Network Working Group F. Baker
Internet-Draft Cisco Systems
Intended status: Standards Track D. Lamparter
Expires: January 4, 2016 NetDEF
July 3, 2015

IPv6 Source/Destination Routing using IS-IS
draft-baker-ipv6-isis-dst-src-routing-03

Abstract

This note describes the changes necessary for IS-IS to route IPv6 traffic from a specified prefix to a specified prefix.

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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Table of Contents

1. Introduction

This specification defines how to exchange destination/source routing [I-D.lamparter-rtgwg-dst-src-routing] information in IS-IS for IPv6 [RFC5308] routing environments. To this extent, a new sub-TLV for an IPv6 [RFC2460] Source Prefix is added, and Multi Topology Routing [RFC5120] is employed to address compatibility and isolation concerns.

The router MUST implement the Destination/Source Routing mechanism described in [I-D.lamparter-rtgwg-dst-src-routing]. This implies not simply routing "to a destination", but routing "to that destination AND from a specified source". The obvious application is egress routing, as required for a multihomed entity with a provider-allocated prefix from each of several upstream networks. Traffic within the network could be source/destination routed as well, or could be implicitly or explicitly routed from "any prefix", ::/0. Other use cases are described in [I-D.baker-rtgwg-src-dst-routing-use-cases]. If a FIB contains a route to a given destination from one or more prefixes not including ::/0, and a given packet destined there that has a source address that is in none of them, the packet in effect has no route, just as if the destination itself were not in the route table.

1.1. Requirements Language

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119].

2. Theory of Routing

Both IS-IS and OSPF perform their calculations by building a lattice of routers and links from the router performing the calculation to each router, and then use routes (sequences in the lattice) to get to destinations that those routes advertise connectivity to. Following the SPF algorithm, calculation starts by selecting a starting point (typically the router doing the calculation), and successively adding {link, router} pairs until one has calculated a route to every router in the network. As each router is added, including the original router, destinations that it is directly connected to are turned into routes in the route table: "to get to 2001:db8::/32, route traffic to {interface, list of next hop routers}". For immediate neighbors to the originating router, of course, there is no next hop router; traffic is handled locally.

In this context, the route is qualified by a source prefix; It is installed into the FIB with the destination prefix, and the FIB applies the route if and only if the IPv6 source address also matches the advertised prefix. Of course, there may be multiple LSPs in the RIB with the same destination and differing source prefixes; these may also have the same or differing next hop lists. The intended forwarding action is to forward matching traffic to one of the next hop routers associated with this destination and source prefix, or to discard non-matching traffic as "destination unreachable".

TLVs that lack a source prefix sub-TLV match any source address (i.e., the source prefix TLV defaults to ::/0), by definition.

To ensure that routers without support for Destination/Source routing are excluded from path calculation for routes with a non-default source prefix, a separate MTID is used to carry Destination/Source routes. A router MUST NOT participate in a topology with such an MTID unless it implements Destination/Source routing.

There is a distinct Destination/Source Routing MTID for each of the underlying base MT topologies the information applies to. The set of routes propagated towards the forwarding plane is the union of the information in the base topology and the D/S Routing MTID. Incoming connectivity information with a default or non-present source prefix is advertised in the base topology, routes with non-default source prefix are advertised in the D/S Routing MTID.

2.1. Notation

For the purposes of this document, a route from the prefix A to the prefix B (in other words, whose source prefix is A and whose destination prefix is B) is expressed as A->B. A packet with the source address A and the destination address B is similarly described as A->B.

2.2. Dealing with ambiguity

In any routing protocol, there is the possibility of ambiguity. For example, one router might advertise a fairly general prefix - a default route, a discard prefix (which consumes all traffic that is not directed to an instantiated subnet), or simply an aggregated prefix while another router advertises a more specific one. In source/destination routing, potentially ambiguous cases include cases in which the link state database contains two routes A->B' and A'->B, in which A' is a more specific prefix within the prefix A and B' is a more specific prefix within the prefix B. Traditionally, we have dealt with ambiguous destination routes using a "longest match first" rule. If the same datagram matches more than one destination prefix advertised within an area, we follow the route with the longest matching prefix.

With source/destination routes, as noted in [I-D.baker-rtgwg-src-dst-routing-use-cases], we follow a similar but slightly different rule; the FIB lookup MUST yield the route with the longest matching destination prefix that also matches the source prefix constraint. In the event of a tie on the destination prefix, it MUST also match the longest matching source prefix among those options.

An example of the issue is this. Suppose we have two routes:

  1. 2001:db8:1::/48 -> 2001:db8:3:3::/64
  2. 2001:db8:2::/48 -> 2001:db8:3::/48

and a packet

If we require the algorithm to follow the longest destination match without regard to the source, the destination address matches 2001:db8:3:3::/64 (the first route), and the source address doesn't match the constraint of the first route; we therefore have no route. The FIB algorithm, in this example, must therefore match the second route, even though it is not the longest destination match, because it also matches the source address.

2.3. Multi-topology Routing

As outlined in Section 2, this document specifies the use of separate topologies for Multi Topology Routing [RFC5120] to carry Destination/Source routing information. These topologies form pairs with a base topology each as follows:

base               base    D/S
designated usage   MTID    MTID
----------------------------------
default topology   0       TBD-MT0
IPv4 management    1       n/a
IPv6 default       2       TBD-MT2
IPv4 multicast     3       n/a
IPv6 multicast     4       n/a
IPv6 management    5       TBD-MT5

Destination/Source Routing MTIDs

The rationale for in-/excluding base MTIDs to provide a D/S MTID for is as follows:

MTID 0:
The base (non-MTR) topology in some installations carries all routing information, including IPv6 reachabilities. In such a setup, the topology with MTID TBD-MT0 is used to carry associated D/S reachabilities.
MTIDs 1 and 3:
Topologies with MTID 1 and 3 carry exclusively IPv4 reachabilities. Thus, no IPv6 D/S topology is created to associate with them.
MTID 2:
The topology with MTID 2 carries IPv6 reachabilities in common M-ISIS setups. (MTID 0 in such cases carries exclusively IPv4 reachability information.) Associated IPv6 D/S reachabilities MUST be carried in MTID TBD-MT2.
MTID 4:
MTID 4, while carrying IPv6 connectivity information, is used for multicast RPF lookups. Since Destination/Source routing is not compatible with multicast RPF lookups, no associated D/S MTID is defined for IS-IS.
MTID 5:
An alternate management/administration topology may carry its routing information in MTID 5. Destination/Source routing is applicable to this and MUST use MTID TBD-MT5 to carry associated reachability TLVs.

It should be noted that implementing M-ISIS is thus a prerequirement for supporting the protocol outlined in this document. Even installations that previously used only MTID 0 (i.e. no M-ISIS) will need to start using MTID TBD-MT0.

3. Protocol encoding for IPv6 Source Prefix information

Destination/Source reachabilities are originated using TLV 237, using an additional sub-TLV to carry the source prefix as follows.

As noted in Section 2, any IPv6 Reachability TLV that does not specify a source prefix is functionally identical to specifying ::/0 as the source prefix. Such routes SHOULD NOT be originated into the D/S MTID, but rather into the base MTID.

3.1. Source Prefix sub-TLV

The following Sub-TLV is defined for TLV 237:

 0                   1                   2                   3
 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|      Type     |    Length     |Prefix Length  |    Prefix
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

Source Prefix Sub-TLV

Source Prefix Type:
TBD-TLV (assigned by IANA)
TLV Length:
Length of the sub-TLV in octets
Prefix Length:
Length of the prefix in bits
Prefix:
(source prefix length+7)/8 octets of prefix

4. IANA Considerations

IANA is requested to allocate Values from the "IS-IS Multi-Topology ID Values" registry as follows:

TBD-MT0:
IPv6 Dest/Source routing corresponding to topology 0
TBD-MT2:
Reserved for IPv6 Dest/Source routing corresponding to topology 2
TBD-MT5:
Reserved for IPv6 Dest/Source routing corresponding to topology 5

Additionally, IANA is requested to allocate an IS-IS codepoint from the "Sub-TLVs for TLVs 135, 235, 236, and 237" registry:

Type:
TBD-TLV
Description:
IPv6 SADR Source Prefix
Applicable to TLV 237:
Yes
Applicable to TLVs 135, 235, 236:
No

5. Security Considerations

The same injection and resource exhaustion attack scenarios as with all routing protocols apply.

Security considerations from [I-D.lamparter-rtgwg-dst-src-routing] are particularly relevant to this document, in particular the possibility to inject (more) specific routes to hijack traffic.

6. Privacy Considerations

No privacy considerations apply to this document, as it only specifies routing control plane information.

7. Acknowledgements

(TODO)

8. References

8.1. Normative References

[I-D.lamparter-rtgwg-dst-src-routing] Lamparter, D., "Destination/Source Routing", Internet-Draft draft-lamparter-rtgwg-dst-src-routing-01, June 2015.
[IS-IS] ISO/IEC, "Intermediate System to Intermediate System Intra-Domain Routing Exchange Protocol for use in Conjunction with the Protocol for Providing the Connectionless-mode Network Service (ISO 8473)", ISO/IEC 10589:2002, Second Edition, 2002.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2460] Deering, S. and R. Hinden, "Internet Protocol, Version 6 (IPv6) Specification", RFC 2460, December 1998.
[RFC5120] Przygienda, T., Shen, N. and N. Sheth, "M-ISIS: Multi Topology (MT) Routing in Intermediate System to Intermediate Systems (IS-ISs)", RFC 5120, February 2008.
[RFC5308] Hopps, C., "Routing IPv6 with IS-IS", RFC 5308, October 2008.

8.2. Informative References

[I-D.baker-ipv6-isis-dst-flowlabel-routing] Baker, F., "Using IS-IS with Token-based Access Control", Internet-Draft draft-baker-ipv6-isis-dst-flowlabel-routing-01, August 2013.
[I-D.baker-rtgwg-src-dst-routing-use-cases] Baker, F., "Requirements and Use Cases for Source/Destination Routing", Internet-Draft draft-baker-rtgwg-src-dst-routing-use-cases-01, October 2014.

Appendix A. Correctness considerations

While Multi-Topology routing in general can be assumed to work correctly when used on its own, this may not apply to a scenario mixing route calculation results as suggested in this document. However, this specific application is easily understandable as correct:

The compatibility mechanics thus rest on 2 pillars:

Appendix B. Change Log

(to be removed)

Initial Version:
February 2013
updated Version:
August 2013
Added MTR:
August 2014
Split into 4 drafts:
October 2014
Dropped 'Critical Sub-TLV' drafts
June 2015

Authors' Addresses

Fred Baker Cisco Systems Santa Barbara, California 93117 USA EMail: fred@cisco.com
David Lamparter NetDEF Leipzig, 04103 Germany EMail: david@opensourcerouting.org