xref: /freebsd/contrib/ntp/README.leapsmear (revision e8d8bef961a50d4dc22501cde4fb9fb0be1b2532)
1Leap Second Smearing with NTP
2-----------------------------
3
4By Martin Burnicki
5with some edits by Harlan Stenn
6
7The NTP software protocol and its reference implementation, ntpd, were
8originally designed to distribute UTC time over a network as accurately as
9possible.
10
11Unfortunately, leap seconds are scheduled to be inserted into or deleted
12from the UTC time scale in irregular intervals to keep the UTC time scale
13synchronized with the Earth rotation.  Deletions haven't happened, yet, but
14insertions have happened over 30 times.
15
16The problem is that POSIX requires 86400 seconds in a day, and there is no
17prescribed way to handle leap seconds in POSIX.
18
19Whenever a leap second is to be handled ntpd either:
20
21- passes the leap second announcement down to the OS kernel (if the OS
22supports this) and the kernel handles the leap second automatically, or
23
24- applies the leap second correction itself.
25
26NTP servers also pass a leap second warning flag down to their clients via
27the normal NTP packet exchange, so clients also become aware of an
28approaching leap second, and can handle the leap second appropriately.
29
30
31The Problem on Unix-like Systems
32--------------------------------
33If a leap second is to be inserted then in most Unix-like systems the OS
34kernel just steps the time back by 1 second at the beginning of the leap
35second, so the last second of the UTC day is repeated and thus duplicate
36timestamps can occur.
37
38Unfortunately there are lots of applications which get confused it the
39system time is stepped back, e.g. due to a leap second insertion.  Thus,
40many users have been looking for ways to avoid this, and tried to introduce
41workarounds which may work properly, or not.
42
43So even though these Unix kernels normally can handle leap seconds, the way
44they do this is not optimal for applications.
45
46One good way to handle the leap second is to use ntp_gettime() instead of
47the usual calls, because ntp_gettime() includes a "clock state" variable
48that will actually tell you if the time you are receiving is OK or not, and
49if it is OK, if the current second is an in-progress leap second.  But even
50though this mechanism has been available for about 20 years' time, almost
51nobody uses it.
52
53
54NTP Client for Windows Contains a Workaround
55--------------------------------------------
56The Windows system time knows nothing about leap seconds, so for many years
57the Windows port of ntpd provides a workaround where the system time is
58slewed by the client to compensate the leap second.
59
60Thus it is not required to use a smearing NTP server for Windows clients,
61but of course the smearing server approach also works.
62
63
64The Leap Smear Approach
65-----------------------
66Due to the reasons mentioned above some support for leap smearing has
67recently been implemented in ntpd.  This means that to insert a leap second
68an NTP server adds a certain increasing "smear" offset to the real UTC time
69sent to its clients, so that after some predefined interval the leap second
70offset is compensated.  The smear interval should be long enough,
71e.g. several hours, so that NTP clients can easily follow the clock drift
72caused by the smeared time.
73
74During the period while the leap smear is being performed, ntpd will include
75a specially-formatted 'refid' in time packets that contain "smeared" time.
76This refid is of the form 254.x.y.z, where x.y.z are 24 encoded bits of the
77smear value.
78
79With this approach the time an NTP server sends to its clients still matches
80UTC before the leap second, up to the beginning of the smear interval, and
81again corresponds to UTC after the insertion of the leap second has
82finished, at the end of the smear interval.  By examining the first byte of
83the refid, one can also determine if the server is offering smeared time or
84not.
85
86Of course, clients which receive the "smeared" time from an NTP server don't
87have to (and even must not) care about the leap second anymore.  Smearing is
88just transparent to the clients, and the clients don't even notice there's a
89leap second.
90
91
92Pros and Cons of the Smearing Approach
93--------------------------------------
94The disadvantages of this approach are:
95
96- During the smear interval the time provided by smearing NTP servers
97differs significantly from UTC, and thus from the time provided by normal,
98non-smearing NTP servers.  The difference can be up to 1 second, depending
99on the smear algorithm.
100
101- Since smeared time differs from true UTC, and many applications require
102correct legal time (UTC), there may be legal consequences to using smeared
103time.  Make sure you check to see if this requirement affects you.
104
105However, for applications where it's only important that all computers have
106the same time and a temporary offset of up to 1 s to UTC is acceptable, a
107better approach may be to slew the time in a well defined way, over a
108certain interval, which is what we call smearing the leap second.
109
110
111The Motivation to Implement Leap Smearing
112-----------------------------------------
113Here is some historical background for ntpd, related to smearing/slewing
114time.
115
116Up to ntpd 4.2.4, if kernel support for leap seconds was either not
117available or was not enabled, ntpd didn't care about the leap second at all.
118So if ntpd was run with -x and thus kernel support wasn't used, ntpd saw a
119sudden 1 s offset after the leap second and normally would have stepped the
120time by -1 s a few minutes later.  However, 'ntpd -x' does not step the time
121but "slews" the 1-second correction, which takes 33 minutes and 20 seconds
122to complete.  This could be considered a bug, but certainly this was only an
123accidental behavior.
124
125However, as we learned in the discussion in http://bugs.ntp.org/2745, this
126behavior was very much appreciated since indeed the time was never stepped
127back, and even though the start of the slewing was somewhat undefined and
128depended on the poll interval.  The system time was off by 1 second for
129several minutes before slewing even started.
130
131In ntpd 4.2.6 some code was added which let ntpd step the time at UTC
132midnight to insert a leap second, if kernel support was not used.
133Unfortunately this also happened if ntpd was started with -x, so the folks
134who expected that the time was never stepped when ntpd was run with -x found
135this wasn't true anymore, and again from the discussion in NTP bug 2745 we
136learn that there were even some folks who patched ntpd to get the 4.2.4
137behavior back.
138
139In 4.2.8 the leap second code was rewritten and some enhancements were
140introduced, but the resulting code still showed the behavior of 4.2.6,
141i.e. ntpd with -x would still step the time.  This has only recently been
142fixed in the current ntpd stable code, but this fix is only available with a
143certain patch level of ntpd 4.2.8.
144
145So a possible solution for users who were looking for a way to come over the
146leap second without the time being stepped could have been to check the
147version of ntpd installed on each of their systems.  If it's still 4.2.4 be
148sure to start the client ntpd with -x.  If it's 4.2.6 or 4.2.8 it won't work
149anyway except if you had a patched ntpd version instead of the original
150version.  So you'd need to upgrade to the current -stable code to be able to
151run ntpd with -x and get the desired result, so you'd still have the
152requirement to check/update/configure every single machine in your network
153that runs ntpd.
154
155Google's leap smear approach is a very efficient solution for this, for
156sites that do not require correct timestamps for legal purposes.  You just
157have to take care that your NTP servers support leap smearing and configure
158those few servers accordingly.  If the smear interval is long enough so that
159NTP clients can follow the smeared time it doesn't matter at all which
160version of ntpd is installed on a client machine, it just works, and it even
161works around kernel bugs due to the leap second.
162
163Since all clients follow the same smeared time the time difference between
164the clients during the smear interval is as small as possible, compared to
165the -x approach.  The current leap second code in ntpd determines the point
166in system time when the leap second is to be inserted, and given a
167particular smear interval it's easy to determine the start point of the
168smearing, and the smearing is finished when the leap second ends, i.e. the
169next UTC day begins.
170
171The maximum error doesn't exceed what you'd get with the old smearing caused
172by -x in ntpd 4.2.4, so if users could accept the old behavior they would
173even accept the smearing at the server side.
174
175In order to affect the local timekeeping as little as possible the leap
176smear support currently implemented in ntpd does not affect the internal
177system time at all.  Only the timestamps and refid in outgoing reply packets
178*to clients* are modified by the smear offset, so this makes sure the basic
179functionality of ntpd is not accidentally broken.  Also peer packets
180exchanged with other NTP servers are based on the real UTC system time and
181the normal refid, as usual.
182
183The leap smear implementation is optionally available in ntp-4.2.8p3 and
184later, and the changes can be tracked via http://bugs.ntp.org/2855.
185
186
187Using NTP's Leap Second Smearing
188--------------------------------
189- Leap Second Smearing MUST NOT be used for public servers, e.g. servers
190provided by metrology institutes, or servers participating in the NTP pool
191project.  There would be a high risk that NTP clients get the time from a
192mixture of smearing and non-smearing NTP servers which could result in
193undefined client behavior.  Instead, leap second smearing should only be
194configured on time servers providing dedicated clients with time, if all
195those clients can accept smeared time.
196
197- Leap Second Smearing is NOT configured by default.  The only way to get
198this behavior is to invoke the ./configure script from the NTP source code
199package with the --enable-leap-smear parameter before the executables are
200built.
201
202- Even if ntpd has been compiled to enable leap smearing support, leap
203smearing is only done if explicitly configured.
204
205- The leap smear interval should be at least several hours' long, and up to
2061 day (86400s).  If the interval is too short then the applied smear offset
207is applied too quickly for clients to follow.  86400s (1 day) is a good
208choice.
209
210- If several NTP servers are set up for leap smearing then the *same* smear
211interval should be configured on each server.
212
213- Smearing NTP servers DO NOT send a leap second warning flag to client time
214requests.  Since the leap second is applied gradually the clients don't even
215notice there's a leap second being inserted, and thus there will be no log
216message or similar related to the leap second be visible on the clients.
217
218- Since clients don't (and must not) become aware of the leap second at all,
219clients getting the time from a smearing NTP server MUST NOT be configured
220to use a leap second file.  If they had a leap second file they would apply
221the leap second twice: the smeared one from the server, plus another one
222inserted by themselves due to the leap second file.  As a result, the
223additional correction would soon be detected and corrected/adjusted.
224
225- Clients MUST NOT be configured to poll both smearing and non-smearing NTP
226servers at the same time.  During the smear interval they would get
227different times from different servers and wouldn't know which server(s) to
228accept.
229
230
231Setting Up A Smearing NTP Server
232--------------------------------
233If an NTP server should perform leap smearing then the leap smear interval
234(in seconds) needs to be specified in the NTP configuration file ntp.conf,
235e.g.:
236
237 leapsmearinterval 86400
238
239Please keep in mind the leap smear interval should be between several and 24
240hours' long.  With shorter values clients may not be able to follow the
241drift caused by the smeared time, and with longer values the discrepancy
242between system time and UTC will cause more problems when reconciling
243timestamp differences.
244
245When ntpd starts and a smear interval has been specified then a log message
246is generated, e.g.:
247
248 ntpd[31120]: config: leap smear interval 86400 s
249
250While ntpd is running with a leap smear interval specified the command:
251
252 ntpq -c rv
253
254reports the smear status, e.g.:
255
256# ntpq -c rv
257associd=0 status=4419 leap_add_sec, sync_uhf_radio, 1 event, leap_armed,
258version="ntpd 4.2.8p3-RC1@1.3349-o Mon Jun 22 14:24:09 UTC 2015 (26)",
259processor="i586", system="Linux/3.7.1", leap=01, stratum=1,
260precision=-18, rootdelay=0.000, rootdisp=1.075, refid=MRS,
261reftime=d93dab96.09666671 Tue, Jun 30 2015 23:58:14.036,
262clock=d93dab9b.3386a8d5 Tue, Jun 30 2015 23:58:19.201, peer=2335,
263tc=3, mintc=3, offset=-0.097015, frequency=44.627, sys_jitter=0.003815,
264clk_jitter=0.451, clk_wander=0.035, tai=35, leapsec=201507010000,
265expire=201512280000, leapsmearinterval=86400, leapsmearoffset=-932.087
266
267In the example above 'leapsmearinterval' reports the configured leap smear
268interval all the time, while the 'leapsmearoffset' value is 0 outside the
269interval and increases from 0 to -1000 ms over the interval.  So this can be
270used to monitor if and how the time sent to clients is smeared.  With a
271leapsmearoffset of -.932087, the refid reported in smeared packets would be
272254.196.88.176.
273