/*global define*/
define([
'../ThirdParty/sprintf',
'./binarySearch',
'./defaultValue',
'./defined',
'./DeveloperError',
'./GregorianDate',
'./isLeapYear',
'./LeapSecond',
'./TimeConstants',
'./TimeStandard'
], function(
sprintf,
binarySearch,
defaultValue,
defined,
DeveloperError,
GregorianDate,
isLeapYear,
LeapSecond,
TimeConstants,
TimeStandard) {
'use strict';
var gregorianDateScratch = new GregorianDate();
var daysInMonth = [31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31];
var daysInLeapFeburary = 29;
function compareLeapSecondDates(leapSecond, dateToFind) {
return JulianDate.compare(leapSecond.julianDate, dateToFind.julianDate);
}
// we don't really need a leap second instance, anything with a julianDate property will do
var binarySearchScratchLeapSecond = new LeapSecond();
function convertUtcToTai(julianDate) {
//Even though julianDate is in UTC, we'll treat it as TAI and
//search the leap second table for it.
binarySearchScratchLeapSecond.julianDate = julianDate;
var leapSeconds = JulianDate.leapSeconds;
var index = binarySearch(leapSeconds, binarySearchScratchLeapSecond, compareLeapSecondDates);
if (index < 0) {
index = ~index;
}
if (index >= leapSeconds.length) {
index = leapSeconds.length - 1;
}
var offset = leapSeconds[index].offset;
if (index > 0) {
//Now we have the index of the closest leap second that comes on or after our UTC time.
//However, if the difference between the UTC date being converted and the TAI
//defined leap second is greater than the offset, we are off by one and need to use
//the previous leap second.
var difference = JulianDate.secondsDifference(leapSeconds[index].julianDate, julianDate);
if (difference > offset) {
index--;
offset = leapSeconds[index].offset;
}
}
JulianDate.addSeconds(julianDate, offset, julianDate);
}
function convertTaiToUtc(julianDate, result) {
binarySearchScratchLeapSecond.julianDate = julianDate;
var leapSeconds = JulianDate.leapSeconds;
var index = binarySearch(leapSeconds, binarySearchScratchLeapSecond, compareLeapSecondDates);
if (index < 0) {
index = ~index;
}
//All times before our first leap second get the first offset.
if (index === 0) {
return JulianDate.addSeconds(julianDate, -leapSeconds[0].offset, result);
}
//All times after our leap second get the last offset.
if (index >= leapSeconds.length) {
return JulianDate.addSeconds(julianDate, -leapSeconds[index - 1].offset, result);
}
//Compute the difference between the found leap second and the time we are converting.
var difference = JulianDate.secondsDifference(leapSeconds[index].julianDate, julianDate);
if (difference === 0) {
//The date is in our leap second table.
return JulianDate.addSeconds(julianDate, -leapSeconds[index].offset, result);
}
if (difference <= 1.0) {
//The requested date is during the moment of a leap second, then we cannot convert to UTC
return undefined;
}
//The time is in between two leap seconds, index is the leap second after the date
//we're converting, so we subtract one to get the correct LeapSecond instance.
return JulianDate.addSeconds(julianDate, -leapSeconds[--index].offset, result);
}
function setComponents(wholeDays, secondsOfDay, julianDate) {
var extraDays = (secondsOfDay / TimeConstants.SECONDS_PER_DAY) | 0;
wholeDays += extraDays;
secondsOfDay -= TimeConstants.SECONDS_PER_DAY * extraDays;
if (secondsOfDay < 0) {
wholeDays--;
secondsOfDay += TimeConstants.SECONDS_PER_DAY;
}
julianDate.dayNumber = wholeDays;
julianDate.secondsOfDay = secondsOfDay;
return julianDate;
}
function computeJulianDateComponents(year, month, day, hour, minute, second, millisecond) {
// Algorithm from page 604 of the Explanatory Supplement to the
// Astronomical Almanac (Seidelmann 1992).
var a = ((month - 14) / 12) | 0;
var b = year + 4800 + a;
var dayNumber = (((1461 * b) / 4) | 0) + (((367 * (month - 2 - 12 * a)) / 12) | 0) - (((3 * (((b + 100) / 100) | 0)) / 4) | 0) + day - 32075;
// JulianDates are noon-based
hour = hour - 12;
if (hour < 0) {
hour += 24;
}
var secondsOfDay = second + ((hour * TimeConstants.SECONDS_PER_HOUR) + (minute * TimeConstants.SECONDS_PER_MINUTE) + (millisecond * TimeConstants.SECONDS_PER_MILLISECOND));
if (secondsOfDay >= 43200.0) {
dayNumber -= 1;
}
return [dayNumber, secondsOfDay];
}
//Regular expressions used for ISO8601 date parsing.
//YYYY
var matchCalendarYear = /^(\d{4})$/;
//YYYY-MM (YYYYMM is invalid)
var matchCalendarMonth = /^(\d{4})-(\d{2})$/;
//YYYY-DDD or YYYYDDD
var matchOrdinalDate = /^(\d{4})-?(\d{3})$/;
//YYYY-Www or YYYYWww or YYYY-Www-D or YYYYWwwD
var matchWeekDate = /^(\d{4})-?W(\d{2})-?(\d{1})?$/;
//YYYY-MM-DD or YYYYMMDD
var matchCalendarDate = /^(\d{4})-?(\d{2})-?(\d{2})$/;
// Match utc offset
var utcOffset = /([Z+\-])?(\d{2})?:?(\d{2})?$/;
// Match hours HH or HH.xxxxx
var matchHours = /^(\d{2})(\.\d+)?/.source + utcOffset.source;
// Match hours/minutes HH:MM HHMM.xxxxx
var matchHoursMinutes = /^(\d{2}):?(\d{2})(\.\d+)?/.source + utcOffset.source;
// Match hours/minutes HH:MM:SS HHMMSS.xxxxx
var matchHoursMinutesSeconds = /^(\d{2}):?(\d{2}):?(\d{2})(\.\d+)?/.source + utcOffset.source;
var iso8601ErrorMessage = 'Invalid ISO 8601 date.';
/**
* Represents an astronomical Julian date, which is the number of days since noon on January 1, -4712 (4713 BC).
* For increased precision, this class stores the whole number part of the date and the seconds
* part of the date in separate components. In order to be safe for arithmetic and represent
* leap seconds, the date is always stored in the International Atomic Time standard
* {@link TimeStandard.TAI}.
* @alias JulianDate
* @constructor
*
* @param {Number} [julianDayNumber=0.0] The Julian Day Number representing the number of whole days. Fractional days will also be handled correctly.
* @param {Number} [secondsOfDay=0.0] The number of seconds into the current Julian Day Number. Fractional seconds, negative seconds and seconds greater than a day will be handled correctly.
* @param {TimeStandard} [timeStandard=TimeStandard.UTC] The time standard in which the first two parameters are defined.
*/
function JulianDate(julianDayNumber, secondsOfDay, timeStandard) {
/**
* Gets or sets the number of whole days.
* @type {Number}
*/
this.dayNumber = undefined;
/**
* Gets or sets the number of seconds into the current day.
* @type {Number}
*/
this.secondsOfDay = undefined;
julianDayNumber = defaultValue(julianDayNumber, 0.0);
secondsOfDay = defaultValue(secondsOfDay, 0.0);
timeStandard = defaultValue(timeStandard, TimeStandard.UTC);
//If julianDayNumber is fractional, make it an integer and add the number of seconds the fraction represented.
var wholeDays = julianDayNumber | 0;
secondsOfDay = secondsOfDay + (julianDayNumber - wholeDays) * TimeConstants.SECONDS_PER_DAY;
setComponents(wholeDays, secondsOfDay, this);
if (timeStandard === TimeStandard.UTC) {
convertUtcToTai(this);
}
}
/**
* Creates a new instance from a JavaScript Date.
*
* @param {Date} date A JavaScript Date.
* @param {JulianDate} [result] An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter or a new instance if none was provided.
*
* @exception {DeveloperError} date must be a valid JavaScript Date.
*/
JulianDate.fromDate = function(date, result) {
//>>includeStart('debug', pragmas.debug);
if (!(date instanceof Date) || isNaN(date.getTime())) {
throw new DeveloperError('date must be a valid JavaScript Date.');
}
//>>includeEnd('debug');
var components = computeJulianDateComponents(date.getUTCFullYear(), date.getUTCMonth() + 1, date.getUTCDate(), date.getUTCHours(), date.getUTCMinutes(), date.getUTCSeconds(), date.getUTCMilliseconds());
if (!defined(result)) {
return new JulianDate(components[0], components[1], TimeStandard.UTC);
}
setComponents(components[0], components[1], result);
convertUtcToTai(result);
return result;
};
/**
* Creates a new instance from a from an {@link http://en.wikipedia.org/wiki/ISO_8601|ISO 8601} date.
* This method is superior to <code>Date.parse</code> because it will handle all valid formats defined by the ISO 8601
* specification, including leap seconds and sub-millisecond times, which discarded by most JavaScript implementations.
*
* @param {String} iso8601String An ISO 8601 date.
* @param {JulianDate} [result] An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter or a new instance if none was provided.
*
* @exception {DeveloperError} Invalid ISO 8601 date.
*/
JulianDate.fromIso8601 = function(iso8601String, result) {
//>>includeStart('debug', pragmas.debug);
if (typeof iso8601String !== 'string') {
throw new DeveloperError(iso8601ErrorMessage);
}
//>>includeEnd('debug');
//Comma and decimal point both indicate a fractional number according to ISO 8601,
//start out by blanket replacing , with . which is the only valid such symbol in JS.
iso8601String = iso8601String.replace(',', '.');
//Split the string into its date and time components, denoted by a mandatory T
var tokens = iso8601String.split('T');
var year;
var month = 1;
var day = 1;
var hour = 0;
var minute = 0;
var second = 0;
var millisecond = 0;
//Lacking a time is okay, but a missing date is illegal.
var date = tokens[0];
var time = tokens[1];
var tmp;
var inLeapYear;
//>>includeStart('debug', pragmas.debug);
if (!defined(date)) {
throw new DeveloperError(iso8601ErrorMessage);
}
var dashCount;
//>>includeEnd('debug');
//First match the date against possible regular expressions.
tokens = date.match(matchCalendarDate);
if (tokens !== null) {
//>>includeStart('debug', pragmas.debug);
dashCount = date.split('-').length - 1;
if (dashCount > 0 && dashCount !== 2) {
throw new DeveloperError(iso8601ErrorMessage);
}
//>>includeEnd('debug');
year = +tokens[1];
month = +tokens[2];
day = +tokens[3];
} else {
tokens = date.match(matchCalendarMonth);
if (tokens !== null) {
year = +tokens[1];
month = +tokens[2];
} else {
tokens = date.match(matchCalendarYear);
if (tokens !== null) {
year = +tokens[1];
} else {
//Not a year/month/day so it must be an ordinal date.
var dayOfYear;
tokens = date.match(matchOrdinalDate);
if (tokens !== null) {
year = +tokens[1];
dayOfYear = +tokens[2];
inLeapYear = isLeapYear(year);
//This validation is only applicable for this format.
//>>includeStart('debug', pragmas.debug);
if (dayOfYear < 1 || (inLeapYear && dayOfYear > 366) || (!inLeapYear && dayOfYear > 365)) {
throw new DeveloperError(iso8601ErrorMessage);
}
//>>includeEnd('debug')
} else {
tokens = date.match(matchWeekDate);
if (tokens !== null) {
//ISO week date to ordinal date from
//http://en.wikipedia.org/w/index.php?title=ISO_week_date&oldid=474176775
year = +tokens[1];
var weekNumber = +tokens[2];
var dayOfWeek = +tokens[3] || 0;
//>>includeStart('debug', pragmas.debug);
dashCount = date.split('-').length - 1;
if (dashCount > 0 &&
((!defined(tokens[3]) && dashCount !== 1) ||
(defined(tokens[3]) && dashCount !== 2))) {
throw new DeveloperError(iso8601ErrorMessage);
}
//>>includeEnd('debug')
var january4 = new Date(Date.UTC(year, 0, 4));
dayOfYear = (weekNumber * 7) + dayOfWeek - january4.getUTCDay() - 3;
} else {
//None of our regular expressions succeeded in parsing the date properly.
//>>includeStart('debug', pragmas.debug);
throw new DeveloperError(iso8601ErrorMessage);
//>>includeEnd('debug')
}
}
//Split an ordinal date into month/day.
tmp = new Date(Date.UTC(year, 0, 1));
tmp.setUTCDate(dayOfYear);
month = tmp.getUTCMonth() + 1;
day = tmp.getUTCDate();
}
}
}
//Now that we have all of the date components, validate them to make sure nothing is out of range.
inLeapYear = isLeapYear(year);
//>>includeStart('debug', pragmas.debug);
if (month < 1 || month > 12 || day < 1 || ((month !== 2 || !inLeapYear) && day > daysInMonth[month - 1]) || (inLeapYear && month === 2 && day > daysInLeapFeburary)) {
throw new DeveloperError(iso8601ErrorMessage);
}
//>>includeEnd('debug')
//Not move onto the time string, which is much simpler.
var offsetIndex;
if (defined(time)) {
tokens = time.match(matchHoursMinutesSeconds);
if (tokens !== null) {
//>>includeStart('debug', pragmas.debug);
dashCount = time.split(':').length - 1;
if (dashCount > 0 && dashCount !== 2 && dashCount !== 3) {
throw new DeveloperError(iso8601ErrorMessage);
}
//>>includeEnd('debug')
hour = +tokens[1];
minute = +tokens[2];
second = +tokens[3];
millisecond = +(tokens[4] || 0) * 1000.0;
offsetIndex = 5;
} else {
tokens = time.match(matchHoursMinutes);
if (tokens !== null) {
//>>includeStart('debug', pragmas.debug);
dashCount = time.split(':').length - 1;
if (dashCount > 2) {
throw new DeveloperError(iso8601ErrorMessage);
}
//>>includeEnd('debug')
hour = +tokens[1];
minute = +tokens[2];
second = +(tokens[3] || 0) * 60.0;
offsetIndex = 4;
} else {
tokens = time.match(matchHours);
if (tokens !== null) {
hour = +tokens[1];
minute = +(tokens[2] || 0) * 60.0;
offsetIndex = 3;
} else {
//>>includeStart('debug', pragmas.debug);
throw new DeveloperError(iso8601ErrorMessage);
//>>includeEnd('debug')
}
}
}
//Validate that all values are in proper range. Minutes and hours have special cases at 60 and 24.
//>>includeStart('debug', pragmas.debug);
if (minute >= 60 || second >= 61 || hour > 24 || (hour === 24 && (minute > 0 || second > 0 || millisecond > 0))) {
throw new DeveloperError(iso8601ErrorMessage);
}
//>>includeEnd('debug');
//Check the UTC offset value, if no value exists, use local time
//a Z indicates UTC, + or - are offsets.
var offset = tokens[offsetIndex];
var offsetHours = +(tokens[offsetIndex + 1]);
var offsetMinutes = +(tokens[offsetIndex + 2] || 0);
switch (offset) {
case '+':
hour = hour - offsetHours;
minute = minute - offsetMinutes;
break;
case '-':
hour = hour + offsetHours;
minute = minute + offsetMinutes;
break;
case 'Z':
break;
default:
minute = minute + new Date(Date.UTC(year, month - 1, day, hour, minute)).getTimezoneOffset();
break;
}
} else {
//If no time is specified, it is considered the beginning of the day, local time.
minute = minute + new Date(year, month - 1, day).getTimezoneOffset();
}
//ISO8601 denotes a leap second by any time having a seconds component of 60 seconds.
//If that's the case, we need to temporarily subtract a second in order to build a UTC date.
//Then we add it back in after converting to TAI.
var isLeapSecond = second === 60;
if (isLeapSecond) {
second--;
}
//Even if we successfully parsed the string into its components, after applying UTC offset or
//special cases like 24:00:00 denoting midnight, we need to normalize the data appropriately.
//milliseconds can never be greater than 1000, and seconds can't be above 60, so we start with minutes
while (minute >= 60) {
minute -= 60;
hour++;
}
while (hour >= 24) {
hour -= 24;
day++;
}
tmp = (inLeapYear && month === 2) ? daysInLeapFeburary : daysInMonth[month - 1];
while (day > tmp) {
day -= tmp;
month++;
if (month > 12) {
month -= 12;
year++;
}
tmp = (inLeapYear && month === 2) ? daysInLeapFeburary : daysInMonth[month - 1];
}
//If UTC offset is at the beginning/end of the day, minutes can be negative.
while (minute < 0) {
minute += 60;
hour--;
}
while (hour < 0) {
hour += 24;
day--;
}
while (day < 1) {
month--;
if (month < 1) {
month += 12;
year--;
}
tmp = (inLeapYear && month === 2) ? daysInLeapFeburary : daysInMonth[month - 1];
day += tmp;
}
//Now create the JulianDate components from the Gregorian date and actually create our instance.
var components = computeJulianDateComponents(year, month, day, hour, minute, second, millisecond);
if (!defined(result)) {
result = new JulianDate(components[0], components[1], TimeStandard.UTC);
} else {
setComponents(components[0], components[1], result);
convertUtcToTai(result);
}
//If we were on a leap second, add it back.
if (isLeapSecond) {
JulianDate.addSeconds(result, 1, result);
}
return result;
};
/**
* Creates a new instance that represents the current system time.
* This is equivalent to calling <code>JulianDate.fromDate(new Date());</code>.
*
* @param {JulianDate} [result] An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter or a new instance if none was provided.
*/
JulianDate.now = function(result) {
return JulianDate.fromDate(new Date(), result);
};
var toGregorianDateScratch = new JulianDate(0, 0, TimeStandard.TAI);
/**
* Creates a {@link GregorianDate} from the provided instance.
*
* @param {JulianDate} julianDate The date to be converted.
* @param {GregorianDate} [result] An existing instance to use for the result.
* @returns {GregorianDate} The modified result parameter or a new instance if none was provided.
*/
JulianDate.toGregorianDate = function(julianDate, result) {
//>>includeStart('debug', pragmas.debug);
if (!defined(julianDate)) {
throw new DeveloperError('julianDate is required.');
}
//>>includeEnd('debug');
var isLeapSecond = false;
var thisUtc = convertTaiToUtc(julianDate, toGregorianDateScratch);
if (!defined(thisUtc)) {
//Conversion to UTC will fail if we are during a leap second.
//If that's the case, subtract a second and convert again.
//JavaScript doesn't support leap seconds, so this results in second 59 being repeated twice.
JulianDate.addSeconds(julianDate, -1, toGregorianDateScratch);
thisUtc = convertTaiToUtc(toGregorianDateScratch, toGregorianDateScratch);
isLeapSecond = true;
}
var julianDayNumber = thisUtc.dayNumber;
var secondsOfDay = thisUtc.secondsOfDay;
if (secondsOfDay >= 43200.0) {
julianDayNumber += 1;
}
// Algorithm from page 604 of the Explanatory Supplement to the
// Astronomical Almanac (Seidelmann 1992).
var L = (julianDayNumber + 68569) | 0;
var N = (4 * L / 146097) | 0;
L = (L - (((146097 * N + 3) / 4) | 0)) | 0;
var I = ((4000 * (L + 1)) / 1461001) | 0;
L = (L - (((1461 * I) / 4) | 0) + 31) | 0;
var J = ((80 * L) / 2447) | 0;
var day = (L - (((2447 * J) / 80) | 0)) | 0;
L = (J / 11) | 0;
var month = (J + 2 - 12 * L) | 0;
var year = (100 * (N - 49) + I + L) | 0;
var hour = (secondsOfDay / TimeConstants.SECONDS_PER_HOUR) | 0;
var remainingSeconds = secondsOfDay - (hour * TimeConstants.SECONDS_PER_HOUR);
var minute = (remainingSeconds / TimeConstants.SECONDS_PER_MINUTE) | 0;
remainingSeconds = remainingSeconds - (minute * TimeConstants.SECONDS_PER_MINUTE);
var second = remainingSeconds | 0;
var millisecond = ((remainingSeconds - second) / TimeConstants.SECONDS_PER_MILLISECOND);
// JulianDates are noon-based
hour += 12;
if (hour > 23) {
hour -= 24;
}
//If we were on a leap second, add it back.
if (isLeapSecond) {
second += 1;
}
if (!defined(result)) {
return new GregorianDate(year, month, day, hour, minute, second, millisecond, isLeapSecond);
}
result.year = year;
result.month = month;
result.day = day;
result.hour = hour;
result.minute = minute;
result.second = second;
result.millisecond = millisecond;
result.isLeapSecond = isLeapSecond;
return result;
};
/**
* Creates a JavaScript Date from the provided instance.
* Since JavaScript dates are only accurate to the nearest millisecond and
* cannot represent a leap second, consider using {@link JulianDate.toGregorianDate} instead.
* If the provided JulianDate is during a leap second, the previous second is used.
*
* @param {JulianDate} julianDate The date to be converted.
* @returns {Date} A new instance representing the provided date.
*/
JulianDate.toDate = function(julianDate) {
//>>includeStart('debug', pragmas.debug);
if (!defined(julianDate)) {
throw new DeveloperError('julianDate is required.');
}
//>>includeEnd('debug');
var gDate = JulianDate.toGregorianDate(julianDate, gregorianDateScratch);
var second = gDate.second;
if (gDate.isLeapSecond) {
second -= 1;
}
return new Date(Date.UTC(gDate.year, gDate.month - 1, gDate.day, gDate.hour, gDate.minute, second, gDate.millisecond));
};
/**
* Creates an ISO8601 representation of the provided date.
*
* @param {JulianDate} julianDate The date to be converted.
* @param {Number} [precision] The number of fractional digits used to represent the seconds component. By default, the most precise representation is used.
* @returns {String} The ISO8601 representation of the provided date.
*/
JulianDate.toIso8601 = function(julianDate, precision) {
//>>includeStart('debug', pragmas.debug);
if (!defined(julianDate)) {
throw new DeveloperError('julianDate is required.');
}
//>>includeEnd('debug');
var gDate = JulianDate.toGregorianDate(julianDate, gDate);
var millisecondStr;
if (!defined(precision) && gDate.millisecond !== 0) {
//Forces milliseconds into a number with at least 3 digits to whatever the default toString() precision is.
millisecondStr = (gDate.millisecond * 0.01).toString().replace('.', '');
return sprintf("%04d-%02d-%02dT%02d:%02d:%02d.%sZ", gDate.year, gDate.month, gDate.day, gDate.hour, gDate.minute, gDate.second, millisecondStr);
}
//Precision is either 0 or milliseconds is 0 with undefined precision, in either case, leave off milliseconds entirely
if (!defined(precision) || precision === 0) {
return sprintf("%04d-%02d-%02dT%02d:%02d:%02dZ", gDate.year, gDate.month, gDate.day, gDate.hour, gDate.minute, gDate.second);
}
//Forces milliseconds into a number with at least 3 digits to whatever the specified precision is.
millisecondStr = (gDate.millisecond * 0.01).toFixed(precision).replace('.', '').slice(0, precision);
return sprintf("%04d-%02d-%02dT%02d:%02d:%02d.%sZ", gDate.year, gDate.month, gDate.day, gDate.hour, gDate.minute, gDate.second, millisecondStr);
};
/**
* Duplicates a JulianDate instance.
*
* @param {JulianDate} julianDate The date to duplicate.
* @param {JulianDate} [result] An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter or a new instance if none was provided. Returns undefined if julianDate is undefined.
*/
JulianDate.clone = function(julianDate, result) {
if (!defined(julianDate)) {
return undefined;
}
if (!defined(result)) {
return new JulianDate(julianDate.dayNumber, julianDate.secondsOfDay, TimeStandard.TAI);
}
result.dayNumber = julianDate.dayNumber;
result.secondsOfDay = julianDate.secondsOfDay;
return result;
};
/**
* Compares two instances.
*
* @param {JulianDate} left The first instance.
* @param {JulianDate} right The second instance.
* @returns {Number} A negative value if left is less than right, a positive value if left is greater than right, or zero if left and right are equal.
*/
JulianDate.compare = function(left, right) {
//>>includeStart('debug', pragmas.debug);
if (!defined(left)) {
throw new DeveloperError('left is required.');
}
if (!defined(right)) {
throw new DeveloperError('right is required.');
}
//>>includeEnd('debug');
var julianDayNumberDifference = left.dayNumber - right.dayNumber;
if (julianDayNumberDifference !== 0) {
return julianDayNumberDifference;
}
return left.secondsOfDay - right.secondsOfDay;
};
/**
* Compares two instances and returns <code>true</code> if they are equal, <code>false</code> otherwise.
*
* @param {JulianDate} [left] The first instance.
* @param {JulianDate} [right] The second instance.
* @returns {Boolean} <code>true</code> if the dates are equal; otherwise, <code>false</code>.
*/
JulianDate.equals = function(left, right) {
return (left === right) ||
(defined(left) &&
defined(right) &&
left.dayNumber === right.dayNumber &&
left.secondsOfDay === right.secondsOfDay);
};
/**
* Compares two instances and returns <code>true</code> if they are within <code>epsilon</code> seconds of
* each other. That is, in order for the dates to be considered equal (and for
* this function to return <code>true</code>), the absolute value of the difference between them, in
* seconds, must be less than <code>epsilon</code>.
*
* @param {JulianDate} [left] The first instance.
* @param {JulianDate} [right] The second instance.
* @param {Number} epsilon The maximum number of seconds that should separate the two instances.
* @returns {Boolean} <code>true</code> if the two dates are within <code>epsilon</code> seconds of each other; otherwise <code>false</code>.
*/
JulianDate.equalsEpsilon = function(left, right, epsilon) {
//>>includeStart('debug', pragmas.debug);
if (!defined(epsilon)) {
throw new DeveloperError('epsilon is required.');
}
//>>includeEnd('debug');
return (left === right) ||
(defined(left) &&
defined(right) &&
Math.abs(JulianDate.secondsDifference(left, right)) <= epsilon);
};
/**
* Computes the total number of whole and fractional days represented by the provided instance.
*
* @param {JulianDate} julianDate The date.
* @returns {Number} The Julian date as single floating point number.
*/
JulianDate.totalDays = function(julianDate) {
//>>includeStart('debug', pragmas.debug);
if (!defined(julianDate)) {
throw new DeveloperError('julianDate is required.');
}
//>>includeEnd('debug');
return julianDate.dayNumber + (julianDate.secondsOfDay / TimeConstants.SECONDS_PER_DAY);
};
/**
* Computes the difference in seconds between the provided instance.
*
* @param {JulianDate} left The first instance.
* @param {JulianDate} right The second instance.
* @returns {Number} The difference, in seconds, when subtracting <code>right</code> from <code>left</code>.
*/
JulianDate.secondsDifference = function(left, right) {
//>>includeStart('debug', pragmas.debug);
if (!defined(left)) {
throw new DeveloperError('left is required.');
}
if (!defined(right)) {
throw new DeveloperError('right is required.');
}
//>>includeEnd('debug');
var dayDifference = (left.dayNumber - right.dayNumber) * TimeConstants.SECONDS_PER_DAY;
return (dayDifference + (left.secondsOfDay - right.secondsOfDay));
};
/**
* Computes the difference in days between the provided instance.
*
* @param {JulianDate} left The first instance.
* @param {JulianDate} right The second instance.
* @returns {Number} The difference, in days, when subtracting <code>right</code> from <code>left</code>.
*/
JulianDate.daysDifference = function(left, right) {
//>>includeStart('debug', pragmas.debug);
if (!defined(left)) {
throw new DeveloperError('left is required.');
}
if (!defined(right)) {
throw new DeveloperError('right is required.');
}
//>>includeEnd('debug');
var dayDifference = (left.dayNumber - right.dayNumber);
var secondDifference = (left.secondsOfDay - right.secondsOfDay) / TimeConstants.SECONDS_PER_DAY;
return dayDifference + secondDifference;
};
/**
* Computes the number of seconds the provided instance is ahead of UTC.
*
* @param {JulianDate} julianDate The date.
* @returns {Number} The number of seconds the provided instance is ahead of UTC
*/
JulianDate.computeTaiMinusUtc = function(julianDate) {
binarySearchScratchLeapSecond.julianDate = julianDate;
var leapSeconds = JulianDate.leapSeconds;
var index = binarySearch(leapSeconds, binarySearchScratchLeapSecond, compareLeapSecondDates);
if (index < 0) {
index = ~index;
--index;
if (index < 0) {
index = 0;
}
}
return leapSeconds[index].offset;
};
/**
* Adds the provided number of seconds to the provided date instance.
*
* @param {JulianDate} julianDate The date.
* @param {Number} seconds The number of seconds to add or subtract.
* @param {JulianDate} result An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter.
*/
JulianDate.addSeconds = function(julianDate, seconds, result) {
//>>includeStart('debug', pragmas.debug);
if (!defined(julianDate)) {
throw new DeveloperError('julianDate is required.');
}
if (!defined(seconds)) {
throw new DeveloperError('seconds is required.');
}
if (!defined(result)) {
throw new DeveloperError('result is required.');
}
//>>includeEnd('debug');
return setComponents(julianDate.dayNumber, julianDate.secondsOfDay + seconds, result);
};
/**
* Adds the provided number of minutes to the provided date instance.
*
* @param {JulianDate} julianDate The date.
* @param {Number} minutes The number of minutes to add or subtract.
* @param {JulianDate} result An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter.
*/
JulianDate.addMinutes = function(julianDate, minutes, result) {
//>>includeStart('debug', pragmas.debug);
if (!defined(julianDate)) {
throw new DeveloperError('julianDate is required.');
}
if (!defined(minutes)) {
throw new DeveloperError('minutes is required.');
}
if (!defined(result)) {
throw new DeveloperError('result is required.');
}
//>>includeEnd('debug');
var newSecondsOfDay = julianDate.secondsOfDay + (minutes * TimeConstants.SECONDS_PER_MINUTE);
return setComponents(julianDate.dayNumber, newSecondsOfDay, result);
};
/**
* Adds the provided number of hours to the provided date instance.
*
* @param {JulianDate} julianDate The date.
* @param {Number} hours The number of hours to add or subtract.
* @param {JulianDate} result An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter.
*/
JulianDate.addHours = function(julianDate, hours, result) {
//>>includeStart('debug', pragmas.debug);
if (!defined(julianDate)) {
throw new DeveloperError('julianDate is required.');
}
if (!defined(hours)) {
throw new DeveloperError('hours is required.');
}
if (!defined(result)) {
throw new DeveloperError('result is required.');
}
//>>includeEnd('debug');
var newSecondsOfDay = julianDate.secondsOfDay + (hours * TimeConstants.SECONDS_PER_HOUR);
return setComponents(julianDate.dayNumber, newSecondsOfDay, result);
};
/**
* Adds the provided number of days to the provided date instance.
*
* @param {JulianDate} julianDate The date.
* @param {Number} days The number of days to add or subtract.
* @param {JulianDate} result An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter.
*/
JulianDate.addDays = function(julianDate, days, result) {
//>>includeStart('debug', pragmas.debug);
if (!defined(julianDate)) {
throw new DeveloperError('julianDate is required.');
}
if (!defined(days)) {
throw new DeveloperError('days is required.');
}
if (!defined(result)) {
throw new DeveloperError('result is required.');
}
//>>includeEnd('debug');
var newJulianDayNumber = julianDate.dayNumber + days;
return setComponents(newJulianDayNumber, julianDate.secondsOfDay, result);
};
/**
* Compares the provided instances and returns <code>true</code> if <code>left</code> is earlier than <code>right</code>, <code>false</code> otherwise.
*
* @param {JulianDate} left The first instance.
* @param {JulianDate} right The second instance.
* @returns {Boolean} <code>true</code> if <code>left</code> is earlier than <code>right</code>, <code>false</code> otherwise.
*/
JulianDate.lessThan = function(left, right) {
return JulianDate.compare(left, right) < 0;
};
/**
* Compares the provided instances and returns <code>true</code> if <code>left</code> is earlier than or equal to <code>right</code>, <code>false</code> otherwise.
*
* @param {JulianDate} left The first instance.
* @param {JulianDate} right The second instance.
* @returns {Boolean} <code>true</code> if <code>left</code> is earlier than or equal to <code>right</code>, <code>false</code> otherwise.
*/
JulianDate.lessThanOrEquals = function(left, right) {
return JulianDate.compare(left, right) <= 0;
};
/**
* Compares the provided instances and returns <code>true</code> if <code>left</code> is later than <code>right</code>, <code>false</code> otherwise.
*
* @param {JulianDate} left The first instance.
* @param {JulianDate} right The second instance.
* @returns {Boolean} <code>true</code> if <code>left</code> is later than <code>right</code>, <code>false</code> otherwise.
*/
JulianDate.greaterThan = function(left, right) {
return JulianDate.compare(left, right) > 0;
};
/**
* Compares the provided instances and returns <code>true</code> if <code>left</code> is later than or equal to <code>right</code>, <code>false</code> otherwise.
*
* @param {JulianDate} left The first instance.
* @param {JulianDate} right The second instance.
* @returns {Boolean} <code>true</code> if <code>left</code> is later than or equal to <code>right</code>, <code>false</code> otherwise.
*/
JulianDate.greaterThanOrEquals = function(left, right) {
return JulianDate.compare(left, right) >= 0;
};
/**
* Duplicates this instance.
*
* @param {JulianDate} [result] An existing instance to use for the result.
* @returns {JulianDate} The modified result parameter or a new instance if none was provided.
*/
JulianDate.prototype.clone = function(result) {
return JulianDate.clone(this, result);
};
/**
* Compares this and the provided instance and returns <code>true</code> if they are equal, <code>false</code> otherwise.
*
* @param {JulianDate} [right] The second instance.
* @returns {Boolean} <code>true</code> if the dates are equal; otherwise, <code>false</code>.
*/
JulianDate.prototype.equals = function(right) {
return JulianDate.equals(this, right);
};
/**
* Compares this and the provided instance and returns <code>true</code> if they are within <code>epsilon</code> seconds of
* each other. That is, in order for the dates to be considered equal (and for
* this function to return <code>true</code>), the absolute value of the difference between them, in
* seconds, must be less than <code>epsilon</code>.
*
* @param {JulianDate} [right] The second instance.
* @param {Number} epsilon The maximum number of seconds that should separate the two instances.
* @returns {Boolean} <code>true</code> if the two dates are within <code>epsilon</code> seconds of each other; otherwise <code>false</code>.
*/
JulianDate.prototype.equalsEpsilon = function(right, epsilon) {
return JulianDate.equalsEpsilon(this, right, epsilon);
};
/**
* Creates a string representing this date in ISO8601 format.
*
* @returns {String} A string representing this date in ISO8601 format.
*/
JulianDate.prototype.toString = function() {
return JulianDate.toIso8601(this);
};
/**
* Gets or sets the list of leap seconds used throughout Cesium.
* @memberof JulianDate
* @type {LeapSecond[]}
*/
JulianDate.leapSeconds = [
new LeapSecond(new JulianDate(2441317, 43210.0, TimeStandard.TAI), 10), // January 1, 1972 00:00:00 UTC
new LeapSecond(new JulianDate(2441499, 43211.0, TimeStandard.TAI), 11), // July 1, 1972 00:00:00 UTC
new LeapSecond(new JulianDate(2441683, 43212.0, TimeStandard.TAI), 12), // January 1, 1973 00:00:00 UTC
new LeapSecond(new JulianDate(2442048, 43213.0, TimeStandard.TAI), 13), // January 1, 1974 00:00:00 UTC
new LeapSecond(new JulianDate(2442413, 43214.0, TimeStandard.TAI), 14), // January 1, 1975 00:00:00 UTC
new LeapSecond(new JulianDate(2442778, 43215.0, TimeStandard.TAI), 15), // January 1, 1976 00:00:00 UTC
new LeapSecond(new JulianDate(2443144, 43216.0, TimeStandard.TAI), 16), // January 1, 1977 00:00:00 UTC
new LeapSecond(new JulianDate(2443509, 43217.0, TimeStandard.TAI), 17), // January 1, 1978 00:00:00 UTC
new LeapSecond(new JulianDate(2443874, 43218.0, TimeStandard.TAI), 18), // January 1, 1979 00:00:00 UTC
new LeapSecond(new JulianDate(2444239, 43219.0, TimeStandard.TAI), 19), // January 1, 1980 00:00:00 UTC
new LeapSecond(new JulianDate(2444786, 43220.0, TimeStandard.TAI), 20), // July 1, 1981 00:00:00 UTC
new LeapSecond(new JulianDate(2445151, 43221.0, TimeStandard.TAI), 21), // July 1, 1982 00:00:00 UTC
new LeapSecond(new JulianDate(2445516, 43222.0, TimeStandard.TAI), 22), // July 1, 1983 00:00:00 UTC
new LeapSecond(new JulianDate(2446247, 43223.0, TimeStandard.TAI), 23), // July 1, 1985 00:00:00 UTC
new LeapSecond(new JulianDate(2447161, 43224.0, TimeStandard.TAI), 24), // January 1, 1988 00:00:00 UTC
new LeapSecond(new JulianDate(2447892, 43225.0, TimeStandard.TAI), 25), // January 1, 1990 00:00:00 UTC
new LeapSecond(new JulianDate(2448257, 43226.0, TimeStandard.TAI), 26), // January 1, 1991 00:00:00 UTC
new LeapSecond(new JulianDate(2448804, 43227.0, TimeStandard.TAI), 27), // July 1, 1992 00:00:00 UTC
new LeapSecond(new JulianDate(2449169, 43228.0, TimeStandard.TAI), 28), // July 1, 1993 00:00:00 UTC
new LeapSecond(new JulianDate(2449534, 43229.0, TimeStandard.TAI), 29), // July 1, 1994 00:00:00 UTC
new LeapSecond(new JulianDate(2450083, 43230.0, TimeStandard.TAI), 30), // January 1, 1996 00:00:00 UTC
new LeapSecond(new JulianDate(2450630, 43231.0, TimeStandard.TAI), 31), // July 1, 1997 00:00:00 UTC
new LeapSecond(new JulianDate(2451179, 43232.0, TimeStandard.TAI), 32), // January 1, 1999 00:00:00 UTC
new LeapSecond(new JulianDate(2453736, 43233.0, TimeStandard.TAI), 33), // January 1, 2006 00:00:00 UTC
new LeapSecond(new JulianDate(2454832, 43234.0, TimeStandard.TAI), 34), // January 1, 2009 00:00:00 UTC
new LeapSecond(new JulianDate(2456109, 43235.0, TimeStandard.TAI), 35), // July 1, 2012 00:00:00 UTC
new LeapSecond(new JulianDate(2457204, 43236.0, TimeStandard.TAI), 36), // July 1, 2015 00:00:00 UTC
new LeapSecond(new JulianDate(2457754, 43237.0, TimeStandard.TAI), 37) // January 1, 2017 00:00:00 UTC
];
return JulianDate;
});