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	standard library package Time {
	doc
	/*
	* This package specifies concepts to support time-related quantities and metrology, beyond
	* the quantities duration and time as defined in [ISO 80000-3]. Representations of the
	* Gregorian calendar date and time of day as specified by the [ISO 8601-1] standard are used.
	*/

	private import Occurrences::Occurrence;
	private import ScalarValues::Real;
	private import ScalarValues::Integer;
	private import ScalarValues::Natural;
	private import ScalarValues::String;
	private import Quantities::ScalarQuantityValue;
	private import Quantities::scalarQuantities;
	private import MeasurementReferences::*;
	public import ISQBase::DurationValue;
	public import ISQBase::DurationUnit;
	public import ISQBase::duration;
	public import ISQSpaceTime::TimeValue;
	public import ISQSpaceTime::TimeUnit;
	public import ISQSpaceTime::time;

	readonly part universalClock : Clock[1] :> Clocks::universalClock {
	doc
	/*
	* universalClock is a single Clock that can be used as a default universal time reference.
	*/
	}

	part def Clock :> Clocks::Clock {
	doc
	/*
	* A Clock provides a currentTime as a TimeInstantValue that advances montonically over its lifetime.
	*/

	attribute :>> currentTime : TimeInstantValue;
	}

	calc def TimeOf :> Clocks::TimeOf {
	doc
	/*
	* TimeOf returns a TimeInstantValue for a given Occurrence relative to a given Clock. This TimeInstantValue is the
	* time of the start of the Occurrence, which is considered to be synchronized with the snapshot of the Clock with a
	* currentTime equal to the returned timeInstant.
	*/

	in o : Occurrence[1];
	in clock : Clock[1] default localClock;
	return timeInstant : TimeInstantValue[1];
	}

	calc def DurationOf :> Clocks::DurationOf {
	doc
	/*
	* DurationOf returns the duration of a given Occurrence relative to a given Clock, which is equal to the TimeOf
	* the end snapshot of the Occurrence minus the TimeOf its start snapshot.
	*/

	in o : Occurrence[1];
	in clock : Clock[1] default localClock;
	return duration : DurationValue;
	}

	attribute def TimeScale :> IntervalScale {
	doc
	/*
	* Generic time scale to express a time instant, including a textual definition of the meaning of zero time instant value
	*
	* Attribute definitionalEpoch captures the specification of the time instant with value zero, also known as the (reference) epoch.
	*/

	attribute :>> unit: DurationUnit[1];
	attribute definitionalEpoch: DefinitionalQuantityValue[1];
	attribute :>> definitionalQuantityValues = definitionalEpoch;
	}

	attribute def TimeInstantValue :> ScalarQuantityValue {
	doc
	/*
	* Representation of a time instant quantity
	*
	* Also known as instant (of time), or, point in time.
	*/

	attribute :>> num: Real[1];
	attribute :>> mRef: TimeScale[1];
	}
	attribute timeInstant: TimeInstantValue :> scalarQuantities;

	abstract attribute def DateTime :> TimeInstantValue {
	doc
	/*
	* Generic representation of a time instant as a calendar date and time of day
	*/
	}

	abstract attribute def Date :> TimeInstantValue {
	doc
	/*
	* Generic representation of a time instant as a calendar date
	*/
	}

	abstract attribute def TimeOfDay :> TimeInstantValue {
	doc
	/*
	* Generic representation of a time instant as a time of day
	*/
	}

	attribute <UTC> 'Coordinated Universal Time' : TimeScale {
	doc
	/*
	* Representation of the Coordinated Universal Time (UTC) time scale
	*
	* UTC is the primary time standard by which the world regulates clocks and time. It is within about 1 second of mean solar time
	* at 0° longitude and is not adjusted for daylight saving time.
	* UTC is obtained from International Atomic Time (TAI) by the insertion of leap seconds according to the advice of
	* the International Earth Rotation and Reference Systems Service (IERS) to ensure approximate agreement
	* with the time derived from the rotation of the Earth.
	*
	* References:
	* ITU-R TF.460-6 (see https://www.itu.int/rec/R-REC-TF.460/en)
	* BIPM technical services: Time Metrology (see https://www.bipm.org/en/time-metrology)
	*
	* Introductions:
	* For UTC see https://en.wikipedia.org/wiki/Coordinated_Universal_Time
	* For TAI see https://en.wikipedia.org/wiki/International_Atomic_Time
	*/

	attribute :>> unit = SI::s;
	attribute :>> definitionalEpoch: DefinitionalQuantityValue { :>> num = 0; :>> definition = "UTC epoch at 1 January 1958 at 0 hour 0 minute 0 second"; }
	}

	attribute def UtcTimeInstantValue :> DateTime {
	:>> mRef = UTC {
	doc
	/*
	* Representation of a time instant expressed on the Coordinated Universal Time (UTC) time scale
	*/
	}
	}
	attribute utcTimeInstant: UtcTimeInstantValue :> timeInstant;

	/*
	* Representations of a Gregorian calendar date and time of day as specified by the ISO 8601-1 standard.
	*
	* As explained in ISO 8601-1 clause 4.2.1:
	* ISO 8601-1 uses the Gregorian calendar for the identification of calendar days.
	*
	* The Gregorian calendar provides a time scale consisting of a series of contiguous calendar years,
	* each identified by a year number represented by an integer, greater than that of the
	* immediately preceding calendar year by 1. ISO 8601-1 allows the identification of calendar years
	* by their year number for years both before and after the introduction of the Gregorian calendar.
	*
	* The Gregorian calendar distinguishes common years of 365 consecutive calendar days and leap years
	* of 366 consecutive calendar days.
	*
	* In the Gregorian calendar each calendar year is divided into 12 sequential calendar months,
	* each consisting of a specific number of calendar days in the range 28 to 31. Usage of the Gregorian calendar
	* for identifying dates preceding its introduction (15 October 1582) should only be by mutual agreement
	* of the communicating partners.
	*
	* Reference: ISO 8601-1:2019 (First edition)
	* "Date and time — Representations for information interchange — Part 1: Basic rules"
	* (see https://www.iso.org/standard/70907.html)
	*/

	attribute def Iso8601DateTimeEncoding :> String {
	doc
	/*
	* Extended string encoding of an ISO 8601-1 date and time
	*
	* The format of the string must comply with the following EBNF production:
	* ['+' \| '-'] YYYY '-' MM '-' DD 'T' hh ':' mm ':' ss ['.' fff [fff]] ('Z' \| timezoneOffset )
	* where:
	* YYYY is 4-or-more-digit year number, which can be negative for years before 0000;
	* MM is 2-digit month in year number, in which 01 is January, 02 is February, ..., 12 is December;
	* DD is 2-digit day in month number in range 01 to 28, 29, 30, 31 depending on month and leap year;
	* hh is 2-digit hour in day number in range 00 to 23;
	* mm is 2-digit minute in hour in range 00 to 59;
	* ss is 2-digit second in minute in range 00 to 60, in in case of leap second;
	* ['.' fff [fff]] is an optional 3-digit millisecond or 6-digit microsecond fraction;
	* timezoneOffset is ('+' \| '-') hhOffset ':' mmOffset, denoting the local timezone hour and minute offset w.r.t. UTC,
	* in which '+' specifies an offset ahead of UTC and '-' specifies an offset behind UTC;
	*
	* Note 1: All components are expressed with leading zeros.
	* Note 2: 'Z' instead of timezoneOffset denotes a UTC time, i.e. zero time offset.
	* Note 3: The ss value may only be 60 when a leap second is inserted.
	*
	* Examples of such a date and time value are:
	* 2021-08-30T12:30:24Z (UTC date and time with second precision)
	* 2018-01-23T23:14:44.304827Z (UTC date and time with microsecond precision)
	* 1969-07-20T20:17:00Z (UTC date and time with second precision)
	* 1969-07-20T15:17:00-05:00 (local date and time with second precision for a timezone 5 hour behind UTC)
	* 1969-07-20T22:17:00+02:00 (local date and time with second precision for a timezone 2 hour ahead of UTC)
	*
	* TODO: Add constraint to verify ISO 8691 extended string encoding.
	*/
	}

	attribute def Iso8601DateTime :> UtcTimeInstantValue {
	doc
	/*
	* Representation of an ISO 8601-1 date and time in extended string format
	*/

	attribute val: Iso8601DateTimeEncoding;
	attribute :>> num = getElapsedUtcTime(val);
	private calc getElapsedUtcTime {
	in iso8601DateTime: Iso8601DateTimeEncoding;
	/* Return the number of seconds elapsed since the UTC epoch.
	* Can be negative when the date and time is earlier than the epoch.
	*/
	return : Real;
	}
	}

	attribute def Iso8601DateTimeStructure :> UtcTimeInstantValue {
	doc
	/*
	* Representation of an ISO 8601 date and time with explicit date and time component attributes
	*
	* TO DO: Specify restrictions for attributes month (1 to 12), day (1 to 31), hour (0 to 23), minute (0 to 59), second (0 to 60),
	* microsecond (0 to 999999), hourOffset (-12 to +12), minuteOffset (-59 to +59)
	*
	* The total time offset is equal to the summation of hourOffset and minuteOffset.
	*/

	attribute year: Integer;
	attribute month: Natural;
	attribute day: Natural;
	attribute hour: Natural;
	attribute minute: Natural;
	attribute second: Natural;
	attribute microsecond: Natural;
	attribute hourOffset: Integer;
	attribute minuteOffset: Integer;
	attribute :>> num = getElapsedUtcTime(year, month, day, hour, minute, second, microsecond, hourOffset, minuteOffset);
	private calc getElapsedUtcTime {
	in year: Integer;
	in month: Natural;
	in day: Natural;
	in hour: Natural;
	in minute: Natural;
	in second: Natural;
	in microsecond: Natural;
	in hourOffset: Integer;
	in minuteOffest: Integer;
	return : Real;
	}
	}

	calc convertIso8601DateTimeToStructure {
	doc
	/*
	* Calculation to convert an ISO 8601 date and time instant from string to component structure representation
	*/

	in iso8601DateTime: Iso8601DateTime;
	/* Parse ISO 8601 string encoding to date and time components */
	return : Iso8601DateTimeStructure;
	}

	calc convertIso8601StructureToDateTime {
	doc
	/*
	* Calculation to convert an ISO 8601 date and time instant from component structure to string representation
	*/

	in iso8601DateTimeStructure: Iso8601DateTimeStructure;
	attribute x: Iso8601DateTime;
	/* Concatenate ISO 8601 date and time components to string
	* year-month-dayThour:minute:second±hourOffset:minuteOffset
	*/
	return : Iso8601DateTime;
	}
	}