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Example 1 with CalendarSystem

use of sun.util.calendar.CalendarSystem in project j2objc by google.

the class Date method normalize.

private final BaseCalendar.Date normalize() {
    if (cdate == null) {
        BaseCalendar cal = getCalendarSystem(fastTime);
        cdate = (BaseCalendar.Date) cal.getCalendarDate(fastTime, TimeZone.getDefaultRef());
        return cdate;
    }
    // required for the compatible behavior.
    if (!cdate.isNormalized()) {
        cdate = normalize(cdate);
    }
    // If the default TimeZone has changed, then recalculate the
    // fields with the new TimeZone.
    TimeZone tz = TimeZone.getDefaultRef();
    if (tz != cdate.getZone()) {
        cdate.setZone(tz);
        CalendarSystem cal = getCalendarSystem(cdate);
        cal.getCalendarDate(fastTime, cdate);
    }
    return cdate;
}
Also used : BaseCalendar(sun.util.calendar.BaseCalendar) CalendarSystem(sun.util.calendar.CalendarSystem)

Example 2 with CalendarSystem

use of sun.util.calendar.CalendarSystem in project j2objc by google.

the class GregorianCalendar method getActualMaximum.

/**
     * Returns the maximum value that this calendar field could have,
     * taking into consideration the given time value and the current
     * values of the
     * {@link Calendar#getFirstDayOfWeek() getFirstDayOfWeek},
     * {@link Calendar#getMinimalDaysInFirstWeek() getMinimalDaysInFirstWeek},
     * {@link #getGregorianChange() getGregorianChange} and
     * {@link Calendar#getTimeZone() getTimeZone} methods.
     * For example, if the date of this instance is February 1, 2004,
     * the actual maximum value of the <code>DAY_OF_MONTH</code> field
     * is 29 because 2004 is a leap year, and if the date of this
     * instance is February 1, 2005, it's 28.
     *
     * <p>This method calculates the maximum value of {@link
     * Calendar#WEEK_OF_YEAR WEEK_OF_YEAR} based on the {@link
     * Calendar#YEAR YEAR} (calendar year) value, not the <a
     * href="#week_year">week year</a>. Call {@link
     * #getWeeksInWeekYear()} to get the maximum value of {@code
     * WEEK_OF_YEAR} in the week year of this {@code GregorianCalendar}.
     *
     * @param field the calendar field
     * @return the maximum of the given field for the time value of
     * this <code>GregorianCalendar</code>
     * @see #getMinimum(int)
     * @see #getMaximum(int)
     * @see #getGreatestMinimum(int)
     * @see #getLeastMaximum(int)
     * @see #getActualMinimum(int)
     * @since 1.2
     */
public int getActualMaximum(int field) {
    final int fieldsForFixedMax = ERA_MASK | DAY_OF_WEEK_MASK | HOUR_MASK | AM_PM_MASK | HOUR_OF_DAY_MASK | MINUTE_MASK | SECOND_MASK | MILLISECOND_MASK | ZONE_OFFSET_MASK | DST_OFFSET_MASK;
    if ((fieldsForFixedMax & (1 << field)) != 0) {
        return getMaximum(field);
    }
    GregorianCalendar gc = getNormalizedCalendar();
    BaseCalendar.Date date = gc.cdate;
    BaseCalendar cal = gc.calsys;
    int normalizedYear = date.getNormalizedYear();
    int value = -1;
    switch(field) {
        case MONTH:
            {
                if (!gc.isCutoverYear(normalizedYear)) {
                    value = DECEMBER;
                    break;
                }
                // January 1 of the next year may or may not exist.
                long nextJan1;
                do {
                    nextJan1 = gcal.getFixedDate(++normalizedYear, BaseCalendar.JANUARY, 1, null);
                } while (nextJan1 < gregorianCutoverDate);
                BaseCalendar.Date d = (BaseCalendar.Date) date.clone();
                cal.getCalendarDateFromFixedDate(d, nextJan1 - 1);
                value = d.getMonth() - 1;
            }
            break;
        case DAY_OF_MONTH:
            {
                value = cal.getMonthLength(date);
                if (!gc.isCutoverYear(normalizedYear) || date.getDayOfMonth() == value) {
                    break;
                }
                // Handle cutover year.
                long fd = gc.getCurrentFixedDate();
                if (fd >= gregorianCutoverDate) {
                    break;
                }
                int monthLength = gc.actualMonthLength();
                long monthEnd = gc.getFixedDateMonth1(gc.cdate, fd) + monthLength - 1;
                // Convert the fixed date to its calendar date.
                BaseCalendar.Date d = gc.getCalendarDate(monthEnd);
                value = d.getDayOfMonth();
            }
            break;
        case DAY_OF_YEAR:
            {
                if (!gc.isCutoverYear(normalizedYear)) {
                    value = cal.getYearLength(date);
                    break;
                }
                // Handle cutover year.
                long jan1;
                if (gregorianCutoverYear == gregorianCutoverYearJulian) {
                    BaseCalendar cocal = gc.getCutoverCalendarSystem();
                    jan1 = cocal.getFixedDate(normalizedYear, 1, 1, null);
                } else if (normalizedYear == gregorianCutoverYearJulian) {
                    jan1 = cal.getFixedDate(normalizedYear, 1, 1, null);
                } else {
                    jan1 = gregorianCutoverDate;
                }
                // January 1 of the next year may or may not exist.
                long nextJan1 = gcal.getFixedDate(++normalizedYear, 1, 1, null);
                if (nextJan1 < gregorianCutoverDate) {
                    nextJan1 = gregorianCutoverDate;
                }
                assert jan1 <= cal.getFixedDate(date.getNormalizedYear(), date.getMonth(), date.getDayOfMonth(), date);
                assert nextJan1 >= cal.getFixedDate(date.getNormalizedYear(), date.getMonth(), date.getDayOfMonth(), date);
                value = (int) (nextJan1 - jan1);
            }
            break;
        case WEEK_OF_YEAR:
            {
                if (!gc.isCutoverYear(normalizedYear)) {
                    // Get the day of week of January 1 of the year
                    CalendarDate d = cal.newCalendarDate(TimeZone.NO_TIMEZONE);
                    d.setDate(date.getYear(), BaseCalendar.JANUARY, 1);
                    int dayOfWeek = cal.getDayOfWeek(d);
                    // Normalize the day of week with the firstDayOfWeek value
                    dayOfWeek -= getFirstDayOfWeek();
                    if (dayOfWeek < 0) {
                        dayOfWeek += 7;
                    }
                    value = 52;
                    int magic = dayOfWeek + getMinimalDaysInFirstWeek() - 1;
                    if ((magic == 6) || (date.isLeapYear() && (magic == 5 || magic == 12))) {
                        value++;
                    }
                    break;
                }
                if (gc == this) {
                    gc = (GregorianCalendar) gc.clone();
                }
                int maxDayOfYear = getActualMaximum(DAY_OF_YEAR);
                gc.set(DAY_OF_YEAR, maxDayOfYear);
                value = gc.get(WEEK_OF_YEAR);
                if (internalGet(YEAR) != gc.getWeekYear()) {
                    gc.set(DAY_OF_YEAR, maxDayOfYear - 7);
                    value = gc.get(WEEK_OF_YEAR);
                }
            }
            break;
        case WEEK_OF_MONTH:
            {
                if (!gc.isCutoverYear(normalizedYear)) {
                    CalendarDate d = cal.newCalendarDate(null);
                    d.setDate(date.getYear(), date.getMonth(), 1);
                    int dayOfWeek = cal.getDayOfWeek(d);
                    int monthLength = cal.getMonthLength(d);
                    dayOfWeek -= getFirstDayOfWeek();
                    if (dayOfWeek < 0) {
                        dayOfWeek += 7;
                    }
                    // # of days in the first week
                    int nDaysFirstWeek = 7 - dayOfWeek;
                    value = 3;
                    if (nDaysFirstWeek >= getMinimalDaysInFirstWeek()) {
                        value++;
                    }
                    monthLength -= nDaysFirstWeek + 7 * 3;
                    if (monthLength > 0) {
                        value++;
                        if (monthLength > 7) {
                            value++;
                        }
                    }
                    break;
                }
                // Cutover year handling
                if (gc == this) {
                    gc = (GregorianCalendar) gc.clone();
                }
                int y = gc.internalGet(YEAR);
                int m = gc.internalGet(MONTH);
                do {
                    value = gc.get(WEEK_OF_MONTH);
                    gc.add(WEEK_OF_MONTH, +1);
                } while (gc.get(YEAR) == y && gc.get(MONTH) == m);
            }
            break;
        case DAY_OF_WEEK_IN_MONTH:
            {
                // may be in the Gregorian cutover month
                int ndays, dow1;
                int dow = date.getDayOfWeek();
                if (!gc.isCutoverYear(normalizedYear)) {
                    BaseCalendar.Date d = (BaseCalendar.Date) date.clone();
                    ndays = cal.getMonthLength(d);
                    d.setDayOfMonth(1);
                    cal.normalize(d);
                    dow1 = d.getDayOfWeek();
                } else {
                    // Let a cloned GregorianCalendar take care of the cutover cases.
                    if (gc == this) {
                        gc = (GregorianCalendar) clone();
                    }
                    ndays = gc.actualMonthLength();
                    gc.set(DAY_OF_MONTH, gc.getActualMinimum(DAY_OF_MONTH));
                    dow1 = gc.get(DAY_OF_WEEK);
                }
                int x = dow - dow1;
                if (x < 0) {
                    x += 7;
                }
                ndays -= x;
                value = (ndays + 6) / 7;
            }
            break;
        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 BCE - Aug 17, 292278994 CE
             *     Julian    = Dec  2, 292269055 BCE - Jan  3, 292272993 CE
             *     Hybrid    = Dec  2, 292269055 BCE - Aug 17, 292278994 CE
             *
             * 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.
             */
            {
                if (gc == this) {
                    gc = (GregorianCalendar) clone();
                }
                // Calculate the millisecond offset from the beginning
                // of the year of this calendar and adjust the max
                // year value if we are beyond the limit in the max
                // year.
                long current = gc.getYearOffsetInMillis();
                if (gc.internalGetEra() == CE) {
                    gc.setTimeInMillis(Long.MAX_VALUE);
                    value = gc.get(YEAR);
                    long maxEnd = gc.getYearOffsetInMillis();
                    if (current > maxEnd) {
                        value--;
                    }
                } else {
                    CalendarSystem mincal = gc.getTimeInMillis() >= gregorianCutover ? gcal : getJulianCalendarSystem();
                    CalendarDate d = mincal.getCalendarDate(Long.MIN_VALUE, getZone());
                    long maxEnd = (cal.getDayOfYear(d) - 1) * 24 + d.getHours();
                    maxEnd *= 60;
                    maxEnd += d.getMinutes();
                    maxEnd *= 60;
                    maxEnd += d.getSeconds();
                    maxEnd *= 1000;
                    maxEnd += d.getMillis();
                    value = d.getYear();
                    if (value <= 0) {
                        assert mincal == gcal;
                        value = 1 - value;
                    }
                    if (current < maxEnd) {
                        value--;
                    }
                }
            }
            break;
        default:
            throw new ArrayIndexOutOfBoundsException(field);
    }
    return value;
}
Also used : CalendarDate(sun.util.calendar.CalendarDate) BaseCalendar(sun.util.calendar.BaseCalendar) CalendarSystem(sun.util.calendar.CalendarSystem) CalendarDate(sun.util.calendar.CalendarDate)

Example 3 with CalendarSystem

use of sun.util.calendar.CalendarSystem in project jdk8u_jdk by JetBrains.

the class DerInputBuffer method getTime.

/**
     * Private helper routine to extract time from the der value.
     * @param len the number of bytes to use
     * @param generalized true if Generalized Time is to be read, false
     * if UTC Time is to be read.
     */
private Date getTime(int len, boolean generalized) throws IOException {
    /*
         * UTC time encoded as ASCII chars:
         *       YYMMDDhhmmZ
         *       YYMMDDhhmmssZ
         *       YYMMDDhhmm+hhmm
         *       YYMMDDhhmm-hhmm
         *       YYMMDDhhmmss+hhmm
         *       YYMMDDhhmmss-hhmm
         * UTC Time is broken in storing only two digits of year.
         * If YY < 50, we assume 20YY;
         * if YY >= 50, we assume 19YY, as per RFC 3280.
         *
         * Generalized time has a four-digit year and allows any
         * precision specified in ISO 8601. However, for our purposes,
         * we will only allow the same format as UTC time, except that
         * fractional seconds (millisecond precision) are supported.
         */
    int year, month, day, hour, minute, second, millis;
    String type = null;
    if (generalized) {
        type = "Generalized";
        year = 1000 * Character.digit((char) buf[pos++], 10);
        year += 100 * Character.digit((char) buf[pos++], 10);
        year += 10 * Character.digit((char) buf[pos++], 10);
        year += Character.digit((char) buf[pos++], 10);
        // For the two extra YY
        len -= 2;
    } else {
        type = "UTC";
        year = 10 * Character.digit((char) buf[pos++], 10);
        year += Character.digit((char) buf[pos++], 10);
        if (// origin 2000
        year < 50)
            year += 2000;
        else
            // origin 1900
            year += 1900;
    }
    month = 10 * Character.digit((char) buf[pos++], 10);
    month += Character.digit((char) buf[pos++], 10);
    day = 10 * Character.digit((char) buf[pos++], 10);
    day += Character.digit((char) buf[pos++], 10);
    hour = 10 * Character.digit((char) buf[pos++], 10);
    hour += Character.digit((char) buf[pos++], 10);
    minute = 10 * Character.digit((char) buf[pos++], 10);
    minute += Character.digit((char) buf[pos++], 10);
    // YYMMDDhhmm
    len -= 10;
    /*
         * We allow for non-encoded seconds, even though the
         * IETF-PKIX specification says that the seconds should
         * always be encoded even if it is zero.
         */
    millis = 0;
    if (len > 2 && len < 12) {
        second = 10 * Character.digit((char) buf[pos++], 10);
        second += Character.digit((char) buf[pos++], 10);
        len -= 2;
        // handle fractional seconds (if present)
        if (buf[pos] == '.' || buf[pos] == ',') {
            len--;
            pos++;
            // handle upto milisecond precision only
            int precision = 0;
            int peek = pos;
            while (buf[peek] != 'Z' && buf[peek] != '+' && buf[peek] != '-') {
                peek++;
                precision++;
            }
            switch(precision) {
                case 3:
                    millis += 100 * Character.digit((char) buf[pos++], 10);
                    millis += 10 * Character.digit((char) buf[pos++], 10);
                    millis += Character.digit((char) buf[pos++], 10);
                    break;
                case 2:
                    millis += 100 * Character.digit((char) buf[pos++], 10);
                    millis += 10 * Character.digit((char) buf[pos++], 10);
                    break;
                case 1:
                    millis += 100 * Character.digit((char) buf[pos++], 10);
                    break;
                default:
                    throw new IOException("Parse " + type + " time, unsupported precision for seconds value");
            }
            len -= precision;
        }
    } else
        second = 0;
    if (month == 0 || day == 0 || month > 12 || day > 31 || hour >= 24 || minute >= 60 || second >= 60)
        throw new IOException("Parse " + type + " time, invalid format");
    /*
         * Generalized time can theoretically allow any precision,
         * but we're not supporting that.
         */
    CalendarSystem gcal = CalendarSystem.getGregorianCalendar();
    // no time zone
    CalendarDate date = gcal.newCalendarDate(null);
    date.setDate(year, month, day);
    date.setTimeOfDay(hour, minute, second, millis);
    long time = gcal.getTime(date);
    /*
         * Finally, "Z" or "+hhmm" or "-hhmm" ... offsets change hhmm
         */
    if (!(len == 1 || len == 5))
        throw new IOException("Parse " + type + " time, invalid offset");
    int hr, min;
    switch(buf[pos++]) {
        case '+':
            hr = 10 * Character.digit((char) buf[pos++], 10);
            hr += Character.digit((char) buf[pos++], 10);
            min = 10 * Character.digit((char) buf[pos++], 10);
            min += Character.digit((char) buf[pos++], 10);
            if (hr >= 24 || min >= 60)
                throw new IOException("Parse " + type + " time, +hhmm");
            time -= ((hr * 60) + min) * 60 * 1000;
            break;
        case '-':
            hr = 10 * Character.digit((char) buf[pos++], 10);
            hr += Character.digit((char) buf[pos++], 10);
            min = 10 * Character.digit((char) buf[pos++], 10);
            min += Character.digit((char) buf[pos++], 10);
            if (hr >= 24 || min >= 60)
                throw new IOException("Parse " + type + " time, -hhmm");
            time += ((hr * 60) + min) * 60 * 1000;
            break;
        case 'Z':
            break;
        default:
            throw new IOException("Parse " + type + " time, garbage offset");
    }
    return new Date(time);
}
Also used : CalendarDate(sun.util.calendar.CalendarDate) IOException(java.io.IOException) CalendarSystem(sun.util.calendar.CalendarSystem) CalendarDate(sun.util.calendar.CalendarDate) Date(java.util.Date)

Example 4 with CalendarSystem

use of sun.util.calendar.CalendarSystem in project jdk8u_jdk by JetBrains.

the class Date method normalize.

private final BaseCalendar.Date normalize() {
    if (cdate == null) {
        BaseCalendar cal = getCalendarSystem(fastTime);
        cdate = (BaseCalendar.Date) cal.getCalendarDate(fastTime, TimeZone.getDefaultRef());
        return cdate;
    }
    // required for the compatible behavior.
    if (!cdate.isNormalized()) {
        cdate = normalize(cdate);
    }
    // If the default TimeZone has changed, then recalculate the
    // fields with the new TimeZone.
    TimeZone tz = TimeZone.getDefaultRef();
    if (tz != cdate.getZone()) {
        cdate.setZone(tz);
        CalendarSystem cal = getCalendarSystem(cdate);
        cal.getCalendarDate(fastTime, cdate);
    }
    return cdate;
}
Also used : BaseCalendar(sun.util.calendar.BaseCalendar) CalendarSystem(sun.util.calendar.CalendarSystem)

Example 5 with CalendarSystem

use of sun.util.calendar.CalendarSystem in project j2objc by google.

the class DerInputBuffer method getTime.

/**
     * Private helper routine to extract time from the der value.
     * @param len the number of bytes to use
     * @param generalized true if Generalized Time is to be read, false
     * if UTC Time is to be read.
     */
private Date getTime(int len, boolean generalized) throws IOException {
    /*
         * UTC time encoded as ASCII chars:
         *       YYMMDDhhmmZ
         *       YYMMDDhhmmssZ
         *       YYMMDDhhmm+hhmm
         *       YYMMDDhhmm-hhmm
         *       YYMMDDhhmmss+hhmm
         *       YYMMDDhhmmss-hhmm
         * UTC Time is broken in storing only two digits of year.
         * If YY < 50, we assume 20YY;
         * if YY >= 50, we assume 19YY, as per RFC 3280.
         *
         * Generalized time has a four-digit year and allows any
         * precision specified in ISO 8601. However, for our purposes,
         * we will only allow the same format as UTC time, except that
         * fractional seconds (millisecond precision) are supported.
         */
    int year, month, day, hour, minute, second, millis;
    String type = null;
    if (generalized) {
        type = "Generalized";
        year = 1000 * Character.digit((char) buf[pos++], 10);
        year += 100 * Character.digit((char) buf[pos++], 10);
        year += 10 * Character.digit((char) buf[pos++], 10);
        year += Character.digit((char) buf[pos++], 10);
        // For the two extra YY
        len -= 2;
    } else {
        type = "UTC";
        year = 10 * Character.digit((char) buf[pos++], 10);
        year += Character.digit((char) buf[pos++], 10);
        if (// origin 2000
        year < 50)
            year += 2000;
        else
            // origin 1900
            year += 1900;
    }
    month = 10 * Character.digit((char) buf[pos++], 10);
    month += Character.digit((char) buf[pos++], 10);
    day = 10 * Character.digit((char) buf[pos++], 10);
    day += Character.digit((char) buf[pos++], 10);
    hour = 10 * Character.digit((char) buf[pos++], 10);
    hour += Character.digit((char) buf[pos++], 10);
    minute = 10 * Character.digit((char) buf[pos++], 10);
    minute += Character.digit((char) buf[pos++], 10);
    // YYMMDDhhmm
    len -= 10;
    /*
         * We allow for non-encoded seconds, even though the
         * IETF-PKIX specification says that the seconds should
         * always be encoded even if it is zero.
         */
    millis = 0;
    if (len > 2 && len < 12) {
        second = 10 * Character.digit((char) buf[pos++], 10);
        second += Character.digit((char) buf[pos++], 10);
        len -= 2;
        // handle fractional seconds (if present)
        if (buf[pos] == '.' || buf[pos] == ',') {
            len--;
            pos++;
            // handle upto milisecond precision only
            int precision = 0;
            int peek = pos;
            while (buf[peek] != 'Z' && buf[peek] != '+' && buf[peek] != '-') {
                peek++;
                precision++;
            }
            switch(precision) {
                case 3:
                    millis += 100 * Character.digit((char) buf[pos++], 10);
                    millis += 10 * Character.digit((char) buf[pos++], 10);
                    millis += Character.digit((char) buf[pos++], 10);
                    break;
                case 2:
                    millis += 100 * Character.digit((char) buf[pos++], 10);
                    millis += 10 * Character.digit((char) buf[pos++], 10);
                    break;
                case 1:
                    millis += 100 * Character.digit((char) buf[pos++], 10);
                    break;
                default:
                    throw new IOException("Parse " + type + " time, unsupported precision for seconds value");
            }
            len -= precision;
        }
    } else
        second = 0;
    if (month == 0 || day == 0 || month > 12 || day > 31 || hour >= 24 || minute >= 60 || second >= 60)
        throw new IOException("Parse " + type + " time, invalid format");
    /*
         * Generalized time can theoretically allow any precision,
         * but we're not supporting that.
         */
    CalendarSystem gcal = CalendarSystem.getGregorianCalendar();
    // no time zone
    CalendarDate date = gcal.newCalendarDate(null);
    date.setDate(year, month, day);
    date.setTimeOfDay(hour, minute, second, millis);
    long time = gcal.getTime(date);
    /*
         * Finally, "Z" or "+hhmm" or "-hhmm" ... offsets change hhmm
         */
    if (!(len == 1 || len == 5))
        throw new IOException("Parse " + type + " time, invalid offset");
    int hr, min;
    switch(buf[pos++]) {
        case '+':
            hr = 10 * Character.digit((char) buf[pos++], 10);
            hr += Character.digit((char) buf[pos++], 10);
            min = 10 * Character.digit((char) buf[pos++], 10);
            min += Character.digit((char) buf[pos++], 10);
            if (hr >= 24 || min >= 60)
                throw new IOException("Parse " + type + " time, +hhmm");
            time -= ((hr * 60) + min) * 60 * 1000;
            break;
        case '-':
            hr = 10 * Character.digit((char) buf[pos++], 10);
            hr += Character.digit((char) buf[pos++], 10);
            min = 10 * Character.digit((char) buf[pos++], 10);
            min += Character.digit((char) buf[pos++], 10);
            if (hr >= 24 || min >= 60)
                throw new IOException("Parse " + type + " time, -hhmm");
            time += ((hr * 60) + min) * 60 * 1000;
            break;
        case 'Z':
            break;
        default:
            throw new IOException("Parse " + type + " time, garbage offset");
    }
    return new Date(time);
}
Also used : CalendarDate(sun.util.calendar.CalendarDate) IOException(java.io.IOException) CalendarSystem(sun.util.calendar.CalendarSystem) CalendarDate(sun.util.calendar.CalendarDate) Date(java.util.Date)

Aggregations

CalendarSystem (sun.util.calendar.CalendarSystem)6 BaseCalendar (sun.util.calendar.BaseCalendar)4 CalendarDate (sun.util.calendar.CalendarDate)4 IOException (java.io.IOException)2 Date (java.util.Date)2