Internet-Draft Automatic Stub Networks November 2022
Lemon Expires 14 May 2023 [Page]
Workgroup:
Internet Engineering Task Force
Published:
Intended Status:
Best Current Practice
Expires:
Author:
T. Lemon
Apple Inc.

Automatically Connecting Stub Networks to Unmanaged Infrastructure

Abstract

This document describes a set of practices for connecting stub networks to adjacent infrastructure networks. This is applicable in cases such as constrained (Internet of Things) networks where there is a need to provide functional parity of service discovery and reachability between devices on the stub network and devices on an adjacent infrastructure link (for example, a home network).

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 14 May 2023.

Table of Contents

1. Introduction

This document describes a set of practices for connecting stub networks to adjacent infrastructure networks. There are several use cases for stub networks. Motivating factors include:

What makes stub networks a distinct type of network is simply that a stub network never provides transit between networks to which it is connected. The term "stub" refers to the way the network is seen by the link to which it is connected: there is reachability through a stub network router to devices on the stub network from the infrastructure link, but there is no reachability through the stub network to any link beyond that one.

Eliminating transit routing is not intended to be seen as a virtue in itself, but rather as a simplifying assumption that makes it possible to solve a subset of the general problem of automating multi-link networks. Stub networks may be globally reachable, or may be only locally reachable. This document addresses local reachability. A host on a locally reachable stub network can only interoperate with hosts on the network link(s) to which it is connected.

It may be noted that just as you can plug several home routers together in series to form multi-layer NATs, there is nothing preventing the owner of a stub network router from plugging it into another stub network router. In the case of an IoT wireless network, there may be no way to do this, nor would it be desirable, but a stub router that uses ethernet on both the infrastructure and stub network sides could be connected this way. Nothing in this document is intended to prevent this from being done, but neither do we attempt to solve the problems that this could create.

The goal of this document is to describe the minimal set of changes or behaviors required to use existing IETF specifications to support the stub network use case. The result is intended to be deployable on existing networks without requiring changes to those networks.

1.1. Interoperability Goals

The goal here is for hosts on the stub network to be able to interoperate with hosts on the adjacent infrastructure link or links. What we mean by "interoperate" is that a host on a stub network:

  • is discoverable by hosts attached to adjacent infrastructure links
  • is able to discover hosts attached to adjacent infrastructure links
  • is able to discover hosts on the Internet
  • is able to acquire an IP address that can be used to communicate with hosts attached to adjacent infrastructure links
  • has reachability to the hosts attached to adjacent infrastructure links
  • is reachable by hosts on the adjacent infrastructure link
  • is able to reach hosts on the Internet

Discoverability here means "discoverable using DNS, or DNS Service Discovery". DNS Service Discovery includes multicast DNS [RFC6762]. As an example, when one host connected to a specific WiFi network wishes to discover services on hosts connected to that same WiFi network, it can do so using multicast DNS. Similarly, when a host on some other network wishes to discover the same service, it must use DNS-based DNS Service Discovery [RFC6763]. In both cases, "discoverable using DNS" means that the host has an entry in the DNS.

We lump discoverability in with reachability and addressability, both of which are essentially Layer 3 issues. The reason for this is that it does us no good to automatically set up connectivity between stub network hosts and infrastructure hosts if the infrastructure hosts have no means to learn about the availability of services provided by stub network hosts. For stub network hosts that only consume cloud services this will not be an issue, but for stub networks that provide services, such as IoT devices on stub networks with incompatible media, discoverability is necessary in order for stub network connectivity to be useful.

Ability to acquire an IP address that can be used to communicate means that the IP address a host on the stub network acquires can be used to communicate with it by hosts on adjacent links, for locally reachable stub networks.

Reachability to hosts on adjacent links means that when a host (A) on the stub network has the IP address of such a host (B), with which it intends to communicate, host (A) knows of a next-hop router to which it can send datagrams, so that they will ultimately reach host (B).

Reachability from hosts on adjacent links means that when host (A) on an adjacent link has a datagram destined for the IP address of a host (B) on the stub network, a next-hop router is known by host (A) such that, when the datagram is sent to that router, it will ultimately reach host (B) on the stub network.

1.2. Usability Goals

In addition to the interoperability goals we've described above, the additional goal for stub networks is that they be able to be connected automatically, with no user intervention. The experience of connecting a stub network to an infrastructure should be as straightforward as connecting a new host to the same infrastructure network.

2. Glossary

Addressability
The ability to associate each node on a link with its own IPv6 address.
Reachability
Given an IPv6 destination address that is not on-link for any link to which a node is attached, the information required that allows the node to send packets to a router that can forward those packets towards a link where the destination address is on-link.
Infrastructure network
the network infrastructure to which a stub router connects. This network can be a single link, or a network of links. The network may also provide some services, such as a DNS resolver, a DHCPv4 server, and a DHCPv6 prefix delegation server, for example.
Adjacent infrastructure link
any link to which a stub network router is directly attached, that is part of an infrastructure network and is not the stub network.
Off-Stub-Network-Routable (OSNR) Prefix
a prefix advertised on the stub network that can be used for communication with hosts not on the stub network.

3. Constants

This section describes the meaning of and gives default values for various constants used in this document.

STALE_RA_TIME
Default: 10 minutes. The amount of time that can pass after the last time a router advertisement from a particular has been received before we assume the router is no longer present. This is a stopgap in case the router is reachable but has silently stopped advertising a prefix; this situation is unlikely, but if it does happen, new devices joining the infrastructure network will not be able to reach devices on the stub network until the stub router decides that the router that advertised the usable prefix is stale.
STUB_PROVIDED_PREFIX_LIFETIME
Default: 30 minutes. The valid and preferred lifetime the stub router will advertise. This needs to be long enough that a host is actually willing to use it, and obviously should also be long enough that a missed beacon will not cause the host to stop using it. The values suggested here allow ten beacons to be missed before the host will stop using the prefix.
BEACON_INTERVAL
Default: 3 minutes. How often the stub router will transmit an RA. This should be frequent enough that a missed Router Solicit (e.g. due to congestion on a WiFi link) will not result in an extremely long outage (assuming the congestion passes before the beacon is sent, of course).
PREFIX_DELEGATION_INTERVAL
Default: 30 minutes. The lifetime a stub router should request for a DHCPv6-delegated prefix. The longer this is, the more prefixes will be consumed on a network where stub routers are not stable. The lifetime here is chosen to be long enough that a reboot of the DHCP server will not prevent the prefix being renewed. It happens to coincide with the value of STUB_PROVIDED_PREFIX_LIFETIME, but the two should not be considered to be equivalent.
MAX_USABLE_REACHABLE_TIME
Default: 60 seconds. The maximum ReachableTime value that a router can have in the Neighbor Table before any usable prefixes it has advertised are no longer considered usable.

4. Conventions and Terminology Used in This Document

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.

5. Support for adjacent infrastructure links

We assume that the adjacent infrastructure link supports Neighbor Discovery [RFC4861], and specifically that routers and on-link prefixes can be advertised using router advertisements and discovered using neighbor solicits. The stub network link may also support this, or may use some different mechanism. This section specifies how advertisement of the on-link prefix for such links is managed. In this section we will use the term "Advertising Interface" as described in Section 6.2.2 of [RFC4861].

Support for adjacent infrastructure links on networks where Neighbor Discovery is not supported are out of scope for this document. Stub routers do not provide routing between adjacent infrastructure links when connected to more than one such link.

5.1. Managing addressability on an adjacent infrastructure link

In order to provide IPv6 routing to the stub network, IPv6 addressing must be available on each adjacent infrastructure link. Ideally such addressing is already present on these links, and need not be provided. However, if it is not present, the stub router must provide it.

IPv6 addressing is considered to be present on the link if a usable on-link prefix is advertised on the adjacent infrastructure link. A usable on-link prefix is a prefix advertised on the link that has a preferred time of 30 minutes or more, is marked on-link and allows autonomous configuration.

A prefix is not considered a usable on-link prefix if it is advertised on the link as on-link, but the 'm' bit is set in the Router Advertisement message header ([RFC4861], Section 4.2) that contains the Prefix option. This indicates that node addressibility is being managed using DHCPv6. Nodes are not required to use DHCPv6 to acquire addresses, so a prefix that requires the use of DHCPv6 can't be considered "usable"-not all hosts can actually use it.

A prefix is considered to be advertised on the link if, when a Router Solicit message ([RFC4861], Section 4.1) is sent, a Router Advertisement message is received in response which contains a prefix information option ([RFC4861], Section 4.6.2) for that prefix.

After an RA message containing a usable prefix has been received, it can be assumed for some period of time thereafter that the prefix is still valid on the link. However, prefix lifetimes and router lifetimes are often quite long. In addition to knowing that a prefix has been advertised on the link in the past, and is still valid, we must therefore ensure that at least one router that has advertised this prefix is still alive to respond to router advertisements.

5.1.2. State Machine for maintaining a usable on-link prefix on an infrastructure link

The possible states of an interface connected to an adjacent infrastructure link are described here, along with actions required to be taken to monitor the state. The purpose of the state machine described here is to ensure that at all times, when a new host arrives on the adjacent infrastructure link, it is able to acquire an IPv6 address on that link.

5.1.2.1. Status of IP addressability on adjacent infrastructure link unknown (STATE-UNKNOWN)

When the stub router interface first connects to the adjacent infrastructure link, it MUST begin router discovery.

If, after router discovery has completed, no usable on-link prefix has been found, the router moves this interface to STATE-BEGIN-ADVERTISING (Section 5.1.2.3).

If, during router discovery, a usable on-link prefix is found, the router moves the interface to STATE-USABLE (Section 5.1.2.2).

In this state, the stub router MUST NOT treat this interface as an advertising interface as described in Section 6.2.2 of [RFC4861].

5.1.2.2. IP addressability already present on adjacent infrastructure link (STATE-USABLE)

When entering this state, if the router MUST discontinue treating the interface as an Advertising Interface as described in Section 6.2.2 of [RFC4861], if it has been doing so.

When a new host appears on the adjacent infrastructure link and sends an initial router solicit, if it does not receive a usable on-link prefix, it will not be able to communicate. Consequently, the stub router MUST monitor router solicits and advertisements on the interface in order to determine whether a prefix that has been advertised on the link is still being advertised. To accomplish this we have two complementary methods: router staleness detection and neighbor unreachability detection.

5.1.2.2.1. Router staleness detection

The stub router MUST listen for router advertisements on the adjacent infrastructure link to which the interface is attached, and record the time at which each router advertisement was received. The router MUST NOT consider any router advertisement that is older than STALE_RA_TIME to be usable. When the last non-stale router advertisement containing a usable prefixes on the link is marked stale, the stub router MUST move the interface to STATE-BEGIN-ADVERTISING.

5.1.2.2.2. Router Unreachability Detection

For each usable route, the stub router MUST monitor the state of reachability to the router(s) that advertised it as described in ([RFC4861], Section 7.3.1) using a ReachableTime value of no more than MAX_USABLE_REACHABLE_TIME. The reason for this is that if no router providing the on-link prefix on the infrastructure link is reachable, then when a new host joins the network, it will have no usable on-link prefix to use for autoconfiguration, and thus will be unable to communicate with hosts on the stub network.

Whenever the ReachableTime for a router advertising a usable prefix exceeds MAX_USABLE_REACHABLE_TIME, the stub router MUST send unicast neighbor solicits as described in Section 7.2.2 of [RFC4861] until either a response is received, which resets ReachableTime to zero, or the maximum number of retransmissions has been sent.

The stub router MUST listen for router solicits on the adjacent infrastructure link. When a router solicit is received, if none of the on-link routers on the adjacent infrastructure link are marked reachable, the stub router MUST move this interface to the STATE-BEGIN-ADVERTISING state (Section 5.1.2.3).

If a beacon interval arrives, and there are no routers advertising usable prefixes that have a ReachableTime that is less than MAX_USABLE_REACHABLE_TIME, then the router MUST move this interface to the STATE-BEGIN-ADVERTISING state.

5.1.2.3. IP addressability not present on adjacent infrastructure link (STATE-BEGIN-ADVERTISING)

In this state, the stub router generates its own on-link prefix for the interface. This prefix has a valid and preferred lifetime of STUB_PROVIDED_PREFIX_LIFETIME seconds. The stub router sends a router advertisement containing this prefix. The 'A' (autonomous configuration), 'L' (on-link) Section 4.6.2 of [RFC4861] and the Stub Router bit ([I-D.hui-stub-router-ra-flag]) MUST be set in the prefix header.

This router advertisement MUST also include a Route Information Option (Section 2.3 of [RFC4191]) for each routable prefix advertised on the stub network. If the stub router is also a normal router (e.g. a home WiFi router), it SHOULD include all other routes that it is advertising in the RA, if there is space.

After having sent the initial router advertisement, the stub router moves the interface into the STATE-ADVERTISING-USABLE state (Section 5.1.2.4).

5.1.2.4. IP addressability not present on adjacent infrastructure link (STATE-ADVERTISING-USABLE)

When entering this state, if the router MUST begin treating the interface as an Advertising Interface as described in Section 6.2.2 of [RFC4861] if it is not already doing so.

The stub router sends a router advertisement message, as described in Section 5.1.2.3, every BEACON_INTERVAL seconds.

The stub router may receive a router advertisement containing a usable on-link prefix on the adjacent infrastructure link. If the advertised prefix is different than the prefix the stub router is advertising as the on-link usable prefix, and the Stub Router bit is not set in the prefix option for the prefix, the stub router moves the interface to STATE-DEPRECATING (Section 5.1.2.5).

If the stub router bit is set in the received prefix, then one of the following must be true:

  • The prefixes are equal. In this case, the interface remains in STATE-ADVERTISING-USABLE.
  • The prefix the stub router is advertising is a ULA [RFC4193], and the received prefix is a non-ULA prefix. In this case, the interface moves into the STATE-DEPRECATING (Section 5.1.2.5) state.
  • Both prefixes are ULA prefixes, and the received prefix, considered as a 128-bit big-endian unsigned integer, is numerically lower, then the interface moves to STATE-DEPRECATING (Section 5.1.2.5.
  • Otherwise the interface remains in STATE-ADVERTISING-USABLE.
5.1.2.5. Stub router deprecating its on-link prefix (STATE-DEPRECATING)

On entry to this state, the stub router has been treating the interface as an Advertising Interface as described in Section 6.2.2 of [RFC4861], and MUST continue to do so.

When the stub router has detected the availability of usable on-link prefix on the adjacent infrastructure link to which the interface is attached, and that prefix is preferable to the one it is advertising, it continues to advertise its own prefix, but deprecates it:

  • the preferred lifetime for its prefix should be set to zero in subsequent router advertisement messages.
  • the valid lifetime for its prefix should be reduced with each subsequent router advertisement messages.
  • the usability of the infrastructure-provided on-link prefix should be monitored as in the STATE-USABLE state; if during the deprecation period, the stub router detects that there are no longer any usable prefixes on the link, as described in Section 5.1.2.2.1 or in Section 5.1.2.2.2, it MUST return the interface to the STATE-BEGIN-ADVERTISING (Section 5.1.2.4) state and resume advertising its prefix with the valid and preferred lifetimes described there.

In this state, the valid lifetime (VALID) is computed based on three values: the current time when a router advertisement is being generated (NOW), the time at which the new usable on-link prefix advertisement was received (DEPRECATE_TIME), and STUB_PROVIDED_PREFIX_LIFETIME. All of these values are in seconds. VALID is computed as follows:

VALID = STUB_PROVIDED_PREFIX_LIFETIME - (NOW - DEPRECATE_TIME)

If VALID is less than BEACON_INTERVAL, the stub router does not include the deprecated prefix in the router advertisement. Note that VALID could be less than zero. Otherwise, the prefix is provided in the advertisement, but with a valid lifetime of VALID.

5.2. Managing addressability on the stub network

How addressability is managed on stub networks depends on the nature of the stub network. For some stub networks, the stub router can be sure that it is the only router. For example, a stub router that is providing a Wi-Fi network for tethering will advertise its own SSID and use its own joining credentials; in this case, it can assume that it is the only router for that network, and advertise a default route and on-link prefix just like any other router.

However, some stub networks are more cooperative in nature, for example IP mesh networks. On such networks, multiple stub routers may be present and be providing addressability and reachability.

In either case, some stub router connected to the stub network MUST provide a usable on-link prefix (the OSNR prefix) for the stub network. If the stub network is a multicast-capable medium where Router Advertisements are used for router discovery, the same mechanism described in Section 5.1.2 is used.

Stub networks that do not support the use of Router Advertisements for router discovery must use some similar mechanism that is compatible with that type of network. Describing the process of establishing a common OSNR prefix on such networks is out of scope for this document.

5.2.1. Maintenance across stub router restarts

Stub routers may restart from time to time; when a restart occurs, the stub router may have been advertising state to the network which, following the restart, is no longer required.

For example, suppose there are two stub routers connected to the same infrastructure link. When the first stub router is restarted, the second takes over providing an on-link prefix. Now the first router rejoins the link. It sees that the second stub router's prefix is advertised on the infrastructure link, and therefore does not advertise its own.

This behavior can cause problems because the first stub router no longer sees the on-link prefix it had been advertising on infrastructure as on-link. Consequently, if it receives a packet to forward to such an address, it will forward that packet directly to a default router, if one is present; otherwise, it will have no route to the destination, and will drop the packet.

To address this problem, stub routers SHOULD remember the last time a prefix was advertised across restarts. On restart, the router can immediately begin deprecating the prefix, and can stop after the prefix valid lifetime goes to zero, based on the recorded time that the last advertisement was sent.

When a stub router has only flash memory with limited write lifetime, it may be inappropriate to do a write to flash every time a prefix beacon happens. In this case, the router SHOULD record the set of prefixes that have been advertised on infrastructure and the maximum valid lifetime that was advertised. On restart, the router should assume that hosts on the infrastructure link have received advertisements for any such prefixes, and should immediately deprecate them, and continue to do so until the maximum valid lifetime has elapsed after restart.

[WG: we could actually just not advertise the prefix, rather than deprecating it. In this case, the host should wind up preferring some other prefix for new connections anyway, because it will have a later preferred lifetime expiry. As long as we remember the route and resume forwarding for it, existing connections can continue until the prefix becomes invalid.

5.2.2. Generating a ULA prefix to provide addressability

In order to be able to provide addressability either on the stub network or on an adjacent infrastructure network, a stub router must allocate its own ULA prefix. ULA prefixes, described in Unique Local IPv6 Unicast Addresses ([RFC4193]) are randomly allocated prefixes. A stub router MUST allocate a single ULA prefix for use in providing on-link prefixes to the stub network and the infrastructure network, as needed.

The ULA prefix allocated by a stub router SHOULD be maintained across reboots, and SHOULD remain stable over time. For privacy reasons, a stub router that roams from network to network may wish to allocate a different ULA prefix each time it connects to a different infrastructure network.

If IPv6 prefix delegation is available, which implies that IPv6 service is also available on the infrastructure link, then the stub router MAY use IPv6 prefix delegation to acquire a prefix to advertise on the stub network, rather than allocating one out of its ULA prefix.

5.2.3. Using DHCPv6 Prefix Delegation to acquire a prefix to provide addressability

If DHCPv6 PD is available on the link, it is preferable to acquire a prefix using DHCPv6 PD rather than generating a ULA prefix, because the DHCPv6-PD-provided prefix is routable at least on the local infrastructure. Therefore, when DHCPv6-PD is available, the BR MUST use DHCPv6 PD rather than its own prefix.

5.3. Managing reachability on the adjacent infrastructure link

Stub routers MUST advertise reachability to stub network OSNR prefixes on any AIL to which they are connected. If the stub router is advertising a usable prefix on any interface, any such prefixes MUST be advertised on that interface in the same beacon that is advertising the usable prefix, to avoid unnecessary multicast traffic.

Each stub network will have some set of prefixes that are advertised as on-link for that network. A stub router connected to that network SHOULD advertise reachability to all such prefixes on any AIL to which it is attached using router advertisements

5.4. Managing reachability on the stub network

The stub router MAY advertise itself as a default router on the stub network, if it itself has a default route on the AIL. In some cases it may not be desirable to advertise reachability to the Internet as a whole; in this case the stub router is not required to advertise itself as a default router.

If the stub router is not advertising itself as a default router on the stub network, it MUST advertise reachability to any prefixes that are being advertised as on-link on AILs to which it is attached. This is true for prefixes it is advertising, and for other prefixes being advertised on that link.

Note that in some stub network configurations, it is possible for more than one stub router to be connected to the stub network, and each stub router may be connected to a different AIL. In this case, a stub router advertising a default route may receive a packet destined for a link that is not an AIL for that router, but is an AIL for a different router. In such a case, if the infrastructure is not capable of routing between these two AILs, a packet which could have been delivered by another stub router will be lost by the stub router that received it.

Consequently, stub routers SHOULD be configurable to not advertise themselves as default routers on the stub network. Stub routers SHOULD be configurable to explicitly advertise AIL prefixes on the stub network even if they are advertising as a default router. The mechanisms by which such configuration can be accomplished are out of scope for this document.

It is also possible that stub routers for more than one stub network may be connected to the same adjacent infrastructure link. In this case, the stub routers will be advertising Router Information Options in their router advertisements for their OSNR prefixes. Stub routers MUST track the presence of such routes, and MUST advertise reachability to them on interfaces connected to stub networks.

5.5. Providing discoverability between stub network links and infrastructure network links

Since DNS-SD is in wide use, and provides for ad-hoc, self-configuring advertising using the mDNS transport, this is a suitable mandatory-to-implement protocol for stub networks, which must be able to attach to infrastructure networks without the help of new mechanisms provided by the infrastructure. Therefore, stub routers MUST provide DNS-SD service as described in this section.

5.5.1. Discoverability by hosts on adjacent infrastructure links

The adjacent infrastructure can be assumed to already enable some service discovery mechanism between hosts on the infrastructure network, and can be assumed to provide a local DNS resolver. Therefore, we do not need to define a stub-network-specific mechanism for providing these services on the infrastructure network.

In some cases it will be necessary for hosts on the adjacent infrastructure link to be able to discover devices on the stub network. In other cases, this will be unnecessary or even undesirable. For example, it may be undesirable for devices on an adjacent infrastructure link to be able to discover devices on a Wi-Fi tether, for example provided by a mobile phone.

One example of a use case for stub networks where such discovery is desirable is the constrained network use case. In this case a low-power, low-cost stub network provides connectivity for devices that provide services to the infrastructure. For such networks, it is necessary that devices on the infrastructure be able to discover devices on the stub network.

The most basic use case for this is to provide feature parity with existing solutions like multicast DNS (mDNS). For example, a light bulb with built-in Wi-Fi connectivity might be discoverable on the infrastructure link to which it is connected, using mDNS, but likely is not discoverable on other links. To provide equivalent functionality for an equivalent device on a constrained network that is a stub network, the stub network device must be discoverable on the infrastructure link (which is an AIL from the perspective of the stub network).

If services are to be advertised using DNS Service Discovery [RFC6763], there are in principle two ways to accomplish this. One is to present services on the stub network as a DNS zone which can then be configured as a browsing domain in the DNS ([RFC6763], Section 11). The second is to advertise stub network services on the AIL using multicast DNS (mDNS) [RFC6762].

Because this document defines behavior for stub routers connecting to infrastructure networks that do not provide any new mechanism for integrating stub networks, there is no way for a stub router to provide DNS-SD service on an infrastructure link in the form of a DNS zone in which to do discovery. Therefore, service on the infrastructure link MUST be provided using an Advertising Proxy, as defined in [I-D.ietf-dnssd-advertising-proxy].

One limitation of this solution is that it requires that hosts on the stub network use the DNS-SD Service Registration Protocol [I-D.ietf-dnssd-srp] to register their DNS-SD advertisements. This means that in the case of a stub network used for WiFi tethering, hosts on the stub network will not be discoverable by hosts on the infrastructure network. Any solution to this problem would require that the stub router provide a Discovery Proxy [RFC8766]. However, a discovery proxy is queried using DNS, not mDNS. This requires assistance from the infrastructure network, and is therefore out of scope for this document.

5.5.2. Providing discoverability of adjacent infrastructure hosts on the stub network

Hosts on the stub network may need to discover hosts on the adjacent infrastructure network, or on the stub network. In the IoT network example we've been using, there might be a light switch on the stub network which needs to be able to actuate a light bulb connected to the adjacent infrastructure network. In order to know where to send the actuation messages, the light switch will need to be able to discover the light bulb's address somehow.

Because the stub network is managed by stub routers, any DNS resolver that's available on the stub network will necessarily be provided by one or more stub routers. This means that the stub router can enable discovery of hosts on the infrastructure network by hosts on the stub network using a Discovery Proxy [RFC8766]. The Discovery Proxy can be advertised as available to hosts on the stub network through the DNS resolver provided on the stub network, as described in Section 11 of [RFC6763].

By implication, this means that stub routers MUST provide a DNS resolver. In addition, stub routers MUST provide DNS zones for each adjacent infrastructure link, and MUST list these zones in the list of default browsing zones as defined in RFC6763. [[WG: we need to say how these zones are named. Or refer to the Advertising Proxy doc and have that doc say how they are named.]]

The stub router MUST also maintain an SRP registrar and use registrations made through that registrar to populate a DNS zone which is advertised as a default browsing domain, as above. This SRP registrar MUST be advertised on the stub network either using the dnssd-srp and/or dnssd-srp-tls service names or some stub-network-specific mechanism, the details of which are out of scope for this document.

6. Providing reachability to IPv4 services to the stub network

6.1. NAT64 provided by infrastructure

Stub networks are defined to be IPv6-only because it would be difficult to implement a stub network using IPv4 technology. However, stub network devices may need to be able to communicate with IPv4-only services either on the adjacent infrastructure, or on the global internet. Ideally, the infrastructure network fully supports IPv6, and all services on the infrastructure network are IPv6-capable. In this case, perhaps the infrastructure network provides NAT64 service to IPv4-only hosts on the internet. In this ideal setting, the stub router need do nothing-the infrastructure network is doing it all.

In this situation, if there are multiple stub routers, each connected to the same adjacent infrastructure link, there is no need for special behavior-each stub router can advertise a default route, and any stub router will do to route NAT64 traffic. If some stub routers are connected to different adjacent infrastructure links than others, some of which support NAT64 and some of which do not, then the default route may not carry traffic to the correct link for NAT64 service. In this case, a more specific address to the infrastructure NAT64 prefix(es) MUST be advertised by those stub routers that are able to discover it.

6.2. NAT64 provided by stub router(s)

Most infrastructure networks at present do not provide NAT64 service. It is therefore necessary for stub routers to be able to provide NAT64 service if IPv4 hosts are to be reachable from the stub network.

To provide NAT64 service, a stub router must allocate a NAT64 prefix. For convenience, the stub network allocates a single prefix out of the /48 ULA prefix that it maintains. Out of the 2^16 possible subnets of the /48, the stub router SHOULD use the numerically highest /64 prefix.

If there are multiple stub routers providing connectivity between the stub network and infrastructure, each stub network uses its own NAT64 prefix-there is no common NAT64 prefix. The reason for this is that NAT64 translation is not stateless, and is tied to the stub router's IPv4 address. Therefore each NAT64 egress is not equivalent.

A stub network that services a Wi-Fi stub network SHOULD provide DNS64 translation: hosts on the stub network cannot be assumed to be able to do DNS64 synthesis in the stub resolver. In this case the DNS resolver on the stub router MUST honor the CD and DO bits if received in a request, since this indicates that the stub resolver on the requestor intends to do DNSSEC validation. In this case, the resolver on the stub router MUST NOT perform DNS64 synthesis.

On specific stub networks it may be desirable to require the stub network device to perform DNS64 synthesis. Stub network routers for such networks do not need to provide DNS64 synthesis. Instead, they MUST provide an ipv4only.arpa answer that advertises the NAT64 prefix for that stub router, and MUST provide an explicit route to that NAT64 prefix on the stub network using RA or whatever technology is specific to that stub network type.

In constrained networks it can be very useful if stub network resolvers provide the information required to do DNS64 translation in the answer to the AAAA query. If the answer to an AAAA query comes back with "no data" (not NXDOMAIN), this suggests that there may be an A record. In this case, the stub network's resolver SHOULD attempt to look up an A record on the same name. If such a record exists, the resolver SHOULD return no data in the Answer section of the DNS response, and SHOULD provide any CNAME records that were involved in returning the "no data" answer to the AAAA query, and SHOULD provide any A records that were ultimately returned, in the Additional section. The resolver should also include an ipv4only.arpa record in the Additional section.

7. Handling partitioning events on a stub network

If a stub network is constructed using mesh technology, it may become partitioned. In such a situation, it may be one stub router is connected to one partition, and another stub router is connected to the other partition. In this situation, in order for all nodes to be reachable, it is necessary that each partition of the stub network have its own prefix. When such a partition occurs, the stub routers must detect that it has occurred. If a stub router is currently providing a prefix on the stub network, it need take no action. If a stub router had not been providing a prefix on the stub network, and now discovers that there is no stub router providing a prefix on the network, it MUST begin to provide its own prefix on the stub network. It MUST also advertise reachability to that new prefix on its adjacent infrastructure link(s).

When partitions of this type occur, they may also heal. When a partition heals in a situation where two stub routers have both been advertising a prefix, it will now appear that there are two prefixes on the stub network.

When the time comes to deprecate one or more prefixes as a result of a network partition healing, only one prefix should remain. If there are any GUA prefixes, and if there is no specific configuration contradicting this, the GUA prefix that is numerically lowest should be kept, and all others deprecated. If there are no GUA prefixes, then the ULA prefix that is numerically lowest should be kept, and the others deprecated. By using this approach, it is not necessary for the routers to coordinate in advance.

8. Normative References

[RFC2119]
Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, , <https://www.rfc-editor.org/info/rfc2119>.
[RFC4191]
Draves, R. and D. Thaler, "Default Router Preferences and More-Specific Routes", RFC 4191, DOI 10.17487/RFC4191, , <https://www.rfc-editor.org/info/rfc4191>.
[RFC4193]
Hinden, R. and B. Haberman, "Unique Local IPv6 Unicast Addresses", RFC 4193, DOI 10.17487/RFC4193, , <https://www.rfc-editor.org/info/rfc4193>.
[RFC4861]
Narten, T., Nordmark, E., Simpson, W., and H. Soliman, "Neighbor Discovery for IP version 6 (IPv6)", RFC 4861, DOI 10.17487/RFC4861, , <https://www.rfc-editor.org/info/rfc4861>.
[RFC6762]
Cheshire, S. and M. Krochmal, "Multicast DNS", RFC 6762, DOI 10.17487/RFC6762, , <https://www.rfc-editor.org/info/rfc6762>.
[RFC6763]
Cheshire, S. and M. Krochmal, "DNS-Based Service Discovery", RFC 6763, DOI 10.17487/RFC6763, , <https://www.rfc-editor.org/info/rfc6763>.
[RFC8174]
Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, , <https://www.rfc-editor.org/info/rfc8174>.
[RFC8766]
Cheshire, S., "Discovery Proxy for Multicast DNS-Based Service Discovery", RFC 8766, DOI 10.17487/RFC8766, , <https://www.rfc-editor.org/info/rfc8766>.
[I-D.ietf-dnssd-srp]
Lemon, T. and S. Cheshire, "Service Registration Protocol for DNS-Based Service Discovery", Work in Progress, Internet-Draft, draft-ietf-dnssd-srp-17, , <https://www.ietf.org/archive/id/draft-ietf-dnssd-srp-17.txt>.
[I-D.ietf-dnssd-advertising-proxy]
Cheshire, S. and T. Lemon, "Advertising Proxy for DNS-SD Service Registration Protocol", Work in Progress, Internet-Draft, draft-ietf-dnssd-advertising-proxy-01, , <https://www.ietf.org/archive/id/draft-ietf-dnssd-advertising-proxy-01.txt>.
[I-D.hui-stub-router-ra-flag]
Hui, J., "Stub Router Flag in ICMPv6 Router Advertisement Messages", Work in Progress, Internet-Draft, draft-hui-stub-router-ra-flag-00, , <https://www.ietf.org/archive/id/draft-hui-stub-router-ra-flag-00.txt>.

Author's Address

Ted Lemon
Apple Inc.
One Apple Park Way
Cupertino, California 95014
United States of America