All Downloads are FREE. Search and download functionalities are using the official Maven repository.

com.ibm.icu.util.GregorianCalendar Maven / Gradle / Ivy

Go to download

International Component for Unicode for Java (ICU4J) is a mature, widely used Java library providing Unicode and Globalization support

There is a newer version: 76.1
Show newest version
// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
/*
 * Copyright (C) 1996-2016, International Business Machines
 * Corporation and others.  All Rights Reserved.
 */

package com.ibm.icu.util;

import java.util.Date;
import java.util.Locale;

import com.ibm.icu.util.ULocale.Category;

/**
 * {@icuenhanced java.util.GregorianCalendar}.{@icu _usage_}
 *
 * 

GregorianCalendar is a concrete subclass of * {@link Calendar} * and provides the standard calendar used by most of the world. * *

The standard (Gregorian) calendar has 2 eras, BC and AD. * *

This implementation handles a single discontinuity, which corresponds by * default to the date the Gregorian calendar was instituted (October 15, 1582 * in some countries, later in others). The cutover date may be changed by the * caller by calling setGregorianChange(). * *

Historically, in those countries which adopted the Gregorian calendar first, * October 4, 1582 was thus followed by October 15, 1582. This calendar models * this correctly. Before the Gregorian cutover, GregorianCalendar * implements the Julian calendar. The only difference between the Gregorian * and the Julian calendar is the leap year rule. The Julian calendar specifies * leap years every four years, whereas the Gregorian calendar omits century * years which are not divisible by 400. * *

GregorianCalendar implements proleptic Gregorian and * Julian calendars. That is, dates are computed by extrapolating the current * rules indefinitely far backward and forward in time. As a result, * GregorianCalendar may be used for all years to generate * meaningful and consistent results. However, dates obtained using * GregorianCalendar are historically accurate only from March 1, 4 * AD onward, when modern Julian calendar rules were adopted. Before this date, * leap year rules were applied irregularly, and before 45 BC the Julian * calendar did not even exist. * *

Prior to the institution of the Gregorian calendar, New Year's Day was * March 25. To avoid confusion, this calendar always uses January 1. A manual * adjustment may be made if desired for dates that are prior to the Gregorian * changeover and which fall between January 1 and March 24. * *

Values calculated for the WEEK_OF_YEAR field range from 1 to * 53. Week 1 for a year is the earliest seven day period starting on * getFirstDayOfWeek() that contains at least * getMinimalDaysInFirstWeek() days from that year. It thus * depends on the values of getMinimalDaysInFirstWeek(), * getFirstDayOfWeek(), and the day of the week of January 1. * Weeks between week 1 of one year and week 1 of the following year are * numbered sequentially from 2 to 52 or 53 (as needed). *

For example, January 1, 1998 was a Thursday. If * getFirstDayOfWeek() is MONDAY and * getMinimalDaysInFirstWeek() is 4 (these are the values * reflecting ISO 8601 and many national standards), then week 1 of 1998 starts * on December 29, 1997, and ends on January 4, 1998. If, however, * getFirstDayOfWeek() is SUNDAY, then week 1 of 1998 * starts on January 4, 1998, and ends on January 10, 1998; the first three days * of 1998 then are part of week 53 of 1997. * *

Values calculated for the WEEK_OF_MONTH field range from 0 or * 1 to 4 or 5. Week 1 of a month (the days with WEEK_OF_MONTH = * 1) is the earliest set of at least * getMinimalDaysInFirstWeek() contiguous days in that month, * ending on the day before getFirstDayOfWeek(). Unlike * week 1 of a year, week 1 of a month may be shorter than 7 days, need * not start on getFirstDayOfWeek(), and will not include days of * the previous month. Days of a month before week 1 have a * WEEK_OF_MONTH of 0. * *

For example, if getFirstDayOfWeek() is SUNDAY * and getMinimalDaysInFirstWeek() is 4, then the first week of * January 1998 is Sunday, January 4 through Saturday, January 10. These days * have a WEEK_OF_MONTH of 1. Thursday, January 1 through * Saturday, January 3 have a WEEK_OF_MONTH of 0. If * getMinimalDaysInFirstWeek() is changed to 3, then January 1 * through January 3 have a WEEK_OF_MONTH of 1. * *

* Example: *

*
 * // get the supported ids for GMT-08:00 (Pacific Standard Time)
 * String[] ids = TimeZone.getAvailableIDs(-8 * 60 * 60 * 1000);
 * // if no ids were returned, something is wrong. get out.
 * if (ids.length == 0)
 *     System.exit(0);
 *
 *  // begin output
 * System.out.println("Current Time");
 *
 * // create a Pacific Standard Time time zone
 * SimpleTimeZone pdt = new SimpleTimeZone(-8 * 60 * 60 * 1000, ids[0]);
 *
 * // set up rules for daylight savings time
 * pdt.setStartRule(Calendar.MARCH, 2, Calendar.SUNDAY, 2 * 60 * 60 * 1000);
 * pdt.setEndRule(Calendar.NOVEMBER, 1, Calendar.SUNDAY, 2 * 60 * 60 * 1000);
 *
 * // create a GregorianCalendar with the Pacific Daylight time zone
 * // and the current date and time
 * Calendar calendar = new GregorianCalendar(pdt);
 * Date trialTime = new Date();
 * calendar.setTime(trialTime);
 *
 * // print out a bunch of interesting things
 * System.out.println("ERA: " + calendar.get(Calendar.ERA));
 * System.out.println("YEAR: " + calendar.get(Calendar.YEAR));
 * System.out.println("MONTH: " + calendar.get(Calendar.MONTH));
 * System.out.println("WEEK_OF_YEAR: " + calendar.get(Calendar.WEEK_OF_YEAR));
 * System.out.println("WEEK_OF_MONTH: " + calendar.get(Calendar.WEEK_OF_MONTH));
 * System.out.println("DATE: " + calendar.get(Calendar.DATE));
 * System.out.println("DAY_OF_MONTH: " + calendar.get(Calendar.DAY_OF_MONTH));
 * System.out.println("DAY_OF_YEAR: " + calendar.get(Calendar.DAY_OF_YEAR));
 * System.out.println("DAY_OF_WEEK: " + calendar.get(Calendar.DAY_OF_WEEK));
 * System.out.println("DAY_OF_WEEK_IN_MONTH: "
 *                    + calendar.get(Calendar.DAY_OF_WEEK_IN_MONTH));
 * System.out.println("AM_PM: " + calendar.get(Calendar.AM_PM));
 * System.out.println("HOUR: " + calendar.get(Calendar.HOUR));
 * System.out.println("HOUR_OF_DAY: " + calendar.get(Calendar.HOUR_OF_DAY));
 * System.out.println("MINUTE: " + calendar.get(Calendar.MINUTE));
 * System.out.println("SECOND: " + calendar.get(Calendar.SECOND));
 * System.out.println("MILLISECOND: " + calendar.get(Calendar.MILLISECOND));
 * System.out.println("ZONE_OFFSET: "
 *                    + (calendar.get(Calendar.ZONE_OFFSET)/(60*60*1000)));
 * System.out.println("DST_OFFSET: "
 *                    + (calendar.get(Calendar.DST_OFFSET)/(60*60*1000)));

 * System.out.println("Current Time, with hour reset to 3");
 * calendar.clear(Calendar.HOUR_OF_DAY); // so doesn't override
 * calendar.set(Calendar.HOUR, 3);
 * System.out.println("ERA: " + calendar.get(Calendar.ERA));
 * System.out.println("YEAR: " + calendar.get(Calendar.YEAR));
 * System.out.println("MONTH: " + calendar.get(Calendar.MONTH));
 * System.out.println("WEEK_OF_YEAR: " + calendar.get(Calendar.WEEK_OF_YEAR));
 * System.out.println("WEEK_OF_MONTH: " + calendar.get(Calendar.WEEK_OF_MONTH));
 * System.out.println("DATE: " + calendar.get(Calendar.DATE));
 * System.out.println("DAY_OF_MONTH: " + calendar.get(Calendar.DAY_OF_MONTH));
 * System.out.println("DAY_OF_YEAR: " + calendar.get(Calendar.DAY_OF_YEAR));
 * System.out.println("DAY_OF_WEEK: " + calendar.get(Calendar.DAY_OF_WEEK));
 * System.out.println("DAY_OF_WEEK_IN_MONTH: "
 *                    + calendar.get(Calendar.DAY_OF_WEEK_IN_MONTH));
 * System.out.println("AM_PM: " + calendar.get(Calendar.AM_PM));
 * System.out.println("HOUR: " + calendar.get(Calendar.HOUR));
 * System.out.println("HOUR_OF_DAY: " + calendar.get(Calendar.HOUR_OF_DAY));
 * System.out.println("MINUTE: " + calendar.get(Calendar.MINUTE));
 * System.out.println("SECOND: " + calendar.get(Calendar.SECOND));
 * System.out.println("MILLISECOND: " + calendar.get(Calendar.MILLISECOND));
 * System.out.println("ZONE_OFFSET: "
 *        + (calendar.get(Calendar.ZONE_OFFSET)/(60*60*1000))); // in hours
 * System.out.println("DST_OFFSET: "
 *        + (calendar.get(Calendar.DST_OFFSET)/(60*60*1000))); // in hours
*
*

* GregorianCalendar usually should be instantiated using * {@link com.ibm.icu.util.Calendar#getInstance(ULocale)} passing in a ULocale * with the tag "@calendar=gregorian".

* @see Calendar * @see TimeZone * @author Deborah Goldsmith, Mark Davis, Chen-Lieh Huang, Alan Liu * @stable ICU 2.0 */ public class GregorianCalendar extends Calendar { // jdk1.4.2 serialver private static final long serialVersionUID = 9199388694351062137L; /* * Implementation Notes * * The Julian day number, as used here, is a modified number which has its * onset at midnight, rather than noon. * * The epoch is the number of days or milliseconds from some defined * starting point. The epoch for java.util.Date is used here; that is, * milliseconds from January 1, 1970 (Gregorian), midnight UTC. Other * epochs which are used are January 1, year 1 (Gregorian), which is day 1 * of the Gregorian calendar, and December 30, year 0 (Gregorian), which is * day 1 of the Julian calendar. * * We implement the proleptic Julian and Gregorian calendars. This means we * implement the modern definition of the calendar even though the * historical usage differs. For example, if the Gregorian change is set * to new Date(Long.MIN_VALUE), we have a pure Gregorian calendar which * labels dates preceding the invention of the Gregorian calendar in 1582 as * if the calendar existed then. * * Likewise, with the Julian calendar, we assume a consistent 4-year leap * rule, even though the historical pattern of leap years is irregular, * being every 3 years from 45 BC through 9 BC, then every 4 years from 8 AD * onwards, with no leap years in-between. Thus date computations and * functions such as isLeapYear() are not intended to be historically * accurate. * * Given that milliseconds are a long, day numbers such as Julian day * numbers, Gregorian or Julian calendar days, or epoch days, are also * longs. Years can fit into an int. */ ////////////////// // Class Variables ////////////////// /** * Value of the ERA field indicating * the period before the common era (before Christ), also known as BCE. * The sequence of years at the transition from BC to AD is * ..., 2 BC, 1 BC, 1 AD, 2 AD,... * @see Calendar#ERA * @stable ICU 2.0 */ public static final int BC = 0; /** * Value of the ERA field indicating * the common era (Anno Domini), also known as CE. * The sequence of years at the transition from BC to AD is * ..., 2 BC, 1 BC, 1 AD, 2 AD,... * @see Calendar#ERA * @stable ICU 2.0 */ public static final int AD = 1; private static final int EPOCH_YEAR = 1970; private static final int[][] MONTH_COUNT = { //len len2 st st2 { 31, 31, 0, 0 }, // Jan { 28, 29, 31, 31 }, // Feb { 31, 31, 59, 60 }, // Mar { 30, 30, 90, 91 }, // Apr { 31, 31, 120, 121 }, // May { 30, 30, 151, 152 }, // Jun { 31, 31, 181, 182 }, // Jul { 31, 31, 212, 213 }, // Aug { 30, 30, 243, 244 }, // Sep { 31, 31, 273, 274 }, // Oct { 30, 30, 304, 305 }, // Nov { 31, 31, 334, 335 } // Dec // len length of month // len2 length of month in a leap year // st days in year before start of month // st2 days in year before month in leap year }; /** * Old year limits were least max 292269054, max 292278994. */ private static final int LIMITS[][] = { // Minimum Greatest Least Maximum // Minimum Maximum { 0, 0, 1, 1 }, // ERA { 1, 1, 5828963, 5838270 }, // YEAR { 0, 0, 11, 11 }, // MONTH { 1, 1, 52, 53 }, // WEEK_OF_YEAR {/* */}, // WEEK_OF_MONTH { 1, 1, 28, 31 }, // DAY_OF_MONTH { 1, 1, 365, 366 }, // DAY_OF_YEAR {/* */}, // DAY_OF_WEEK { -1, -1, 4, 5 }, // DAY_OF_WEEK_IN_MONTH {/* */}, // AM_PM {/* */}, // HOUR {/* */}, // HOUR_OF_DAY {/* */}, // MINUTE {/* */}, // SECOND {/* */}, // MILLISECOND {/* */}, // ZONE_OFFSET {/* */}, // DST_OFFSET { -5838270, -5838270, 5828964, 5838271 }, // YEAR_WOY {/* */}, // DOW_LOCAL { -5838269, -5838269, 5828963, 5838270 }, // EXTENDED_YEAR {/* */}, // JULIAN_DAY {/* */}, // MILLISECONDS_IN_DAY {/* */}, // IS_LEAP_MONTH }; /** * @stable ICU 2.0 */ protected int handleGetLimit(int field, int limitType) { return LIMITS[field][limitType]; } ///////////////////// // Instance Variables ///////////////////// /** * The point at which the Gregorian calendar rules are used, measured in * milliseconds from the standard epoch. Default is October 15, 1582 * (Gregorian) 00:00:00 UTC or -12219292800000L. For this value, October 4, * 1582 (Julian) is followed by October 15, 1582 (Gregorian). This * corresponds to Julian day number 2299161. * @serial */ private long gregorianCutover = -12219292800000L; /** * Julian day number of the Gregorian cutover. */ private transient int cutoverJulianDay = 2299161; /** * The year of the gregorianCutover, with 0 representing * 1 BC, -1 representing 2 BC, etc. */ private transient int gregorianCutoverYear = 1582; /** * Used by handleComputeJulianDay() and handleComputeMonthStart(). * @stable ICU 2.0 */ transient protected boolean isGregorian; /** * Used by handleComputeJulianDay() and handleComputeMonthStart(). * @stable ICU 2.0 */ transient protected boolean invertGregorian; /////////////// // Constructors /////////////// /** * Constructs a default GregorianCalendar using the current time * in the default time zone with the default FORMAT locale. * @see Category#FORMAT * @stable ICU 2.0 */ public GregorianCalendar() { this(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT)); } /** * Constructs a GregorianCalendar based on the current time * in the given time zone with the default FORMAT locale. * @param zone the given time zone. * @see Category#FORMAT * @stable ICU 2.0 */ public GregorianCalendar(TimeZone zone) { this(zone, ULocale.getDefault(Category.FORMAT)); } /** * Constructs a GregorianCalendar based on the current time * in the default time zone with the given locale. * @param aLocale the given locale. * @stable ICU 2.0 */ public GregorianCalendar(Locale aLocale) { this(TimeZone.forLocaleOrDefault(aLocale), aLocale); } /** * {@icu} Constructs a GregorianCalendar based on the current time * in the default time zone with the given locale. * @param locale the given ulocale. * @stable ICU 3.2 */ public GregorianCalendar(ULocale locale) { this(TimeZone.forULocaleOrDefault(locale), locale); } /** * {@icu} Constructs a GregorianCalendar based on the current time * in the given time zone with the given locale. * @param zone the given time zone. * @param aLocale the given locale. * @stable ICU 2.0 */ public GregorianCalendar(TimeZone zone, Locale aLocale) { super(zone, aLocale); setTimeInMillis(System.currentTimeMillis()); } /** * Constructs a GregorianCalendar based on the current time * in the given time zone with the given locale. * @param zone the given time zone. * @param locale the given ulocale. * @stable ICU 3.2 */ public GregorianCalendar(TimeZone zone, ULocale locale) { super(zone, locale); setTimeInMillis(System.currentTimeMillis()); } /** * Constructs a GregorianCalendar with the given date set * in the default time zone with the default FORMAT locale. * @param year the value used to set the YEAR time field in the calendar. * @param month the value used to set the MONTH time field in the calendar. * Month value is 0-based. e.g., 0 for January. * @param date the value used to set the DATE time field in the calendar. * @see Category#FORMAT * @stable ICU 2.0 */ public GregorianCalendar(int year, int month, int date) { super(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT)); set(ERA, AD); set(YEAR, year); set(MONTH, month); set(DATE, date); } /** * Constructs a GregorianCalendar with the given date * and time set for the default time zone with the default FORMAT locale. * @param year the value used to set the YEAR time field in the calendar. * @param month the value used to set the MONTH time field in the calendar. * Month value is 0-based. e.g., 0 for January. * @param date the value used to set the DATE time field in the calendar. * @param hour the value used to set the HOUR_OF_DAY time field * in the calendar. * @param minute the value used to set the MINUTE time field * in the calendar. * @see Category#FORMAT * @stable ICU 2.0 */ public GregorianCalendar(int year, int month, int date, int hour, int minute) { super(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT)); set(ERA, AD); set(YEAR, year); set(MONTH, month); set(DATE, date); set(HOUR_OF_DAY, hour); set(MINUTE, minute); } /** * Constructs a GregorianCalendar with the given date * and time set for the default time zone with the default FORMAT locale. * @param year the value used to set the YEAR time field in the calendar. * @param month the value used to set the MONTH time field in the calendar. * Month value is 0-based. e.g., 0 for January. * @param date the value used to set the DATE time field in the calendar. * @param hour the value used to set the HOUR_OF_DAY time field * in the calendar. * @param minute the value used to set the MINUTE time field * in the calendar. * @param second the value used to set the SECOND time field * in the calendar. * @see Category#FORMAT * @stable ICU 2.0 */ public GregorianCalendar(int year, int month, int date, int hour, int minute, int second) { super(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT)); set(ERA, AD); set(YEAR, year); set(MONTH, month); set(DATE, date); set(HOUR_OF_DAY, hour); set(MINUTE, minute); set(SECOND, second); } ///////////////// // Public methods ///////////////// /** * Sets the GregorianCalendar change date. This is the point when the switch * from Julian dates to Gregorian dates occurred. Default is October 15, * 1582. Previous to this, dates will be in the Julian calendar. *

* To obtain a pure Julian calendar, set the change date to * Date(Long.MAX_VALUE). To obtain a pure Gregorian calendar, * set the change date to Date(Long.MIN_VALUE). * * @param date the given Gregorian cutover date. * @stable ICU 2.0 */ public void setGregorianChange(Date date) { gregorianCutover = date.getTime(); // If the cutover has an extreme value, then create a pure // Gregorian or pure Julian calendar by giving the cutover year and // JD extreme values. if (gregorianCutover <= MIN_MILLIS) { gregorianCutoverYear = cutoverJulianDay = Integer.MIN_VALUE; } else if (gregorianCutover >= MAX_MILLIS) { gregorianCutoverYear = cutoverJulianDay = Integer.MAX_VALUE; } else { // Precompute two internal variables which we use to do the actual // cutover computations. These are the Julian day of the cutover // and the cutover year. cutoverJulianDay = (int) floorDivide(gregorianCutover, ONE_DAY); // Convert cutover millis to extended year GregorianCalendar cal = new GregorianCalendar(getTimeZone()); cal.setTime(date); gregorianCutoverYear = cal.get(EXTENDED_YEAR); } } /** * Gets the Gregorian Calendar change date. This is the point when the * switch from Julian dates to Gregorian dates occurred. Default is * October 15, 1582. Previous to this, dates will be in the Julian * calendar. * @return the Gregorian cutover date for this calendar. * @stable ICU 2.0 */ public final Date getGregorianChange() { return new Date(gregorianCutover); } /** * Determines if the given year is a leap year. Returns true if the * given year is a leap year. * @param year the given year. * @return true if the given year is a leap year; false otherwise. * @stable ICU 2.0 */ public boolean isLeapYear(int year) { return year >= gregorianCutoverYear ? ((year%4 == 0) && ((year%100 != 0) || (year%400 == 0))) : // Gregorian (year%4 == 0); // Julian } /** * Returns true if the given Calendar object is equivalent to this * one. Calendar override. * * @param other the Calendar to be compared with this Calendar * @stable ICU 2.4 */ public boolean isEquivalentTo(Calendar other) { return super.isEquivalentTo(other) && gregorianCutover == ((GregorianCalendar)other).gregorianCutover; } /** * Override hashCode. * Generates the hash code for the GregorianCalendar object * @stable ICU 2.0 */ public int hashCode() { return super.hashCode() ^ (int)gregorianCutover; } /** * Roll a field by a signed amount. * @stable ICU 2.0 */ public void roll(int field, int amount) { switch (field) { case WEEK_OF_YEAR: { // Unlike WEEK_OF_MONTH, WEEK_OF_YEAR never shifts the day of the // week. Also, rolling the week of the year can have seemingly // strange effects simply because the year of the week of year // may be different from the calendar year. For example, the // date Dec 28, 1997 is the first day of week 1 of 1998 (if // weeks start on Sunday and the minimal days in first week is // <= 3). int woy = get(WEEK_OF_YEAR); // Get the ISO year, which matches the week of year. This // may be one year before or after the calendar year. int isoYear = get(YEAR_WOY); int isoDoy = internalGet(DAY_OF_YEAR); if (internalGet(MONTH) == Calendar.JANUARY) { if (woy >= 52) { isoDoy += handleGetYearLength(isoYear); } } else { if (woy == 1) { isoDoy -= handleGetYearLength(isoYear - 1); } } woy += amount; // Do fast checks to avoid unnecessary computation: if (woy < 1 || woy > 52) { // Determine the last week of the ISO year. // We do this using the standard formula we use // everywhere in this file. If we can see that the // days at the end of the year are going to fall into // week 1 of the next year, we drop the last week by // subtracting 7 from the last day of the year. int lastDoy = handleGetYearLength(isoYear); int lastRelDow = (lastDoy - isoDoy + internalGet(DAY_OF_WEEK) - getFirstDayOfWeek()) % 7; if (lastRelDow < 0) lastRelDow += 7; if ((6 - lastRelDow) >= getMinimalDaysInFirstWeek()) lastDoy -= 7; int lastWoy = weekNumber(lastDoy, lastRelDow + 1); woy = ((woy + lastWoy - 1) % lastWoy) + 1; } set(WEEK_OF_YEAR, woy); set(YEAR, isoYear); // Why not YEAR_WOY? - Alan 11/6/00 return; } default: super.roll(field, amount); return; } } /** * Return the minimum value that this field could have, given the current date. * For the Gregorian calendar, this is the same as getMinimum() and getGreatestMinimum(). * @stable ICU 2.0 */ public int getActualMinimum(int field) { return getMinimum(field); } /** * Return the maximum value that this field could have, given the current date. * For example, with the date "Feb 3, 1997" and the DAY_OF_MONTH field, the actual * maximum would be 28; for "Feb 3, 1996" it s 29. Similarly for a Hebrew calendar, * for some years the actual maximum for MONTH is 12, and for others 13. * @stable ICU 2.0 */ public int getActualMaximum(int field) { /* It is a known limitation that the code here (and in getActualMinimum) * won't behave properly at the extreme limits of GregorianCalendar's * representable range (except for the code that handles the YEAR * field). That's because the ends of the representable range are at * odd spots in the year. For calendars with the default Gregorian * cutover, these limits are Sun Dec 02 16:47:04 GMT 292269055 BC to Sun * Aug 17 07:12:55 GMT 292278994 AD, somewhat different for non-GMT * zones. As a result, if the calendar is set to Aug 1 292278994 AD, * the actual maximum of DAY_OF_MONTH is 17, not 30. If the date is Mar * 31 in that year, the actual maximum month might be Jul, whereas is * the date is Mar 15, the actual maximum might be Aug -- depending on * the precise semantics that are desired. Similar considerations * affect all fields. Nonetheless, this effect is sufficiently arcane * that we permit it, rather than complicating the code to handle such * intricacies. - liu 8/20/98 * UPDATE: No longer true, since we have pulled in the limit values on * the year. - Liu 11/6/00 */ switch (field) { case YEAR: /* The year computation is no different, in principle, from the * others, however, the range of possible maxima is large. In * addition, the way we know we've exceeded the range is different. * For these reasons, we use the special case code below to handle * this field. * * The actual maxima for YEAR depend on the type of calendar: * * Gregorian = May 17, 292275056 BC - Aug 17, 292278994 AD * Julian = Dec 2, 292269055 BC - Jan 3, 292272993 AD * Hybrid = Dec 2, 292269055 BC - Aug 17, 292278994 AD * * We know we've exceeded the maximum when either the month, date, * time, or era changes in response to setting the year. We don't * check for month, date, and time here because the year and era are * sufficient to detect an invalid year setting. NOTE: If code is * added to check the month and date in the future for some reason, * Feb 29 must be allowed to shift to Mar 1 when setting the year. */ { Calendar cal = (Calendar) clone(); cal.setLenient(true); int era = cal.get(ERA); Date d = cal.getTime(); /* Perform a binary search, with the invariant that lowGood is a * valid year, and highBad is an out of range year. */ int lowGood = LIMITS[YEAR][1]; int highBad = LIMITS[YEAR][2]+1; while ((lowGood + 1) < highBad) { int y = (lowGood + highBad) / 2; cal.set(YEAR, y); if (cal.get(YEAR) == y && cal.get(ERA) == era) { lowGood = y; } else { highBad = y; cal.setTime(d); // Restore original fields } } return lowGood; } default: return super.getActualMaximum(field); } } ////////////////////// // Proposed public API ////////////////////// /** * Return true if the current time for this Calendar is in Daylignt * Savings Time. */ boolean inDaylightTime() { if (!getTimeZone().useDaylightTime()) return false; complete(); // Force update of DST_OFFSET field return internalGet(DST_OFFSET) != 0; } ///////////////////// // Calendar framework ///////////////////// /** * @stable ICU 2.0 */ protected int handleGetMonthLength(int extendedYear, int month) { // If the month is out of range, adjust it into range, and // modify the extended year value accordingly. if (month < 0 || month > 11) { int[] rem = new int[1]; extendedYear += floorDivide(month, 12, rem); month = rem[0]; } return MONTH_COUNT[month][isLeapYear(extendedYear)?1:0]; } /** * @stable ICU 2.0 */ protected int handleGetYearLength(int eyear) { return isLeapYear(eyear) ? 366 : 365; } ///////////////////////////// // Time => Fields computation ///////////////////////////// /** * Override Calendar to compute several fields specific to the hybrid * Gregorian-Julian calendar system. These are: * *

  • ERA *
  • YEAR *
  • MONTH *
  • DAY_OF_MONTH *
  • DAY_OF_YEAR *
  • EXTENDED_YEAR
* @stable ICU 2.0 */ protected void handleComputeFields(int julianDay) { int eyear, month, dayOfMonth, dayOfYear; if (julianDay >= cutoverJulianDay) { month = getGregorianMonth(); dayOfMonth = getGregorianDayOfMonth(); dayOfYear = getGregorianDayOfYear(); eyear = getGregorianYear(); } else { // The Julian epoch day (not the same as Julian Day) // is zero on Saturday December 30, 0 (Gregorian). long julianEpochDay = julianDay - (JAN_1_1_JULIAN_DAY - 2); eyear = (int) floorDivide(4*julianEpochDay + 1464, 1461); // Compute the Julian calendar day number for January 1, eyear long january1 = 365L*(eyear-1L) + floorDivide(eyear-1L, 4L); dayOfYear = (int)(julianEpochDay - january1); // 0-based // Julian leap years occurred historically every 4 years starting // with 8 AD. Before 8 AD the spacing is irregular; every 3 years // from 45 BC to 9 BC, and then none until 8 AD. However, we don't // implement this historical detail; instead, we implement the // computatinally cleaner proleptic calendar, which assumes // consistent 4-year cycles throughout time. boolean isLeap = ((eyear&0x3) == 0); // equiv. to (eyear%4 == 0) // Common Julian/Gregorian calculation int correction = 0; int march1 = isLeap ? 60 : 59; // zero-based DOY for March 1 if (dayOfYear >= march1) { correction = isLeap ? 1 : 2; } month = (12 * (dayOfYear + correction) + 6) / 367; // zero-based month dayOfMonth = dayOfYear - MONTH_COUNT[month][isLeap?3:2] + 1; // one-based DOM ++dayOfYear; } internalSet(MONTH, month); internalSet(DAY_OF_MONTH, dayOfMonth); internalSet(DAY_OF_YEAR, dayOfYear); internalSet(EXTENDED_YEAR, eyear); int era = AD; if (eyear < 1) { era = BC; eyear = 1 - eyear; } internalSet(ERA, era); internalSet(YEAR, eyear); } ///////////////////////////// // Fields => Time computation ///////////////////////////// /** * @stable ICU 2.0 */ protected int handleGetExtendedYear() { int year; if (newerField(EXTENDED_YEAR, YEAR) == EXTENDED_YEAR) { year = internalGet(EXTENDED_YEAR, EPOCH_YEAR); } else { // The year defaults to the epoch start, the era to AD int era = internalGet(ERA, AD); if (era == BC) { year = 1 - internalGet(YEAR, 1); // Convert to extended year } else { year = internalGet(YEAR, EPOCH_YEAR); } } return year; } /** * @stable ICU 2.0 */ protected int handleComputeJulianDay(int bestField) { invertGregorian = false; int jd = super.handleComputeJulianDay(bestField); // The following check handles portions of the cutover year BEFORE the // cutover itself happens. if (isGregorian != (jd >= cutoverJulianDay)) { invertGregorian = true; jd = super.handleComputeJulianDay(bestField); } return jd; } /** * Return JD of start of given month/year * @stable ICU 2.0 */ protected int handleComputeMonthStart(int eyear, int month, boolean useMonth) { // If the month is out of range, adjust it into range, and // modify the extended year value accordingly. if (month < 0 || month > 11) { int[] rem = new int[1]; eyear += floorDivide(month, 12, rem); month = rem[0]; } boolean isLeap = eyear%4 == 0; int y = eyear - 1; int julianDay = 365*y + floorDivide(y, 4) + (JAN_1_1_JULIAN_DAY - 3); isGregorian = (eyear >= gregorianCutoverYear); if (invertGregorian) { isGregorian = !isGregorian; } if (isGregorian) { isLeap = isLeap && ((eyear%100 != 0) || (eyear%400 == 0)); // Add 2 because Gregorian calendar starts 2 days after // Julian calendar julianDay += floorDivide(y, 400) - floorDivide(y, 100) + 2; } // At this point julianDay indicates the day BEFORE the first // day of January 1, of either the Julian or Gregorian // calendar. if (month != 0) { julianDay += MONTH_COUNT[month][isLeap?3:2]; } return julianDay; } /** * {@inheritDoc} * @stable ICU 3.8 */ public String getType() { return "gregorian"; } /* private static CalendarFactory factory; public static CalendarFactory factory() { if (factory == null) { factory = new CalendarFactory() { public Calendar create(TimeZone tz, ULocale loc) { return new GregorianCalendar(tz, loc); } public String factoryName() { return "Gregorian"; } }; } return factory; } */ }




© 2015 - 2024 Weber Informatics LLC | Privacy Policy