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I am hoping to make this question and the answers to it the definitive guide to dealing with daylight saving time, in particular for dealing with the actual change overs.

If you have anything to add, please do

Many systems are dependent on keeping accurate time, the problem is with changes to time due to daylight savings - moving the clock forward or backwards.

For instance, one has business rules in an order taking system that depend on the time of the order - if the clock changes, the rules might not be as clear. How should the time of the order be persisted? There is of course an endless number of scenarios - this one is simply an illustrative one.

  • How have you dealt with the daylight saving issue?
  • What assumptions are part of your solution? (looking for context here)

As important, if not more so:

  • What did you try that did not work?
  • Why did it not work?

I would be interested in programming, OS, data persistence and other pertinent aspects of the issue.

General answers are great, but I would also like to see details especially if they are only available on one platform.

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This is one of the best practical questions I've seen on SO. This is also a very painful issue. IMHO, If everyone plays along, sharing their experience with DST issues, this page could eventually turn into an invaluable resource. +1. –  M.A. Hanin Mar 28 '10 at 12:58
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"Set hardware clocks and OS clocks to UTC" Whoat? –  abatishchev May 31 '12 at 15:10
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@Oded: I can agree if "on server" will be added. But still that can affect another applications which need local time. By this and other reasons I think it's better to request Utc time explicitly. –  abatishchev Jun 1 '12 at 6:47
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UTC is preferred to GMT, both because it is more precisely defined and because GMT definitions are messed up on some operating systems. It's common for people to treat the terms "GMT" and "UTC" as interchangeable but they aren't entirely. For almost any software / systems purpose, use UTC. See stackoverflow.com/questions/2292334/… –  Chris Johnson Oct 1 '12 at 10:04
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@JoshStodola -- Jon Skeet's 'answer'. –  Kenny Evitt Mar 31 '13 at 2:36
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26 Answers


Summary of answers and other data: (please add yours)

Do:

  • Whenever you are referring to a particular moment in time, persist the time according to a unified standard that is not affected by daylight savings. GMT and UTC have been mentioned by different people, though UTC seems to be mentioned most often.
  • ?? Include the local time offset as is (including DST offset) when storing timestamps. ?? Store timestamps as UTC or epochs(number of seconds since 1970) without time zone or offset.
  • Include the original time zone name, so you can reconstruct the original time at a later point and display correct offsets if needed.
  • Remember that DST offsets are not always an integer number of hours (for example, Indian Standard Time is UTC+05:30).
  • If using Java, use Joda Time.
  • If using .NET, consider using Noda Time.
  • If using Perl, use DateTime.
  • If using Python, use pytz
  • If using PHP > 5.2, use the native time zones conversions provided by DateTime, and DateTimeZone classes. Be careful when using DateTimeZone::listAbbreviations(); see answer. To keep PHP with up to date Olson data install periodically this PECL package; see answer.
  • Create a table TZOffsets with three columns: RegionClassId, StartDateTime, and OffsetMinutes (int, in minutes). See answer
  • Business rules should always work on civil time (UTC/GMT).
  • Internally, keep timestamps in something like civil-time-seconds-from-epoch. See answer.
  • Only convert to local times at the last possible moment.
  • Remember that time zones and offsets are not fixed and may change. For instance, historically US and UK used the same dates to 'spring forward' and 'fall back'. However, in the mid 2000s the US changed the dates that the clocks get changed on. This now means that for 48 weeks of the year the difference between London time and New York time is 5 hours and for 4 weeks (3 in the spring, 1 in the autumn) it is 4 hours. Be aware of items like this in any calculations that involve multiple zones.
  • Consider the type of time (actual event time, broadcast time, relative time, historical time, recurring time) what elements (timestamp, time zone offset and time zone name) you need to store for correct retrieval - see "Types of Time" in answer.
  • Check if your DBMS needs to be shutdown during transition.
  • Keep your OS, database and application tzdata files in sync, between themselves and the rest of the world.
  • On Servers, set hardware clocks and OS clocks to UTC.
  • Use NTP services on all servers.
  • If doing historical auditing store both UTC and local time (this allows exact pinpointing of time, as conversion tables will change).
  • If using FAT32, remember that timestamps are stored in local time, not UTC.
  • When dealing with recurring events (weekly TV show, for example), remember that the time changes with DST and will be different across time zones.
  • Always query dates as lower-bound inclusive, upper-bound exclusive (>=, <).

Don't:

  • Do not use JavaScript date and time calculations in web applications unless you ABSOLUTELY have to.
  • Never trust client datetime. It may very well be incorrect.
  • Do not compare client datetimes with server datetimes.

Testing:

  • When testing make sure you test countries in the Western and Eastern hemispheres, with both DST in progress and not and a country that does not use DST (6 in total).
  • Test all third-party libraries and applications and make sure they handle time zone data correctly.

Reference:

Other:

  • Lobby your representative to end the abomination that is DST. We can always hope...
  • Lobby for EST

My Answer:

Always persist the time according to a unified standard, preferably UTC.

UTC is agnostic to daylight saving time and as such it is a good baseline. Once you have that, displaying the proper time according to time zone, DST, etc... is just a matter of applying the proper delta.

Persist globally, display locally. - Me, Now

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Using GMT doesn't really solve the problem, you still need to figure out what is the right delta to apply, and this is where all the complexity lies. The delta can be complex to determine in systems that are used by users in different regions (with different daylight saving switch schedules) or in systems showing historical/future data. –  ckarras Mar 28 '10 at 14:40
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That's true if all the application needs to do is to display the current local time. But if we have for example a server in Australia that needs to display the date/time for a transaction in Canada on April 2 2006 (This was the last year before the daylight saving switching rules changed in Canada) - do you have an OS call that can do DateTime("2006/04/02 14:35Z").ToLocalTime().WithDaylightSavingRules("Canada",2006) ? –  ckarras Mar 28 '10 at 15:00
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Yes, there is such an OS call in Windows - SystemTimeToTzSpecificLocation. msdn.microsoft.com/en-us/library/ms724949(VS.85).aspx –  Michael Madsen Mar 28 '10 at 15:25
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@tchrist Maybe if you're persistent you can. –  Peter Ajtai Feb 10 '12 at 0:41
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Keep in mind converting future dates (even just tomorrow) to UTC you always lose something. For example, you used some known offset to make that conversion, but since the date is in the future, there is always a chance the group that sets those rules will change those rules. Also, it is virtually impossible to convert some future dates to UTC because the daylight savings times are not known until that year (some countries set the dates every year, not 10+ years ahead or based on any set rules). –  eselk Feb 21 '13 at 15:39
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I'm not sure what I can add to the answers above, but here are a few points from me:

Types of times

There are four different times you should consider:

  1. Event time: eg, the time when an international sporting event happens, or a coronation/death/etc. This is dependent on the timezone of the event and not of the viewer.
  2. Television time: eg, a particular TV show is broadcast at 9pm local time all around the world. Important when thinking about publishing the results (of say American Idol) on your website
  3. Relative time: eg: This question has an open bounty closing in 21 hours. This is easy to display
  4. Recurring time: eg: A TV show is on every Monday at 9pm, even when DST changes.

There is also Historic/alternate time. These are annoying because they may not map back to standard time. Eg: Julian dates, dates according to a Lunar calendar on Saturn, The Klingon calendar.

Storing start/end timestamps in UTC works well. For 1, you need an event timezone name + offset stored along with the event. For 2, you need a local time identifier stored with each region and a local timezone name + offset stored for every viewer (it's possible to derive this from the IP if you're in a crunch). For 3, store in UTC seconds and no need for timezones. 4 is a special case of 1 or 2 depending on whether it's a global or a local event, but you also need to store a created at timestamp so you can tell if a timezone definition changed before or after this event was created. This is necessary if you need to show historic data.

Storing times

  • Always store time in UTC
  • Convert to local time on display (local being defined by the user looking at the data)
  • When storing a timezone, you need the name, timestamp and the offset. This is required because governments sometimes change the meanings of their timezones (eg: the US govt changed DST dates), and your application needs to handle things gracefully... eg: The exact timestamp when episodes of LOST showed both before and after DST rules changed.

Offsets and names

An example of the above would be:

The soccer world cup finals game happened in South Africa (UTC+2--SAST) on July 11, 2010 at 19:00 UTC.

With this information, we can historically determine the exact time when the 2010 WCS finals took place even if the South African timezone definition changes, and be able to display that to viewers in their local timezone at the time when they query the database.

System Time

You also need to keep your OS, database and application tzdata files in sync, both with each other, and with the rest of the world, and test extensively when you upgrade. It's not unheard of that a third party app that you depend on did not handle a TZ change correctly.

Make sure hardware clocks are set to UTC, and if you're running servers around the world, make sure their OSes are configured to use UTC as well. This becomes apparent when you need to copy hourly rotated apache log files from servers in multiple timezones. Sorting them by filename only works if all files are named with the same timezone. It also means that you don't have to do date math in your head when you ssh from one box to another and need to compare timestamps.

Also, run ntpd on all boxes.

Clients

Never trust the timestamp you get from a client machine as valid. For example, the Date: HTTP headers, or a javascript Date.getTime() call. These are fine when used as opaque identifiers, or when doing date math during a single session on the same client, but don't try to cross-reference these values with something you have on the server. Your clients don't run NTP, and may not necessarily have a working battery for their BIOS clock.

Trivia

Finally, governments will sometimes do very weird things:

Standard time in the Netherlands was exactly 19 minutes and 32.13 seconds ahead of UTC by law from 1909-05-01 through 1937-06-30. This time zone cannot be represented exactly using the HH:MM format.

Ok, I think I'm done.

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This answer has some great points, I especially wanted to point this out part "Recurring time: eg: A TV show is on every Monday at 9pm, even when DST changes" Storing times in UTC in the DB and then converting for display helps handle a lot of the tricky aspects of dealing with time zones. However, handling "recurring events" that cross DST barriers becomes much tougher. –  Jared Hales Aug 5 '10 at 13:53
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+1 for the Trivia. Keeping the content interesting makes this task more enjoyable, which may lead to increased productivity :) –  Chris Jan 8 '11 at 6:54
    
Very good answer bluesmoon, thanks. –  Alix Axel Oct 18 '11 at 9:52
    
+1 for referencing LOST –  jberger Mar 6 '12 at 22:12
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A lot of good stuff in this answer, but a few issues. 1) Many time zone abbreviations are ambiguous. see here 2) Not always do you want to store in UTC. Most of the time - yes, but context matters. In your terms, television time would not be stored in UTC. Also, sometimes its unlawful or against policy to not store the local time - which is where things like DateTimeOffset (or equivalent) come in handy. Otherwise, good write up. –  Matt Johnson Jan 11 '13 at 1:38
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This is an important and surprisingly tough issue. The truth is that there is no completely satisfying stardard for persisting time. For example, the SQL standard and the ISO format (ISO 8601) are clearly not enough.

From the conceptual point of view, one usually deals with two types of time-date data, and it's convenient to distinguish them (the above standards do not) : "physical time" and "civil time".

A "physical" instant of time is a point in the continuous universal timeline that physics deal with (ignoring relativity, of course). This concept can be adecuately coded-persisted in UTC, for example (if you can ignore leap seconds).

A "civil" time is a datetime specification that follows civil norms: a point of time here is fully specified by a set of datetime fields (Y,M,D,H,MM,S,FS) plus a TZ (timezone specification) (also a "calendar", actually; but lets assume we restrict the discussion to Gregorian calendar). A timezone and a calendar jointly allow (in principle) to map from one representation to another. But civil and physical time instants are fundamentally different types of magnitudes, and they should be kept conceptually separated and treated differently (an analogy: arrays of bytes and character strings).

The issue is confusing because we speak of these types events interchangeably, and because the civil times are subject to political changes. The problem (and the need to distinguish these concepts) becomes more evident for events in the future. Example (taken from my discussion here

John records in his calendar a reminder for some event at datetime 2019-Jul-27, 10:30:00, TZ=Chile/Santiago, (which has offset GMT+4, hence it corresponds to UTC 2019-Jul-27 14:30:00). But some day in the future, the country decides to change the TZ offset to GMT+5.

Now, when the day comes... should that reminder trigger at

A) 2019-Jul-27 10:30:00 Chile/Santiago = UTC time 2019-Jul-27 15:30:00 ?

or

B) 2019-Jul-27 9:30:00 Chile/Santiago = UTC time 2019-Jul-27 14:30:00 ?

There is no correct answer, unless one knows what John conceptually meant when he told the calendar "Please ring me at 2019-Jul-27, 10:30:00 TZ=Chile/Santiago"

Did he mean a "civil date-time" ("when the clocks in my city tell 10:30")? In that case, A) is the correct answer.

Or did he mean a "physical instant of time", a point in the continuus line of time of our universe, say, "when the next solar eclipse happens". In that case, answer B) is the correct one.

A few Date/Time APIs get this distinction right: among them, Jodatime, which is the foundation of the next (third!) Java DateTime API (JSR 310).

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Another point to consider which I've not seen addressed in APIs is that even when time and time zone are given, there are at least two plausible meanings for e.g. "13:00:00EDT". It could be refer to something which is known to have occurred at 1pm local time, which was believed to have been Eastern Daylight Time, or something which is known to have occurred at the moment that Eastern time hit 13:00, which is believed to have occurred in a place observing Eastern Daylight Time. If one has many timestamps where the time-zone info may be wrong (e.g. digital camera files)... –  supercat Oct 29 '13 at 17:04
    
...knowing whether they reflect an accurate local time or global time may be important in determining how to correct them. –  supercat Oct 29 '13 at 17:04
    
Very useful. Just a small point: Chile/Santiago is GMT-4, I say this because the topic is about time conversion and related issues so it might be misleading to the readers (10:30 GMT+4 -> 6:30 UTC/GMT) –  vizog Jun 15 at 8:27
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Make clear architectural separation of concerns - to know exactly which tier intereacts with users, and has to change date-time for/from cannonical representation (UTC). Non-UTC date-time is presentation (follows users local timezone), UTC time is model (remains unique for back-end and mid tiers).

Also, decide what's your actual audience, what you don't have to serve and where do you draw the line. Don't touch exotic callendars unless you actually have important customers there and then consider separate user-facing server(s) just for that region.

If you can acquire and maintain user's location, use location for systematic date-time conversion (say .NET culture or a SQL table) but provide a way for end-user to choose overrides if date-time is critical for your users.

If there are historical audit obligations involved (like telling exactly when Jo in AZ paid a bill 2 yrs ago in September) then keep both UTC and local time for the record (your coversion tables will change in a course of time).

Define the time referential time zone for data that comes in bulk - like files, web services etc. Say East Coast company has data center in CA - you need to ask and know what they use as a standard instead of assuming one or the other.

Don't trust time-zone offsets embedded in textual representation of the date-time and don't accept to parse and follow them. Instead always request that time zone and/or refernece zone have to be explicitly defined. You can easily receive time with PST offset but the time is actually EST since that's cleints's reference time and records were just exported at a server which is in PST.

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You need to know about the Olson tz database, which is available from ftp://elsie.nci.nih.gov/pub http://iana.org/time-zones/. It is updated multiple times per year to deal with the often last-minute changes in when (and whether) to switch between winter and summer (standard and daylight saving) time in different countries around the world. In 2009, the last release was 2009s; in 2010, it was 2010n; in 2011, it was 2011n; at the end of May 2012, the release was 2012c. Note that there is a set of code to manage the data and the actual time zone data itself, in two separate archives (tzcode20xxy.tar.gz and tzdata20xxy.tar.gz). Both code and data are in the public domain.

This is the source of time zone names such as America/Los_Angeles (and synonyms such as US/Pacific).

If you need to keep track of different zones, then you need the Olson database. As others have advised, you also want to store the data in a fixed format — UTC is normally the one chosen — along with a record of the time zone in which the data was generated. You may want to distinguish between the offset from UTC at the time and the time zone name; that can make a difference later. Also, knowing that it is currently 2010-03-28T23:47:00-07:00 (US/Pacific) may or may not help you with interpreting the value 2010-11-15T12:30 — which is presumably specified in PST (Pacific Standard Time) rather than PDT (Pacific Daylight Saving Time).

The standard C library interfaces are not dreadfully helpful with this sort of stuff.


The Olson data has moved, in part because A D Olson will be retiring soon, and in part because there was a (now dismissed) law suit against the maintainers for copyright infringement. The time zone database is now managed under the auspices of IANA, the Internet Assigned Numbers Authority, and there's a link on the front page to 'Time Zone Database'. The discussion mailing list is now tz@iana.org; the announcement list is tz-announce@iana.org.

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The Olson database contains historical data as well, which makes it particularly useful for handling DST. E.g., it knows that a UTC value corresponding to March 31, 2000 in the U.S. is not in DST, but a UTC value corresponding to March 31, 2008 in the U.S. is. –  Josh Kelley Mar 29 '10 at 14:29
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The Unicode Consortium maintains a mapping between Olson tome zone IDs and Windows time zone IDs: unicode.org/repos/cldr-tmp/trunk/diff/supplemental/… –  Josh Kelley Mar 29 '10 at 14:30
    
Updated link for the Unicode Consortium's page: unicode.org/repos/cldr-tmp/trunk/diff/supplemental/… –  Span Jun 2 '11 at 4:17
    
Where can one found information about parsing the Olson files? I want to compile it into a db table, but can't figure out how should I read the files –  shealtiel Sep 7 '11 at 14:09
    
@gidireich: the main information is found with the data, and it is not easy to understand. The main documentation for it is in the zic.8 man page (or zic.8.txt). You'll need the tzcode2011i.tar.gz file rather than, or as well as, the tzdata2011i.tar.gz file to get this information. –  Jonathan Leffler Sep 7 '11 at 14:46
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In general, include the local time offset (including DST offset) in stored timestamps: UTC alone is not enough if you later want to display the timestamp in its original timezone (and DST setting).

Keep in mind that the offset is not always an integer number of hours (e.g. Indian Standard Time is UTC+05:30).

For example, suitable formats are a tuple (unix time, offset in minutes) or ISO 8601.

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For display, the offset is perfect. If you want to make changes, the offset is still not enough. You have to also know the time zone because the new value may require a different offset. –  Matt Johnson Jan 11 '13 at 1:30
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Crossing the boundary of "computer time" and "people time" is a nightmare. The main one being that there is no sort of standard for the rules governing timezones and daylight saving times. Countries are free to change their timezone and DST rules at any time, and they do.

Some countries e.g. Israel, Brazil, decide each year when to have their daylight saving times, so it is impossible to know in advance when (if) DST will be in effect. Others have fixed(ish) rules as to when DST is in effect. Other countries do not use DST as all.

Timezones do not have to be full hour differences from GMT. Nepal is +5.45. There are even timezones that are +13. That means that:

SUN 23:00 in Howland Island (-12)
MON 11:00 GMT 
TUE 00:00 in Tonga (+13)

are all the same time, yet 3 different days!

There is also no clear standard on the abbreviations for timezones, and how they change when in DST so you end up with things like this:

AST Arab Standard Time     UTC+03
AST Arabian Standard Time  UTC+04
AST Arabic Standard Time   UTC+03

The best advice is to stay away from local times as much as possible and stick to UTC where you can. Only convert to local times at the last possible moment.

When testing make sure you test countries in the Western and Eastern hemispheres, with both DST in progress and not and a country that does not use DST (6 in total).

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Regarding Israel - this is half true. Though the time for the DST change is not a specific date in the Julian calendar - there is a rule based on the Hebrew calendar (there was a change in 2014). Anyway, the general idea is correct - this things might and do change once in a while –  Yaron U. Apr 27 at 6:31
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I have a slightly different take on this. I'm speaking from a .Net perspective, regarding DateTimeOffset and DateTime classes, but a lot of the same concepts apply to any language.

DateTimeOffset is a representation of instantaneous time. By that, I mean a moment in time that is universal for everyone (not accounting for relativity). Another way to represent instantaneous time is with a DateTime where .Kind is DateTimeKind.Utc.

This is distinct from calendar time, which is a position on someone's calendar, and there are many different calendars all over the globe. We call these calendars time zones. Calendar time is represented by a DateTime where .Kind is DateTimeKind.Unspecified, or DateTimeKind.Local. And .Local is only meaningful in scenarios where you have an implied understanding of where the computer that is using the result is positioned. (For example, a user's workstation)

So then, why DateTimeOffset instead of a UTC DateTime? It's all about perspective. Let's use an analogy - we'll pretend to be photographers.

Imagine you are standing on a calendar timeline, pointing a camera at a person on the instantaneous timeline laid out in front of you. You line up your camera according to the rules of your timezone - which change periodically due to daylight savings times and changes in legal definitions of the time zones. (You don't have a steady hand, so your camera is shaky.)

The person standing in the photo would see the angle at which your camera came from. If others were taking pictures, they could be from different angles. This is what the Offset part of the DateTimeOffset represents.

So if you label your camera "Pacific Time", sometimes you are pointing from -8, and sometimes you are pointing from -7. There are cameras all over the world, all labeled different things, and all pointing at the same instantaneous timeline from different angles. Some of them are right next to (or on top of) each other, so just knowing the offset isn't enough to determine which timezone the time is related to.

And what about UTC? Well, it's the one camera out there that is guaranteed to have a steady hand. It's on a tripod, firmly anchored into the ground. It's not going anywhere. We call it's angle of perspective the zero offset.

Instantaneous Time vs Calendar Time Visualization

So - what does this analogy tell us? It provides some intuitive guidelines.

  • If you are representing time relative to some place in particular, represent it in calendar time with a DateTime. Just be sure you don't ever confuse one calendar with another. Unspecified should be your assumption. Local is only useful coming from DateTime.Now. For example, I might get DateTime.Now and save it in a database - but when I retrieve it, I have to assume its Unspecified. I can't rely that my local calendar is the same calendar that it was originally taken from.

  • If you must always be certain of the moment, make sure you are representing instantaneous time. Use DateTimeOffset to enforce it, or use UTC DateTime by convention.

  • If you need to track a moment of instantaneous time, but you want to also know "What time did the user think it was on their local calendar?" - then you must use a DateTimeOffset. This is very important for timekeeping systems, for example - both for technical and legal concerns.

  • If you ever need to modify a previously recorded DateTimeOffset - you don't have enough information in the offset alone to ensure that the new offset is still relevant for the user. You must also store a timezone identifier (think - I need the name of that camera so I can take a new picture even if the position has changed).

    It should also be pointed out that NodaTime has a representation called ZonedDateTime for this, while the .Net base class library does not have anything similar. You would need to store both a DateTimeOffset and a TimeZoneInfo.Id value.

  • Occasionally, you will want to represent a calendar time that is local to "whomever is looking at it". For example, when defining what today means. Today is always midnight to midnight, but these represent a near-infinite number of overlapping ranges on the instantaneous timeline. (In practice we have a finite number of timezones, but you can express offsets down to the tick) So in these situations, make sure you understand how to either limit the "who's asking?" question down to a single time zone, or deal with translating them back to instantaneous time as appropriate.

Here are a few other little bits about DateTimeOffset that back up this analogy, and some tips for keeping it straight:

  • If you compare two DateTimeOffset values, they are first normalized to zero offset before comparing. In other words, 2012-01-01T00:00:00+00:00 and 2012-01-01T02:00:00+02:00 refer to the same instantaneous moment, and are therefore equivalent.

  • If you are doing any unit testing and need to be certain of the offset, test both the DateTimeOffset value, and the .Offset property separately.

  • There is a one-way implicit conversion built in to the .Net framework that lets you pass a DateTime into any DateTimeOffset parameter or variable. When doing so, the .Kind matters. If you pass a UTC kind, it will carry in with a zero offset, but if you pass either .Local or .Unspecified, it will assume to be local. The framework is basically saying, "Well, you asked me to convert calendar time to instantaneous time, but I have no idea where this came from, so I'm just going to use the local calendar." This is a huge gotcha if you load up an unspecified DateTime on a computer with a different timezone. (IMHO - that should throw an exception - but it doesn't.)

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+1 finally some awesome .NET specific advise, thanks! –  eselk Feb 21 '13 at 20:14
    
One thing I don't see in a DateTimeOffset is any way to distinguish between the values "17:00 UTC, in Eastern Daylight Time", and "13:00 Eastern Daylight Time". The two values may seem to represent the same moment in time, but if one discovers that the stored time zone should have been Central Daylight Time, the former should continue to refer to the same moment, while the latter should be changed to represent one an hour later. –  supercat Apr 30 '13 at 17:14
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@supercat - DateTimeOffset can store 2013-04-30T17:00+00:00 or 2013-04-03T13:00-04:00 but it isn't aware of time zones like "Eastern Daylight Time" at all. Only offsets. If you need this functionality, you have to store separately the time zone id, or use ZonedDateTime from NodaTime. –  Matt Johnson Apr 30 '13 at 17:32
    
@MattJohnson: My point was that if one has a time with an offset that might not be correct, one might in some cases know the local time with more certainty than the absolute time, and in other cases know the absolute time with more certainty. If one discovers that some time stamps have an offset that is incorrect, it may be that the time stamps report the correct absolute time (in which case the absolute time should stay constant and the local time changed) or the correct local time (in which case the absolute time should change and the local time remain constant). –  supercat Apr 30 '13 at 17:40
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While I haven't tried it, an approach to time zone adjustments I would find compelling would be as follows:

  1. Store everything in UTC.

  2. Create a table TZOffsets with three columns: RegionClassId, StartDateTime, and OffsetMinutes (int, in minutes).

In the table, store a list of dates and times when the local time changed, and by how much. The number of regions in the table and the number of dates would depend on what range of dates and areas of the world you need to support. Think of this as if it is "historical" date, even though the dates should include the future to some practical limit.

When you need to compute the local time of any UTC time, just do this:

SELECT DATEADD('m', SUM(OffsetMinutes), @inputdatetime) AS LocalDateTime
FROM   TZOffsets
WHERE  StartDateTime <= @inputdatetime
       AND RegionClassId = @RegionClassId;

You might want to cache this table in your app and use LINQ or some similar means to do the queries rather than hitting the database.

This data can be distilled from the public domain tz database [http://www.twinsun.com/tz/tz-link.htm].

Advantages and footnotes of this approach:

  1. No rules are baked into code, you can adjust the offsets for new regions or date ranges readily.
  2. You don't have to support every range of dates or regions, you can add them as needed.
  3. Regions don't have to correspond directly to geopolitical boundaries, and to avoid duplication of rows (for instance, most states in the US handle DST the same way), you can have broad RegionClass entries that link in another table to more traditional lists of states, countries, etc.
  4. For situations like the US where the start and end date of DST has changed over the past few years, this is pretty easy to deal with.
  5. Since the StartDateTime field can store a time as well, the 2:00 AM standard change-over time is handled easily.
  6. Not everywhere in the world uses a 1-hour DST. This handles those cases easily.
  7. The data table is cross-platform and could be a separate open-source project that could be used by developers who use nearly any database platform or programming language.
  8. This can be used for offsets that have nothing to do with time zones. For instance, the 1-second adjustments that happen from time to time to adjust for the Earth's rotation, historical adjustments to and within the Gregorian calendar, etc.
  9. Since this is in a database table, standard report queries, etc. can take advantage of the data without a trip through business logic code.
  10. This handles time zone offsets as well if you want it to, and can even account for special historical cases where a region is assigned to another time zone. All you need is an initial date that assigns a time zone offset to each region with a minimal start date. This would require creating at least one region for each time zone, but would allow you to ask interesting questions like: "What is the difference in local time between Yuma, Arizona and Seattle, Washington on February 2, 1989 at 5:00am?" (Just subtract one SUM() from the other).

Now, the only disadvantage of this approach or any other is that conversions from local time to GMT are not perfect, since any DST change that has a negative offset to the clock repeats a given local time. No easy way to deal with that one, I'm afraid, which is one reason storing local times is bad news in the first place.

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Your database idea has already been implemented as the Olson Database. While daylight savings time does create an overlap specifying the daylight specific timezone can help resolve the issue. 2:15 EST and 2:15 EDT are different times. As noted in other posts specifying the offset also resolves the ambiguity. –  BillThor Aug 3 '10 at 23:04
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The big problem with keeping your own database is keeping it updated. Olson and Windows are maintained for you. I've had more than one case of having bad DST transitions because tables were out of date. Ripping them out entirely and relying on a framework or OS level database is much more reliable. –  Matt Johnson Jan 11 '13 at 1:28
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Do not create your own database: always rely on system's API! –  Alex Oct 9 '13 at 9:54
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If your design can accommodate it, avoid local time conversion all together!

I know to some this might sound insane but think about UX: users process near, relative dates (today, yesterday, next Monday) faster than absolute dates (2010.09.17, Friday Sept 17) on glance. And when you think about it more, the accuracy of timezones (and DST) is more important the closer the date is to now(), so if you can express dates/datetimes in a relative format for +/- 1 or 2 weeks, the rest of the dates can be UTC and it wont matter too much to 95% of users.

This way you can store all dates in UTC and do the relative comparisons in UTC and simply show the user UTC dates outside of your Relative Date Threshold.

This can also apply to user input too (but generally in a more limited fashion). Selecting from a drop down that only has { Yesterday, Today, Tomorrow, Next Monday, Next Thursday } is so much simpler and easier for the user than a date picker. Date pickers are some of the most pain inducing components of form filling. Of course this will not work for all cases but you can see that it only takes a little clever design to make it very powerful.

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+1 Interesting idea. UTC can be a beautiful thing ;o) –  Jon Sep 17 '10 at 15:48
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I have hit this on two types of systems, “shift planning systems (e.g. factory workers)” and “gas depend management systems)…

23 and 25 hour long days are a pain to cope with, so are 8hr shifts that take 7hr or 9hr. The problem is you will find that each customers, or even department of the customer have different rules they have created (often without documenting) on what they do in these special cases.

Some questions are best not asked of the customer’s until after they have paid for your “off the shelf” software. It is very rare to find a customer that thinks about this type of issue up front when buying software.

I think in all cases you should record time in UTC and convert to/from local time before storing the date/time. However even know which take a given time is in can be hard with Daylight saving and time zones.

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My girlfriend, a nurse, works nights and they have to write the timezone during the DST switchover. For instance, 2AM CST vs 2AM CDT –  Joe Philllips Aug 5 '10 at 2:48
    
Yes, this is common: when you compute a (civil) daily average, you have to cope with days of 23, 24, or 25 hours. As a consequence, when you compute add 1 day it is not add 24 hours! Second, don't try to build your own timezone code ; only use systems API. And don't forget to update each deployed system in order to get the up-to-date timezone database. –  Alex Oct 9 '13 at 9:44
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For PHP:

The DateTimeZone class in PHP > 5.2 is already based on the Olson db which others mention, so if you are doing timezone conversions in PHP and not in the DB, you are exempt of working with (the hard-to-understand) Olson files.

However, PHP is not updated as frequently as the Olson DB, so just using PHPs time zone conversions may leave you with outdated DST information, and influence the correctness of your data. While this is not expected to happen frequently, it may happen, and will happen if you have large base of users worldwide.

To cope with the above issue, exist a pecl package, that all it's funcionality is to update PHP's TimeZone data. Install this package as frequently as it is updated, and you are at a very good standpoint. I'm not sure if this packages updates follow Olson updates exactly, but it seems to be updated in a frequency which is at least very close to Olson updates

http://pecl.php.net/package/timezonedb

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Keep your servers set to UTC, and make sure they all are configured for ntp or the equivalent.

UTC avoids daylight savings time issues, and out-of-sync servers can cause unpredictable results that take a while to diagnose.

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I recently had a problem in a web application where on an Ajax post-back the datetime coming back to my server-side code was different from the datetime served out.

It most likely had to do with my JavaScript code on the client that built up the date for posting back to the client as string, because JavaScript was adjusting for time zone and daylight savings, and in some browsers the calculation for when to apply daylight savings seemed to be different than in others.

In the end I opted to remove date and time calculations on the client entirely, and posted back to my server on an integer key which then got translated to date time on the server, to allow for consistent transformations.

My learning from this: Do not use JavaScript date and time calculations in web applications unless you ABSOLUTELY have to.

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Javascript runs at the client machine, not at the server machine. Javascript's base datetime is the client's datetime, not the server's datetime. –  BalusC Mar 29 '10 at 11:39
    
Hi BalusC. I understand this (from my original post: "javacode script on the client that built up the date..."). My issue was that certain client machine processed DST one way, and some others another way. Therefore I moved all of that processing server-side to prevent the browser weirdness –  Joon Mar 31 '10 at 8:28
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Be careful when dealing with timestamps stored in the FAT32 filesystem - it is always persisted in local time coordinates (which include DST - see msdn article). Got burned on that one.

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Great point. NTFS doesn't have this problem, but some people still use FAT32 - especially on USB keys. –  Matt Johnson Jan 11 '13 at 1:22
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One other thing, make sure the servers have the up to date daylight savings patch applied.

We had a situation last year where our times were consistently out by one hour for a three-week period for North American users, even though we were using a UTC based system.

It turns out in the end it was the servers. They just needed an up-to-date patch applied (Windows Server 2003).

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For the web, the rules aren't that complicated...

  • Server-side, use UTC
  • Client-side, use Olson
    • Reason: UTC-offsets are not daylight savings-safe (e.g. New York is EST (UTC - 5 Hours) part of the year, EDT (UTC - 4 Hours) rest of the year).
    • For client-side time zone determination, you have two options:

The rest is just UTC/local conversion using your server-side datetime libraries. Good to go...

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If you happen to maintain database systems that are running with DST active, check carefully whether they need to be shut down during the transition in fall. Mandy DBS (or other systems as well) don't like passing the same point in (local) time twice, which is exactly what happens when you turn back the clock in fall. SAP has solved this with a (IMHO really neat) workaround - instead of turning back the clock, they just let the internal clock run at half the usual speed for two hours...

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Business rules should always work on civil time (unless there's legislation that says otherwise). Be aware that civil time is a mess, but it's what people use so it's what is important.

Internally, keep timestamps in something like civil-time-seconds-from-epoch. The epoch doesn't matter particularly (I favour the Unix epoch) but it does make things easier than the alternative. Pretend that leap-seconds don't exist unless you're doing something that really needs them (e.g., satellite tracking). The mapping between timestamps and displayed time is the only point where DST rules should be applied; the rules change frequently (on a global level, several times a year; blame politicians) so you should make sure that you do not hard-code the mapping. Olson's TZ database is invaluable.

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The problem here is that civil time (aka calendar time) does not properly represent a single moment in time. If you take the seconds-from-epoch approach, are you really going to account for every moment that was skipped over or rewound for daylight savings transitions? Probably not. Epoch basis only works against UTC or some other fixed, instantaneous-time reference. –  Matt Johnson Jan 11 '13 at 1:21
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PHP's DateTimeZone::listAbbreviations() output

This PHP method returns an associative array containing some 'major' timezones (like CEST), which on their own contain more specific 'geographic' timezones (like Europe/Amsterdam).

If you're using these timezones and their offset/DST information, it's extremely important to realize the following:

It seems like all different offset/DST configurations (including historical configurations) of each timezone are included!

For example, Europe/Amsterdam can be found six times in the output of this function. Two occurrences (offset 1172/4772) are for the Amsterdam time used until 1937; two (1200/4800) are for the time that was used between 1937 and 1940; and two (3600/4800) are for the time used since 1940.

Therefore, you cannot rely on the offset/DST information returned by this function as being currently correct/in use!

If you want to know the current offset/DST of a certain timezone, you'll have to do something like this:

<?php
$now = new DateTime(null, new DateTimeZone('Europe/Amsterdam'));
echo $now->getOffset();
?>
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Are you using the .NET framework? If so, let me introduce you to the DateTimeOffset type, added with .NET 3.5.

This structure holds both a DateTime and an Offset (TimeSpan), which specifies the difference between the DateTimeOffset instance's date and time and Coordinated Universal Time (UTC).

  • The DateTimeOffset.Now static method will return a DateTimeOffset instance consisting of the current (local) time, and the local offset (as defined in the operating system's regional info).

  • The DateTimeOffset.UtcNow static method will return a DateTimeOffset instance consisting of the current time in UTC (as if you were in Greenwich).

Other helpful types are the TimeZone and TimeZoneInfo classes.

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This is not a solution to the problem presented. –  Cara Turpin Jan 2 at 21:45
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Actually, kernel32.dll does not export SystemTimeToTzSpecificLocation. It does however export the following two: SystemTimeToTzSpecificLocalTime and TzSpecificLocalTimeToSystemTime...

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Just wanted to point out two things that seem inaccurate or at least confusing:

Always persist time according to a unified standard that is not affected by daylight savings. GMT and UTC have been mentioned by different people, though UTC seems to be mentioned most often.

For (almost) all practical computing purposes, UTC is, in fact, GMT. Unless you see a timestamps with a fractional second, you're dealing with GMT which makes this distinction redundant.

Include the local time offset as is (including DST offset) when storing timestamps.

A timestamp is always represented in GMT and thus has no offset.

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The local time offset will allow you to recreate the original "wall time" of the event. If you do not store this additional field, this data is lost. –  nogridbag Apr 16 '12 at 18:33
    
Yes, except UTC and GMT offsets are inverse. For example UTC-0700 is the same as GMT+0700. Really, everything digital should be using UTC these days. –  Matt Johnson Sep 13 '12 at 19:36
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@Matt: are you sure about UTC and GMT offsets being inverse? where can I read up on that? –  Zalumon Feb 16 '13 at 14:22
    
Actually, I think I was incorrect before. GMT and UTC aren't inverted themselves. It's that there are implementations that show them in inverse, such as the IANA/Olson/TZDB database. See here. Another area you see offsets in inverse is in javascript's getTimezoneOffset() function. –  Matt Johnson Feb 16 '13 at 17:49
    
@MattJohnson: Those are hacks and should be abolished. –  Alix Axel Feb 16 '13 at 22:55
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Never rely only on constructors like

 new DateTime(int year, int month, int day, int hour, int minute, TimeZone timezone)

They can throw exceptions when a certain date time does not exist due to DST. Instead, build your own methods for creating such dates. In them, catch any exceptions that occur due to DST, and adjust the time is needed with the transition offset. DST may occur on different dates and at different hours (even at midnight for Brazil) according to the timezone.

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For those struggling with this on .NET, see if using DateTimeOffset and/or TimeZoneInfo are worth your while.

If you want to use IANA/Olson time zones, or find the built in types are insufficient for your needs, check out Noda Time, which offers a much smarter date and time API for .NET.

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In dealing with databases (in particular MySQL, but this applies to most databases), I found it hard to store UTC.

  • Databases usually work with server datetime by default (that is, CURRENT_TIMESTAMP).
  • You may not be able to change the server timezone.
  • Even if you are able to change the timezone, you may have third-party code that expects server timezone to be local.

I found it easier to just store server datetime in the database, then let the database convert the stored datetime back to UTC (that is, UNIX_TIMESTAMP()) in the SQL statements. After that you can use the datetime as UTC in your code.

If you have 100% control over the server and all code, it's probably better to change server timezone to UTC.

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Local time (the server time) can be ambiguous during "fall-back" style daylight savings transitions. It's not reliable to use as you described. There may be more than one UTC time that the server's local time could be representing. –  Matt Johnson Jan 11 '13 at 1:13
    
Local time is perfectly fine if the server is located in a sane time zone, i.e. one that doesn't do DST. –  sayap Apr 2 '13 at 10:06
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protected by Oded Dec 5 '12 at 14:56

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