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/*********************************************************************
 * Copyright (C) 2000-2014, International Business Machines
 * Corporation and others. All Rights Reserved.
 *********************************************************************
 */

package com.ibm.icu.util;

import java.io.IOException;
import java.io.ObjectInputStream;
import java.util.Date;
import java.util.Locale;

import com.ibm.icu.impl.CalendarAstronomer;
import com.ibm.icu.impl.CalendarCache;
import com.ibm.icu.text.DateFormat;
import com.ibm.icu.util.ULocale.Category;

/**
 * ChineseCalendar is a concrete subclass of {@link Calendar}
 * that implements a traditional Chinese calendar.  The traditional Chinese
 * calendar is a lunisolar calendar: Each month starts on a new moon, and
 * the months are numbered according to solar events, specifically, to
 * guarantee that month 11 always contains the winter solstice.  In order
 * to accomplish this, leap months are inserted in certain years.  Leap
 * months are numbered the same as the month they follow.  The decision of
 * which month is a leap month depends on the relative movements of the sun
 * and moon.
 *
 * 

All astronomical computations are performed with respect to a time * zone of GMT+8:00 and a longitude of 120 degrees east. Although some * calendars implement a historically more accurate convention of using * Beijing's local longitude (116 degrees 25 minutes east) and time zone * (GMT+7:45:40) for dates before 1929, we do not implement this here. * *

Years are counted in two different ways in the Chinese calendar. The * first method is by sequential numbering from the 61st year of the reign * of Huang Di, 2637 BCE, which is designated year 1 on the Chinese * calendar. The second method uses 60-year cycles from the same starting * point, which is designated year 1 of cycle 1. In this class, the * EXTENDED_YEAR field contains the sequential year count. * The ERA field contains the cycle number, and the * YEAR field contains the year of the cycle, a value between * 1 and 60. * *

There is some variation in what is considered the starting point of * the calendar, with some sources starting in the first year of the reign * of Huang Di, rather than the 61st. This gives continuous year numbers * 60 years greater and cycle numbers one greater than what this class * implements. * *

Because ChineseCalendar defines an additional field and * redefines the way the ERA field is used, it requires a new * format class, ChineseDateFormat. As always, use the * methods DateFormat.getXxxInstance(Calendar cal,...) to * obtain a formatter for this calendar. * *

References:

* *

* This class should not be subclassed.

*

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

* * @see com.ibm.icu.util.Calendar * @author Alan Liu * @stable ICU 2.8 */ public class ChineseCalendar extends Calendar { // jdk1.4.2 serialver private static final long serialVersionUID = 7312110751940929420L; //------------------------------------------------------------------ // Developer Notes // // Time is represented as a scalar in two ways in this class. One is // the usual UTC epoch millis, that is, milliseconds after January 1, // 1970 Gregorian, 0:00:00.000 UTC. The other is in terms of 'local // days.' This is the number of days after January 1, 1970 Gregorian, // local to Beijing, China (since all computations of the Chinese // calendar are done in Beijing). That is, 0 represents January 1, // 1970 0:00 Asia/Shanghai. Conversion of local days to and from // standard epoch milliseconds is accomplished by the daysToMillis() // and millisToDays() methods. // // Several methods use caches to improve performance. Caches are at // the object, not class level, under the assumption that typical // usage will be to have one instance of ChineseCalendar at a time. /** * The start year of this Chinese calendar instance. */ private int epochYear; /** * The zone used for the astronomical calculation of this Chinese * calendar instance. */ private TimeZone zoneAstro; /** * We have one instance per object, and we don't synchronize it because * Calendar doesn't support multithreaded execution in the first place. */ private transient CalendarAstronomer astro = new CalendarAstronomer(); /** * Cache that maps Gregorian year to local days of winter solstice. * @see #winterSolstice */ private transient CalendarCache winterSolsticeCache = new CalendarCache(); /** * Cache that maps Gregorian year to local days of Chinese new year. * @see #newYear */ private transient CalendarCache newYearCache = new CalendarCache(); /** * True if the current year is a leap year. Updated with each time to * fields resolution. * @see #computeChineseFields */ private transient boolean isLeapYear; //------------------------------------------------------------------ // Constructors //------------------------------------------------------------------ /** * Construct a ChineseCalendar with the default time zone and locale. * @stable ICU 2.8 */ public ChineseCalendar() { this(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT), CHINESE_EPOCH_YEAR, CHINA_ZONE); } /** * Construct a ChineseCalendar with the give date set in the default time zone * with the default locale. * @param date The date to which the new calendar is set. * @stable ICU 4.0 */ public ChineseCalendar(Date date) { this(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT), CHINESE_EPOCH_YEAR, CHINA_ZONE); setTime(date); } /** * Constructs a ChineseCalendar with the given date set * in the default time zone with the default FORMAT locale. * * @param year The value used to set the calendar's {@link #YEAR YEAR} time field. * @param month The value used to set the calendar's {@link #MONTH MONTH} time field. * The value is 0-based. e.g., 0 for January. * @param isLeapMonth The value used to set the Chinese calendar's (@link #IS_LEAP_MONTH) * time field. * @param date The value used to set the calendar's {@link #DATE DATE} time field. * @see Category#FORMAT * @stable ICU 4.0 */ public ChineseCalendar(int year, int month, int isLeapMonth, int date) { this(year, month, isLeapMonth, date, 0, 0, 0); } /** * Constructs a ChineseCalendar 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 {@link #YEAR YEAR} time field in the calendar. * @param month the value used to set the {@link #MONTH MONTH} time field in the calendar. * Note that the month value is 0-based. e.g., 0 for January. * @param isLeapMonth the value used to set the {@link #IS_LEAP_MONTH} time field * in the calendar. * @param date the value used to set the {@link #DATE DATE} time field in the calendar. * @param hour the value used to set the {@link #HOUR_OF_DAY HOUR_OF_DAY} time field * in the calendar. * @param minute the value used to set the {@link #MINUTE MINUTE} time field * in the calendar. * @param second the value used to set the {@link #SECOND SECOND} time field * in the calendar. * @see Category#FORMAT * @stable ICU 4.0 */ public ChineseCalendar(int year, int month, int isLeapMonth, int date, int hour, int minute, int second) { this(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT), CHINESE_EPOCH_YEAR, CHINA_ZONE); // The current time is set at this point, so ERA field is already // set to the current era. // Then we need to clean up time fields this.set(MILLISECOND, 0); // Then, set the given field values. this.set(YEAR, year); this.set(MONTH, month); this.set(IS_LEAP_MONTH, isLeapMonth); this.set(DATE, date); this.set(HOUR_OF_DAY, hour); this.set(MINUTE, minute); this.set(SECOND, second); } /** * Constructs a ChineseCalendar with the given date set * in the default time zone with the default FORMAT locale. * * @param era The value used to set the calendar's {@link #ERA ERA} time field. * @param year The value used to set the calendar's {@link #YEAR YEAR} time field. * @param month The value used to set the calendar's {@link #MONTH MONTH} time field. * The value is 0-based. e.g., 0 for January. * @param isLeapMonth The value used to set the Chinese calendar's (@link #IS_LEAP_MONTH) * time field. * @param date The value used to set the calendar's {@link #DATE DATE} time field. * @see Category#FORMAT * @stable ICU 4.6 */ public ChineseCalendar(int era, int year, int month, int isLeapMonth, int date) { this(era, year, month, isLeapMonth, date, 0, 0, 0); } /** * Constructs a ChineseCalendar with the given date * and time set for the default time zone with the default FORMAT locale. * * @param era the value used to set the calendar's {@link #ERA ERA} time field. * @param year the value used to set the {@link #YEAR YEAR} time field in the calendar. * @param month the value used to set the {@link #MONTH MONTH} time field in the calendar. * Note that the month value is 0-based. e.g., 0 for January. * @param isLeapMonth the value used to set the {@link #IS_LEAP_MONTH} time field * in the calendar. * @param date the value used to set the {@link #DATE DATE} time field in the calendar. * @param hour the value used to set the {@link #HOUR_OF_DAY HOUR_OF_DAY} time field * in the calendar. * @param minute the value used to set the {@link #MINUTE MINUTE} time field * in the calendar. * @param second the value used to set the {@link #SECOND SECOND} time field * in the calendar. * @see Category#FORMAT * @stable ICU 4.6 */ public ChineseCalendar(int era, int year, int month, int isLeapMonth, int date, int hour, int minute, int second) { this(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT), CHINESE_EPOCH_YEAR, CHINA_ZONE); // Set 0 to millisecond field this.set(MILLISECOND, 0); // Then, set the given field values. this.set(ERA, era); this.set(YEAR, year); this.set(MONTH, month); this.set(IS_LEAP_MONTH, isLeapMonth); this.set(DATE, date); this.set(HOUR_OF_DAY, hour); this.set(MINUTE, minute); this.set(SECOND, second); } /** * Constructs a ChineseCalendar based on the current time * in the default time zone with the given locale. * @param aLocale The given locale * @stable ICU 4.0 */ public ChineseCalendar(Locale aLocale) { this(TimeZone.getDefault(), ULocale.forLocale(aLocale), CHINESE_EPOCH_YEAR, CHINA_ZONE); } /** * Construct a ChineseCalendar 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 4.0 */ public ChineseCalendar(TimeZone zone) { this(zone, ULocale.getDefault(Category.FORMAT), CHINESE_EPOCH_YEAR, CHINA_ZONE); } /** * Construct a ChineseCalendar 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 2.8 */ public ChineseCalendar(TimeZone zone, Locale aLocale) { this(zone, ULocale.forLocale(aLocale), CHINESE_EPOCH_YEAR, CHINA_ZONE); } /** * Constructs a ChineseCalendar based on the current time * in the default time zone with the given locale. * * @param locale the given ulocale * @stable ICU 4.0 */ public ChineseCalendar(ULocale locale) { this(TimeZone.getDefault(), locale, CHINESE_EPOCH_YEAR, CHINA_ZONE); } /** * Construct a ChineseCalendar based on the current time * with the given time zone with the given locale. * @param zone the given time zone * @param locale the given ulocale * @stable ICU 3.2 */ public ChineseCalendar(TimeZone zone, ULocale locale) { this(zone, locale, CHINESE_EPOCH_YEAR, CHINA_ZONE); } /** * Construct a ChineseCalenar based on the current time * with the given time zone, the locale, the epoch year and the time zone * used for astronomical calculation. * @internal * @deprecated This API is ICU internal only. */ @Deprecated protected ChineseCalendar(TimeZone zone, ULocale locale, int epochYear, TimeZone zoneAstroCalc) { super(zone, locale); this.epochYear = epochYear; this.zoneAstro = zoneAstroCalc; setTimeInMillis(System.currentTimeMillis()); } //------------------------------------------------------------------ // Public constants //------------------------------------------------------------------ /** * Field indicating whether or not the current month is a leap month. * Should have a value of 0 for non-leap months, and 1 for leap months. * @stable ICU 2.8 */ // public static int IS_LEAP_MONTH = BASE_FIELD_COUNT; //------------------------------------------------------------------ // Calendar framework //------------------------------------------------------------------ /** * Array defining the limits of field values for this class. Field * limits which are invariant with respect to calendar system and * defined by Calendar are left blank. * * Notes: * * ERA 5000000 / 60 = 83333. * * MONTH There are 12 or 13 lunar months in a year. However, we always * number them 0..11, with an intercalated, identically numbered leap * month, when necessary. * * DAY_OF_YEAR In a non-leap year there are 353, 354, or 355 days. In * a leap year there are 383, 384, or 385 days. * * WEEK_OF_YEAR The least maximum occurs if there are 353 days in the * year, and the first 6 are the last week of the previous year. Then * we have 49 full weeks and 4 days in the last week: 6 + 49*7 + 4 = * 353. So the least maximum is 50. The maximum occurs if there are * 385 days in the year, and WOY 1 extends 6 days into the prior year. * Then there are 54 full weeks, and 6 days in the last week: 1 + 54*7 * + 6 = 385. The 6 days of the last week will fall into WOY 1 of the * next year. Maximum is 55. * * WEEK_OF_MONTH In a 29 day month, if the first 7 days make up week 1 * that leaves 3 full weeks and 1 day at the end. The least maximum is * thus 5. In a 30 days month, if the previous 6 days belong WOM 1 of * this month, we have 4 full weeks and 1 days at the end (which * technically will be WOM 1 of the next month, but will be reported by * time->fields and hence by getActualMaximum as WOM 6 of this month). * Maximum is 6. * * DAY_OF_WEEK_IN_MONTH In a 29 or 30 day month, there are 4 full weeks * plus 1 or 2 days at the end, so the maximum is always 5. */ private static final int LIMITS[][] = { // Minimum Greatest Least Maximum // Minimum Maximum { 1, 1, 83333, 83333 }, // ERA { 1, 1, 60, 60 }, // YEAR { 0, 0, 11, 11 }, // MONTH { 1, 1, 50, 55 }, // WEEK_OF_YEAR {/* */}, // WEEK_OF_MONTH { 1, 1, 29, 30 }, // DAY_OF_MONTH { 1, 1, 353, 385 }, // DAY_OF_YEAR {/* */}, // DAY_OF_WEEK { -1, -1, 5, 5 }, // DAY_OF_WEEK_IN_MONTH {/* */}, // AM_PM {/* */}, // HOUR {/* */}, // HOUR_OF_DAY {/* */}, // MINUTE {/* */}, // SECOND {/* */}, // MILLISECOND {/* */}, // ZONE_OFFSET {/* */}, // DST_OFFSET { -5000000, -5000000, 5000000, 5000000 }, // YEAR_WOY {/* */}, // DOW_LOCAL { -5000000, -5000000, 5000000, 5000000 }, // EXTENDED_YEAR {/* */}, // JULIAN_DAY {/* */}, // MILLISECONDS_IN_DAY { 0, 0, 1, 1 }, // IS_LEAP_MONTH }; /** * Override Calendar to return the limit value for the given field. * @stable ICU 2.8 */ protected int handleGetLimit(int field, int limitType) { return LIMITS[field][limitType]; } /** * Implement abstract Calendar method to return the extended year * defined by the current fields. This will use either the ERA and * YEAR field as the cycle and year-of-cycle, or the EXTENDED_YEAR * field as the continuous year count, depending on which is newer. * @stable ICU 2.8 */ protected int handleGetExtendedYear() { int year; if (newestStamp(ERA, YEAR, UNSET) <= getStamp(EXTENDED_YEAR)) { year = internalGet(EXTENDED_YEAR, 1); // Default to year 1 } else { int cycle = internalGet(ERA, 1) - 1; // 0-based cycle // adjust to the instance specific epoch year = cycle * 60 + internalGet(YEAR, 1) - (epochYear - CHINESE_EPOCH_YEAR); } return year; } /** * Override Calendar method to return the number of days in the given * extended year and month. * *

Note: This method also reads the IS_LEAP_MONTH field to determine * whether or not the given month is a leap month. * @stable ICU 2.8 */ protected int handleGetMonthLength(int extendedYear, int month) { int thisStart = handleComputeMonthStart(extendedYear, month, true) - EPOCH_JULIAN_DAY + 1; // Julian day -> local days int nextStart = newMoonNear(thisStart + SYNODIC_GAP, true); return nextStart - thisStart; } /** * {@inheritDoc} * * @stable ICU 4.2 */ protected DateFormat handleGetDateFormat(String pattern, String override, ULocale locale) { // Note: ICU 50 or later versions no longer use ChineseDateFormat. // The super class's handleGetDateFormat will create an instance of // SimpleDateFormat which supports Chinese calendar date formatting // since ICU 49. //return new ChineseDateFormat(pattern, override, locale); return super.handleGetDateFormat(pattern, override, locale); } /** * Field resolution table that incorporates IS_LEAP_MONTH. */ static final int[][][] CHINESE_DATE_PRECEDENCE = { { { DAY_OF_MONTH }, { WEEK_OF_YEAR, DAY_OF_WEEK }, { WEEK_OF_MONTH, DAY_OF_WEEK }, { DAY_OF_WEEK_IN_MONTH, DAY_OF_WEEK }, { WEEK_OF_YEAR, DOW_LOCAL }, { WEEK_OF_MONTH, DOW_LOCAL }, { DAY_OF_WEEK_IN_MONTH, DOW_LOCAL }, { DAY_OF_YEAR }, { RESOLVE_REMAP | DAY_OF_MONTH, IS_LEAP_MONTH }, }, { { WEEK_OF_YEAR }, { WEEK_OF_MONTH }, { DAY_OF_WEEK_IN_MONTH }, { RESOLVE_REMAP | DAY_OF_WEEK_IN_MONTH, DAY_OF_WEEK }, { RESOLVE_REMAP | DAY_OF_WEEK_IN_MONTH, DOW_LOCAL }, }, }; /** * Override Calendar to add IS_LEAP_MONTH to the field resolution * table. * @stable ICU 2.8 */ protected int[][][] getFieldResolutionTable() { return CHINESE_DATE_PRECEDENCE; } /** * Adjust this calendar to be delta months before or after a given * start position, pinning the day of month if necessary. The start * position is given as a local days number for the start of the month * and a day-of-month. Used by add() and roll(). * @param newMoon the local days of the first day of the month of the * start position (days after January 1, 1970 0:00 Asia/Shanghai) * @param dom the 1-based day-of-month of the start position * @param delta the number of months to move forward or backward from * the start position */ private void offsetMonth(int newMoon, int dom, int delta) { // Move to the middle of the month before our target month. newMoon += (int) (CalendarAstronomer.SYNODIC_MONTH * (delta - 0.5)); // Search forward to the target month's new moon newMoon = newMoonNear(newMoon, true); // Find the target dom int jd = newMoon + EPOCH_JULIAN_DAY - 1 + dom; // Pin the dom. In this calendar all months are 29 or 30 days // so pinning just means handling dom 30. if (dom > 29) { set(JULIAN_DAY, jd-1); // TODO Fix this. We really shouldn't ever have to // explicitly call complete(). This is either a bug in // this method, in ChineseCalendar, or in // Calendar.getActualMaximum(). I suspect the last. complete(); if (getActualMaximum(DAY_OF_MONTH) >= dom) { set(JULIAN_DAY, jd); } } else { set(JULIAN_DAY, jd); } } /** * Override Calendar to handle leap months properly. * @stable ICU 2.8 */ public void add(int field, int amount) { switch (field) { case MONTH: if (amount != 0) { int dom = get(DAY_OF_MONTH); int day = get(JULIAN_DAY) - EPOCH_JULIAN_DAY; // Get local day int moon = day - dom + 1; // New moon offsetMonth(moon, dom, amount); } break; default: super.add(field, amount); break; } } /** * Override Calendar to handle leap months properly. * @stable ICU 2.8 */ public void roll(int field, int amount) { switch (field) { case MONTH: if (amount != 0) { int dom = get(DAY_OF_MONTH); int day = get(JULIAN_DAY) - EPOCH_JULIAN_DAY; // Get local day int moon = day - dom + 1; // New moon (start of this month) // Note throughout the following: Months 12 and 1 are never // followed by a leap month (D&R p. 185). // Compute the adjusted month number m. This is zero-based // value from 0..11 in a non-leap year, and from 0..12 in a // leap year. int m = get(MONTH); // 0-based month if (isLeapYear) { // (member variable) if (get(IS_LEAP_MONTH) == 1) { ++m; } else { // Check for a prior leap month. (In the // following, month 0 is the first month of the // year.) Month 0 is never followed by a leap // month, and we know month m is not a leap month. // moon1 will be the start of month 0 if there is // no leap month between month 0 and month m; // otherwise it will be the start of month 1. int moon1 = moon - (int) (CalendarAstronomer.SYNODIC_MONTH * (m - 0.5)); moon1 = newMoonNear(moon1, true); if (isLeapMonthBetween(moon1, moon)) { ++m; } } } // Now do the standard roll computation on m, with the // allowed range of 0..n-1, where n is 12 or 13. int n = isLeapYear ? 13 : 12; // Months in this year int newM = (m + amount) % n; if (newM < 0) { newM += n; } if (newM != m) { offsetMonth(moon, dom, newM - m); } } break; default: super.roll(field, amount); break; } } //------------------------------------------------------------------ // Support methods and constants //------------------------------------------------------------------ /** * The start year of the Chinese calendar, the 61st year of the reign * of Huang Di. Some sources use the first year of his reign, * resulting in EXTENDED_YEAR values 60 years greater and ERA (cycle) * values one greater. */ private static final int CHINESE_EPOCH_YEAR = -2636; // Gregorian year /** * The time zone used for performing astronomical computations. * Some sources use a different historically accurate * offset of GMT+7:45:40 for years before 1929; we do not do this. */ private static final TimeZone CHINA_ZONE = new SimpleTimeZone(8 * ONE_HOUR, "CHINA_ZONE").freeze(); /** * Value to be added or subtracted from the local days of a new moon to * get close to the next or prior new moon, but not cross it. Must be * >= 1 and < CalendarAstronomer.SYNODIC_MONTH. */ private static final int SYNODIC_GAP = 25; /** * Convert local days to UTC epoch milliseconds. * This is not an accurate conversion in terms that getTimezoneOffset * takes the milliseconds in GMT (not local time). In theory, more * accurate algorithm can be implemented but practically we do not need * to go through that complication as long as the historically timezone * changes did not happen around the 'tricky' new moon (new moon around * the midnight). * * @param days days after January 1, 1970 0:00 in the astronomical base zone * @return milliseconds after January 1, 1970 0:00 GMT */ private final long daysToMillis(int days) { long millis = days * ONE_DAY; return millis - zoneAstro.getOffset(millis); } /** * Convert UTC epoch milliseconds to local days. * @param millis milliseconds after January 1, 1970 0:00 GMT * @return days days after January 1, 1970 0:00 in the astronomical base zone */ private final int millisToDays(long millis) { return (int) floorDivide(millis + zoneAstro.getOffset(millis), ONE_DAY); } //------------------------------------------------------------------ // Astronomical computations //------------------------------------------------------------------ /** * Return the major solar term on or after December 15 of the given * Gregorian year, that is, the winter solstice of the given year. * Computations are relative to Asia/Shanghai time zone. * @param gyear a Gregorian year * @return days after January 1, 1970 0:00 Asia/Shanghai of the * winter solstice of the given year */ private int winterSolstice(int gyear) { long cacheValue = winterSolsticeCache.get(gyear); if (cacheValue == CalendarCache.EMPTY) { // In books December 15 is used, but it fails for some years // using our algorithms, e.g.: 1298 1391 1492 1553 1560. That // is, winterSolstice(1298) starts search at Dec 14 08:00:00 // PST 1298 with a final result of Dec 14 10:31:59 PST 1299. long ms = daysToMillis(computeGregorianMonthStart(gyear, DECEMBER) + 1 - EPOCH_JULIAN_DAY); astro.setTime(ms); // Winter solstice is 270 degrees solar longitude aka Dongzhi long solarLong = astro.getSunTime(CalendarAstronomer.WINTER_SOLSTICE, true); cacheValue = millisToDays(solarLong); winterSolsticeCache.put(gyear, cacheValue); } return (int) cacheValue; } /** * Return the closest new moon to the given date, searching either * forward or backward in time. * @param days days after January 1, 1970 0:00 Asia/Shanghai * @param after if true, search for a new moon on or after the given * date; otherwise, search for a new moon before it * @return days after January 1, 1970 0:00 Asia/Shanghai of the nearest * new moon after or before days */ private int newMoonNear(int days, boolean after) { astro.setTime(daysToMillis(days)); long newMoon = astro.getMoonTime(CalendarAstronomer.NEW_MOON, after); return millisToDays(newMoon); } /** * Return the nearest integer number of synodic months between * two dates. * @param day1 days after January 1, 1970 0:00 Asia/Shanghai * @param day2 days after January 1, 1970 0:00 Asia/Shanghai * @return the nearest integer number of months between day1 and day2 */ private int synodicMonthsBetween(int day1, int day2) { return (int) Math.round((day2 - day1) / CalendarAstronomer.SYNODIC_MONTH); } /** * Return the major solar term on or before a given date. This * will be an integer from 1..12, with 1 corresponding to 330 degrees, * 2 to 0 degrees, 3 to 30 degrees,..., and 12 to 300 degrees. * @param days days after January 1, 1970 0:00 Asia/Shanghai */ private int majorSolarTerm(int days) { astro.setTime(daysToMillis(days)); // Compute (floor(solarLongitude / (pi/6)) + 2) % 12 int term = ((int) Math.floor(6 * astro.getSunLongitude() / Math.PI) + 2) % 12; if (term < 1) { term += 12; } return term; } /** * Return true if the given month lacks a major solar term. * @param newMoon days after January 1, 1970 0:00 Asia/Shanghai of a new * moon */ private boolean hasNoMajorSolarTerm(int newMoon) { int mst = majorSolarTerm(newMoon); int nmn = newMoonNear(newMoon + SYNODIC_GAP, true); int mstt = majorSolarTerm(nmn); return mst == mstt; /* return majorSolarTerm(newMoon) == majorSolarTerm(newMoonNear(newMoon + SYNODIC_GAP, true)); */ } //------------------------------------------------------------------ // Time to fields //------------------------------------------------------------------ /** * Return true if there is a leap month on or after month newMoon1 and * at or before month newMoon2. * @param newMoon1 days after January 1, 1970 0:00 astronomical base zone of a * new moon * @param newMoon2 days after January 1, 1970 0:00 astronomical base zone of a * new moon */ private boolean isLeapMonthBetween(int newMoon1, int newMoon2) { // This is only needed to debug the timeOfAngle divergence bug. // Remove this later. Liu 11/9/00 // DEBUG if (synodicMonthsBetween(newMoon1, newMoon2) >= 50) { throw new IllegalArgumentException("isLeapMonthBetween(" + newMoon1 + ", " + newMoon2 + "): Invalid parameters"); } return (newMoon2 >= newMoon1) && (isLeapMonthBetween(newMoon1, newMoonNear(newMoon2 - SYNODIC_GAP, false)) || hasNoMajorSolarTerm(newMoon2)); } /** * Override Calendar to compute several fields specific to the Chinese * calendar system. These are: * *

  • ERA *
  • YEAR *
  • MONTH *
  • DAY_OF_MONTH *
  • DAY_OF_YEAR *
  • EXTENDED_YEAR
* * The DAY_OF_WEEK and DOW_LOCAL fields are already set when this * method is called. The getGregorianXxx() methods return Gregorian * calendar equivalents for the given Julian day. * *

Compute the ChineseCalendar-specific field IS_LEAP_MONTH. * @stable ICU 2.8 */ protected void handleComputeFields(int julianDay) { computeChineseFields(julianDay - EPOCH_JULIAN_DAY, // local days getGregorianYear(), getGregorianMonth(), true); // set all fields } /** * Compute fields for the Chinese calendar system. This method can * either set all relevant fields, as required by * handleComputeFields(), or it can just set the MONTH and * IS_LEAP_MONTH fields, as required by * handleComputeMonthStart(). * *

As a side effect, this method sets {@link #isLeapYear}. * @param days days after January 1, 1970 0:00 astronomical base zone of the * date to compute fields for * @param gyear the Gregorian year of the given date * @param gmonth the Gregorian month of the given date * @param setAllFields if true, set the EXTENDED_YEAR, ERA, YEAR, * DAY_OF_MONTH, and DAY_OF_YEAR fields. In either case set the MONTH * and IS_LEAP_MONTH fields. */ private void computeChineseFields(int days, int gyear, int gmonth, boolean setAllFields) { // Find the winter solstices before and after the target date. // These define the boundaries of this Chinese year, specifically, // the position of month 11, which always contains the solstice. // We want solsticeBefore <= date < solsticeAfter. int solsticeBefore; int solsticeAfter = winterSolstice(gyear); if (days < solsticeAfter) { solsticeBefore = winterSolstice(gyear - 1); } else { solsticeBefore = solsticeAfter; solsticeAfter = winterSolstice(gyear + 1); } // Find the start of the month after month 11. This will be either // the prior month 12 or leap month 11 (very rare). Also find the // start of the following month 11. int firstMoon = newMoonNear(solsticeBefore + 1, true); int lastMoon = newMoonNear(solsticeAfter + 1, false); int thisMoon = newMoonNear(days + 1, false); // Start of this month // Note: isLeapYear is a member variable isLeapYear = synodicMonthsBetween(firstMoon, lastMoon) == 12; int month = synodicMonthsBetween(firstMoon, thisMoon); if (isLeapYear && isLeapMonthBetween(firstMoon, thisMoon)) { month--; } if (month < 1) { month += 12; } boolean isLeapMonth = isLeapYear && hasNoMajorSolarTerm(thisMoon) && !isLeapMonthBetween(firstMoon, newMoonNear(thisMoon - SYNODIC_GAP, false)); internalSet(MONTH, month-1); // Convert from 1-based to 0-based internalSet(IS_LEAP_MONTH, isLeapMonth?1:0); if (setAllFields) { // Extended year and cycle year is based on the epoch year int extended_year = gyear - epochYear; int cycle_year = gyear - CHINESE_EPOCH_YEAR; if (month < 11 || gmonth >= JULY) { extended_year++; cycle_year++; } int dayOfMonth = days - thisMoon + 1; internalSet(EXTENDED_YEAR, extended_year); // 0->0,60 1->1,1 60->1,60 61->2,1 etc. int[] yearOfCycle = new int[1]; int cycle = floorDivide(cycle_year-1, 60, yearOfCycle); internalSet(ERA, cycle+1); internalSet(YEAR, yearOfCycle[0]+1); internalSet(DAY_OF_MONTH, dayOfMonth); // Days will be before the first new year we compute if this // date is in month 11, leap 11, 12. There is never a leap 12. // New year computations are cached so this should be cheap in // the long run. int newYear = newYear(gyear); if (days < newYear) { newYear = newYear(gyear-1); } internalSet(DAY_OF_YEAR, days - newYear + 1); } } //------------------------------------------------------------------ // Fields to time //------------------------------------------------------------------ /** * Return the Chinese new year of the given Gregorian year. * @param gyear a Gregorian year * @return days after January 1, 1970 0:00 astronomical base zone of the * Chinese new year of the given year (this will be a new moon) */ private int newYear(int gyear) { long cacheValue = newYearCache.get(gyear); if (cacheValue == CalendarCache.EMPTY) { int solsticeBefore= winterSolstice(gyear - 1); int solsticeAfter = winterSolstice(gyear); int newMoon1 = newMoonNear(solsticeBefore + 1, true); int newMoon2 = newMoonNear(newMoon1 + SYNODIC_GAP, true); int newMoon11 = newMoonNear(solsticeAfter + 1, false); if (synodicMonthsBetween(newMoon1, newMoon11) == 12 && (hasNoMajorSolarTerm(newMoon1) || hasNoMajorSolarTerm(newMoon2))) { cacheValue = newMoonNear(newMoon2 + SYNODIC_GAP, true); } else { cacheValue = newMoon2; } newYearCache.put(gyear, cacheValue); } return (int) cacheValue; } /** * Return the Julian day number of day before the first day of the * given month in the given extended year. * *

Note: This method reads the IS_LEAP_MONTH field to determine * whether the given month is a leap month. * @param eyear the extended year * @param month the zero-based month. The month is also determined * by reading the IS_LEAP_MONTH field. * @return the Julian day number of the day before the first * day of the given month and year * @stable ICU 2.8 */ 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]; } int gyear = eyear + epochYear - 1; // Gregorian year int newYear = newYear(gyear); int newMoon = newMoonNear(newYear + month * 29, true); int julianDay = newMoon + EPOCH_JULIAN_DAY; // Save fields for later restoration int saveMonth = internalGet(MONTH); int saveIsLeapMonth = internalGet(IS_LEAP_MONTH); // Ignore IS_LEAP_MONTH field if useMonth is false int isLeapMonth = useMonth ? saveIsLeapMonth : 0; computeGregorianFields(julianDay); // This will modify the MONTH and IS_LEAP_MONTH fields (only) computeChineseFields(newMoon, getGregorianYear(), getGregorianMonth(), false); if (month != internalGet(MONTH) || isLeapMonth != internalGet(IS_LEAP_MONTH)) { newMoon = newMoonNear(newMoon + SYNODIC_GAP, true); julianDay = newMoon + EPOCH_JULIAN_DAY; } internalSet(MONTH, saveMonth); internalSet(IS_LEAP_MONTH, saveIsLeapMonth); return julianDay - 1; } /** * {@inheritDoc} * @stable ICU 3.8 */ public String getType() { return "chinese"; } /** * {@inheritDoc} * @internal * @deprecated This API is ICU internal only. */ @Deprecated public boolean haveDefaultCentury() { return false; } /** * Override readObject. */ private void readObject(ObjectInputStream stream) throws IOException, ClassNotFoundException { epochYear = CHINESE_EPOCH_YEAR; zoneAstro = CHINA_ZONE; stream.defaultReadObject(); /* set up the transient caches... */ astro = new CalendarAstronomer(); winterSolsticeCache = new CalendarCache(); newYearCache = new CalendarCache(); } /* private static CalendarFactory factory; public static CalendarFactory factory() { if (factory == null) { factory = new CalendarFactory() { public Calendar create(TimeZone tz, ULocale loc) { return new ChineseCalendar(tz, loc); } public String factoryName() { return "Chinese"; } }; } return factory; } */ }





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