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Regarding Unix (POSIX) time, Wikipedia says:

Due to its handling of leap seconds, it is neither a linear representation of time nor a true representation of UTC.

But the Unix date command does not seem to be aware of them actually

$ date -d '@867715199' --utc
Mon Jun 30 23:59:59 UTC 1997
$ date -d '@867715200' --utc
Tue Jul  1 00:00:00 UTC 1997

While there should be a leap second there at Mon Jun 30 23:59:60 UTC 1997.

Does this mean that only the date command ignores leap seconds, while the concept of Unix time doesn't?

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38

The number of seconds per day are fixed with Unix timestamps.

The Unix time number is zero at the Unix epoch, and increases by exactly 86400 per day since the epoch.

So it cannot represent leap seconds. The OS will slow down the clock to accommodate for this. The leap seconds is simply not existent as far a Unix timestamps are concerned.

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    A unix second is allowed to be different from a "real" second. The unix day has 86400s which are actually 86401 real seconds (for days with leap seconds). Otherwise the clock is ahead like TAI: TAI has been exactly 35 seconds ahead of UTC. The 35 seconds results from the initial difference of 10 seconds at the start of 1972, plus 25 leap seconds in UTC since 1972. May 15 '13 at 8:05
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    @ThomasJung, Your answer is misleading / wrong. 1) The Unix time can and does represent leap seconds, albeit not unambiguously. For example, UTC 1998-12-31 23:59:60.25 is represented as Unix time 915148800.25. If the number of seconds were fixed with Unix timestamps, we would have 86400 unique integer Unix timestamps per day, every day. Although Unix timestamps increase by 86400 per day, it doesn't mean that we have 86400 seconds in Unix timestamps per day. Not every real number is a valid Unix timestamp due to negative leap seconds, and not every real..
    – Pacerier
    Jun 16 '13 at 17:31
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    ..number is a unique Unix timestamp due to positive leap seconds. 2) Leap seconds do exist as far as Unix timestamps are concerned. If they didn't, Unix time will freeze during a leap second, which it doesn't.
    – Pacerier
    Jun 16 '13 at 19:37
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    @Campa: TAI time continues to tick during a leap seconds as always (each intercalary leap second increases TAI - UTC difference. POSIX time is UTC time (excluding moments during leap seconds). TAI can tell actual elapsed UTC (SI) seconds, POSIX -- UT (Earth rotation) seconds (because UTC is within 0.9 seconds from UT). To find the actual number of elapsed seconds between two events given in UTC, you need to know the corresponding leap counts at each event e.g., 2010-01-01 -- 34 leap seconds, 2013-01-01 -- 35 leap seconds.
    – jfs
    Sep 15 '14 at 0:22
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    @Jung : could you please rephrase to "So it cannot represent leap seconds unambiguously " ?
    – Campa
    Apr 23 '15 at 7:25
30

Unix time is easy to work with, but some timestamps are not real times, and some timestamps are not unique times.

That is, there are some duplicate timestamps representing two different seconds in time, because in unix time the sixtieth second might have to repeat itself (as there can't be a sixty-first second). Theoretically, they could also be gaps in the future because the sixtieth second doesn't have to exist, although no skipping leap seconds have been issued so far.

Rationale for unix time: it's defined so that it's easy to work with. Adding support for leap seconds to the standard libraries is very tricky. For example, you want to represent 1 Jan 2050 in a database. No-one on earth knows how many seconds away that date is in UTC! The date can't be stored as a UTC timestamp, because the IAU doesn't know how many leap seconds we'll have to add in the next decades (they're as good as random). So how can a programmer do date arithmetic when the length of time which will elapse between any two dates in the future isn't know until a year or two before? Unix time is simple: we know the timestamp of 1 Jan 2050 already (namely, 80 years * #of seconds in a year). UTC is extremely hard to work with all year round, whereas unix time is only hard to work with in the instant a leap second occurs.

For what it's worth, I've never met a programmer who agrees with leap seconds. They should clearly be abolished.

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    No, unix time never has leap seconds. It's synced with UTC, that is, unix time ticks at the same moment as UTC ticks: the second has exactly the same length, and they line up. Sometimes when unix time ticks though its value goes up by two, whereas UTC only ever goes up by one. Unix time is massively, massively easier than any system with leap seconds because leap seconds are a total joke. May 14 '13 at 13:29
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    Sorry, stupid mistake in last comment. Third sentence should read: "Sometimes when unix time ticks though its value repeats the previous second, whereas UTC only ever goes up by one." May 14 '13 at 13:40
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    @Pacerier OK, so 1 Jan 2050, 00:00:00 is 2524629600. What's the UTC timestamp for that? No-one knows. That's a big issue for programmers: either you write a lot of code, or do some really sloppy programming (which might not even be legal, depending on any regulation the software has to comply with). Leap seconds are as good as random, in that we don't know when they'll come. We don't have any models that accurately predict the earth's wobble, we just have to wait and see each year. Of course it's deterministic, but that's no help either to programmers or the IAU. Jun 17 '13 at 9:51
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    You seem to be stuck to the idea that a timestamp must be a reflection of a count of seconds, though in fact goo.gl/QWsOo a timestamp is simply a sequence of characters or encoded information. In other words, the string "1 Jan 2050, 00:00:00" is in fact a UTC timestamp by itself if we can decode it to the UTC time "1 Jan 2050, 00:00:00". If you don't like alphanumerics, we can always convert this to any arbitrary encoded integer like "2498729866093" and it's still a UTC timestamp as long as the receiver........
    – Pacerier
    Jun 21 '13 at 2:21
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    I've deleted my comments. You win. If you want to learn, start by learning about probability distributions.
    – jfs
    Oct 30 '14 at 9:19
14

There is a lot of discussion here and elsewhere about leap seconds, but it isn't a complicated issue, because it doesn't have anything to do with UTC, or GMT, or UT1, or TAI, or any other time standard. POSIX (Unix) time is, by definition, that which is specified by the IEEE Std 1003.1 "POSIX" standard, available here.

The standard is unambiguous: POSIX time does not include leap seconds.

Coordinated Universal Time (UTC) includes leap seconds. However, in POSIX time (seconds since the Epoch), leap seconds are ignored (not applied) to provide an easy and compatible method of computing time differences. Broken-down POSIX time is therefore not necessarily UTC, despite its appearance.

The standard goes into significant detail unambiguously stating that POSIX time does not include leap seconds, in particular:

It is a practical impossibility to mandate that a conforming implementation must have a fixed relationship to any particular official clock (consider isolated systems, or systems performing "reruns" by setting the clock to some arbitrary time).

Since leap seconds are decided by committee, it is not just a "bad idea" to include leap seconds in POSIX time, it is impossible given that the standard allows for conforming implementations which do not have network access.

Elsewhere in this question @Pacerier has said that POSIX time does include leap seconds, and that each POSIX time may correspond to more than one UTC time. While this is certainly one possible interpretation of a POSIX timestamp, this is by no means specified by the standard. His arguments largely amount to weasel words that do not apply to the standard, which defines POSIX time.

Now, things get complicated. As specified by the standard, POSIX time may not be equivalent to UTC time:

Broken-down POSIX time is therefore not necessarily UTC, despite its appearance.

However, in practice, it is. In order to understand the issue, you have to understand time standards. GMT and UT1 are based on the astronomical position of the Earth in the universe. TAI is based on the actual amount of time that passes in the universe as measured by physical (atomic) reactions. In TAI, each second is an "SI second," which are all exactly the same length. In UTC, each second is an SI second, but leap seconds are added as necessary to readjust the clock back to within .9 seconds of GMT/UT1. The GMT and UT1 time standards are defined by empirical measurements of the Earth's position and movement in the universe, and these empirical measurements cannot through any means (neither scientific theory nor approximation) be predicted. As such, leap seconds are also unpredictable.

Now, the POSIX standard also specifies that the intention is for all POSIX timestamps to be interoperable (mean the same thing) in different implementations. One solution is for everyone to agree that each POSIX second is one SI second, in which case POSIX time is equivalent to TAI (with the specified epoch), and nobody need contact anyone except for their atomic clock. We didn't do that, however, probably because we wanted POSIX timestamps to be UTC timestamps.

Using an apparent loophole in the POSIX standard, implementations intentionally slow down or speed up seconds -- so that POSIX time no longer uses SI seconds -- in order to remain in sync with UTC time. Reading the standard it is clear this was not what was intended, because this cannot be done with isolated systems, which therefore cannot interoperate with other machines (their timestamps, without leap seconds, mean something different for other machines, with leap seconds). Read:

[...] it is important that the interpretation of time names and seconds since the Epoch values be consistent across conforming systems; that is, it is important that all conforming systems interpret "536457599 seconds since the Epoch" as 59 seconds, 59 minutes, 23 hours 31 December 1986, regardless of the accuracy of the system's idea of the current time. The expression is given to ensure a consistent interpretation, not to attempt to specify the calendar. [...] This unspecified second is nominally equal to an International System (SI) second in duration.

The "loophole" allowing this behavior:

Note that as a practical consequence of this, the length of a second as measured by some external standard is not specified.

So, implementations abuse this freedom by intentionally changing it to something which cannot, by definition, be interoperable among isolated or nonparticipating systems. Alternatively, the implementation may simply repeat POSIX times as if no time had passed. See this Unix StackExchange answer for details on all modern implementations.

Phew, that was confusing alright... A real brain teaser!

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  • You mean "In UTC, each second is an SI second, but leap seconds are subtracted* as necessary..."
    – Carlo Wood
    Jan 27 '21 at 3:04
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Since both of the other answers contain lots of misleading information, I'll throw this in.

Thomas is right that the number of Unix Epoch timestamp seconds per day are fixed. What this means is that on days where there is a leap second, the second right before midnight (the 61st second of the UTC minute before midnight) is given the same timestamp as the previous second.

That timestamp is "replayed", if you will. So the same unix timestamp will be used for two real-world seconds. This also means that if you're getting fraction unix epochs, the whole second will repeat.

X86399.0, X86399.5, X86400.0, X86400.5, X86400.0, X86400.5, then X86401.0.

So unix time can't unambiguously represent leap seconds - the leap second timestamp is also the timestamp for the previous real-world second.

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    It also means that the phrase "the number of seconds since the epoch" is extremely misleading. Those are NOT S.I. seconds, but some kinds mysterious and not really precisely defined "POSIX seconds" whose length varies as more leap seconds are (more or less randomly) applied.
    – Carlo Wood
    Jan 27 '21 at 3:14

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