M-ISIS: Multi Topology (MT) Routing in Intermediate System to Intermediate Systems (IS-ISs)
draft-ietf-isis-wg-multi-topology-12
The information below is for an old version of the document that is already published as an RFC.
| Document | Type | RFC Internet-Draft (isis WG) | |
|---|---|---|---|
| Author | Tony Przygienda | ||
| Last updated | 2015-10-14 (Latest revision 2007-11-13) | ||
| Stream | Internet Engineering Task Force (IETF) | ||
| Formats | plain text htmlized pdfized bibtex | ||
| Reviews | |||
| Stream | WG state | (None) | |
| Document shepherd | (None) | ||
| IESG | IESG state | RFC 5120 (Proposed Standard) | |
| Consensus boilerplate | Unknown | ||
| Telechat date | (None) | ||
| Responsible AD | Russ Housley | ||
| Send notices to | (None) |
draft-ietf-isis-wg-multi-topology-12
Internet Draft Tony Przygienda
prz@net4u.ch
Naiming Shen
Cisco Systems
Nischal Sheth
Juniper Networks
Expires: May 2008 November 5, 2007
Intended Status: Proposed Standard
M-ISIS: Multi Topology (MT) Routing in IS-IS
<draft-ietf-isis-wg-multi-topology-12.txt>
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Copyright Notice
Copyright (C) The IETF Trust (2007).
Abstract
This document describes an optional mechanism within ISIS used today
by many ISPs for IGP routing within their clouds. This document
describes how to run within a single ISIS domain a set of
independent IP topologies that we call Multi-Topologies (MTs).
This MT extension can be used for variety of purposes such as an
in-band management network ``on top'' of the original IGP topology,
maintain separate IGP routing domains for isolated multicast or
IPv6 islands within the backbone, or force a subset of an address
space to follow a different topology.
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1. Introduction
Maintaining multiple MTs for ISIS [ISO10589] [RFC1195] in a
backwards-compatible manner necessitates several extensions to the
packet encoding and additional SPF procedures. The problem can
be partitioned into forming of adjacencies, and advertising of
prefixes and reachable intermediate systems within each topology.
Having put all the necessary additional information in place, it
must be properly used by MT capable SPF computation. The following
sections describe each of the problems separately. To simplify the
text, "standard" ISIS topology is defined to be MT ID #0 (zero).
1.1 Conventions Used in This Document
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 RFC 2119 [RFC2119].
1.2 Definitions of Terms Used in This Document
CSNP Complete Sequence Number Packet. Used to describe all the
contents of a link state database of IS-IS.
DIS Designated Intermediate System. The intermediate system
elected to advertise the pseudonode for a broadcast
network.
IIH IS-IS Hello. Packets that are used to discover adjacent
intermediate systems.
LSP Link State Packet. Packet generated by an intermediate
system and lists adjacent systems, prefixes and other
information.
PSNP Partial Sequence Number Packet. Used to request information
from an adjacent intermediate system's link state
database.
SPF Shortest Path First. An algorithm that takes a database
of nodes within a domain and builds a tree of connectivity
along the shortest paths through the entire network.
2. Maintaining MT Adjacencies
Each adjacency formed MUST be classified as belonging to a set of
MTs on the interface. This is achieved by adding a new TLV into
IIH packets that advertises which topologies the interface belongs
to. If MT #0 is the only MT on the interface, it is optional to
advertise it in the new TLV. Thus not including such a TLV in the
IIH implies MT ID #0 capability only. Through this exchange of MT
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capabilities, a router is able to advertise the IS TLVs in LSPs
with common MT set over those adjacencies.
In the case of adjacency contains multiple MTs on an interface, and
if there exists overlapping IP address space among the topologies,
additional mechanism MUST be used to resolve the topology identity
of the incoming IP packets on the interface. See more discussion in
section 8.2.2 of this document.
2.1. Forming Adjacencies on Point-to-Point Interfaces
Adjacencies on point-to-point interfaces are formed as usual with
ISIS routers not implementing MT extensions. If local router does
not participate in certain MTs, it will not advertise those MTIDs
in its IIHs and thus will not include that neighbor within it's
LSPs. On the other hand, if a MTID is not detected in remote
side's IIHs, the local router MUST NOT include that neighbor
within its LSPs. The local router SHOULD NOT form an adjacency if
they don't have at least one common MT over the interface.
2.2. Forming Adjacencies on Broadcast Interfaces
On a LAN, all the routers on the LAN which implement the MT
extension MAY advertise their MT capability TLV in their IIHs.
If there is at least one adjacency on the LAN interface which
belongs to this MT, the MT capable router MUST include the
corresponding MT IS Reachable TLV in its LSP, otherwise it MAY
include this MT IS Reachable TLV in its LSP if the LAN interface
participates in this MT set.
Two Routers on a LAN SHALL always establish adjacency regardless
whether they have common MT or not. This is to ensure all
the routers on the LAN can correctly elect the same DIS. The IS
SHOULD NOT include the MT IS TLV in its LSP if none of the
adjacencies on the LAN contains this MT.
The DIS, CSNP and PSNP functions are not changed by MT extension.
3. Advertising MT Reachable Intermediate Systems in LSPs
A router MUST include within its LSPs in the Reachable Intermediate
Systems TLVs only adjacent nodes that are participating in the
corresponding topology and advertise such TLVs only if it
participates itself in the corresponding topology. Standard
Reachable Intermediate Systems TLV is acting here as MT ID #0
equivalent of the newly introduced MT Reachable Intermediate Systems
TLV. A router MUST announce the MT IS TLV when there is at least
one adjacency on the interface that belongs to this MT, otherwise
it MAY announce the MT IS TLV of an adjacency for a given MT if this
interface participates in the LAN.
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Since it is not possible to prevent a router that does not
understand MT extensions from being responsible for generation of
the according pseudo-node, it is not possible either to introduce
special TLVs in the pseudo-node LSPs nor run distinct DIS elections
per MT. Therefore, a generated pseudo-node LSP by DIS MUST contain
in its IS Reachable TLV all nodes on the LAN as usual regardless
of their MT capabilities. In other words, there is no change to the
pseudo-node LSP construction.
4. MTs and Overload, Partition and Attached Bits
A router could for each of the MTs become potentially
partitioned, overloaded and attached independently. To prevent
unnecessary complexity, MT extensions does not support MT based
partition repair. The overload, partition and attached bits in LSP
header only reflect the status of the default topology.
Attached bit and overload bit are part of the MT TLV being
distributed within a node's LSP fragment zero. Since each adjacency
can belong to different MTs, it is possible that some MTs are L2
attached, and others are not on the same router. The overload
bit in the MT TLV can be used to signal the topology being
overloaded. A MT based system is considered being overloaded if
the overload bit in the MT is set.
Route leaking between the levels SHOULD only be performed within
the same MT.
5. Advertising MT Specific IP Prefixes
Each of the MTs commands its own address space so a new TLV is
necessary for prefixes stored in MTs other than MT ID #0. To
make the encoding less confusing when same prefixes are present in
multiple MTs and accelerate SPF per MT, rather than adding a sub-TLV
in TE extensions, a new TLV is introduced for that purpose that
closely follows TE encoding [LS01].
6. MT SPF Computation
Each MT MUST run its own instance of the decision process.
The pseudo-node LSPs are used by all topologies during computation.
Each non-default topology MAY have it's attached bit and overload
bit set in the MT TLV. Reverse connectivity check within SPF MUST
follow the according MT to assure the bi-directional reachability
within the same MT.
The results of each computation SHOULD be stored in a separate RIB
in normal cases, otherwise overlapping addresses in different
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topologies could lead to undesirable routing behavior such as
forwarding loops. The forwarding logic and configuration need to
ensure the same MT is traversed from the source to the destination
for packets. The nexthops derived from the MT SPF MUST belong to
the adjacencies conforming to the same MT for correct forwarding.
It is recommended for the administrators to ensure consistent
configuration of all routers in the domain to prevent undesirable
forwarding behavior.
No attempt is made in this document to allow one topology to
calculate routes using the routing information from another
topology inside SPF. Even though it is possible to redistribute
and leak routes from another IS-IS topology or from external
sources, and the exact mechanism is beyond the scope of this
document.
7. Packet Encoding
Three new TLVs are added to support MT extensions. One of them is
common for the LSPs and IIHs. Encoding of Intermediate System TLV
and IPv4 Reachable Prefixes is tied to traffic engineering
extensions [LS01] to simplify the implementation effort. The main
reasons we choose using new TLVs instead of using sub-TLVs inside
existing TLV type-22 and type-135 are: In many cases,
multi-topologies are non-congruent, using sub-TLV approach will
not save LSP space; Many sub-TLVs are already being used in TLV
type-22, and many more are being proposed while there is a maximum
limit on the TLV size, from the existing TLVs; If traffic
engineering or some other applications are being applied per
topology level later, the new TLVs can automatically inherit the
same attributes already defined for the "standard" IPv4 topology
without going through long standard process to redefine them per
topology.
7.1. Multi-Topology TLV
TLV number of this TLV is 229. It contains one or more MTs
the router is participating in the following structure:
x CODE - 229
x LENGTH - total length of the value field, it SHOULD be 2
times the number of MT components.
x VALUE - one or more 2-byte MT components, structured
as follows:
No. of Octets
+--------------------------------+
|O |A |R |R | MT ID | 2
+--------------------------------+
Bit O represents the OVERLOAD bit for the MT (only valid
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in LSP fragment zero for MTs other than ID #0, otherwise
SHOULD be set to 0 on transmission and ignored on receipt.)
Bit A represents the ATTACH bit for the MT (only valid
in LSP fragment zero for MTs other than ID #0, otherwise
SHOULD be set to 0 on transmission and ignored on receipt.)
Bits R are reserved, SHOULD be set to 0 on transmission
and ignored on receipt.
MT ID is a 12-bit field containing the ID of the topology
being announced.
This MT TLV can advertise up to 127 MTs and it can occur multiple
times if needed within IIHs and LSP fragment zero. The result MT
set SHOULD be the union of all the MT TLV occurrence in the packet.
Any other ISIS PDU occurrence of this TLV MUST be ignored. Lack
of MT TLV in hellos and fragment zero LSP MUST be interpreted as
participation of the advertising interface or router in
MT ID #0 only. If a router advertises MT TLV, it has to advertise
all the MTs it participates in, specifically including topology
ID #0 also.
7.2. MT Intermediate Systems TLV
TLV number of this TLV is 222. It is aligned with extended IS
reachability TLV type 22 beside an additional two bytes in front at
the beginning of the TLV.
x CODE - 222
x LENGTH - total length of the value field
x VALUE - 2-byte MT membership plus the format of extended IS
reachability TLV, structured as follows:
No. of Octets
+--------------------------------+
|R |R |R |R | MT ID | 2
+--------------------------------+
| extended IS TLV format | 11 - 253
+--------------------------------+
. .
. .
+--------------------------------+
| extended IS TLV format | 11 - 253
+--------------------------------+
Bits R are reserved, SHOULD be set to 0 on transmission
and ignored on receipt.
MT ID is a 12-bit field containing the non-zero MT ID of the
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topology being announced. The TLV MUST be ignored if the ID
is zero. This is to ensure the consistent view of the standard
unicast topology.
After the 2-byte MT membership format, the MT IS content is
in the same format as extended IS TLV, type 22 [LS01]. It
can contain up to 23 neighbors of the same MT if no sub-TLVs
are used.
This TLV can occur multiple times.
7.3. Multi-Topology Reachable IPv4 Prefixes TLV
TLV number of this TLV is 235. It is aligned with extended IP
reachability TLV type 135 beside an additional two bytes in front.
x CODE - 235
x LENGTH - total length of the value field
x VALUE - 2-byte MT membership plus the format of extended
extended IP reachability TLV, structured as follows:
No. of Octets
+--------------------------------+
|R |R |R |R | MT ID | 2
+--------------------------------+
| extended IP TLV format | 5 - 253
+--------------------------------+
. .
. .
+--------------------------------+
| extended IP TLV format | 5 - 253
+--------------------------------+
Bits R are reserved, SHOULD be set to 0 on transmission
and ignored on receipt.
MT ID is a 12-bit field containing the non-zero ID of the
topology being announced. The TLV MUST be ignored if the ID
is zero. This is to ensure the consistent view of the standard
unicast topology.
After the 2-byte MT membership format, the MT IPv4 content
is in the same format as extended IP reachability TLV,
type 135 [LS01].
This TLV can occur multiple times.
7.4. Multi-Topology Reachable IPv6 Prefixes TLV
TLV number of this TLV is 237. It is aligned with IPv6 Reachability
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TLV type 236 beside an additional two bytes in front.
x CODE - 237
x LENGTH - total length of the value field
x VALUE - 2-byte MT membership plus the format of IPv6
Reachability TLV, structured as follows:
No. of Octets
+--------------------------------+
|R |R |R |R | MT ID | 2
+--------------------------------+
| IPv6 Reachability format | 6 - 253
+--------------------------------+
. .
+--------------------------------+
| IPv6 Reachability format | 6 - 253
+--------------------------------+
Bits R are reserved, SHOULD be set to 0 on transmission
and ignored on receipt.
MT ID is a 12-bit field containing the ID of the topology
being announced. The TLV MUST be ignored if the ID
is zero.
After the 2-byte MT membership format, the MT IPv6 context
is in the same format as IPv6 Reachability TLV,
type 236 [H01].
This TLV can occur multiple times.
7.5. Reserved MT ID Values
Certain MT topologies are assigned to serve pre-determined purposes:
- MT ID #0: Equivalent to the "standard" topology.
- MT ID #1: Reserved for IPv4 in-band management
purposes.
- MT ID #2: Reserved for IPv6 routing topology.
- MT ID #3: Reserved for IPv4 multicast routing topology.
- MT ID #4: Reserved for IPv6 multicast routing topology.
- MT ID #5: Reserved for IPv6 in-band management
purposes.
- MT ID #6-#3995: Reserved for IETF consensus.
- MT ID #3996-#4095: Reserved for development, experimental and
proprietary features [RFC3692].
8. MT IP Forwarding Considerations
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Using MT extension for ISIS routing can result in multiple RIBs
on the system. In this section we
list some of the known considerations for IP forwarding in various
MT scenario. Certain deployment scenarios presented here
imply different trade-offs in terms of deployment difficulties
and advantages obtained.
8.1. Each MT belong to a distinct address family
In this case, each MT related routes are installed into a
separate RIB. Multiple topologies can share the same ISIS interface
on detecting the incoming packet address family. As an example,
IPv4 and IPv6 can share the same interface without any further
considerations under MT ISIS.
8.2. Some MTs belong to the same address family
8.2.1. Each interface belongs to one and only one MT
In this case, MTs can be used to forward packets from the
same address family, even with overlapping addresses. Since the
MTs have their dedicated interfaces, and those interfaces can be
associated with certain MT RIBs and FIBs.
8.2.2. Multiple MTs share an interface with overlapping addresses
Some additional mechanism is needed to select the correct RIBs
for the incoming IP packets to determine the correct RIB to make
a forwarding decision. For example, if the topologies are
QoS partitioned, then the DSCP bits in the IP packet header can
be utilized to make the decision. Some IP header or even packet
data information MAY be checked to make the forwarding table
selection, such as source IP address in the header can be used
to determine the desired forwarding behavior.
This topic is not unique to IS-IS or even to Multi-topology, it
is a local policy and configuration decision to make sure the
inbound traffic uses the correct forwarding tables. For example,
preferred customer packets are sent through a L2TP towards the
high-bandwidth upstream provider, and other packets are sent
through a different L2TP to a normal-bandwidth provider. Those
mechanism are not part of the L2TP protocol specifications.
The generic approach of packet to multiple MT RIB mapping over
the same inbound interface is outside the scope of this document.
8.2.3. Multiple MTs share an interface with non-overlapping addresses
When there is no overlap in the address space among all the MTs,
strictly speaking the destination address space classifies the
topology a packet belongs to. It is possible to install routes
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from different MTs into a shared RIB. As an example of such a
deployment, a special ISIS topology can be setup for certain
EBGP nexthop addresses.
8.3 Some MTs are not used for forwarding purpose
MT in ISIS MAY be used even if the resulting RIB is not used for
forwarding purposes. As an example, multicast RPF check can be
performed on a different RIB than the standard unicast RIB albeit
an entirely different RIB is used for the multicast forwarding.
However, an incoming packet MUST be still clearly identified as
belonging to a unique topology.
9. MT Network Management Considerations
When multiple ISIS topologies exist within a domain, some of the
routers can be configured to participate in a subset of the MTs
in the network. This section discusses some of the options we
have to enable operations or the network management stations to
access those routers.
9.1. Create dedicated management topology to include all the nodes
This approach is to setup a dedicated management topology or
'in-band' management topology. This 'mgmt' topology will include
all the routers need to be managed. The computed routes in the
topology will be installed into the 'mgmt' RIB. In the condition
of the 'mgmt' topology uses a set of non-overlapping address space
with the default topology, those 'mgmt' routes can also be
optionally installed into the default RIB.
The advantages of duplicate 'mgmt' routes in both RIBs include:
the network management utilities on the system does not have to be
modified to use specific RIB other than the default RIB; the 'mgmt'
topology can share the same link with the default topology if so
designed.
9.2. Extend the default topology to all the nodes
Even in the case default topology is not used on some of the nodes
in the IP forwarding, we MAY want to extend the default topology
to those nodes for the purpose of network management. Operators
SHOULD set high cost on the links which belong to the extended
portion of the default topology. This way the IP data traffic
will not be forwarded through those nodes during network topology
changes.
10. Acknowledgments
The authors would like to thank Andrew Partan, Dino Farinacci,
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Derek Yeung, Alex Zinin, Stefano Previdi, Heidi Ou, Steve Luong,
Pekka Savola, Mike Shand, Shankar Vemulapalli and Les Ginsberg
for the discussion, their review, comments and contributions to
this document.
11. Security Consideration
ISIS security applies to the work presented. No specific security
issues with the proposed solutions are known. The authentication
procedure for ISIS PDUs is the same regardless of MT information
inside the ISIS PDUs.
Note that an authentication mechanism, such as the one defined in
[RFC3567] SHOULD be applied if there is high risk resulting
from modification of multi-topology information.
As described in section 8.2.2, multiple topologies share an
interface in the same address space, some mechanism beyond
IS-IS need to be used to select the right forwarding table
for an inbound packet. A misconfiguration on the system or
a packet with spoofed source address for example can lead to
packet loss or unauthorized use of premium network resource.
12. IANA Considerations
This document defines the following new IS-IS TLV types, which have
already been reflected in the IANA IS-IS TLV code-point registry:
Name Value
MT-ISN 222
M-Topologies 229
MT IP. Reach 235
MT IPv6 IP. Reach 237
IANA is requested to create a new registry, "IS-IS multi-topology ID
values" with the assignment listed in Section 7.5 of this document
and registration policies [RFC2434] for future assignments. The
MT ID values range 6-3095 are allocated through Expert Review;
values in the range of 3096-4095 are reserved for Private Use.
In all cases, assigned values are to be registered with IANA.
13. References
13.1. Normative References
[ISO10589] ISO. Intermediate System to Intermediate System Routing
Exchange Protocol for Use in Conjunction with the
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Protocol for Providing the Connectionless-Mode Network
Service. ISO 10589, 1992.
[RFC1195] R. Callon. Use of OSI ISIS for Routing in TCP/IP and
Dual Environments. RFC 1195, December 1990.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC3692] Narten, T., "Assigning Experimental and Testing
Numbers Considered Useful", BCP 82, RFC 3692, January
2004.
[RFC2434] Narten, T. and H. Alvestrand, "Guidelines for Writing
an IANA Considerations Section in RFCs", BCP 26,
RFC 2434, October 1998.
13.2. Informative References
[RFC3567] Li, T. and R. Atkinson, "Intermediate System to
Intermediate System (IS-IS) Cryptographic
Authentication", RFC 3567, July 2003.
[LS01] T. Li and H. Smit. IS-IS Extensions for Traffic
Engineering. RFC 3784, May 2005.
[H01] C. Hopps. Routing IPv6 with IS-IS.
draft-ietf-isis-ipv6-07.txt, October 2007.
(work in progress)
14. Authors' Addresses
Tony Przygienda
Z2 Sagl
Via Rovello 32
CH-6942 Savosa
prz@net4u.ch
Naiming Shen
Cisco Systems
225 West Tasman Drive
San Jose, CA, 95134 USA
naiming@cisco.com
Nischal Sheth
Juniper Networks
1194 North Mathilda Avenue
Sunnyvale, CA 94089 USA
nsheth@juniper.net
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