xref: /freebsd/contrib/ntp/ntpd/ntpd-opts.def (revision 1f4bcc459a76b7aa664f3fd557684cd0ba6da352)
1/* -*- Mode: Text -*- */
2
3autogen definitions options;
4
5#include copyright.def
6
7prog-name	= "ntpd";
8prog-title	= "NTP daemon program";
9argument	= "[ <server1> ... <serverN> ]";
10
11#include ntpdbase-opts.def
12
13/* explain: Additional information whenever the usage routine is invoked */
14explain = <<- _END_EXPLAIN
15	_END_EXPLAIN;
16
17doc-section	= {
18  ds-type	= 'DESCRIPTION';
19  ds-format	= 'mdoc';
20  ds-text	= <<- _END_PROG_MDOC_DESCRIP
21The
22.Nm
23utility is an operating system daemon which sets
24and maintains the system time of day in synchronism with Internet
25standard time servers.
26It is a complete implementation of the
27Network Time Protocol (NTP) version 4, as defined by RFC-5905,
28but also retains compatibility with
29version 3, as defined by RFC-1305, and versions 1
30and 2, as defined by RFC-1059 and RFC-1119, respectively.
31.Pp
32The
33.Nm
34utility does most computations in 64-bit floating point
35arithmetic and does relatively clumsy 64-bit fixed point operations
36only when necessary to preserve the ultimate precision, about 232
37picoseconds.
38While the ultimate precision is not achievable with
39ordinary workstations and networks of today, it may be required
40with future gigahertz CPU clocks and gigabit LANs.
41.Pp
42Ordinarily,
43.Nm
44reads the
45.Xr ntp.conf 5
46configuration file at startup time in order to determine the
47synchronization sources and operating modes.
48It is also possible to
49specify a working, although limited, configuration entirely on the
50command line, obviating the need for a configuration file.
51This may
52be particularly useful when the local host is to be configured as a
53broadcast/multicast client, with all peers being determined by
54listening to broadcasts at run time.
55.Pp
56If NetInfo support is built into
57.Nm ,
58then
59.Nm
60will attempt to read its configuration from the
61NetInfo if the default
62.Xr ntp.conf 5
63file cannot be read and no file is
64specified by the
65.Fl c
66option.
67.Pp
68Various internal
69.Nm
70variables can be displayed and
71configuration options altered while the
72.Nm
73is running
74using the
75.Xr ntpq 1ntpqmdoc
76and
77.Xr ntpdc 1ntpdcmdoc
78utility programs.
79.Pp
80When
81.Nm
82starts it looks at the value of
83.Xr umask 2 ,
84and if zero
85.Nm
86will set the
87.Xr umask 2
88to 022.
89	_END_PROG_MDOC_DESCRIP;
90};
91
92doc-section	= {
93  ds-type	= 'USAGE';
94  ds-format	= 'mdoc';
95  ds-text	= <<- _END_MDOC_USAGE
96.Ss "How NTP Operates"
97The
98.Nm
99utility operates by exchanging messages with
100one or more configured servers over a range of designated poll intervals.
101When
102started, whether for the first or subsequent times, the program
103requires several exchanges from the majority of these servers so
104the signal processing and mitigation algorithms can accumulate and
105groom the data and set the clock.
106In order to protect the network
107from bursts, the initial poll interval for each server is delayed
108an interval randomized over a few seconds.
109At the default initial poll
110interval of 64s, several minutes can elapse before the clock is
111set.
112This initial delay to set the clock
113can be safely and dramatically reduced using the
114.Cm iburst
115keyword with the
116.Ic server
117configuration
118command, as described in
119.Xr ntp.conf 5 .
120.Pp
121Most operating systems and hardware of today incorporate a
122time-of-year (TOY) chip to maintain the time during periods when
123the power is off.
124When the machine is booted, the chip is used to
125initialize the operating system time.
126After the machine has
127synchronized to a NTP server, the operating system corrects the
128chip from time to time.
129In the default case, if
130.Nm
131detects that the time on the host
132is more than 1000s from the server time,
133.Nm
134assumes something must be terribly wrong and the only
135reliable action is for the operator to intervene and set the clock
136by hand.
137(Reasons for this include there is no TOY chip,
138or its battery is dead, or that the TOY chip is just of poor quality.)
139This causes
140.Nm
141to exit with a panic message to
142the system log.
143The
144.Fl g
145option overrides this check and the
146clock will be set to the server time regardless of the chip time
147(up to 68 years in the past or future \(em
148this is a limitation of the NTPv4 protocol).
149However, and to protect against broken hardware, such as when the
150CMOS battery fails or the clock counter becomes defective, once the
151clock has been set an error greater than 1000s will cause
152.Nm
153to exit anyway.
154.Pp
155Under ordinary conditions,
156.Nm
157adjusts the clock in
158small steps so that the timescale is effectively continuous and
159without discontinuities.
160Under conditions of extreme network
161congestion, the roundtrip delay jitter can exceed three seconds and
162the synchronization distance, which is equal to one-half the
163roundtrip delay plus error budget terms, can become very large.
164The
165.Nm
166algorithms discard sample offsets exceeding 128 ms,
167unless the interval during which no sample offset is less than 128
168ms exceeds 900s.
169The first sample after that, no matter what the
170offset, steps the clock to the indicated time.
171In practice this
172reduces the false alarm rate where the clock is stepped in error to
173a vanishingly low incidence.
174.Pp
175As the result of this behavior, once the clock has been set it
176very rarely strays more than 128 ms even under extreme cases of
177network path congestion and jitter.
178Sometimes, in particular when
179.Nm
180is first started without a valid drift file
181on a system with a large intrinsic drift
182the error might grow to exceed 128 ms,
183which would cause the clock to be set backwards
184if the local clock time is more than 128 s
185in the future relative to the server.
186In some applications, this behavior may be unacceptable.
187There are several solutions, however.
188If the
189.Fl x
190option is included on the command line, the clock will
191never be stepped and only slew corrections will be used.
192But this choice comes with a cost that
193should be carefully explored before deciding to use
194the
195.Fl x
196option.
197The maximum slew rate possible is limited
198to 500 parts-per-million (PPM) as a consequence of the correctness
199principles on which the NTP protocol and algorithm design are
200based.
201As a result, the local clock can take a long time to
202converge to an acceptable offset, about 2,000 s for each second the
203clock is outside the acceptable range.
204During this interval the
205local clock will not be consistent with any other network clock and
206the system cannot be used for distributed applications that require
207correctly synchronized network time.
208.Pp
209In spite of the above precautions, sometimes when large
210frequency errors are present the resulting time offsets stray
211outside the 128-ms range and an eventual step or slew time
212correction is required.
213If following such a correction the
214frequency error is so large that the first sample is outside the
215acceptable range,
216.Nm
217enters the same state as when the
218.Pa ntp.drift
219file is not present.
220The intent of this behavior
221is to quickly correct the frequency and restore operation to the
222normal tracking mode.
223In the most extreme cases
224(the host
225.Cm time.ien.it
226comes to mind), there may be occasional
227step/slew corrections and subsequent frequency corrections.
228It
229helps in these cases to use the
230.Cm burst
231keyword when
232configuring the server, but
233ONLY
234when you have permission to do so from the owner of the target host.
235.Pp
236Finally,
237in the past many startup scripts would run
238.Xr ntpdate 1ntpdatemdoc
239or
240.Xr sntp 1sntpmdoc
241to get the system clock close to correct before starting
242.Xr ntpd 1ntpdmdoc ,
243but this was never more than a mediocre hack and is no longer needed.
244If you are following the instructions in
245.Sx "Starting NTP (Best Current Practice)"
246and you still need to set the system time before starting
247.Nm ,
248please open a bug report and document what is going on,
249and then look at using
250.Xr sntp 1sntpmdoc
251if you really need to set the clock before starting
252.Nm .
253.Pp
254There is a way to start
255.Xr ntpd 1ntpdmdoc
256that often addresses all of the problems mentioned above.
257.Ss "Starting NTP (Best Current Practice)"
258First, use the
259.Cm iburst
260option on your
261.Cm server
262entries.
263.Pp
264If you can also keep a good
265.Pa ntp.drift
266file then
267.Xr ntpd 1ntpdmdoc
268will effectively "warm-start" and your system's clock will
269be stable in under 11 seconds' time.
270.Pp
271As soon as possible in the startup sequence, start
272.Xr ntpd 1ntpdmdoc
273with at least the
274.Fl g
275and perhaps the
276.Fl N
277options.
278Then,
279start the rest of your "normal" processes.
280This will give
281.Xr ntpd 1ntpdmdoc
282as much time as possible to get the system's clock synchronized and stable.
283.Pp
284Finally,
285if you have processes like
286.Cm dovecot
287or database servers
288that require
289monotonically-increasing time,
290run
291.Xr ntp-wait 1ntp-waitmdoc
292as late as possible in the boot sequence
293(perhaps with the
294.Fl v
295flag)
296and after
297.Xr ntp-wait 1ntp-waitmdoc
298exits successfully
299it is as safe as it will ever be to start any process that require
300stable time.
301.Ss "Frequency Discipline"
302The
303.Nm
304behavior at startup depends on whether the
305frequency file, usually
306.Pa ntp.drift ,
307exists.
308This file
309contains the latest estimate of clock frequency error.
310When the
311.Nm
312is started and the file does not exist, the
313.Nm
314enters a special mode designed to quickly adapt to
315the particular system clock oscillator time and frequency error.
316This takes approximately 15 minutes, after which the time and
317frequency are set to nominal values and the
318.Nm
319enters
320normal mode, where the time and frequency are continuously tracked
321relative to the server.
322After one hour the frequency file is
323created and the current frequency offset written to it.
324When the
325.Nm
326is started and the file does exist, the
327.Nm
328frequency is initialized from the file and enters normal mode
329immediately.
330After that the current frequency offset is written to
331the file at hourly intervals.
332.Ss "Operating Modes"
333The
334.Nm
335utility can operate in any of several modes, including
336symmetric active/passive, client/server broadcast/multicast and
337manycast, as described in the
338.Qq Association Management
339page
340(available as part of the HTML documentation
341provided in
342.Pa /usr/share/doc/ntp ) .
343It normally operates continuously while
344monitoring for small changes in frequency and trimming the clock
345for the ultimate precision.
346However, it can operate in a one-time
347mode where the time is set from an external server and frequency is
348set from a previously recorded frequency file.
349A
350broadcast/multicast or manycast client can discover remote servers,
351compute server-client propagation delay correction factors and
352configure itself automatically.
353This makes it possible to deploy a
354fleet of workstations without specifying configuration details
355specific to the local environment.
356.Pp
357By default,
358.Nm
359runs in continuous mode where each of
360possibly several external servers is polled at intervals determined
361by an intricate state machine.
362The state machine measures the
363incidental roundtrip delay jitter and oscillator frequency wander
364and determines the best poll interval using a heuristic algorithm.
365Ordinarily, and in most operating environments, the state machine
366will start with 64s intervals and eventually increase in steps to
3671024s.
368A small amount of random variation is introduced in order to
369avoid bunching at the servers.
370In addition, should a server become
371unreachable for some time, the poll interval is increased in steps
372to 1024s in order to reduce network overhead.
373.Pp
374In some cases it may not be practical for
375.Nm
376to run continuously.
377A common workaround has been to run the
378.Xr ntpdate 1ntpdatemdoc
379or
380.Xr sntp 1sntpmdoc
381programs from a
382.Xr cron 8
383job at designated
384times.
385However, these programs do not have the crafted signal
386processing, error checking or mitigation algorithms of
387.Nm .
388The
389.Fl q
390option is intended for this purpose.
391Setting this option will cause
392.Nm
393to exit just after
394setting the clock for the first time.
395The procedure for initially
396setting the clock is the same as in continuous mode; most
397applications will probably want to specify the
398.Cm iburst
399keyword with the
400.Ic server
401configuration command.
402With this
403keyword a volley of messages are exchanged to groom the data and
404the clock is set in about 10 s.
405If nothing is heard after a
406couple of minutes, the daemon times out and exits.
407After a suitable
408period of mourning, the
409.Xr ntpdate 1ntpdatemdoc
410program will be
411retired.
412.Pp
413When kernel support is available to discipline the clock
414frequency, which is the case for stock Solaris, Tru64, Linux and
415.Fx ,
416a useful feature is available to discipline the clock
417frequency.
418First,
419.Nm
420is run in continuous mode with
421selected servers in order to measure and record the intrinsic clock
422frequency offset in the frequency file.
423It may take some hours for
424the frequency and offset to settle down.
425Then the
426.Nm
427is
428stopped and run in one-time mode as required.
429At each startup, the
430frequency is read from the file and initializes the kernel
431frequency.
432.Ss "Poll Interval Control"
433This version of NTP includes an intricate state machine to
434reduce the network load while maintaining a quality of
435synchronization consistent with the observed jitter and wander.
436There are a number of ways to tailor the operation in order enhance
437accuracy by reducing the interval or to reduce network overhead by
438increasing it.
439However, the user is advised to carefully consider
440the consequences of changing the poll adjustment range from the
441default minimum of 64 s to the default maximum of 1,024 s.
442The
443default minimum can be changed with the
444.Ic tinker
445.Cm minpoll
446command to a value not less than 16 s.
447This value is used for all
448configured associations, unless overridden by the
449.Cm minpoll
450option on the configuration command.
451Note that most device drivers
452will not operate properly if the poll interval is less than 64 s
453and that the broadcast server and manycast client associations will
454also use the default, unless overridden.
455.Pp
456In some cases involving dial up or toll services, it may be
457useful to increase the minimum interval to a few tens of minutes
458and maximum interval to a day or so.
459Under normal operation
460conditions, once the clock discipline loop has stabilized the
461interval will be increased in steps from the minimum to the
462maximum.
463However, this assumes the intrinsic clock frequency error
464is small enough for the discipline loop correct it.
465The capture
466range of the loop is 500 PPM at an interval of 64s decreasing by a
467factor of two for each doubling of interval.
468At a minimum of 1,024
469s, for example, the capture range is only 31 PPM.
470If the intrinsic
471error is greater than this, the drift file
472.Pa ntp.drift
473will
474have to be specially tailored to reduce the residual error below
475this limit.
476Once this is done, the drift file is automatically
477updated once per hour and is available to initialize the frequency
478on subsequent daemon restarts.
479.Ss "The huff-n'-puff Filter"
480In scenarios where a considerable amount of data are to be
481downloaded or uploaded over telephone modems, timekeeping quality
482can be seriously degraded.
483This occurs because the differential
484delays on the two directions of transmission can be quite large.
485In
486many cases the apparent time errors are so large as to exceed the
487step threshold and a step correction can occur during and after the
488data transfer is in progress.
489.Pp
490The huff-n'-puff filter is designed to correct the apparent time
491offset in these cases.
492It depends on knowledge of the propagation
493delay when no other traffic is present.
494In common scenarios this
495occurs during other than work hours.
496The filter maintains a shift
497register that remembers the minimum delay over the most recent
498interval measured usually in hours.
499Under conditions of severe
500delay, the filter corrects the apparent offset using the sign of
501the offset and the difference between the apparent delay and
502minimum delay.
503The name of the filter reflects the negative (huff)
504and positive (puff) correction, which depends on the sign of the
505offset.
506.Pp
507The filter is activated by the
508.Ic tinker
509command and
510.Cm huffpuff
511keyword, as described in
512.Xr ntp.conf 5 .
513	_END_MDOC_USAGE;
514};
515
516doc-section	= {
517  ds-type	= 'FILES';
518  ds-format	= 'mdoc';
519  ds-text	= <<- _END_MDOC_FILES
520.Bl -tag -width /etc/ntp.drift -compact
521.It Pa /etc/ntp.conf
522the default name of the configuration file
523.It Pa /etc/ntp.drift
524the default name of the drift file
525.It Pa /etc/ntp.keys
526the default name of the key file
527.El
528	_END_MDOC_FILES;
529};
530
531doc-section	= {
532  ds-type	= 'SEE ALSO';
533  ds-format	= 'mdoc';
534  ds-text	= <<- _END_MDOC_SEE_ALSO
535.Xr ntp.conf 5 ,
536.Xr ntpdate 1ntpdatemdoc ,
537.Xr ntpdc 1ntpdcmdoc ,
538.Xr ntpq 1ntpqmdoc ,
539.Xr sntp 1sntpmdoc
540.Pp
541In addition to the manual pages provided,
542comprehensive documentation is available on the world wide web
543at
544.Li http://www.ntp.org/ .
545A snapshot of this documentation is available in HTML format in
546.Pa /usr/share/doc/ntp .
547.Rs
548.%A David L. Mills
549.%T Network Time Protocol (Version 1)
550.%O RFC1059
551.Re
552.Rs
553.%A David L. Mills
554.%T Network Time Protocol (Version 2)
555.%O RFC1119
556.Re
557.Rs
558.%A David L. Mills
559.%T Network Time Protocol (Version 3)
560.%O RFC1305
561.Re
562.Rs
563.%A David L. Mills
564.%A J. Martin, Ed.
565.%A J. Burbank
566.%A W. Kasch
567.%T Network Time Protocol Version 4: Protocol and Algorithms Specification
568.%O RFC5905
569.Re
570.Rs
571.%A David L. Mills
572.%A B. Haberman, Ed.
573.%T Network Time Protocol Version 4: Autokey Specification
574.%O RFC5906
575.Re
576.Rs
577.%A H. Gerstung
578.%A C. Elliott
579.%A B. Haberman, Ed.
580.%T Definitions of Managed Objects for Network Time Protocol Version 4: (NTPv4)
581.%O RFC5907
582.Re
583.Rs
584.%A R. Gayraud
585.%A B. Lourdelet
586.%T Network Time Protocol (NTP) Server Option for DHCPv6
587.%O RFC5908
588.Re
589	_END_MDOC_SEE_ALSO;
590};
591
592doc-section	= {
593  ds-type	= 'BUGS';
594  ds-format	= 'mdoc';
595  ds-text	= <<- _END_MDOC_BUGS
596The
597.Nm
598utility has gotten rather fat.
599While not huge, it has gotten
600larger than might be desirable for an elevated-priority
601.Nm
602running on a workstation, particularly since many of
603the fancy features which consume the space were designed more with
604a busy primary server, rather than a high stratum workstation in
605mind.
606	_END_MDOC_BUGS;
607};
608
609doc-section	= {
610  ds-type	= 'NOTES';
611  ds-format	= 'mdoc';
612  ds-text	= <<- _END_MDOC_NOTES
613Portions of this document came from FreeBSD.
614	_END_MDOC_NOTES;
615};
616