tz
code and datatz
database
The tz
database attempts to record the history and predicted future of
civil time scales.
It organizes time zone and daylight saving time
data by partitioning the world into timezones
whose clocks all agree about timestamps that occur after the POSIX Epoch
(1970-01-01 00:00:00 UTC).
Although 1970 is a somewhat-arbitrary cutoff, there are significant
challenges to moving the cutoff earlier even by a decade or two, due
to the wide variety of local practices before computer timekeeping
became prevalent.
Most timezones correspond to a notable location and the database
records all known clock transitions for that location;
some timezones correspond instead to a fixed UTC offset.
Each timezone typically corresponds to a geographical region that is
smaller than a traditional time zone, because clocks in a timezone
all agree after 1970 whereas a traditional time zone merely
specifies current standard time. For example, applications that deal
with current and future timestamps in the traditional North
American mountain time zone can choose from the timezones
America/Denver
which observes US-style daylight saving
time (DST),
and America/Phoenix
which does not observe DST.
Applications that also deal with past timestamps in the mountain time
zone can choose from over a dozen timezones, such as
America/Boise
, America/Edmonton
, and
America/Hermosillo
, each of which currently uses mountain
time but differs from other timezones for some timestamps after 1970.
Clock transitions before 1970 are recorded for location-based timezones,
because most systems support timestamps before 1970 and could
misbehave if data entries were omitted for pre-1970 transitions.
However, the database is not designed for and does not suffice for
applications requiring accurate handling of all past times everywhere,
as it would take far too much effort and guesswork to record all
details of pre-1970 civil timekeeping.
Although some information outside the scope of the database is
collected in a file backzone
that is distributed along
with the database proper, this file is less reliable and does not
necessarily follow database guidelines.
As described below, reference source code for using the
tz
database is also available.
The tz
code is upwards compatible with POSIX, an international
standard for UNIX-like systems.
As of this writing, the current edition of POSIX is POSIX.1-2024,
which has been published but not yet in HTML form.
Unlike its predecessor POSIX.1-2017 ( The Open
Group Base Specifications Issue 7, IEEE Std 1003.1-2017, 2018
Edition), POSIX.1-2024 requires support for the
tz
database, which has a
model for describing civil time that is more complex than the
standard and daylight saving times required by POSIX.1-2017.
A tz
timezone corresponds to a ruleset that can
have more than two changes per year, these changes need not merely
flip back and forth between two alternatives, and the rules themselves
can change at times.
Whether and when a timezone changes its clock,
and even the timezone's notional base offset from UTC,
are variable.
It does not always make sense to talk about a timezone's
"base offset", which is not necessarily a single number.
Each timezone has a name that uniquely identifies the timezone.
Inexperienced users are not expected to select these names unaided.
Distributors should provide documentation and/or a simple selection
interface that explains each name via a map or via descriptive text like
"Czech Republic" instead of the timezone name "Europe/Prague
".
If geolocation information is available, a selection interface can
locate the user on a timezone map or prioritize names that are
geographically close. For an example selection interface, see the
tzselect
program in the tz
code.
The Unicode Common Locale Data
Repository contains data that may be useful for other selection
interfaces; it maps timezone names like Europe/Prague
to
locale-dependent strings like "Prague", "Praha", "Прага", and "布拉格".
The naming conventions attempt to strike a balance among the following goals:
Names normally have the format
AREA/
LOCATION, where
AREA is a continent or ocean, and
LOCATION is a specific location within the area.
North and South America share the same area, 'America
'.
Typical names are 'Africa/Cairo
',
'America/New_York
', and 'Pacific/Honolulu
'.
Some names are further qualified to help avoid confusion; for example,
'America/Indiana/Petersburg
' distinguishes Petersburg,
Indiana from other Petersburgs in America.
Here are the general guidelines used for choosing timezone names, in decreasing order of importance:
/
').
Do not use the file name components '.
' and
'..
'.
Within a file name component, use only ASCII letters,
'.
', '-
' and '_
'.
Do not use digits, as that might create an ambiguity with POSIX's proleptic
TZ
strings.
A file name component must not exceed 14 characters or start with
'-
'.
E.g., prefer America/Noronha
to
America/Fernando_de_Noronha
.
Exceptions: see the discussion of legacy names below.
//
', or
start or end with '/
'.
/
', as a regular file cannot have the
same name as a directory in POSIX.
For example, America/New_York
precludes
America/New_York/Bronx
.
America/Costa_Rica
to
America/San_Jose
and America/Guyana
to America/Georgetown
.
Europe/Paris
to Europe/France
,
since
France
has had multiple time zones.
Europe/Rome
to Europa/Roma
, and
prefer Europe/Athens
to the Greek
Ευρώπη/Αθήνα
or the Romanized
Evrópi/Athína
.
The POSIX file name restrictions encourage this guideline.
Asia/Shanghai
to
Asia/Beijing
.
Among locations with similar populations, pick the best-known
location, e.g., prefer Europe/Rome
to
Europe/Milan
.
Atlantic/Canary
to
Atlantic/Canaries
.
_Islands
' and
'_City
', unless that would lead to ambiguity.
E.g., prefer America/Cayman
to
America/Cayman_Islands
and
America/Guatemala
to
America/Guatemala_City
, but prefer
America/Mexico_City
to
America/Mexico
because the
country of Mexico has several time zones.
_
' to represent a space.
.
' from abbreviations in names.
E.g., prefer Atlantic/St_Helena
to
Atlantic/St._Helena
.
Europe/Rome
to
Europe/Milan
merely because Milan's population has grown
to be somewhat greater than Rome's.
backward
' file as a link to the new spelling.
This means old spellings will continue to work.
Ordinarily a name change should occur only in the rare case when
a location's consensus English-language spelling changes; for example,
in 2008 Asia/Calcutta
was renamed to Asia/Kolkata
due to long-time widespread use of the new city name instead of the old.
Guidelines have evolved with time, and names following old versions of these guidelines might not follow the current version. When guidelines have changed, old names continue to be supported. Guideline changes have included the following:
backward
' for most of these older names
(e.g., 'US/Eastern
' instead of 'America/New_York
').
The other old-fashioned names still supported are
'WET
', 'CET
', 'MET
', and
'EET
' (see the file 'europe
').
etcetera
'.
Also, the file 'backward
' defines the legacy names
'Etc/GMT0
', 'Etc/GMT-0
', 'Etc/GMT+0
',
'GMT0
', 'GMT-0
' and 'GMT+0
',
and the file 'northamerica
' defines the legacy names
'EST5EDT
', 'CST6CDT
',
'MST7MDT
', and 'PST8PDT
'.
The file zone1970.tab
lists geographical locations used
to name timezones.
It is intended to be an exhaustive list of names for geographic
regions as described above; this is a subset of the timezones in the data.
Although a zone1970.tab
location's
longitude
corresponds to
its local mean
time (LMT) offset with one hour for every 15°
east longitude, this relationship is not exact.
The backward-compatibility file zone.tab
is similar
but conforms to the older-version guidelines related to ISO 3166-1;
it lists only one country code per entry and unlike zone1970.tab
it can list names defined in backward
.
Applications that process only timestamps from now on can instead use the file
zonenow.tab
, which partitions the world more coarsely,
into regions where clocks agree now and in the predicted future;
this file is smaller and simpler than zone1970.tab
and zone.tab
.
The database defines each timezone name to be a zone, or a link to a zone.
The source file backward
defines links for backward
compatibility; it does not define zones.
Although backward
was originally designed to be optional,
nowadays distributions typically use it
and no great weight should be attached to whether a link
is defined in backward
or in some other file.
The source file etcetera
defines names that may be useful
on platforms that do not support proleptic TZ
strings
like <+08>-8
;
no other source file other than backward
contains links to its zones.
One of etcetera
's names is Etc/UTC
,
used by functions like gmtime
to obtain leap
second information on platforms that support leap seconds.
Another etcetera
name, GMT
,
is used by older code releases.
When this package is installed, it generates time zone abbreviations
like 'EST
' to be compatible with human tradition and POSIX.
Here are the general guidelines used for choosing time zone abbreviations,
in decreasing order of importance:
+
' or '-
'.
Previous editions of this database also used characters like
space and '?
', but these characters have a
special meaning to the
UNIX shell
and cause commands like
'set
`date`
'
to have unexpected effects.
Previous editions of this guideline required upper-case letters, but the
Congressman who introduced
Chamorro
Standard Time preferred "ChST", so lower-case letters are now
allowed.
Also, POSIX from 2001 on relaxed the rule to allow '-
',
'+
', and alphanumeric characters from the portable
character set in the current locale.
In practice ASCII alphanumerics and '+
' and
'-
' are safe in all locales.
In other words, in the C locale the POSIX extended regular
expression [-+[:alnum:]]{3,6}
should match the
abbreviation.
This guarantees that all abbreviations could have been specified
explicitly by a POSIX proleptic TZ
string.
These abbreviations (for standard/daylight/etc. time) are: ACST/ACDT Australian Central, AST/ADT/APT/AWT/ADDT Atlantic, AEST/AEDT Australian Eastern, AHST/AHDT Alaska-Hawaii, AKST/AKDT Alaska, AWST/AWDT Australian Western, BST/BDT Bering, CAT/CAST Central Africa, CET/CEST/CEMT Central European, ChST Chamorro, CST/CDT/CWT/CPT Central [North America], CST/CDT China, GMT/BST/IST/BDST Greenwich, EAT East Africa, EST/EDT/EWT/EPT Eastern [North America], EET/EEST Eastern European, GST/GDT Guam, HST/HDT/HWT/HPT Hawaii, HKT/HKST/HKWT Hong Kong, IST India, IST/GMT Irish, IST/IDT/IDDT Israel, JST/JDT Japan, KST/KDT Korea, MET/MEST Middle European (a backward-compatibility alias for Central European), MSK/MSD Moscow, MST/MDT/MWT/MPT Mountain, NST/NDT/NWT/NPT/NDDT Newfoundland, NST/NDT/NWT/NPT Nome, NZMT/NZST New Zealand through 1945, NZST/NZDT New Zealand 1946–present, PKT/PKST Pakistan, PST/PDT/PWT/PPT Pacific, PST/PDT Philippine, SAST South Africa, SST Samoa, UTC Universal, WAT/WAST West Africa, WET/WEST/WEMT Western European, WIB Waktu Indonesia Barat, WIT Waktu Indonesia Timur, WITA Waktu Indonesia Tengah, YST/YDT/YWT/YPT/YDDT Yukon.
For times taken from a city's longitude, use the
traditional xMT notation.
The only abbreviation like this in current use is 'GMT'.
The others are for timestamps before 1960,
except that Monrovia Mean Time persisted until 1972.
Typically, numeric abbreviations (e.g., '-
004430' for
MMT) would cause trouble here, as the numeric strings would exceed
the POSIX length limit.
These abbreviations are: AMT Asunción, Athens; BMT Baghdad, Bangkok, Batavia, Bermuda, Bern, Bogotá, Brussels, Bucharest; CMT Calamarca, Caracas, Chisinau, Colón, Córdoba; DMT Dublin/Dunsink; EMT Easter; FFMT Fort-de-France; FMT Funchal; GMT Greenwich; HMT Havana, Helsinki, Horta, Howrah; IMT Irkutsk, Istanbul; JMT Jerusalem; KMT Kaunas, Kyiv, Kingston; LMT Lima, Lisbon, local; MMT Macassar, Madras, Malé, Managua, Minsk, Monrovia, Montevideo, Moratuwa, Moscow; PLMT Phù Liễn; PMT Paramaribo, Paris, Perm, Pontianak, Prague; PMMT Port Moresby; PPMT Port-au-Prince; QMT Quito; RMT Rangoon, Riga, Rome; SDMT Santo Domingo; SJMT San José; SMT Santiago, Simferopol, Singapore, Stanley; TBMT Tbilisi; TMT Tallinn, Tehran; WMT Warsaw.
A few abbreviations also follow the pattern that GMT/BST established for time in the UK. They are: BMT/BST for Bermuda 1890–1930, CMT/BST for Calamarca Mean Time and Bolivian Summer Time 1890–1932, DMT/IST for Dublin/Dunsink Mean Time and Irish Summer Time 1880–1916, MMT/MST/MDST for Moscow 1880–1919, and RMT/LST for Riga Mean Time and Latvian Summer time 1880–1926.
tz
database".
-
05 and +
0530 that are generated
by zic
's %z
notation.
-
00') for
locations while uninhabited.
The leading '-
' is a flag that the UT offset is in
some sense undefined; this notation is derived
from Internet
RFC 3339.
(The abbreviation 'Z' that
Internet
RFC 9557 uses for this concept
would violate the POSIX requirement
of at least three characters in an abbreviation.)
Application writers should note that these abbreviations are ambiguous
in practice: e.g., 'CST' means one thing in China and something else
in North America, and 'IST' can refer to time in India, Ireland or
Israel.
To avoid ambiguity, use numeric UT offsets like
'-
0600' instead of time zone abbreviations like 'CST'.
tz
database
The tz
database is not authoritative, and it
surely has errors.
Corrections are welcome and encouraged; see the file CONTRIBUTING
.
Users requiring authoritative data should consult national standards
bodies and the references cited in the database's comments.
Errors in the tz
database arise from many sources:
tz
database predicts future
timestamps, and current predictions
will be incorrect after future governments change the rules.
For example, if today someone schedules a meeting for 13:00 next
October 1, Casablanca time, and tomorrow Morocco changes its
daylight saving rules, software can mess up after the rule change
if it blithely relies on conversions made before the change.
tz
database's scope were extended to
cover even just the known or guessed history of standard time; for
example, the current single entry for France would need to split
into dozens of entries, perhaps hundreds.
And in most of the world even this approach would be misleading
due to widespread disagreement or indifference about what times
should be observed.
In her 2015 book
The
Global Transformation of Time, 1870–1950,
Vanessa Ogle writes
"Outside of Europe and North America there was no system of time
zones at all, often not even a stable landscape of mean times,
prior to the middle decades of the twentieth century".
See: Timothy Shenk, Booked:
A Global History of Time. Dissent 2015-12-17.
tz
database relies on
years of first-class work done by
Joseph Myers and others; see
"History of
legal time in Britain".
Other countries are not done nearly as well.
tz
database stands for the containing region, its pre-1970 data
entries are often accurate for only a small subset of that region.
For example, Europe/London
stands for the United
Kingdom, but its pre-1847 times are valid only for locations that
have London's exact meridian, and its 1847 transition
to GMT is known to be valid only for the L&NW and
the Caledonian railways.
tz
database does not record the
earliest time for which a timezone's
data entries are thereafter valid for every location in the region.
For example, Europe/London
is valid for all locations
in its region after GMT was made the standard time,
but the date of standardization (1880-08-02) is not in the
tz
database, other than in commentary.
For many timezones the earliest time of
validity is unknown.
tz
database does not record a
region's boundaries, and in many cases the boundaries are not known.
For example, the timezone
America/Kentucky/Louisville
represents a region
around the city of Louisville, the boundaries of which are
unclear.
tz
database were often spread out over hours, days, or even decades.
tz
database requires.
tz
database cannot represent stopped clocks.
However, on 1911-03-11 at 00:00, some public-facing French clocks
were changed by stopping them for a few minutes to effect a transition.
The tz
database models this via a
backward transition; the relevant French legislation does not
specify exactly how the transition was to occur.
tz
code can handle.
For example, from 1880 to 1916 clocks in Ireland observed Dublin Mean
Time (estimated to be UT
−00:25:21.1); although the tz
source data can represent the .1 second, TZif files and the code cannot.
In practice these old specifications were rarely if ever
implemented to subsecond precision.
tz
database are correct, the
tz
rules that generate them may not
faithfully reflect the historical rules.
For example, from 1922 until World War II the UK moved clocks
forward the day following the third Saturday in April unless that
was Easter, in which case it moved clocks forward the previous
Sunday.
Because the tz
database has no
way to specify Easter, these exceptional years are entered as
separate tz Rule
lines, even though the
legal rules did not change.
When transitions are known but the historical rules behind them are not,
the database contains Zone
and Rule
entries that are intended to represent only the generated
transitions, not any underlying historical rules; however, this
intent is recorded at best only in commentary.
tz
database models time
using the proleptic
Gregorian calendar with days containing 24 equal-length hours
numbered 00 through 23, except when clock transitions occur.
Pre-standard time is modeled as local mean time.
However, historically many people used other calendars and other timescales.
For example, the Roman Empire used
the Julian
calendar,
and Roman
timekeeping had twelve varying-length daytime hours with a
non-hour-based system at night.
And even today, some local practices diverge from the Gregorian
calendar with 24-hour days. These divergences range from
relatively minor, such as Japanese bars giving times like "24:30" for the
wee hours of the morning, to more-significant differences such as the
east African practice of starting the day at dawn, renumbering
the Western 06:00 to be 12:00. These practices are largely outside
the scope of the tz
code and data, which
provide only limited support for date and time localization
such as that required by POSIX.
If DST is not used a different time zone
can often do the trick; for example, in Kenya a TZ
setting
like <-03>3
or America/Cayenne
starts
the day six hours later than Africa/Nairobi
does.
tz
database assumes Universal Time
(UT) as an origin, even though UT is not
standardized for older timestamps.
In the tz
database commentary,
UT denotes a family of time standards that includes
Coordinated Universal Time (UTC) along with other
variants such as UT1 and GMT,
with days starting at midnight.
Although UT equals UTC for modern
timestamps, UTC was not defined until 1960, so
commentary uses the more general abbreviation UT for
timestamps that might predate 1960.
Since UT, UT1, etc. disagree slightly,
and since pre-1972 UTC seconds varied in length,
interpretation of older timestamps can be problematic when
subsecond accuracy is needed.
tz
database does not represent how
uncertain its information is.
Ideally it would contain information about when data entries are
incomplete or dicey.
Partial temporal knowledge is a field of active research, though,
and it is not clear how to apply it here.
In short, many, perhaps most, of the tz
database's pre-1970 and future timestamps are either wrong or
misleading.
Any attempt to pass the
tz
database off as the definition of time
should be unacceptable to anybody who cares about the facts.
In particular, the tz
database's
LMT offsets should not be considered meaningful, and
should not prompt creation of timezones
merely because two locations
differ in LMT or transitioned to standard time at
different dates.
The tz
code contains time and date functions
that are upwards compatible with those of POSIX.
Code compatible with this package is already
part of many platforms, where the
primary use of this package is to update obsolete time-related files.
To do this, you may need to compile the time zone compiler
zic
supplied with this package instead of using the
system zic
, since the format of zic
's
input is occasionally extended, and a platform may still be shipping
an older zic
.
In POSIX, time display in a process is controlled by the
environment variable TZ
, which can have two forms:
TZ
value
like CET-1CEST,M3.5.0,M10.5.0/3
uses a complex
notation that specifies a single standard time along with daylight
saving rules that apply to all years past, present, and future.
TZ
value
like Europe/Berlin
names a location that stands for
civil time near that location, which can have more than
one standard time and more than one set of daylight saving rules,
to record timekeeping practice more accurately.
These names are defined by the tz
database.
Some platforms support only the features required by POSIX.1-2017, and have not yet upgraded to POSIX.1-2024. Code intended to be portable to these platforms must deal with problems that were fixed in later POSIX editions.
TZ
,
and there is no convenient and efficient way to determine
the UT offset and time zone abbreviation of arbitrary
timestamps, particularly for timezones
that do not fit into the POSIX model.
The proleptic TZ
string,
which is all that POSIX.1-2017 requires,
has a format that is hard to describe and is error-prone in practice.
Also, proleptic TZ
strings cannot deal with daylight
saving time rules not based on the Gregorian calendar (as in
Morocco), or with situations where more than two time zone
abbreviations or UT offsets are used in an area.
A proleptic TZ
string has the following format:
stdoffset[dst[offset][,
date[/
time],
date[/
time]]]
where:
<+09>
';
this allows "+
" and "-
" in the names.
[±]hh:[mm[:ss]]
'
and specifies the offset west of UT.
'hh' may be a single digit;
0≤hh≤24.
The default DST offset is one hour ahead of
standard time.
/
time],
date[/
time]:
[mm[:
ss]]'
and defaults to 02:00.
This is the same format as the offset, except that a
leading '+
' or '-
' is not allowed.
M
m.
n.
d
(0[Sunday]≤d≤6[Saturday], 1≤n≤5,
1≤m≤12)5
' stands for the last week in which
day d appears (which may be either the 4th or
5th week).
Typically, this is the only useful form; the n
and J
n forms are rarely used.
Here is an example proleptic TZ
string for New
Zealand after 2007.
It says that standard time (NZST) is 12 hours ahead
of UT, and that daylight saving time
(NZDT) is observed from September's last Sunday at
02:00 until April's first Sunday at 03:00:
TZ='NZST-12NZDT,M9.5.0,M4.1.0/3'
This proleptic TZ
string is hard to remember, and
mishandles some timestamps before 2008.
With this package you can use a geographical TZ
instead:
TZ='Pacific/Auckland'
POSIX.1-2017 also has the limitations of POSIX.1-2024, discussed in the next section.
POSIX.1-2024 extends POSIX.1-2017 in the following significant ways:
TZ
.
Earlier POSIX editions require support only for proleptic TZ
.
struct tm
to have a UT offset member tm_gmtoff
and a time zone abbreviation member tm_zone
.
Earlier POSIX editions lack this requirement.
"<-02>2<-01>,M3.5.0/-1,M10.5.0/0"
where the transition time −1:00 means 23:00 the previous day.
However POSIX.1-2024, like earlier POSIX editions, has some limitations:
TZ
environment variable is process-global, which
makes it hard to write efficient, thread-safe applications that
need access to multiple timezones.
TZ
environment variable.
While an administrator can "do everything in UT" to
get around the problem, doing so is inconvenient and precludes
handling daylight saving time shifts – as might be required to
limit phone calls to off-peak hours.
time_t
clock counts exclude leap
seconds.
TZ
values like
"EST5EDT
".
Traditionally the current US DST rules
were used to interpret such values, but this meant that the
US DST rules were compiled into each
time conversion package, and when
US time conversion rules changed (as in the United
States in 1987 and again in 2007), all packages that
interpreted TZ
values had to be updated
to ensure proper results.
tz
code
The tz
code defines some properties
left unspecified by POSIX, and attempts to support some
extensions to POSIX.
tz
code attempts to support all the
time_t
implementations allowed by POSIX.
The time_t
type represents a nonnegative count of seconds
since 1970-01-01 00:00:00 UTC, ignoring leap seconds.
In practice, time_t
is usually a signed 64- or 32-bit
integer; 32-bit signed time_t
values stop working after
2038-01-19 03:14:07 UTC, so new implementations these
days typically use a signed 64-bit integer.
Unsigned 32-bit integers are used on one or two platforms, and 36-bit
and 40-bit integers are also used occasionally.
Although earlier POSIX versions allowed time_t
to be a
floating-point type, this was not supported by any practical system,
and POSIX.1-2013+ and the tz
code both
require time_t
to be an integer type.
If the TZ
environment variable uses the geographical format,
it is used in generating
the name of a file from which time-related information is read.
The file's format is TZif,
a timezone information format that contains binary data; see
Internet
RFC 8536.
The daylight saving time rules to be used for a
particular timezone are encoded in the
TZif file; the format of the file allows US,
Australian, and other rules to be encoded, and
allows for situations where more than two time zone
abbreviations are used.
When the tz
code was developed in the 1980s,
it was recognized that allowing the TZ
environment
variable to take on values such as 'America/New_York
'
might cause "old" programs (that expect TZ
to have a
certain format) to operate incorrectly; consideration was given to using
some other environment variable (for example, TIMEZONE
)
to hold the string used to generate the TZif file's name.
In the end, however, it was decided to continue using
TZ
: it is widely used for time zone purposes;
separately maintaining both TZ
and TIMEZONE
seemed a nuisance; and systems where
"new" forms of TZ
might cause problems can simply
use legacy TZ
values such as "EST5EDT
" which
can be used by "new" programs as well as by "old" programs that
assume pre-POSIX TZ
values.
tzalloc
, tzfree
,
localtime_rz
, and mktime_z
for
more-efficient thread-safe applications that need to use multiple
timezones.
The tzalloc
and tzfree
functions
allocate and free objects of type timezone_t
,
and localtime_rz
and mktime_z
are
like localtime_r
and mktime
with an
extra timezone_t
argument.
The functions were inspired by NetBSD.
time_t
values are supported, on systems
where time_t
is signed.
POSIX and ISO C
define some APIs that are vestigial:
they are not needed, and are relics of a too-simple model that does
not suffice to handle many real-world timestamps.
Although the tz
code supports these
vestigial APIs for backwards compatibility, they should
be avoided in portable applications.
The vestigial APIs are:
tzname
variable does not suffice and is no
longer needed.
It is planned to be removed in a future edition of POSIX.
To get a timestamp's time zone abbreviation, consult
the tm_zone
member if available; otherwise,
use strftime
's "%Z"
conversion
specification.
daylight
and timezone
variables do not suffice and are no longer needed.
They are planned to be removed in a future edition of POSIX.
To get a timestamp's UT offset, consult
the tm_gmtoff
member if available; otherwise,
subtract values returned by localtime
and gmtime
using the rules of the Gregorian calendar,
or use strftime
's "%z"
conversion
specification if a string like "+0900"
suffices.
tm_isdst
member is almost never needed and most of
its uses should be discouraged in favor of the abovementioned
APIs.
Although it can still be used in arguments to
mktime
to disambiguate timestamps near
a DST transition when the clock jumps back on
platforms lacking tm_gmtoff
, this
disambiguation does not work when standard time itself jumps back,
which can occur when a location changes to a time zone with a
lesser UT offset.
timezone
function is not present in this
package; it is impossible to reliably map timezone
's
arguments (a "minutes west of GMT" value and a
"daylight saving time in effect" flag) to a time zone
abbreviation, and we refuse to guess.
Programs that in the past used the timezone
function
may now examine localtime(&clock)->tm_zone
(if TM_ZONE
is defined) or
tzname[localtime(&clock)->tm_isdst]
(if HAVE_TZNAME
is nonzero) to learn the correct time
zone abbreviation to use.
gettimeofday
function is not
used in this package.
This formerly let users obtain the current UTC offset
and DST flag, but this functionality was removed in
later versions of BSD.
time_t
values when doing conversions
for places that do not use UT.
This package takes care to do these conversions correctly.
A comment in the source code tells how to get compatibly wrong
results.
STD_INSPIRED
is nonzero should, at this point, be
looked on primarily as food for thought.
They are not in any sense "standard compatible" – some are
not, in fact, specified in any standard.
They do, however, represent responses of various authors to
standardization proposals.
The tz
code and data supply the following interfaces:
tzselect
, zdump
,
and zic
, documented in their man pages.
zic
input files, documented in
the zic
man page.
zic
output files, documented in
the tzfile
man page.
zone1970.tab
.
iso3166.tab
.
version
' in each release.
Interface changes in a release attempt to preserve compatibility with
recent releases.
For example, tz
data files typically do not
rely on recently added zic
features, so that users can
run older zic
versions to process newer data files.
Downloading
the tz
database describes how releases
are tagged and distributed.
Interfaces not listed above are less stable. For example, users should not rely on particular UT offsets or abbreviations for timestamps, as data entries are often based on guesswork and these guesses may be corrected or improved.
Timezone boundaries are not part of the stable interface. For example, even though the Asia/Bangkok timezone currently includes Chang Mai, Hanoi, and Phnom Penh, this is not part of the stable interface and the timezone can split at any time. If a calendar application records a future event in some location other than Bangkok by putting "Asia/Bangkok" in the event's record, the application should be robust in the presence of timezone splits between now and the future time.
Leap seconds were introduced in 1972 to accommodate the difference between atomic time and the less regular rotation of the earth. Unfortunately they have caused so many problems with civil timekeeping that there are plans to discontinue them by 2035. Even if these plans come to fruition, a record of leap seconds will still be needed to resolve timestamps from 1972 through 2035, and there may also be a need to record whatever mechanism replaces them.
The tz
code and data can account for leap seconds,
thanks to code contributed by Bradley White.
However, the leap second support of this package is rarely used directly
because POSIX requires leap seconds to be excluded and many
software packages would mishandle leap seconds if they were present.
Instead, leap seconds are more commonly handled by occasionally adjusting
the operating system kernel clock as described in
Precision timekeeping,
and this package by default installs a leapseconds file
commonly used by
NTP
software that adjusts the kernel clock.
However, kernel-clock twiddling approximates UTC only roughly,
and systems needing more precise UTC can use this package's leap
second support directly.
The directly supported mechanism assumes that time_t
counts of seconds since the POSIX epoch normally include leap seconds,
as opposed to POSIX time_t
counts which exclude leap seconds.
This modified timescale is converted to UTC
at the same point that time zone and DST
adjustments are applied –
namely, at calls to localtime
and analogous functions –
and the process is driven by leap second information
stored in alternate versions of the TZif files.
Because a leap second adjustment may be needed even
if no time zone correction is desired,
calls to gmtime
-like functions
also need to consult a TZif file,
conventionally named Etc/UTC
(GMT in previous versions),
to see whether leap second corrections are needed.
To convert an application's time_t
timestamps to or from
POSIX time_t
timestamps (for use when, say,
embedding or interpreting timestamps in portable
tar
files),
the application can call the utility functions
time2posix
and posix2time
included with this package.
If the POSIX-compatible TZif file set is installed
in a directory whose basename is zoneinfo, the
leap-second-aware file set is by default installed in a separate
directory zoneinfo-leaps.
Although each process can have its own time zone by setting
its TZ
environment variable, there is no support for some
processes being leap-second aware while other processes are
POSIX-compatible; the leap-second choice is system-wide.
So if you configure your kernel to count leap seconds, you should also
discard zoneinfo and rename zoneinfo-leaps
to zoneinfo.
Alternatively, you can install just one set of TZif files
in the first place; see the REDO
variable in this package's
makefile.
Calendrical issues are a bit out of scope for a time zone database,
but they indicate the sort of problems that we would run into if we
extended the time zone database further into the past.
An excellent resource in this area is Edward M. Reingold
and Nachum Dershowitz, Calendrical
Calculations: The Ultimate Edition, Cambridge University Press (2018).
Other information and sources are given in the file 'calendars
'
in the tz
distribution.
They sometimes disagree.
The European Space Agency is considering the establishment of a reference timescale for the Moon, which has days roughly equivalent to 29.5 Earth days, and where relativistic effects cause clocks to tick slightly faster than on Earth. Also, NASA has been ordered to consider the establishment of Coordinated Lunar Time (LTC). It is not yet known whether the US and European efforts will result in multiple timescales on the Moon.
Some people's work schedules have used Mars time. Jet Propulsion Laboratory (JPL) coordinators kept Mars time on and off during the Mars Pathfinder mission (1997). Some of their family members also adapted to Mars time. Dozens of special Mars watches were built for JPL workers who kept Mars time during the Mars Exploration Rovers (MER) mission (2004–2018). These timepieces looked like normal Seikos and Citizens but were adjusted to use Mars seconds rather than terrestrial seconds, although unfortunately the adjusted watches were unreliable and appear to have had only limited use.
A Mars solar day is called a "sol" and has a mean period equal to about 24 hours 39 minutes 35.244 seconds in terrestrial time. It is divided into a conventional 24-hour clock, so each Mars second equals about 1.02749125 terrestrial seconds. (One MER worker noted, "If I am working Mars hours, and Mars hours are 2.5% more than Earth hours, shouldn't I get an extra 2.5% pay raise?")
The prime meridian of Mars goes through the center of the crater Airy-0, named in honor of the British astronomer who built the Greenwich telescope that defines Earth's prime meridian. Mean solar time on the Mars prime meridian is called Mars Coordinated Time (MTC).
Each landed mission on Mars has adopted a different reference for solar timekeeping, so there is no real standard for Mars time zones. For example, the MER mission defined two time zones "Local Solar Time A" and "Local Solar Time B" for its two missions, each zone designed so that its time equals local true solar time at approximately the middle of the nominal mission. The A and B zones differ enough so that an MER worker assigned to the A zone might suffer "Mars lag" when switching to work in the B zone. Such a "time zone" is not particularly suited for any application other than the mission itself.
Many calendars have been proposed for Mars, but none have achieved wide acceptance. Astronomers often use Mars Sol Date (MSD) which is a sequential count of Mars solar days elapsed since about 1873-12-29 12:00 GMT.
In our solar system, Mars is the planet with time and calendar most like Earth's. On other planets, Sun-based time and calendars would work quite differently. For example, although Mercury's sidereal rotation period is 58.646 Earth days, Mercury revolves around the Sun so rapidly that an observer on Mercury's equator would see a sunrise only every 175.97 Earth days, i.e., a Mercury year is 0.5 of a Mercury day. Venus is more complicated, partly because its rotation is slightly retrograde: its year is 1.92 of its days. Gas giants like Jupiter are trickier still, as their polar and equatorial regions rotate at different rates, so that the length of a day depends on latitude. This effect is most pronounced on Neptune, where the day is about 12 hours at the poles and 18 hours at the equator.
Although the tz
database does not support
time on other planets, it is documented here in the hopes that support
will be added eventually.
Sources for time on other planets: