GLib Reference Manual | ||||
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Date and Time FunctionsDate and Time Functions — calendrical calculations and miscellaneous time stuff |
#include <glib.h> #define G_USEC_PER_SEC GTimeVal; void g_get_current_time (GTimeVal *result); void g_usleep (gulong microseconds); void g_time_val_add (GTimeVal *time_, glong microseconds); gboolean g_time_val_from_iso8601 (const gchar *iso_date, GTimeVal *time_); gchar* g_time_val_to_iso8601 (GTimeVal *time_); GDate; typedef GTime; enum GDateDMY; typedef GDateDay; enum GDateMonth; typedef GDateYear; enum GDateWeekday; #define G_DATE_BAD_DAY #define G_DATE_BAD_JULIAN #define G_DATE_BAD_YEAR GDate* g_date_new (void); GDate* g_date_new_dmy (GDateDay day, GDateMonth month, GDateYear year); GDate* g_date_new_julian (guint32 julian_day); void g_date_clear (GDate *date, guint n_dates); void g_date_free (GDate *date); void g_date_set_day (GDate *date, GDateDay day); void g_date_set_month (GDate *date, GDateMonth month); void g_date_set_year (GDate *date, GDateYear year); void g_date_set_dmy (GDate *date, GDateDay day, GDateMonth month, GDateYear y); void g_date_set_julian (GDate *date, guint32 julian_date); void g_date_set_time (GDate *date, GTime time_); void g_date_set_time_t (GDate *date, time_t timet); void g_date_set_time_val (GDate *date, GTimeVal *timeval); void g_date_set_parse (GDate *date, const gchar *str); void g_date_add_days (GDate *date, guint n_days); void g_date_subtract_days (GDate *date, guint n_days); void g_date_add_months (GDate *date, guint n_months); void g_date_subtract_months (GDate *date, guint n_months); void g_date_add_years (GDate *date, guint n_years); void g_date_subtract_years (GDate *date, guint n_years); gint g_date_days_between (const GDate *date1, const GDate *date2); gint g_date_compare (const GDate *lhs, const GDate *rhs); void g_date_clamp (GDate *date, const GDate *min_date, const GDate *max_date); void g_date_order (GDate *date1, GDate *date2); GDateDay g_date_get_day (const GDate *date); GDateMonth g_date_get_month (const GDate *date); GDateYear g_date_get_year (const GDate *date); guint32 g_date_get_julian (const GDate *date); GDateWeekday g_date_get_weekday (const GDate *date); guint g_date_get_day_of_year (const GDate *date); guint8 g_date_get_days_in_month (GDateMonth month, GDateYear year); gboolean g_date_is_first_of_month (const GDate *date); gboolean g_date_is_last_of_month (const GDate *date); gboolean g_date_is_leap_year (GDateYear year); guint g_date_get_monday_week_of_year (const GDate *date); guint8 g_date_get_monday_weeks_in_year (GDateYear year); guint g_date_get_sunday_week_of_year (const GDate *date); guint8 g_date_get_sunday_weeks_in_year (GDateYear year); guint g_date_get_iso8601_week_of_year (const GDate *date); gsize g_date_strftime (gchar *s, gsize slen, const gchar *format, const GDate *date); void g_date_to_struct_tm (const GDate *date, struct tm *tm); gboolean g_date_valid (const GDate *date); gboolean g_date_valid_day (GDateDay day); gboolean g_date_valid_month (GDateMonth month); gboolean g_date_valid_year (GDateYear year); gboolean g_date_valid_dmy (GDateDay day, GDateMonth month, GDateYear year); gboolean g_date_valid_julian (guint32 julian_date); gboolean g_date_valid_weekday (GDateWeekday weekday);
The GDate data structure represents a day between January 1, Year 1,
and sometime a few thousand years in the future (right now it will go
to the year 65535 or so, but g_date_set_parse()
only parses up to the
year 8000 or so - just count on "a few thousand"). GDate is meant to
represent everyday dates, not astronomical dates or historical dates
or ISO timestamps or the like. It extrapolates the current Gregorian
calendar forward and backward in time; there is no attempt to change
the calendar to match time periods or locations. GDate does not store
time information; it represents a day.
The GDate implementation has several nice features; it is only a 64-bit struct, so storing large numbers of dates is very efficient. It can keep both a Julian and day-month-year representation of the date, since some calculations are much easier with one representation or the other. A Julian representation is simply a count of days since some fixed day in the past; for GDate the fixed day is January 1, 1 AD. ("Julian" dates in the GDate API aren't really Julian dates in the technical sense; technically, Julian dates count from the start of the Julian period, Jan 1, 4713 BC).
GDate is simple to use. First you need a "blank" date; you can get a
dynamically allocated date from g_date_new()
, or you can declare an
automatic variable or array and initialize it to a sane state by
calling g_date_clear()
. A cleared date is sane; it's safe to call
g_date_set_dmy()
and the other mutator functions to initialize the
value of a cleared date. However, a cleared date is initially
invalid, meaning that it doesn't represent a day
that exists. It is undefined to call any of the date calculation
routines on an invalid date. If you obtain a date from a user or other
unpredictable source, you should check its validity with the
g_date_valid()
predicate. g_date_valid()
is also used to check for
errors with g_date_set_parse()
and other functions that can
fail. Dates can be invalidated by calling g_date_clear()
again.
It is very important to use the API to access the GDate struct. Often only the day-month-year or only the Julian representation is valid. Sometimes neither is valid. Use the API.
GLib doesn't contain any time-manipulation functions; however, there
is a GTime typedef and a GTimeVal struct which represents a more
precise time (with microseconds). You can request the current time as
a GTimeVal with g_get_current_time()
.
#define G_USEC_PER_SEC 1000000
Number of microseconds in one second (1 million). This macro is provided for code readability.
typedef struct { glong tv_sec; glong tv_usec; } GTimeVal;
Represents a precise time, with seconds and microseconds.
Similar to the struct timeval returned by
the
UNIX call.
gettimeofday()
void g_get_current_time (GTimeVal *result);
Equivalent to the UNIX gettimeofday()
function, but portable.
result : |
GTimeVal structure in which to store current time. |
void g_usleep (gulong microseconds);
Pauses the current thread for the given number of microseconds. There
are 1 million microseconds per second (represented by the
G_USEC_PER_SEC macro). g_usleep()
may have limited precision,
depending on hardware and operating system; don't rely on the exact
length of the sleep.
microseconds : |
number of microseconds to pause |
void g_time_val_add (GTimeVal *time_, glong microseconds);
Adds the given number of microseconds to time_
. microseconds
can
also be negative to decrease the value of time_
.
time_ : |
a GTimeVal |
microseconds : |
number of microseconds to add to time
|
gboolean g_time_val_from_iso8601 (const gchar *iso_date, GTimeVal *time_);
Converts a string containing an ISO 8601 encoded date and time
to a GTimeVal and puts it into time_
.
iso_date : |
an ISO 8601 encoded date string |
time_ : |
a GTimeVal |
Returns : | TRUE if the conversion was successful.
|
Since 2.12
gchar* g_time_val_to_iso8601 (GTimeVal *time_);
Converts time_
into an ISO 8601 encoded string, relative to the
Coordinated Universal Time (UTC).
time_ : |
a GTimeVal |
Returns : | a newly allocated string containing an ISO 8601 date |
Since 2.12
typedef struct { guint julian_days : 32; /* julian days representation - we use a * bitfield hoping that 64 bit platforms * will pack this whole struct in one big * int */ guint julian : 1; /* julian is valid */ guint dmy : 1; /* dmy is valid */ /* DMY representation */ guint day : 6; guint month : 4; guint year : 16; } GDate;
Represents a day between January 1, Year 1 and a few thousand years in
the future. None of its members should be accessed directly. If the
GDate is obtained from g_date_new()
, it will
be safe to mutate but invalid and thus not safe for calendrical computations.
If it's declared on the stack, it will contain garbage so must be
initialized with g_date_clear()
. g_date_clear()
makes the date invalid
but sane. An invalid date doesn't represent a day, it's "empty." A
date becomes valid after you set it to a Julian day or you set a day,
month, and year.
guint julian_days : 32; |
the Julian representation of the date |
guint julian : 1; |
this bit is set if julian_days is valid
|
guint dmy : 1; |
this is set if day , month and year are valid
|
guint day : 6; |
the day of the day-month-year representation of the date, as a number between 1 and 31 |
guint month : 4; |
the day of the day-month-year representation of the date, as a number between 1 and 12 |
guint year : 16; |
the day of the day-month-year representation of the date |
typedef gint32 GTime;
Simply a replacement for time_t. It has been deprected since it is not equivalent to time_t on 64-bit platforms with a 64-bit time_t. Unrelated to GTimer.
Note that GTime is defined to always be a 32bit integer,
unlike time_t which may be 64bit on some systems.
Therefore, GTime will overflow in the year 2038, and
you cannot use the address of a GTime variable as argument
to the UNIX time()
function. Instead, do the following:
time_t ttime; GTime gtime; time (&ttime); gtime = (GTime)ttime;
typedef enum { G_DATE_DAY = 0, G_DATE_MONTH = 1, G_DATE_YEAR = 2 } GDateDMY;
This enumeration isn't used in the API, but may be useful if you need to mark a number as a day, month, or year.
typedef guint8 GDateDay; /* day of the month */
Integer representing a day of the month; between 1 and 31. G_DATE_BAD_DAY represents an invalid day of the month.
typedef enum { G_DATE_BAD_MONTH = 0, G_DATE_JANUARY = 1, G_DATE_FEBRUARY = 2, G_DATE_MARCH = 3, G_DATE_APRIL = 4, G_DATE_MAY = 5, G_DATE_JUNE = 6, G_DATE_JULY = 7, G_DATE_AUGUST = 8, G_DATE_SEPTEMBER = 9, G_DATE_OCTOBER = 10, G_DATE_NOVEMBER = 11, G_DATE_DECEMBER = 12 } GDateMonth;
Enumeration representing a month; values are G_DATE_JANUARY, G_DATE_FEBRUARY, etc. G_DATE_BAD_MONTH is the invalid value.
typedef guint16 GDateYear;
Integer representing a year; G_DATE_BAD_YEAR is the invalid value. The year must be 1 or higher; negative (BC) years are not allowed. The year is represented with four digits.
typedef enum { G_DATE_BAD_WEEKDAY = 0, G_DATE_MONDAY = 1, G_DATE_TUESDAY = 2, G_DATE_WEDNESDAY = 3, G_DATE_THURSDAY = 4, G_DATE_FRIDAY = 5, G_DATE_SATURDAY = 6, G_DATE_SUNDAY = 7 } GDateWeekday;
Enumeration representing a day of the week; G_DATE_MONDAY, G_DATE_TUESDAY, etc. G_DATE_BAD_WEEKDAY is an invalid weekday.
GDate* g_date_new (void);
Allocates a GDate and initializes it to a sane state. The new date will
be cleared (as if you'd called g_date_clear()
) but invalid (it won't
represent an existing day). Free the return value with g_date_free()
.
Returns : | a newly-allocated GDate |
GDate* g_date_new_dmy (GDateDay day, GDateMonth month, GDateYear year);
Like g_date_new()
, but also sets the value of the date. Assuming the
day-month-year triplet you pass in represents an existing day, the
returned date will be valid.
day : |
day of the month |
month : |
month of the year |
year : |
year |
Returns : | a newly-allocated GDate initialized with day , month , and year
|
GDate* g_date_new_julian (guint32 julian_day);
Like g_date_new()
, but also sets the value of the date. Assuming the
Julian day number you pass in is valid (greater than 0, less than an
unreasonably large number), the returned date will be valid.
julian_day : |
days since January 1, Year 1 |
Returns : | a newly-allocated GDate initialized with julian_day
|
void g_date_clear (GDate *date, guint n_dates);
Initializes one or more GDate structs to a sane but invalid
state. The cleared dates will not represent an existing date, but will
not contain garbage. Useful to init a date declared on the stack.
Validity can be tested with g_date_valid()
.
date : |
pointer to one or more dates to clear |
n_dates : |
number of dates to clear |
void g_date_free (GDate *date);
Frees a GDate returned from g_date_new()
.
date : |
a GDate |
void g_date_set_day (GDate *date, GDateDay day);
Sets the day of the month for a GDate. If the resulting day-month-year triplet is invalid, the date will be invalid.
date : |
a GDate |
day : |
day to set |
void g_date_set_month (GDate *date, GDateMonth month);
Sets the month of the year for a GDate. If the resulting day-month-year triplet is invalid, the date will be invalid.
date : |
a GDate |
month : |
month to set |
void g_date_set_year (GDate *date, GDateYear year);
Sets the year for a GDate. If the resulting day-month-year triplet is invalid, the date will be invalid.
date : |
a GDate |
year : |
year to set |
void g_date_set_dmy (GDate *date, GDateDay day, GDateMonth month, GDateYear y);
Sets the value of a GDate from a day, month, and year. The day-month-year
triplet must be valid; if you aren't sure it is, call g_date_valid_dmy()
to
check before you set it.
date : |
a GDate |
day : |
day |
month : |
month |
y : |
year |
void g_date_set_julian (GDate *date, guint32 julian_date);
Sets the value of a GDate from a Julian day number.
date : |
a GDate |
julian_date : |
Julian day number (days since January 1, Year 1) |
void g_date_set_time (GDate *date, GTime time_);
g_date_set_time
is deprecated and should not be used in newly-written code.
Sets the value of a date from a GTime value. The time to date conversion is done using the user's current timezone.
Deprecated
:2.10: Use g_date_set_time_t()
instead.
void g_date_set_time_t (GDate *date, time_t timet);
Sets the value of a date to the date corresponding to a time specified as a time_t. The time to date conversion is done using the user's current timezone.
To set the value of a date to the current day, you could write:
g_date_set_time_t (date, time (NULL));
date : |
a GDate |
timet : |
time_t value to set |
Since 2.10
void g_date_set_time_val (GDate *date, GTimeVal *timeval);
Sets the value of a date from a GTimeVal value. Note that the
tv_usec
member is ignored, because GDate can't make use of the
additional precision.
Since 2.10
void g_date_set_parse (GDate *date, const gchar *str);
Parses a user-inputted string str
, and try to figure out what date it
represents, taking the current locale
into account. If the string is successfully parsed, the date will be
valid after the call. Otherwise, it will be invalid. You should check
using g_date_valid()
to see whether the parsing succeeded.
This function is not appropriate for file formats and the like; it isn't very precise, and its exact behavior varies with the locale. It's intended to be a heuristic routine that guesses what the user means by a given string (and it does work pretty well in that capacity).
date : |
a GDate to fill in |
str : |
string to parse |
void g_date_add_days (GDate *date, guint n_days);
Increments a date some number of days. To move forward by weeks, add weeks*7 days. The date must be valid.
date : |
a GDate to increment |
n_days : |
number of days to move the date forward |
void g_date_subtract_days (GDate *date, guint n_days);
Moves a date some number of days into the past. To move by weeks, just move by weeks*7 days. The date must be valid.
date : |
a GDate to decrement |
n_days : |
number of days to move |
void g_date_add_months (GDate *date, guint n_months);
Increments a date by some number of months. If the day of the month is greater than 28, this routine may change the day of the month (because the destination month may not have the current day in it). The date must be valid.
date : |
a GDate to increment |
n_months : |
number of months to move forward |
void g_date_subtract_months (GDate *date, guint n_months);
Moves a date some number of months into the past. If the current day of the month doesn't exist in the destination month, the day of the month may change. The date must be valid.
date : |
a GDate to decrement |
n_months : |
number of months to move |
void g_date_add_years (GDate *date, guint n_years);
Increments a date by some number of years. If the date is February 29, and the destination year is not a leap year, the date will be changed to February 28. The date must be valid.
date : |
a GDate to increment |
n_years : |
number of years to move forward |
void g_date_subtract_years (GDate *date, guint n_years);
Moves a date some number of years into the past. If the current day doesn't exist in the destination year (i.e. it's February 29 and you move to a non-leap-year) then the day is changed to February 29. The date must be valid.
date : |
a GDate to decrement |
n_years : |
number of years to move |
gint g_date_days_between (const GDate *date1, const GDate *date2);
Computes the number of days between two dates.
If date2
is prior to date1
, the returned value is negative.
Both dates must be valid.
date1 : |
the first date |
date2 : |
the second date |
Returns : | the number of days between date1 and date2
|
gint g_date_compare (const GDate *lhs, const GDate *rhs);
qsort()
-style comparsion function for dates. Both
dates must be valid.
lhs : |
first date to compare |
rhs : |
second date to compare |
Returns : | 0 for equal, less than zero if lhs is less than rhs ,
greater than zero if lhs is greater than rhs
|
void g_date_clamp (GDate *date, const GDate *min_date, const GDate *max_date);
If date
is prior to min_date
, sets date
equal to min_date
.
If date
falls after max_date
, sets date
equal to max_date
.
Otherwise, date
is unchanged.
Either of min_date
and max_date
may be NULL
. All non-NULL
dates
must be valid.
date : |
a GDate to clamp |
min_date : |
minimum accepted value for date
|
max_date : |
maximum accepted value for date
|
void g_date_order (GDate *date1, GDate *date2);
Checks if date1
is less than or equal to date2
,
and swap the values if this is not the case.
date1 : |
the first date |
date2 : |
the second date |
GDateDay g_date_get_day (const GDate *date);
Returns the day of the month. The date must be valid.
date : |
a GDate to extract the day of the month from |
Returns : | day of the month |
GDateMonth g_date_get_month (const GDate *date);
Returns the month of the year. The date must be valid.
date : |
a GDate to get the month from |
Returns : | month of the year as a GDateMonth |
GDateYear g_date_get_year (const GDate *date);
Returns the year of a GDate. The date must be valid.
date : |
a GDate |
Returns : | year in which the date falls |
guint32 g_date_get_julian (const GDate *date);
Returns the Julian day or "serial number" of the GDate. The Julian day is simply the number of days since January 1, Year 1; i.e., January 1, Year 1 is Julian day 1; January 2, Year 1 is Julian day 2, etc. The date must be valid.
date : |
a GDate to extract the Julian day from |
Returns : | Julian day |
GDateWeekday g_date_get_weekday (const GDate *date);
Returns the day of the week for a GDate. The date must be valid.
date : |
a GDate. |
Returns : | day of the week as a GDateWeekday. |
guint g_date_get_day_of_year (const GDate *date);
Returns the day of the year, where Jan 1 is the first day of the year. The date must be valid.
date : |
a GDate to extract day of year from |
Returns : | day of the year |
guint8 g_date_get_days_in_month (GDateMonth month, GDateYear year);
Returns the number of days in a month, taking leap years into account.
month : |
month |
year : |
year |
Returns : | number of days in month during the year
|
gboolean g_date_is_first_of_month (const GDate *date);
Returns TRUE
if the date is on the first of a month. The date must be valid.
gboolean g_date_is_last_of_month (const GDate *date);
Returns TRUE
if the date is the last day of the month. The date must be valid.
gboolean g_date_is_leap_year (GDateYear year);
Returns TRUE
if the year is a leap year.[4]
year : |
year to check |
Returns : |
TRUE if the year is a leap year
|
guint g_date_get_monday_week_of_year (const GDate *date);
Returns the week of the year, where weeks are understood to start on Monday. If the date is before the first Monday of the year, return 0. The date must be valid.
date : |
a GDate |
Returns : | week of the year |
guint8 g_date_get_monday_weeks_in_year (GDateYear year);
Returns the number of weeks in the year, where weeks are taken to start on Monday. Will be 52 or 53. The date must be valid. (Years always have 52 7-day periods, plus 1 or 2 extra days depending on whether it's a leap year. This function is basically telling you how many Mondays are in the year, i.e. there are 53 Mondays if one of the extra days happens to be a Monday.)
year : |
a year |
Returns : | number of Mondays in the year |
guint g_date_get_sunday_week_of_year (const GDate *date);
Returns the week of the year during which this date falls, if weeks are understood to being on Sunday. The date must be valid. Can return 0 if the day is before the first Sunday of the year.
date : |
a GDate |
Returns : | week number |
guint8 g_date_get_sunday_weeks_in_year (GDateYear year);
Returns the number of weeks in the year, where weeks are taken to start on Sunday. Will be 52 or 53. The date must be valid. (Years always have 52 7-day periods, plus 1 or 2 extra days depending on whether it's a leap year. This function is basically telling you how many Sundays are in the year, i.e. there are 53 Sundays if one of the extra days happens to be a Sunday.)
year : |
year to count weeks in |
Returns : | number of weeks |
guint g_date_get_iso8601_week_of_year (const GDate *date);
Returns the week of the year, where weeks are interpreted according to ISO 8601.
date : |
a valid GDate |
Returns : | ISO 8601 week number of the year. |
Since 2.6
gsize g_date_strftime (gchar *s, gsize slen, const gchar *format, const GDate *date);
Generates a printed representation of the date, in a
locale-specific way. Works just like
the platform's C library strftime()
function, but only accepts date-related
formats; time-related formats give undefined results. Date must be valid.
Unlike strftime()
(which uses the locale encoding), works on a UTF-8 format
string and stores a UTF-8 result.
This function does not provide any conversion specifiers in addition
to those implemented by the platform's C library. For example, don't
expect that using g_date_strftime()
would make the F
provided by the C99
strftime()
work on Windows where the C library only complies to C89.
s : |
destination buffer |
slen : |
buffer size |
format : |
format string |
date : |
valid GDate |
Returns : | number of characters written to the buffer, or 0 the buffer was too small |
void g_date_to_struct_tm (const GDate *date, struct tm *tm);
Fills in the date-related bits of a struct tm
using the date
value. Initializes the non-date parts with something
sane but meaningless.
date : |
a GDate to set the struct tm from. |
tm : |
struct tm to fill. |
gboolean g_date_valid (const GDate *date);
Returns TRUE
if the GDate represents an existing day. The date must not
contain garbage; it should have been initialized with g_date_clear()
if it wasn't allocated by one of the g_date_new()
variants.
date : |
a GDate to check |
Returns : | Whether the date is valid |
gboolean g_date_valid_day (GDateDay day);
Returns TRUE
if the day of the month is valid (a day is valid if it's
between 1 and 31 inclusive).
day : |
day to check |
Returns : |
TRUE if the day is valid
|
gboolean g_date_valid_month (GDateMonth month);
Returns TRUE
if the month value is valid. The 12 GDateMonth
enumeration values are the only valid months.
month : |
month |
Returns : |
TRUE if the month is valid
|
gboolean g_date_valid_year (GDateYear year);
Returns TRUE
if the year is valid. Any year greater than 0 is valid,
though there is a 16-bit limit to what GDate will understand.
year : |
year |
Returns : |
TRUE if the year is valid
|
gboolean g_date_valid_dmy (GDateDay day, GDateMonth month, GDateYear year);
Returns TRUE
if the day-month-year triplet forms a valid, existing day
in the range of days GDate understands (Year 1 or later, no more than
a few thousand years in the future).
day : |
day |
month : |
month |
year : |
year |
Returns : |
TRUE if the date is a valid one
|
gboolean g_date_valid_julian (guint32 julian_date);
Returns TRUE
if the Julian day is valid. Anything greater than zero
is basically a valid Julian, though there is a 32-bit limit.
julian_date : |
Julian day to check |
Returns : |
TRUE if the Julian day is valid
|
gboolean g_date_valid_weekday (GDateWeekday weekday);
Returns TRUE
if the weekday is valid. The seven GDateWeekday enumeration
values are the only valid weekdays.
weekday : |
weekday |
Returns : |
TRUE if the weekday is valid
|
[4] For the purposes of this function, leap year is every year divisible by 4 unless that year is divisible by 100. If it is divisible by 100 it would be a leap year only if that year is also divisible by 400.