Calendar class is an abstract class that provides methods
for converting between a specific instant in time and a set of calendar fields
such as YEAR, MONTH,
DAY_OF_MONTH, HOUR, and so on, and for
manipulating the calendar fields, such as getting the date of the next
week. An instant in time can be represented by a millisecond value that is
an offset from the Epoch, January 1, 1970
00:00:00.000 GMT (Gregorian).
The class also provides additional fields and methods for
implementing a concrete calendar system outside the package. Those
fields and methods are defined as protected.
Like other locale-sensitive classes, Calendar provides a
class method, getInstance, for getting a generally useful
object of this type. Calendar's getInstance method
returns a Calendar object whose
calendar fields have been initialized with the current date and time:
Calendar rightNow = Calendar.getInstance();
A Calendar object can produce all the calendar field values
needed to implement the date-time formatting for a particular language and
calendar style (for example, Japanese-Gregorian, Japanese-Traditional).
Calendar defines the range of values returned by
certain calendar fields, as well as their meaning. For example,
the first month of the calendar system has value MONTH ==
JANUARY for all calendars. Other values are defined by the
concrete subclass, such as ERA. See individual field
documentation and subclass documentation for details.
The calendar field values can be set by calling the set
methods. Any field values set in a Calendar will not be
interpreted until it needs to calculate its time value (milliseconds from
the Epoch) or values of the calendar fields. Calling the
get, getTimeInMillis, getTime,
add and roll involves such calculation.
Calendar has two modes for interpreting the calendar
fields, lenient and non-lenient. When a
Calendar is in lenient mode, it accepts a wider range of
calendar field values than it produces. When a Calendar
recomputes calendar field values for return by get(), all of
the calendar fields are normalized. For example, a lenient
GregorianCalendar interprets MONTH == JANUARY,
DAY_OF_MONTH == 32 as February 1.
When a Calendar is in non-lenient mode, it throws an
exception if there is any inconsistency in its calendar fields. For
example, a GregorianCalendar always produces
DAY_OF_MONTH values between 1 and the length of the month. A
non-lenient GregorianCalendar throws an exception upon
calculating its time or calendar field values if any out-of-range field
value has been set.
Calendar defines a locale-specific seven day week using two
parameters: the first day of the week and the minimal days in first week
(from 1 to 7). These numbers are taken from the locale resource data when a
Calendar is constructed. They may also be specified explicitly
through the methods for setting their values.
When setting or getting the WEEK_OF_MONTH or
WEEK_OF_YEAR fields, Calendar must determine the
first week of the month or year as a reference point. The first week of a
month or year is defined as the earliest seven day period beginning on
getFirstDayOfWeek() and containing at least
getMinimalDaysInFirstWeek() days of that month or year. Weeks
numbered ..., -1, 0 precede the first week; weeks numbered 2, 3,... follow
it. Note that the normalized numbering returned by get() may be
different. For example, a specific Calendar subclass may
designate the week before week 1 of a year as week n of
the previous year.
Calendar will resolve
calendar field values to determine the date and time in the
following way.
If there is any conflict in calendar field values,
Calendar gives priorities to calendar fields that have been set
more recently. The following are the default combinations of the
calendar fields. The most recent combination, as determined by the
most recently set single field, will be used.
For the time of day fields:YEAR + MONTH + DAY_OF_MONTH YEAR + MONTH + WEEK_OF_MONTH + DAY_OF_WEEK YEAR + MONTH + DAY_OF_WEEK_IN_MONTH + DAY_OF_WEEK YEAR + DAY_OF_YEAR YEAR + DAY_OF_WEEK + WEEK_OF_YEAR
HOUR_OF_DAY AM_PM + HOUR
If there are any calendar fields whose values haven't been set in the selected
field combination, Calendar uses their default values. The default
value of each field may vary by concrete calendar systems. For example, in
GregorianCalendar, the default of a field is the same as that
of the start of the Epoch: i.e., YEAR = 1970, MONTH =
JANUARY, DAY_OF_MONTH = 1, etc.
Note: There are certain possible ambiguities in interpretation of certain singular times, which are resolved in the following ways:
The date or time format strings are not part of the definition of a calendar, as those must be modifiable or overridable by the user at runtime. Use DateFormat to format dates.
set(), add(), and roll().
set(f, value) changes calendar field
f to value. In addition, it sets an
internal member variable to indicate that calendar field f has
been changed. Although calendar field f is changed immediately,
the calendar's time value in milliseconds is not recomputed until the next call to
get(), getTime(), getTimeInMillis(),
add(), or roll() is made. Thus, multiple calls to
set() do not trigger multiple, unnecessary
computations. As a result of changing a calendar field using
set(), other calendar fields may also change, depending on the
calendar field, the calendar field value, and the calendar system. In addition,
get(f) will not necessarily return value set by
the call to the set method
after the calendar fields have been recomputed. The specifics are determined by
the concrete calendar class.
Example: Consider a GregorianCalendar
originally set to August 31, 1999. Calling set(Calendar.MONTH,
Calendar.SEPTEMBER) sets the date to September 31,
1999. This is a temporary internal representation that resolves to
October 1, 1999 if getTime()is then called. However, a
call to set(Calendar.DAY_OF_MONTH, 30) before the call to
getTime() sets the date to September 30, 1999, since
no recomputation occurs after set() itself.
add(f, delta) adds delta
to field f. This is equivalent to calling set(f,
get(f) + delta) with two adjustments:
Add rule 1. The value of field
fafter the call minus the value of fieldfbefore the call isdelta, modulo any overflow that has occurred in fieldf. Overflow occurs when a field value exceeds its range and, as a result, the next larger field is incremented or decremented and the field value is adjusted back into its range.Add rule 2. If a smaller field is expected to be invariant, but it is impossible for it to be equal to its prior value because of changes in its minimum or maximum after field
fis changed or other constraints, such as time zone offset changes, then its value is adjusted to be as close as possible to its expected value. A smaller field represents a smaller unit of time.HOURis a smaller field thanDAY_OF_MONTH. No adjustment is made to smaller fields that are not expected to be invariant. The calendar system determines what fields are expected to be invariant.
In addition, unlike set(), add() forces
an immediate recomputation of the calendar's milliseconds and all
fields.
Example: Consider a GregorianCalendar
originally set to August 31, 1999. Calling add(Calendar.MONTH,
13) sets the calendar to September 30, 2000. Add rule
1 sets the MONTH field to September, since
adding 13 months to August gives September of the next year. Since
DAY_OF_MONTH cannot be 31 in September in a
GregorianCalendar, add rule 2 sets the
DAY_OF_MONTH to 30, the closest possible value. Although
it is a smaller field, DAY_OF_WEEK is not adjusted by
rule 2, since it is expected to change when the month changes in a
GregorianCalendar.
roll(f, delta) adds
delta to field f without changing larger
fields. This is equivalent to calling add(f, delta) with
the following adjustment:
Roll rule. Larger fields are unchanged after the call. A larger field represents a larger unit of time.
DAY_OF_MONTHis a larger field thanHOUR.
Usage model. To motivate the behavior of
add() and roll(), consider a user interface
component with increment and decrement buttons for the month, day, and
year, and an underlying GregorianCalendar. If the
interface reads January 31, 1999 and the user presses the month
increment button, what should it read? If the underlying
implementation uses set(), it might read March 3, 1999. A
better result would be February 28, 1999. Furthermore, if the user
presses the month increment button again, it should read March 31,
1999, not March 28, 1999. By saving the original date and using either
add() or roll(), depending on whether larger
fields should be affected, the user interface can behave as most users
will intuitively expect.
get and set indicating
whether the HOUR is before or after noon.
E.g., at 10:04:15.250 PM the AM_PM is PM.get and set indicating the
day of the month. This is a synonym for DAY_OF_MONTH.
The first day of the month has value 1.get and set indicating the
day of the month. This is a synonym for DATE.
The first day of the month has value 1.get and set indicating the day
of the week. This field takes values SUNDAY,
MONDAY, TUESDAY, WEDNESDAY,
THURSDAY, FRIDAY, and SATURDAY.get and set indicating the
ordinal number of the day of the week within the current month. Together
with the DAY_OF_WEEK field, this uniquely specifies a day
within a month. Unlike WEEK_OF_MONTH and
WEEK_OF_YEAR, this field's value does not depend on
getFirstDayOfWeek() or
getMinimalDaysInFirstWeek(). DAY_OF_MONTH 1
through 7 always correspond to DAY_OF_WEEK_IN_MONTH
1; 8 through 14 correspond to
DAY_OF_WEEK_IN_MONTH 2, and so on.
DAY_OF_WEEK_IN_MONTH 0 indicates the week before
DAY_OF_WEEK_IN_MONTH 1. Negative values count back from the
end of the month, so the last Sunday of a month is specified as
DAY_OF_WEEK = SUNDAY, DAY_OF_WEEK_IN_MONTH = -1. Because
negative values count backward they will usually be aligned differently
within the month than positive values. For example, if a month has 31
days, DAY_OF_WEEK_IN_MONTH -1 will overlap
DAY_OF_WEEK_IN_MONTH 5 and the end of 4.get and set indicating the day
number within the current year. The first day of the year has value 1.get and set indicating the
daylight savings offset in milliseconds.
This field reflects the correct daylight saving offset value of
the time zone of this Calendar if the
TimeZone implementation subclass supports
historical Daylight Saving Time schedule changes.
get and set indicating the
era, e.g., AD or BC in the Julian calendar. This is a calendar-specific
value; see subclass documentation.get and set.
Field numbers range from 0..FIELD_COUNT-1.get and set indicating the
hour of the morning or afternoon. HOUR is used for the
12-hour clock (0 - 11). Noon and midnight are represented by 0, not by 12.
E.g., at 10:04:15.250 PM the HOUR is 10.get and set indicating the
hour of the day. HOUR_OF_DAY is used for the 24-hour clock.
E.g., at 10:04:15.250 PM the HOUR_OF_DAY is 22.get and set indicating the
millisecond within the second.
E.g., at 10:04:15.250 PM the MILLISECOND is 250.get and set indicating the
minute within the hour.
E.g., at 10:04:15.250 PM the MINUTE is 4.get and set indicating the
month. This is a calendar-specific value. The first month of the year is
JANUARY which is 0; the last depends on the number of months in a year.get and set indicating the
second within the minute.
E.g., at 10:04:15.250 PM the SECOND is 15.GregorianCalendar
does not use this value, lunar calendars do.get and set indicating the
week number within the current month. The first week of the month, as
defined by getFirstDayOfWeek() and
getMinimalDaysInFirstWeek(), has value 1. Subclasses define
the value of WEEK_OF_MONTH for days before the first week of
the month.get and set indicating the
week number within the current year. The first week of the year, as
defined by getFirstDayOfWeek() and
getMinimalDaysInFirstWeek(), has value 1. Subclasses define
the value of WEEK_OF_YEAR for days before the first week of
the year.get and set indicating the
year. This is a calendar-specific value; see subclass documentation.get and set
indicating the raw offset from GMT in milliseconds.
This field reflects the correct GMT offset value of the time
zone of this Calendar if the
TimeZone implementation subclass supports
historical GMT offset changes.
add(Calendar.DAY_OF_MONTH, -5).
Calendar represents a time
after the time represented by the specified
Object. This method is equivalent to:
if and only ifcompareTo(when) > 0
when is a Calendar
instance. Otherwise, the method returns false.Calendar represents a time
before the time represented by the specified
Object. This method is equivalent to:
if and only ifcompareTo(when) < 0
when is a Calendar
instance. Otherwise, the method returns false.Calendar undefined. This means that isSet()
will return false for all the
calendar fields, and the date and time calculations will treat
the fields as if they had never been set. A
Calendar implementation class may use its specific
default field values for date/time calculations. For example,
GregorianCalendar uses 1970 if the
YEAR field value is undefined.Calendar undefined. This means that isSet(field)
will return false, and
the date and time calculations will treat the field as if it
had never been set. A Calendar implementation
class may use the field's specific default value for date and
time calculations.
The #HOUR_OF_DAY
, #HOUR
and #AM_PM
fields are handled independently and the the resolution rule for the time of
day is applied. Clearing one of the fields doesn't reset
the hour of day value of this Calendar. Use set(Calendar.HOUR_OF_DAY, 0)
to reset the hour
value.
Calendar objects.In the foregoing description, the notation sgn(expression) designates the mathematical signum function, which is defined to return one of -1, 0, or 1 according to whether the value of expression is negative, zero or positive. The implementor must ensure sgn(x.compareTo(y)) == -sgn(y.compareTo(x)) for all x and y. (This implies that x.compareTo(y) must throw an exception iff y.compareTo(x) throws an exception.)
The implementor must also ensure that the relation is transitive: (x.compareTo(y)>0 && y.compareTo(z)>0) implies x.compareTo(z)>0.
Finally, the implementer must ensure that x.compareTo(y)==0 implies that sgn(x.compareTo(z)) == sgn(y.compareTo(z)), for all z.
It is strongly recommended, but not strictly required that (x.compareTo(y)==0) == (x.equals(y)). Generally speaking, any class that implements the Comparable interface and violates this condition should clearly indicate this fact. The recommended language is "Note: this class has a natural ordering that is inconsistent with equals."
Calendar to the specified
Object. The result is true if and only if
the argument is a Calendar object of the same calendar
system that represents the same time value (millisecond offset from the
Epoch) under the same
Calendar parameters as this object.
The Calendar parameters are the values represented
by the isLenient, getFirstDayOfWeek,
getMinimalDaysInFirstWeek and getTimeZone
methods. If there is any difference in those parameters
between the two Calendars, this method returns
false.
Use the compareTo method to compare only the time values.
Calendar. For example, the actual maximum value of
the MONTH field is 12 in some years, and 13 in
other years in the Hebrew calendar system.
The default implementation of this method uses an iterative algorithm to determine the actual maximum value for the calendar field. Subclasses should, if possible, override this with a more efficient implementation.
Calendar.
The default implementation of this method uses an iterative
algorithm to determine the actual minimum value for the
calendar field. Subclasses should, if possible, override this
with a more efficient implementation - in many cases, they can
simply return getMinimum().
getInstance
methods of this class can return localized instances.
The array returned must contain at least a Locale
instance equal to Locale.US
.SUNDAY in the U.S.,
MONDAY in France.Calendar returned is based on the current time
in the default time zone with the default locale.Calendar returned is based on the current time
in the default time zone with the given locale.Calendar returned is based on the current time
in the given time zone with the default locale.Calendar returned is based on the current time
in the given time zone with the given locale.Calendar instance. The lowest maximum
value is defined as the smallest value returned by
for any possible time value. The least
maximum value depends on calendar system specific parameters of
the instance. For example, a Calendar for the
Gregorian calendar system returns 28 for the
DAY_OF_MONTH field, because the 28th is the last
day of the shortest month of this calendar, February in a
common year.Calendar instance. The maximum value is defined as
the largest value returned by the get
method
for any possible time value. The maximum value depends on
calendar system specific parameters of the instance.Calendar instance. The minimum value is defined as
the smallest value returned by the get
method
for any possible time value. The minimum value depends on
calendar system specific parameters of the instance.get method call.wait methods.
The awakened thread will not be able to proceed until the current thread relinquishes the lock on this object. The awakened thread will compete in the usual manner with any other threads that might be actively competing to synchronize on this object; for example, the awakened thread enjoys no reliable privilege or disadvantage in being the next thread to lock this object.
This method should only be called by a thread that is the owner of this object's monitor. A thread becomes the owner of the object's monitor in one of three ways:
synchronized statement
that synchronizes on the object.
Class, by executing a
synchronized static method of that class.
Only one thread at a time can own an object's monitor.
wait methods.
The awakened threads will not be able to proceed until the current thread relinquishes the lock on this object. The awakened threads will compete in the usual manner with any other threads that might be actively competing to synchronize on this object; for example, the awakened threads enjoy no reliable privilege or disadvantage in being the next thread to lock this object.
This method should only be called by a thread that is the owner
of this object's monitor. See the notify method for a
description of the ways in which a thread can become the owner of
a monitor.
roll(Calendar.DATE, true).
When rolling on the year or Calendar.YEAR field, it will roll the year
value in the range between 1 and the value returned by calling
getMaximum(Calendar.YEAR).
When rolling on the month or Calendar.MONTH field, other fields like
date might conflict and, need to be changed. For instance,
rolling the month on the date 01/31/96 will result in 02/29/96.
When rolling on the hour-in-day or Calendar.HOUR_OF_DAY field, it will
roll the hour value in the range between 0 and 23, which is zero-based.
NOTE: This default implementation on Calendar just repeatedly calls the
version of roll()
that rolls by one unit. This may not
always do the right thing. For example, if the DAY_OF_MONTH field is 31,
rolling through February will leave it set to 28. The GregorianCalendar
version of this function takes care of this problem. Other subclasses
should also provide overrides of this function that do the right thing.
SUNDAY in the U.S.,
MONDAY in France.Date.
Note: Calling setTime() with
Date(Long.MAX_VALUE) or Date(Long.MIN_VALUE)
may yield incorrect field values from get().
null.
The current thread must own this object's monitor. The thread
releases ownership of this monitor and waits until another thread
notifies threads waiting on this object's monitor to wake up
either through a call to the notify method or the
notifyAll method. The thread then waits until it can
re-obtain ownership of the monitor and resumes execution.
As in the one argument version, interrupts and spurious wakeups are possible, and this method should always be used in a loop:
synchronized (obj) {
while (<condition does not hold>)
obj.wait();
... // Perform action appropriate to condition
}
This method should only be called by a thread that is the owner
of this object's monitor. See the notify method for a
description of the ways in which a thread can become the owner of
a monitor.The current thread must own this object's monitor.
This method causes the current thread (call it T) to place itself in the wait set for this object and then to relinquish any and all synchronization claims on this object. Thread T becomes disabled for thread scheduling purposes and lies dormant until one of four things happens:
A thread can also wake up without being notified, interrupted, or timing out, a so-called spurious wakeup. While this will rarely occur in practice, applications must guard against it by testing for the condition that should have caused the thread to be awakened, and continuing to wait if the condition is not satisfied. In other words, waits should always occur in loops, like this one:
synchronized (obj) {
while (<condition does not hold>)
obj.wait(timeout);
... // Perform action appropriate to condition
}
(For more information on this topic, see Section 3.2.3 in Doug Lea's
"Concurrent Programming in Java (Second Edition)" (Addison-Wesley,
2000), or Item 50 in Joshua Bloch's "Effective Java Programming
Language Guide" (Addison-Wesley, 2001).
If the current thread is interrupted by another thread while it is waiting, then an InterruptedException is thrown. This exception is not thrown until the lock status of this object has been restored as described above.
Note that the wait method, as it places the current thread into the wait set for this object, unlocks only this object; any other objects on which the current thread may be synchronized remain locked while the thread waits.
This method should only be called by a thread that is the owner
of this object's monitor. See the notify method for a
description of the ways in which a thread can become the owner of
a monitor.
This method is similar to the wait method of one
argument, but it allows finer control over the amount of time to
wait for a notification before giving up. The amount of real time,
measured in nanoseconds, is given by:
1000000*timeout+nanos
In all other respects, this method does the same thing as the method of one argument. In particular, wait(0, 0) means the same thing as wait(0).
The current thread must own this object's monitor. The thread releases ownership of this monitor and waits until either of the following two conditions has occurred:
notify method
or the notifyAll method.
timeout
milliseconds plus nanos nanoseconds arguments, has
elapsed.
The thread then waits until it can re-obtain ownership of the monitor and resumes execution.
As in the one argument version, interrupts and spurious wakeups are possible, and this method should always be used in a loop:
synchronized (obj) {
while (<condition does not hold>)
obj.wait(timeout, nanos);
... // Perform action appropriate to condition
}
This method should only be called by a thread that is the owner
of this object's monitor. See the notify method for a
description of the ways in which a thread can become the owner of
a monitor.