v6ops | J. Linkova |
Internet-Draft | |
Intended status: Informational | December 10, 2019 |
Expires: June 12, 2020 |
Neighbor Cache Entries on First-Hop Routers: Operational Considerations
draft-ietf-v6ops-nd-cache-init-01
Neighbor Discovery (RFC4861) is used by IPv6 nodes to determine the link-layer addresses of neighboring nodes as well as to discover and maintain reachability information. This document discusses how the neighbor discovery state machine on a first-hop router is causing user-visible connectivity issues when a new (not being seen on the network before) IPv6 address is being used.
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The section 7.2.5 of [RFC4861] states: "When a valid Neighbor Advertisement is received (either solicited or unsolicited), the Neighbor Cache is searched for the target's entry. If no entry exists, the advertisement SHOULD be silently discarded. There is no need to create an entry if none exists, since the recipient has apparently not initiated any communication with the target."
This approach is perfectly suitable for host2host communications which are in most cases bi-directional and it could be expected that if a host A has an ND cache entry for the host B IPv6 address, the host B also has the corresponding ND entry for the host A address in its cache. However when a host communicates to off-link destinations via its first-hop router that logic does not apply. The most typical scenario when the problem may arise is a host joining the network, forming a new address and using that address for accessing the Internet:
This scenario illustrates the problem happening when the device connects to the network for the first time or after a timeout long enough for the device address to be removed from the router neighbor cache. However the same sequence of events happen when the host starts using the new GUA previously unseen by the router, such as a new privacy address [RFC4941] or if the router Neighbor Cache has been flushed.
While in dual-stack networks this problem might hidden by Happy Eyeballs [RFC8305] it manifest quite clearly in IPv6-only environments, especially wireless ones, leading to poor user experience and contributing to negative perception of IPv6-only solutions as unstable and non-deployable.
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.
ND: Neighbor Discovery, [RFC4861].
SLAAC: IPv6 Stateless Address Autoconfiguration, [RFC4862].
NS: Neighbor Solicitation, [RFC4861].
NA: Neighbor Advertisement, [RFC4861].
RS: Router Solicitation, [RFC4861].
RA: outer Advertisement, [RFC4861].
SLLA: Source link-layer Address, an option in the ND packets containing the link-layer address of the sender of the packet, [RFC4861].
TLLA: Target link-layer Address, an option in the ND packets containing the link-layer address of the target, [RFC4861].
GUA: Global Unicast Address, [RFC4291].
DAD: Duplicate Address Detection, [RFC4862].
Optimistic DAD: a modification of DAD, [RFC4429].
It would be highly desirable to improve the Neighbor Discovery mechanics so routers have a usable cache entry for a host address by the time the first packet for that address is received by the router. In particular,
The Neighbor Discovery is designed to allow IPv6 nodes to discover neighboring nodes reachability and learn IPv6 to link-layer addresses mapping. Therefore ND seems to be the most appropriate tool to inform the first-hop routers about addresses the host is going to use.
Section 4.4 of [RFC4861] says:
"A node sends Neighbor Advertisements in response to Neighbor Solicitations and sends unsolicited Neighbor Advertisements in order to (unreliably) propagate new information quickly."
Propagating information about new GUA as quickly as possible is exactly what is required to solve the problem outlined in this document. Therefore the host might send an unsolicited NA with the target link-layer address option to advertize its GUA as soon as the said address enters Optimistic or Preferred state.
The proposed solution is discussed in [I-D.linkova-6man-grand]. In summary the follwing changes to [RFC4861] are suggested:
It should be noted that some routing and switching platforms have implemented such behaviour already. Administrators could enable creating neighbor discovery cache entries based on unsolicited NA packets sent from the previously unknown neighbors on that interface.
The problem could be addressed from different angles. Possible approaches are:
The following sections discuss those approaches in more detail.
One of the possible approaches might be to declare that everything is working as intended and let the upper-layer protocols to deal with packet loss. The obvious drawbacks include:
The most radical approach would be to move away from the reactive ND as defined in [RFC4861] and expand the registration-based ND ([RFC6775], [RFC8505]) used in Low-Power Wireless Personal Area Networks (6LoWPANs) to the rest of IPv6 deployments. This option required some investigation and discussions and seems to be an overkill for the problem described in this document.
The host could force creating a STALE entry for its GUA in the router ND cache by sending the following Neighbor Solicitation message:
The main disadvantages of this approach are:
The host could send a router solicitation message to 'all routers' multicast address, using its GUA as a source. If the host link-layer address is included in the Source Link-Layer Address option, the router would create a STALE entry for the host GUA as per the section 6.2.6 of [RFC4861]. However this approach can not be used if the GUA is in optimistic state: the section 2.2 of [RFC4429] explicitly prohibits using an Optimistic Address as the source address of a Router Solicitation with a SLLAO as it might disrupt the rightful owner of the address in the case of a collision. So for the optimistic addresses the host can send an RS without SLLAO included. In that case the router may respond with either a multicast or a unicast RA (only the latter would create a cache entry).
This approach has the following drawbacks:
Routers may be able to learn about new addresses by gleaning from the DAD Neighbor Solicitation messages. The router could listen to all solicited node multicast address groups and upon receiving a Neighbor Solicitation from the unspecified address search its Neighbor Cache for the solicitation's Target Address. If no entry exists the router may create an entry, set its reachability state to 'INCOMPLETE' and start the address resolution for that entry.
The same solution was proposed in [I-D.halpern-6man-nd-pre-resolve-addr]. Some routing vendors support such optimization already. However this approach has a number of drawbacks and therefore should not be used as the only solution:
The host may trigger the router to start the address resolution by sending a data packet such as ping or traceroute to its default router link-local address, using the GUA as a source address. As the RTT to the default gateway is lower than RTT to any off-link destinations it's quite likely that the router would start the neighbor discovery process for the host GUA before the first packet of the returning traffic arrives.
The downside of this approach includes:
When a router receives a transit packet it might check the presence of the neighbor cache entry for the packet source address and if the entry does not exist start address resolution process. This approach does ensure that a Neighbor Cache entry is proactively created every time a new, previously unseen GUA is used for sending offlink traffic. However this functionality needs to be limited to explicitly configured networks/interfaces, as the router needs to distinguish between onlink addresses (ones the router needs to have Neighbor Cache entries for) and the rest of the address space. In addition, implementing such functionality is much more complicated than all other solutions as it would involve complex data-control planes interaction.
This memo asks the IANA for no new parameters.
This memo documents the operational issue and does not introduce any new security considerations. Security considerations of the proposed solution are discussed in the corresponding section of [I-D.linkova-6man-grand].
Thanks to the following people (in alphabetical order) for their review and feedback: Lorenzo Colitti, Igor Gashinsky, Tatuya Jinmei, Erik Kline, Warren Kumari, Michael Richardson, Pascal Thubert, Loganaden Velvindron, Eric Vyncke.
[I-D.halpern-6man-nd-pre-resolve-addr] | Chen, I. and J. Halpern, "Triggering ND Address Resolution on Receiving DAD-NS", Internet-Draft draft-halpern-6man-nd-pre-resolve-addr-00, January 2014. |
[RFC4941] | Narten, T., Draves, R. and S. Krishnan, "Privacy Extensions for Stateless Address Autoconfiguration in IPv6", RFC 4941, DOI 10.17487/RFC4941, September 2007. |
[RFC6583] | Gashinsky, I., Jaeggli, J. and W. Kumari, "Operational Neighbor Discovery Problems", RFC 6583, DOI 10.17487/RFC6583, March 2012. |