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Chapter 14. Configuring NTP Using the chrony Suite

14.1. Introduction to the chrony Suite
14.1.1. Differences Between ntpd and chronyd
14.1.2. Choosing Between NTP Daemons
14.2. Understanding chrony and Its Configuration
14.2.1. Understanding chronyd
14.2.2. Understanding chronyc
14.2.3. Understanding the chrony Configuration Commands
14.2.4. Security with chronyc
14.3. Using chrony
14.3.1. Installing chrony
14.3.2. Checking the Status of chronyd
14.3.3. Starting chronyd
14.3.4. Stopping chronyd
14.3.5. Checking if chrony is Synchronized
14.3.6. Manually Adjusting the System Clock
14.4. Setting Up chrony for Different Environments
14.4.1. Setting Up chrony for a System Which is Infrequently Connected
14.4.2. Setting Up chrony for a System in an Isolated Network
14.5. Using chronyc
14.5.1. Using chronyc to Control chronyd
14.5.2. Using chronyc for Remote Administration
14.6. Additional Resources
14.6.1. Installed Documentation
14.6.2. Online Documentation
Accurate time keeping is important for a number of reasons in IT. In networking for example, accurate time stamps in packets and logs are required. In Linux systems, the NTP protocol is implemented by a daemon running in user space.
The user space daemon updates the system clock running in the kernel. The system clock can keep time by using various clock sources. Usually, the Time Stamp Counter (TSC) is used. The TSC is a CPU register which counts the number of cycles since it was last reset. It is very fast, has a high resolution, and there are no interrupts.
There is a choice between the daemons ntpd and chronyd, which are available from the repositories in the ntp and chrony packages respectively. This section describes the use of the chrony suite of utilities to update the system clock on systems that do not fit into the conventional permanently networked, always on, dedicated server category.

14.1. Introduction to the chrony Suite

Chrony consists of chronyd, a daemon that runs in user space, and chronyc, a command line program for making adjustments to chronyd. Systems which are not permanently connected, or not permanently powered up, take a relatively long time to adjust their system clocks with ntpd. This is because many small corrections are made based on observations of the clocks drift and offset. Temperature changes, which may be significant when powering up a system, affect the stability of hardware clocks. Although adjustments begin within a few milliseconds of booting a system, acceptable accuracy may take anything from ten seconds from a warm restart to a number of hours depending on your requirements, operating environment and hardware. chrony is a different implementation of the NTP protocol than ntpd, it can adjust the system clock more rapidly.

14.1.1. Differences Between ntpd and chronyd

One of the main differences between ntpd and chronyd is in the algorithms used to control the computer's clock. Things chronyd can do better than ntpd are:
  • chronyd can work well when external time references are only intermittently accessible, whereas ntpd needs regular polling of time reference to work well.
  • chronyd can perform well even when the network is congested for longer periods of time.
  • chronyd can usually synchronize the clock faster and with better time accuracy.
  • chronyd quickly adapts to sudden changes in the rate of the clock, for example, due to changes in the temperature of the crystal oscillator, whereas ntpd may need a long time to settle down again.
  • In the default configuration, chronyd never steps the time after the clock has been synchronized at system start, in order not to upset other running programs. ntpd can be configured to never step the time too, but it has to use a different means of adjusting the clock, which has some disadvantages.
  • chronyd can adjust the rate of the clock on a Linux system in a larger range, which allows it to operate even on machines with a broken or unstable clock. For example, on some virtual machines.
Things chronyd can do that ntpd cannot do:
  • chronyd provides support for isolated networks where the only method of time correction is manual entry. For example, by the administrator looking at a clock. chronyd can examine the errors corrected at different updates to estimate the rate at which the computer gains or loses time, and use this estimate to trim the computer clock subsequently.
  • chronyd provides support to work out the rate of gain or loss of the real-time clock, the hardware clock, that maintains the time when the computer is turned off. It can use this data when the system boots to set the system time using an adjusted value of the time taken from the real-time clock. This is, at time of writing, only available in Linux.
Things ntpd can do that chronyd cannot do:
  • ntpd fully supports NTP version 4 (RFC 5905), including broadcast, multicast, manycast clients and servers, and the orphan mode. It also supports extra authentication schemes based on public-key cryptography (RFC 5906). chronyd uses NTP version 3 (RFC 1305), which is compatible with version 4.
  • ntpd includes drivers for many reference clocks whereas chronyd relies on other programs, for example gpsd, to access the data from the reference clocks.

14.1.2. Choosing Between NTP Daemons

  • Chrony should be considered for all systems which are frequently suspended or otherwise intermittently disconnected and reconnected to a network. Mobile and virtual systems for example.
  • The NTP daemon (ntpd) should be considered for systems which are normally kept permanently on. Systems which are required to use broadcast or multicast IP, or to perform authentication of packets with the Autokey protocol, should consider using ntpd. Chrony only supports symmetric key authentication using a message authentication code (MAC) with MD5, SHA1 or stronger hash functions, whereas ntpd also supports the Autokey authentication protocol which can make use of the PKI system. Autokey is described in RFC 5906.