One document matched: draft-ietf-mpls-mgmt-overview-03.txt
Differences from draft-ietf-mpls-mgmt-overview-02.txt
Network Working Group Thomas D. Nadeau
Internet Draft Cisco Systems, Inc.
Category: Informational
Expires: August 2003 Cheenu Srinivasan
Parama Networks, Inc.
Adrian Farrel
Movaz Networks, Inc.
February 2003
Multiprotocol Label Switching (MPLS) Management Overview
draft-ietf-mpls-mgmt-overview-03.txt
Status of this Memo
This document is an Internet-Draft and is in full
conformance with all provisions of Section 10 of RFC 2026
[RFC2026].
Internet-Drafts are working documents of the Internet
Engineering Task Force (IETF), its areas, and its working
groups. Note that other groups may also distribute working
documents as Internet-Drafts.
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."
The list of current Internet-Drafts can be accessed at
http://www.ietf.org/ietf/1id-abstracts.txt.
The list of Internet-Draft Shadow Directories can be
accessed at http://www.ietf.org/shadow.html.
Abstract
A range of management Information Bases (MIBs) has been
developed to help model and manage the various aspects of
Multiprotocol Label Switching (MPLS) networks. These MIBs
are defined in separate drafts and RFCs that focus on the
specific areas of responsibility of their MIBs.
This memo describes the management architecture for MPLS
and indicates the inter-relationships between the different
MIBs used for MPLS network management.
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Table of Contents
1. Introduction 3
2. Terminology 3
3. The SNMP Management Framework 4
4. An Introduction to the MPLS Working Group MIB Modules 4
4.1. Structure of the MPLS MIB OID Tree 5
4.2. MPLS-TC-MIB 5
4.3. MPLS-LSR-MIB 6
4.4. MPLS-LDP-MIB 6
4.5. MPLS-LDP-GENERIC-MIB 6
4.6. MPLS-LDP-ATM-MIB 7
4.7. MPLS-LDP-FRAME-RELAY-MIB 7
4.8. MPLS-TE-MIB 7
4.9. MPLS-FTN-MIB 7
4.10. MPLS-LINK-BUNDLING-MIB 8
4.11. MIB Interdependencies 8
4.12. Dependencies on External MIBs 9
5. Tables, Scalars and Notifications in MPLS-LSR-MIB 9
5.1. Tables 9
5.2. Scalars 10
5.3. Notifications 10
5.4. Dependencies Between MIB Module Tables 10
6. Tables, Scalars and Notifications in the LDP MIB 11
6.1. MIB Modules 11
6.2. Tables 11
6.3. Scalars 12
6.4. Notifications 13
6.5. Dependencies Between MIB Module Tables 13
7. Tables, Scalars and Notifications in MPLS-TE-MIB 14
7.1. Tables 14
7.2. Scalars 15
7.3. Notifications 15
7.4. Dependencies Between MIB Module Tables 15
8. Tables, Scalars and Notifications in MPLS-FTN-MIB 16
8.1. Tables 16
8.2. Scalars 16
8.3. Notifications 16
8.4. Dependencies Between MIB Tables 16
9. Tables and Objects in MPLS-LINK-BUNDLING-MIB 16
9.1. Tables 16
9.2. Scalars 17
9.3. Notifications 17
9.4. Dependencies Between MIB Module Tables 17
10. MIB Table Dependencies Between MPLS MIBs 18
11. A Note on Interfaces 18
11.1. MPLS Tunnels as Interfaces 19
11.2. Application of the Interfaces Group to TE Links 19
11.3. References to Interface MIB Objects from Other MPLS MIBs 20
12. Management Options 21
13. Related IETF MIB Modules 22
13.1. pwe3 Working Group MIB Modules 22
13.2. ppvpn Working Group MIB Modules 23
13.2.1. PPVPN-MPLS-VPN-MIB 23
13.3. ccamp Working Group MIBs 23
14. Traffic Engineering Working Group TE MIB 23
14.1. Choosing Between TE MIBs Modules 24
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15. Security Considerations 24
16. Acknowledgements 24
17. Intellectual Property Consideration 25
18. Normative References 25
19. Informative References 26
20. Authors' Addresses 28
21. Full Copyright Statement 29
1. Introduction
This memo describes the Management Architecture for Multi-
Protocol Label Switching (MPLS) [RFC3031]. In particular,
it describes how the managed objects defined in various
MPLS related Management Information Base (MIB) documents
model different aspects of MPLS. Furthermore, this document
explains the interactions and dependencies between each of
these MIBs.
For additional information, this draft also includes a
brief note on MIBs produced by the Pseudo Wire Emulation
Edge to Edge (pwe3), Provider Provisioned Virtual Private
Network (ppvpn), Common Control and Measurement Plane
(ccamp), and Internet Traffic Engineering (tewg) working
groups.
The draft begins with a brief outline of the SNMP
framework. This is not intended to be a complete reference
on SNMP, but is provided to give context to the rest of the
draft and to indicate reference material for readers that
need to know more about SNMP.
This draft does not propose any additions to the MPLS MIB
framework, nor define any standards for the Internet
community. It is an informational draft. In all cases,
the reader is advised to turn to the draft or RFC that
defines the MIB in question for further information.
Comments should be made directly to the MPLS mailing list
at mpls@uu.net.
2. Terminology
This document uses terminology from the MPLS architecture
document [RFC3031] and the following MPLS related MIBs:
MPLS TC MIB [TCMIB], MPLS LSR MIB [LSRMIB], MPLS TE MIB
[TEMIB], MPLS LDP MIB [LDPMIB], MPLS FTN MIB [FTNMIB], MPLS
LINK BUNDLING MIB [LBMIB], and PPVPN MPLS VPN MIB [VPNMIB].
Throughout this document hyphenated MIB names (such as MPLS-
TE-MIB) should be taken to refer to specific MIB modules.
Non-hyphenated MIB names (such as MPLS LDP MIB) indicate
MIB documents.
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3. The SNMP Management Framework
The SNMP Management Framework presently consists of five
major components:
- An overall architecture, described in RFC 2571
[RFC2571].
- Mechanisms for describing and naming objects and events
for the purpose of management. The first version of
this Structure of Management Information (SMI) is
called SMIv1 and described in STD 16, RFC 1155
[RFC1155], STD 16, RFC 1212 [RFC1212] and STD 16, RFC
1215 [RFC1215]. The second version, called SMIv2, is
described in STD 58, RFC 2578 [RFC2578], STD 58, RFC
2579 [RFC2579] and STD 58, RFC 2580 [RFC2580].
- Message protocols for transferring management
information. The first version of the SNMP message
protocol is called SNMPv1 and described in STD 15, RFC
1157 [RFC1157]. A second version of the SNMP message
protocol, which is not an Internet standards track
protocol, is called SNMPv2c and described in RFC 1901
[RFC1901] and RFC 1906 [RFC1906]. The third version of
the message protocol is called SNMPv3 and described in
RFC 1906 [RFC1906], RFC 2572 [RFC2572] and RFC 2574
[RFC2574].
- Protocol operations for accessing management
information. The first set of protocol operations and
associated PDU formats is described in STD 15, RFC 1157
[RFC1157]. A second set of protocol operations and
associated PDU formats is described in RFC 1905
[RFC1905].
- A set of fundamental applications described in RFC 2573
[RFC2573] and the view-based access control mechanism
described in RFC 2575 [RFC2575].
A more detailed introduction to the current SNMP Management
Framework can be found in RFC 2570 [RFC2570].
Managed objects are accessed via a virtual information
store, termed the Management Information Base or MIB.
Objects in the MIB are defined using the mechanisms defined
in the SMI.
4. An Introduction to the MPLS Working Group MIB Modules
This section addresses the MIB documents produced by the
MPLS working group, namely MPLS TC MIB, MPLS LSR MIB, MPLS
TE MIB, MPLS LDP MIB, MPLS FTN MIB, and MPLS LINK BUNDLING
MIB. The rest of this section briefly describes the
following:
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- the MPLS Object Identifier (OID) tree structure and the
position of different MPLS related MIBs on this tree;
- the purpose of each of the MIB modules within the MIB
documents, what it can be used for, and how it relates
to the other MIB modules.
4.1. Structure of the MPLS MIB OID Tree
The MPLS MIB OID tree has the following structure.
transmission -- RFC1213-MIB [RFC1213]
|
+- mplsMIB (166?) -- MPLS-TC-MIB
| |
| +- mplsTCMIB (1) -- MPLS-TC-MIB
| |
| +- mplsLsrMIB (2) -- MPLS-LSR-MIB
| |
| +- mplsTeMIB (3) -- MPLS-TE-MIB
| |
| +- mplsLdpMIB (4) -- MPLS-LDP-MIB
| |
| +- mplsLdpAtmMIB (5) -- MPLS-LDP-ATM-MIB
| |
| +- mplsLdpFrameRelayMIB (6) -- MPLS-LDP-FRAME-RELAY-MIB
| |
| +- mplsLdpGenericMIB (7) -- MPLS-LDP-GENERIC-MIB
| |
| +- mplsFTNMIB (8) -- MPLS-FTN-MIB
?
+- linkBundlingMIB (TBD) -- LINK-BUNDLING-MIB
Note: OID information is pending assignment by IANA.
Conflicts and absent information shown above will be
included in a later revision.
4.2. MPLS-TC-MIB
MPLS-TC-MIB defines textual conventions [RFC2579] and
object identities that may be common to MPLS related MIB
modules. These conventions allow multiple MIB modules to
use the same syntax and format for a concept that is shared
between the MIB modules.
For example, labels are a central part of MPLS and need to
be presented in many of the MIB modules. The textual
convention for representing an MPLS label is defined in
MPLS-TC-MIB.
All of the other MPLS MIBs import this MIB so that they can
use one or more of the textual conventions it defines.
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4.3. MPLS-LSR-MIB
MPLS-LSR-MIB describes managed objects for modeling a MPLS
Label Switch Router (LSR). This puts it at the heart of
the management architecture for MPLS.
This MIB module is used to model and manage the basic label
switching behavior of an MPLS LSR. It represents the label
forwarding information base (LFIB) of the LSR and provides
a view of the LSPs that are being switched by the LSR in
question.
Since basic MPLS label switching is common to all MPLS
applications, this MIB is referenced by many of the other
MPLS MIB modules.
In general, MPLS-LSR-MIB provides a model of incoming
labels on MPLS-enabled interfaces being mapped to outgoing
labels on MPLS-enabled interfaces via a conceptual object
called an MPLS cross-connect. MPLS cross-connect entries
and their properties are represented in MPLS-LSR-MIB and
are typically referenced by other MIB modules in order to
refer to the underlying MPLS LSP.
For example, MPLS-TE-MIB models traffic engineered tunnels.
These tunnels map to one more underlying MPLS LSPs. MPLS-TE-
MIB refers to the underlying LSP by pointing to cross-
connect entries in MPLS-LSR-MIB.
4.4. MPLS-LDP-MIB
MPLS-LDP-MIB describes managed objects used to model and
manage the MPLS Label Distribution Protocol (LDP)
[RFC3036]. LDP is one of the MPLS protocols used to
distribute labels and establish LSPs.
This MIB module contains objects common to all LDP
implementations. For an LDP implementation, this MIB
module must always be implemented along with one or more of
the other LDP MIB modules from the following sections.
4.5. MPLS-LDP-GENERIC-MIB
This MIB module must be supported by LDP implementations if
LDP uses a Per Platform Label Space. This MIB Module
contains tables for configuring MPLS Generic Label Ranges
Although the LDP Specification does not provide a way for
configuring Label Ranges for Generic Labels, the MIB does
provide a way to reserve a range of generic labels because
this was thought to be useful by the working group.
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4.6. MPLS-LDP-ATM-MIB
This MIB module must be supported by LDP implementations if
LDP uses ATM as the Layer 2 medium. Tables in this MIB
module allow for configuring LDP to use ATM.
4.7. MPLS-LDP-FRAME-RELAY-MIB
This MIB module must be supported by LDP implementations if
LDP uses FRAME RELAY as the Layer 2 medium. Tables in this
MIB module allow for configuration of LDP to use Frame
Relay.
4.8. MPLS-TE-MIB
MPLS-TE-MIB describes managed objects that are used to
model and manage MPLS Traffic Engineered (TE) Tunnels.
This MIB module is based around a table that represents TE
tunnels that either originate from, traverse via or
terminate on the LSR in question or. The MIB module
provides configuration and statistics objects needed for TE
tunnels.
4.9. MPLS-FTN-MIB
MPLS-FTN-MIB describes managed objects that are used to
model and manage the MPLS FEC-to-NHLFE (FTN) mappings that
take place at an ingress LER.
A Label Edge Router (LER) is an LSR placed at the edge of
an MPLS domain and passes traffic into and out of the MPLS
domain. An ingress LER is responsible for classifying data
and assigning it to a suitable LSP.
This classification is done using Forwarding Equivalency
Classes (FECs) that define the common attributes of data
(usually packets) that will be treated in the same way.
Once data has been classified it can be handed off to an
LSP through the Next Hop Label Forwarding Entry (NHLFE).
In the case of an IP-to-MPLS mapping, the FEC objects
describe IP 5-tuples representing IP source and destination
ranges, protocol ranges etc. Matching IP packets are mapped
to an NHLFE that can either be an MPLS LSP or an MPLS TE
tunnel.
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4.10. MPLS-LINK-BUNDLING-MIB
MPLS-LINK-BUNDLING-MIB describes managed objects that are
used to model and manage link bundling in an MPLS network.
The link bundling feature is designed to aggregate one or
more similar data channels between a pair of LSRs into a
bundled link. The data channel is referred to as a TE link
and is a sub-interface capable of carrying MPLS traffic
engineered traffic.
A link bundle is a sub-interface that bonds the traffic of
a group of one or more TE links.
4.11. MIB Interdependencies
This section provides an overview of the relationship
between the MPLS MIB modules described above. More details
of these relationships are given below once the MIB modules
have been discussed in more detail.
The arrows in the following diagram show a 'depends on'
relationship. A "MIB module A depends on MIB module B"
relationship means that MIB module A uses a structure or
textual convention defined in MIB module B, or that MIB
module A contains a pointer (index or RowPointer) to an
object in MIB module B.
+-------> MPLS-TC-MIB
| ^
| |
| MPLS-LSR-MIB <-----------------+
| |
+<------- MPLS-LDP-MIB ----------------->+
| ^ |
| | |
| +<-- MPLS-LDP-GENERIC-MIB |
| | |
| +<-- MPLS-LDP-ATM-MIB |
| | |
| +<-- MPLS-LDP-FRAME-RELAY-MIB |
| |
+<------- MPLS-TE-MIB ------------------>+
| ^ |
| | |
+<------- MPLS-FTN-MIB ----------------->+
Thus:
- All the MPLS MIB modules depend on MPLS-TC-MIB.
- MPLS-LDP-MIB, MPLS-TE-MIB and MPLS-FTN-MIB contain
references to objects in MPLS-LSR-MIB.
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- MPLS-LDP-GENERIC-MIB, MPLS-LDP-ATM-MIB and MPLS-LDP-
FRAME-RELAY-MIB contain references to objects in MPLS-
LDP-MIB.
- MPLS-FTN-MIB contains references to objects in MPLS-TE-
MIB.
4.12. Dependencies on External MIBs
With the exception of MPLS-TC-MIB, all the MPLS MIB modules
have dependencies on the Interfaces MIB [RFC2863]. They
reference MPLS-capable interfaces in the Interfaces Table
(ifTable) in this MIB.
The Interfaces Group of MIB II defines generic managed
objects for managing interfaces. The MPLS MIBs contain
media-specific extensions to the Interfaces Group for
managing MPLS interfaces.
The MPLS MIB modules assume the interpretation of the
Interfaces Group to be in accordance with [RFC2863] which
states that ifTable contains information on the managed
resource's interfaces and that each sub-layer below the
internetwork layer of a network interface is considered an
interface.
Thus, the MPLS interface is represented as an entry in
ifTable.
The inter-relation of entries in ifTable is defined by the
Interfaces Stack Group defined in [RFC2863].
5. Tables, Scalars and Notifications in MPLS-LSR-MIB
5.1. Tables
MPLS-LSR-MIB contains the following tables.
- The interface configuration table
(mplsInterfaceConfTable) is used for enabling MPLS on
MPLS-capable interfaces.
- The in-segment (mplsInSegmentTable) and out-segment
(mplsOutSegmentTable) tables are used to configure and
monitor LSP segments carrying data into and out of the
LSR, respectively.
- The cross-connect table (mplsXCTable) is used to
associate in and out segments in order to form a cross-
connect (i.e. to represent an LSP transiting the LSR).
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- The label stack table (mplsLabelStackTable) allows the
specification of multi-label stacks to be imposed on a
given LSP at this LSR
- The Traffic Parameter table (mplsTrafficParamTable) is
used to specify and record LSP related traffic
parameters.
- The MPLS in-segment (mplsInSegmentPerfTable) and out-
segment (mplsOutSegmentPerfTable) performance tables
contain objects to measure the performance of LSPs.
- The MPLS interface performance table
(mplsInterfacePerfTable) has objects to measure MPLS
performance on a per-interface basis.
5.2. Scalars
Where tables in the MIB module have arbitrary indexes,
scalars are provided to supply the next available index.
This applies to mplsOutSegmentTable, mplsXCTable,
mplsLabelStackTable and mplsTrafficParamTable.
mplsMaxLabelStackDepth defines the maximum size of a
imposed label stack supported at this LSR.
mplsXCTrapEnable is used to enable and disable
notifications from MPLS-LSR-MIB.
5.3. Notifications
MPLS-LSR-MIB can issue two notifications (if notifications
are enabled).
- mplsXCUp reports when a cross-connect becomes active.
- mplsXCDown reports when a cross-connect becomes
inactive.
5.4. Dependencies Between MIB Module Tables
The tables in MPLS-LSR-MIB are related as shown on the
diagram below. The arrows indicate a reference from one
table to another.
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mplsInterfacePerfTable
^
|
mplsInterfaceConfTable
^ ^
| |
+----+ +----+
| |
| mplsTrafficParamTable | mplsLabelStackTable
| ^ ^ | ^
| | | | |
mplsInSegmentTable mplsOutSegmentTable
| | | |
| +----> mplsXCTable <----+ |
V V
mplsInSegmentPerfTable mplsOutSegmentPerfTable
6. Tables, Scalars and Notifications in the LDP MIB
6.1. MIB Modules
The MIB for LDP contains four MIB modules. This structure
makes it easier for an implementation to select only those
parts of the MIB that are relevant to it. The MIB Modules
are the MPLS-LDP-MIB, the MPLS-LDP-GENERIC-MIB, the MPLS-
LDP-ATM-MIB and the MPLS-LDP-FRAME-RELAY-MIB.
The MPLS-LDP-MIB defines objects which are specific to LDP
without any Layer 2 objects. The MPLS-LDP-GENERIC-MIB
defines Layer 2 Per Platform Label Space objects for use
with the MPLS-LDP-MIB and for use on Ehternet. The MPLS-
LDP-ATM-MIB defines Layer 2 Asynchronous Transfer Mode
(ATM) objects for use with the MPLS-LDP-MIB. The MPLS-LDP-
FRAME-RELAY-MIB defines Layer 2 FRAME-RELAY objects for use
with the MPLS-LDP-MIB.
The MPLS-LDP-MIB Module MUST be supported and at least one
of the Layer 2 MIB Modules MUST be supported.
6.2. Tables
The tables in the LDP MIB for configuring the LDP behavior
of an LSR are as follows.
- The LDP Entity Table (mplsLdpEntityTable) provides a
way to configure the LSR for using LDP. There must be
at least one LDP Entity for the LSR to support LDP.
Each entry/row in this table represents a single LDP
Entity.
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- Several tables exist to help configure LDP's use of
labels. These are spread through the MIB modules
described in the previous section. They are:
mplsLdpEntityGenLRTable, mplsLdpEntityAtmParmsTable and
mplsLdpEntityAtmLRTable,
mplsLdpEntityFrameRelayParmsTable and
mplsLdpEntityFrLRTable. They are used to configure
generic, ATM and Frame Relay labels as their names
suggest.
- The LDP Peer Table (mplsLdpPeerTable) is a read-only
table, that contains information about LDP Peers known
to LDP Entities.
- The LDP Hello Adjacencies Table
(mplsLdpHelloAdjacencyTable) is a table of all
adjacencies between all LDP Entities and all LDP Peers.
- Several tables exist to monitor and control LDP
sessions. The LDP Session Table (mplsLdpSessionTable)
represents sessions between an LDP Entity and a Peer.
The mplsLdpAtmSesTable and mplsLdpFrameRelaySesTable
contain session information specific to ATM.
- The MPLS LDP Session Peer Address Table
(mplsLdpSesPeerAddrTable) stores addresses learned
after session initialization via Address Message
advertisement.
- The LDP FEC Table (mplsFecTable) represents FEC
(Forwarding Equivalence Class) information that may be
in use on one or more LSPs. The LDP LSP FEC Table
(mplsLdpLspFecTable) shows the FECs associated with
each LSP.
- MPLS-LDP-MIB has a mapping table (mplsLdpLspTable)
which maps the LDP MIB's representation of LDP sessions
to the underlying LSR MIB's representation of the LSPs
created by these sessions by pointing to
mplsInSegmentTable, mplsOutSegmentTable and
mplsXCTable, respectively.
- Statistics may be gathered through the LDP Entity
Statistics Table (mplsLdpEntityStatsTable) and the LDP
Session Statistics Table (mplsLdpSesStatsTable)
6.3. Scalars
Where tables in the MIB have arbitrary indexes, scalars are
provided to supply the next available index. This applies
to the mplsLdpEntityTable and the mplsFecTable.
Two scalars exist to configure the LSR. The LSR ID is set in
mplsLdpLsrId, and the loop detection capabilities are reported
in mplsLdpLsrLoopDetectionCapable
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6.4. Notifications
MPLS-LDP-MIB defines four notifications that a device can
issue.
- mplsLdpInitSesThresholdExceeded is reported when the
number of Session Initialization messages exceeds a
configured threshold.
- mplsLdpPVLMismatch is issued if the Path Vector Limit
for a configured Entity and Peer do not match.
- mplsLdpSessionUp and mplsLdpSessionDown report the
transition of Session state.
No scalar object is provided to enable and disable
notifications from MPLS-LDP-MIB. Instead, the implementer
is referred to [RFC2573].
6.5. Dependencies Between MIB Module Tables
The many tables in the four LDP MIB modules are related as
shown on the diagram below. The arrows indicate a
reference from one table to another. Note that in many
cases the reference is through an augmentation of the
referenced table.
mplsLdpEntityGenLRTable ------------->+
mplsLdpEntityAtmParmsTable ---------->+
mplsLdpEntityAtmLRTable ------------->+
mplsLdpEntityFrameRelayParmsTable --->+
mplsLdpEntityFrLRTable -------------->+
mplsLdpEntityStatsTable ------------->+
|
mplsLdpHelloAdjacencyTable |
| |
| mplsLdpEntityTable <--+
| ^ ^
V | |
mplsLdpPeerTable <-+- mplsLdpSesPeerAddrTable
^ |
| V
mplsLdpSessionTable
^ ^
| |
mplsLdpSesStatsTable ------+ +-- mplsLdpLspFecTable
mplsLdpAtmSesTable --------+ | | |
mplsLdpFrameRelaySesTable--+ | | V
| | mplsFecTable
| V
+-- mplsLdpLspTable
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7. Tables, Scalars and Notifications in MPLS-TE-MIB
7.1. Tables
MPLS-TE-MIB contains the following tables.
- The Tunnel table (mplsTunnelTable) is used to configure
and report MPLS tunnels. Note that reporting of
tunnels in this table at transit LSRs is optional.
Entries in the mplsTunnelTable are indexed by four
objects. The source and destination LSR Ids give
context to the entry, and an index
(mplsTunnelIndexIndex) identifies the tunnel itself.
However, the fourth index (mplsTunnelInstance) may give
rise to some confusion since its usage is not clearly
explained.
The description says: "Uniquely identifies an instance
of a tunnel. It is useful to identify multiple
instances of tunnels for the purposes of backup and
parallel tunnels." In the case of backup tunnels,
multiple instances of the same tunnel may be defined,
but only one is active at any time. Different instances
may have different properties (such as explicit
routes), and one instance may be set up to protect
against failure of another. Parallel tunnels may be
used to provide load sharing or protection.
The mplsTunnelInstancePriority object is used to
indicate the precedence of tunnels with the same LSR
Ids and mplsTunnelIndexIndex value. The
mplsTunnelPrimaryInstance object gives a quick
reference back to the preferred instance of the tunnel.
The mplsTunnelIndexIndex value is typically signaled as
the Tunnel ID, and the mplsTunnelInstance as the LSP Id
in protocols where both fields exist. In protocols
where there is only one identifying index (usually
known as the LSP Id), only the mplsTunnelIndexIndex is
signaled.
- The Resource table (mplsTunnelResourceTable) is used to
configure resources to be requested on this tunnel.
The CRLDP resource table (mplsTunnelCRLDPResTable) is
used to request additional resource details that are
specific to tunnels signaled using CR-LDP.
- The routes requested, computed and actually used for a
tunnel are found in the Tunnel Hop Table
(mplsTunnelHopTable) Tunnel Computed Hop Table
(mplsTunnelCHopTable) and Tunnel Actual Hop Table
(mplsTunnelARHopTable).
- Statistics about the performance of tunnels may be
gathered through the Tunnel Performance Table
(mplsTunnelPerfTable).
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7.2. Scalars
Where tables in the MIB have arbitrary indexes, scalars are
provided to supply the next available index. This applies
to the mplsTunnelTable, the mplsTunnelResourceTable and the
mplsTunnelHopTable.
Two scalars exist to configure the support for MPLS tunnels
on the LSR. mplsTunnelTEDistProto lists the signaling
methods and protocols supported. mplsTunnelMaxHops defines
the size of route that may be configured on the LSR.
Two further scalars enhance the statistics on the LSR by
counting the number of configured (mplsTunnelConfigured)
and active (mplsTunnelActive) tunnels.
The scalar mplsTunnelTrapEnable is used to enable and
disable notifications from MPLS-TE-MIB.
7.3. Notifications
MPLS-TE-MIB defines four notifications that a device can
issue.
- mplsTunnelUp and mplsTunnelDown report the transition
of Tunnel state.
- Rerouting and re-optimization of Tunnels paths are
reported by mplsTunnelRerouted and
mplsTunnelReoptimized.
7.4. Dependencies Between MIB Module Tables
The tables in MPLS-TE-MIB are related as shown on the
diagram below. The arrows indicate a reference from one
table to another.
mplsTunnelPerfTable
|
V
mplsTunnelTable
^ ^
| |
mplsTunnelResourceTable +---mplsTunnelHopTable
^ |
| +---mplsTunnelCHopTable
mplsTunnelCRLDPResTable |
+---mplsTunnelARHopTable
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8. Tables, Scalars and Notifications in MPLS-FTN-MIB
8.1. Tables
MPLS-FTN-MIB contains the following tables.
- The FEC to NHLFE Table (mplsFTNTable) defines the FEC
to NHLFE rules to be applied to incoming packets, and
the actions to be taken on matching packets.
- The FEC to NHLFE Map Table (mplsFTNMapTable) provides
the capability to activate FTN rules defined in the
mplsFTNTable on specific interfaces in the system.
- Performance statistics for FTN rules are found in the
mplsFTNPerfTable.
8.2. Scalars
A single scalar (mplsFTNIndexNext) exists. It is used to
supply the next valid index into the mplsFTNTable.
8.3. Notifications
There are no notifications in this MIB.
8.4. Dependencies Between MIB Tables
The tables in MPLS-FTN-MIB are related as shown on the
diagram below. The arrows indicate a reference from one
table to another.
mplsFTNTable
^ ^
| |
mplsFTNMapTable mplsFTNPerfTable
9. Tables and Objects in MPLS-LINK-BUNDLING-MIB
9.1. Tables
MPLS-LINK-BUNDLING-MIB contains the following tables.
- The TE link table (teLinkTable) is used to specify TE
links, including bundled links, and their generic
traffic engineering parameters.
- The TE link descriptor table (teLinkDescriptorTable) is
used to list the TE link descriptors.
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- The TE link OSPF traffic engineering table
(teLinkOspfTeTable) is used for configuring OSPF
traffic engineering parameters associated with TE
links.
- The shared risk link group (SRLG) table
(teLinkSrlgTable) is used to specify the SRLGs
associated with TE links.
- The TE link bandwidth table (teLinkBandwidthTable) is
used to report priority-based bandwidth values
associated with TE links.
- The data-bearing channel table
(dataBearingChannelTable) is used to identify the data-
bearing channels that are associated with the TE links
and specify the data-bearing channel generic traffic
engineering parameters.
- The data-bearing channel link descriptor table
(dataBearingChannelDescriptorTable) is used to list the
data-bearing channel link descriptors.
- The data-bearing channel bandwidth table
(dataBearingChannelBandwidthTable) is used to report
priority-based bandwidth values associated with data-
bearing channels.
9.2. Scalars
A single scalar (linkBundlingTrapEnable) exists. It is
used to enable and disable notifications from the MIB from
being issued by a device.
9.3. Notifications
A single notification is defined.
- linkBundleMismatch is generated when a mismatch of TE
parameters between members of a bundled link is found.
9.4. Dependencies Between MIB Module Tables
The tables in MPLS-LINK-BUNDLING-MIB are related as shown
on the diagram below. The arrows indicate a reference from
one table to another.
Note that many of the associations between tables are
through a common index that is the ifIndex of the related
interface.
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teLinkTable
^
|
teLinkOspfLinkTable -----+
|
teLinkDescriptorTable ---+
|
teLinkSrlgTable ---------+
|
teLinkBandwidthTable ----+
dataBearingChannelTable
^
|
dataBearingChannelDescriptorTable ---+
|
dataBearingChannelBandwidthTable ----+
10. MIB Table Dependencies Between MPLS MIBs
Section 4.8 gave an overview of how the MPLS MIB modules
are related. Now that the tables in the MIB modules have
been introduced, it is possible to give a more detailed
diagram of these relationships.
MPLS-TC-MIB is left off the diagram since so many of the
MIB module tables use textual conventions from that MIB
module.
mplsLsrXCTable mplsLsrInSegmentTable
^ ^
| |
+---- mplsLdpLspTable
| |
mplsTunnelTable ------+ V
^ | mplsLsrOutSegmentTable
| |
mplsFTNTable ---------+
11. A Note on Interfaces
The Interfaces Group of MIB II defines generic managed
objects for managing interfaces. The MPLS MIBs make
references to interfaces in order that it can be clearly
determined where the procedures managed by the MIBs should
be performed. Additionally, the MPLS MIBs (notably the
MPLS-TE-MIB and the MPLS-LINK-BUNDLING-MIB) utilize
interface stacking within the Interface Group.
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11.1. MPLS Tunnels as Interfaces
The MPLS-TE-MIB builds on the concept of managing MPLS
Tunnels as logical interfaces. [RFC2863] states that the
interfaces table (ifTable) contains information on the
managed resource's interfaces, and that each sub-layer
below the internetwork layer of a network interface is
considered an interface. Thus, an MPLS Tunnel managed as
an interface is represented as an entry in the ifTable.
The interrelation of entries in the ifTable is defined by
the Interfaces Stack Group defined in [RFC2863].
When using MPLS Tunnels as interfaces, the interface stack
table might appear as follows:
+------------------------------------------------+
| MPLS tunnel interface ifType = mplsTunnel(150) |
+------------------------------------------------+
| MPLS interface ifType = mpls(166) |
+------------------------------------------------+
| Underlying layer |
+------------------------------------------------+
In the diagram above, "Underlying layer" refers to the
ifIndex of any interface type for which MPLS
internetworking has been defined. Examples include ATM,
Frame Relay, and Ethernet.
A detailed listing of the mapping between ifTable objects
and their use for MPLS Tunnels is given in [TCMIB]. A few
key objects are listed here to provide an overview of the
concepts.
Each MPLS tunnel is represented by an entry in the ifTable.
Each tunnel is therefore assigned a unique ifIndex.
The type of an interface represented by an entry in the
ifTable is indicated by the ifType object. The value that
is allocated to identify an MPLS tunnel is 150.
The ifOperStatus object reflects the actual operational
status of MPLS tunnel and may be mapped from the
mplsTunnelOperStatus object.
It may be considered convenient and good management to set
the ifName object to reflect the name of the MPLS tunnel as
contained in the mplsTunnelName object.
11.2. Application of the Interfaces Group to TE Links
The MPLS-LINK-BUNDLING-MIB also uses interface stacking to
manage TE Link interfaces as logical interfaces. The TE
Link interface is represented as an entry in the ifTable.
The inter-relation of entries in the ifTable is defined by
Interfaces Stack Group defined in [RFC2863]. When using TE
Link interfaces, the interface stack table might appear as
follows:
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+---------------------------------------------------------------+
| MPLS interface ifType = mpls(166) |
+---------------------------------------------------------------+
| TE link-interface (bundle) ifType = teLink(200) |
+------------------------------+-+------------------------------+
| TE link ifType = teLink(200) | | TE link ifType = teLink(200) |
+-------------+--+-------------+ +-------------+--+-------------+
|opticalTrans | |opticalTrans | |opticalTrans | |opticalTrans |
|ifType = 196 | |ifType = 196 | |ifType = 196 | |ifType = 196 |
+-------------+ +-------------+ +-------------+ +-------------+
In the above diagram, "opticalTrans" is an example of an
underlying physical interface: in this case an optical
transport interface. TE link management and bundling can
be seen in the levels of interface stacking. Two TE links
are defined each managing two optical transport links.
These two TE links are combined into a bundle which is
managed as a single TE link interface. This TE Link
interface supports MPLS and is presented as an MPLS
interface.
A detailed listing of the mapping between ifTable objects
and their use for TE Links is given in [LBMIB]. A few key
objects are listed here to provide an overview of the
concepts.
Each TE Link interface is represented by a separate entry
in the ifTable with a unique ifIndex.
The type of an interface represented by an entry in the
ifTable is indicated by the ifType object. The value that
is allocated to identify a TE Link 200.
11.3. References to Interface MIB Objects from Other MPLS MIBs
The MPLS-TE-MIB contains two objects that reference the
management of an MPLS tunnel as an interface.
mplsTunnelIsIf is a TRuthValue that indicates whether the
tunnel is present in the ifTable. If the tunnel is managed
as an interface, the mplsTunnelIfIndex object contains the
ifIndex that identifies the corresponding entry in the
ifTable.
The MPLS-LSR-MIB includes a table (mplsInterfaceConfTable)
for configuring the support for MPLS on specific
interfaces. A conceptual row in this table is created
automatically by an LSR for every interface that is capable
of and configured for support of MPLS. A conceptual row in
this table will exist if and only if a corresponding entry
in ifTable exists with ifType = mpls(166). The fate of the
entries in the two tables are closely linked so that if the
entry in the ifTable is operationally disabled, the entry
in the mplsInterfaceConfTable is deleted. During the life
of an entry in the mplsInterfaceConfTable a corresponding
entry is managed in the mplsInterfacePerfTable to show
performance counters for the MPLS-capable interface.
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The ifIndex that identifies MPLS-capable interfaces also
plays an important indexing role in the MPLS-LSR-MIB. In-
segments (that is incoming LSP labels) are represented in
the mplsInSegmentTable which is indexed by the
mplsInSegmentIfIndex and mplsInSegmentLabel objects.
mplsInSegmentIfIndex is set to the ifIndex of the incoming
MPLS-capable interface. mplsInSegmentLabel identifies the
incoming MPLS label. Note that the corresponding
mplsOutSegmentTable contains an mplsOutSegmentIfIndex
object to identify the outgoing MPLS-capable interface, but
that this does not form part of the index of the table.
The MPLS-LDP-MIB use ifIndex extensively to identify the
interface over which MPLS is active.
Within the MPLS-FTN-MIB, the mplsFTNMapTable maps entries
in the mplsFTNTable to interfaces on which the mplsFTNTable
entries should be used. Interfaces are identified using
their ifIndex values.
12. Management Options
It is not the intention of this document to provide
instructions or advice to implementers of Management
Stations, Management Agents or managed entities. It is,
however, useful to make some observations about how the MIB
modules described above might be used to manage MPLS
systems.
All MPLS LSPs may appear in the MPLS-LSR-MIB. At transit
nodes they are seen as full cross-connects between incoming
labels on incoming interfaces and outgoing labels on
outgoing interfaces. At ingress or egress points the cross-
connections are unbalanced having spoof upstream or
downstream legs respectively.
Split and merge points of LSPs may be represented as more
complex cross-connects in the MPLS-LSR-MIB. Similarly,
bidirectional LSPs can be represented by using the same
cross-connect index for each of the forward and reverse
cross-connections.
The modules in the LDP MIB are intended solely for use with
LDP and CR-LDP. LSPs that are signaled through other means
may conveniently be stored in the mplsLdpLspTable for
consistency with LSPs set up using LDP, but there is little
further value to this since the table gives only pointers
into the MPLS-LSR-MIB. If, however, the LSPs are
established with associated FECs using some signaling
method other than LDP (for example, BGP) it may be
advantageous to use the mplsLdpLspTable, mplsFecTable and
mplsLdpLspFecTable to correlate the LSPs.
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Note that if CR-LDP is the signaling protocol there is no
requirement to use the LSP-related tables in the LDP MIB
since the LSP will be adequately represented in the MPLS-TE-
MIB and the MPLS-LSR-MIB.
MPLS tunnels may be represented in the MPLS-TE-MIB with
their cross-connects indicated in the MPLS-LSR-MIB.
Tunnels are often (although not always) set up with a
series of constraints that may be represented in the MPLS-
TE-MIB. Note that a distinguishing feature of a tunnel is
that it has an ingress and an egress, where LSPs
established through LDP may be end-to-end or may be hop-by-
hop.
All LSPs (tunnels and non-tunnels) may be established as a
result of signaling protocols already defined or for future
study. In addition, LSPs may be manually set up by issuing
configuration commands to each of the LSRs on the LSP.
These commands may utilize SNMP by performing write
operations to the MIB tables and objects described here.
Alternatively, configuration may be through some non-
standard interface such as a Command Line or a Graphical
User Interface. Such configured LSPs may also be
represented in the MIB tables.
Do not be mislead by considerations of the "permanence" of
LSPs when deciding which tables of which MIB modules to
use. An MPLS tunnel may have a very long life expectancy
if set up by an amnesiac user, or a very short lifetime is
automatically provisioned to satisfy on-demand traffic
requirements. Similarly, an LSP established in response to
a routing protocol (sometimes known as a hop-by-hop LSP)
may be equally stable or unstable.
13. Related IETF MIB Modules
This section describes the broad interactions between MIB
modules produced by the pwe3, ppvpn, and ccamp working
groups and the MPLS MIB modules.
13.1. pwe3 Working Group MIB Modules
The pwe3 working group has produced a document [PWE3FW]
that includes a description of the framework for PWE3 MIBs.
Since the PWE3 architecture includes the use of MPLS as an
emulated service and as a PSN service, the MPLS MIBs
described above may be leveraged. The pwe3 framework
document describes the interactions between the MPLS MIBs
and the PWE3 MIBs.
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13.2. ppvpn Working Group MIB Modules
At present, the ppvpn working group has not included a
discussion of how the MPLS MIBs interact with the MIBs
being produced by that working group. The authors of this
draft hope to make a forthcoming addition to the ppvpn
framework document [PPVPNFW] detailing these interactions.
At the moment, there is only a single MIB module [VPNMIB]
produced which is discussed next.
13.2.1. PPVPN-MPLS-VPN-MIB
PPVPN-MPLS-VPN-MIB describes managed objects that are used
to model and manage RFC2547bis MPLS VPNs [RFC2547Bis].
This MIB module contains tables which model virtual routing
forwarding entries (VRFs), as well as the interfaces
associated with those VRFs.
13.2.1.1. Position in the OID Tree
transmission -- RFC1213-MIB
|
+- vpnMIB (TBD) -- PPVPN-MPLS-VPN-MIB
13.2.1.2. Dependencies
This MIB module currently has no direct dependencies to any
of the MPLS MIB modules. This MIB module models MPLS VPN
interfaces as entries in the Interfaces MIB's Interfaces
Table (ifTable). This MIB module may be modified in the
future to import textual conventions from MPLS-TC-MIB.
13.3. ccamp Working Group MIBs
At present, there are no MIBs produced by the ccamp working
group that interact directly with the MPLS MIBs. However,
in the future, the existing MPLS MIBs will need to be
extended and augmented to facilitate the technology being
produced by this working group. Along with any MIBs
produced by the ccamp working group, a separate ccamp-
specific Management Framework document is expected to be
issued describing the relationship between these MIBs and
the existing MPLS (and other) MIBs.
14. Traffic Engineering Working Group TE MIB
The tewg has produced a traffic engineering MIB [TEWGMIB]
containing objects for monitoring traffic engineered MPLS
based tunnels at their ingress points.
In many senses the tewg TE MIB contains the same
information as MPLS-TE-MIB. Both MIBs can be used to
monitor MPLS tunnels.
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The tewg TE MIB was initially styled towards simple textual
representation of information about tunnels. This made it
simple to implement as a read only MIB, displaying details
of existing tunnels that were configured or established
through other means.
As write access has been added, the MIB continues to allow
simple representations of tunnels.
The price of this simplicity within the MIB, however, is an
increased complexity in the Management Station or greater
sophistication in the operator. It is necessary to apply
parsing rules to text strings to in order to fully
interpret or to configure tunnels.
Many advanced features of MPLS tunnels are not included in
this MIB.
14.1. Choosing Between TE MIBs Modules
The tewg TE MIB is a flexible MIB designed to manage
traffic engineering tunnels regardless of the
implementation technology. This flexibility and a focus on
simplicity leads to many compromises. Some MPLS
configuration parameters are left out, while others are
present with only limited options.
MPLS-TE-MIB should be used for a fully configurable high
function implementation. It provides objects for managing
all features of MPLS Tunnels.
The tewg TE MIB may be used for quick implementation or for
non-complex situations. It may be particularly suitable
for read-only inspection of tunnels established by some
other means (such as a CLI).
15. Security Considerations
This document describes the inter-relationships amongst the
different MIBs relevant to MPLS management and as such does
not have any security implications beyond those imposed by
these MIBs themselves.
16. Acknowledgements
Many small pieces of text in this draft have been borrowed
from the documents that define the MIBs described here.
The authors would like to express appreciation to all who
worked on those MIBs.
Thanks also to all those who attended the November 2002
MPLS MIB open meeting and gave constructive feedback, and
in particular to Sharon Chisholm for her thoughts on
Management Options.
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17. Intellectual Property Consideration
The IETF takes no position regarding the validity or scope
of any intellectual property or other rights that might be
claimed to pertain to the implementation or use of the
technology described in this document or the extent to
which any license under such rights might or might not be
available; neither does it represent that it has made any
effort to identify any such rights. Information on the
IETF's procedures with respect to rights in standards-track
and standards-related documentation can be found in BCP-11.
Copies of claims of rights made available for publication
and any assurances of licenses to be made available, or the
result of an attempt made to obtain a general license or
permission for the use of such proprietary rights by
implementors or users of this specification can be obtained
from the IETF Secretariat. The IETF invites any interested
party to bring to its attention any copyrights, patents or
patent applications, or other proprietary rights which may
cover technology that may be required to practice this
standard. Please address the information to the IETF
Executive Director.
18. Normative References
[TCMIB] Nadeau, T., Cucchiara, J., Srinivasan, C,
Viswanathan, A. and H. Sjostrand,
"Definition of Textual Conventions and
OBJECT-IDENTITIES for Multi-Protocol Label
Switching (MPLS) Management", Internet Draft
<draft-ietf-mpls-tc-mib-03.txt>, January
2002 (work in progress).
[LSRMIB] Srinivasan, C., Viswanathan, A. and T.
Nadeau, "MPLS Label Switch Router Management
Information Base", Internet Draft <draft-
ietf-mpls-lsr-mib-09.txt>, October 2002
(work in progress).
[LDPMIB] J. Cucchiara, et al., "Definitions of
Managed Objects for the Multiprotocol Label
Switching, Label Distribution Protocol
(LDP)", <draft-ietf-mpls-ldp-mib-09.txt>,
October 2002 (work in progress).
[TEMIB] Srinivasan, C., Viswanathan, A. and T.
Nadeau, "MPLS Traffic Engineering Management
Information Base Using SMIv2", Internet
Draft <draft-ietf-mpls-te-mib-09.txt>,
November 2002 (work in progress).
Nadeau, Srinivasan and Farrel [Page 25]
Internet Draft draft-ietf-mpls-mgmt-overview-03.txt February 2003
[FTNMIB] Nadeau, T., Srinivasan, C., and A.
Viswanathan, "Multiprotocol Label Switching
(MPLS) FEC-To-NHLFE (FTN) Management
Information Base", Internet Draft <draft-
ietf-mpls-ftn-mib-05.txt>, November 2002
(work in progress).
[LBMIB] Dubuc, M., Dharanikota, S., Nadeau, T., J.
Lang, "Link Bundling Management Information
Base Using SMIv2", Internet Draft <draft-
ietf-mpls-bundle-mib-04.txt>, November 2002
(work in progress).
[VPNMIB] Nadeau, T., Fang, L., Van Der Linde, H.,
Brannon, S., Chiussi, F., Dube, J, and M.
Tatham, "MPLS/BGP Virtual Private Network
Management Information Base Using SMIv2",
Internet Draft, <draft-ietf-ppvpn-mpls-vpn-
mib-05.txt>, November 2002 (work in
progress).
[PWE3FW] Pate, P., Xiao, X., White., C., Kompella.,
K., Malis, A., Johnson, T., and T. Nadeau,
"Framework for Pseudo Wire Emulation Edge-to-
Edge (PWE3)", Internet Draft <draft-ietf-
pwe3-framework-01.txt>, June, 2002 (work in
progress).
[PPVPNFW] Callon, R., Suzuki, M., Gleeson, B., Malis,
A., Muthukrishnan, K., Rosen, E., Sargor,
C., and J. Yu, "A Framework for Provider
Provisioned Virtual Private Networks",
Internet Draft <draft-ietf-ppvpn-framework-
07.txt>, January 2003 (work in progress).
[RFC2863] McCloghrie, K. and F. Kastenholtz, "The
Interfaces Group MIB ", RFC 2863, June 2000.
19. Informative References
[RFC2547Bis] Rosen, E. et al, "MPLS/BGP VPNs", Internet
Draft <draft-ietf-ppvpn-rfc2547bis-03.txt>,
October 2002.
[TEWGMIB] Kompella, K., "A Traffic Engineering MIB",
Internet Draft <draft-ietf-tewg-mib-03.txt>,
September 2002 (work in progress).
[RFC1155] Rose, M., and K. McCloghrie, "Structure and
Identification of Management Information for
TCP/IP-based Internets", RFC 1155, May 1990.
[RFC1157] Case, J., Fedor, M., Schoffstall, M., and J.
Davin, "Simple Network Management Protocol",
RFC 1157, May 1990.
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[RFC1212] Rose, M., and K. McCloghrie, "Concise MIB
Definitions", RFC 1212, March 1991.
[RFC1213] McCloghrie, K, and M. Rose, "Management
Information Base for Network Management of
TCP/IP Based Internets", RFC 1213, March
1991.
[RFC1215] M. Rose, "A Convention for Defining Traps
for use with the SNMP", RFC 1215, March
1991.
[RFC1901] Case, J., McCloghrie, K., Rose, M., and S.
Waldbusser, "Introduction to Community-based
SNMPv2", RFC 1901, January 1996.
[RFC1905] Case, J., McCloghrie, K., Rose, M., and S.
Waldbusser, "Protocol Operations for Version
2 of the Simple Network Management Protocol
(SNMPv2)", RFC 1905, January 1996.
[RFC1906] Case, J., McCloghrie, K., Rose, M., and S.
Waldbusser, "Transport Mappings for Version
2 of the Simple Network Management Protocol
(SNMPv2)", RFC 1906, January 1996.
[RFC2026] S. Bradner, "The Internet Standards Process
-- Revision 3", RFC 2026, October 1996.
[RFC2570] Case, J., Mundy, R., Partain, D., and B.
Stewart, "Introduction to Version 3 of the
Internet-standard Network Management
Framework", RFC 2570, April 1999.
[RFC2571] Harrington, D., Presuhn, R., and B. Wijnen,
"An Architecture for Describing SNMP
Management Frameworks", RFC 2571, April
1999.
[RFC2572] Case, J., Harrington D., Presuhn R., and B.
Wijnen, "Message Processing and Dispatching
for the Simple Network Management Protocol
(SNMP)", RFC 2572, April 1999.
[RFC2573] Levi, D., Meyer, P., and B. Stewart, "SNMPv3
Applications", RFC 2573, April 1999.
[RFC2574] Blumenthal, U., and B. Wijnen, "User-based
Security Model (USM) for version 3 of the
Simple Network Management Protocol
(SNMPv3)", RFC 2574, April 1999.
[RFC2575] Wijnen, B., Presuhn, R., and K. McCloghrie,
"View-based Access Control Model (VACM) for
the Simple Network Management Protocol
(SNMP)", RFC 2575, April 1999.
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[RFC2578] McCloghrie, K., Perkins, D., Schoenwaelder,
J., Case, J., Rose, M., and S. Waldbusser,
"Structure of Management Information Version
2 (SMIv2)", STD 58, RFC 2578, April 1999.
[RFC2579] McCloghrie, K., Perkins, D., Schoenwaelder,
J., Case, J., Rose, M., and S. Waldbusser,
"Textual Conventions for SMIv2", STD 58, RFC
2579, April 1999.
[RFC2580] McCloghrie, K., Perkins, D., Schoenwaelder,
J., Case, J., Rose, M., and S. Waldbusser,
"Conformance Statements for SMIv2", STD 58,
RFC 2580, April 1999.
[RFC3031] Rosen, E., Viswanathan, A., and R. Callon,
"Multiprotocol Label Switching
Architecture", RFC 3031, January 2001.
[RFC3036] Andersson, L., Doolan, P., Feldman, N.,
Fredette, A., and B. Thomas, "LDP
Specification", RFC 3036, January 2001.
20. Authors' Addresses
Thomas D. Nadeau
Cisco Systems, Inc.
300 Apollo Drive
Chelmsford, MA 01824
Phone: +1-978-244-3051
Email: tnadeau@cisco.com
Cheenu Srinivasan
Parama Networks, Inc.
1030 Broad Street
Shrewsbury, NJ 07702
Phone: +1-732-544-9120 x731
Email: cheenu@paramanet.com
Adrian Farrel
Movaz Networks, Inc.
7926 Jones Branch Drive, Suite 615
McLean, VA 22102
Phone: +1-703-847-1867
Email: afarrel@movaz.com
Nadeau, Srinivasan and Farrel [Page 28]
Internet Draft draft-ietf-mpls-mgmt-overview-03.txt February 2003
21. Full Copyright Statement
Copyright (C) The Internet Society (2003). All Rights
Reserved.
This document and translations of it may be copied and
furnished to others, and derivative works that comment on
or otherwise explain it or assist in its implementation may
be prepared, copied, published and distributed, in whole or
in part, without restriction of any kind, provided that the
above copyright notice and this paragraph are included on
all such copies and derivative works. However, this
document itself may not be modified in any way, such as by
removing the copyright notice or references to the Internet
Society or other Internet organizations, except as needed
for the purpose of developing Internet standards in which
case the procedures for copyrights defined in the Internet
Standards process must be followed, or as required to
translate it into languages other than English.
The limited permissions granted above are perpetual and
will not be revoked by the Internet Society or its
successors or assigns. This document and the information
contained herein is provided on an "AS IS" basis and THE
INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK FORCE
DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT
NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION
HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
PURPOSE.
Nadeau, Srinivasan and Farrel [Page 29]
| PAFTECH AB 2003-2026 | 2026-04-22 19:07:35 |