaining_days = remaining_days % DAYS_IN_400YEARS; y100_cycles = remaining_days / DAYS_IN_100YEARS; remaining_days = remaining_days % DAYS_IN_100YEARS; the_year += y100_cycles * 100; y4_cycles = remaining_days / DAYS_IN_4YEARS; remaining_days = remaining_days % DAYS_IN_4YEARS; the_year += y4_cycles * 4; y1_cycles = remaining_days / 365; the_year += y1_cycles; remaining_days = remaining_days % 365; if (y1_cycles == 4 || y100_cycles == 4) { g_assert (remaining_days == 0); /* special case that indicates that the date is actually one year before, * in the 31th of December */ the_year--; the_month = 12; the_day = 31; goto end; } /* now get the month and the day */ leap = y1_cycles == 3 && (y4_cycles != 24 || y100_cycles == 3); g_assert (leap == GREGORIAN_LEAP(the_year)); the_month = (remaining_days + 50) >> 5; preceding = (days_in_year[0][the_month - 1] + (the_month > 2 && leap)); if (preceding > remaining_days) { /* estimate is too large */ the_month -= 1; preceding -= leap ? days_in_months[1][the_month] : days_in_months[0][the_month]; } remaining_days -= preceding; g_assert(0 <= remaining_days); the_day = remaining_days + 1; end: if (year) *year = the_year; if (month) *month = the_month; if (day) *day = the_day; } /** * g_date_time_get_year: * @datetime: A #GDateTime * * Retrieves the year represented by @datetime in the Gregorian calendar. * * Return value: the year represented by @datetime * * Since: 2.26 */ gint g_date_time_get_year (GDateTime *datetime) { gint year; g_return_val_if_fail (datetime != NULL, 0); g_date_time_get_ymd (datetime, &year, NULL, NULL); return year; } /** * g_date_time_get_month: * @datetime: a #GDateTime * * Retrieves the month of the year represented by @datetime in the Gregorian * calendar. * * Return value: the month represented by @datetime * * Since: 2.26 */ gint g_date_time_get_month (GDateTime *datetime) { gint month; g_return_val_if_fail (datetime != NULL, 0); g_date_time_get_ymd (datetime, NULL, &month, NULL); return month; } /** * g_date_time_get_day_of_month: * @datetime: a #GDateTime * * Retrieves the day of the month represented by @datetime in the gregorian * calendar. * * Return value: the day of the month * * Since: 2.26 */ gint g_date_time_get_day_of_month (GDateTime *datetime) { gint day_of_year, i; const guint16 *days; guint16 last = 0; g_return_val_if_fail (datetime != NULL, 0); days = days_in_year[GREGORIAN_LEAP (g_date_time_get_year (datetime)) ? 1 : 0]; g_date_time_get_week_number (datetime, NULL, NULL, &day_of_year); for (i = 1; i <= 12; i++) { if (days [i] >= day_of_year) return day_of_year - last; last = days [i]; } g_warn_if_reached (); return 0; } /* Week of year / day of week getters {{{1 */ /** * g_date_time_get_week_numbering_year: * @datetime: a #GDateTime * * Returns the ISO 8601 week-numbering year in which the week containing * @datetime falls. * * This function, taken together with g_date_time_get_week_of_year() and * g_date_time_get_day_of_week() can be used to determine the full ISO * week date on which @datetime falls. * * This is usually equal to the normal Gregorian year (as returned by * g_date_time_get_year()), except as detailed below: * * For Thursday, the week-numbering year is always equal to the usual * calendar year. For other days, the number is such that every day * within a complete week (Monday to Sunday) is contained within the * same week-numbering year. * * For Monday, Tuesday and Wednesday occurring near the end of the year, * this may mean that the week-numbering year is one greater than the * calendar year (so that these days have the same week-numbering year * as the Thursday occurring early in the next year). * * For Friday, Saturaday and Sunday occurring near the start of the year, * this may mean that the week-numbering year is one less than the * calendar year (so that these days have the same week-numbering year * as the Thursday occurring late in the previous year). * * An equivalent description is that the week-numbering year is equal to * the calendar year containing the majority of the days in the current * week (Monday to Sunday). * * Note that January 1 0001 in the proleptic Gregorian calendar is a * Monday, so this function never returns 0. * * Returns: the ISO 8601 week-numbering year for @datetime * * Since: 2.26 **/ gint g_date_time_get_week_numbering_year (GDateTime *datetime) { gint year, month, day, weekday; g_date_time_get_ymd (datetime, &year, &month, &day); weekday = g_date_time_get_day_of_week (datetime); /* January 1, 2, 3 might be in the previous year if they occur after * Thursday. * * Jan 1: Friday, Saturday, Sunday => day 1: weekday 5, 6, 7 * Jan 2: Saturday, Sunday => day 2: weekday 6, 7 * Jan 3: Sunday => day 3: weekday 7 * * So we have a special case if (day - weekday) <= -4 */ if (month == 1 && (day - weekday) <= -4) return year - 1; /* December 29, 30, 31 might be in the next year if they occur before * Thursday. * * Dec 31: Monday, Tuesday, Wednesday => day 31: weekday 1, 2, 3 * Dec 30: Monday, Tuesday => day 30: weekday 1, 2 * Dec 29: Monday => day 29: weekday 1 * * So we have a special case if (day - weekday) >= 28 */ else if (month == 12 && (day - weekday) >= 28) return year + 1; else return year; } /** * g_date_time_get_week_of_year: * @datetime: a #GDateTime * * Returns the ISO 8601 week number for the week containing @datetime. * The ISO 8601 week number is the same for every day of the week (from * Moday through Sunday). That can produce some unusual results * (described below). * * The first week of the year is week 1. This is the week that contains * the first Thursday of the year. Equivalently, this is the first week * that has more than 4 of its days falling within the calendar year. * * The value 0 is never returned by this function. Days contained * within a year but occurring before the first ISO 8601 week of that * year are considered as being contained in the last week of the * previous year. Similarly, the final days of a calendar year may be * considered as being part of the first ISO 8601 week of the next year * if 4 or more days of that week are contained within the new year. * * Returns: the ISO 8601 week number for @datetime. * * Since: 2.26 */ gint g_date_time_get_week_of_year (GDateTime *datetime) { gint weeknum; g_return_val_if_fail (datetime != NULL, 0); g_date_time_get_week_number (datetime, &weeknum, NULL, NULL); return weeknum; } /** * g_date_time_get_day_of_week: * @datetime: a #GDateTime * * Retrieves the ISO 8601 day of the week on which @datetime falls (1 is * Monday, 2 is Tuesday... 7 is Sunday). * * Return value: the day of the week * * Since: 2.26 */ gint g_date_time_get_day_of_week (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, 0); return (datetime->days - 1) % 7 + 1; } /* Day of year getter {{{1 */ /** * g_date_time_get_day_of_year: * @datetime: a #GDateTime * * Retrieves the day of the year represented by @datetime in the Gregorian * calendar. * * Return value: the day of the year * * Since: 2.26 */ gint g_date_time_get_day_of_year (GDateTime *datetime) { gint doy = 0; g_return_val_if_fail (datetime != NULL, 0); g_date_time_get_week_number (datetime, NULL, NULL, &doy); return doy; } /* Time component getters {{{1 */ /** * g_date_time_get_hour: * @datetime: a #GDateTime * * Retrieves the hour of the day represented by @datetime * * Return value: the hour of the day * * Since: 2.26 */ gint g_date_time_get_hour (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, 0); return (datetime->usec / USEC_PER_HOUR); } /** * g_date_time_get_minute: * @datetime: a #GDateTime * * Retrieves the minute of the hour represented by @datetime * * Return value: the minute of the hour * * Since: 2.26 */ gint g_date_time_get_minute (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, 0); return (datetime->usec % USEC_PER_HOUR) / USEC_PER_MINUTE; } /** * g_date_time_get_second: * @datetime: a #GDateTime * * Retrieves the second of the minute represented by @datetime * * Return value: the second represented by @datetime * * Since: 2.26 */ gint g_date_time_get_second (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, 0); return (datetime->usec % USEC_PER_MINUTE) / USEC_PER_SECOND; } /** * g_date_time_get_microsecond: * @datetime: a #GDateTime * * Retrieves the microsecond of the date represented by @datetime * * Return value: the microsecond of the second * * Since: 2.26 */ gint g_date_time_get_microsecond (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, 0); return (datetime->usec % USEC_PER_SECOND); } /** * g_date_time_get_seconds: * @datetime: a #GDateTime * * Retrieves the number of seconds since the start of the last minute, * including the fractional part. * * Returns: the number of seconds * * Since: 2.26 **/ gdouble g_date_time_get_seconds (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, 0); return (datetime->usec % USEC_PER_MINUTE) / 1000000.0; } /* Exporters {{{1 */ /** * g_date_time_to_unix: * @datetime: a #GDateTime * * Gives the Unix time corresponding to @datetime, rounding down to the * nearest second. * * Unix time is the number of seconds that have elapsed since 1970-01-01 * 00:00:00 UTC, regardless of the time zone associated with @datetime. * * Returns: the Unix time corresponding to @datetime * * Since: 2.26 **/ gint64 g_date_time_to_unix (GDateTime *datetime) { return INSTANT_TO_UNIX (g_date_time_to_instant (datetime)); } /** * g_date_time_to_timeval: * @datetime: a #GDateTime * @tv: a #GTimeVal to modify * * Stores the instant in time that @datetime represents into @tv. * * The time contained in a #GTimeVal is always stored in the form of * seconds elapsed since 1970-01-01 00:00:00 UTC, regardless of the time * zone associated with @datetime. * * On systems where 'long' is 32bit (ie: all 32bit systems and all * Windows systems), a #GTimeVal is incapable of storing the entire * range of values that #GDateTime is capable of expressing. On those * systems, this function returns %FALSE to indicate that the time is * out of range. * * On systems where 'long' is 64bit, this function never fails. * * Returns: %TRUE if successful, else %FALSE * * Since: 2.26 **/ gboolean g_date_time_to_timeval (GDateTime *datetime, GTimeVal *tv) { tv->tv_sec = INSTANT_TO_UNIX (g_date_time_to_instant (datetime)); tv->tv_usec = datetime->usec % USEC_PER_SECOND; return TRUE; } /* Timezone queries {{{1 */ /** * g_date_time_get_utc_offset: * @datetime: a #GDateTime * * Determines the offset to UTC in effect at the time and in the time * zone of @datetime. * * The offset is the number of microseconds that you add to UTC time to * arrive at local time for the time zone (ie: negative numbers for time * zones west of GMT, positive numbers for east). * * If @datetime represents UTC time, then the offset is always zero. * * Returns: the number of microseconds that should be added to UTC to * get the local time * * Since: 2.26 **/ GTimeSpan g_date_time_get_utc_offset (GDateTime *datetime) { gint offset; g_return_val_if_fail (datetime != NULL, 0); offset = g_time_zone_get_offset (datetime->tz, datetime->interval); return (gint64) offset * USEC_PER_SECOND; } /** * g_date_time_get_timezone_abbreviation: * @datetime: a #GDateTime * * Determines the time zone abbreviation to be used at the time and in * the time zone of @datetime. * * For example, in Toronto this is currently "EST" during the winter * months and "EDT" during the summer months when daylight savings * time is in effect. * * Returns: (transfer none): the time zone abbreviation. The returned * string is owned by the #GDateTime and it should not be * modified or freed * * Since: 2.26 **/ const gchar * g_date_time_get_timezone_abbreviation (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, NULL); return g_time_zone_get_abbreviation (datetime->tz, datetime->interval); } /** * g_date_time_is_daylight_savings: * @datetime: a #GDateTime * * Determines if daylight savings time is in effect at the time and in * the time zone of @datetime. * * Returns: %TRUE if daylight savings time is in effect * * Since: 2.26 **/ gboolean g_date_time_is_daylight_savings (GDateTime *datetime) { g_return_val_if_fail (datetime != NULL, FALSE); return g_time_zone_is_dst (datetime->tz, datetime->interval); } /* Timezone convert {{{1 */ /** * g_date_time_to_timezone: * @datetime: a #GDateTime * @tz: the new #GTimeZone * * Create a new #GDateTime corresponding to the same instant in time as * @datetime, but in the time zone @tz. * * This call can fail in the case that the time goes out of bounds. For * example, converting 0001-01-01 00:00:00 UTC to a time zone west of * Greenwich will fail (due to the year 0 being out of range). * * You should release the return value by calling g_date_time_unref() * when you are done with it. * * Returns: a new #GDateTime, or %NULL * * Since: 2.26 **/ GDateTime * g_date_time_to_timezone (GDateTime *datetime, GTimeZone *tz) { return g_date_time_from_instant (tz, g_date_time_to_instant (datetime)); } /** * g_date_time_to_local: * @datetime: a #GDateTime * * Creates a new #GDateTime corresponding to the same instant in time as * @datetime, but in the local time zone. * * This call is equivalent to calling g_date_time_to_timezone() with the * time zone returned by g_time_zone_new_local(). * * Returns: the newly created #GDateTime * * Since: 2.26 **/ GDateTime * g_date_time_to_local (GDateTime *datetime) { GDateTime *new; GTimeZone *local; local = g_time_zone_new_local (); new = g_date_time_to_timezone (datetime, local); g_time_zone_unref (local); return new; } /** * g_date_time_to_utc: * @datetime: a #GDateTime * * Creates a new #GDateTime corresponding to the same instant in time as * @datetime, but in UTC. * * This call is equivalent to calling g_date_time_to_timezone() with the * time zone returned by g_time_zone_new_utc(). * * Returns: the newly created #GDateTime * * Since: 2.26 **/ GDateTime * g_date_time_to_utc (GDateTime *datetime) { GDateTime *new; GTimeZone *utc; utc = g_time_zone_new_utc (); new = g_date_time_to_timezone (datetime, utc); g_time_zone_unref (utc); return new; } /* Format {{{1 */ static void format_number (GString *str, gboolean use_alt_digits, gchar pad, gint width, guint32 number) { const gunichar ascii_digits[10] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9' }; const gunichar *digits = ascii_digits; gunichar tmp[10]; gint i = 0; g_return_if_fail (width <= 10); #ifdef HAVE_LANGINFO_OUTDIGIT if (use_alt_digits) { static gunichar alt_digits[10]; static gsize initialised; /* 2^32 has 10 digits */ if G_UNLIKELY (g_once_init_enter (&initialised)) { #define DO_DIGIT(n) \ { \ union { guint integer; char *pointer; } val; \ val.pointer = nl_langinfo (_NL_CTYPE_OUTDIGIT## n ##_WC); \ alt_digits[n] = val.integer; \ } DO_DIGIT(0); DO_DIGIT(1); DO_DIGIT(2); DO_DIGIT(3); DO_DIGIT(4); DO_DIGIT(5); DO_DIGIT(6); DO_DIGIT(7); DO_DIGIT(8); DO_DIGIT(9); #undef DO_DIGIT g_once_init_leave (&initialised, TRUE); } digits = alt_digits; } #endif /* HAVE_LANGINFO_OUTDIGIT */ do { tmp[i++] = digits[number % 10]; number /= 10; } while (number); while (pad && i < width) tmp[i++] = pad == '0' ? digits[0] : pad; /* should really be impossible */ g_assert (i <= 10); while (i) g_string_append_unichar (str, tmp[--i]); } /** * g_date_time_format: * @datetime: A #GDateTime * @format: a valid UTF-8 string, containing the format for the * #GDateTime * * Creates a newly allocated string representing the requested @format. * * The format strings understood by this function are a subset of the * strftime() format language as specified by C99. The \%D, \%U and \%W * conversions are not supported, nor is the 'E' modifier. The GNU * extensions \%k, \%l, \%s and \%P are supported, however, as are the * '0', '_' and '-' modifiers. * * In contrast to strftime(), this function always produces a UTF-8 * string, regardless of the current locale. Note that the rendering of * many formats is locale-dependent and may not match the strftime() * output exactly. * * The following format specifiers are supported: * * * * \%a: * * the abbreviated weekday name according to the current locale * * * \%A: * * the full weekday name according to the current locale * * * \%b: * * the abbreviated month name according to the current locale * * * \%B: * * the full month name according to the current locale * * * \%c: * * the preferred date and time representation for the current locale * * * \%C: * * The century number (year/100) as a 2-digit integer (00-99) * * * \%d: * * the day of the month as a decimal number (range 01 to 31) * * * \%e: * * the day of the month as a decimal number (range 1 to 31) * * * \%F: * * equivalent to \%Y-\%m-\%d (the ISO 8601 date * format) * * * \%g: * * the last two digits of the ISO 8601 week-based year as a decimal * number (00-99). This works well with \%V and \%u. * * * \%G: * * the ISO 8601 week-based year as a decimal number. This works well * with \%V and \%u. * * * \%h: * * equivalent to \%b * * * \%H: * * the hour as a decimal number using a 24-hour clock (range 00 to * 23) * * * \%I: * * the hour as a decimal number using a 12-hour clock (range 01 to * 12) * * * \%j: * * the day of the year as a decimal number (range 001 to 366) * * * \%k: * * the hour (24-hour clock) as a decimal number (range 0 to 23); * single digits are preceded by a blank * * * \%l: * * the hour (12-hour clock) as a decimal number (range 1 to 12); * single digits are preceded by a blank * * * \%m: * * the month as a decimal number (range 01 to 12) * * * \%M: * * the minute as a decimal number (range 00 to 59) * * * \%p: * * either "AM" or "PM" according to the given time value, or the * corresponding strings for the current locale. Noon is treated as * "PM" and midnight as "AM". * * * \%P: * * like \%p but lowercase: "am" or "pm" or a corresponding string for * the current locale * * * \%r: * * the time in a.m. or p.m. notation * * * \%R: * * the time in 24-hour notation (\%H:\%M) * * * \%s: * * the number of seconds since the Epoch, that is, since 1970-01-01 * 00:00:00 UTC * * * \%S: * * the second as a decimal number (range 00 to 60) * * * \%t: * * a tab character * * * \%T: * * the time in 24-hour notation with seconds (\%H:\%M:\%S) * * * \%u: * * the ISO 8601 standard day of the week as a decimal, range 1 to 7, * Monday being 1. This works well with \%G and \%V. * * * \%V: * * the ISO 8601 standard week number of the current year as a decimal * number, range 01 to 53, where week 1 is the first week that has at * least 4 days in the new year. See g_date_time_get_week_of_year(). * This works well with \%G and \%u. * * * \%w: * * the day of the week as a decimal, range 0 to 6, Sunday being 0. * This is not the ISO 8601 standard format -- use \%u instead. * * * \%x: * * the preferred date representation for the current locale without * the time * * * \%X: * * the preferred time representation for the current locale without * the date * * * \%y: * * the year as a decimal number without the century * * * \%Y: * * the year as a decimal number including the century * * * \%z: * * the time-zone as hour offset from UTC * * * \%Z: * * the time zone or name or abbreviation * * * \%\%: * * a literal \% character * * * * Some conversion specifications can be modified by preceding the * conversion specifier by one or more modifier characters. The * following modifiers are supported for many of the numeric * conversions: * * * O * * Use alternative numeric symbols, if the current locale * supports those. * * * * _ * * Pad a numeric result with spaces. * This overrides the default padding for the specifier. * * * * - * * Do not pad a numeric result. * This overrides the default padding for the specifier. * * * * 0 * * Pad a numeric result with zeros. * This overrides the default padding for the specifier. * * * * * Returns: a newly allocated string formatted to the requested format * or %NULL in the case that there was an error. The string * should be freed with g_free(). * * Since: 2.26 */ gchar * g_date_time_format (GDateTime *datetime, const gchar *format) { GString *outstr; gchar *tmp; gunichar c; gboolean in_mod = FALSE; gboolean alt_digits = FALSE; gboolean pad_set = FALSE; gchar pad = '\0'; gchar *ampm; g_return_val_if_fail (datetime != NULL, NULL); g_return_val_if_fail (format != NULL, NULL); g_return_val_if_fail (g_utf8_validate (format, -1, NULL), NULL); outstr = g_string_sized_new (strlen (format) * 2); in_mod = FALSE; for (; *format; format = g_utf8_next_char (format)) { c = g_utf8_get_char (format); switch (c) { case '%': if (!in_mod) { in_mod = TRUE; alt_digits = FALSE; pad_set = FALSE; break; } /* Fall through */ default: if (in_mod) { switch (c) { case 'a': g_string_append (outstr, WEEKDAY_ABBR (datetime)); break; case 'A': g_string_append (outstr, WEEKDAY_FULL (datetime)); break; case 'b': g_string_append (outstr, MONTH_ABBR (datetime)); break; case 'B': g_string_append (outstr, MONTH_FULL (datetime)); break; case 'c': { tmp = g_date_time_format (datetime, PREFERRED_DATE_TIME_FMT); g_string_append (outstr, tmp); g_free (tmp); } break; case 'C': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_year (datetime) / 100); break; case 'd': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_day_of_month (datetime)); break; case 'e': format_number (outstr, alt_digits, pad_set ? pad : ' ', 2, g_date_time_get_day_of_month (datetime)); break; case 'F': g_string_append_printf (outstr, "%d-%02d-%02d", g_date_time_get_year (datetime), g_date_time_get_month (datetime), g_date_time_get_day_of_month (datetime)); break; case 'g': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_week_numbering_year (datetime) % 100); break; case 'G': format_number (outstr, alt_digits, pad_set ? pad : 0, 0, g_date_time_get_week_numbering_year (datetime)); break; case 'h': g_string_append (outstr, MONTH_ABBR (datetime)); break; case 'H': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_hour (datetime)); break; case 'I': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, (g_date_time_get_hour (datetime) + 11) % 12 + 1); break; case 'j': format_number (outstr, alt_digits, pad_set ? pad : '0', 3, g_date_time_get_day_of_year (datetime)); break; case 'k': format_number (outstr, alt_digits, pad_set ? pad : ' ', 2, g_date_time_get_hour (datetime)); break; case 'l': format_number (outstr, alt_digits, pad_set ? pad : ' ', 2, (g_date_time_get_hour (datetime) + 11) % 12 + 1); break; case 'n': g_string_append_c (outstr, '\n'); break; case 'm': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_month (datetime)); break; case 'M': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_minute (datetime)); break; case 'O': alt_digits = TRUE; goto next_mod; case 'p': ampm = g_utf8_strup (GET_AMPM (datetime), -1); g_string_append (outstr, ampm); g_free (ampm); break; case 'P': ampm = g_utf8_strdown (GET_AMPM (datetime), -1); g_string_append (outstr, ampm); g_free (ampm); break; case 'r': { tmp = g_date_time_format (datetime, PREFERRED_12HR_TIME_FMT); g_string_append (outstr, tmp); g_free (tmp); } break; case 'R': g_string_append_printf (outstr, "%02d:%02d", g_date_time_get_hour (datetime), g_date_time_get_minute (datetime)); break; case 's': g_string_append_printf (outstr, "%" G_GINT64_FORMAT, g_date_time_to_unix (datetime)); break; case 'S': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_second (datetime)); break; case 't': g_string_append_c (outstr, '\t'); break; case 'T': g_string_append_printf (outstr, "%02d:%02d:%02d", g_date_time_get_hour (datetime), g_date_time_get_minute (datetime), g_date_time_get_second (datetime)); break; case 'u': format_number (outstr, alt_digits, 0, 0, g_date_time_get_day_of_week (datetime)); break; case 'V': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_week_of_year (datetime)); break; case 'w': format_number (outstr, alt_digits, 0, 0, g_date_time_get_day_of_week (datetime) % 7); break; case 'x': { tmp = g_date_time_format (datetime, PREFERRED_DATE_FMT); g_string_append (outstr, tmp); g_free (tmp); } break; case 'X': { tmp = g_date_time_format (datetime, PREFERRED_TIME_FMT); g_string_append (outstr, tmp); g_free (tmp); } break; case 'y': format_number (outstr, alt_digits, pad_set ? pad : '0', 2, g_date_time_get_year (datetime) % 100); break; case 'Y': format_number (outstr, alt_digits, 0, 0, g_date_time_get_year (datetime)); break; case 'z': if (datetime->tz != NULL) { gint64 offset = g_date_time_get_utc_offset (datetime) / USEC_PER_SECOND; g_string_append_printf (outstr, "%+03d%02d", (int) offset / 3600, (int) abs(offset) / 60 % 60); } else g_string_append (outstr, "+0000"); break; case 'Z': g_string_append (outstr, g_date_time_get_timezone_abbreviation (datetime)); break; case '%': g_string_append_c (outstr, '%'); break; case '-': pad_set = TRUE; pad = 0; goto next_mod; case '_': pad_set = TRUE; pad = ' '; goto next_mod; case '0': pad_set = TRUE; pad = '0'; goto next_mod; default: goto bad_format; } in_mod = FALSE; } else g_string_append_unichar (outstr, c); } next_mod: ; } return g_string_free (outstr, FALSE); bad_format: g_string_free (outstr, TRUE); return NULL; } /* Epilogue {{{1 */ /* vim:set foldmethod=marker: */