TimeComponents.java
/* Copyright 2002-2022 CS GROUP
* Licensed to CS GROUP (CS) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* CS licenses this file to You 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.orekit.time;
import java.io.Serializable;
import java.text.DecimalFormat;
import java.text.DecimalFormatSymbols;
import java.util.Locale;
import java.util.regex.Matcher;
import java.util.regex.Pattern;
import org.hipparchus.util.FastMath;
import org.orekit.errors.OrekitIllegalArgumentException;
import org.orekit.errors.OrekitMessages;
import org.orekit.utils.Constants;
/** Class representing a time within the day broken up as hour,
* minute and second components.
* <p>Instances of this class are guaranteed to be immutable.</p>
* @see DateComponents
* @see DateTimeComponents
* @author Luc Maisonobe
*/
public class TimeComponents implements Serializable, Comparable<TimeComponents> {
/** Constant for commonly used hour 00:00:00. */
public static final TimeComponents H00 = new TimeComponents(0, 0, 0);
/** Constant for commonly used hour 12:00:00. */
public static final TimeComponents H12 = new TimeComponents(12, 0, 0);
/** Serializable UID. */
private static final long serialVersionUID = 20160331L;
/** Formatting symbols used in {@link #toString()}. */
private static final DecimalFormatSymbols US_SYMBOLS =
new DecimalFormatSymbols(Locale.US);
/** Basic and extends formats for local time, with optional timezone. */
private static final Pattern ISO8601_FORMATS = Pattern.compile("^(\\d\\d):?(\\d\\d):?(\\d\\d(?:[.,]\\d+)?)?(?:Z|([-+]\\d\\d(?::?\\d\\d)?))?$");
/** Hour number. */
private final int hour;
/** Minute number. */
private final int minute;
/** Second number. */
private final double second;
/** Offset between the specified date and UTC.
* <p>
* Always an integral number of minutes, as per ISO-8601 standard.
* </p>
* @since 7.2
*/
private final int minutesFromUTC;
/** Build a time from its clock elements.
* <p>Note that seconds between 60.0 (inclusive) and 61.0 (exclusive) are allowed
* in this method, since they do occur during leap seconds introduction
* in the {@link UTCScale UTC} time scale.</p>
* @param hour hour number from 0 to 23
* @param minute minute number from 0 to 59
* @param second second number from 0.0 to 61.0 (excluded)
* @exception IllegalArgumentException if inconsistent arguments
* are given (parameters out of range)
*/
public TimeComponents(final int hour, final int minute, final double second)
throws IllegalArgumentException {
this(hour, minute, second, 0);
}
/** Build a time from its clock elements.
* <p>Note that seconds between 60.0 (inclusive) and 61.0 (exclusive) are allowed
* in this method, since they do occur during leap seconds introduction
* in the {@link UTCScale UTC} time scale.</p>
* @param hour hour number from 0 to 23
* @param minute minute number from 0 to 59
* @param second second number from 0.0 to 61.0 (excluded)
* @param minutesFromUTC offset between the specified date and UTC, as an
* integral number of minutes, as per ISO-8601 standard
* @exception IllegalArgumentException if inconsistent arguments
* are given (parameters out of range)
* @since 7.2
*/
public TimeComponents(final int hour, final int minute, final double second,
final int minutesFromUTC)
throws IllegalArgumentException {
// range check
if (hour < 0 || hour > 23 ||
minute < 0 || minute > 59 ||
second < 0 || second >= 61.0) {
throw new OrekitIllegalArgumentException(OrekitMessages.NON_EXISTENT_HMS_TIME,
hour, minute, second);
}
this.hour = hour;
this.minute = minute;
this.second = second;
this.minutesFromUTC = minutesFromUTC;
}
/**
* Build a time from the second number within the day.
*
* <p>If the {@code secondInDay} is less than {@code 60.0} then {@link #getSecond()}
* will be less than {@code 60.0}, otherwise it will be less than {@code 61.0}. This constructor
* may produce an invalid value of {@link #getSecond()} during a negative leap second,
* through there has never been one. For more control over the number of seconds in
* the final minute use {@link #fromSeconds(int, double, double, int)}.
*
* <p>This constructor is always in UTC (i.e. {@link #getMinutesFromUTC() will return
* 0}).
*
* @param secondInDay second number from 0.0 to {@link Constants#JULIAN_DAY} {@code +
* 1} (excluded)
* @throws OrekitIllegalArgumentException if seconds number is out of range
* @see #fromSeconds(int, double, double, int)
* @see #TimeComponents(int, double)
*/
public TimeComponents(final double secondInDay)
throws OrekitIllegalArgumentException {
this(0, secondInDay);
}
/**
* Build a time from the second number within the day.
*
* <p>The second number is defined here as the sum
* {@code secondInDayA + secondInDayB} from 0.0 to {@link Constants#JULIAN_DAY}
* {@code + 1} (excluded). The two parameters are used for increased accuracy.
*
* <p>If the sum is less than {@code 60.0} then {@link #getSecond()} will be less
* than {@code 60.0}, otherwise it will be less than {@code 61.0}. This constructor
* may produce an invalid value of {@link #getSecond()} during a negative leap second,
* through there has never been one. For more control over the number of seconds in
* the final minute use {@link #fromSeconds(int, double, double, int)}.
*
* <p>This constructor is always in UTC (i.e. {@link #getMinutesFromUTC()} will
* return 0).
*
* @param secondInDayA first part of the second number
* @param secondInDayB last part of the second number
* @throws OrekitIllegalArgumentException if seconds number is out of range
* @see #fromSeconds(int, double, double, int)
*/
public TimeComponents(final int secondInDayA, final double secondInDayB)
throws OrekitIllegalArgumentException {
// if the total is at least 86400 then assume there is a leap second
this(
(Constants.JULIAN_DAY - secondInDayA) - secondInDayB > 0 ? secondInDayA : secondInDayA - 1,
secondInDayB,
(Constants.JULIAN_DAY - secondInDayA) - secondInDayB > 0 ? 0 : 1,
(Constants.JULIAN_DAY - secondInDayA) - secondInDayB > 0 ? 60 : 61);
}
/**
* Build a time from the second number within the day.
*
* <p>The seconds past midnight is the sum {@code secondInDayA + secondInDayB +
* leap}. The two parameters are used for increased accuracy. Only the first part of
* the sum ({@code secondInDayA + secondInDayB}) is used to compute the hours and
* minutes. The third parameter ({@code leap}) is added directly to the second value
* ({@link #getSecond()}) to implement leap seconds. These three quantities must
* satisfy the following constraints. This first guarantees the hour and minute are
* valid, the second guarantees the second is valid.
*
* <pre>
* {@code 0 <= secondInDayA + secondInDayB < 86400}
* {@code 0 <= (secondInDayA + secondInDayB) % 60 + leap < minuteDuration}
* {@code 0 <= leap <= minuteDuration - 60 if minuteDuration >= 60}
* {@code 0 >= leap >= minuteDuration - 60 if minuteDuration < 60}
* </pre>
*
* <p>If the seconds of minute ({@link #getSecond()}) computed from {@code
* secondInDayA + secondInDayB + leap} is greater than or equal to {@code
* minuteDuration} then the second of minute will be set to {@code
* FastMath.nextDown(minuteDuration)}. This prevents rounding to an invalid seconds of
* minute number when the input values have greater precision than a {@code double}.
*
* <p>This constructor is always in UTC (i.e. {@link #getMinutesFromUTC() will return
* 0}).
*
* <p>If {@code secondsInDayB} or {@code leap} is NaN then the hour and minute will
* be determined from {@code secondInDayA} and the second of minute will be NaN.
*
* <p>This constructor is private to avoid confusion with the other constructors that
* would be caused by overloading. Use {@link #fromSeconds(int, double, double,
* int)}.
*
* @param secondInDayA first part of the second number.
* @param secondInDayB last part of the second number.
* @param leap magnitude of the leap second if this point in time is during
* a leap second, otherwise {@code 0.0}. This value is not used
* to compute hours and minutes, but it is added to the computed
* second of minute.
* @param minuteDuration number of seconds in the current minute, normally {@code 60}.
* @throws OrekitIllegalArgumentException if the inequalities above do not hold.
* @see #fromSeconds(int, double, double, int)
* @since 10.2
*/
private TimeComponents(final int secondInDayA,
final double secondInDayB,
final double leap,
final int minuteDuration) throws OrekitIllegalArgumentException {
// split the numbers as a whole number of seconds
// and a fractional part between 0.0 (included) and 1.0 (excluded)
final int carry = (int) FastMath.floor(secondInDayB);
int wholeSeconds = secondInDayA + carry;
final double fractional = secondInDayB - carry;
// range check
if (wholeSeconds < 0 || wholeSeconds >= Constants.JULIAN_DAY) {
throw new OrekitIllegalArgumentException(
OrekitMessages.OUT_OF_RANGE_SECONDS_NUMBER_DETAIL,
// this can produce some strange messages due to rounding
secondInDayA + secondInDayB,
0,
Constants.JULIAN_DAY);
}
final int maxExtraSeconds = minuteDuration - 60;
if (leap * maxExtraSeconds < 0 ||
FastMath.abs(leap) > FastMath.abs(maxExtraSeconds)) {
throw new OrekitIllegalArgumentException(
OrekitMessages.OUT_OF_RANGE_SECONDS_NUMBER_DETAIL,
leap, 0, maxExtraSeconds);
}
// extract the time components
hour = wholeSeconds / 3600;
wholeSeconds -= 3600 * hour;
minute = wholeSeconds / 60;
wholeSeconds -= 60 * minute;
// at this point ((minuteDuration - wholeSeconds) - leap) - fractional > 0
// or else one of the preconditions was violated. Even if there is not violation,
// naiveSecond may round to minuteDuration, creating an invalid time.
// In that case round down to preserve a valid time at the cost of up to 1 ULP of error.
// See #676 and #681.
final double naiveSecond = wholeSeconds + (leap + fractional);
if (naiveSecond < 0) {
throw new OrekitIllegalArgumentException(
OrekitMessages.OUT_OF_RANGE_SECONDS_NUMBER_DETAIL,
naiveSecond, 0, minuteDuration);
}
if (naiveSecond < minuteDuration || Double.isNaN(naiveSecond)) {
second = naiveSecond;
} else {
second = FastMath.nextDown((double) minuteDuration);
}
minutesFromUTC = 0;
}
/**
* Build a time from the second number within the day.
*
* <p>The seconds past midnight is the sum {@code secondInDayA + secondInDayB +
* leap}. The two parameters are used for increased accuracy. Only the first part of
* the sum ({@code secondInDayA + secondInDayB}) is used to compute the hours and
* minutes. The third parameter ({@code leap}) is added directly to the second value
* ({@link #getSecond()}) to implement leap seconds. These three quantities must
* satisfy the following constraints. This first guarantees the hour and minute are
* valid, the second guarantees the second is valid.
*
* <pre>
* {@code 0 <= secondInDayA + secondInDayB < 86400}
* {@code 0 <= (secondInDayA + secondInDayB) % 60 + leap <= minuteDuration}
* {@code 0 <= leap <= minuteDuration - 60 if minuteDuration >= 60}
* {@code 0 >= leap >= minuteDuration - 60 if minuteDuration < 60}
* </pre>
*
* <p>If the seconds of minute ({@link #getSecond()}) computed from {@code
* secondInDayA + secondInDayB + leap} is greater than or equal to {@code 60 + leap}
* then the second of minute will be set to {@code FastMath.nextDown(60 + leap)}. This
* prevents rounding to an invalid seconds of minute number when the input values have
* greater precision than a {@code double}.
*
* <p>This constructor is always in UTC (i.e. {@link #getMinutesFromUTC() will return
* 0}).
*
* <p>If {@code secondsInDayB} or {@code leap} is NaN then the hour and minute will
* be determined from {@code secondInDayA} and the second of minute will be NaN.
*
* @param secondInDayA first part of the second number.
* @param secondInDayB last part of the second number.
* @param leap magnitude of the leap second if this point in time is during
* a leap second, otherwise {@code 0.0}. This value is not used
* to compute hours and minutes, but it is added to the computed
* second of minute.
* @param minuteDuration number of seconds in the current minute, normally {@code 60}.
* @return new time components for the specified time.
* @throws OrekitIllegalArgumentException if the inequalities above do not hold.
* @since 10.2
*/
public static TimeComponents fromSeconds(final int secondInDayA,
final double secondInDayB,
final double leap,
final int minuteDuration) {
return new TimeComponents(secondInDayA, secondInDayB, leap, minuteDuration);
}
/** Parse a string in ISO-8601 format to build a time.
* <p>The supported formats are:
* <ul>
* <li>basic and extended format local time: hhmmss, hh:mm:ss (with optional decimals in seconds)</li>
* <li>optional UTC time: hhmmssZ, hh:mm:ssZ</li>
* <li>optional signed hours UTC offset: hhmmss+HH, hhmmss-HH, hh:mm:ss+HH, hh:mm:ss-HH</li>
* <li>optional signed basic hours and minutes UTC offset: hhmmss+HHMM, hhmmss-HHMM, hh:mm:ss+HHMM, hh:mm:ss-HHMM</li>
* <li>optional signed extended hours and minutes UTC offset: hhmmss+HH:MM, hhmmss-HH:MM, hh:mm:ss+HH:MM, hh:mm:ss-HH:MM</li>
* </ul>
*
* <p> As shown by the list above, only the complete representations defined in section 4.2
* of ISO-8601 standard are supported, neither expended representations nor representations
* with reduced accuracy are supported.
*
* @param string string to parse
* @return a parsed time
* @exception IllegalArgumentException if string cannot be parsed
*/
public static TimeComponents parseTime(final String string) {
// is the date a calendar date ?
final Matcher timeMatcher = ISO8601_FORMATS.matcher(string);
if (timeMatcher.matches()) {
final int hour = Integer.parseInt(timeMatcher.group(1));
final int minute = Integer.parseInt(timeMatcher.group(2));
final double second = timeMatcher.group(3) == null ? 0.0 : Double.parseDouble(timeMatcher.group(3).replace(',', '.'));
final String offset = timeMatcher.group(4);
final int minutesFromUTC;
if (offset == null) {
// no offset from UTC is given
minutesFromUTC = 0;
} else {
// we need to parse an offset from UTC
// the sign is mandatory and the ':' separator is optional
// so we can have offsets given as -06:00 or +0100
final int sign = offset.codePointAt(0) == '-' ? -1 : +1;
final int hourOffset = Integer.parseInt(offset.substring(1, 3));
final int minutesOffset = offset.length() <= 3 ? 0 : Integer.parseInt(offset.substring(offset.length() - 2));
minutesFromUTC = sign * (minutesOffset + 60 * hourOffset);
}
return new TimeComponents(hour, minute, second, minutesFromUTC);
}
throw new OrekitIllegalArgumentException(OrekitMessages.NON_EXISTENT_TIME, string);
}
/** Get the hour number.
* @return hour number from 0 to 23
*/
public int getHour() {
return hour;
}
/** Get the minute number.
* @return minute minute number from 0 to 59
*/
public int getMinute() {
return minute;
}
/** Get the seconds number.
* @return second second number from 0.0 to 61.0 (excluded). Note that 60 ≤ second
* < 61 only occurs during a leap second.
*/
public double getSecond() {
return second;
}
/** Get the offset between the specified date and UTC.
* <p>
* The offset is always an integral number of minutes, as per ISO-8601 standard.
* </p>
* @return offset in minutes between the specified date and UTC
* @since 7.2
*/
public int getMinutesFromUTC() {
return minutesFromUTC;
}
/** Get the second number within the local day, <em>without</em> applying the {@link #getMinutesFromUTC() offset from UTC}.
* @return second number from 0.0 to Constants.JULIAN_DAY
* @see #getSecondsInUTCDay()
* @since 7.2
*/
public double getSecondsInLocalDay() {
return second + 60 * minute + 3600 * hour;
}
/** Get the second number within the UTC day, applying the {@link #getMinutesFromUTC() offset from UTC}.
* @return second number from {@link #getMinutesFromUTC() -getMinutesFromUTC()}
* to Constants.JULIAN_DAY {@link #getMinutesFromUTC() + getMinutesFromUTC()}
* @see #getSecondsInLocalDay()
* @since 7.2
*/
public double getSecondsInUTCDay() {
return second + 60 * (minute - minutesFromUTC) + 3600 * hour;
}
/**
* Package private method that allows specification of seconds format. Allows access
* from {@link DateTimeComponents#toString(int, int)}. Access from outside of rounding
* methods would result in invalid times, see #590, #591.
*
* @param secondsFormat for the seconds.
* @return string without UTC offset.
*/
String toStringWithoutUtcOffset(final DecimalFormat secondsFormat) {
return String.format("%02d:%02d:%s", hour, minute, secondsFormat.format(second));
}
/**
* Get a string representation of the time without the offset from UTC.
*
* @return a string representation of the time in an ISO 8601 like format.
* @see #formatUtcOffset()
* @see #toString()
*/
public String toStringWithoutUtcOffset() {
// create formats here as they are not thread safe
// Format for seconds to prevent rounding up to an invalid time. See #591
final DecimalFormat secondsFormat =
new DecimalFormat("00.000###########", US_SYMBOLS);
return toStringWithoutUtcOffset(secondsFormat);
}
/**
* Get the UTC offset as a string in ISO8601 format. For example, {@code +00:00}.
*
* @return the UTC offset as a string.
* @see #toStringWithoutUtcOffset()
* @see #toString()
*/
public String formatUtcOffset() {
final int hourOffset = FastMath.abs(minutesFromUTC) / 60;
final int minuteOffset = FastMath.abs(minutesFromUTC) % 60;
return (minutesFromUTC < 0 ? '-' : '+') +
String.format("%02d:%02d", hourOffset, minuteOffset);
}
/**
* Get a string representation of the time including the offset from UTC.
*
* @return string representation of the time in an ISO 8601 like format including the
* UTC offset.
* @see #toStringWithoutUtcOffset()
* @see #formatUtcOffset()
*/
public String toString() {
return toStringWithoutUtcOffset() + formatUtcOffset();
}
/** {@inheritDoc} */
public int compareTo(final TimeComponents other) {
return Double.compare(getSecondsInUTCDay(), other.getSecondsInUTCDay());
}
/** {@inheritDoc} */
public boolean equals(final Object other) {
try {
final TimeComponents otherTime = (TimeComponents) other;
return otherTime != null &&
hour == otherTime.hour &&
minute == otherTime.minute &&
second == otherTime.second &&
minutesFromUTC == otherTime.minutesFromUTC;
} catch (ClassCastException cce) {
return false;
}
}
/** {@inheritDoc} */
public int hashCode() {
final long bits = Double.doubleToLongBits(second);
return ((hour << 16) ^ ((minute - minutesFromUTC) << 8)) ^ (int) (bits ^ (bits >>> 32));
}
}