DHC Work Group I. Farrer
Internet-Draft Deutsche Telekom AG
Intended status: Standards Track Naveen. Kottapalli
Expires: September 6, 2020 Benu Networks
M. Hunek
Technical University of Liberec
Richard. Patterson
March 5, 2020

DHCPv6 Prefix Delegating Relay
draft-ietf-dhc-dhcpv6-pd-relay-requirements-00

Abstract

Operational experience with DHCPv6 prefix delegation has shown that when the DHCPv6 relay function is not co-located with the DHCPv6 server function, issues such as timer synchronization between the DHCP functional elements, rejection of client's messages by the relay, and other problems have been observed. These problems can result in prefix delegation failing or traffic to/from clients addressed from the delegated prefix being unrouteable. Although [RFC8415] mentions this deployment scenario, it does not provide necessary detail on how the relay element should behave when used with PD.

This document describes functional requirements for a DHCPv6 PD relay when used for relaying prefixes delegated by a separate DHCPv6 server.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

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This Internet-Draft will expire on September 6, 2020.

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Table of Contents

1. Introduction

For Internet service providers that offer native IPv6 access with prefix delegation to their customers, a common deployment architecture is to have a DHCPv6 relay agent function located in the ISP's Layer-3 customer edge device and separate, centralized DHCPv6 server infrastructure. [RFC8415] describes the functionality of a DHCPv6 relay and Section 19.1.3 mentions the deployment scenario, but does not provide detail for all of the functional requirements that the relay needs to fulfill to operate deterministically in this deployment scenario.

A DHCPv6 relay agent for prefix delegation is a function commonly implemented in routing devices, but implementations vary in their functionality and client/server inter-working. This can result in operational problems such as messages not being forwarded by the relay or unreachability of the delegated prefixes. This document provides a set of requirements for devices implementing a relay function for use with prefix delegation.

The mechanisms for a relay to inject routes (including aggregated ones), on its network-facing interface based on prefixes learnt from a server via DHCP-PD are out of scope of the document.

Multi-hop relaying is also not considered as the functionality is solely required by a DHCP relay agent that is co-located with the first-hop router that the DHCPv6 client requesting the prefix is connected to.

The behavior defined in [RFC7283] is also applicable for DHCv6-PD-relay deployments.

2. Terminology

2.1. General

This document uses the terminology defined in [RFC8415], however when defining the functional elements for prefix delegation [RFC8415], Section 4.2 defines the term 'delegating router' as:

This document is concerned with deployment scenarios in which the DHCPv6 relay and DHCPv6 server functions are separated, so the term 'delegating router' is not used. Instead, a new term is introduced to describe the relaying function:

Delegating relay
A delegating relay acts as an intermediate device, forwarding DHCPv6 messages containing IA_PD/IAPREFIX options between the client and server. The delegating relay does not implement a DHCPv6 server function. The delegating relay is also responsible for routing traffic for the delegated prefixes.

Where the term 'relay' is used on its own within this document, it should be understood to be a delegating relay, unless specifically stated otherwise.

[RFC8415] defines the 'DHCP server', (or 'server') as:

This document serves the deployment cases where a DHCPv6 server is not located on the same link as the client (necessitating the delegating relay). The server supports prefix delegation and is capable of leasing prefixes to clients, but is not responsible for other functions required of a delegating router, such as managing routes for the delegated prefixes.

The term 'requesting router' has previously been used to describe the DHCP client requesting prefixes for use. This document adopts the [RFC8415] terminology and uses 'DHCP client' or 'client' interchangeably for this element.

2.2. Topology

The following diagram shows the deployment topology relevant to this document.

  +                                    _    ,--,_
  |   +--------+    +------------+   _(  `'      )_    +--------+
  +---+   PD   |----| Delegating |--(   Operator   )---| DHCPv6 |
  |   | Client |    |    relay   |   `(_ Network_)'    | server |
  |   +--------+    +----------- +      `--'`---'      +--------+
  |
  +
Client Network
        

Figure 1

The client request prefixes via the client facing interface of the delegating relay. The resulting prefixes will be used for addressing the client network. The delegating relay is responsible for forwarding DHCP messages, including prefix delegation requests and responses between the client and server. Messages are forwarded from the delegating relay to the server using multicast or unicast via the operator network facing interface.

The delegating relay provides the operator's Layer-3 edge towards the client and is responsible for routing traffic to and from clients connected to the client network using addresses from the delegated prefixes.

2.3. 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. This document uses these keywords not strictly for the purpose of interoperability, but rather for the purpose of establishing industry-common baseline functionality. As such, the document points to several other specifications (preferably in RFC or stable form) to provide additional guidance to implementers regarding any protocol implementation required to produce a DHCP relaying router that functions successfully with prefix delegation.

3. Problems Observed with Existing Delegating Relays Implementations

The following sections of the document describe problems that have been observed with delegating relay implementations in commercially available devices.

3.1. DHCP Messages not being Forwarded by the Delegating relay

Delegating relay implementations have been observed not to forward messages between the client and server. This generally occurs if a client sends a message which is unexpected by the delegating relay. For example, the delegating router already has an active PD lease entry for an existing client on a port. A new client is connected to this port and sends a solicit message. The delegating relay then drops the solicit messages until it receives either a DHCP release message from the original client, or the existing lease times out. This causes a particular problem when a client device needs to be replaced due to a failure.

In addition to dropping messages, in some cases the delegating relay will generate error messages and send them to the client, e.g. 'NoBinding' messages being sent in the event that the delegating relay does not have an active delegated prefix lease.

3.2. Delegating Relay Loss of State on Reboot

For proper routing of client's traffic, the delegating relay requires a corresponding routing table entry for each active prefix delegated to a connected client. A delegating router which does not store this state persistently across reboots will not be able to forward traffic to client's delegated leases until the state is re-established through new DHCP messages.

3.3. Multiple Simultaneous Delegated Prefixes for a Single DUID on a Single Client

[RFC8415] allows for a client to include more than one instance of OPTION_IA_PD in messages in order to request multiple prefix delegations by the server. If configured for this, the server supplies one instance of OPTION_IAPREFIX for each received instance of OPTION_IA_PD, each containing information for a different delegated prefix.

In some delegating relay implementations, only a single delegated prefix per-DUID is supported. In those cases only one IPv6 route for only one of the delegated router is installed; meaning that other prefixes delegated to a client are unreachable.

3.4. Dropping Messages from Devices with Duplicate MAC addresses and DUIDs

It is an unfortunate operational reality that client devices with duplicate MAC addresses and/or DUIDs exist and have been deployed. In this situation, the operational costs of locating and swapping out such devices are prohibitive.

Delegating relays have been observed to restrict forwarding client messages originating from one client DUID to a single interface. In this case if the same client DUID appears from a second client on another interface while there is already an active lease, messages originating from the second client are dropped causing the second client to be unable to obtain a prefix delegation.

4. Requirements for Delegating Relays

To resolve the problems described in Section 3 the following section of the document describes a set of functional requirements for the delegating relay.

4.1. General Requirements

G-1:
The delegating router MUST forward messages bidirectionally between the client and server without changing the contents of the message.
G-2:
As described in Section 16 of [RFC8415], in the event that a received message contains a DHCPv6 option which the relay does not implement, the message MUST be forwarded.
G-3:
The relay MUST allow for multiple prefixes to be delegated for the same client IA_PD. These delegations may have different lifetimes.
G-4:
The relay MUST allow for multiple prefixes with separate IA_PDs to be delegated to a single client connected to a single interface, identified by its DHCPv6 Client Identifier (DUID).
G-5:
The relay MUST allow the same client identifier (DUID) to have active delegated prefix leases on more than one interface simultaneously. This is to allow client devices with duplicate DUIDs to function on separate broadcast domains.
G-6:
The maximum number of simultaneous prefixes delegated to a single client MUST be configurable.
G-7:
The relay MUST implement a mechanism to limit the maximum number of active prefix delegations on a single port for all client identifiers and IA_PDs. This value SHOULD be configurable.
G-8:
The delegating relay MUST synchronize the lifetimes of active prefix delegation leases with server.

4.2. Routing Requirements

R-1:
The relay MUST maintain a local routing table that is dynamically updated with prefixes and the associated next-hops as they are delegated to clients. When a delegated prefix is released or expires, the associated route MUST be removed from the relay's routing table.
R-2:
The relay MUST provide a mechanism to dynamically update access control lists permitting ingress traffic sourced from clients' delegated prefixes. This is to implement anti-spoofing as described in [BCP38].
R-3:
The relay MAY provide a mechanism to dynamically advertise delegated prefixes into an routing protocol as they are learnt. When a delegated prefix is released or expires, the delegated route MUST be withdrawn from the routing protocol. The mechanism using which the routes are inserted and deleted is out of the scope of this document.

4.3. Service Continuity Requirements

S-1:
In the event that the relay is restarted, active client prefix delegations will be lost. This may result in clients becoming unreachable. In order to mitigate this problem, it is RECOMMENDED that the relay implements either of the following:
The relay MAY implement DHCPv6 bulk lease query as defined in [RFC5460].
The relay SHOULD store active prefix delegations in persistent storage so they can be re-read after the reboot.

S-2:
If a client's next-hop link-local address becomes unreachable (e.g., due to a link-down event on the relevant physical interface), routes for the client's delegated prefixes MUST be retained by the delegating relay unless they are released or removed due to expiring DHCP timers. This is to re-establish routing for the delegated prefix if the client next-hop becomes reachable without the relay needing to be re-learnt.
S-3:
The relay MAY implement DHCPv6 active lease query as defined in [RFC7653] to keep the local lease database in sync with the DHCPv6 server.

4.4. Operational Requirements

O-1:
The relay SHOULD implement an interface allowing the operator to view the active delegated prefixes. This SHOULD provide information about the delegated lease and client details such as client identifier, next-hop address, connected interface, and remaining lifetimes.
O-2:
The relay SHOULD provide a method for the operator to clear active bindings for an individual lease, client or all bindings on a port.
O-3:
To facilitate troubleshooting of operational problems between the delegating relay and other elements, it is RECOMMENDED that the delegating relay's system time is synchronised with the network.

5. Acknowledgements

The authors of this document would like to thank Bernie Volz for his valuable comments.

6. IANA Considerations

This memo includes no request to IANA.

7. Security Considerations

If the delegating relay implements [BCP38] filtering, then the filtering rules will need to be dynamically updated as delegated prefixes are leased.

[RFC8213] describes a method for securing traffic between the relay agent and server by sending DHCP messages over an IPSec tunnel. In this case the IPSec tunnel is functionally the server-facing interface and DHCPv6 message snooping can be carried out as described. It is RECOMMENDED that this is implemented by the delegating relay.

8. References

8.1. 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.
[RFC5460] Stapp, M., "DHCPv6 Bulk Leasequery", RFC 5460, DOI 10.17487/RFC5460, February 2009.
[RFC7653] Raghuvanshi, D., Kinnear, K. and D. Kukrety, "DHCPv6 Active Leasequery", RFC 7653, DOI 10.17487/RFC7653, October 2015.
[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, May 2017.
[RFC8415] Mrugalski, T., Siodelski, M., Volz, B., Yourtchenko, A., Richardson, M., Jiang, S., Lemon, T. and T. Winters, "Dynamic Host Configuration Protocol for IPv6 (DHCPv6)", RFC 8415, DOI 10.17487/RFC8415, November 2018.

8.2. Informative References

[BCP38] IETF, "Network Ingress Filtering: Defeating Denial of Service Attacks which employ IP Source Address Spoofing https://tools.ietf.org/html/bcp38", RFC 2827, BCP 38
[RFC7283] Cui, Y., Sun, Q. and T. Lemon, "Handling Unknown DHCPv6 Messages", RFC 7283, DOI 10.17487/RFC7283, July 2014.
[RFC8213] Volz, B. and Y. Pal, "Security of Messages Exchanged between Servers and Relay Agents", RFC 8213, DOI 10.17487/RFC8213, August 2017.

Authors' Addresses

Ian Farrer Deutsche Telekom AG Landgrabenweg 151 Bonn, NRW 53227 DE EMail: ian.farrer@telekom.de
Naveen Kottapalli Benu Networks 300 Concord Road Billerica, MA 01821 US EMail: naveen.sarma@gmail.com
Martin Hunek Technical University of Liberec Studentska 1402/2 Liberec, L 46017 CZ EMail: martin.hunek@tul.cz
Richard Patterson EMail: richard@helix.net.nz