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/*
 * Copyright (c) 1996, 2011, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
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 *
 * This code 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 General Public License
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/*
 * (C) Copyright Taligent, Inc. 1996-1998 - All Rights Reserved
 * (C) Copyright IBM Corp. 1996-1998 - All Rights Reserved
 *
 *   The original version of this source code and documentation is copyrighted
 * and owned by Taligent, Inc., a wholly-owned subsidiary of IBM. These
 * materials are provided under terms of a License Agreement between Taligent
 * and Sun. This technology is protected by multiple US and International
 * patents. This notice and attribution to Taligent may not be removed.
 *   Taligent is a registered trademark of Taligent, Inc.
 *
 */

package java.util;

import java.io.IOException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.io.OptionalDataException;
import java.io.Serializable;
import java.security.AccessController;
import java.security.PrivilegedActionException;
import java.security.PrivilegedExceptionAction;
import java.text.DateFormat;
import java.text.DateFormatSymbols;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;

/**
 * The Calendar class is an abstract class that provides methods
 * for converting between a specific instant in time and a set of {@link
 * #fields 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. * *

Getting and Setting Calendar Field Values

* *

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. * *

Leniency

* *

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. * *

First Week

* * 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 Fields Resolution

* * When computing a date and time from the calendar fields, there * may be insufficient information for the computation (such as only * year and month with no day of month), or there may be inconsistent * information (such as Tuesday, July 15, 1996 (Gregorian) -- July 15, * 1996 is actually a Monday). 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 date 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
 * 
* * For the time of day fields: *
*
 * 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: *

    *
  1. 23:59 is the last minute of the day and 00:00 is the first * minute of the next day. Thus, 23:59 on Dec 31, 1999 < 00:00 on * Jan 1, 2000 < 00:01 on Jan 1, 2000. * *
  2. Although historically not precise, midnight also belongs to "am", * and noon belongs to "pm", so on the same day, * 12:00 am (midnight) < 12:01 am, and 12:00 pm (noon) < 12:01 pm *
* *

* 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 {@link DateFormat} * to format dates. * *

Field Manipulation

* * The calendar fields can be changed using three methods: * 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 f * after the call minus the value of field f before the * call is delta, modulo any overflow that has occurred in * field f. 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 * f is 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. HOUR is a smaller field than * DAY_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_MONTH is a larger field than * HOUR.

*
* *

Example: See {@link java.util.GregorianCalendar#roll(int, int)}. * *

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.

* * @see java.lang.System#currentTimeMillis() * @see Date * @see GregorianCalendar * @see TimeZone * @see java.text.DateFormat * @author Mark Davis, David Goldsmith, Chen-Lieh Huang, Alan Liu * @since JDK1.1 */ public abstract class Calendar implements Serializable, Cloneable, Comparable { // Data flow in Calendar // --------------------- // The current time is represented in two ways by Calendar: as UTC // milliseconds from the epoch (1 January 1970 0:00 UTC), and as local // fields such as MONTH, HOUR, AM_PM, etc. It is possible to compute the // millis from the fields, and vice versa. The data needed to do this // conversion is encapsulated by a TimeZone object owned by the Calendar. // The data provided by the TimeZone object may also be overridden if the // user sets the ZONE_OFFSET and/or DST_OFFSET fields directly. The class // keeps track of what information was most recently set by the caller, and // uses that to compute any other information as needed. // If the user sets the fields using set(), the data flow is as follows. // This is implemented by the Calendar subclass's computeTime() method. // During this process, certain fields may be ignored. The disambiguation // algorithm for resolving which fields to pay attention to is described // in the class documentation. // local fields (YEAR, MONTH, DATE, HOUR, MINUTE, etc.) // | // | Using Calendar-specific algorithm // V // local standard millis // | // | Using TimeZone or user-set ZONE_OFFSET / DST_OFFSET // V // UTC millis (in time data member) // If the user sets the UTC millis using setTime() or setTimeInMillis(), // the data flow is as follows. This is implemented by the Calendar // subclass's computeFields() method. // UTC millis (in time data member) // | // | Using TimeZone getOffset() // V // local standard millis // | // | Using Calendar-specific algorithm // V // local fields (YEAR, MONTH, DATE, HOUR, MINUTE, etc.) // In general, a round trip from fields, through local and UTC millis, and // back out to fields is made when necessary. This is implemented by the // complete() method. Resolving a partial set of fields into a UTC millis // value allows all remaining fields to be generated from that value. If // the Calendar is lenient, the fields are also renormalized to standard // ranges when they are regenerated. /** * Field number for get and set indicating the * era, e.g., AD or BC in the Julian calendar. This is a calendar-specific * value; see subclass documentation. * * @see GregorianCalendar#AD * @see GregorianCalendar#BC */ public final static int ERA = 0; /** * Field number for get and set indicating the * year. This is a calendar-specific value; see subclass documentation. */ public final static int YEAR = 1; /** * Field number for get and set indicating the * month. This is a calendar-specific value. The first month of * the year in the Gregorian and Julian calendars is * JANUARY which is 0; the last depends on the number * of months in a year. * * @see #JANUARY * @see #FEBRUARY * @see #MARCH * @see #APRIL * @see #MAY * @see #JUNE * @see #JULY * @see #AUGUST * @see #SEPTEMBER * @see #OCTOBER * @see #NOVEMBER * @see #DECEMBER * @see #UNDECIMBER */ public final static int MONTH = 2; /** * Field number for 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. * * @see #getFirstDayOfWeek * @see #getMinimalDaysInFirstWeek */ public final static int WEEK_OF_YEAR = 3; /** * Field number for 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. * * @see #getFirstDayOfWeek * @see #getMinimalDaysInFirstWeek */ public final static int WEEK_OF_MONTH = 4; /** * Field number for 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. * * @see #DAY_OF_MONTH */ public final static int DATE = 5; /** * Field number for get and set indicating the * day of the month. This is a synonym for DATE. * The first day of the month has value 1. * * @see #DATE */ public final static int DAY_OF_MONTH = 5; /** * Field number for get and set indicating the day * number within the current year. The first day of the year has value 1. */ public final static int DAY_OF_YEAR = 6; /** * Field number for get and set indicating the day * of the week. This field takes values SUNDAY, * MONDAY, TUESDAY, WEDNESDAY, * THURSDAY, FRIDAY, and SATURDAY. * * @see #SUNDAY * @see #MONDAY * @see #TUESDAY * @see #WEDNESDAY * @see #THURSDAY * @see #FRIDAY * @see #SATURDAY */ public final static int DAY_OF_WEEK = 7; /** * Field number for 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. * * @see #DAY_OF_WEEK * @see #WEEK_OF_MONTH */ public final static int DAY_OF_WEEK_IN_MONTH = 8; /** * Field number for 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. * * @see #AM * @see #PM * @see #HOUR */ public final static int AM_PM = 9; /** * Field number for 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. * * @see #AM_PM * @see #HOUR_OF_DAY */ public final static int HOUR = 10; /** * Field number for 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. * * @see #HOUR */ public final static int HOUR_OF_DAY = 11; /** * Field number for get and set indicating the * minute within the hour. * E.g., at 10:04:15.250 PM the MINUTE is 4. */ public final static int MINUTE = 12; /** * Field number for get and set indicating the * second within the minute. * E.g., at 10:04:15.250 PM the SECOND is 15. */ public final static int SECOND = 13; /** * Field number for get and set indicating the * millisecond within the second. * E.g., at 10:04:15.250 PM the MILLISECOND is 250. */ public final static int MILLISECOND = 14; /** * Field number for 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. */ public final static int ZONE_OFFSET = 15; /** * Field number for get and set indicating the * daylight saving 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. */ public final static int DST_OFFSET = 16; /** * The number of distinct fields recognized by get and set. * Field numbers range from 0..FIELD_COUNT-1. */ public final static int FIELD_COUNT = 17; /** * Value of the {@link #DAY_OF_WEEK} field indicating * Sunday. */ public final static int SUNDAY = 1; /** * Value of the {@link #DAY_OF_WEEK} field indicating * Monday. */ public final static int MONDAY = 2; /** * Value of the {@link #DAY_OF_WEEK} field indicating * Tuesday. */ public final static int TUESDAY = 3; /** * Value of the {@link #DAY_OF_WEEK} field indicating * Wednesday. */ public final static int WEDNESDAY = 4; /** * Value of the {@link #DAY_OF_WEEK} field indicating * Thursday. */ public final static int THURSDAY = 5; /** * Value of the {@link #DAY_OF_WEEK} field indicating * Friday. */ public final static int FRIDAY = 6; /** * Value of the {@link #DAY_OF_WEEK} field indicating * Saturday. */ public final static int SATURDAY = 7; /** * Value of the {@link #MONTH} field indicating the * first month of the year in the Gregorian and Julian calendars. */ public final static int JANUARY = 0; /** * Value of the {@link #MONTH} field indicating the * second month of the year in the Gregorian and Julian calendars. */ public final static int FEBRUARY = 1; /** * Value of the {@link #MONTH} field indicating the * third month of the year in the Gregorian and Julian calendars. */ public final static int MARCH = 2; /** * Value of the {@link #MONTH} field indicating the * fourth month of the year in the Gregorian and Julian calendars. */ public final static int APRIL = 3; /** * Value of the {@link #MONTH} field indicating the * fifth month of the year in the Gregorian and Julian calendars. */ public final static int MAY = 4; /** * Value of the {@link #MONTH} field indicating the * sixth month of the year in the Gregorian and Julian calendars. */ public final static int JUNE = 5; /** * Value of the {@link #MONTH} field indicating the * seventh month of the year in the Gregorian and Julian calendars. */ public final static int JULY = 6; /** * Value of the {@link #MONTH} field indicating the * eighth month of the year in the Gregorian and Julian calendars. */ public final static int AUGUST = 7; /** * Value of the {@link #MONTH} field indicating the * ninth month of the year in the Gregorian and Julian calendars. */ public final static int SEPTEMBER = 8; /** * Value of the {@link #MONTH} field indicating the * tenth month of the year in the Gregorian and Julian calendars. */ public final static int OCTOBER = 9; /** * Value of the {@link #MONTH} field indicating the * eleventh month of the year in the Gregorian and Julian calendars. */ public final static int NOVEMBER = 10; /** * Value of the {@link #MONTH} field indicating the * twelfth month of the year in the Gregorian and Julian calendars. */ public final static int DECEMBER = 11; /** * Value of the {@link #MONTH} field indicating the * thirteenth month of the year. Although GregorianCalendar * does not use this value, lunar calendars do. */ public final static int UNDECIMBER = 12; /** * Value of the {@link #AM_PM} field indicating the * period of the day from midnight to just before noon. */ public final static int AM = 0; /** * Value of the {@link #AM_PM} field indicating the * period of the day from noon to just before midnight. */ public final static int PM = 1; /** * A style specifier for {@link #getDisplayNames(int, int, Locale) * getDisplayNames} indicating names in all styles, such as * "January" and "Jan". * * @see #SHORT * @see #LONG * @since 1.6 */ public static final int ALL_STYLES = 0; /** * A style specifier for {@link #getDisplayName(int, int, Locale) * getDisplayName} and {@link #getDisplayNames(int, int, Locale) * getDisplayNames} indicating a short name, such as "Jan". * * @see #LONG * @since 1.6 */ public static final int SHORT = 1; /** * A style specifier for {@link #getDisplayName(int, int, Locale) * getDisplayName} and {@link #getDisplayNames(int, int, Locale) * getDisplayNames} indicating a long name, such as "January". * * @see #SHORT * @since 1.6 */ public static final int LONG = 2; // Internal notes: // Calendar contains two kinds of time representations: current "time" in // milliseconds, and a set of calendar "fields" representing the current time. // The two representations are usually in sync, but can get out of sync // as follows. // 1. Initially, no fields are set, and the time is invalid. // 2. If the time is set, all fields are computed and in sync. // 3. If a single field is set, the time is invalid. // Recomputation of the time and fields happens when the object needs // to return a result to the user, or use a result for a computation. /** * The calendar field values for the currently set time for this calendar. * This is an array of FIELD_COUNT integers, with index values * ERA through DST_OFFSET. * @serial */ protected int fields[]; /** * The flags which tell if a specified calendar field for the calendar is set. * A new object has no fields set. After the first call to a method * which generates the fields, they all remain set after that. * This is an array of FIELD_COUNT booleans, with index values * ERA through DST_OFFSET. * @serial */ protected boolean isSet[]; /** * Pseudo-time-stamps which specify when each field was set. There * are two special values, UNSET and COMPUTED. Values from * MINIMUM_USER_SET to Integer.MAX_VALUE are legal user set values. */ transient private int stamp[]; /** * The currently set time for this calendar, expressed in milliseconds after * January 1, 1970, 0:00:00 GMT. * @see #isTimeSet * @serial */ protected long time; /** * True if then the value of time is valid. * The time is made invalid by a change to an item of field[]. * @see #time * @serial */ protected boolean isTimeSet; /** * True if fields[] are in sync with the currently set time. * If false, then the next attempt to get the value of a field will * force a recomputation of all fields from the current value of * time. * @serial */ protected boolean areFieldsSet; /** * True if all fields have been set. * @serial */ transient boolean areAllFieldsSet; /** * True if this calendar allows out-of-range field values during computation * of time from fields[]. * @see #setLenient * @see #isLenient * @serial */ private boolean lenient = true; /** * The TimeZone used by this calendar. Calendar * uses the time zone data to translate between locale and GMT time. * @serial */ private TimeZone zone; /** * True if zone references to a shared TimeZone object. */ transient private boolean sharedZone = false; /** * The first day of the week, with possible values SUNDAY, * MONDAY, etc. This is a locale-dependent value. * @serial */ private int firstDayOfWeek; /** * The number of days required for the first week in a month or year, * with possible values from 1 to 7. This is a locale-dependent value. * @serial */ private int minimalDaysInFirstWeek; /** * Cache to hold the firstDayOfWeek and minimalDaysInFirstWeek * of a Locale. */ private static final ConcurrentMap cachedLocaleData = new ConcurrentHashMap(3); // Special values of stamp[] /** * The corresponding fields[] has no value. */ private static final int UNSET = 0; /** * The value of the corresponding fields[] has been calculated internally. */ private static final int COMPUTED = 1; /** * The value of the corresponding fields[] has been set externally. Stamp * values which are greater than 1 represents the (pseudo) time when the * corresponding fields[] value was set. */ private static final int MINIMUM_USER_STAMP = 2; /** * The mask value that represents all of the fields. */ static final int ALL_FIELDS = (1 << FIELD_COUNT) - 1; /** * The next available value for stamp[], an internal array. * This actually should not be written out to the stream, and will probably * be removed from the stream in the near future. In the meantime, * a value of MINIMUM_USER_STAMP should be used. * @serial */ private int nextStamp = MINIMUM_USER_STAMP; // the internal serial version which says which version was written // - 0 (default) for version up to JDK 1.1.5 // - 1 for version from JDK 1.1.6, which writes a correct 'time' value // as well as compatible values for other fields. This is a // transitional format. // - 2 (not implemented yet) a future version, in which fields[], // areFieldsSet, and isTimeSet become transient, and isSet[] is // removed. In JDK 1.1.6 we write a format compatible with version 2. static final int currentSerialVersion = 1; /** * The version of the serialized data on the stream. Possible values: *

*
0 or not present on stream
*
* JDK 1.1.5 or earlier. *
*
1
*
* JDK 1.1.6 or later. Writes a correct 'time' value * as well as compatible values for other fields. This is a * transitional format. *
*
* When streaming out this class, the most recent format * and the highest allowable serialVersionOnStream * is written. * @serial * @since JDK1.1.6 */ private int serialVersionOnStream = currentSerialVersion; // Proclaim serialization compatibility with JDK 1.1 static final long serialVersionUID = -1807547505821590642L; // Mask values for calendar fields final static int ERA_MASK = (1 << ERA); final static int YEAR_MASK = (1 << YEAR); final static int MONTH_MASK = (1 << MONTH); final static int WEEK_OF_YEAR_MASK = (1 << WEEK_OF_YEAR); final static int WEEK_OF_MONTH_MASK = (1 << WEEK_OF_MONTH); final static int DAY_OF_MONTH_MASK = (1 << DAY_OF_MONTH); final static int DATE_MASK = DAY_OF_MONTH_MASK; final static int DAY_OF_YEAR_MASK = (1 << DAY_OF_YEAR); final static int DAY_OF_WEEK_MASK = (1 << DAY_OF_WEEK); final static int DAY_OF_WEEK_IN_MONTH_MASK = (1 << DAY_OF_WEEK_IN_MONTH); final static int AM_PM_MASK = (1 << AM_PM); final static int HOUR_MASK = (1 << HOUR); final static int HOUR_OF_DAY_MASK = (1 << HOUR_OF_DAY); final static int MINUTE_MASK = (1 << MINUTE); final static int SECOND_MASK = (1 << SECOND); final static int MILLISECOND_MASK = (1 << MILLISECOND); final static int ZONE_OFFSET_MASK = (1 << ZONE_OFFSET); final static int DST_OFFSET_MASK = (1 << DST_OFFSET); /** * Constructs a Calendar with the default time zone * and locale. * @see TimeZone#getDefault */ protected Calendar() { this(TimeZone.getDefaultRef(), Locale.getDefault(Locale.Category.FORMAT)); sharedZone = true; } /** * Constructs a calendar with the specified time zone and locale. * * @param zone the time zone to use * @param aLocale the locale for the week data */ protected Calendar(TimeZone zone, Locale aLocale) { fields = new int[FIELD_COUNT]; isSet = new boolean[FIELD_COUNT]; stamp = new int[FIELD_COUNT]; this.zone = zone; setWeekCountData(aLocale); } /** * Gets a calendar using the default time zone and locale. The * Calendar returned is based on the current time * in the default time zone with the default locale. * * @return a Calendar. */ public static Calendar getInstance() { Calendar cal = createCalendar(TimeZone.getDefaultRef(), Locale.getDefault(Locale.Category.FORMAT)); cal.sharedZone = true; return cal; } /** * Gets a calendar using the specified time zone and default locale. * The Calendar returned is based on the current time * in the given time zone with the default locale. * * @param zone the time zone to use * @return a Calendar. */ public static Calendar getInstance(TimeZone zone) { return createCalendar(zone, Locale.getDefault(Locale.Category.FORMAT)); } /** * Gets a calendar using the default time zone and specified locale. * The Calendar returned is based on the current time * in the default time zone with the given locale. * * @param aLocale the locale for the week data * @return a Calendar. */ public static Calendar getInstance(Locale aLocale) { Calendar cal = createCalendar(TimeZone.getDefaultRef(), aLocale); cal.sharedZone = true; return cal; } /** * Gets a calendar with the specified time zone and locale. * The Calendar returned is based on the current time * in the given time zone with the given locale. * * @param zone the time zone to use * @param aLocale the locale for the week data * @return a Calendar. */ public static Calendar getInstance(TimeZone zone, Locale aLocale) { return createCalendar(zone, aLocale); } private static Calendar createCalendar(TimeZone zone, Locale aLocale) { Calendar cal = null; String caltype = aLocale.getUnicodeLocaleType("ca"); if (caltype == null) { // Calendar type is not specified. // If the specified locale is a Thai locale, // returns a BuddhistCalendar instance. if ("th".equals(aLocale.getLanguage()) && ("TH".equals(aLocale.getCountry()))) { // cal = new BuddhistCalendar(zone, aLocale); } else { // cal = new GregorianCalendar(zone, aLocale); } } else if (caltype.equals("japanese")) { // cal = new JapaneseImperialCalendar(zone, aLocale); } else if (caltype.equals("buddhist")) { // cal = new BuddhistCalendar(zone, aLocale); } else { // Unsupported calendar type. // Use Gregorian calendar as a fallback. // cal = new GregorianCalendar(zone, aLocale); } return cal; } /** * Returns an array of all locales for which the getInstance * methods of this class can return localized instances. * The array returned must contain at least a Locale * instance equal to {@link java.util.Locale#US Locale.US}. * * @return An array of locales for which localized * Calendar instances are available. */ public static synchronized Locale[] getAvailableLocales() { return DateFormat.getAvailableLocales(); } /** * Converts the current calendar field values in {@link #fields fields[]} * to the millisecond time value * {@link #time}. * * @see #complete() * @see #computeFields() */ protected abstract void computeTime(); /** * Converts the current millisecond time value {@link #time} * to calendar field values in {@link #fields fields[]}. * This allows you to sync up the calendar field values with * a new time that is set for the calendar. The time is not * recomputed first; to recompute the time, then the fields, call the * {@link #complete()} method. * * @see #computeTime() */ protected abstract void computeFields(); /** * Returns a Date object representing this * Calendar's time value (millisecond offset from the Epoch"). * * @return a Date representing the time value. * @see #setTime(Date) * @see #getTimeInMillis() */ public final Date getTime() { return new Date(getTimeInMillis()); } /** * Sets this Calendar's time with the given Date. *

* Note: Calling setTime() with * Date(Long.MAX_VALUE) or Date(Long.MIN_VALUE) * may yield incorrect field values from get(). * * @param date the given Date. * @see #getTime() * @see #setTimeInMillis(long) */ public final void setTime(Date date) { setTimeInMillis(date.getTime()); } /** * Returns this Calendar's time value in milliseconds. * * @return the current time as UTC milliseconds from the epoch. * @see #getTime() * @see #setTimeInMillis(long) */ public long getTimeInMillis() { if (!isTimeSet) { updateTime(); } return time; } /** * Sets this Calendar's current time from the given long value. * * @param millis the new time in UTC milliseconds from the epoch. * @see #setTime(Date) * @see #getTimeInMillis() */ public void setTimeInMillis(long millis) { // If we don't need to recalculate the calendar field values, // do nothing. // if (time == millis && isTimeSet && areFieldsSet && areAllFieldsSet // && (zone instanceof ZoneInfo) && !((ZoneInfo)zone).isDirty()) { // return; // } time = millis; isTimeSet = true; areFieldsSet = false; computeFields(); areAllFieldsSet = areFieldsSet = true; } /** * Returns the value of the given calendar field. In lenient mode, * all calendar fields are normalized. In non-lenient mode, all * calendar fields are validated and this method throws an * exception if any calendar fields have out-of-range values. The * normalization and validation are handled by the * {@link #complete()} method, which process is calendar * system dependent. * * @param field the given calendar field. * @return the value for the given calendar field. * @throws ArrayIndexOutOfBoundsException if the specified field is out of range * (field < 0 || field >= FIELD_COUNT). * @see #set(int,int) * @see #complete() */ public int get(int field) { complete(); return internalGet(field); } /** * Returns the value of the given calendar field. This method does * not involve normalization or validation of the field value. * * @param field the given calendar field. * @return the value for the given calendar field. * @see #get(int) */ protected final int internalGet(int field) { return fields[field]; } /** * Sets the value of the given calendar field. This method does * not affect any setting state of the field in this * Calendar instance. * * @throws IndexOutOfBoundsException if the specified field is out of range * (field < 0 || field >= FIELD_COUNT). * @see #areFieldsSet * @see #isTimeSet * @see #areAllFieldsSet * @see #set(int,int) */ final void internalSet(int field, int value) { fields[field] = value; } /** * Sets the given calendar field to the given value. The value is not * interpreted by this method regardless of the leniency mode. * * @param field the given calendar field. * @param value the value to be set for the given calendar field. * @throws ArrayIndexOutOfBoundsException if the specified field is out of range * (field < 0 || field >= FIELD_COUNT). * in non-lenient mode. * @see #set(int,int,int) * @see #set(int,int,int,int,int) * @see #set(int,int,int,int,int,int) * @see #get(int) */ public void set(int field, int value) { // If the fields are partially normalized, calculate all the // fields before changing any fields. if (areFieldsSet && !areAllFieldsSet) { computeFields(); } internalSet(field, value); isTimeSet = false; areFieldsSet = false; isSet[field] = true; stamp[field] = nextStamp++; if (nextStamp == Integer.MAX_VALUE) { adjustStamp(); } } /** * Sets the values for the calendar fields YEAR, * MONTH, and DAY_OF_MONTH. * Previous values of other calendar fields are retained. If this is not desired, * call {@link #clear()} first. * * @param year the value used to set the YEAR calendar field. * @param month the value used to set the MONTH calendar field. * Month value is 0-based. e.g., 0 for January. * @param date the value used to set the DAY_OF_MONTH calendar field. * @see #set(int,int) * @see #set(int,int,int,int,int) * @see #set(int,int,int,int,int,int) */ public final void set(int year, int month, int date) { set(YEAR, year); set(MONTH, month); set(DATE, date); } /** * Sets the values for the calendar fields YEAR, * MONTH, DAY_OF_MONTH, * HOUR_OF_DAY, and MINUTE. * Previous values of other fields are retained. If this is not desired, * call {@link #clear()} first. * * @param year the value used to set the YEAR calendar field. * @param month the value used to set the MONTH calendar field. * Month value is 0-based. e.g., 0 for January. * @param date the value used to set the DAY_OF_MONTH calendar field. * @param hourOfDay the value used to set the HOUR_OF_DAY calendar field. * @param minute the value used to set the MINUTE calendar field. * @see #set(int,int) * @see #set(int,int,int) * @see #set(int,int,int,int,int,int) */ public final void set(int year, int month, int date, int hourOfDay, int minute) { set(YEAR, year); set(MONTH, month); set(DATE, date); set(HOUR_OF_DAY, hourOfDay); set(MINUTE, minute); } /** * Sets the values for the fields YEAR, MONTH, * DAY_OF_MONTH, HOUR, MINUTE, and * SECOND. * Previous values of other fields are retained. If this is not desired, * call {@link #clear()} first. * * @param year the value used to set the YEAR calendar field. * @param month the value used to set the MONTH calendar field. * Month value is 0-based. e.g., 0 for January. * @param date the value used to set the DAY_OF_MONTH calendar field. * @param hourOfDay the value used to set the HOUR_OF_DAY calendar field. * @param minute the value used to set the MINUTE calendar field. * @param second the value used to set the SECOND calendar field. * @see #set(int,int) * @see #set(int,int,int) * @see #set(int,int,int,int,int) */ public final void set(int year, int month, int date, int hourOfDay, int minute, int second) { set(YEAR, year); set(MONTH, month); set(DATE, date); set(HOUR_OF_DAY, hourOfDay); set(MINUTE, minute); set(SECOND, second); } /** * Sets all the calendar field values and the time value * (millisecond offset from the Epoch) of * this Calendar undefined. This means that {@link * #isSet(int) 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. * * @see #clear(int) */ public final void clear() { for (int i = 0; i < fields.length; ) { stamp[i] = fields[i] = 0; // UNSET == 0 isSet[i++] = false; } areAllFieldsSet = areFieldsSet = false; isTimeSet = false; } /** * Sets the given calendar field value and the time value * (millisecond offset from the Epoch) of * this Calendar undefined. This means that {@link * #isSet(int) 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 {@link #HOUR_OF_DAY}, {@link #HOUR} and {@link #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 {@link * #set(int,int) set(Calendar.HOUR_OF_DAY, 0)} to reset the hour * value. * * @param field the calendar field to be cleared. * @see #clear() */ public final void clear(int field) { fields[field] = 0; stamp[field] = UNSET; isSet[field] = false; areAllFieldsSet = areFieldsSet = false; isTimeSet = false; } /** * Determines if the given calendar field has a value set, * including cases that the value has been set by internal fields * calculations triggered by a get method call. * * @return true if the given calendar field has a value set; * false otherwise. */ public final boolean isSet(int field) { return stamp[field] != UNSET; } /** * Returns the string representation of the calendar * field value in the given style and * locale. If no string representation is * applicable, null is returned. This method calls * {@link Calendar#get(int) get(field)} to get the calendar * field value if the string representation is * applicable to the given calendar field. * *

For example, if this Calendar is a * GregorianCalendar and its date is 2005-01-01, then * the string representation of the {@link #MONTH} field would be * "January" in the long style in an English locale or "Jan" in * the short style. However, no string representation would be * available for the {@link #DAY_OF_MONTH} field, and this method * would return null. * *

The default implementation supports the calendar fields for * which a {@link DateFormatSymbols} has names in the given * locale. * * @param field * the calendar field for which the string representation * is returned * @param style * the style applied to the string representation; one of * {@link #SHORT} or {@link #LONG}. * @param locale * the locale for the string representation * @return the string representation of the given * field in the given style, or * null if no string representation is * applicable. * @exception IllegalArgumentException * if field or style is invalid, * or if this Calendar is non-lenient and any * of the calendar fields have invalid values * @exception NullPointerException * if locale is null * @since 1.6 */ public String getDisplayName(int field, int style, Locale locale) { if (!checkDisplayNameParams(field, style, ALL_STYLES, LONG, locale, ERA_MASK|MONTH_MASK|DAY_OF_WEEK_MASK|AM_PM_MASK)) { return null; } DateFormatSymbols symbols = DateFormatSymbols.getInstance(locale); String[] strings = getFieldStrings(field, style, symbols); if (strings != null) { int fieldValue = get(field); if (fieldValue < strings.length) { return strings[fieldValue]; } } return null; } /** * Returns a Map containing all names of the calendar * field in the given style and * locale and their corresponding field values. For * example, if this Calendar is a {@link * GregorianCalendar}, the returned map would contain "Jan" to * {@link #JANUARY}, "Feb" to {@link #FEBRUARY}, and so on, in the * {@linkplain #SHORT short} style in an English locale. * *

The values of other calendar fields may be taken into * account to determine a set of display names. For example, if * this Calendar is a lunisolar calendar system and * the year value given by the {@link #YEAR} field has a leap * month, this method would return month names containing the leap * month name, and month names are mapped to their values specific * for the year. * *

The default implementation supports display names contained in * a {@link DateFormatSymbols}. For example, if field * is {@link #MONTH} and style is {@link * #ALL_STYLES}, this method returns a Map containing * all strings returned by {@link DateFormatSymbols#getShortMonths()} * and {@link DateFormatSymbols#getMonths()}. * * @param field * the calendar field for which the display names are returned * @param style * the style applied to the display names; one of {@link * #SHORT}, {@link #LONG}, or {@link #ALL_STYLES}. * @param locale * the locale for the display names * @return a Map containing all display names in * style and locale and their * field values, or null if no display names * are defined for field * @exception IllegalArgumentException * if field or style is invalid, * or if this Calendar is non-lenient and any * of the calendar fields have invalid values * @exception NullPointerException * if locale is null * @since 1.6 */ public Map getDisplayNames(int field, int style, Locale locale) { if (!checkDisplayNameParams(field, style, ALL_STYLES, LONG, locale, ERA_MASK|MONTH_MASK|DAY_OF_WEEK_MASK|AM_PM_MASK)) { return null; } // ALL_STYLES if (style == ALL_STYLES) { Map shortNames = getDisplayNamesImpl(field, SHORT, locale); if (field == ERA || field == AM_PM) { return shortNames; } Map longNames = getDisplayNamesImpl(field, LONG, locale); if (shortNames == null) { return longNames; } if (longNames != null) { shortNames.putAll(longNames); } return shortNames; } // SHORT or LONG return getDisplayNamesImpl(field, style, locale); } private Map getDisplayNamesImpl(int field, int style, Locale locale) { DateFormatSymbols symbols = DateFormatSymbols.getInstance(locale); String[] strings = getFieldStrings(field, style, symbols); if (strings != null) { Map names = new HashMap(); for (int i = 0; i < strings.length; i++) { if (strings[i].length() == 0) { continue; } names.put(strings[i], i); } return names; } return null; } boolean checkDisplayNameParams(int field, int style, int minStyle, int maxStyle, Locale locale, int fieldMask) { if (field < 0 || field >= fields.length || style < minStyle || style > maxStyle) { throw new IllegalArgumentException(); } if (locale == null) { throw new NullPointerException(); } return isFieldSet(fieldMask, field); } private String[] getFieldStrings(int field, int style, DateFormatSymbols symbols) { String[] strings = null; switch (field) { case ERA: strings = symbols.getEras(); break; case MONTH: strings = (style == LONG) ? symbols.getMonths() : symbols.getShortMonths(); break; case DAY_OF_WEEK: strings = (style == LONG) ? symbols.getWeekdays() : symbols.getShortWeekdays(); break; case AM_PM: strings = symbols.getAmPmStrings(); break; } return strings; } /** * Fills in any unset fields in the calendar fields. First, the {@link * #computeTime()} method is called if the time value (millisecond offset * from the Epoch) has not been calculated from * calendar field values. Then, the {@link #computeFields()} method is * called to calculate all calendar field values. */ protected void complete() { if (!isTimeSet) updateTime(); if (!areFieldsSet || !areAllFieldsSet) { computeFields(); // fills in unset fields areAllFieldsSet = areFieldsSet = true; } } /** * Returns whether the value of the specified calendar field has been set * externally by calling one of the setter methods rather than by the * internal time calculation. * * @return true if the field has been set externally, * false otherwise. * @exception IndexOutOfBoundsException if the specified * field is out of range * (field < 0 || field >= FIELD_COUNT). * @see #selectFields() * @see #setFieldsComputed(int) */ final boolean isExternallySet(int field) { return stamp[field] >= MINIMUM_USER_STAMP; } /** * Returns a field mask (bit mask) indicating all calendar fields that * have the state of externally or internally set. * * @return a bit mask indicating set state fields */ final int getSetStateFields() { int mask = 0; for (int i = 0; i < fields.length; i++) { if (stamp[i] != UNSET) { mask |= 1 << i; } } return mask; } /** * Sets the state of the specified calendar fields to * computed. This state means that the specified calendar fields * have valid values that have been set by internal time calculation * rather than by calling one of the setter methods. * * @param fieldMask the field to be marked as computed. * @exception IndexOutOfBoundsException if the specified * field is out of range * (field < 0 || field >= FIELD_COUNT). * @see #isExternallySet(int) * @see #selectFields() */ final void setFieldsComputed(int fieldMask) { if (fieldMask == ALL_FIELDS) { for (int i = 0; i < fields.length; i++) { stamp[i] = COMPUTED; isSet[i] = true; } areFieldsSet = areAllFieldsSet = true; } else { for (int i = 0; i < fields.length; i++) { if ((fieldMask & 1) == 1) { stamp[i] = COMPUTED; isSet[i] = true; } else { if (areAllFieldsSet && !isSet[i]) { areAllFieldsSet = false; } } fieldMask >>>= 1; } } } /** * Sets the state of the calendar fields that are not specified * by fieldMask to unset. If fieldMask * specifies all the calendar fields, then the state of this * Calendar becomes that all the calendar fields are in sync * with the time value (millisecond offset from the Epoch). * * @param fieldMask the field mask indicating which calendar fields are in * sync with the time value. * @exception IndexOutOfBoundsException if the specified * field is out of range * (field < 0 || field >= FIELD_COUNT). * @see #isExternallySet(int) * @see #selectFields() */ final void setFieldsNormalized(int fieldMask) { if (fieldMask != ALL_FIELDS) { for (int i = 0; i < fields.length; i++) { if ((fieldMask & 1) == 0) { stamp[i] = fields[i] = 0; // UNSET == 0 isSet[i] = false; } fieldMask >>= 1; } } // Some or all of the fields are in sync with the // milliseconds, but the stamp values are not normalized yet. areFieldsSet = true; areAllFieldsSet = false; } /** * Returns whether the calendar fields are partially in sync with the time * value or fully in sync but not stamp values are not normalized yet. */ final boolean isPartiallyNormalized() { return areFieldsSet && !areAllFieldsSet; } /** * Returns whether the calendar fields are fully in sync with the time * value. */ final boolean isFullyNormalized() { return areFieldsSet && areAllFieldsSet; } /** * Marks this Calendar as not sync'd. */ final void setUnnormalized() { areFieldsSet = areAllFieldsSet = false; } /** * Returns whether the specified field is on in the * fieldMask. */ static final boolean isFieldSet(int fieldMask, int field) { return (fieldMask & (1 << field)) != 0; } /** * Returns a field mask indicating which calendar field values * to be used to calculate the time value. The calendar fields are * returned as a bit mask, each bit of which corresponds to a field, i.e., * the mask value of field is (1 << * field). For example, 0x26 represents the YEAR, * MONTH, and DAY_OF_MONTH fields (i.e., 0x26 is * equal to * (1<<YEAR)|(1<<MONTH)|(1<<DAY_OF_MONTH)). * *

This method supports the calendar fields resolution as described in * the class description. If the bit mask for a given field is on and its * field has not been set (i.e., isSet(field) is * false), then the default value of the field has to be * used, which case means that the field has been selected because the * selected combination involves the field. * * @return a bit mask of selected fields * @see #isExternallySet(int) * @see #setInternallySetState(int) */ final int selectFields() { // This implementation has been taken from the GregorianCalendar class. // The YEAR field must always be used regardless of its SET // state because YEAR is a mandatory field to determine the date // and the default value (EPOCH_YEAR) may change through the // normalization process. int fieldMask = YEAR_MASK; if (stamp[ERA] != UNSET) { fieldMask |= ERA_MASK; } // Find the most recent group of fields specifying the day within // the year. These may be any of the following combinations: // MONTH + DAY_OF_MONTH // MONTH + WEEK_OF_MONTH + DAY_OF_WEEK // MONTH + DAY_OF_WEEK_IN_MONTH + DAY_OF_WEEK // DAY_OF_YEAR // WEEK_OF_YEAR + DAY_OF_WEEK // We look for the most recent of the fields in each group to determine // the age of the group. For groups involving a week-related field such // as WEEK_OF_MONTH, DAY_OF_WEEK_IN_MONTH, or WEEK_OF_YEAR, both the // week-related field and the DAY_OF_WEEK must be set for the group as a // whole to be considered. (See bug 4153860 - liu 7/24/98.) int dowStamp = stamp[DAY_OF_WEEK]; int monthStamp = stamp[MONTH]; int domStamp = stamp[DAY_OF_MONTH]; int womStamp = aggregateStamp(stamp[WEEK_OF_MONTH], dowStamp); int dowimStamp = aggregateStamp(stamp[DAY_OF_WEEK_IN_MONTH], dowStamp); int doyStamp = stamp[DAY_OF_YEAR]; int woyStamp = aggregateStamp(stamp[WEEK_OF_YEAR], dowStamp); int bestStamp = domStamp; if (womStamp > bestStamp) { bestStamp = womStamp; } if (dowimStamp > bestStamp) { bestStamp = dowimStamp; } if (doyStamp > bestStamp) { bestStamp = doyStamp; } if (woyStamp > bestStamp) { bestStamp = woyStamp; } /* No complete combination exists. Look for WEEK_OF_MONTH, * DAY_OF_WEEK_IN_MONTH, or WEEK_OF_YEAR alone. Treat DAY_OF_WEEK alone * as DAY_OF_WEEK_IN_MONTH. */ if (bestStamp == UNSET) { womStamp = stamp[WEEK_OF_MONTH]; dowimStamp = Math.max(stamp[DAY_OF_WEEK_IN_MONTH], dowStamp); woyStamp = stamp[WEEK_OF_YEAR]; bestStamp = Math.max(Math.max(womStamp, dowimStamp), woyStamp); /* Treat MONTH alone or no fields at all as DAY_OF_MONTH. This may * result in bestStamp = domStamp = UNSET if no fields are set, * which indicates DAY_OF_MONTH. */ if (bestStamp == UNSET) { bestStamp = domStamp = monthStamp; } } if (bestStamp == domStamp || (bestStamp == womStamp && stamp[WEEK_OF_MONTH] >= stamp[WEEK_OF_YEAR]) || (bestStamp == dowimStamp && stamp[DAY_OF_WEEK_IN_MONTH] >= stamp[WEEK_OF_YEAR])) { fieldMask |= MONTH_MASK; if (bestStamp == domStamp) { fieldMask |= DAY_OF_MONTH_MASK; } else { assert (bestStamp == womStamp || bestStamp == dowimStamp); if (dowStamp != UNSET) { fieldMask |= DAY_OF_WEEK_MASK; } if (womStamp == dowimStamp) { // When they are equal, give the priority to // WEEK_OF_MONTH for compatibility. if (stamp[WEEK_OF_MONTH] >= stamp[DAY_OF_WEEK_IN_MONTH]) { fieldMask |= WEEK_OF_MONTH_MASK; } else { fieldMask |= DAY_OF_WEEK_IN_MONTH_MASK; } } else { if (bestStamp == womStamp) { fieldMask |= WEEK_OF_MONTH_MASK; } else { assert (bestStamp == dowimStamp); if (stamp[DAY_OF_WEEK_IN_MONTH] != UNSET) { fieldMask |= DAY_OF_WEEK_IN_MONTH_MASK; } } } } } else { assert (bestStamp == doyStamp || bestStamp == woyStamp || bestStamp == UNSET); if (bestStamp == doyStamp) { fieldMask |= DAY_OF_YEAR_MASK; } else { assert (bestStamp == woyStamp); if (dowStamp != UNSET) { fieldMask |= DAY_OF_WEEK_MASK; } fieldMask |= WEEK_OF_YEAR_MASK; } } // Find the best set of fields specifying the time of day. There // are only two possibilities here; the HOUR_OF_DAY or the // AM_PM and the HOUR. int hourOfDayStamp = stamp[HOUR_OF_DAY]; int hourStamp = aggregateStamp(stamp[HOUR], stamp[AM_PM]); bestStamp = (hourStamp > hourOfDayStamp) ? hourStamp : hourOfDayStamp; // if bestStamp is still UNSET, then take HOUR or AM_PM. (See 4846659) if (bestStamp == UNSET) { bestStamp = Math.max(stamp[HOUR], stamp[AM_PM]); } // Hours if (bestStamp != UNSET) { if (bestStamp == hourOfDayStamp) { fieldMask |= HOUR_OF_DAY_MASK; } else { fieldMask |= HOUR_MASK; if (stamp[AM_PM] != UNSET) { fieldMask |= AM_PM_MASK; } } } if (stamp[MINUTE] != UNSET) { fieldMask |= MINUTE_MASK; } if (stamp[SECOND] != UNSET) { fieldMask |= SECOND_MASK; } if (stamp[MILLISECOND] != UNSET) { fieldMask |= MILLISECOND_MASK; } if (stamp[ZONE_OFFSET] >= MINIMUM_USER_STAMP) { fieldMask |= ZONE_OFFSET_MASK; } if (stamp[DST_OFFSET] >= MINIMUM_USER_STAMP) { fieldMask |= DST_OFFSET_MASK; } return fieldMask; } /** * Returns the pseudo-time-stamp for two fields, given their * individual pseudo-time-stamps. If either of the fields * is unset, then the aggregate is unset. Otherwise, the * aggregate is the later of the two stamps. */ private static final int aggregateStamp(int stamp_a, int stamp_b) { if (stamp_a == UNSET || stamp_b == UNSET) { return UNSET; } return (stamp_a > stamp_b) ? stamp_a : stamp_b; } /** * Compares this 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 {@link #compareTo(Calendar) compareTo} method to * compare only the time values. * * @param obj the object to compare with. * @return true if this object is equal to obj; * false otherwise. */ public boolean equals(Object obj) { if (this == obj) return true; try { Calendar that = (Calendar)obj; return compareTo(getMillisOf(that)) == 0 && lenient == that.lenient && firstDayOfWeek == that.firstDayOfWeek && minimalDaysInFirstWeek == that.minimalDaysInFirstWeek && zone.equals(that.zone); } catch (Exception e) { // Note: GregorianCalendar.computeTime throws // IllegalArgumentException if the ERA value is invalid // even it's in lenient mode. } return false; } /** * Returns a hash code for this calendar. * * @return a hash code value for this object. * @since 1.2 */ public int hashCode() { // 'otheritems' represents the hash code for the previous versions. int otheritems = (lenient ? 1 : 0) | (firstDayOfWeek << 1) | (minimalDaysInFirstWeek << 4) | (zone.hashCode() << 7); long t = getMillisOf(this); return (int) t ^ (int)(t >> 32) ^ otheritems; } /** * Returns whether this Calendar represents a time * before the time represented by the specified * Object. This method is equivalent to: *

* compareTo(when) < 0 *
* if and only if when is a Calendar * instance. Otherwise, the method returns false. * * @param when the Object to be compared * @return true if the time of this * Calendar is before the time represented by * when; false otherwise. * @see #compareTo(Calendar) */ public boolean before(Object when) { return when instanceof Calendar && compareTo((Calendar)when) < 0; } /** * Returns whether this Calendar represents a time * after the time represented by the specified * Object. This method is equivalent to: *
* compareTo(when) > 0 *
* if and only if when is a Calendar * instance. Otherwise, the method returns false. * * @param when the Object to be compared * @return true if the time of this Calendar is * after the time represented by when; false * otherwise. * @see #compareTo(Calendar) */ public boolean after(Object when) { return when instanceof Calendar && compareTo((Calendar)when) > 0; } /** * Compares the time values (millisecond offsets from the Epoch) represented by two * Calendar objects. * * @param anotherCalendar the Calendar to be compared. * @return the value 0 if the time represented by the argument * is equal to the time represented by this Calendar; a value * less than 0 if the time of this Calendar is * before the time represented by the argument; and a value greater than * 0 if the time of this Calendar is after the * time represented by the argument. * @exception NullPointerException if the specified Calendar is * null. * @exception IllegalArgumentException if the time value of the * specified Calendar object can't be obtained due to * any invalid calendar values. * @since 1.5 */ public int compareTo(Calendar anotherCalendar) { return compareTo(getMillisOf(anotherCalendar)); } /** * Adds or subtracts the specified amount of time to the given calendar field, * based on the calendar's rules. For example, to subtract 5 days from * the current time of the calendar, you can achieve it by calling: *

add(Calendar.DAY_OF_MONTH, -5). * * @param field the calendar field. * @param amount the amount of date or time to be added to the field. * @see #roll(int,int) * @see #set(int,int) */ abstract public void add(int field, int amount); /** * Adds or subtracts (up/down) a single unit of time on the given time * field without changing larger fields. For example, to roll the current * date up by one day, you can achieve it by calling: *

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. * * @param field the time field. * @param up indicates if the value of the specified time field is to be * rolled up or rolled down. Use true if rolling up, false otherwise. * @see Calendar#add(int,int) * @see Calendar#set(int,int) */ abstract public void roll(int field, boolean up); /** * Adds the specified (signed) amount to the specified calendar field * without changing larger fields. A negative amount means to roll * down. * *

NOTE: This default implementation on Calendar just repeatedly calls the * version of {@link #roll(int,boolean) 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. * * @param field the calendar field. * @param amount the signed amount to add to the calendar field. * @since 1.2 * @see #roll(int,boolean) * @see #add(int,int) * @see #set(int,int) */ public void roll(int field, int amount) { while (amount > 0) { roll(field, true); amount--; } while (amount < 0) { roll(field, false); amount++; } } /** * Sets the time zone with the given time zone value. * * @param value the given time zone. */ public void setTimeZone(TimeZone value) { zone = value; sharedZone = false; /* Recompute the fields from the time using the new zone. This also * works if isTimeSet is false (after a call to set()). In that case * the time will be computed from the fields using the new zone, then * the fields will get recomputed from that. Consider the sequence of * calls: cal.setTimeZone(EST); cal.set(HOUR, 1); cal.setTimeZone(PST). * Is cal set to 1 o'clock EST or 1 o'clock PST? Answer: PST. More * generally, a call to setTimeZone() affects calls to set() BEFORE AND * AFTER it up to the next call to complete(). */ areAllFieldsSet = areFieldsSet = false; } /** * Gets the time zone. * * @return the time zone object associated with this calendar. */ public TimeZone getTimeZone() { // If the TimeZone object is shared by other Calendar instances, then // create a clone. if (sharedZone) { zone = (TimeZone) zone.clone(); sharedZone = false; } return zone; } /** * Returns the time zone (without cloning). */ TimeZone getZone() { return zone; } /** * Sets the sharedZone flag to shared. */ void setZoneShared(boolean shared) { sharedZone = shared; } /** * Specifies whether or not date/time interpretation is to be lenient. With * lenient interpretation, a date such as "February 942, 1996" will be * treated as being equivalent to the 941st day after February 1, 1996. * With strict (non-lenient) interpretation, such dates will cause an exception to be * thrown. The default is lenient. * * @param lenient true if the lenient mode is to be turned * on; false if it is to be turned off. * @see #isLenient() * @see java.text.DateFormat#setLenient */ public void setLenient(boolean lenient) { this.lenient = lenient; } /** * Tells whether date/time interpretation is to be lenient. * * @return true if the interpretation mode of this calendar is lenient; * false otherwise. * @see #setLenient(boolean) */ public boolean isLenient() { return lenient; } /** * Sets what the first day of the week is; e.g., SUNDAY in the U.S., * MONDAY in France. * * @param value the given first day of the week. * @see #getFirstDayOfWeek() * @see #getMinimalDaysInFirstWeek() */ public void setFirstDayOfWeek(int value) { if (firstDayOfWeek == value) { return; } firstDayOfWeek = value; invalidateWeekFields(); } /** * Gets what the first day of the week is; e.g., SUNDAY in the U.S., * MONDAY in France. * * @return the first day of the week. * @see #setFirstDayOfWeek(int) * @see #getMinimalDaysInFirstWeek() */ public int getFirstDayOfWeek() { return firstDayOfWeek; } /** * Sets what the minimal days required in the first week of the year are; * For example, if the first week is defined as one that contains the first * day of the first month of a year, call this method with value 1. If it * must be a full week, use value 7. * * @param value the given minimal days required in the first week * of the year. * @see #getMinimalDaysInFirstWeek() */ public void setMinimalDaysInFirstWeek(int value) { if (minimalDaysInFirstWeek == value) { return; } minimalDaysInFirstWeek = value; invalidateWeekFields(); } /** * Gets what the minimal days required in the first week of the year are; * e.g., if the first week is defined as one that contains the first day * of the first month of a year, this method returns 1. If * the minimal days required must be a full week, this method * returns 7. * * @return the minimal days required in the first week of the year. * @see #setMinimalDaysInFirstWeek(int) */ public int getMinimalDaysInFirstWeek() { return minimalDaysInFirstWeek; } /** * Returns whether this {@code Calendar} supports week dates. * *

The default implementation of this method returns {@code false}. * * @return {@code true} if this {@code Calendar} supports week dates; * {@code false} otherwise. * @see #getWeekYear() * @see #setWeekDate(int,int,int) * @see #getWeeksInWeekYear() * @since 1.7 */ public boolean isWeekDateSupported() { return false; } /** * Returns the week year represented by this {@code Calendar}. The * week year is in sync with the week cycle. The {@linkplain * #getFirstDayOfWeek() first day of the first week} is the first * day of the week year. * *

The default implementation of this method throws an * {@link UnsupportedOperationException}. * * @return the week year of this {@code Calendar} * @exception UnsupportedOperationException * if any week year numbering isn't supported * in this {@code Calendar}. * @see #isWeekDateSupported() * @see #getFirstDayOfWeek() * @see #getMinimalDaysInFirstWeek() * @since 1.7 */ public int getWeekYear() { throw new UnsupportedOperationException(); } /** * Sets the date of this {@code Calendar} with the the given date * specifiers - week year, week of year, and day of week. * *

Unlike the {@code set} method, all of the calendar fields * and {@code time} values are calculated upon return. * *

If {@code weekOfYear} is out of the valid week-of-year range * in {@code weekYear}, the {@code weekYear} and {@code * weekOfYear} values are adjusted in lenient mode, or an {@code * IllegalArgumentException} is thrown in non-lenient mode. * *

The default implementation of this method throws an * {@code UnsupportedOperationException}. * * @param weekYear the week year * @param weekOfYear the week number based on {@code weekYear} * @param dayOfWeek the day of week value: one of the constants * for the {@link #DAY_OF_WEEK} field: {@link * #SUNDAY}, ..., {@link #SATURDAY}. * @exception IllegalArgumentException * if any of the given date specifiers is invalid * or any of the calendar fields are inconsistent * with the given date specifiers in non-lenient mode * @exception UnsupportedOperationException * if any week year numbering isn't supported in this * {@code Calendar}. * @see #isWeekDateSupported() * @see #getFirstDayOfWeek() * @see #getMinimalDaysInFirstWeek() * @since 1.7 */ public void setWeekDate(int weekYear, int weekOfYear, int dayOfWeek) { throw new UnsupportedOperationException(); } /** * Returns the number of weeks in the week year represented by this * {@code Calendar}. * *

The default implementation of this method throws an * {@code UnsupportedOperationException}. * * @return the number of weeks in the week year. * @exception UnsupportedOperationException * if any week year numbering isn't supported in this * {@code Calendar}. * @see #WEEK_OF_YEAR * @see #isWeekDateSupported() * @see #getWeekYear() * @see #getActualMaximum(int) * @since 1.7 */ public int getWeeksInWeekYear() { throw new UnsupportedOperationException(); } /** * Returns the minimum value for the given calendar field of this * Calendar instance. The minimum value is defined as * the smallest value returned by the {@link #get(int) get} method * for any possible time value. The minimum value depends on * calendar system specific parameters of the instance. * * @param field the calendar field. * @return the minimum value for the given calendar field. * @see #getMaximum(int) * @see #getGreatestMinimum(int) * @see #getLeastMaximum(int) * @see #getActualMinimum(int) * @see #getActualMaximum(int) */ abstract public int getMinimum(int field); /** * Returns the maximum value for the given calendar field of this * Calendar instance. The maximum value is defined as * the largest value returned by the {@link #get(int) get} method * for any possible time value. The maximum value depends on * calendar system specific parameters of the instance. * * @param field the calendar field. * @return the maximum value for the given calendar field. * @see #getMinimum(int) * @see #getGreatestMinimum(int) * @see #getLeastMaximum(int) * @see #getActualMinimum(int) * @see #getActualMaximum(int) */ abstract public int getMaximum(int field); /** * Returns the highest minimum value for the given calendar field * of this Calendar instance. The highest minimum * value is defined as the largest value returned by {@link * #getActualMinimum(int)} for any possible time value. The * greatest minimum value depends on calendar system specific * parameters of the instance. * * @param field the calendar field. * @return the highest minimum value for the given calendar field. * @see #getMinimum(int) * @see #getMaximum(int) * @see #getLeastMaximum(int) * @see #getActualMinimum(int) * @see #getActualMaximum(int) */ abstract public int getGreatestMinimum(int field); /** * Returns the lowest maximum value for the given calendar field * of this Calendar instance. The lowest maximum * value is defined as the smallest value returned by {@link * #getActualMaximum(int)} 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. * * @param field the calendar field. * @return the lowest maximum value for the given calendar field. * @see #getMinimum(int) * @see #getMaximum(int) * @see #getGreatestMinimum(int) * @see #getActualMinimum(int) * @see #getActualMaximum(int) */ abstract public int getLeastMaximum(int field); /** * Returns the minimum value that the specified calendar field * could have, given the time value of this 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(). * * @param field the calendar field * @return the minimum of the given calendar field for the time * value of this Calendar * @see #getMinimum(int) * @see #getMaximum(int) * @see #getGreatestMinimum(int) * @see #getLeastMaximum(int) * @see #getActualMaximum(int) * @since 1.2 */ public int getActualMinimum(int field) { int fieldValue = getGreatestMinimum(field); int endValue = getMinimum(field); // if we know that the minimum value is always the same, just return it if (fieldValue == endValue) { return fieldValue; } // clone the calendar so we don't mess with the real one, and set it to // accept anything for the field values Calendar work = (Calendar)this.clone(); work.setLenient(true); // now try each value from getLeastMaximum() to getMaximum() one by one until // we get a value that normalizes to another value. The last value that // normalizes to itself is the actual minimum for the current date int result = fieldValue; do { work.set(field, fieldValue); if (work.get(field) != fieldValue) { break; } else { result = fieldValue; fieldValue--; } } while (fieldValue >= endValue); return result; } /** * Returns the maximum value that the specified calendar field * could have, given the time value of this * 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. * * @param field the calendar field * @return the maximum of the given calendar field for the time * value of this Calendar * @see #getMinimum(int) * @see #getMaximum(int) * @see #getGreatestMinimum(int) * @see #getLeastMaximum(int) * @see #getActualMinimum(int) * @since 1.2 */ public int getActualMaximum(int field) { int fieldValue = getLeastMaximum(field); int endValue = getMaximum(field); // if we know that the maximum value is always the same, just return it. if (fieldValue == endValue) { return fieldValue; } // clone the calendar so we don't mess with the real one, and set it to // accept anything for the field values. Calendar work = (Calendar)this.clone(); work.setLenient(true); // if we're counting weeks, set the day of the week to Sunday. We know the // last week of a month or year will contain the first day of the week. if (field == WEEK_OF_YEAR || field == WEEK_OF_MONTH) work.set(DAY_OF_WEEK, firstDayOfWeek); // now try each value from getLeastMaximum() to getMaximum() one by one until // we get a value that normalizes to another value. The last value that // normalizes to itself is the actual maximum for the current date int result = fieldValue; do { work.set(field, fieldValue); if (work.get(field) != fieldValue) { break; } else { result = fieldValue; fieldValue++; } } while (fieldValue <= endValue); return result; } /** * Creates and returns a copy of this object. * * @return a copy of this object. */ public Object clone() { try { Calendar other = (Calendar) super.clone(); other.fields = new int[FIELD_COUNT]; other.isSet = new boolean[FIELD_COUNT]; other.stamp = new int[FIELD_COUNT]; for (int i = 0; i < FIELD_COUNT; i++) { other.fields[i] = fields[i]; other.stamp[i] = stamp[i]; other.isSet[i] = isSet[i]; } other.zone = (TimeZone) zone.clone(); return other; } catch (CloneNotSupportedException e) { // this shouldn't happen, since we are Cloneable throw new InternalError(); } } private static final String[] FIELD_NAME = { "ERA", "YEAR", "MONTH", "WEEK_OF_YEAR", "WEEK_OF_MONTH", "DAY_OF_MONTH", "DAY_OF_YEAR", "DAY_OF_WEEK", "DAY_OF_WEEK_IN_MONTH", "AM_PM", "HOUR", "HOUR_OF_DAY", "MINUTE", "SECOND", "MILLISECOND", "ZONE_OFFSET", "DST_OFFSET" }; /** * Returns the name of the specified calendar field. * * @param field the calendar field * @return the calendar field name * @exception IndexOutOfBoundsException if field is negative, * equal to or greater then FIELD_COUNT. */ static final String getFieldName(int field) { return FIELD_NAME[field]; } /** * Return a string representation of this calendar. This method * is intended to be used only for debugging purposes, and the * format of the returned string may vary between implementations. * The returned string may be empty but may not be null. * * @return a string representation of this calendar. */ public String toString() { // NOTE: BuddhistCalendar.toString() interprets the string // produced by this method so that the Gregorian year number // is substituted by its B.E. year value. It relies on // "...,YEAR=,..." or "...,YEAR=?,...". StringBuilder buffer = new StringBuilder(800); buffer.append(getClass().getName()).append('['); appendValue(buffer, "time", isTimeSet, time); buffer.append(",areFieldsSet=").append(areFieldsSet); buffer.append(",areAllFieldsSet=").append(areAllFieldsSet); buffer.append(",lenient=").append(lenient); buffer.append(",zone=").append(zone); appendValue(buffer, ",firstDayOfWeek", true, (long) firstDayOfWeek); appendValue(buffer, ",minimalDaysInFirstWeek", true, (long) minimalDaysInFirstWeek); for (int i = 0; i < FIELD_COUNT; ++i) { buffer.append(','); appendValue(buffer, FIELD_NAME[i], isSet(i), (long) fields[i]); } buffer.append(']'); return buffer.toString(); } // =======================privates=============================== private static final void appendValue(StringBuilder sb, String item, boolean valid, long value) { sb.append(item).append('='); if (valid) { sb.append(value); } else { sb.append('?'); } } /** * Both firstDayOfWeek and minimalDaysInFirstWeek are locale-dependent. * They are used to figure out the week count for a specific date for * a given locale. These must be set when a Calendar is constructed. * @param desiredLocale the given locale. */ private void setWeekCountData(Locale desiredLocale) { /* try to get the Locale data from the cache */ int[] data = cachedLocaleData.get(desiredLocale); if (data == null) { /* cache miss */ // ResourceBundle bundle = LocaleData.getCalendarData(desiredLocale); data = new int[2]; // data[0] = Integer.parseInt(bundle.getString("firstDayOfWeek")); // data[1] = Integer.parseInt(bundle.getString("minimalDaysInFirstWeek")); cachedLocaleData.putIfAbsent(desiredLocale, data); } firstDayOfWeek = data[0]; minimalDaysInFirstWeek = data[1]; } /** * Recomputes the time and updates the status fields isTimeSet * and areFieldsSet. Callers should check isTimeSet and only * call this method if isTimeSet is false. */ private void updateTime() { computeTime(); // The areFieldsSet and areAllFieldsSet values are no longer // controlled here (as of 1.5). isTimeSet = true; } private int compareTo(long t) { long thisTime = getMillisOf(this); return (thisTime > t) ? 1 : (thisTime == t) ? 0 : -1; } private static final long getMillisOf(Calendar calendar) { if (calendar.isTimeSet) { return calendar.time; } Calendar cal = (Calendar) calendar.clone(); cal.setLenient(true); return cal.getTimeInMillis(); } /** * Adjusts the stamp[] values before nextStamp overflow. nextStamp * is set to the next stamp value upon the return. */ private final void adjustStamp() { int max = MINIMUM_USER_STAMP; int newStamp = MINIMUM_USER_STAMP; for (;;) { int min = Integer.MAX_VALUE; for (int i = 0; i < stamp.length; i++) { int v = stamp[i]; if (v >= newStamp && min > v) { min = v; } if (max < v) { max = v; } } if (max != min && min == Integer.MAX_VALUE) { break; } for (int i = 0; i < stamp.length; i++) { if (stamp[i] == min) { stamp[i] = newStamp; } } newStamp++; if (min == max) { break; } } nextStamp = newStamp; } /** * Sets the WEEK_OF_MONTH and WEEK_OF_YEAR fields to new values with the * new parameter value if they have been calculated internally. */ private void invalidateWeekFields() { if (stamp[WEEK_OF_MONTH] != COMPUTED && stamp[WEEK_OF_YEAR] != COMPUTED) { return; } // We have to check the new values of these fields after changing // firstDayOfWeek and/or minimalDaysInFirstWeek. If the field values // have been changed, then set the new values. (4822110) Calendar cal = (Calendar) clone(); cal.setLenient(true); cal.clear(WEEK_OF_MONTH); cal.clear(WEEK_OF_YEAR); if (stamp[WEEK_OF_MONTH] == COMPUTED) { int weekOfMonth = cal.get(WEEK_OF_MONTH); if (fields[WEEK_OF_MONTH] != weekOfMonth) { fields[WEEK_OF_MONTH] = weekOfMonth; } } if (stamp[WEEK_OF_YEAR] == COMPUTED) { int weekOfYear = cal.get(WEEK_OF_YEAR); if (fields[WEEK_OF_YEAR] != weekOfYear) { fields[WEEK_OF_YEAR] = weekOfYear; } } } /** * Save the state of this object to a stream (i.e., serialize it). * * Ideally, Calendar would only write out its state data and * the current time, and not write any field data out, such as * fields[], isTimeSet, areFieldsSet, * and isSet[]. nextStamp also should not be part * of the persistent state. Unfortunately, this didn't happen before JDK 1.1 * shipped. To be compatible with JDK 1.1, we will always have to write out * the field values and state flags. However, nextStamp can be * removed from the serialization stream; this will probably happen in the * near future. */ private void writeObject(ObjectOutputStream stream) throws IOException { // Try to compute the time correctly, for the future (stream // version 2) in which we don't write out fields[] or isSet[]. if (!isTimeSet) { try { updateTime(); } catch (IllegalArgumentException e) {} } // If this Calendar has a ZoneInfo, save it and set a // SimpleTimeZone equivalent (as a single DST schedule) for // backward compatibility. TimeZone savedZone = null; // if (zone instanceof ZoneInfo) { // SimpleTimeZone stz = ((ZoneInfo)zone).getLastRuleInstance(); // if (stz == null) { // stz = new SimpleTimeZone(zone.getRawOffset(), zone.getID()); // } // savedZone = zone; // zone = stz; // } // Write out the 1.1 FCS object. stream.defaultWriteObject(); // Write out the ZoneInfo object // 4802409: we write out even if it is null, a temporary workaround // the real fix for bug 4844924 in corba-iiop stream.writeObject(savedZone); if (savedZone != null) { zone = savedZone; } } /** * Reconstitutes this object from a stream (i.e., deserialize it). */ private void readObject(ObjectInputStream stream) throws IOException, ClassNotFoundException { final ObjectInputStream input = stream; input.defaultReadObject(); stamp = new int[FIELD_COUNT]; // Starting with version 2 (not implemented yet), we expect that // fields[], isSet[], isTimeSet, and areFieldsSet may not be // streamed out anymore. We expect 'time' to be correct. if (serialVersionOnStream >= 2) { isTimeSet = true; if (fields == null) fields = new int[FIELD_COUNT]; if (isSet == null) isSet = new boolean[FIELD_COUNT]; } else if (serialVersionOnStream >= 0) { for (int i=0; i() { // public ZoneInfo run() throws Exception { // return (ZoneInfo) input.readObject(); // } // }, // CalendarAccessControlContext.INSTANCE); // } catch (PrivilegedActionException pae) { // Exception e = pae.getException(); // if (!(e instanceof OptionalDataException)) { // if (e instanceof RuntimeException) { // throw (RuntimeException) e; // } else if (e instanceof IOException) { // throw (IOException) e; // } else if (e instanceof ClassNotFoundException) { // throw (ClassNotFoundException) e; // } // throw new RuntimeException(e); // } // } if (zi != null) { zone = zi; } // If the deserialized object has a SimpleTimeZone, try to // replace it with a ZoneInfo equivalent (as of 1.4) in order // to be compatible with the SimpleTimeZone-based // implementation as much as possible. if (zone instanceof SimpleTimeZone) { String id = zone.getID(); TimeZone tz = TimeZone.getTimeZone(id); if (tz != null && tz.hasSameRules(zone) && tz.getID().equals(id)) { zone = tz; } } } }





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