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/*
 *  Copyright 2001-2009 Stephen Colebourne
 *
 *  Licensed under the Apache License, Version 2.0 (the "License");
 *  you may not use this file except in compliance with the License.
 *  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 *  Unless required by applicable law or agreed to in writing, software
 *  distributed under the License is distributed on an "AS IS" BASIS,
 *  WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 *  See the License for the specific language governing permissions and
 *  limitations under the License.
 */
package org.joda.time.chrono;

import java.util.HashMap;
import java.util.Map;

import org.joda.time.Chronology;
import org.joda.time.DateTimeConstants;
import org.joda.time.DateTimeFieldType;
import org.joda.time.DateTimeZone;
import org.joda.time.IllegalFieldValueException;
import org.joda.time.field.SkipDateTimeField;

/**
 * Implements a pure proleptic Julian calendar system, which defines every
 * fourth year as leap. This implementation follows the leap year rule
 * strictly, even for dates before 8 CE, where leap years were actually
 * irregular. In the Julian calendar, year zero does not exist: 1 BCE is
 * followed by 1 CE.
 * 

* Although the Julian calendar did not exist before 45 BCE, this chronology * assumes it did, thus it is proleptic. This implementation also fixes the * start of the year at January 1. *

* JulianChronology is thread-safe and immutable. * * @see Wikipedia * @see GregorianChronology * @see GJChronology * * @author Guy Allard * @author Brian S O'Neill * @author Stephen Colebourne * @since 1.0 */ public final class JulianChronology extends BasicGJChronology { /** Serialization lock */ private static final long serialVersionUID = -8731039522547897247L; private static final long MILLIS_PER_YEAR = (long) (365.25 * DateTimeConstants.MILLIS_PER_DAY); private static final long MILLIS_PER_MONTH = (long) (365.25 * DateTimeConstants.MILLIS_PER_DAY / 12); /** The lowest year that can be fully supported. */ private static final int MIN_YEAR = -292269054; /** The highest year that can be fully supported. */ private static final int MAX_YEAR = 292272992; /** Singleton instance of a UTC JulianChronology */ private static final JulianChronology INSTANCE_UTC; /** Cache of zone to chronology arrays */ private static final Map cCache = new HashMap(); static { INSTANCE_UTC = getInstance(DateTimeZone.UTC); } static int adjustYearForSet(int year) { if (year <= 0) { if (year == 0) { throw new IllegalFieldValueException (DateTimeFieldType.year(), Integer.valueOf(year), null, null); } year++; } return year; } /** * Gets an instance of the JulianChronology. * The time zone of the returned instance is UTC. * * @return a singleton UTC instance of the chronology */ public static JulianChronology getInstanceUTC() { return INSTANCE_UTC; } /** * Gets an instance of the JulianChronology in the default time zone. * * @return a chronology in the default time zone */ public static JulianChronology getInstance() { return getInstance(DateTimeZone.getDefault(), 4); } /** * Gets an instance of the JulianChronology in the given time zone. * * @param zone the time zone to get the chronology in, null is default * @return a chronology in the specified time zone */ public static JulianChronology getInstance(DateTimeZone zone) { return getInstance(zone, 4); } /** * Gets an instance of the JulianChronology in the given time zone. * * @param zone the time zone to get the chronology in, null is default * @param minDaysInFirstWeek minimum number of days in first week of the year; default is 4 * @return a chronology in the specified time zone */ public static JulianChronology getInstance(DateTimeZone zone, int minDaysInFirstWeek) { if (zone == null) { zone = DateTimeZone.getDefault(); } JulianChronology chrono; synchronized (cCache) { JulianChronology[] chronos = cCache.get(zone); if (chronos == null) { chronos = new JulianChronology[7]; cCache.put(zone, chronos); } try { chrono = chronos[minDaysInFirstWeek - 1]; } catch (ArrayIndexOutOfBoundsException e) { throw new IllegalArgumentException ("Invalid min days in first week: " + minDaysInFirstWeek); } if (chrono == null) { if (zone == DateTimeZone.UTC) { chrono = new JulianChronology(null, null, minDaysInFirstWeek); } else { chrono = getInstance(DateTimeZone.UTC, minDaysInFirstWeek); chrono = new JulianChronology (ZonedChronology.getInstance(chrono, zone), null, minDaysInFirstWeek); } chronos[minDaysInFirstWeek - 1] = chrono; } } return chrono; } // Constructors and instance variables //----------------------------------------------------------------------- /** * Restricted constructor */ JulianChronology(Chronology base, Object param, int minDaysInFirstWeek) { super(base, param, minDaysInFirstWeek); } /** * Serialization singleton */ private Object readResolve() { Chronology base = getBase(); int minDays = getMinimumDaysInFirstWeek(); minDays = (minDays == 0 ? 4 : minDays); // handle rename of BaseGJChronology return base == null ? getInstance(DateTimeZone.UTC, minDays) : getInstance(base.getZone(), minDays); } // Conversion //----------------------------------------------------------------------- /** * Gets the Chronology in the UTC time zone. * * @return the chronology in UTC */ public Chronology withUTC() { return INSTANCE_UTC; } /** * Gets the Chronology in a specific time zone. * * @param zone the zone to get the chronology in, null is default * @return the chronology */ public Chronology withZone(DateTimeZone zone) { if (zone == null) { zone = DateTimeZone.getDefault(); } if (zone == getZone()) { return this; } return getInstance(zone); } long getDateMidnightMillis(int year, int monthOfYear, int dayOfMonth) throws IllegalArgumentException { return super.getDateMidnightMillis(adjustYearForSet(year), monthOfYear, dayOfMonth); } boolean isLeapYear(int year) { return (year & 3) == 0; } long calculateFirstDayOfYearMillis(int year) { // Java epoch is 1970-01-01 Gregorian which is 1969-12-19 Julian. // Calculate relative to the nearest leap year and account for the // difference later. int relativeYear = year - 1968; int leapYears; if (relativeYear <= 0) { // Add 3 before shifting right since /4 and >>2 behave differently // on negative numbers. leapYears = (relativeYear + 3) >> 2; } else { leapYears = relativeYear >> 2; // For post 1968 an adjustment is needed as jan1st is before leap day if (!isLeapYear(year)) { leapYears++; } } long millis = (relativeYear * 365L + leapYears) * (long)DateTimeConstants.MILLIS_PER_DAY; // Adjust to account for difference between 1968-01-01 and 1969-12-19. return millis - (366L + 352) * DateTimeConstants.MILLIS_PER_DAY; } int getMinYear() { return MIN_YEAR; } int getMaxYear() { return MAX_YEAR; } long getAverageMillisPerYear() { return MILLIS_PER_YEAR; } long getAverageMillisPerYearDividedByTwo() { return MILLIS_PER_YEAR / 2; } long getAverageMillisPerMonth() { return MILLIS_PER_MONTH; } long getApproxMillisAtEpochDividedByTwo() { return (1969L * MILLIS_PER_YEAR + 352L * DateTimeConstants.MILLIS_PER_DAY) / 2; } protected void assemble(Fields fields) { if (getBase() == null) { super.assemble(fields); // Julian chronology has no year zero. fields.year = new SkipDateTimeField(this, fields.year); fields.weekyear = new SkipDateTimeField(this, fields.weekyear); } } }





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