/* GENERATED SOURCE. DO NOT MODIFY. */ // © 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 android.icu.util; import java.io.IOException; import java.io.ObjectInputStream; import java.util.Date; import java.util.Locale; import java.util.function.IntConsumer; import android.icu.impl.CalendarAstronomer; import android.icu.impl.CalendarCache; import android.icu.impl.CalendarUtil; import android.icu.util.ULocale.Category; /** * IslamicCalendar is a subclass of Calendar * that that implements the Islamic civil and religious calendars. It * is used as the civil calendar in most of the Arab world and the * liturgical calendar of the Islamic faith worldwide. This calendar * is also known as the "Hijri" calendar, since it starts at the time * of Mohammed's emigration (or "hijra") to Medinah on Thursday, * July 15, 622 AD (Julian). *

* The Islamic calendar is strictly lunar, and thus an Islamic year of twelve * lunar months does not correspond to the solar year used by most other * calendar systems, including the Gregorian. An Islamic year is, on average, * about 354 days long, so each successive Islamic year starts about 11 days * earlier in the corresponding Gregorian year. *

* Each month of the calendar starts when the new moon's crescent is visible * at sunset. However, in order to keep the time fields in this class * synchronized with those of the other calendars and with local clock time, * we treat days and months as beginning at midnight, * roughly 6 hours after the corresponding sunset. *

* There are three main variants of the Islamic calendar in existence. The first * is the civil calendar, which uses a fixed cycle of alternating 29- * and 30-day months, with a leap day added to the last month of 11 out of * every 30 years. This calendar is easily calculated and thus predictable in * advance, so it is used as the civil calendar in a number of Arab countries. * This is the default behavior of a newly-created IslamicCalendar * object. *

* The Islamic religious calendar and Saudi Arabia's Umm al-Qura * calendar, however, are based on the observation of the crescent moon. * It is thus affected by the position at which the * observations are made, seasonal variations in the time of sunset, the * eccentricities of the moon's orbit, and even the weather at the observation * site. This makes it impossible to calculate in advance, and it causes the * start of a month in the religious calendar to differ from the civil calendar * by up to three days. *

* Using astronomical calculations for the position of the sun and moon, the * moon's illumination, and other factors, it is possible to determine the start * of a lunar month with a fairly high degree of certainty. However, these * calculations are extremely complicated and thus slow, so most algorithms, * including the one used here, are only approximations of the true astronomical * calculations. At present, the approximations used in this class are fairly * simplistic; they will be improved in later versions of the code. *

* Like the Islamic religious calendar, Umm al-Qura is also based * on the sighting method of the crescent moon but is standardized by Saudi Arabia. *

* The fixed-cycle civil calendar is used. *

* This class should not be subclassed.

*

* IslamicCalendar usually should be instantiated using * {@link android.icu.util.Calendar#getInstance(ULocale)} passing in a ULocale * with the tag "@calendar=islamic" or "@calendar=islamic-civil" * or "@calendar=islamic-umalqura".

* * @see android.icu.util.GregorianCalendar * @see android.icu.util.Calendar * * @author Laura Werner * @author Alan Liu */ public class IslamicCalendar extends Calendar { // jdk1.4.2 serialver private static final long serialVersionUID = -6253365474073869325L; //------------------------------------------------------------------------- // Constants... //------------------------------------------------------------------------- /** * Constant for Muharram, the 1st month of the Islamic year. */ public static final int MUHARRAM = 0; /** * Constant for Safar, the 2nd month of the Islamic year. */ public static final int SAFAR = 1; /** * Constant for Rabi' al-awwal (or Rabi' I), the 3rd month of the Islamic year. */ public static final int RABI_1 = 2; /** * Constant for Rabi' al-thani or (Rabi' II), the 4th month of the Islamic year. */ public static final int RABI_2 = 3; /** * Constant for Jumada al-awwal or (Jumada I), the 5th month of the Islamic year. */ public static final int JUMADA_1 = 4; /** * Constant for Jumada al-thani or (Jumada II), the 6th month of the Islamic year. */ public static final int JUMADA_2 = 5; /** * Constant for Rajab, the 7th month of the Islamic year. */ public static final int RAJAB = 6; /** * Constant for Sha'ban, the 8th month of the Islamic year. */ public static final int SHABAN = 7; /** * Constant for Ramadan, the 9th month of the Islamic year. */ public static final int RAMADAN = 8; /** * Constant for Shawwal, the 10th month of the Islamic year. */ public static final int SHAWWAL = 9; /** * Constant for Dhu al-Qi'dah, the 11th month of the Islamic year. */ public static final int DHU_AL_QIDAH = 10; /** * Constant for Dhu al-Hijjah, the 12th month of the Islamic year. */ public static final int DHU_AL_HIJJAH = 11; private static final long HIJRA_MILLIS = -42521587200000L; // 7/16/622 AD 00:00 /** * Friday EPOCH */ private static final long CIVIL_EPOCH = 1948440; // CE 622 July 16 Friday (Julian calendar) / CE 622 July 19 (Gregorian calendar) // /** * Thursday EPOCH */ private static final long ASTRONOMICAL_EPOCH = 1948439; // CE 622 July 15 Thursday (Julian calendar) //------------------------------------------------------------------------- // Constructors... //------------------------------------------------------------------------- /** * Constructs a default IslamicCalendar using the current time * in the default time zone with the default FORMAT locale. * @see Category#FORMAT */ public IslamicCalendar() { this(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT)); } /** * Constructs an IslamicCalendar based on the current time * in the given time zone with the default FORMAT locale. * @param zone the given time zone. * @see Category#FORMAT */ public IslamicCalendar(TimeZone zone) { this(zone, ULocale.getDefault(Category.FORMAT)); } /** * Constructs an IslamicCalendar based on the current time * in the default time zone with the given locale. * * @param aLocale the given locale. */ public IslamicCalendar(Locale aLocale) { this(TimeZone.forLocaleOrDefault(aLocale), aLocale); } /** * Constructs an IslamicCalendar based on the current time * in the default time zone with the given locale. * * @param locale the given ulocale. */ public IslamicCalendar(ULocale locale) { this(TimeZone.forULocaleOrDefault(locale), locale); } /** * Constructs an IslamicCalendar 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. */ public IslamicCalendar(TimeZone zone, Locale aLocale) { this(zone, ULocale.forLocale(aLocale)); } /** * Constructs an IslamicCalendar 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. */ public IslamicCalendar(TimeZone zone, ULocale locale) { super(zone, locale); setCalcTypeForLocale(locale); setTimeInMillis(System.currentTimeMillis()); } /** * Constructs an IslamicCalendar with the given date set * in the default time zone with the default FORMAT locale. * * @param date The date to which the new calendar is set. * @see Category#FORMAT */ public IslamicCalendar(Date date) { super(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT)); this.setTime(date); } /** * Constructs an IslamicCalendar with the given date set * in 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 Muharram. * @param date the value used to set the {@link #DATE DATE} time field in the calendar. * @see Category#FORMAT */ public IslamicCalendar(int year, int month, int date) { super(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT)); this.set(Calendar.YEAR, year); this.set(Calendar.MONTH, month); this.set(Calendar.DATE, date); } /** * Constructs an IslamicCalendar 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 Muharram. * @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 */ public IslamicCalendar(int year, int month, int date, int hour, int minute, int second) { super(TimeZone.getDefault(), ULocale.getDefault(Category.FORMAT)); this.set(Calendar.YEAR, year); this.set(Calendar.MONTH, month); this.set(Calendar.DATE, date); this.set(Calendar.HOUR_OF_DAY, hour); this.set(Calendar.MINUTE, minute); this.set(Calendar.SECOND, second); } // Private interface for different Islamic calendar algorithms. private interface Algorithm { /** * Returns true if this object is using the fixed-cycle civil * calendar, or false if using the religious, astronomical * calendar. */ public boolean isCivil(); /** * Return the type the algorithm implement. */ public CalculationType getType(); /** * Return the epoch used by this algorithm. */ public long epoch(); /** * Return the day # on which the given year starts. Days are counted * from the Hijri epoch, origin 0. * * @param year The hijri year */ public long yearStart(int year); /** * Return the day # on which the given month starts. Days are counted * from the Hijri epoch, origin 0. * * @param year The hijri year * @param month The hijri month, 0-based */ public long monthStart(int year, int month); /** * Return the length (in days) of the given month. * * @param year The hijri year * @param month The hijri month, 0-based */ public int monthLength(int year, int month); /** * Return the length (in days) of the given year. * * @param year The hijri year */ public int yearLength(int year); /** * Compute the year, month, dayOfMonth, and dayOfYear of the given julian days * and current time and feed the caculuated results to the consumers. * @param julianDays * @param current the time in millisecond. * @param yearConsumer consumer to take the year result. * @param monthConsumer consumer to take the month result. * @param dayOfMonthConsumer consumer to take the dayOfMonth result. * @param dayOfYearConsumer consumer to take the dayOfYear result. */ public void compute(long julianDays, long current, IntConsumer yearConsumer, IntConsumer monthConsumer, IntConsumer dayOfMonthConsumer, IntConsumer dayOfYearConsumer); }; /** * Algorithm which implement the rules for CalculationType.ISLAMIC. */ static private class IslamicAlgorithm implements Algorithm { public boolean isCivil() { return false; } public CalculationType getType() { return CalculationType.ISLAMIC; } public long epoch() { return CIVIL_EPOCH; } public long yearStart(int year) { return monthStart(year, 0); } public long monthStart(int year, int month) { // Normalize year/month in case month is outside the normal bounds, which may occur // in the case of an add operation return trueMonthStart(12*((year + month / 12)-1) + (month % 12)); } public int monthLength(int year, int month) { month += 12*(year-1); return (int)(trueMonthStart(month+1) - trueMonthStart(month)); } public int yearLength(int year) { int month = 12*(year-1); return (int)(trueMonthStart(month + 12) - trueMonthStart(month)); } public void compute(long julianDays, long current, IntConsumer yearConsumer, IntConsumer monthConsumer, IntConsumer dayOfMonthConsumer, IntConsumer dayOfYearConsumer) { long days = julianDays - epoch(); // Guess at the number of elapsed full months since the epoch int month = (int)Math.floor(days / CalendarAstronomer.SYNODIC_MONTH); long monthStart = (long)Math.floor(month * CalendarAstronomer.SYNODIC_MONTH - 1); if (days - monthStart >= 25 && moonAge(current) > 0) { // If we're near the end of the month, assume next month and search backwards month++; } // Find out the last time that the new moon was actually visible at this longitude // This returns midnight the night that the moon was visible at sunset. while ((monthStart = trueMonthStart(month)) > days) { // If it was after the date in question, back up a month and try again month--; } int year = month >= 0 ? ((month / 12) + 1) : ((month + 1 ) / 12); month = ((month % 12) + 12 ) % 12; yearConsumer.accept(year); monthConsumer.accept(month); dayOfMonthConsumer.accept((int)(days - monthStart(year, month)) + 1); dayOfYearConsumer.accept((int)(days - yearStart(year) + 1)); } }; /** * Algorithm which implement the rules for CalculationType.ISLAMIC_CIVIL. */ static private class CivilAlgorithm implements Algorithm { public boolean isCivil() { return true; } public CalculationType getType() { return CalculationType.ISLAMIC_CIVIL; } public long epoch() { return CIVIL_EPOCH; } public long yearStart(int year) { return (year-1)*354 + (long)Math.floor((3+11*year)/30.0); } public long monthStart(int year, int month) { // Normalize year/month in case month is outside the normal bounds, which may occur // in the case of an add operation return (long)Math.ceil(29.5*(month % 12)) + yearStart(year + month / 12); } public int monthLength(int year, int month) { int length = 29; if (month % 2 == 0) { ++length; } if (month == DHU_AL_HIJJAH && civilLeapYear(year)) { ++length; } return length; } public int yearLength(int year) { return 354 + (civilLeapYear(year) ? 1 : 0); } public void compute(long julianDays, long current, IntConsumer yearConsumer, IntConsumer monthConsumer, IntConsumer dayOfMonthConsumer, IntConsumer dayOfYearConsumer) { long days = julianDays - epoch(); // Use the civil calendar approximation, which is just arithmetic int year = (int)Math.floor( (30 * days + 10646) / 10631.0 ); int month = (int)Math.ceil((days - 29 - yearStart(year)) / 29.5 ); month = Math.min(month, 11); yearConsumer.accept(year); monthConsumer.accept(month); dayOfMonthConsumer.accept((int)(days - monthStart(year, month)) + 1); dayOfYearConsumer.accept((int)(days - yearStart(year) + 1)); } }; /** * Algorithm which implement the rules for CalculationType.ISLAMIC_TBLA. * Mostly the same as CivilAlgorithm, except it return false for isCivil and use different * epoch value. */ static private class TBLAAlgorithm extends CivilAlgorithm { public boolean isCivil() { return false; } public CalculationType getType() { return CalculationType.ISLAMIC_TBLA; } public long epoch() { return ASTRONOMICAL_EPOCH; } }; /** * Algorithm which implement the rules for CalculationType.ISLAMIC_UMALQURA. */ static private class UmalquraAlgorithm implements Algorithm { public boolean isCivil() { return false; } public CalculationType getType() { return CalculationType.ISLAMIC_UMALQURA; } public long epoch() { return CIVIL_EPOCH; } public long yearStart(int year) { if (year < UMALQURA_YEAR_START || year > UMALQURA_YEAR_END) { return CIVIL_ALGORITHM.yearStart(year); } int index = year - UMALQURA_YEAR_START; // rounded least-squares fit of the dates previously calculated from UMALQURA_MONTHLENGTH iteration int yrStartLinearEstimate = (int)((354.36720 * index) + 460322.05 + 0.5); // need a slight correction to some return yrStartLinearEstimate + UMALQURA_YEAR_START_ESTIMATE_FIX[index]; } public long monthStart(int year, int month) { // Normalize year/month in case month is outside the normal bounds, which may occur // in the case of an add operation year += month / 12; month %= 12; if (year < UMALQURA_YEAR_START) { return CIVIL_ALGORITHM.monthStart(year, month); } long ms = yearStart(year); for(int i=0; i< month; i++) { ms+= monthLength(year, i); } return ms; } public int monthLength(int year, int month) { if (year < UMALQURA_YEAR_START || year > UMALQURA_YEAR_END) { return CIVIL_ALGORITHM.monthLength(year, month); } int index = (year - UMALQURA_YEAR_START); // calculate year offset into bit map array int mask = (0x01 << (11 - month)); // set mask for bit corresponding to month if((UMALQURA_MONTHLENGTH[index] & mask) != 0) { return 30; } return 29; } public int yearLength(int year) { if (year < UMALQURA_YEAR_START || year > UMALQURA_YEAR_END) { return CIVIL_ALGORITHM.yearLength(year); } int length = 0; for(int i = 0; i < 12; i++) { length += monthLength(year, i); } return length; } public void compute(long julianDays, long current, IntConsumer yearConsumer, IntConsumer monthConsumer, IntConsumer dayOfMonthConsumer, IntConsumer dayOfYearConsumer) { long days = julianDays - epoch(); if( days < yearStart(UMALQURA_YEAR_START)) { CIVIL_ALGORITHM.compute(julianDays, current, yearConsumer, monthConsumer, dayOfMonthConsumer, dayOfYearConsumer); return; } // Estimate a value y which is closer to but not greater than the year. // It is the inverse function of the logic inside yearStart() about the // linear estimate. int year = (int)((days - (460322.05 + 0.5)) / 354.36720) + UMALQURA_YEAR_START - 1; int month = 0; long monthStart; long d = 1; while (d > 0) { year++; d = days - yearStart(year) +1; int yearLength = yearLength(year); if (d == yearLength) { month = 11; break; } else if (d < yearLength) { int monthLen = monthLength(year, month); for (month = 0; d > monthLen; monthLen = monthLength(year, ++month)) { d -= monthLen; } break; } } yearConsumer.accept(year); monthConsumer.accept(month); dayOfMonthConsumer.accept((int)(days - monthStart(year, month)) + 1); dayOfYearConsumer.accept((int)(days - yearStart(year) + 1)); } }; private static Algorithm ISLAMIC_ALGORITHM; private static Algorithm CIVIL_ALGORITHM; private static Algorithm TBLA_ALGORITHM; private static Algorithm UMALQURA_ALGORITHM; static { ISLAMIC_ALGORITHM = new IslamicAlgorithm(); CIVIL_ALGORITHM = new CivilAlgorithm(); TBLA_ALGORITHM = new TBLAAlgorithm(); UMALQURA_ALGORITHM = new UmalquraAlgorithm(); }; /** * Determines whether this object uses the fixed-cycle Islamic civil calendar * or an approximation of the religious, astronomical calendar. * * @param beCivil true to use the civil calendar, * false to use the astronomical calendar. * @apiNote Discouraged: ICU 57 use setCalculationType(CalculationType) instead * @hide unsupported on Android */ public void setCivil(boolean beCivil) { if (beCivil && cType != CalculationType.ISLAMIC_CIVIL) { // The fields of the calendar will become invalid, because the calendar // rules are different long m = getTimeInMillis(); cType = CalculationType.ISLAMIC_CIVIL; algorithm = CIVIL_ALGORITHM; clear(); setTimeInMillis(m); } else if(!beCivil && cType != CalculationType.ISLAMIC) { // The fields of the calendar will become invalid, because the calendar // rules are different long m = getTimeInMillis(); cType = CalculationType.ISLAMIC; algorithm = ISLAMIC_ALGORITHM; clear(); setTimeInMillis(m); } civil = algorithm.isCivil(); } /** * Returns true if this object is using the fixed-cycle civil * calendar, or false if using the religious, astronomical * calendar. * @apiNote Discouraged: ICU 57 use getCalculationType() instead * @hide unsupported on Android */ public boolean isCivil() { return algorithm.isCivil(); } //------------------------------------------------------------------------- // Minimum / Maximum access functions //------------------------------------------------------------------------- // Note: Current IslamicCalendar implementation does not work // well with negative years. private static final int LIMITS[][] = { // Minimum Greatest Least Maximum // Minimum Maximum { 0, 0, 0, 0}, // ERA { 1, 1, 5000000, 5000000}, // YEAR { 0, 0, 11, 11}, // MONTH { 1, 1, 50, 51}, // WEEK_OF_YEAR {/* */}, // WEEK_OF_MONTH { 1, 1, 29, 30}, // DAY_OF_MONTH { 1, 1, 354, 355}, // 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 { 1, 1, 5000000, 5000000}, // YEAR_WOY {/* */}, // DOW_LOCAL { 1, 1, 5000000, 5000000}, // EXTENDED_YEAR {/* */}, // JULIAN_DAY {/* */}, // MILLISECONDS_IN_DAY {/* */}, // IS_LEAP_MONTH { 0, 0, 11, 11 }, // ORDINAL_MONTH }; /* * bit map array where a bit turned on represents a month with 30 days. */ private static final int[] UMALQURA_MONTHLENGTH = { //* 1300 -1302 */ "1010 1010 1010", "1101 0101 0100", "1110 1100 1001", 0x0AAA, 0x0D54, 0x0EC9, //* 1303 -1307 */ "0110 1101 0100", "0110 1110 1010", "0011 0110 1100", "1010 1010 1101", "0101 0101 0101", 0x06D4, 0x06EA, 0x036C, 0x0AAD, 0x0555, //* 1308 -1312 */ "0110 1010 1001", "0111 1001 0010", "1011 1010 1001", "0101 1101 0100", "1010 1101 1010", 0x06A9, 0x0792, 0x0BA9, 0x05D4, 0x0ADA, //* 1313 -1317 */ "0101 0101 1100", "1101 0010 1101", "0110 1001 0101", "0111 0100 1010", "1011 0101 0100", 0x055C, 0x0D2D, 0x0695, 0x074A, 0x0B54, //* 1318 -1322 */ "1011 0110 1010", "0101 1010 1101", "0100 1010 1110", "1010 0100 1111", "0101 0001 0111", 0x0B6A, 0x05AD, 0x04AE, 0x0A4F, 0x0517, //* 1323 -1327 */ "0110 1000 1011", "0110 1010 0101", "1010 1101 0101", "0010 1101 0110", "1001 0101 1011", 0x068B, 0x06A5, 0x0AD5, 0x02D6, 0x095B, //* 1328 -1332 */ "0100 1001 1101", "1010 0100 1101", "1101 0010 0110", "1101 1001 0101", "0101 1010 1100", 0x049D, 0x0A4D, 0x0D26, 0x0D95, 0x05AC, //* 1333 -1337 */ "1001 1011 0110", "0010 1011 1010", "1010 0101 1011", "0101 0010 1011", "1010 1001 0101", 0x09B6, 0x02BA, 0x0A5B, 0x052B, 0x0A95, //* 1338 -1342 */ "0110 1100 1010", "1010 1110 1001", "0010 1111 0100", "1001 0111 0110", "0010 1011 0110", 0x06CA, 0x0AE9, 0x02F4, 0x0976, 0x02B6, //* 1343 -1347 */ "1001 0101 0110", "1010 1100 1010", "1011 1010 0100", "1011 1101 0010", "0101 1101 1001", 0x0956, 0x0ACA, 0x0BA4, 0x0BD2, 0x05D9, //* 1348 -1352 */ "0010 1101 1100", "1001 0110 1101", "0101 0100 1101", "1010 1010 0101", "1011 0101 0010", 0x02DC, 0x096D, 0x054D, 0x0AA5, 0x0B52, //* 1353 -1357 */ "1011 1010 0101", "0101 1011 0100", "1001 1011 0110", "0101 0101 0111", "0010 1001 0111", 0x0BA5, 0x05B4, 0x09B6, 0x0557, 0x0297, //* 1358 -1362 */ "0101 0100 1011", "0110 1010 0011", "0111 0101 0010", "1011 0110 0101", "0101 0110 1010", 0x054B, 0x06A3, 0x0752, 0x0B65, 0x056A, //* 1363 -1367 */ "1010 1010 1011", "0101 0010 1011", "1100 1001 0101", "1101 0100 1010", "1101 1010 0101", 0x0AAB, 0x052B, 0x0C95, 0x0D4A, 0x0DA5, //* 1368 -1372 */ "0101 1100 1010", "1010 1101 0110", "1001 0101 0111", "0100 1010 1011", "1001 0100 1011", 0x05CA, 0x0AD6, 0x0957, 0x04AB, 0x094B, //* 1373 -1377 */ "1010 1010 0101", "1011 0101 0010", "1011 0110 1010", "0101 0111 0101", "0010 0111 0110", 0x0AA5, 0x0B52, 0x0B6A, 0x0575, 0x0276, //* 1378 -1382 */ "1000 1011 0111", "0100 0101 1011", "0101 0101 0101", "0101 1010 1001", "0101 1011 0100", 0x08B7, 0x045B, 0x0555, 0x05A9, 0x05B4, //* 1383 -1387 */ "1001 1101 1010", "0100 1101 1101", "0010 0110 1110", "1001 0011 0110", "1010 1010 1010", 0x09DA, 0x04DD, 0x026E, 0x0936, 0x0AAA, //* 1388 -1392 */ "1101 0101 0100", "1101 1011 0010", "0101 1101 0101", "0010 1101 1010", "1001 0101 1011", 0x0D54, 0x0DB2, 0x05D5, 0x02DA, 0x095B, //* 1393 -1397 */ "0100 1010 1011", "1010 0101 0101", "1011 0100 1001", "1011 0110 0100", "1011 0111 0001", 0x04AB, 0x0A55, 0x0B49, 0x0B64, 0x0B71, //* 1398 -1402 */ "0101 1011 0100", "1010 1011 0101", "1010 0101 0101", "1101 0010 0101", "1110 1001 0010", 0x05B4, 0x0AB5, 0x0A55, 0x0D25, 0x0E92, //* 1403 -1407 */ "1110 1100 1001", "0110 1101 0100", "1010 1110 1001", "1001 0110 1011", "0100 1010 1011", 0x0EC9, 0x06D4, 0x0AE9, 0x096B, 0x04AB, //* 1408 -1412 */ "1010 1001 0011", "1101 0100 1001", "1101 1010 0100", "1101 1011 0010", "1010 1011 1001", 0x0A93, 0x0D49, 0x0DA4, 0x0DB2, 0x0AB9, //* 1413 -1417 */ "0100 1011 1010", "1010 0101 1011", "0101 0010 1011", "1010 1001 0101", "1011 0010 1010", 0x04BA, 0x0A5B, 0x052B, 0x0A95, 0x0B2A, //* 1418 -1422 */ "1011 0101 0101", "0101 0101 1100", "0100 1011 1101", "0010 0011 1101", "1001 0001 1101", 0x0B55, 0x055C, 0x04BD, 0x023D, 0x091D, //* 1423 -1427 */ "1010 1001 0101", "1011 0100 1010", "1011 0101 1010", "0101 0110 1101", "0010 1011 0110", 0x0A95, 0x0B4A, 0x0B5A, 0x056D, 0x02B6, //* 1428 -1432 */ "1001 0011 1011", "0100 1001 1011", "0110 0101 0101", "0110 1010 1001", "0111 0101 0100", 0x093B, 0x049B, 0x0655, 0x06A9, 0x0754, //* 1433 -1437 */ "1011 0110 1010", "0101 0110 1100", "1010 1010 1101", "0101 0101 0101", "1011 0010 1001", 0x0B6A, 0x056C, 0x0AAD, 0x0555, 0x0B29, //* 1438 -1442 */ "1011 1001 0010", "1011 1010 1001", "0101 1101 0100", "1010 1101 1010", "0101 0101 1010", 0x0B92, 0x0BA9, 0x05D4, 0x0ADA, 0x055A, //* 1443 -1447 */ "1010 1010 1011", "0101 1001 0101", "0111 0100 1001", "0111 0110 0100", "1011 1010 1010", 0x0AAB, 0x0595, 0x0749, 0x0764, 0x0BAA, //* 1448 -1452 */ "0101 1011 0101", "0010 1011 0110", "1010 0101 0110", "1110 0100 1101", "1011 0010 0101", 0x05B5, 0x02B6, 0x0A56, 0x0E4D, 0x0B25, //* 1453 -1457 */ "1011 0101 0010", "1011 0110 1010", "0101 1010 1101", "0010 1010 1110", "1001 0010 1111", 0x0B52, 0x0B6A, 0x05AD, 0x02AE, 0x092F, //* 1458 -1462 */ "0100 1001 0111", "0110 0100 1011", "0110 1010 0101", "0110 1010 1100", "1010 1101 0110", 0x0497, 0x064B, 0x06A5, 0x06AC, 0x0AD6, //* 1463 -1467 */ "0101 0101 1101", "0100 1001 1101", "1010 0100 1101", "1101 0001 0110", "1101 1001 0101", 0x055D, 0x049D, 0x0A4D, 0x0D16, 0x0D95, //* 1468 -1472 */ "0101 1010 1010", "0101 1011 0101", "0010 1101 1010", "1001 0101 1011", "0100 1010 1101", 0x05AA, 0x05B5, 0x02DA, 0x095B, 0x04AD, //* 1473 -1477 */ "0101 1001 0101", "0110 1100 1010", "0110 1110 0100", "1010 1110 1010", "0100 1111 0101", 0x0595, 0x06CA, 0x06E4, 0x0AEA, 0x04F5, //* 1478 -1482 */ "0010 1011 0110", "1001 0101 0110", "1010 1010 1010", "1011 0101 0100", "1011 1101 0010", 0x02B6, 0x0956, 0x0AAA, 0x0B54, 0x0BD2, //* 1483 -1487 */ "0101 1101 1001", "0010 1110 1010", "1001 0110 1101", "0100 1010 1101", "1010 1001 0101", 0x05D9, 0x02EA, 0x096D, 0x04AD, 0x0A95, //* 1488 -1492 */ "1011 0100 1010", "1011 1010 0101", "0101 1011 0010", "1001 1011 0101", "0100 1101 0110", 0x0B4A, 0x0BA5, 0x05B2, 0x09B5, 0x04D6, //* 1493 -1497 */ "1010 1001 0111", "0101 0100 0111", "0110 1001 0011", "0111 0100 1001", "1011 0101 0101", 0x0A97, 0x0547, 0x0693, 0x0749, 0x0B55, //* 1498 -1508 */ "0101 0110 1010", "1010 0110 1011", "0101 0010 1011", "1010 1000 1011", "1101 0100 0110", "1101 1010 0011", "0101 1100 1010", "1010 1101 0110", "0100 1101 1011", "0010 0110 1011", "1001 0100 1011", 0x056A, 0x0A6B, 0x052B, 0x0A8B, 0x0D46, 0x0DA3, 0x05CA, 0x0AD6, 0x04DB, 0x026B, 0x094B, //* 1509 -1519 */ "1010 1010 0101", "1011 0101 0010", "1011 0110 1001", "0101 0111 0101", "0001 0111 0110", "1000 1011 0111", "0010 0101 1011", "0101 0010 1011", "0101 0110 0101", "0101 1011 0100", "1001 1101 1010", 0x0AA5, 0x0B52, 0x0B69, 0x0575, 0x0176, 0x08B7, 0x025B, 0x052B, 0x0565, 0x05B4, 0x09DA, //* 1520 -1530 */ "0100 1110 1101", "0001 0110 1101", "1000 1011 0110", "1010 1010 0110", "1101 0101 0010", "1101 1010 1001", "0101 1101 0100", "1010 1101 1010", "1001 0101 1011", "0100 1010 1011", "0110 0101 0011", 0x04ED, 0x016D, 0x08B6, 0x0AA6, 0x0D52, 0x0DA9, 0x05D4, 0x0ADA, 0x095B, 0x04AB, 0x0653, //* 1531 -1541 */ "0111 0010 1001", "0111 0110 0010", "1011 1010 1001", "0101 1011 0010", "1010 1011 0101", "0101 0101 0101", "1011 0010 0101", "1101 1001 0010", "1110 1100 1001", "0110 1101 0010", "1010 1110 1001", 0x0729, 0x0762, 0x0BA9, 0x05B2, 0x0AB5, 0x0555, 0x0B25, 0x0D92, 0x0EC9, 0x06D2, 0x0AE9, //* 1542 -1552 */ "0101 0110 1011", "0100 1010 1011", "1010 0101 0101", "1101 0010 1001", "1101 0101 0100", "1101 1010 1010", "1001 1011 0101", "0100 1011 1010", "1010 0011 1011", "0100 1001 1011", "1010 0100 1101", 0x056B, 0x04AB, 0x0A55, 0x0D29, 0x0D54, 0x0DAA, 0x09B5, 0x04BA, 0x0A3B, 0x049B, 0x0A4D, //* 1553 -1563 */ "1010 1010 1010", "1010 1101 0101", "0010 1101 1010", "1001 0101 1101", "0100 0101 1110", "1010 0010 1110", "1100 1001 1010", "1101 0101 0101", "0110 1011 0010", "0110 1011 1001", "0100 1011 1010", 0x0AAA, 0x0AD5, 0x02DA, 0x095D, 0x045E, 0x0A2E, 0x0C9A, 0x0D55, 0x06B2, 0x06B9, 0x04BA, //* 1564 -1574 */ "1010 0101 1101", "0101 0010 1101", "1010 1001 0101", "1011 0101 0010", "1011 1010 1000", "1011 1011 0100", "0101 1011 1001", "0010 1101 1010", "1001 0101 1010", "1011 0100 1010", "1101 1010 0100", 0x0A5D, 0x052D, 0x0A95, 0x0B52, 0x0BA8, 0x0BB4, 0x05B9, 0x02DA, 0x095A, 0x0B4A, 0x0DA4, //* 1575 -1585 */ "1110 1101 0001", "0110 1110 1000", "1011 0110 1010", "0101 0110 1101", "0101 0011 0101", "0110 1001 0101", "1101 0100 1010", "1101 1010 1000", "1101 1101 0100", "0110 1101 1010", "0101 0101 1011", 0x0ED1, 0x06E8, 0x0B6A, 0x056D, 0x0535, 0x0695, 0x0D4A, 0x0DA8, 0x0DD4, 0x06DA, 0x055B, //* 1586 -1596 */ "0010 1001 1101", "0110 0010 1011", "1011 0001 0101", "1011 0100 1010", "1011 1001 0101", "0101 1010 1010", "1010 1010 1110", "1001 0010 1110", "1100 1000 1111", "0101 0010 0111", "0110 1001 0101", 0x029D, 0x062B, 0x0B15, 0x0B4A, 0x0B95, 0x05AA, 0x0AAE, 0x092E, 0x0C8F, 0x0527, 0x0695, //* 1597 -1600 */ "0110 1010 1010", "1010 1101 0110", "0101 0101 1101", "0010 1001 1101", }; 0x06AA, 0x0AD6, 0x055D, 0x029D }; private static final int UMALQURA_YEAR_START = 1300; private static final int UMALQURA_YEAR_END = 1600; /** */ @Override protected int handleGetLimit(int field, int limitType) { return LIMITS[field][limitType]; } //------------------------------------------------------------------------- // Assorted calculation utilities // // we could compress this down more if we need to private static final byte[] UMALQURA_YEAR_START_ESTIMATE_FIX = { 0, 0, -1, 0, -1, 0, 0, 0, 0, 0, // 1300.. -1, 0, 0, 0, 0, 0, 0, 0, -1, 0, // 1310.. 1, 0, 1, 1, 0, 0, 0, 0, 1, 0, // 1320.. 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, // 1330.. 0, 0, 1, 0, 0, -1, -1, 0, 0, 0, // 1340.. 1, 0, 0, -1, 0, 0, 0, 1, 1, 0, // 1350.. 0, 0, 0, 0, 0, 0, 0, -1, 0, 0, // 1360.. 0, 1, 1, 0, 0, -1, 0, 1, 0, 1, // 1370.. 1, 0, 0, -1, 0, 1, 0, 0, 0, -1, // 1380.. 0, 1, 0, 1, 0, 0, 0, -1, 0, 0, // 1390.. 0, 0, -1, -1, 0, -1, 0, 1, 0, 0, // 1400.. 0, -1, 0, 0, 0, 1, 0, 0, 0, 0, // 1410.. 0, 1, 0, 0, -1, -1, 0, 0, 0, 1, // 1420.. 0, 0, -1, -1, 0, -1, 0, 0, -1, -1, // 1430.. 0, -1, 0, -1, 0, 0, -1, -1, 0, 0, // 1440.. 0, 0, 0, 0, -1, 0, 1, 0, 1, 1, // 1450.. 0, 0, -1, 0, 1, 0, 0, 0, 0, 0, // 1460.. 1, 0, 1, 0, 0, 0, -1, 0, 1, 0, // 1470.. 0, -1, -1, 0, 0, 0, 1, 0, 0, 0, // 1480.. 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, // 1490.. 1, 0, 0, -1, 0, 0, 0, 1, 1, 0, // 1500.. 0, -1, 0, 1, 0, 1, 1, 0, 0, 0, // 1510.. 0, 1, 0, 0, 0, -1, 0, 0, 0, 1, // 1520.. 0, 0, 0, -1, 0, 0, 0, 0, 0, -1, // 1530.. 0, -1, 0, 1, 0, 0, 0, -1, 0, 1, // 1540.. 0, 1, 0, 0, 0, 0, 0, 1, 0, 0, // 1550.. -1, 0, 0, 0, 0, 1, 0, 0, 0, -1, // 1560.. 0, 0, 0, 0, -1, -1, 0, -1, 0, 1, // 1570.. 0, 0, -1, -1, 0, 0, 1, 1, 0, 0, // 1580.. -1, 0, 0, 0, 0, 1, 0, 0, 0, 0, // 1590.. 1 // 1600 }; // Unused code - Alan 2003-05 // /** // * Find the day of the week for a given day // * // * @param day The # of days since the start of the Islamic calendar. // */ // // private and uncalled, perhaps not used yet? // private static final int absoluteDayToDayOfWeek(long day) // { // // Calculate the day of the week. // // This relies on the fact that the epoch was a Thursday. // int dayOfWeek = (int)(day + THURSDAY) % 7 + SUNDAY; // if (dayOfWeek < 0) { // dayOfWeek += 7; // } // return dayOfWeek; // } /** * Determine whether a year is a leap year in the Islamic civil calendar */ private final static boolean civilLeapYear(int year) { return (14 + 11 * year) % 30 < 11; } /** * Return the day # on which the given year starts. Days are counted * from the Hijri epoch, origin 0. */ private long yearStart(int year) { return algorithm.yearStart(year); } /** * Find the day number on which a particular month of the true/lunar * Islamic calendar starts. * * @param month The month in question, origin 0 from the Hijri epoch * * @return The day number on which the given month starts. */ private static final long trueMonthStart(long month) { long start = cache.get(month); if (start == CalendarCache.EMPTY) { // Make a guess at when the month started, using the average length long origin = HIJRA_MILLIS + (long)Math.floor(month * CalendarAstronomer.SYNODIC_MONTH) * ONE_DAY; double age = moonAge(origin); if (moonAge(origin) >= 0) { // The month has already started do { origin -= ONE_DAY; age = moonAge(origin); } while (age >= 0); } else { // Preceding month has not ended yet. do { origin += ONE_DAY; age = moonAge(origin); } while (age < 0); } start = (origin - HIJRA_MILLIS) / ONE_DAY + 1; cache.put(month, start); } return start; } /** * Return the "age" of the moon at the given time; this is the difference * in ecliptic latitude between the moon and the sun. This method simply * calls CalendarAstronomer.moonAge, converts to degrees, * and adjusts the resultto be in the range [-180, 180]. * * @param time The time at which the moon's age is desired, * in millis since 1/1/1970. */ static final double moonAge(long time) { double age = (new CalendarAstronomer(time)).getMoonAge(); // Convert to degrees and normalize... age = age * 180 / Math.PI; if (age > 180) { age = age - 360; } return age; } //------------------------------------------------------------------------- // Internal data.... // private static CalendarCache cache = new CalendarCache(); /** * true if this object uses the fixed-cycle Islamic civil calendar, * and false if it approximates the true religious calendar using * astronomical calculations for the time of the new moon. * * @serial */ private boolean civil = true; /** * determines the type of calculation to use for this instance * * @serial */ private CalculationType cType = CalculationType.ISLAMIC_CIVIL; private transient Algorithm algorithm = CIVIL_ALGORITHM; //---------------------------------------------------------------------- // Calendar framework //---------------------------------------------------------------------- /** * Return the length (in days) of the given month. * * @param extendedYear The hijri year * @param month The hijri month, 0-based */ @Override protected int handleGetMonthLength(int extendedYear, int month) { return algorithm.monthLength(extendedYear, month); } /** * Return the number of days in the given Islamic year */ @Override protected int handleGetYearLength(int extendedYear) { return algorithm.yearLength(extendedYear); } //------------------------------------------------------------------------- // Functions for converting from field values to milliseconds.... //------------------------------------------------------------------------- // Return JD of start of given month/year // Calendar says: // Get the Julian day of the day BEFORE the start of this year. // If useMonth is true, get the day before the start of the month. // Hence the -1 /** */ @Override protected int handleComputeMonthStart(int eyear, int month, boolean useMonth) { return (int)(algorithm.monthStart(eyear, month) + algorithm.epoch()- 1); } //------------------------------------------------------------------------- // Functions for converting from milliseconds to field values //------------------------------------------------------------------------- /** */ @Override protected int handleGetExtendedYear() { int year; if (newerField(EXTENDED_YEAR, YEAR) == EXTENDED_YEAR) { year = internalGet(EXTENDED_YEAR, 1); // Default to year 1 } else { year = internalGet(YEAR, 1); // Default to year 1 } return year; } /** * Override Calendar to compute several fields specific to the Islamic * calendar system. These are: * * * * 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. */ @Override protected void handleComputeFields(int julianDay) { algorithm.compute(julianDay, internalGetTimeInMillis(), year -> { internalSet(ERA, 0); internalSet(YEAR, year); internalSet(EXTENDED_YEAR, year); }, month -> { internalSet(MONTH, month); internalSet(ORDINAL_MONTH, month); }, dayOfMonth -> { internalSet(DAY_OF_MONTH, dayOfMonth); }, dayOfYear -> { internalSet(DAY_OF_YEAR, dayOfYear); }); } /** * enumeration of available calendar calculation types */ public enum CalculationType { /** * Religious calendar (astronomical simulation) */ ISLAMIC ("islamic"), /** * Tabular (intercalary years [2,5,7,10,13,16,18,21,24,26,29]) algorithm * with civil (Friday) epoch. */ ISLAMIC_CIVIL ("islamic-civil"), /** * Umm al-Qura calendar */ ISLAMIC_UMALQURA ("islamic-umalqura"), /** * Tabular (intercalary years [2,5,7,10,13,16,18,21,24,26,29]) algorithm * with astronomical (Thursday) epoch. */ ISLAMIC_TBLA ("islamic-tbla"); private String bcpType; CalculationType(String bcpType) { this.bcpType = bcpType; } String bcpType() { return bcpType; } }; /** * sets the calculation type for this calendar. */ public void setCalculationType(CalculationType type) { cType = type; switch (cType) { case ISLAMIC_UMALQURA: algorithm = UMALQURA_ALGORITHM; break; case ISLAMIC: algorithm = ISLAMIC_ALGORITHM; break; case ISLAMIC_TBLA: algorithm = TBLA_ALGORITHM; break; case ISLAMIC_CIVIL: default: algorithm = CIVIL_ALGORITHM; break; } civil = algorithm.isCivil(); } /** * gets the calculation type for this calendar. */ public CalculationType getCalculationType() { return algorithm.getType(); } /** * set type based on locale */ private void setCalcTypeForLocale(ULocale locale) { String localeCalType = CalendarUtil.getCalendarType(locale); if("islamic-civil".equals(localeCalType)) setCalculationType(CalculationType.ISLAMIC_CIVIL); else if("islamic-umalqura".equals(localeCalType)) setCalculationType(CalculationType.ISLAMIC_UMALQURA); else if("islamic-tbla".equals(localeCalType)) setCalculationType(CalculationType.ISLAMIC_TBLA); else if(localeCalType.startsWith("islamic")) setCalculationType(CalculationType.ISLAMIC); // needs to be last so it's always the default if it's islamic-something-unhandled else setCalculationType(CalculationType.ISLAMIC_CIVIL); // default for any non-islamic calendar locale } /** * {@inheritDoc} */ @Override public String getType() { return algorithm.getType().bcpType(); } private void readObject(ObjectInputStream in) throws IOException,ClassNotFoundException { in.defaultReadObject(); if (cType == null) { // The serialized data was created by an ICU version before CalculationType // was introduced. cType = civil ? CalculationType.ISLAMIC_CIVIL : CalculationType.ISLAMIC; } setCalculationType(cType); } //------------------------------------------------------------------------- // Temporal Calendar API. //------------------------------------------------------------------------- /** * [icu] Returns true if the date is in a leap year. Recalculate the current time * field values if the time value has been changed by a call to setTime(). * This method is semantically const, but may alter the object in memory. * A "leap year" is a year that contains more days than other years (for * solar or lunar calendars) or more months than other years (for lunisolar * calendars like Hebrew or Chinese), as defined in the ECMAScript Temporal * proposal. * @return true if the date in the fields is in a Temporal proposal * defined leap year. False otherwise. * @hide draft / provisional / internal are hidden on Android */ public boolean inTemporalLeapYear() { return getActualMaximum(DAY_OF_YEAR) == 355; } //------------------------------------------------------------------------- // End of Temporal Calendar API //------------------------------------------------------------------------- /* private static CalendarFactory factory; public static CalendarFactory factory() { if (factory == null) { factory = new CalendarFactory() { public Calendar create(TimeZone tz, ULocale loc) { return new IslamicCalendar(tz, loc); } public String factoryName() { return "Islamic"; } }; } return factory; } */ }