A time zone represents an offset applied to Greenwich Mean Time (GMT) to obtain local time. The offset might vary throughout the year, if daylight savings time (DST) is used, or might be the same all year long. Typically, regions closer to the equator do not use DST. If DST is in use, then specific rules define the point at which the offset changes and the amount by which it changes. Thus, a time zone is described by the following information:
An identifying string, or ID. This consists only of invariant characters (see the file utypes.h). It typically has the format continent / city. The city chosen is not the only city in which the zone applies, but rather a representative city for the region. Some IDs consist of three or four uppercase letters; these are legacy zone names that are aliases to standard zone names.
An offset from GMT, either positive or negative. Offsets range from approximately minus half a day to plus half a day.
If DST is observed, then three additional pieces of information are needed:
The precise date and time during the year when DST begins. In the first half of the year it‘s in the northern hemisphere, and in the second half of the year it’s in the southern hemisphere.
The precise date and time during the year when DST ends. In the first half of the year it‘s in the southern hemisphere, and in the second half of the year it’s in the northern hemisphere.
The amount by which the GMT offset changes when DST is in effect. This is almost always one hour.
ICU supports local time zones through the classes TimeZone and SimpleTimeZone in the C++ API. In the C API, time zones are designated by their ID strings.
Users can construct their own time zone objects by specifying the above information to the C++ API. However, it is more typical for users to use a pre-existing system time zone since these represent all current international time zones in use. This document lists the system time zones, both in order of GMT offset and in alphabetical order of ID.
Since this list changes one or more times a year, this document only represents a snapshot. For the most current list of ICU system zones, use the method TimeZone::getAvailableIDs().
The zones are listed in binary sort order (that is, ‘A’ through ‘Z’ come before ‘a’ through ‘z’). This is the same order in which the zones are stored internally, and the same order in which they are returned by TimeZone::getAvailableIDs(). The reason for this is that ICU locates zones using a binary search, and the binary search relies on this sort order. You might notice that zones such as Etc/GMT+1 appear to have the wrong sign for their GMT offset. In fact, their sign is inverted since the the Etc zones follow the POSIX sign conventions. This is the way the original Olson data is set up, and ICU reproduces the Olson data faithfully. See the Olson files for more details.
The ICU system time zones are derived from the tz database (also known as the “Olson” database) at ftp://elsie.nci.nih.gov/pub . This is the data used across much of the industry, including by UNIX systems, and is usually updated several times each year. ICU (since version 2.8) and base Java (since Java 1.4) contain code and tz data supporting both current and historic time zone usage.
ICU represents dates and times using UDates. A UDate is a scalar value that indicates a specific point in time, independent of calendar system and local time zone. It is stored as the number of milliseconds from a reference point known as the epoch. The epoch is midnight Universal Time Coordinated (UTC) January 1, 1970 A.D. Negative UDate values indicate times before the epoch.
These classes have the same architecture as the Java classes.
Most people only need to use the DateFormat classes for parsing and formatting dates and times. However, for those who need to convert dates and times or perform numeric calculations, the services described in this section can be very useful.
To translate a UDate to a useful form, a calendar system and local time zone must be specified. These are specified in the form of objects of the Calendar and TimeZone classes. Once these two objects are specified, they can be used to convert the UDate to and from its corresponding calendar fields. The different fields are defined in the Calendar class and include the year, month, day, hour, minute, second, and so on.
Specific Calendar objects correspond to calendar systems (such as Gregorian) and conventions (such as the first day of the week) in use in different parts of the world. To obtain a Calendar object for France, for example, call Calendar::createInstance(Locale::getFrance(), status).
The TimeZone class defines the conversion between universal coordinated time (UTC),, and local time, according to real-world rules. Different TimeZone objects correspond to different real-world time zones. For example, call TimeZone::createTimeZone(“America/Los_Angeles”) to obtain an object that implements the U.S. Pacific time zone, both Pacific Standard Time (PST) and Pacific Daylight Time (PDT).
As previously mentioned, the Calendar and TimeZone objects must be specified correctly together. One way of doing so is to create each independently, then use the Calendar::setTimeZone() method to associate the time zone with the calendar. Another is to use the Calendar::createInstance() method that takes a TimeZone object. For example, call Calendar::createInstance( TimeZone::createInstance( “America/Los_Angeles”), Locale:getUS(), status) to obtain a Calendar appropriate for use in the U.S. Pacific time zone.
ICU has four classes pertaining to calendars and timezones:
Calendar Calendar is an abstract base class that represents a calendar system. Calendar objects map UDate values to and from the individual fields used in a particular calendar system. Calendar also performs field computations such as advancing a date by two months.
Gregorian Calendar (§) GregorianCalendar is a concrete subclass of Calendar that implements the rules of the Julian calendar and the Gregorian calendar, which is the common calendar in use internationally today.
TimeZone TimeZone is an abstract base class that represents a time zone. TimeZone objects map between universal coordinated time (UTC) and local time.
SimpleTimeZone (§) SimpleTimeZone is a concrete subclass of TimeZone that implements standard time and daylight savings time according to real-world rules. Individual SimpleTimeZone objects correspond to real-world time zones.