timlevett · April 8, 2015 19:40
diff --git a/java.util.Date.java.doc b/java.util.Date.java.doc
 /**
 * The class <code>Date</code> represents a specific instant
 * in time, with millisecond precision.
 * <p>
 * Prior to JDK&nbsp;1.1, the class <code>Date</code> had two additional
 * functions.  It allowed the interpretation of dates as year, month, day, hour,
 * minute, and second values.  It also allowed the formatting and parsing
 * of date strings.  Unfortunately, the API for these functions was not
 * amenable to internationalization.  As of JDK&nbsp;1.1, the
 * <code>Calendar</code> class should be used to convert between dates and time
 * fields and the <code>DateFormat</code> class should be used to format and
 * parse date strings.
 * The corresponding methods in <code>Date</code> are deprecated.
 * <p>
 * Although the <code>Date</code> class is intended to reflect
 * coordinated universal time (UTC), it may not do so exactly,
 * depending on the host environment of the Java Virtual Machine.
 * Nearly all modern operating systems assume that 1&nbsp;day&nbsp;=
 * 24&nbsp;&times;&nbsp;60&nbsp;&times;&nbsp;60&nbsp;= 86400 seconds
 * in all cases. In UTC, however, about once every year or two there
 * is an extra second, called a "leap second." The leap
 * second is always added as the last second of the day, and always
 * on December 31 or June 30. For example, the last minute of the
 * year 1995 was 61 seconds long, thanks to an added leap second.
 * Most computer clocks are not accurate enough to be able to reflect
 * the leap-second distinction.
 * <p>
 * Some computer standards are defined in terms of Greenwich mean
 * time (GMT), which is equivalent to universal time (UT).  GMT is
 * the "civil" name for the standard; UT is the
 * "scientific" name for the same standard. The
 * distinction between UTC and UT is that UTC is based on an atomic
 * clock and UT is based on astronomical observations, which for all
 * practical purposes is an invisibly fine hair to split. Because the
 * earth's rotation is not uniform (it slows down and speeds up
 * in complicated ways), UT does not always flow uniformly. Leap
 * seconds are introduced as needed into UTC so as to keep UTC within
 * 0.9 seconds of UT1, which is a version of UT with certain
 * corrections applied. There are other time and date systems as
 * well; for example, the time scale used by the satellite-based
 * global positioning system (GPS) is synchronized to UTC but is
 * <i>not</i> adjusted for leap seconds. An interesting source of
 * further information is the U.S. Naval Observatory, particularly
 * the Directorate of Time at:
 * <blockquote><pre>
 *     <a href=http://tycho.usno.navy.mil>http://tycho.usno.navy.mil</a>
 * </pre></blockquote>
 * <p>
 * and their definitions of "Systems of Time" at:
 * <blockquote><pre>
 *     <a href=http://tycho.usno.navy.mil/systime.html>http://tycho.usno.navy.mil/systime.html</a>
 * </pre></blockquote>
 * <p>
 * In all methods of class <code>Date</code> that accept or return
 * year, month, date, hours, minutes, and seconds values, the
 * following representations are used:
 * <ul>
 * <li>A year <i>y</i> is represented by the integer
 *     <i>y</i>&nbsp;<code>-&nbsp;1900</code>.
 * <li>A month is represented by an integer from 0 to 11; 0 is January,
 *     1 is February, and so forth; thus 11 is December.
 * <li>A date (day of month) is represented by an integer from 1 to 31
 *     in the usual manner.
 * <li>An hour is represented by an integer from 0 to 23. Thus, the hour
 *     from midnight to 1 a.m. is hour 0, and the hour from noon to 1
 *     p.m. is hour 12.
 * <li>A minute is represented by an integer from 0 to 59 in the usual manner.
 * <li>A second is represented by an integer from 0 to 61; the values 60 and
 *     61 occur only for leap seconds and even then only in Java
 *     implementations that actually track leap seconds correctly. Because
 *     of the manner in which leap seconds are currently introduced, it is
 *     extremely unlikely that two leap seconds will occur in the same
 *     minute, but this specification follows the date and time conventions
 *     for ISO C.
 * </ul>
 * <p>
 * In all cases, arguments given to methods for these purposes need
 * not fall within the indicated ranges; for example, a date may be
 * specified as January 32 and is interpreted as meaning February 1.
 *
 * @author  James Gosling
 * @author  Arthur van Hoff
 * @author  Alan Liu
 * @see     java.text.DateFormat
 * @see     java.util.Calendar
 * @see     java.util.TimeZone
 * @since   JDK1.0
 */
	/**
	* The class <code>Date</code> represents a specific instant
	* in time, with millisecond precision.
	* <p>
	* Prior to JDK 1.1, the class <code>Date</code> had two additional
	* functions. It allowed the interpretation of dates as year, month, day, hour,
	* minute, and second values. It also allowed the formatting and parsing
	* of date strings. Unfortunately, the API for these functions was not
	* amenable to internationalization. As of JDK 1.1, the
	* <code>Calendar</code> class should be used to convert between dates and time
	* fields and the <code>DateFormat</code> class should be used to format and
	* parse date strings.
	* The corresponding methods in <code>Date</code> are deprecated.
	* <p>
	* Although the <code>Date</code> class is intended to reflect
	* coordinated universal time (UTC), it may not do so exactly,
	* depending on the host environment of the Java Virtual Machine.
	* Nearly all modern operating systems assume that 1 day =
	* 24 × 60 × 60 = 86400 seconds
	* in all cases. In UTC, however, about once every year or two there
	* is an extra second, called a "leap second." The leap
	* second is always added as the last second of the day, and always
	* on December 31 or June 30. For example, the last minute of the
	* year 1995 was 61 seconds long, thanks to an added leap second.
	* Most computer clocks are not accurate enough to be able to reflect
	* the leap-second distinction.
	* <p>
	* Some computer standards are defined in terms of Greenwich mean
	* time (GMT), which is equivalent to universal time (UT). GMT is
	* the "civil" name for the standard; UT is the
	* "scientific" name for the same standard. The
	* distinction between UTC and UT is that UTC is based on an atomic
	* clock and UT is based on astronomical observations, which for all
	* practical purposes is an invisibly fine hair to split. Because the
	* earth's rotation is not uniform (it slows down and speeds up
	* in complicated ways), UT does not always flow uniformly. Leap
	* seconds are introduced as needed into UTC so as to keep UTC within
	* 0.9 seconds of UT1, which is a version of UT with certain
	* corrections applied. There are other time and date systems as
	* well; for example, the time scale used by the satellite-based
	* global positioning system (GPS) is synchronized to UTC but is
	* <i>not</i> adjusted for leap seconds. An interesting source of
	* further information is the U.S. Naval Observatory, particularly
	* the Directorate of Time at:
	* <blockquote><pre>
	* <a href=http://tycho.usno.navy.mil>http://tycho.usno.navy.mil</a>
	* </pre></blockquote>
	* <p>
	* and their definitions of "Systems of Time" at:
	* <blockquote><pre>
	* <a href=http://tycho.usno.navy.mil/systime.html>http://tycho.usno.navy.mil/systime.html</a>
	* </pre></blockquote>
	* <p>
	* In all methods of class <code>Date</code> that accept or return
	* year, month, date, hours, minutes, and seconds values, the
	* following representations are used:
	* <ul>
	* <li>A year <i>y</i> is represented by the integer
	* <i>y</i> <code>- 1900</code>.
	* <li>A month is represented by an integer from 0 to 11; 0 is January,
	* 1 is February, and so forth; thus 11 is December.
	* <li>A date (day of month) is represented by an integer from 1 to 31
	* in the usual manner.
	* <li>An hour is represented by an integer from 0 to 23. Thus, the hour
	* from midnight to 1 a.m. is hour 0, and the hour from noon to 1
	* p.m. is hour 12.
	* <li>A minute is represented by an integer from 0 to 59 in the usual manner.
	* <li>A second is represented by an integer from 0 to 61; the values 60 and
	* 61 occur only for leap seconds and even then only in Java
	* implementations that actually track leap seconds correctly. Because
	* of the manner in which leap seconds are currently introduced, it is
	* extremely unlikely that two leap seconds will occur in the same
	* minute, but this specification follows the date and time conventions
	* for ISO C.
	* </ul>
	* <p>
	* In all cases, arguments given to methods for these purposes need
	* not fall within the indicated ranges; for example, a date may be
	* specified as January 32 and is interpreted as meaning February 1.
	*
	* @author James Gosling
	* @author Arthur van Hoff
	* @author Alan Liu
	* @see java.text.DateFormat
	* @see java.util.Calendar
	* @see java.util.TimeZone
	* @since JDK1.0
	*/