// // DateTime.h // // Library: Foundation // Package: DateTime // Module: DateTime // // Definition of the DateTime class. // // Copyright (c) 2004-2006, Applied Informatics Software Engineering GmbH. // and Contributors. // // SPDX-License-Identifier: BSL-1.0 // #ifndef Foundation_DateTime_INCLUDED #define Foundation_DateTime_INCLUDED #include "Poco/Foundation.h" #include "Poco/Timespan.h" #include "Poco/Timestamp.h" namespace Poco { class Foundation_API DateTime /// This class represents an instant in time, expressed /// in years, months, days, hours, minutes, seconds /// and milliseconds based on the Gregorian calendar. /// The class is mainly useful for conversions between /// UTC, Julian day and Gregorian calendar dates. /// /// The date and time stored in a DateTime is always in UTC /// (Coordinated Universal Time) and thus independent of the /// timezone in effect on the system. /// /// Conversion calculations are based on algorithms /// collected and described by Peter Baum at /// http://vsg.cape.com/~pbaum/date/date0.htm /// /// Internally, this class stores a date/time in two /// forms (UTC and broken down) for performance reasons. Only use /// this class for conversions between date/time representations. /// Use the Timestamp class for everything else. /// /// Notes: /// * Zero is a valid year (in accordance with ISO 8601 and astronomical year numbering) /// * Year zero (0) is a leap year /// * Negative years (years preceding 1 BC) are not supported /// /// For more information, please see: /// * http://en.wikipedia.org/wiki/Gregorian_Calendar /// * http://en.wikipedia.org/wiki/Julian_day /// * http://en.wikipedia.org/wiki/UTC /// * http://en.wikipedia.org/wiki/ISO_8601 { public: enum Months /// Symbolic names for month numbers (1 to 12). { JANUARY = 1, FEBRUARY, MARCH, APRIL, MAY, JUNE, JULY, AUGUST, SEPTEMBER, OCTOBER, NOVEMBER, DECEMBER }; enum DaysOfWeek /// Symbolic names for week day numbers (0 to 6). { SUNDAY = 0, MONDAY, TUESDAY, WEDNESDAY, THURSDAY, FRIDAY, SATURDAY }; DateTime(); /// Creates a DateTime for the current date and time. DateTime(const Timestamp & timestamp); /// Creates a DateTime for the date and time given in /// a Timestamp. DateTime(int year, int month, int day, int hour = 0, int minute = 0, int second = 0, int millisecond = 0, int microsecond = 0); /// Creates a DateTime for the given Gregorian date and time. /// * year is from 0 to 9999. /// * month is from 1 to 12. /// * day is from 1 to 31. /// * hour is from 0 to 23. /// * minute is from 0 to 59. /// * second is from 0 to 60 (allowing leap seconds). /// * millisecond is from 0 to 999. /// * microsecond is from 0 to 999. DateTime(double julianDay); /// Creates a DateTime for the given Julian day. DateTime(Timestamp::UtcTimeVal utcTime, Timestamp::TimeDiff diff); /// Creates a DateTime from an UtcTimeVal and a TimeDiff. /// /// Mainly used internally by DateTime and friends. DateTime(const DateTime & dateTime); /// Copy constructor. Creates the DateTime from another one. ~DateTime(); /// Destroys the DateTime. DateTime & operator=(const DateTime & dateTime); /// Assigns another DateTime. DateTime & operator=(const Timestamp & timestamp); /// Assigns a Timestamp. DateTime & operator=(double julianDay); /// Assigns a Julian day. DateTime & assign(int year, int month, int day, int hour = 0, int minute = 0, int second = 0, int millisecond = 0, int microseconds = 0); /// Assigns a Gregorian date and time. /// * year is from 0 to 9999. /// * month is from 1 to 12. /// * day is from 1 to 31. /// * hour is from 0 to 23. /// * minute is from 0 to 59. /// * second is from 0 to 60 (allowing leap seconds). /// * millisecond is from 0 to 999. /// * microsecond is from 0 to 999. void swap(DateTime & dateTime); /// Swaps the DateTime with another one. int year() const; /// Returns the year. int month() const; /// Returns the month (1 to 12). int week(int firstDayOfWeek = MONDAY) const; /// Returns the week number within the year. /// FirstDayOfWeek should be either SUNDAY (0) or MONDAY (1). /// The returned week number will be from 0 to 53. Week number 1 is the week /// containing January 4. This is in accordance to ISO 8601. /// /// The following example assumes that firstDayOfWeek is MONDAY. For 2005, which started /// on a Saturday, week 1 will be the week starting on Monday, January 3. /// January 1 and 2 will fall within week 0 (or the last week of the previous year). /// /// For 2007, which starts on a Monday, week 1 will be the week startung on Monday, January 1. /// There will be no week 0 in 2007. int day() const; /// Returns the day within the month (1 to 31). int dayOfWeek() const; /// Returns the weekday (0 to 6, where /// 0 = Sunday, 1 = Monday, ..., 6 = Saturday). int dayOfYear() const; /// Returns the number of the day in the year. /// January 1 is 1, February 1 is 32, etc. int hour() const; /// Returns the hour (0 to 23). int hourAMPM() const; /// Returns the hour (0 to 12). bool isAM() const; /// Returns true if hour < 12; bool isPM() const; /// Returns true if hour >= 12. int minute() const; /// Returns the minute (0 to 59). int second() const; /// Returns the second (0 to 59). int millisecond() const; /// Returns the millisecond (0 to 999) int microsecond() const; /// Returns the microsecond (0 to 999) double julianDay() const; /// Returns the julian day for the date and time. Timestamp timestamp() const; /// Returns the date and time expressed as a Timestamp. Timestamp::UtcTimeVal utcTime() const; /// Returns the date and time expressed in UTC-based /// time. UTC base time is midnight, October 15, 1582. /// Resolution is 100 nanoseconds. bool operator==(const DateTime & dateTime) const; bool operator!=(const DateTime & dateTime) const; bool operator<(const DateTime & dateTime) const; bool operator<=(const DateTime & dateTime) const; bool operator>(const DateTime & dateTime) const; bool operator>=(const DateTime & dateTime) const; DateTime operator+(const Timespan & span) const; DateTime operator-(const Timespan & span) const; Timespan operator-(const DateTime & dateTime) const; DateTime & operator+=(const Timespan & span); DateTime & operator-=(const Timespan & span); void makeUTC(int tzd); /// Converts a local time into UTC, by applying the given time zone differential. void makeLocal(int tzd); /// Converts a UTC time into a local time, by applying the given time zone differential. static bool isLeapYear(int year); /// Returns true if the given year is a leap year; /// false otherwise. static int daysOfMonth(int year, int month); /// Returns the number of days in the given month /// and year. Month is from 1 to 12. static bool isValid(int year, int month, int day, int hour = 0, int minute = 0, int second = 0, int millisecond = 0, int microsecond = 0); /// Checks if the given date and time is valid /// (all arguments are within a proper range). /// /// Returns true if all arguments are valid, false otherwise. protected: static double toJulianDay(Timestamp::UtcTimeVal utcTime); /// Computes the Julian day for an UTC time. static double toJulianDay(int year, int month, int day, int hour = 0, int minute = 0, int second = 0, int millisecond = 0, int microsecond = 0); /// Computes the Julian day for a gregorian calendar date and time. /// See , section 2.3.1 for the algorithm. static Timestamp::UtcTimeVal toUtcTime(double julianDay); /// Computes the UTC time for a Julian day. void computeGregorian(double julianDay); /// Computes the Gregorian date for the given Julian day. /// See , section 3.3.1 for the algorithm. void computeDaytime(); /// Extracts the daytime (hours, minutes, seconds, etc.) from the stored utcTime. private: void checkLimit(short & lower, short & higher, short limit); void normalize(); ///utility functions used to correct the overflow in computeGregorian Timestamp::UtcTimeVal _utcTime; short _year; short _month; short _day; short _hour; short _minute; short _second; short _millisecond; short _microsecond; }; // // inlines // inline Timestamp DateTime::timestamp() const { return Timestamp::fromUtcTime(_utcTime); } inline Timestamp::UtcTimeVal DateTime::utcTime() const { return _utcTime; } inline int DateTime::year() const { return _year; } inline int DateTime::month() const { return _month; } inline int DateTime::day() const { return _day; } inline int DateTime::hour() const { return _hour; } inline int DateTime::hourAMPM() const { if (_hour < 1) return 12; else if (_hour > 12) return _hour - 12; else return _hour; } inline bool DateTime::isAM() const { return _hour < 12; } inline bool DateTime::isPM() const { return _hour >= 12; } inline int DateTime::minute() const { return _minute; } inline int DateTime::second() const { return _second; } inline int DateTime::millisecond() const { return _millisecond; } inline int DateTime::microsecond() const { return _microsecond; } inline bool DateTime::operator==(const DateTime & dateTime) const { return _utcTime == dateTime._utcTime; } inline bool DateTime::operator!=(const DateTime & dateTime) const { return _utcTime != dateTime._utcTime; } inline bool DateTime::operator<(const DateTime & dateTime) const { return _utcTime < dateTime._utcTime; } inline bool DateTime::operator<=(const DateTime & dateTime) const { return _utcTime <= dateTime._utcTime; } inline bool DateTime::operator>(const DateTime & dateTime) const { return _utcTime > dateTime._utcTime; } inline bool DateTime::operator>=(const DateTime & dateTime) const { return _utcTime >= dateTime._utcTime; } inline bool DateTime::isLeapYear(int year) { return (year % 4) == 0 && ((year % 100) != 0 || (year % 400) == 0); } inline void swap(DateTime & d1, DateTime & d2) { d1.swap(d2); } } // namespace Poco #endif // Foundation_DateTime_INCLUDED