Internet Engineering Task Force D. Reilly, Ed.
Internet-Draft Orolia USA
Intended status: Best Current Practice H. Stenn
Expires: September 27, 2019 Network Time Foundation
D. Sibold
PTB
March 26, 2019
Network Time Protocol Best Current Practices
draft-ietf-ntp-bcp-13
Abstract
The Network Time Protocol (NTP) is one of the oldest protocols on the
Internet and has been widely used since its initial publication.
This document is a collection of Best Practices for general operation
of NTP servers and clients on the Internet. It includes
recommendations for stable, accurate and secure operation of NTP
infrastructure. This document is targeted at NTP version 4 as
described in RFC 5905.
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF). Note that other groups may also distribute
working documents as Internet-Drafts. The list of current Internet-
Drafts is at https://datatracker.ietf.org/drafts/current/.
Internet-Drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
material or to cite them other than as "work in progress."
This Internet-Draft will expire on September 27, 2019.
Copyright Notice
Copyright (c) 2019 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(https://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
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carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Requirements Language . . . . . . . . . . . . . . . . . . 3
2. General Network Security Best Practices . . . . . . . . . . . 3
2.1. BCP 38 . . . . . . . . . . . . . . . . . . . . . . . . . 3
3. NTP Configuration Best Practices . . . . . . . . . . . . . . 4
3.1. Keeping NTP up to date . . . . . . . . . . . . . . . . . 4
3.2. Use enough time sources . . . . . . . . . . . . . . . . . 4
3.3. Use a diversity of Reference Clocks . . . . . . . . . . . 5
3.4. Control Messages . . . . . . . . . . . . . . . . . . . . 6
3.5. Monitoring . . . . . . . . . . . . . . . . . . . . . . . 7
3.6. Using Pool Servers . . . . . . . . . . . . . . . . . . . 7
3.7. Leap Second Handling . . . . . . . . . . . . . . . . . . 8
3.7.1. Leap Smearing . . . . . . . . . . . . . . . . . . . . 9
4. NTP Security Mechanisms . . . . . . . . . . . . . . . . . . . 10
4.1. Pre-Shared Key Approach . . . . . . . . . . . . . . . . . 10
4.2. Autokey . . . . . . . . . . . . . . . . . . . . . . . . . 11
4.3. Network Time Security . . . . . . . . . . . . . . . . . . 11
4.4. External Security Protocols . . . . . . . . . . . . . . . 11
5. NTP Security Best Practices . . . . . . . . . . . . . . . . . 11
5.1. Minimizing Information Leakage . . . . . . . . . . . . . 11
5.2. Avoiding Daemon Restart Attacks . . . . . . . . . . . . . 12
5.3. Detection of Attacks Through Monitoring . . . . . . . . . 14
5.4. Kiss-o'-Death Packets . . . . . . . . . . . . . . . . . . 14
5.5. Broadcast Mode Should Only Be Used On Trusted Networks . 15
5.6. Symmetric Mode Should Only Be Used With Trusted Peers . . 15
6. NTP in Embedded Devices . . . . . . . . . . . . . . . . . . . 15
6.1. Updating Embedded Devices . . . . . . . . . . . . . . . . 16
6.2. Server configuration . . . . . . . . . . . . . . . . . . 16
7. NTP over Anycast . . . . . . . . . . . . . . . . . . . . . . 16
8. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 18
9. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 18
10. Security Considerations . . . . . . . . . . . . . . . . . . . 18
11. References . . . . . . . . . . . . . . . . . . . . . . . . . 18
11.1. Normative References . . . . . . . . . . . . . . . . . . 18
11.2. Informative References . . . . . . . . . . . . . . . . . 19
11.3. URIs . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Appendix A. Best Practices specific to the Network Time
Foundation implementation . . . . . . . . . . . . . 21
A.1. Use enough time sources . . . . . . . . . . . . . . . . . 22
A.2. NTP Control and Facility Messages . . . . . . . . . . . . 22
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A.3. Monitoring . . . . . . . . . . . . . . . . . . . . . . . 23
A.4. Leap Second File . . . . . . . . . . . . . . . . . . . . 23
A.5. Leap Smearing . . . . . . . . . . . . . . . . . . . . . . 23
A.6. Configuring ntpd . . . . . . . . . . . . . . . . . . . . 24
A.7. Pre-Shared Keys . . . . . . . . . . . . . . . . . . . . . 24
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 24
1. Introduction
NTP version 4 (NTPv4) has been widely used since its publication as
[RFC5905]. This document is a collection of best practices for the
operation of NTP clients and servers.
The recommendations in this document are intended to help operators
distribute time on their networks more accurately and more securely.
It is intended to apply generally to a broad range of networks. Some
specific networks may have higher accuracy requirements that require
additional techniques beyond what is documented here.
Among the best practices covered are recommendations for general
network security, time protocol specific security, and NTP server and
client configuration. NTP operation in embedded devices is also
covered.
This document also contains information for protocol implementors who
want to develop their own implementations that are compliant to RFC
5905.
1.1. Requirements Language
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in
BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all
capitals, as shown here.
2. General Network Security Best Practices
2.1. BCP 38
Many network attacks rely on modifying the IP source address of a
packet to point to a different IP address than the computer which
originated it. UDP-based protocols such as NTP are generally more
susceptible to spoofing attacks than connection-oriented protocols.
NTP control messages can generate a lot of data in response to a
small query, which makes it attractive as a vector for distributed
denial-of-service attacks. (NTP Control messages are discussed
further in Section 3.4). One documented instance of such an attack
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can be found here [1], and further discussion in [IMC14] and
[NDSS14].
BCP 38 [RFC2827] was published in 2000 to to provide some level of
remediation against address-spoofing attacks. BCP 38 calls for
filtering outgoing and incoming traffic to make sure that the source
and destination IP addresses are consistent with the expected flow of
traffic on each network interface. It is RECOMMENDED that ISP's and
large corporate networks implement ingress and egress filtering.
More information is available at the BCP38 Info Web page [2] .
3. NTP Configuration Best Practices
This section provides Best Practices for NTP configuration and
operation. Application of these best practices that are specific to
the Network Time Foundation implementation, including example
configuration directives valid at the time of this writing, are
compiled in Appendix A.
3.1. Keeping NTP up to date
There are multiple versions of the NTP protocol in use, and multiple
implementations, on many different platforms. The practices in this
document are meant to apply generally to any implementation of
[RFC5905]. NTP users should select an implementation that is
actively maintained. Users should keep up to date on any known
attacks on their selected implementation, and deploy updates
containing security fixes as soon as practical.
3.2. Use enough time sources
An NTP implementation that is compliant with [RFC5905] takes the
available sources of time and submits this timing data to
sophisticated intersection, clustering, and combining algorithms to
get the best estimate of the correct time. The description of these
algorithms is beyond the scope of this document. Interested readers
should read [RFC5905] or the detailed description of NTP in
[MILLS2006].
o If there is only 1 source of time, the answer is obvious. It may
not be a good source of time, but it's the only source of time
that can be considered. Any issue with the time at the source
will be passed on to the client.
o If there are 2 sources of time and they agree well enough, then
the best time can be calculated easily. But if one source fails,
then the solution degrades to the single-source solution outlined
above. And if the two sources don't agree, it will be difficult
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to know which one is correct without making use of information
from outside of the protocol.
o If there are 3 sources of time, there is more data available to
converge on the best calculated time, and this time is more likely
to be accurate. And the loss of one of the sources (by becoming
unreachable or unusable) can be tolerated. But at that point, the
solution degrades to the 2 source solution.
o 4 or more sources of time is better, as long as the sources are
diverse (Section 3.3). If one of these sources develops a problem
there are still at least 3 other time sources.
This analysis assumes that a majority of the servers used in the
solution are honest, even if some may be inaccurate. Operators
should be aware of the possibility that if an attacker is in control
of the network, the time coming from all servers could be
compromised.
Operators who are concerned with maintaining accurate time SHOULD use
at least 4 independent, diverse sources of time. Four sources will
provide sufficient backup in case one source goes down. If four
sources are not available, operators MAY use fewer sources, subject
to the risks outlined above.
But even with 4 or more sources of time, systemic problems can
happen. One example involves the leap smearing concept detailed in
Section 3.7.1. For several hours before and after the June 2015 leap
second, several operators configured their NTP servers with leap
smearing while others did not. Many NTP end nodes could not
determine an accurate time source because 2 of their 4 sources of
time gave them consistent UTC/POSIX time, while the other 2 gave them
consistent leap-smeared time. This is just one of many potential
causes of disagreement among time sources.
Operators are advised to monitor all time sources that are in use.
If time sources do not generally agree, operators are encouraged to
investigate the cause of this and either correct the problems or stop
using defective servers. See Section 3.5 for more information.
3.3. Use a diversity of Reference Clocks
When using servers with attached hardware reference clocks, it is
suggested that different types of reference clocks be used. Having a
diversity of sources with independent implementations means that any
one issue is less likely to cause a service interruption.
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Are all clocks on a network from the same vendor? They may have the
same bugs. Even devices from different vendors may not be truly
independent if they share common elements. Are they using the same
base chipset? Are they all running the same version of firmware?
Chipset and firmware bugs can happen, but they can be more difficult
to diagnose than application software bugs. When having the correct
time is of critical importance, it's ultimately up to operators to
ensure that their sources are sufficiently independent, even if they
are not under the operator's control.
A systemic problem with time from any satellite navigation service is
possible and has happened. Sunspot activity can render satellite or
radio-based time source unusable. Depending on the application
requirements, operators may need to consider backup scenarios in the
rare circumstance when the satellite system is faulty or unavailable.
3.4. Control Messages
Some implementations of NTPv4 provide the NTP Control Messages (also
known as Mode 6 messages) that were originally specified in
Appendix B of [RFC1305] which defined NTPv3. These messages were
never included the NTPv4 specification, but they are still used. At
the time of this writing, work is being done to formally document the
structure of these control messages in [I-D.ietf-ntp-mode-6-cmds].
The NTP Control Messages are designed to permit monitoring and
optionally authenticated control of NTP and its configuration. Used
properly, these facilities provide vital debugging and performance
information and control. But these facilities can be a vector for
amplification attacks when abused. For this reason, it is
RECOMMENDED that publicly-facing NTP servers should block NTP Control
Message queries from outside their organization.
The ability to use NTP Control Messages beyond their basic monitoring
capabilities SHOULD be limited to authenticated sessions that provide
a 'controlkey'. It can also be limited through mechanisms outside of
the NTP specification, such as Access Control Lists, that only allow
access from approved IP addresses.
The NTP Control Messages responses are much larger than the
corresponding queries. Thus, they can be abused in high-bandwidth
DDoS attacks. Section 2.1 gives more information on how to provide
protection for this abuse by implementing BCP 38.
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3.5. Monitoring
Operators SHOULD use their NTP implementation's remote monitoring
capabilities to quickly identify servers which are out of sync, and
ensure correctness of the service. Operators SHOULD also monitor
system logs for messages so problems and abuse attempts can be
quickly identified.
If a system starts to receive NTP Reply packets from a remote time
server that do not correspond to any requests sent by the system,
that can be an indication that an attacker is forging that system's
IP address in requests to the remote time server. The goal of this
attack is to adversely impact the availability of time to the
targeted system whose address is being forged. Based on these forged
packets, the remote time server might decide to throttle or rate
limit packets, or even stop sending packets to the targeted system.
If a system is a broadcast client and its system log shows that it is
receiving early time messages from its server, that is an indication
that somebody may be forging packets from a broadcast server.
(Broadcast client and server modes are defined in Section 3 of
[RFC5905])
If a server's system log shows messages that indicates it is
receiving NTP timestamps that are much earlier than the current
system time, then either the system clock is unusually fast or
somebody is trying to launch a replay attack against that server.
3.6. Using Pool Servers
It only takes a small amount of bandwidth and system resources to
synchronize one NTP client, but NTP servers that can service tens of
thousands of clients take more resources to run. Network operators
and advanced users who want to synchronize their computers MUST only
synchronize to servers that they have permission to use.
The NTP Pool Project is a group of volunteers who have donated their
computing and bandwidth resources to freely distribute time from
primary time sources to others on the Internet. The time is
generally of good quality but comes with no guarantee whatsoever. If
you are interested in using this pool, please review their
instructions at http://www.pool.ntp.org/en/use.html [3].
Vendors can obtain their own subdomain that is part of the NTP Pool
Project. This offers vendors the ability to safely make use of the
time distributed by the pool for their devices. Details are
available at http://www.pool.ntp.org/en/vendors.html [4] .
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If there is a need to synchronize many computers, an operator may
want to run local NTP servers that are synchronized to the NTP Pool
Project. NTP users on that operator's networks can then be
synchronized to local NTP servers.
3.7. Leap Second Handling
UTC is kept in agreement with the astronomical time UT1 [5] to within
+/- 0.9 seconds by the insertion (or possibly a deletion) of a leap
second. UTC is an atomic time scale whereas UT1 is based on the
rotational rate of the earth. Leap seconds are not introduced at a
fixed rate. They are announced by the International Earth Rotation
and Reference Systems Service (IERS) in its Bulletin C [6] when
necessary to keep UTC and UT1 aligned.
NTP time is based on the UTC timescale, and the protocol has the
capability to broadcast leap second information. Some Global
Navigation Satellite Systems (like GPS) or radio transmitters (like
DCF77) broadcast leap second information. If an NTP client is synced
to an NTP server that provides leap second notification, the client
will get advance notification of impending leap seconds
automatically.
Since the length of the UT1 day is generally slowly increasing [7],
all leap seconds that have been introduced since the practice started
in 1972 have been positive leap seconds, where a second is added to
UTC. NTP also supports a negative leap second, where a second is
removed from UTC, if that ever becomes necessary.
While earlier versions of NTP contained some ambiguity regarding when
a leap second that is broadcast by a server should be applied by a
client, RFC 5905 is clear that leap seconds are only applied on the
last day of a month. However, because some older clients may apply
it at the end of the current day, it is RECOMMENDED that NTP servers
wait until the last day of the month before broadcasting leap
seconds. Doing this will prevent older clients from applying a leap
second at the wrong time. When implementing this recommendation,
operators should ensure that clients are not configured to use
polling intervals greater than 24 hours, so the leap second
notification is not missed.
In circumstances where an NTP server is not receiving leap second
information from an automated source, certain organizations maintain
files which are updated every time a new leap second is announced:
NIST: ftp://time.nist.gov/pub/leap-seconds.list
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US Navy (maintains GPS Time): ftp://tycho.usno.navy.mil/pub/ntp/leap-
seconds.list
IERS (announces leap seconds):
https://hpiers.obspm.fr/iers/bul/bulc/ntp/leap-seconds.list
3.7.1. Leap Smearing
Some NTP installations make use of a technique called Leap Smearing.
With this method, instead of introducing an extra second (or
eliminating a second) on a leap second event, NTP time will be slewed
in small increments over a comparably large window of time (called
the smear interval) around the leap second event. The smear interval
should be large enough to make the rate that the time is slewed
small, so that clients will follow the smeared time without
objecting. Periods ranging from 2 to 24 hours have been used
successfully. During the adjustment window, all the NTP clients'
times may be offset from UTC by as much as a full second, depending
on the implementation. But at least all clients will generally agree
on what time they think it is.
The purpose of Leap Smearing is to enable systems that don't deal
with the leap second event properly to function consistently, at the
expense of fidelity to UTC during the smear window. During a
standard leap second event, that minute will have 61 (or possibly 59)
seconds in it, and some applications (and even some OS's) are known
to have problems with that.
Operators who have legal obligations or other strong requirements to
be synchronized with UTC or civil time SHOULD NOT use leap smearing,
because the distributed time cannot be guaranteed to be traceable to
UTC during the smear interval.
Clients that are connected to leap smearing servers MUST NOT apply
the standard NTP leap second handling. These clients must never have
a leap second file loaded, and the smearing servers must never
advertise to clients that a leap second is pending.
Any use of leap smearing servers should be limited to within a
single, well-controlled environment. Leap Smearing MUST NOT be used
for public-facing NTP servers, as they will disagree with non-
smearing servers (as well as UTC) during the leap smear interval, and
there is no standardized way for a client to detect that a server is
using leap smearing. However, be aware that some public-facing
servers may be configured this way anyway in spite of this guidance.
System Administrators are advised to be aware of impending leap
seconds and how the servers (inside and outside their organization)
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they are using deal with them. Individual clients MUST NOT be
configured to use a mixture of smeared and non-smeared servers. If a
client uses smeared servers, the servers it uses must all have the
same leap smear configuration.
4. NTP Security Mechanisms
In the standard configuration NTP packets are exchanged unprotected
between client and server. An adversary that is able to become a
Man-In-The-Middle is therefore able to drop, replay or modify the
content of the NTP packet, which leads to degradation of the time
synchronization or the transmission of false time information. A
threat analysis for time synchronization protocols is given in
[RFC7384]. NTP provides two internal security mechanisms to protect
authenticity and integrity of the NTP packets. Both measures protect
the NTP packet by means of a Message Authentication Code (MAC).
Neither of them encrypts the NTP's payload, because this payload
information is not considered to be confidential.
4.1. Pre-Shared Key Approach
This approach applies a symmetric key for the calculation of the MAC,
which protects authenticity and integrity of the exchanged packets
for an association. NTP does not provide a mechanism for the
exchange of the keys between the associated nodes. Therefore, for
each association, keys MUST be exchanged securely by external means,
and they MUST be protected from disclosure. It is RECOMMENDED that
each association be protected by its own unique key. It is
RECOMMENDED that participants agree to refresh keys periodically.
However, NTP does not provide a mechanism to assist in doing so.
Each communication partner will need to keep track of its keys in its
own local key storage.
[RFC5905] specifies using the MD5 hash algorithm for calculation of
the MAC, but other algorithms may be supported as well. The MD5 hash
is now considered to be too weak and unsuitable for cryptographic
usage. [RFC6151] has more information on the algorithm's weaknesses.
Implementations will soon be available based on AES-128-CMAC
[I-D.ietf-ntp-mac], and users SHOULD use that when it is available.
Some implementations store the key in clear text. Therefore it MUST
only be readable by the NTP process.
An NTP client has to be able to link a key to a particular server in
order to establish a protected association. This linkage is
implementation specific. Once applied, a key will be trusted until
the link is removed.
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4.2. Autokey
[RFC5906] specifies the Autokey protocol. It was published in 2010
to provide automated key management and authentication of NTP
servers. However, security researchers have identified
vulnerabilities [8] in the Autokey protocol.
Autokey SHOULD NOT be used.
4.3. Network Time Security
Work is in progress on an enhanced replacement for Autokey. Refer to
[I-D.ietf-ntp-using-nts-for-ntp] for more information.
4.4. External Security Protocols
If applicable, external security protocols such as IPsec and MACsec
can be applied to enhance integrity and authenticity protection of
NTP time synchronization packets. Usage of such external security
protocols can decrease time synchronization performance [RFC7384].
Therefore, operators are advised to carefully evaluate if the
decreased time synchronization performance meets their specific
timing requirements.
Note that none of the security measures described in Section 4 can
prevent packet delay manipulation attacks on NTP. Such delay attacks
can target time synchronization packets sent as clear-text or even
within an encrypted tunnel. These attacks are described further in
Section 3.2.6 of [RFC7384].
5. NTP Security Best Practices
This section lists some general NTP security practices, but these
issues may (or may not) have been mitigated in particular versions of
particular implementations. Contact the maintainers of the relevant
implementation for more information.
5.1. Minimizing Information Leakage
The base NTP packet leaks important information (including reference
ID and reference time) that may be used in attacks [NDSS16],
[CVE-2015-8138], [CVE-2016-1548]. A remote attacker can learn this
information by sending mode 3 queries to a target system and
inspecting the fields in the mode 4 response packet. NTP control
queries also leak important information (including reference ID,
expected origin timestamp, etc.) that may be used in attacks
[CVE-2015-8139]. A remote attacker can learn this information by
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sending control queries to a target system and inspecting the leaked
information in the response.
As such, mechanisms outside of the NTP protocol, such as Access
Control Lists, SHOULD be used to limit the exposure of this
information to allowed IP addresses, and keep it from remote
attackers not on the list. Hosts SHOULD only respond to NTP control
queries from authorized parties.
An NTP client that does not provide time on the network can
additionally log and drop incoming mode 3 timing queries from
unexpected sources. Note well that the easiest way to monitor the
status of an NTP instance is to send it a mode 3 query, so it may not
be desirable to drop all mode 3 queries. As an alternative,
operators SHOULD either filter mode 3 queries from outside their
networks, or make sure mode 3 queries are allowed only from trusted
systems or networks.
A "leaf-node host" is a host that is using NTP solely for the purpose
of adjusting its own system time. Such a host is not expected to
provide time to other hosts, and relies exclusively on NTP's basic
mode to take time from a set of servers. (That is, the host sends
mode 3 queries to its servers and receives mode 4 responses from
these servers containing timing information.) To minimize
information leakage, leaf-node hosts SHOULD drop all incoming NTP
packets except mode 4 response packets that come from known sources.
An exception to this can be made if a leaf-node host is being
actively monitored, in which case incoming packets from the
monitoring server can be allowed.
Please refer to [I-D.ietf-ntp-data-minimization] for more
information.
5.2. Avoiding Daemon Restart Attacks
[RFC5905] says NTP clients should not accept time shifts greater than
the panic threshold. Specifically, RFC 5905 says "PANIC means the
offset is greater than the panic threshold PANICT (1000 s) and SHOULD
cause the program to exit with a diagnostic message to the system
log."
However, this behavior can be exploited by attackers as described in
[NDSS16], when the following two conditions hold:
1. The operating system automatically restarts the NTP client when
it quits. (Modern *NIX operating systems are replacing
traditional init systems with process supervisors, such as
systemd, which can be configured to automatically restart any
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daemons that quit. This behavior is the default in CoreOS and
Arch Linux. As of the time of this writing, it appears likely to
become the default behavior in other systems as they migrate
legacy init scripts to process supervisors such as systemd.)
2. The NTP client is configured to ignore the panic threshold on all
restarts.
In such cases, if the attacker can send the target an offset that
exceeds the panic threshold, the client will quit. Then, when it
restarts, it ignores the panic threshold and accepts the attacker's
large offset.
Operators need to be aware that when operating with the above two
conditions, the panic threshold offers no protection from attacks.
The natural solution is not to run hosts with these conditions.
Specifically, operators SHOULD NOT ignore the panic threshold in all
cold-start situations unless sufficient oversight and checking is in
place to make sure that this type of attack cannot happen.
As an alternative, the following steps MAY be taken by operators to
mitigate the risk of attack:
o Monitor the NTP system log to detect when the NTP daemon has quit
due to a panic event, as this could be a sign of an attack.
o Request manual intervention when a timestep larger than the panic
threshold is detected.
o Configure the ntp client to only ignore the panic threshold in a
cold start situation.
o Increase the minimum number of servers required before the NTP
client adjusts the system clock. This will make the NTP client
wait until enough trusted sources of time agree before declaring
the time to be correct.
In addition, the following steps SHOULD be taken by those who
implement the NTP protocol:
o Prevent the NTP daemon from taking time steps that set the clock
to a time earlier than the compile date of the NTP daemon.
o Prevent the NTP daemon from putting 'INIT' in the reference ID of
its NTP packets upon initializing. This will make it more
difficult for attackers to know when the daemon reboots.
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5.3. Detection of Attacks Through Monitoring
Operators SHOULD monitor their NTP instances to detect attacks. Many
known attacks on NTP have particular signatures. Common attack
signatures include:
1. Bogus packets - A packet whose origin timestamp does not match
the value that expected by the client.
2. Zero origin packet - A packet with an origin timestamp set to
zero [CVE-2015-8138].
3. A packet with an invalid cryptographic MAC [CCR16].
The observation of many such packets could indicate that the client
is under attack.
5.4. Kiss-o'-Death Packets
The "Kiss-o'-Death" (KoD) packet includes a rate management mechanism
where a server can tell a misbehaving client to reduce its query
rate. KoD packets in general (and the RATE packet in particular) are
defined in Section 7.4 of [RFC5905]. It is RECOMMENDED that all NTP
devices respect these packets and back off when asked to do so by a
server. It is even more important for an embedded device, which may
not have an exposed control interface for NTP.
That said, a client MUST only accept a KoD packet if it has a valid
origin timestamp. Once a RATE packet is accepted, the client should
increase its poll interval value (thus decreasing its polling rate)
up to a reasonable maximum. This maximum can vary by implementation
but should not exceed a poll interval value of 13 (2 hours). The
mechanism to determine how much to increase the poll interval value
is undefined in [RFC5905]. If the client uses the poll interval
value sent by the server in the RATE packet, it MUST NOT simply
accept any value. Using large interval values may open a vector for
a denial-of-service attack that causes the client to stop querying
its server [NDSS16].
The KoD rate management mechanism relies on clients behaving properly
in order to be effective. Some clients ignore the RATE packet
entirely, and other poorly-implemented clients might unintentionally
increase their poll rate and simulate a denial of service attack.
Server administrators are advised to be prepared for this and take
measures outside of the NTP protocol to drop packets from misbehaving
clients when these clients are detected.
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Kiss-o'-Death (KoD) packets can be used in denial of service attacks.
Thus, the observation of even just one RATE packet with a high poll
value could be sign that the client is under attack. And KoD packets
are commonly accepted even when not cryptographically authenticated,
which increases the risk of denial of service attacks.
5.5. Broadcast Mode Should Only Be Used On Trusted Networks
Per [RFC5905], NTP's broadcast mode is authenticated using symmetric
key cryptography. The broadcast server and all its broadcast clients
share a symmetric cryptographic key, and the broadcast server uses
this key to append a message authentication code (MAC) to the
broadcast packets it sends.
Importantly, all broadcast clients that listen to this server have to
know the cryptographic key. This mean that any client can use this
key to send valid broadcast messages that look like they come from
the broadcast server. Thus, a rogue broadcast client can use its
knowledge of this key to attack the other broadcast clients.
For this reason, an NTP broadcast server and all its clients have to
trust each other. Broadcast mode SHOULD only be run from within a
trusted network.
5.6. Symmetric Mode Should Only Be Used With Trusted Peers
In symmetric mode, two peers Alice and Bob can both push and pull
synchronization to and from each other using either ephemeral
symmetric passive (mode 2) or persistent symmetric active (NTP mode
1) packets. The persistent association is preconfigured and
initiated at the active peer but not preconfigured at the passive
peer (Bob). Upon receipt of a mode 1 NTP packet from Alice, Bob
mobilizes a new ephemeral association if he does not have one
already. This is a security risk for Bob because an arbitrary
attacker can attempt to change Bob's time by asking Bob to become its
symmetric passive peer.
For this reason, a host SHOULD only allow symmetric passive
associations to be established with trusted peers. Specifically, a
host SHOULD require each of its symmetric passive association to be
cryptographically authenticated. Each symmetric passive association
SHOULD be authenticated under a different cryptographic key.
6. NTP in Embedded Devices
As computing becomes more ubiquitous, there will be many small
embedded devices that require accurate time. These devices may not
have a persistent battery-backed clock, so using NTP to set the
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correct time on power-up may be critical for proper operation. These
devices may not have a traditional user interface, but if they
connect to the Internet they will be subject to the same security
threats as traditional deployments.
6.1. Updating Embedded Devices
Vendors of embedded devices are advised to pay attention to the
current state of protocol security issues and bugs in their chosen
implementation, because their customers don't have the ability to
update their NTP implementation on their own. Those devices may have
a single firmware upgrade, provided by the manufacturer, that updates
all capabilities at once. This means that the vendor assumes the
responsibility of making sure their devices have an up-to-date and
secure NTP implementation.
Vendors of embedded devices SHOULD include the ability to update the
list of NTP servers used by the device.
There is a catalog of NTP server abuse incidents, some of which
involve embedded devices, on the Wikipedia page for NTP Server Misuse
and Abuse [9].
6.2. Server configuration
Vendors of embedded devices with preconfigured NTP servers need to
carefully consider which servers to use. There are several public-
facing NTP servers available, but they may not be prepared to service
requests from thousands of new devices on the Internet. Vendors MUST
only preconfigure NTP servers that they have permission to use.
Vendors are encouraged to invest resources into providing their own
time servers for their devices to connect to. This may be done
through the NTP Pool Project, as documented in Section 3.6.
Vendors should read [RFC4085], which advises against embedding
globally-routable IP addresses in products, and offers several better
alternatives.
7. NTP over Anycast
Anycast is described in BCP 126 [RFC4786]. (Also see [RFC7094]).
With anycast, a single IP address is assigned to multiple servers,
and routers direct packets to the closest active server.
Anycast is often used for Internet services at known IP addresses,
such as DNS. Anycast can also be used in large organizations to
simplify configuration of many NTP clients. Each client can be
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configured with the same NTP server IP address, and a pool of anycast
servers can be deployed to service those requests. New servers can
be added to or taken from the pool, and other than a temporary loss
of service while a server is taken down, these additions can be
transparent to the clients.
Note well that using a single anycast address for NTP presents its
own potential issues. It means each client will likely use a single
time server source. A key element of a robust NTP deployment is each
client using multiple sources of time. With multiple time sources, a
client will analyze the various time sources, selecting good ones,
and disregarding poor ones. If a single Anycast address is used,
this analysis will not happen. This can be mitigated by creating
multiple, separate anycast pools so clients can have multiple sources
of time while still gaining the configuration benefits of the anycast
pools.
If clients are connected to an NTP server via anycast, the client
does not know which particular server they are connected to. As
anycast servers enter and leave the network, or the network topology
changes, the server a particular client is connected to may change.
This may cause a small shift in time from the perspective of the
client when the server it is connected to changes. In extreme cases
where the network topology is changing rapidly, this could cause the
server seen by a client to rapidly change as well, which can lead to
larger time inaccuracies. It is RECOMMENDED that network operators
only deploy anycast NTP in environments where operators know these
small shifts can be tolerated by the applications running on the
clients being synchronized in this manner.
Configuration of an anycast interface is independent of NTP. Clients
will always connect to the closest server, even if that server is
having NTP issues. It is RECOMMENDED that anycast NTP
implementations have an independent method of monitoring the
performance of NTP on a server. If the server is not performing to
specification, it should remove itself from the Anycast network. It
is also RECOMMENDED that each Anycast NTP server have an alternative
method of access, such as an alternate Unicast IP address, so its
performance can be checked independently of the anycast routing
scheme.
One useful application in large networks is to use a hybrid unicast/
anycast approach. Stratum 1 NTP servers can be deployed with unicast
interfaces at several sites. Each site may have several Stratum 2
servers with two ethernet interfaces, or a single interface which can
support multiple addresses. One interface has a unique unicast IP
address. The second has an anycast IP interface (with a shared IP
address per location). The unicast interfaces can be used to obtain
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time from the Stratum 1 servers globally (and perhaps peer with the
other Stratum 2 servers at their site). Clients at each site can be
configured to use the shared anycast address for their site,
simplifying their configuration. Keeping the anycast routing
restricted on a per-site basis will minimize the disruption at the
client if its closest anycast server changes. Each Stratum 2 server
can be uniquely identified on their unicast interface, to make
monitoring easier.
8. Acknowledgments
The authors wish to acknowledge the contributions of Sue Graves,
Samuel Weiler, Lisa Perdue, Karen O'Donoghue, David Malone, Sharon
Goldberg, Martin Burnicki, Miroslav Lichvar, Daniel Fox Franke,
Robert Nagy, and Brian Haberman.
9. IANA Considerations
This memo includes no request to IANA.
10. Security Considerations
Time is a fundamental component of security on the internet. The
absence of a reliable source of current time subverts many common web
authentication schemes, e.g., by allowing the use of expired
credentials or by allowing for replay of messages only intended to be
processed once.
Much of this document directly addresses how to secure NTP servers.
In particular, see Section 2, Section 4, and Section 5.
There are several general threats to time synchronization protocols
which are discussed in [RFC7384].
[I-D.ietf-ntp-using-nts-for-ntp] specifies the Network Time Security
(NTS) mechanism and applies it to NTP. Readers are encouraged to
check the status of the draft, and make use of the methods it
describes.
11. References
11.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<https://www.rfc-editor.org/info/rfc2119>.
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[RFC2827] Ferguson, P. and D. Senie, "Network Ingress Filtering:
Defeating Denial of Service Attacks which employ IP Source
Address Spoofing", BCP 38, RFC 2827, DOI 10.17487/RFC2827,
May 2000, <https://www.rfc-editor.org/info/rfc2827>.
[RFC4085] Plonka, D., "Embedding Globally-Routable Internet
Addresses Considered Harmful", BCP 105, RFC 4085,
DOI 10.17487/RFC4085, June 2005,
<https://www.rfc-editor.org/info/rfc4085>.
[RFC4786] Abley, J. and K. Lindqvist, "Operation of Anycast
Services", BCP 126, RFC 4786, DOI 10.17487/RFC4786,
December 2006, <https://www.rfc-editor.org/info/rfc4786>.
[RFC5905] Mills, D., Martin, J., Ed., Burbank, J., and W. Kasch,
"Network Time Protocol Version 4: Protocol and Algorithms
Specification", RFC 5905, DOI 10.17487/RFC5905, June 2010,
<https://www.rfc-editor.org/info/rfc5905>.
[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
May 2017, <https://www.rfc-editor.org/info/rfc8174>.
11.2. Informative References
[CCR16] Malhotra, A. and S. Goldberg, "Attacking NTP's
Authenticated Broadcast Mode", SIGCOMM Computer
Communications Review (CCR) , 2016.
[CVE-2015-8138]
Van Gundy, M. and J. Gardner, "NETWORK TIME PROTOCOL
ORIGIN TIMESTAMP CHECK IMPERSONATION VULNERABILITY", 2016,
<http://www.talosintel.com/reports/TALOS-2016-0077>.
[CVE-2015-8139]
Van Gundy, M., "NETWORK TIME PROTOCOL NTPQ AND NTPDC
ORIGIN TIMESTAMP DISCLOSURE VULNERABILITY", 2016,
<http://www.talosintel.com/reports/TALOS-2016-0078>.
[CVE-2016-1548]
Gardner, J. and M. Lichvar, "Xleave Pivot: NTP Basic Mode
to Interleaved", 2016,
<http://blog.talosintel.com/2016/04/
vulnerability-spotlight-further-ntpd_27.html>.
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[I-D.ietf-ntp-data-minimization]
Franke, D. and A. Malhotra, "NTP Client Data
Minimization", draft-ietf-ntp-data-minimization-04 (work
in progress), March 2019.
[I-D.ietf-ntp-mac]
Malhotra, A. and S. Goldberg, "Message Authentication Code
for the Network Time Protocol", draft-ietf-ntp-mac-06
(work in progress), January 2019.
[I-D.ietf-ntp-mode-6-cmds]
Haberman, B., "Control Messages Protocol for Use with
Network Time Protocol Version 4", draft-ietf-ntp-mode-
6-cmds-06 (work in progress), September 2018.
[I-D.ietf-ntp-using-nts-for-ntp]
Franke, D., Sibold, D., Teichel, K., Dansarie, M., and R.
Sundblad, "Network Time Security for the Network Time
Protocol", draft-ietf-ntp-using-nts-for-ntp-17 (work in
progress), February 2019.
[IMC14] Czyz, J., Kallitsis, M., Gharaibeh, M., Papadopoulos, C.,
Bailey, M., and M. Karir, "Taming the 800 Pound Gorilla:
The Rise and Decline of NTP DDoS Attacks", Internet
Measurement Conference , 2014.
[MILLS2006]
Mills, D., "Computer network time synchronization: the
Network Time Protocol", CRC Press , 2006.
[NDSS14] Rossow, C., "Amplification Hell: Revisiting Network
Protocols for DDoS Abuse", NDSS'14, San Diego, CA. , 2014.
[NDSS16] Malhotra, A., Cohen, I., Brakke, E., and S. Goldberg,
"Attacking the Network Time Protocol", NDSS'16, San Diego,
CA. , 2016, <https://eprint.iacr.org/2015/1020.pdf>.
[RFC1305] Mills, D., "Network Time Protocol (Version 3)
Specification, Implementation and Analysis", RFC 1305,
DOI 10.17487/RFC1305, March 1992,
<https://www.rfc-editor.org/info/rfc1305>.
[RFC5906] Haberman, B., Ed. and D. Mills, "Network Time Protocol
Version 4: Autokey Specification", RFC 5906,
DOI 10.17487/RFC5906, June 2010,
<https://www.rfc-editor.org/info/rfc5906>.
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[RFC6151] Turner, S. and L. Chen, "Updated Security Considerations
for the MD5 Message-Digest and the HMAC-MD5 Algorithms",
RFC 6151, DOI 10.17487/RFC6151, March 2011,
<https://www.rfc-editor.org/info/rfc6151>.
[RFC7094] McPherson, D., Oran, D., Thaler, D., and E. Osterweil,
"Architectural Considerations of IP Anycast", RFC 7094,
DOI 10.17487/RFC7094, January 2014,
<https://www.rfc-editor.org/info/rfc7094>.
[RFC7384] Mizrahi, T., "Security Requirements of Time Protocols in
Packet Switched Networks", RFC 7384, DOI 10.17487/RFC7384,
October 2014, <https://www.rfc-editor.org/info/rfc7384>.
11.3. URIs
[1] https://blog.cloudflare.com/technical-details-behind-a-400gbps-
ntp-amplification-ddos-attack/
[2] http://www.bcp38.info
[3] http://www.pool.ntp.org/en/use.html
[4] http://www.pool.ntp.org/en/vendors.html
[5] https://en.wikipedia.org/wiki/Solar_time#Mean_solar_time
[6] https://www.iers.org/IERS/EN/Publications/Bulletins/
bulletins.html
[7] https://en.wikipedia.org/wiki/Solar_time#Mean_solar_time
[8] https://lists.ntp.org/pipermail/ntpwg/2011-August/001714.html
[9] https://en.wikipedia.org/wiki/NTP_server_misuse_and_abuse
[10] http://www.ntp.org/downloads.html
[11] http://bk1.ntp.org/ntp-stable/README.leapsmear?PAGE=anno
[12] https://support.ntp.org/bin/view/Support/ConfiguringNTP
Appendix A. Best Practices specific to the Network Time Foundation
implementation
The Network Time Foundation (NTF) provides a widely used
implementation of NTP, known as ntpd [10]. It is an evolution of the
first NTP implementations developed by David Mills at the University
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of Delaware. This appendix contains additional recommendations
specific to this implementation that are valid at the time of this
writing.
A.1. Use enough time sources
In addition to the recommendation given in Section 3.2 the ntpd
implementation provides the 'pool' directive. Starting with ntp-
4.2.6, using this directive in the ntp.conf file will spin up enough
associations to provide robust time service, and will disconnect poor
servers and add in new servers as-needed. The 'minclock' and
'maxclock' options of the 'tos' command may be used to override the
default values of how many servers are discovered through the 'pool'
directive.
A.2. NTP Control and Facility Messages
In addition to NTP Control Messages the ntpd implementation also
offers the Mode 7 commands for monitoring and configuration.
If Mode 7 has been explicitly enabled to be used for more than basic
monitoring it should be limited to authenticated sessions that
provide a 'requestkey'.
As mentioned above, there are two general ways to use Mode 6 and Mode
7 requests. One way is to query ntpd for information, and this mode
can be disabled with:
restrict ... noquery
The second way to use Mode 6 and Mode 7 requests is to modify ntpd's
behavior. Modification of ntpd's configuration requires an
authenticated session by default. If no authentication keys have
been specified no modifications can be made. For additional
protection, the ability to perform these modifications can be
controlled with:
restrict ... nomodify
Users can prevent their NTP servers from considering query/
configuration traffic by default by adding the following to their
ntp.conf file:
restrict default -4 nomodify notrap nopeer noquery
restrict default -6 nomodify notrap nopeer noquery
restrict source nomodify notrap noquery
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A.3. Monitoring
The ntpd implementation allows remote monitoring. Access to this
service is generally controlled by the "noquery" directive in NTP's
configuration file (ntp.conf) via a "restrict" statement. The syntax
reads:
restrict address mask address_mask noquery
If a system is using broadcast mode and is running ntp-4.2.8p6 or
later, use the 4th field of the ntp.keys file to specify the IPs of
machines that are allowed to serve time to the group.
A.4. Leap Second File
The use of leap second files requires ntpd 4.2.6 or later. After
fetching the leap seconds file onto the server, add this line to
ntpd.conf to apply and use the file, substituting the proper path:
leapfile "/path/to/leap-file"
There may need to restart ntpd to apply this change.
ntpd servers with a manually configured leap second file will ignore
leap second information broadcast from upstream NTP servers until the
leap second file expires. If no valid leap second file is available
then a leap second notification from an attached reference clock is
always accepted by ntpd.
If no valid leap second file is available, a leap second notification
may be accepted from upstream NTP servers. As of ntp-4.2.6, a
majority of servers must provide the notification before it is
accepted. Before 4.2.6, a leap second notification would be accepted
if a single upstream server of a group of configured servers provided
a leap second notification. This would lead to misbehavior if single
NTP servers sent an invalid leap second warning, e.g. due to a faulty
GPS receiver in one server, but this behavior was once chosen because
in the "early days" there was a greater chance that leap second
information would be available from a very limited number of sources.
A.5. Leap Smearing
Leap Smearing was introduced in ntpd versions 4.2.8.p3 and 4.3.47, in
response to client requests. Support for leap smearing is not
configured by default and must be added at compile time. In
addition, no leap smearing will occur unless a leap smear interval is
specified in ntpd.conf . For more information, refer to
http://bk.ntp.org/ntp-stable/README.leapsmear?PAGE=anno [11].
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A.6. Configuring ntpd
See https://support.ntp.org/bin/view/Support/ConfiguringNTP [12] for
additional information on configuring ntpd.
A.7. Pre-Shared Keys
Each communication partner must add the key information to their key
file in the form:
keyid type key
where "keyid" is a number between 1 and 65534, inclusive, "type" is
an ASCII character which defines the key format, and "key" is the key
itself.
An ntpd client establishes a protected association by appending the
option "key keyid" to the server statement in ntp.conf:
server address key keyid
substituting the server address in the "address" field and the
numerical keyid to use with that server in the "keyid" field.
A key is deemed trusted when its keyid is added to the list of
trusted keys by the "trustedkey" statement in ntp.conf.
trustedkey keyid_1 keyid_2 ... keyid_n
Starting with ntp-4.2.8p7 the ntp.keys file accepts an optional 4th
column, a comma-separated list of IPs that are allowed to serve time.
Use this feature. Note, however, that an adversarial client that
knows the symmetric broadcast key could still easily spoof its source
IP to an IP that is allowed to serve time. (This is easy to do
because the origin timestamp on broadcast mode packets is not
validated by the client. By contrast, client/server and symmetric
modes do require origin timestamp validation, making it more
difficult to spoof packets [CCR16]).
Authors' Addresses
Denis Reilly (editor)
Orolia USA
1565 Jefferson Road, Suite 460
Rochester, NY 14623
US
Email: denis.reilly@orolia.com
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Harlan Stenn
Network Time Foundation
P.O. Box 918
Talent, OR 97540
US
Email: stenn@nwtime.org
Dieter Sibold
Physikalisch-Technische Bundesanstalt
Bundesallee 100
Braunschweig D-38116
Germany
Phone: +49-(0)531-592-8420
Fax: +49-531-592-698420
Email: dieter.sibold@ptb.de
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