Internet Engineering Task Force H. Chen
Internet-Draft A. Retana
Intended status: Experimental R. Li
Expires: March 21, 2020 Futurewei
A. Kumar S N
RtBrick
N. So
V. Liu
M. Toy
Verizon
L. Liu
Fijitsu
September 18, 2019
IS-IS Topology-Transparent Zone
draft-chen-isis-ttz-06.txt
Abstract
This document presents a topology-transparent zone in a domain. A
zone comprises a group of routers and a number of circuits connecting
them. Any router outside of the zone is not aware of the zone. The
information about the circuits and routers inside the zone is not
distributed to any router outside of the zone. Any link state change
such as a circuit down inside the zone is not seen by any router
outside of the zone.
Status of this Memo
This Internet-Draft is submitted to IETF 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 http://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 March 21, 2020.
Copyright Notice
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Copyright (c) 2019 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Conventions Used in This Document . . . . . . . . . . . . . . 4
3. Requirements . . . . . . . . . . . . . . . . . . . . . . . . . 4
4. Topology-Transparent Zone . . . . . . . . . . . . . . . . . . 4
4.1. Overview of Topology-Transparent Zone . . . . . . . . . . 4
4.2. An Example of TTZ . . . . . . . . . . . . . . . . . . . . 5
5. Extensions to IS-IS Protocols . . . . . . . . . . . . . . . . 6
5.1. TTZ TLV . . . . . . . . . . . . . . . . . . . . . . . . . 6
6. Updating LSPs for TTZ . . . . . . . . . . . . . . . . . . . . 9
6.1. Updating LSP for a TTZ Internal Router . . . . . . . . . . 9
6.2. Updating LSP for a TTZ Edge Router . . . . . . . . . . . . 9
7. Establishing Adjacencies . . . . . . . . . . . . . . . . . . . 10
7.1. Discover TTZ Neighbor over Normal Adjacency . . . . . . . 10
7.2. Establishing TTZ Adjacencies . . . . . . . . . . . . . . . 10
7.3. Adjacency between TTZ Edge and Router outside . . . . . . 10
8. Distribution of LSPs . . . . . . . . . . . . . . . . . . . . . 11
8.1. Distribution of LSPs within TTZ . . . . . . . . . . . . . 11
8.2. Distribution of LSPs through TTZ . . . . . . . . . . . . . 11
9. Computation of Routing Table . . . . . . . . . . . . . . . . . 12
10. Operations . . . . . . . . . . . . . . . . . . . . . . . . . . 12
10.1. Configuring TTZ . . . . . . . . . . . . . . . . . . . . . 12
10.2. Smooth Migration to TTZ . . . . . . . . . . . . . . . . . 13
10.3. Adding a Router into TTZ . . . . . . . . . . . . . . . . . 14
11. Security Considerations . . . . . . . . . . . . . . . . . . . 14
12. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 14
13. Contributors . . . . . . . . . . . . . . . . . . . . . . . . . 15
14. Acknowledgement . . . . . . . . . . . . . . . . . . . . . . . 15
15. Normative References . . . . . . . . . . . . . . . . . . . . . 15
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 16
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1. Introduction
ISO/IEC 10589 describes IS-IS areas or levels in an Autonomous System
(AS). Each level 1 area has a number of level 1 and level 2 routers
connected to the level 2 area. Each level 1 and level 2 router may
summarize the topology of its attached level 1 areas to the level 2
area or vice versa.
The number of routers in a network becomes larger and larger as the
Internet traffic keeps growing. Through splitting the network into
multiple areas, we can extend the network further. However, there
are a number of issues when a network is split further into more
areas.
At first, dividing a network from one area into multiple areas or
from a number of existing areas to even more areas is a very
challenging and time consuming task since it is involved in
significant network architecture changes.
Secondly, the services carried by the network may be interrupted
while the network is being split from one area into multiple areas or
from a number of existing areas into even more areas.
Furthermore, it is complex for a Multi-Protocol Label Switching
(MPLS) Traffic Engineering (TE) Label Switching Path (LSP) crossing
multiple areas to be setup. In one option, a TE path crossing
multiple areas is computed by using collaborating Path Computation
Elements (PCEs) [RFC5441] through the PCE Communication Protocol
(PCEP)[RFC5440], which is not easy to configure by operators since
the manual configuration of the sequence of domains is required.
Although this issue can be addressed by using the Hierarchical PCE,
this solution may further increase the complexity of network design.
Especially, the current PCE standard method may not guarantee that
the path found is optimal.
This document presents a topology-transparent zone in a domain or an
area and describes extensions to IS-IS for supporting the topology-
transparent zone, which is scalable and resolves the issues above.
A topology-transparent zone comprises a group of routers and a number
of circuits connecting these routers. Any router outside of the zone
is not aware of the zone. The information about the circuits and
routers inside the zone is not distributed to any router outside of
the zone. Any link state change such as a circuit down inside the
zone is not seen by any router outside of the zone.
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2. 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.
3. Requirements
Topology-Transparent Zone (TTZ) may be deployed for resolving some
critical issues such as scalability in existing networks and future
networks. The requirements for TTZ are listed as follows:
o TTZ MUST be backward compatible. When a TTZ is deployed on a set
of routers in a network, the routers outside of the TTZ in the
network do not need to know or support TTZ.
o TTZ MUST support at least one more levels of network hierarchies,
in addition to the hierarchies supported by existing routing
protocols.
o Users SHOULD be able to easily set up an end to end service
crossing TTZs.
o The configuration for a TTZ in a network SHOULD be minimum.
o The changes on the existing protocols for supporting TTZ SHOULD be
minimum.
4. Topology-Transparent Zone
4.1. Overview of Topology-Transparent Zone
A Topology-Transparent Zone (TTZ) is identified by an Identifier
(ID), and it includes a group of routers and a number of circuits
connecting the routers. A TTZ is in an IS-IS domain (area).
The ID of a TTZ or TTZ ID is a number that is unique for identifying
an entity such as a node in an IS-IS domain (area). It is not zero
in general.
In addition to having the functions of an IS-IS level or area, an
IS-IS TTZ makes some improvements on an IS-IS level or area, which
include:
o An IS-IS TTZ is virtualized as the TTZ edge routers connected.
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o An IS-IS TTZ receives the link state information about the
topology outside of the TTZ, stores the information in the TTZ and
floods the information through the TTZ to the routers outside of
TTZ.
4.2. An Example of TTZ
The figure below illustrates an example of a routing domain
containing a TTZ: TTZ 600.
TTZ 600
\
\ ^~^~^~^~^~^~^~^~^~^~^~^~
( )
===[R15]========(==[R61]------------[R63]==)======[R29]===
|| ( | \ / | ) ||
|| ( | \ / | ) ||
|| ( | \ / | ) ||
|| ( | ___\ / | ) ||
|| ( | / [R71] | ) ||
|| ( | [R73] / \ | ) ||
|| ( | / \ | ) ||
|| ( | / \ | ) ||
|| ( | / \ | ) ||
===[R17]========(==[R65]------------[R67]==)======[R31]===
\\ (// \\) //
|| //v~v~v~v~v~v~v~v~v~v~v~\\ ||
|| // \\ ||
|| // \\ ||
\\ // \\ //
======[R23]==============================[R25]=====
// \\
// \\
Figure 1: An Example of TTZ
The routing domain comprises routers R15, R17, R23, R25, R29 and R31.
It also contains TTZ 600, which comprises routers R61, R63, R65, R67,
R71 and R73, and the circuits connecting them.
There are two types of routers in a TTZ: TTZ internal routers and TTZ
edge routers. A TTZ internal router is a router inside the TTZ and
its adjacent routers are inside the TTZ. A TTZ edge router is a
router inside the TTZ and has at least one adjacent router that is
outside of the TTZ.
The TTZ in the figure above comprises four TTZ edge routers R61, R63,
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R65 and R67. Each TTZ edge router is connected to at least one
router outside of the TTZ. For instance, router R61 is a TTZ edge
router since it is connected to router R15, which is outside of the
TTZ.
In addition, the TTZ comprises two TTZ internal routers R71 and R73.
A TTZ internal router is not connected to any router outside of the
TTZ. For instance, router R71 is a TTZ internal router since it is
not connected to any router outside of the TTZ. It is just connected
to routers R61, R63, R65, R67 and R73 inside the TTZ.
A TTZ MUST hide the information inside the TTZ from the outside. It
MUST NOT directly distribute any internal information about the TTZ
to a router outside of the TTZ.
For instance, the TTZ in the figure above MUST NOT send the
information about TTZ internal router R71 to any router outside of
the TTZ in the routing domain; it MUST NOT send the information about
the circuit between TTZ router R61 and R65 to any router outside of
the TTZ.
In order to create a TTZ, we MUST configure the same TTZ ID on the
edge routers and identify the TTZ internal circuits on them. In
addition, we SHOULD configure the TTZ ID on every TTZ internal router
which indicates that every circuit of the router is a TTZ internal
circuit.
From a router outside of the TTZ, a TTZ is seen as a group of routers
fully connected. For instance, router R15 in the figure above, which
is outside of TTZ 600, sees TTZ 600 as a group of TTZ edge routers:
R61, R63, R65 and R67. These four TTZ edge routers are fully
connected.
In addition, a router outside of the TTZ sees TTZ edge routers having
normal connections to the routers outside of the TTZ. For example,
router R15 sees four TTZ edge routers R61, R63, R65 and R67, which
have the normal connections to R15, R29, R17 and R23, R25 and R31
respectively.
5. Extensions to IS-IS Protocols
5.1. TTZ TLV
A new TLV, which is called TTZ TLV, may be added into a link state
PDU(LSP) or a Hello PDU for a TTZ node. It has the following format.
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TTZ TLV Length in Byte
+----------------------+
| Type = TBD | 1
+----------------------+
| Length | 1
+----------------------+
| Flags | 2
+----------------------+
| TTZ ID | 4
+----------------------+
| Sub-TLVs | Length of Sub-TLVs
+----------------------+
Figure 2: TTZ TLV
A TTZ TLV has 1 byte of Type, 1 byte of Length of the value field of
the TLV, which is followed by 2 bytes of Flags and 4 bytes of TTZ ID.
A TTZ TLV in an LSP may contains a number of sub TLVs and have Flags
defined as follows.
0 1
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|E|T|M|N|R| 0 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
E = 1: Edge router of TTZ
T = 1: Distributing TTZ Topology Information for Migration
M = 1: Migrating to TTZ
N = 1: Distributing Normal Topology Information for Rollback
R = 1: Rolling back from TTZ
When a router in a TTZ receives a CLI command triggering TTZ
information distribution for migration, it updates its LSP by adding
a TTZ TLV with T set to 1. When a router in a TTZ receives a CLI
command activating migration to TTZ, it sets M to 1 in the TTZ TLV in
its LSP.
Two new sub-TLVs are defined, which may be added into a TTZ TLV in an
LSP. One is TTZ IS Neighbor sub-TLV, or TTZ ISN sub-TLV for short.
The other is TTZ ES Neighbor sub-TLV, or TTZ ESN sub-TLV for short.
A TTZ ISN sub-TLV contains the information about a number of TTZ IS
neighbors connected to a TTZ edge router. It has the format below.
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TTZ ISN sub-TLV Length in Byte
+----------------------+
| Sub-Type = 1 | 1
+----------------------+
| Length | n*(IDLength + 5)
+----------------------+
| Default Metric(i) | 1
+----------------------+
| Delay Metric(i) | 1
+----------------------+
| Expense Metric(i) | 1
+----------------------+
| Error Metric(i) | 1
+----------------------+
| Neighbor ID(i) | IDLength + 1
+----------------------+
Figure 3: TTZ ISN sub TLV
A TTZ ESN sub-TLV contains the information about a number of TTZ ES
neighbors connected to a TTZ edge router. It has the format below.
TTZ ESN sub-TLV Length in Byte
+----------------------+
| Sub-Type = 2 | 1
+----------------------+
| Length | 4 + n*IDLength
+----------------------+
| Default Metric | 1
+----------------------+
| Delay Metric | 1
+----------------------+
| Expense Metric | 1
+----------------------+
| Error Metric | 1
+----------------------+
| Neighbor ID | IDLength
+----------------------+
| . . . . . . |
+----------------------+
| Neighbor ID | IDLength
+----------------------+
Figure 4: TTZ ESN sub TLV
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6. Updating LSPs for TTZ
6.1. Updating LSP for a TTZ Internal Router
A TTZ internal router adds a TTZ TLV into its LSP after it receives
an LSP containing a TTZ TLV with T = 1 or a CLI command triggering
TTZ information distribution for migration. The TLV has a TTZ ID set
to the ID of the TTZ and E bit in Flags set to 0 indicating TTZ
internal router. The router floods its LSP to its neighbors in the
TTZ.
When a router inside the TTZ receives a link state packet (LSP)
containing a TTZ TLV from a neighboring router in the TTZ, it stores
the link state and floods the link state to the other neighboring
routers in the TTZ.
6.2. Updating LSP for a TTZ Edge Router
For every edge router of a TTZ, it updates its LSP in three steps and
floods the LSP to all its neighbors.
At first, a TTZ edge router adds a TTZ TLV into its LSP after it
receives an LSP containing a TTZ TLV with T = 1 or a CLI command
triggering TTZ information distribution for migration. The TLV has a
TTZ ID set to the ID of the TTZ, E bit in Flags set to 1 indicating
TTZ edge router and a TTZ ISN sub TLV. The sub TLV contains the
information about the TTZ IS neighbors connected to the TTZ edge
router. In addition, the TLV may has a TTZ ESN sub TLV comprising
the information about the TTZ end systems connected to the TTZ edge
router.
Secondly, it adds each of the other TTZ edge routers as an IS
neighbor into the Intermediate System Neighbors TLV in the LSP after
it receives an LSP containing a TTZ TLV with M = 1 or a CLI command
activating migration to TTZ. The metric to the neighbor is the
metric of the shortest path to the edge router within the TTZ.
In addition, it adds a Prefix Neighbors TLV into its LSP. The TLV
contains a number of address prefixes in the TTZ to be reachable from
outside of the TTZ.
And then it removes the IS neighbors corresponding to the IS
neighbors in the TTZ TLV (i.e., in the TTZ ISN sub TLV) from
Intermediate System Neighbors TLV in the LSP, and the ES neighbors
corresponding to the ES neighbors in the TTZ TLV (i.e., in the TTZ
ESN sub TLV) from End System Neighbors TLV in the LSP. This SHOULD
be done after it receives the LSPs for virtualizing TTZ from the
other TTZ edges for a given time.
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7. Establishing Adjacencies
7.1. Discover TTZ Neighbor over Normal Adjacency
For two routers A and B connected by a P2P circuit and having a
normal adjacency, they discover TTZ each other through including a
TTZ TLV containing a TTZ ID in their hello packets. If two ends of
the circuit have the same TTZ ID, A and B are TTZ neighbors;
otherwise, they are not TTZ neighbors, but normal neighbors.
For a number of routers connected through a broadcast circuit and
having normal adjacencies among them, they also discover TTZ each
other through including a TTZ TLV containing a TTZ ID in their hello
packets. The DIS for the circuit "forms" TTZ adjacency with each of
the other routers if all the routers attached to the circuit have the
same TTZ ID configured on the connections to the circuit and included
in their hello packets; otherwise, they are not TTZ neighbors, but
still normal neighbors.
7.2. Establishing TTZ Adjacencies
When a router (say A) is connected via a P2P circuit to another
router (say B) and there is not any adjacency between them over the
circuit, a user configures TTZ on two ends of the circuit to form a
TTZ adjacency.
Routers A and B include a TTZ TLV containing a TTZ ID in their hello
packets. If two routers have the same TTZ IDs in their hellos, an
adjacency between these two routers is to be formed; otherwise, no
adjacency is formed.
For a number of routers connected through a broadcast circuit and
having no adjacency among them, they start to form TTZ adjacencies
after TTZ is configured on the circuit and a TTZ TLV with a TTZ ID is
included in their hello packets. The DIS for the circuit forms TTZ
adjacency with each of the other routers if all the routers attached
to the circuit have the same TTZ ID configured on the connections to
the circuit and included in the hello packets; otherwise, the DIS
does not form any adjacency with any router attached to the circuit.
7.3. Adjacency between TTZ Edge and Router outside
For an edge router in a TTZ, in addition to establishing adjacencies
with other routers in the TTZ that have connections with the edge
router, it forms an adjacency with any router outside of the TTZ that
has a connection with the edge router.
When the edge router synchronizes its link state database with the
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router outside of the TTZ, it sends the router outside of the TTZ the
information about all the LSPs except for the LSPs belong to the TTZ
that are hidden from any router outside of the TTZ.
At the end of the link state database synchronization, the edge
router originates its own LSP and sends this LSP to the router
outside of the TTZ. This LSP contains two groups of circuits.
The first group of circuits are the circuits connecting to the
routers outside of the TTZ from this TTZ edge router. The second
group of circuits are the "virtual" circuits connecting to the other
TTZ edge routers from this TTZ edge router.
From the point of view of the router outside of the TTZ, it sees the
other end as a normal router and forms the adjacency in the same way
as a normal router. It is not aware of anything about its
neighboring TTZ. From the LSPs related to the TTZ edge router in the
other end, it knows that the TTZ edge router is connected to each of
the other TTZ edge routers and some routers outside of the TTZ.
8. Distribution of LSPs
LSPs can be divided into two classes according to their
distributions. One class of LSPs is distributed within a TTZ. The
other is distributed through a TTZ.
8.1. Distribution of LSPs within TTZ
Any LSP generated for a TTZ internal router in a TTZ is distributed
within the TTZ. It will not be distributed to any router outside of
the TTZ.
Any pseudo node LSP generated for a broadcast network inside a TTZ,
is distributed within the TTZ. It will not be distributed to any
router outside of the TTZ.
8.2. Distribution of LSPs through TTZ
Any LSP about a link state outside of a TTZ received by an edge
router of the TTZ is distributed through the TTZ; and any LSP about a
link state for the TTZ generated by a TTZ edge router is distributed
through the TTZ.
For example, when an edge router of a TTZ receives an LSP for a link
state outside of the TTZ from a router outside of the TTZ, it floods
it to its neighboring routers both inside the TTZ and outside of the
TTZ. This LSP may be any LSP such as a router LSP that is
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distributed in a domain.
The routers in the TTZ continue to flood the LSP. When another edge
router of the TTZ receives the LSP, it floods the LSP to its
neighboring routers both outside of the TTZ and inside the TTZ.
9. Computation of Routing Table
The computation of the routing table on a router outside of a TTZ is
the same as that described in ISO/SEC 10589. On a router in a TTZ,
the computation of the routing table has the same procedure flow as
that described in ISO/SEC 10589, with one exception. A router in a
TTZ MUST ignore the circuits in the router LSPs generated by the edge
routers of the TTZ for virtualizing the TTZ.
The routing table on a router inside the TTZ is computed through
using the link state database (LSDB) containing the LSPs for the
topology of the TTZ and the LSPs for the topology outside of the TTZ.
That is that the shortest path to every destination both inside the
TTZ and outside of the TTZ is computed over all the circuits
including the circuits inside the TTZ and the circuits outside of the
TTZ.
10. Operations
10.1. Configuring TTZ
This section proposes some options for configuring a TTZ.
1. Configuring TTZ on Every Circuit in TTZ
If every circuit in a TTZ is configured with a same TTZ ID as a TTZ
circuit, the TTZ is determined. A router with some TTZ circuits and
some normal circuits is a TTZ edge router. A router with only TTZ
circuits is a TTZ internal router.
2. Configuring TTZ on Every Router in TTZ
We may configure a same TTZ ID on every router in the TTZ, and on
every edge router's circuits connecting to the routers in the TTZ.
A router configured with the TTZ ID on some of its circuits is a TTZ
edge router. A router configured with the TTZ ID only is a TTZ
internal router. All the circuits on a TTZ internal router are TTZ
circuits. This option is simpler than the above one.
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10.2. Smooth Migration to TTZ
For a group of routers and a number of circuits connecting the
routers in an area, making them transfer to work as a TTZ without any
service interruption may take a few of steps.
At first, users configure the TTZ feature on every router in the TTZ.
In this stage, a router does not update its LSPs. It will discover
its TTZ neighbors.
Secondly, after configuring the TTZ, users issue a CLI command on one
router in the TTZ, which triggers every router in the TTZ to
distribute TTZ information among the routers in the TTZ. When the
router receives the command, it updates its LSP by adding a TTZ TLV,
and distributes the LSP to its TTZ neighbors. The LSP has T = 1 in
Flags in the TTZ TLV (indicating TTZ information generation and
distribution for migration). When a router in the TTZ receives the
LSP with T = 1, it updates its LSP by adding a TTZ TLV. In this
stage, every router in the TTZ has dual roles. One is to function as
a normal router. The other is to generate and distribute TTZ
information.
Thirdly, users may check whether every router in the TTZ is ready for
transferring to work as a TTZ router. A router in the TTZ is ready
after it has received all the necessary information from all the
routers in the TTZ. This information may be displayed on a router
through a CLI command.
And then users activate the TTZ through using a CLI command such as
migrate to TTZ on one router in the TTZ. The router transfers to
work as a TTZ router, updates its LSP with M = 1 in the TTZ TLV
(indicating Migrating to TTZ) after it receives the command.
After a router in the TTZ receives the LSP with M = 1, it also
transfers to work as a TTZ router. Thus, activating the TTZ on one
TTZ router makes every router in the TTZ transfer to work as a TTZ
router, which computes routes through using the TTZ topology and the
topology outside of the TTZ.
For an edge router of the TTZ, transferring to work as a TTZ router
comprises updating its LSP to virtualize the TTZ by adding each of
the other TTZ edge routers as an IS neighbor and flooding this LSP to
all its direct neighboring routers. And then, the TTZ edge router
removes the IS neighbors corresponding to the IS neighbors in the TTZ
TLV (i.e., in the TTZ ISN sub TLV) from Intermediate System Neighbors
TLV in the LSP
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10.3. Adding a Router into TTZ
When a non TTZ router (say R1) is connected via a P2P circuit to a
TTZ router (say T1) working as TTZ and there is a normal adjacency
between them over the circuit, a user can configure TTZ on two ends
of the circuit to add R1 into the TTZ to which T1 belongs. They
discover TTZ each other in the same way as described in section 7.1.
When a number of non TTZ routers are connected via a broadcast
circuit to a TTZ router (say T1) working as TTZ and there are normal
adjacencies among them, a user configures TTZ on the connection to
the circuit on every router to add the non TTZ routers into the TTZ
to which T1 belongs. The DIS for the circuit "forms" TTZ adjacency
with each of the other routers if all the routers have the same TTZ
ID configured on the connections to the circuit.
When a router (say R1) is connected via a P2P circuit to a TTZ router
(say T1) and there is not any adjacency between them over the
circuit, a user can configure TTZ on two ends of the circuit to add
R1 into the TTZ to which T1 belongs. R1 and T1 will form an
adjacency in the same way as described in section 7.2.
When a router (say R1) is connected via a broadcast circuit to a
group of TTZ routers on the circuit and there is not any adjacency
between R1 and any over the circuit, a user can configure TTZ on the
connection to the circuit on R1 to add R1 into the TTZ to which the
TTZ routers belong. R1 starts to form an adjacency with the DIS for
the circuit after the configuration.
11. Security Considerations
The mechanism described in this document does not raise any new
security issues for the IS-IS protocols.
12. IANA Considerations
This document requires the allocation for a new TLV and a couple of
new sub TLVs in the new TLV. IANA is requested to assign a new Type
(value 150 is suggested) for new TLV TTZ as follows:
+========+========+=======+=======+=======+=======+
| Type | Name | IIH | LSP | SNP | Purge |
+========+========+=======+=======+=======+=======+
| 150 | TTZ | Y | Y | N | N |
+========+========+=======+=======+=======+=======+
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This document defines two new Sub-TLVs in TLV 150. The values below
are suggested for them subject to assignment by IANA or Expert
review.
+========+==================================+
| Type | Name and Description |
+========+==================================+
| 1 | TTZ ISN, TTZ IS Neighbors |
+--------+----------------------------------+
| 2 | TTZ ESN, TTZ ES Neighbors |
+========+==================================+
13. Contributors
Veerendranatha Reddy Vallem
Huawei Technologies
Bangalore
India
Email: veerendranatharv@huawei.com
William McCall
cisco Systems, Inc.
Bellevue, WA
USA
wimccall@cisco.com
14. Acknowledgement
The author would like to thank Acee Lindem, Abhay Roy, Dean Cheng,
Wenhu Lu, Russ White, Tony Przygienda, Bingzhang Zhao, and Lin Han
for their valuable comments.
15. 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,
<https://www.rfc-editor.org/info/rfc2119>.
[RFC7142] Shand, M. and L. Ginsberg, "Reclassification of RFC 1142
to Historic", RFC 7142, DOI 10.17487/RFC7142,
February 2014, <https://www.rfc-editor.org/info/rfc7142>.
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[RFC1195] Callon, R., "Use of OSI IS-IS for routing in TCP/IP and
dual environments", RFC 1195, DOI 10.17487/RFC1195,
December 1990, <https://www.rfc-editor.org/info/rfc1195>.
[RFC5305] Li, T. and H. Smit, "IS-IS Extensions for Traffic
Engineering", RFC 5305, DOI 10.17487/RFC5305,
October 2008, <https://www.rfc-editor.org/info/rfc5305>.
[RFC5029] Vasseur, JP. and S. Previdi, "Definition of an IS-IS Link
Attribute Sub-TLV", RFC 5029, DOI 10.17487/RFC5029,
September 2007, <https://www.rfc-editor.org/info/rfc5029>.
Authors' Addresses
Huaimo Chen
Futurewei
Boston, MA
USA
Email: huaimo.chen@futurewei.com
Alvaro Retana
Futurewei
Raleigh, NC
USA
Email: alvaro.retana@futurewei.com
Richard Li
Futurewei
2330 Central expressway
Santa Clara, CA
USA
Email: richard.li@futurewei.com
Anil Kumar S N
RtBrick
Bangalore
India
Email: anil.ietf@gmail.com
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Ning So
Plano, TX 75082
USA
Email: ningso01@gmail.com
Vic Liu
USA
Email: liu.cmri@gmail.com
Mehmet Toy
Verizon
USA
Email: mehmet.toy@verizon.com
Lei Liu
Fijitsu
USA
Email: liulei.kddi@gmail.com
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