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IETF RFC 4750

OSPF Version 2 Management Information Base

Last modified on Tuesday, December 12th, 2006

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Network Working Group                                      D. Joyal, Ed.
Request for Comments: 4750                                        Nortel
Obsoletes: 1850                                          P. Galecki, Ed.
Category: Standards Track                                      Airvana
                                                       S. Giacalone, Ed.
                                                                    CSFB
                                                    Original Authors:
                                                               R. Coltun
                                                          Touch Acoustra
                                                                F. Baker
                                                           Cisco Systems
                                                           December 2006


              OSPF Version 2 Management Information Base

 Status of This Memo

   This document specifies an Internet standards track protocol for the
   Internet community, and requests discussion and suggestions for
   improvements.  Please refer to the current edition of the "Internet
   Official Protocol Standards" (STD 1) for the standardization state
   and status of this protocol.  Distribution of this memo is unlimited.

 Copyright Notice

   Copyright © The IETF Trust (2006).

 Abstract

   This memo defines a portion of the Management Information Base (MIB)
   for use with network management protocols in TCP/IP-based internets.
   In particular, it defines objects for managing version 2 of the Open
   Shortest Path First Routing Protocol.  Version 2 of the OSPF protocol
   is specific to the IPv4 address family.  Version 3 of the OSPF
   protocol is specific to the IPv6 address family.

   This memo obsoletes RFC 1850; however, it is designed to be backwards
   compatible.  The functional differences between this memo and RFC
   1850 are explained in Appendix B.











Galecki, et al.             Standards Track                  PAGE 1 


RFC 4750 OSPFv2 MIB December 2006 Table of Contents 1. Overview ........................................................3 1.1. The Internet-Standard Management Framework .................3 1.2. Conceptual Row Creation ....................................3 1.3. Default Configuration ......................................4 1.4. OSPF Counters ..............................................5 1.5. Multiple OSPF Instances ....................................5 1.6. Conventions ................................................6 2. Structure of This MIB ...........................................6 2.1. The Purposes of the Sections in This MIB ...................6 2.1.1. General Variables ...................................6 2.1.2. Area Data Structure and Area Stub Metric Table ......6 2.1.3. Link State Database and External Link State Database ............................................7 2.1.4. Address Table and Host Tables .......................7 2.1.5. Interface and Interface Metric Tables ...............7 2.1.6. Virtual Interface Table .............................7 2.1.7. Neighbor and Virtual Neighbor Tables ................7 2.1.8. Local Link State Database Table and Virtual Local Link State Database Table .....................7 2.1.9. AS-scope Link State Database Table ..................7 2.1.10. Area LSA Count Table ...............................7 3. OSPF MIB Module .................................................8 4. OSPF Trap Overview .............................................94 4.1. Introduction ..............................................94 4.2. Approach ..................................................95 4.3. Ignoring Initial Activity .................................95 4.4. Throttling Traps ..........................................95 4.5. One Trap Per OSPF Event ...................................96 4.6. Polling Event Counters ....................................96 4.7. Translating Notification Parameters .......................97 4.8. Historical Artifacts ......................................97 5. OSPF Trap Definitions ..........................................98 6. Security Considerations .......................................110 7. IANA Considerations ...........................................111 8. Acknowledgements ..............................................111 9. References ....................................................111 9.1. Normative References .....................................111 9.2. Informative References ...................................111 Appendix A. TOS Support ..........................................113 Appendix B. Changes from RFC 1850 ................................113 B.1. General Group Changes ....................................113 B.2. OSPF NSSA Enhancement Support ............................113 B.3. Opaque LSA Support .......................................114 B.4. Graceful Restart Support .................................116 B.5. OSPF Compliances .........................................116 B.6. OSPF Authentication and Security .........................117 Galecki, et al. Standards Track PAGE 2

RFC 4750 OSPFv2 MIB December 2006 B.7. OSPF Trap MIB ............................................117 B.8. Miscellaneous ............................................118 1. Overview 1.1. The Internet-Standard Management Framework For a detailed overview of the documents that describe the current Internet-Standard Management Framework, please refer to section 7 of RFC 3410 [RFC 3410]. Managed objects are accessed via a virtual information store, termed the Management Information Base or MIB. MIB objects are generally accessed through the Simple Network Management Protocol (SNMP). Objects in the MIB are defined using the mechanisms defined in the Structure of Management Information (SMI). This memo specifies a MIB module that is compliant to the SMIv2, which is described in STD 58, RFC 2578 [RFC 2578], STD 58, RFC 2579 [RFC 2579] and STD 58, RFC 2580 [RFC 2580]. 1.2. Conceptual Row Creation For the benefit of row-creation in "conceptual" tables, DEFVAL (Default Value) clauses are included in the definitions in section 3, suggesting values that an agent should use for instances of variables that need to be created due to a Set-Request, but that are not specified in the Set-Request. DEFVAL clauses have not been specified for some objects that are read-only, implying that they are zeroed upon row creation. These objects are of the SYNTAX Counter32 or Gauge32. For those objects not having a DEFVAL clause, both management stations and agents should heed the Robustness Principle of the Internet (see [RFC 791]): "be liberal in what you accept, conservative in what you send" Therefore, management stations should include as many of these columnar objects as possible (e.g., all read-write objects) in a Set-Request when creating a conceptual row. Agents should accept a Set-Request with as few of these columnar objects as they need (e.g., the minimum contents of a "row-creating" SET consists of those objects for which, as they cannot be intuited, no default is specified). Galecki, et al. Standards Track PAGE 3

RFC 4750 OSPFv2 MIB December 2006 1.3. Default Configuration OSPF is a powerful routing protocol, equipped with features to handle virtually any configuration requirement that might reasonably be found within an Autonomous System (AS). With this power comes a fair degree of complexity, which the sheer number of objects in the MIB will attest to. Care has therefore been taken, in constructing this MIB, to define default values for virtually every object, to minimize the amount of parameterization required in the typical case. That default configuration is as follows: Given the following assumptions: - IP has already been configured. - The ifTable has already been configured. - ifSpeed is estimated by the interface drivers. - The OSPF process automatically discovers all IP interfaces and creates corresponding OSPF interfaces. - The OSPF process automatically creates the areas required for the interfaces. The simplest configuration of an OSPF process requires the following: - The OSPF process be enabled. This can be accomplished with a single SET: ospfAdminStat := enabled. The configured system will have the following attributes: - The RouterID will be one of the IP addresses of the device. - The device will be neither an Area Border Router nor an Autonomous System Border Router. - Every IP interface, with or without an address, will be an OSPF interface. - The AreaID of each interface will be 0.0.0.0, the backbone. - Authentication will be disabled. Galecki, et al. Standards Track PAGE 4

RFC 4750 OSPFv2 MIB December 2006 - All broadcast and point-to-point interfaces will be operational. Non-broadcast multi-access (NBMA) interfaces require the configuration of at least one neighbor. - Timers on all direct interfaces will be: Hello Interval: 10 seconds Dead Timeout: 40 Seconds Retransmission: 5 Seconds Transit Delay: 1 Second Poll Interval: 120 Seconds - No direct links to hosts will be configured. - No addresses will be summarized. - Metrics, being a measure of bit duration, are unambiguous and intelligent. - No virtual links will be configured. 1.4. OSPF Counters This MIB defines several counters, namely: - ospfOriginateNewLsas, ospfRxNewLsas in the ospfGeneralGroup - ospfSpfRuns, ospfAreaNssaTranslatorEvents in the ospfAreaTable - ospfIfEvents in the ospfIfTable - ospfVirtIfEvents in the ospfVirtIfTable - ospfNbrEvents in the ospfNbrTable - ospfVirtNbrEvents in the ospfVirtNbrTable As a best practice, a management entity, when reading these counters, should use the discontinuity object, ospfDiscontinuityTime, to determine if an event that would invalidate the management entity understanding of the counters has occurred. A restart of the OSPF routing process is a possible example of a discontinuity event. 1.5. Multiple OSPF Instances SNMPv3 supports "Contexts" that can be used to implement MIB views on multiple OSPF instances on the same system. See [RFC 3411] or its successors for details. Galecki, et al. Standards Track PAGE 5

RFC 4750 OSPFv2 MIB December 2006 1.6. Conventions 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 [RFC 2119]. 2. Structure of This MIB This MIB is composed of the following sections: General Variables Area Data Structure Area Stub Metric Table Link State Database (LSDB) Address Range Table Host Table Interface Table Interface Metric Table Virtual Interface Table Neighbor Table Virtual Neighbor Table External Link State Database Aggregate Range Table Local Link State Database AS-scope Link State Database It supports the base OSPFv2 specification [RFC 2328] and extensions to OSPFv2 such as [RFC 1765], [RFC 1793], [RFC 2370], [RFC 3101] and [RFC 3623]. There exists a separate MIB for notifications ("traps"), which is entirely optional. 2.1. The Purposes of the Sections in This MIB 2.1.1. General Variables The general variables describe (as it may seem from the name) variables that are global to the OSPF Process. 2.1.2. Area Data Structure and Area Stub Metric Table The Area Data Structure describes all of the OSPF Areas that the router participates in. The Area Table includes data for Not-So- Stubby-Area (NSSA) translation. The Area Stub Metric Table describes the metrics advertised into a stub area by the default router(s). Galecki, et al. Standards Track PAGE 6

RFC 4750 OSPFv2 MIB December 2006 2.1.3. Link State Database and External Link State Database The link state database is provided primarily to provide detailed information for network debugging. 2.1.4. Address Table and Host Tables The Address Range Table and Host Table are provided to view configured Network Summary and host route information. 2.1.5. Interface and Interface Metric Tables The Interface Table and the Interface Metric Table together describe the various IP interfaces to OSPF. The metrics are placed in separate tables in order to simplify dealing with multiple types of service. The Interface table includes link-local (Opaque type-9) link state advertisement (LSA) statistics. 2.1.6. Virtual Interface Table The Virtual Interface Table describes virtual links to the OSPF Process, similarly to the (non-virtual) Interface Tables. This Table includes link-local (Opaque type-9) LSA statistics. 2.1.7. Neighbor and Virtual Neighbor Tables The Neighbor Table and the Virtual Neighbor Table describe the neighbors to the OSPF Process. 2.1.8. Local Link State Database Table and Virtual Local Link State Database Table The Local Link State Database Table and Virtual Local Link State Database Table are identical to the OSPF LSDB Table in format, but contain only link-local (Opaque type-9) link state advertisements for non-virtual and virtual links. 2.1.9. AS-scope Link State Database Table The AS-scope Link State Database Table is identical to the OSPF LSDB Table in format, but contains only AS-scoped link state advertisements. 2.1.10. Area LSA Count Table The table, which maintains number of link state advertisements on the per-area, per-LSA-type basis. Galecki, et al. Standards Track PAGE 7

RFC 4750 OSPFv2 MIB December 2006 3. OSPF MIB Module OSPF-MIB DEFINITIONS ::= BEGIN IMPORTS MODULE-IDENTITY, OBJECT-TYPE, Counter32, Gauge32, Integer32, Unsigned32, IpAddress, mib-2 FROM SNMPv2-SMI TEXTUAL-CONVENTION, TruthValue, RowStatus, TimeStamp FROM SNMPv2-TC MODULE-COMPLIANCE, OBJECT-GROUP FROM SNMPv2-CONF InterfaceIndexOrZero FROM IF-MIB; ospf MODULE-IDENTITY LAST-UPDATED "200611100000Z" -- November 10, 2006 00:00:00 EST ORGANIZATION "IETF OSPF Working Group" CONTACT-INFO "WG E-Mail: ospf@ietf.org WG Chairs: acee@cisco.com rohit@gmail.com Editors: Dan Joyal Nortel 600 Technology Park Drive Billerica, MA 01821 djoyal@nortel.com Piotr Galecki Airvana 19 Alpha Road Chelmsford, MA 01824 pgalecki@airvana.com Spencer Giacalone CSFB Eleven Madison Ave New York, NY 10010-3629 spencer.giacalone@gmail.com" DESCRIPTION "The MIB module to describe the OSPF Version 2 Protocol. Note that some objects in this MIB module may pose a significant security risk. Refer to the Security Considerations section in RFC 4750 for more information. Galecki, et al. Standards Track PAGE 8

RFC 4750 OSPFv2 MIB December 2006 Copyright © The IETF Trust (2006). This version of this MIB module is part of RFC 4750; see the RFC itself for full legal notices." REVISION "200611100000Z" -- November 10, 2006 09:00:00 EST DESCRIPTION "Updated for latest changes to OSPF Version 2: - updated the General Group with the new ospfRFC1583Compatibility, ospfReferenceBandwidth and ospfDiscontinuityTime objects - added graceful-restart-related objects - added stub-router-related objects - updated the Area Table with NSSA-related objects - added ospfAreaAggregateExtRouteTag object - added Opaque LSA-related objects - updates to the Compliances and Security sections - added area LSA counter table - added section describing translation of notification parameters between SNMP versions - added ospfComplianceObsolete to contain obsolete object groups - deprecated ospfExtLsdbTable See Appendix B of RFC 4750 for more details. This version published as part of RFC 4750" REVISION "199501201225Z" -- Fri Jan 20 12:25:50 PST 1995 DESCRIPTION "The initial SMIv2 revision of this MIB module, published in RFC 1850." ::= { mib-2 14 } AreaID ::= TEXTUAL-CONVENTION STATUS current DESCRIPTION "An OSPF Area Identifier. Note that the Area ID, in OSPF, has the same format as an IP address, but has the function of defining a summarization point for link state advertisements." SYNTAX IpAddress RouterID ::= TEXTUAL-CONVENTION STATUS current DESCRIPTION "A OSPF Router Identifier. Note that the Router ID, in OSPF, has the same format as an IP address, but identifies the router independent Galecki, et al. Standards Track PAGE 9

RFC 4750 OSPFv2 MIB December 2006 of its IP address." SYNTAX IpAddress Metric ::= TEXTUAL-CONVENTION DISPLAY-HINT "d-0" STATUS current DESCRIPTION "The OSPF internal metric. Note that the OSPF metric is defined as an unsigned value in the range." SYNTAX Integer32 (0..'FFFF'h) BigMetric ::= TEXTUAL-CONVENTION DISPLAY-HINT "d-0" STATUS current DESCRIPTION "The OSPF external metric." SYNTAX Integer32 (0..'FFFFFF'h) Status ::= TEXTUAL-CONVENTION STATUS current DESCRIPTION "An indication of the operability of an OSPF function or feature. For example, the status of an interface: 'enabled' indicates that it is willing to communicate with other OSPF routers, and 'disabled' indicates that it is not." SYNTAX INTEGER { enabled (1), disabled (2) } PositiveInteger ::= TEXTUAL-CONVENTION DISPLAY-HINT "d-0" STATUS current DESCRIPTION "A positive integer. Values in excess are precluded as unnecessary and prone to interoperability issues." SYNTAX Integer32 (0..'7FFFFFFF'h) HelloRange ::= TEXTUAL-CONVENTION DISPLAY-HINT "d-0" STATUS current DESCRIPTION "The range of intervals in seconds on which Hello messages are exchanged." SYNTAX Integer32 (1..'FFFF'h) UpToMaxAge ::= TEXTUAL-CONVENTION DISPLAY-HINT "d-0" STATUS current Galecki, et al. Standards Track PAGE 10

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The values in seconds that one might find or configure for variables bounded by the maximum age of an LSA." SYNTAX Integer32 (0..3600) DesignatedRouterPriority ::= TEXTUAL-CONVENTION DISPLAY-HINT "d-0" STATUS current DESCRIPTION "The range of values defined for the priority of a system for becoming the designated router." SYNTAX Integer32 (0..'FF'h) TOSType ::= TEXTUAL-CONVENTION DISPLAY-HINT "d-0" STATUS current DESCRIPTION "Type of Service (TOS) is defined as a mapping to the IP Type of Service Flags as defined in the IP Forwarding Table MIB +-----+-----+-----+-----+-----+-----+-----+-----+ | | | | | PRECEDENCE | TYPE OF SERVICE | 0 | | | | | +-----+-----+-----+-----+-----+-----+-----+-----+ IP TOS IP TOS Field Policy Field Policy Contents Code Contents Code 0 0 0 0 ==> 0 0 0 0 1 ==> 2 0 0 1 0 ==> 4 0 0 1 1 ==> 6 0 1 0 0 ==> 8 0 1 0 1 ==> 10 0 1 1 0 ==> 12 0 1 1 1 ==> 14 1 0 0 0 ==> 16 1 0 0 1 ==> 18 1 0 1 0 ==> 20 1 0 1 1 ==> 22 1 1 0 0 ==> 24 1 1 0 1 ==> 26 1 1 1 0 ==> 28 1 1 1 1 ==> 30 The remaining values are left for future definition." SYNTAX Integer32 (0..30) OspfAuthenticationType ::= TEXTUAL-CONVENTION STATUS current DESCRIPTION "The authentication type." SYNTAX INTEGER { Galecki, et al. Standards Track PAGE 11

RFC 4750 OSPFv2 MIB December 2006 none (0), simplePassword (1), md5 (2) -- reserved for specification by IANA (> 2) } -- OSPF General Variables -- Note: These parameters apply globally to the Router's -- OSPF Process. ospfGeneralGroup OBJECT IDENTIFIER ::= { ospf 1 } ospfRouterId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS read-write STATUS current DESCRIPTION "A 32-bit integer uniquely identifying the router in the Autonomous System. By convention, to ensure uniqueness, this should default to the value of one of the router's IP interface addresses. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." REFERENCE "OSPF Version 2, C.1 Global parameters" ::= { ospfGeneralGroup 1 } ospfAdminStat OBJECT-TYPE SYNTAX Status MAX-ACCESS read-write STATUS current DESCRIPTION "The administrative status of OSPF in the router. The value 'enabled' denotes that the OSPF Process is active on at least one interface; 'disabled' disables it on all interfaces. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." ::= { ospfGeneralGroup 2 } ospfVersionNumber OBJECT-TYPE SYNTAX INTEGER { version2 (2) } MAX-ACCESS read-only STATUS current Galecki, et al. Standards Track PAGE 12

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The current version number of the OSPF protocol is 2." REFERENCE "OSPF Version 2, Title" ::= { ospfGeneralGroup 3 } ospfAreaBdrRtrStatus OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-only STATUS current DESCRIPTION "A flag to note whether this router is an Area Border Router." REFERENCE "OSPF Version 2, Section 3 Splitting the AS into Areas" ::= { ospfGeneralGroup 4 } ospfASBdrRtrStatus OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "A flag to note whether this router is configured as an Autonomous System Border Router. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." REFERENCE "OSPF Version 2, Section 3.3 Classification of routers" ::= { ospfGeneralGroup 5 } ospfExternLsaCount OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of external (LS type-5) link state advertisements in the link state database." REFERENCE "OSPF Version 2, Appendix A.4.5 AS external link advertisements" ::= { ospfGeneralGroup 6 } ospfExternLsaCksumSum OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only Galecki, et al. Standards Track PAGE 13

RFC 4750 OSPFv2 MIB December 2006 STATUS current DESCRIPTION "The 32-bit sum of the LS checksums of the external link state advertisements contained in the link state database. This sum can be used to determine if there has been a change in a router's link state database and to compare the link state database of two routers. The value should be treated as unsigned when comparing two sums of checksums." ::= { ospfGeneralGroup 7 } ospfTOSSupport OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "The router's support for type-of-service routing. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." REFERENCE "OSPF Version 2, Appendix F.1.2 Optional TOS support" ::= { ospfGeneralGroup 8 } ospfOriginateNewLsas OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of new link state advertisements that have been originated. This number is incremented each time the router originates a new LSA. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ospfDiscontinuityTime." ::= { ospfGeneralGroup 9 } ospfRxNewLsas OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION Galecki, et al. Standards Track PAGE 14

RFC 4750 OSPFv2 MIB December 2006 "The number of link state advertisements received that are determined to be new instantiations. This number does not include newer instantiations of self-originated link state advertisements. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ospfDiscontinuityTime." ::= { ospfGeneralGroup 10 } ospfExtLsdbLimit OBJECT-TYPE SYNTAX Integer32 (-1..'7FFFFFFF'h) MAX-ACCESS read-write STATUS current DESCRIPTION "The maximum number of non-default AS-external LSAs entries that can be stored in the link state database. If the value is -1, then there is no limit. When the number of non-default AS-external LSAs in a router's link state database reaches ospfExtLsdbLimit, the router enters overflow state. The router never holds more than ospfExtLsdbLimit non-default AS-external LSAs in its database. OspfExtLsdbLimit MUST be set identically in all routers attached to the OSPF backbone and/or any regular OSPF area (i.e., OSPF stub areas and NSSAs are excluded). This object is persistent and when written the entity SHOULD save the change to non-volatile storage." DEFVAL { -1 } ::= { ospfGeneralGroup 11 } ospfMulticastExtensions OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-write STATUS current DESCRIPTION "A bit mask indicating whether the router is forwarding IP multicast (Class D) datagrams based on the algorithms defined in the multicast extensions to OSPF. Bit 0, if set, indicates that the router can Galecki, et al. Standards Track PAGE 15

RFC 4750 OSPFv2 MIB December 2006 forward IP multicast datagrams in the router's directly attached areas (called intra-area multicast routing). Bit 1, if set, indicates that the router can forward IP multicast datagrams between OSPF areas (called inter-area multicast routing). Bit 2, if set, indicates that the router can forward IP multicast datagrams between Autonomous Systems (called inter-AS multicast routing). Only certain combinations of bit settings are allowed, namely: 0 (no multicast forwarding is enabled), 1 (intra-area multicasting only), 3 (intra-area and inter-area multicasting), 5 (intra-area and inter-AS multicasting), and 7 (multicasting everywhere). By default, no multicast forwarding is enabled. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." DEFVAL { 0 } ::= { ospfGeneralGroup 12 } ospfExitOverflowInterval OBJECT-TYPE SYNTAX PositiveInteger MAX-ACCESS read-write STATUS current DESCRIPTION "The number of seconds that, after entering OverflowState, a router will attempt to leave OverflowState. This allows the router to again originate non-default AS-external LSAs. When set to 0, the router will not leave overflow state until restarted. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." DEFVAL { 0 } ::= { ospfGeneralGroup 13 } ospfDemandExtensions OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write Galecki, et al. Standards Track PAGE 16

RFC 4750 OSPFv2 MIB December 2006 STATUS current DESCRIPTION "The router's support for demand routing. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." REFERENCE "Extending OSPF to Support Demand Circuits" ::= { ospfGeneralGroup 14 } ospfRFC1583Compatibility OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates metrics used to choose among multiple AS-external LSAs. When RFC1583Compatibility is set to enabled, only cost will be used when choosing among multiple AS-external LSAs advertising the same destination. When RFC1583Compatibility is set to disabled, preference will be driven first by type of path using cost only to break ties. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." REFERENCE "OSPF Version 2, Section 16.4.1 External path preferences" ::= { ospfGeneralGroup 15 } ospfOpaqueLsaSupport OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-only STATUS current DESCRIPTION "The router's support for Opaque LSA types." REFERENCE "The OSPF Opaque LSA Option" ::= { ospfGeneralGroup 16 } ospfReferenceBandwidth OBJECT-TYPE SYNTAX Unsigned32 UNITS "kilobits per second" MAX-ACCESS read-write STATUS current DESCRIPTION "Reference bandwidth in kilobits/second for Galecki, et al. Standards Track PAGE 17

RFC 4750 OSPFv2 MIB December 2006 calculating default interface metrics. The default value is 100,000 KBPS (100 MBPS). This object is persistent and when written the entity SHOULD save the change to non-volatile storage." ::= { ospfGeneralGroup 17 } ospfRestartSupport OBJECT-TYPE SYNTAX INTEGER { none (1), plannedOnly (2), plannedAndUnplanned (3) } MAX-ACCESS read-write STATUS current DESCRIPTION "The router's support for OSPF graceful restart. Options include: no restart support, only planned restarts, or both planned and unplanned restarts. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." ::= { ospfGeneralGroup 18 } ospfRestartInterval OBJECT-TYPE SYNTAX Integer32 (1..1800) UNITS "seconds" MAX-ACCESS read-write STATUS current DESCRIPTION "Configured OSPF graceful restart timeout interval. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." ::= { ospfGeneralGroup 19 } ospfRestartStrictLsaChecking OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates if strict LSA checking is enabled for graceful restart. This object is persistent and when written the entity SHOULD save the change to non-volatile Galecki, et al. Standards Track PAGE 18

RFC 4750 OSPFv2 MIB December 2006 storage." ::= { ospfGeneralGroup 20 } ospfRestartStatus OBJECT-TYPE SYNTAX INTEGER { notRestarting (1), plannedRestart (2), unplannedRestart (3) } MAX-ACCESS read-only STATUS current DESCRIPTION "Current status of OSPF graceful restart." ::= { ospfGeneralGroup 21 } ospfRestartAge OBJECT-TYPE SYNTAX Unsigned32 UNITS "seconds" MAX-ACCESS read-only STATUS current DESCRIPTION "Remaining time in current OSPF graceful restart interval." ::= { ospfGeneralGroup 22 } ospfRestartExitReason OBJECT-TYPE SYNTAX INTEGER { none (1), -- none attempted inProgress (2), -- restart in -- progress completed (3), -- successfully -- completed timedOut (4), -- timed out topologyChanged (5) -- aborted due to -- topology change. } MAX-ACCESS read-only STATUS current DESCRIPTION "Describes the outcome of the last attempt at a graceful restart. If the value is 'none', no restart has yet been attempted. If the value is 'inProgress', a restart attempt is currently underway." ::= { ospfGeneralGroup 23 } ospfAsLsaCount OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current Galecki, et al. Standards Track PAGE 19

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The number of AS-scope link state advertisements in the AS-scope link state database." ::= { ospfGeneralGroup 24 } ospfAsLsaCksumSum OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The 32-bit unsigned sum of the LS checksums of the AS link state advertisements contained in the AS-scope link state database. This sum can be used to determine if there has been a change in a router's AS-scope link state database, and to compare the AS-scope link state database of two routers." ::= { ospfGeneralGroup 25 } ospfStubRouterSupport OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-only STATUS current DESCRIPTION "The router's support for stub router functionality." REFERENCE "OSPF Stub Router Advertisement" ::= { ospfGeneralGroup 26 } ospfStubRouterAdvertisement OBJECT-TYPE SYNTAX INTEGER { doNotAdvertise (1), advertise(2) } MAX-ACCESS read-write STATUS current DESCRIPTION "This object controls the advertisement of stub router LSAs by the router. The value doNotAdvertise will result in the advertisement of a standard router LSA and is the default value. This object is persistent and when written the entity SHOULD save the change to non-volatile storage." ::= { ospfGeneralGroup 27 } ospfDiscontinuityTime OBJECT-TYPE SYNTAX TimeStamp Galecki, et al. Standards Track PAGE 20

RFC 4750 OSPFv2 MIB December 2006 MAX-ACCESS read-only STATUS current DESCRIPTION "The value of sysUpTime on the most recent occasion at which any one of this MIB's counters suffered a discontinuity. If no such discontinuities have occurred since the last re-initialization of the local management subsystem, then this object contains a zero value." ::= { ospfGeneralGroup 28 } -- OSPF Area Table -- The OSPF Area Table contains information -- regarding the various areas. ospfAreaTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfAreaEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Information describing the configured parameters and cumulative statistics of the router's attached areas. The interfaces and virtual links are configured as part of these areas. Area 0.0.0.0, by definition, is the backbone area." REFERENCE "OSPF Version 2, Section 6 The Area Data Structure" ::= { ospf 2 } ospfAreaEntry OBJECT-TYPE SYNTAX OspfAreaEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Information describing the configured parameters and cumulative statistics of one of the router's attached areas. The interfaces and virtual links are configured as part of these areas. Area 0.0.0.0, by definition, is the backbone area. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile storage." INDEX { ospfAreaId } ::= { ospfAreaTable 1 } Galecki, et al. Standards Track PAGE 21

RFC 4750 OSPFv2 MIB December 2006 OspfAreaEntry ::= SEQUENCE { ospfAreaId AreaID, ospfAuthType OspfAuthenticationType, ospfImportAsExtern INTEGER, ospfSpfRuns Counter32, ospfAreaBdrRtrCount Gauge32, ospfAsBdrRtrCount Gauge32, ospfAreaLsaCount Gauge32, ospfAreaLsaCksumSum Integer32, ospfAreaSummary INTEGER, ospfAreaStatus RowStatus, ospfAreaNssaTranslatorRole INTEGER, ospfAreaNssaTranslatorState INTEGER, ospfAreaNssaTranslatorStabilityInterval PositiveInteger, ospfAreaNssaTranslatorEvents Counter32 } ospfAreaId OBJECT-TYPE SYNTAX AreaID MAX-ACCESS read-only -- read-only since originally -- an SMIv1 index STATUS current DESCRIPTION "A 32-bit integer uniquely identifying an area. Area ID 0.0.0.0 is used for the OSPF backbone." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospfAreaEntry 1 } ospfAuthType OBJECT-TYPE SYNTAX OspfAuthenticationType MAX-ACCESS read-create STATUS obsolete Galecki, et al. Standards Track PAGE 22

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The authentication type specified for an area." REFERENCE "OSPF Version 2, Appendix D Authentication" DEFVAL { none } -- no authentication, by default ::= { ospfAreaEntry 2 } ospfImportAsExtern OBJECT-TYPE SYNTAX INTEGER { importExternal (1), importNoExternal (2), importNssa (3) } MAX-ACCESS read-create STATUS current DESCRIPTION "Indicates if an area is a stub area, NSSA, or standard area. Type-5 AS-external LSAs and type-11 Opaque LSAs are not imported into stub areas or NSSAs. NSSAs import AS-external data as type-7 LSAs" REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" DEFVAL { importExternal } ::= { ospfAreaEntry 3 } ospfSpfRuns OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of times that the intra-area route table has been calculated using this area's link state database. This is typically done using Dijkstra's algorithm. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ospfDiscontinuityTime." ::= { ospfAreaEntry 4 } ospfAreaBdrRtrCount OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "The total number of Area Border Routers reachable within this area. This is initially zero and is calculated in each Shortest Path First (SPF) pass." Galecki, et al. Standards Track PAGE 23

RFC 4750 OSPFv2 MIB December 2006 ::= { ospfAreaEntry 5 } ospfAsBdrRtrCount OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "The total number of Autonomous System Border Routers reachable within this area. This is initially zero and is calculated in each SPF pass." ::= { ospfAreaEntry 6 } ospfAreaLsaCount OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "The total number of link state advertisements in this area's link state database, excluding AS-external LSAs." ::= { ospfAreaEntry 7 } ospfAreaLsaCksumSum OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "The 32-bit sum of the link state advertisements' LS checksums contained in this area's link state database. This sum excludes external (LS type-5) link state advertisements. The sum can be used to determine if there has been a change in a router's link state database, and to compare the link state database of two routers. The value should be treated as unsigned when comparing two sums of checksums." DEFVAL { 0 } ::= { ospfAreaEntry 8 } ospfAreaSummary OBJECT-TYPE SYNTAX INTEGER { noAreaSummary (1), sendAreaSummary (2) } MAX-ACCESS read-create STATUS current DESCRIPTION Galecki, et al. Standards Track PAGE 24

RFC 4750 OSPFv2 MIB December 2006 "The variable ospfAreaSummary controls the import of summary LSAs into stub and NSSA areas. It has no effect on other areas. If it is noAreaSummary, the router will not originate summary LSAs into the stub or NSSA area. It will rely entirely on its default route. If it is sendAreaSummary, the router will both summarize and propagate summary LSAs." DEFVAL { noAreaSummary } ::= { ospfAreaEntry 9 } ospfAreaStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfAreaEntry 10 } ospfAreaNssaTranslatorRole OBJECT-TYPE SYNTAX INTEGER { always (1), candidate (2) } MAX-ACCESS read-create STATUS current DESCRIPTION "Indicates an NSSA border router's ability to perform NSSA translation of type-7 LSAs into type-5 LSAs." DEFVAL { candidate } ::= { ospfAreaEntry 11 } ospfAreaNssaTranslatorState OBJECT-TYPE SYNTAX INTEGER { enabled (1), elected (2), disabled (3) } MAX-ACCESS read-only STATUS current DESCRIPTION "Indicates if and how an NSSA border router is performing NSSA translation of type-7 LSAs into type-5 Galecki, et al. Standards Track PAGE 25

RFC 4750 OSPFv2 MIB December 2006 LSAs. When this object is set to enabled, the NSSA Border router's OspfAreaNssaExtTranslatorRole has been set to always. When this object is set to elected, a candidate NSSA Border router is Translating type-7 LSAs into type-5. When this object is set to disabled, a candidate NSSA border router is NOT translating type-7 LSAs into type-5." ::= { ospfAreaEntry 12 } ospfAreaNssaTranslatorStabilityInterval OBJECT-TYPE SYNTAX PositiveInteger UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The number of seconds after an elected translator determines its services are no longer required, that it should continue to perform its translation duties." DEFVAL { 40 } ::= { ospfAreaEntry 13 } ospfAreaNssaTranslatorEvents OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "Indicates the number of translator state changes that have occurred since the last boot-up. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ospfDiscontinuityTime." ::= { ospfAreaEntry 14 } -- OSPF Area Default Metric Table ospfStubAreaTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfStubAreaEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The set of metrics that will be advertised by a default Area Border Router into a stub area." REFERENCE "OSPF Version 2, Appendix C.2, Area Parameters" ::= { ospf 3 } ospfStubAreaEntry OBJECT-TYPE SYNTAX OspfStubAreaEntry Galecki, et al. Standards Track PAGE 26

RFC 4750 OSPFv2 MIB December 2006 MAX-ACCESS not-accessible STATUS current DESCRIPTION "The metric for a given Type of Service that will be advertised by a default Area Border Router into a stub area. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile storage." REFERENCE "OSPF Version 2, Appendix C.2, Area Parameters" INDEX { ospfStubAreaId, ospfStubTOS } ::= { ospfStubAreaTable 1 } OspfStubAreaEntry ::= SEQUENCE { ospfStubAreaId AreaID, ospfStubTOS TOSType, ospfStubMetric BigMetric, ospfStubStatus RowStatus, ospfStubMetricType INTEGER } ospfStubAreaId OBJECT-TYPE SYNTAX AreaID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The 32-bit identifier for the stub area. On creation, this can be derived from the instance." ::= { ospfStubAreaEntry 1 } ospfStubTOS OBJECT-TYPE SYNTAX TOSType MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The Type of Service associated with the metric. On creation, this can be derived from Galecki, et al. Standards Track PAGE 27

RFC 4750 OSPFv2 MIB December 2006 the instance." ::= { ospfStubAreaEntry 2 } ospfStubMetric OBJECT-TYPE SYNTAX BigMetric MAX-ACCESS read-create STATUS current DESCRIPTION "The metric value applied at the indicated Type of Service. By default, this equals the least metric at the Type of Service among the interfaces to other areas." ::= { ospfStubAreaEntry 3 } ospfStubStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfStubAreaEntry 4 } ospfStubMetricType OBJECT-TYPE SYNTAX INTEGER { ospfMetric (1), -- OSPF Metric comparableCost (2), -- external type 1 nonComparable (3) -- external type 2 } MAX-ACCESS read-create STATUS current DESCRIPTION "This variable displays the type of metric advertised as a default route." DEFVAL { ospfMetric } ::= { ospfStubAreaEntry 5 } -- OSPF Link State Database ospfLsdbTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfLsdbEntry MAX-ACCESS not-accessible STATUS current Galecki, et al. Standards Track PAGE 28

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The OSPF Process's link state database (LSDB). The LSDB contains the link state advertisements from throughout the areas that the device is attached to." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements" ::= { ospf 4 } ospfLsdbEntry OBJECT-TYPE SYNTAX OspfLsdbEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A single link state advertisement." INDEX { ospfLsdbAreaId, ospfLsdbType, ospfLsdbLsid, ospfLsdbRouterId } ::= { ospfLsdbTable 1 } OspfLsdbEntry ::= SEQUENCE { ospfLsdbAreaId AreaID, ospfLsdbType INTEGER, ospfLsdbLsid IpAddress, ospfLsdbRouterId RouterID, ospfLsdbSequence Integer32, ospfLsdbAge Integer32, ospfLsdbChecksum Integer32, ospfLsdbAdvertisement OCTET STRING } ospfLsdbAreaId OBJECT-TYPE SYNTAX AreaID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The 32-bit identifier of the area from which the LSA was received." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" Galecki, et al. Standards Track PAGE 29

RFC 4750 OSPFv2 MIB December 2006 ::= { ospfLsdbEntry 1 } ospfLsdbType OBJECT-TYPE SYNTAX INTEGER { routerLink (1), networkLink (2), summaryLink (3), asSummaryLink (4), asExternalLink (5), -- but see ospfAsLsdbTable multicastLink (6), nssaExternalLink (7), areaOpaqueLink (10) } MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The type of the link state advertisement. Each link state type has a separate advertisement format. Note: External link state advertisements are permitted for backward compatibility, but should be displayed in the ospfAsLsdbTable rather than here." REFERENCE "OSPF Version 2, Appendix A.4.1 The Link State Advertisement header" ::= { ospfLsdbEntry 2 } ospfLsdbLsid OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The Link State ID is an LS Type Specific field containing either a Router ID or an IP address; it identifies the piece of the routing domain that is being described by the advertisement." REFERENCE "OSPF Version 2, Section 12.1.4 Link State ID" ::= { ospfLsdbEntry 3 } ospfLsdbRouterId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current Galecki, et al. Standards Track PAGE 30

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The 32-bit number that uniquely identifies the originating router in the Autonomous System." REFERENCE "OSPF Version 2, Appendix C.1 Global parameters" ::= { ospfLsdbEntry 4 } ospfLsdbSequence OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "The sequence number field is a signed 32-bit integer. It starts with the value '80000001'h, or -'7FFFFFFF'h, and increments until '7FFFFFFF'h. Thus, a typical sequence number will be very negative. It is used to detect old and duplicate Link State Advertisements. The space of sequence numbers is linearly ordered. The larger the sequence number, the more recent the advertisement." REFERENCE "OSPF Version 2, Section 12.1.6 LS sequence number" ::= { ospfLsdbEntry 5 } ospfLsdbAge OBJECT-TYPE SYNTAX Integer32 -- Should be 0..MaxAge, except when -- doNotAge bit is set UNITS "seconds" MAX-ACCESS read-only STATUS current DESCRIPTION "This field is the age of the link state advertisement in seconds." REFERENCE "OSPF Version 2, Section 12.1.1 LS age" ::= { ospfLsdbEntry 6 } ospfLsdbChecksum OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "This field is the checksum of the complete contents of the advertisement, excepting the age field. The age field is excepted so that an advertisement's age can be incremented without updating the checksum. The checksum used is the same that is used for ISO connectionless Galecki, et al. Standards Track PAGE 31

RFC 4750 OSPFv2 MIB December 2006 datagrams; it is commonly referred to as the Fletcher checksum." REFERENCE "OSPF Version 2, Section 12.1.7 LS checksum" ::= { ospfLsdbEntry 7 } ospfLsdbAdvertisement OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1..65535)) MAX-ACCESS read-only STATUS current DESCRIPTION "The entire link state advertisement, including its header. Note that for variable length LSAs, SNMP agents may not be able to return the largest string size." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements" ::= { ospfLsdbEntry 8 } -- Address Range Table ospfAreaRangeTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfAreaRangeEntry MAX-ACCESS not-accessible STATUS obsolete DESCRIPTION "The Address Range Table acts as an adjunct to the Area Table. It describes those Address Range Summaries that are configured to be propagated from an Area to reduce the amount of information about it that is known beyond its borders. It contains a set of IP address ranges specified by an IP address/IP network mask pair. For example, class B address range of X.X.X.X with a network mask of 255.255.0.0 includes all IP addresses from X.X.0.0 to X.X.255.255. Note that this table is obsoleted and is replaced by the Area Aggregate Table." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospf 5 } ospfAreaRangeEntry OBJECT-TYPE SYNTAX OspfAreaRangeEntry MAX-ACCESS not-accessible STATUS obsolete DESCRIPTION Galecki, et al. Standards Track PAGE 32

RFC 4750 OSPFv2 MIB December 2006 "A single area address range. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile storage." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" INDEX { ospfAreaRangeAreaId, ospfAreaRangeNet } ::= { ospfAreaRangeTable 1 } OspfAreaRangeEntry ::= SEQUENCE { ospfAreaRangeAreaId AreaID, ospfAreaRangeNet IpAddress, ospfAreaRangeMask IpAddress, ospfAreaRangeStatus RowStatus, ospfAreaRangeEffect INTEGER } ospfAreaRangeAreaId OBJECT-TYPE SYNTAX AreaID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS obsolete DESCRIPTION "The area that the address range is to be found within." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospfAreaRangeEntry 1 } ospfAreaRangeNet OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS obsolete DESCRIPTION "The IP address of the net or subnet indicated by the range." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospfAreaRangeEntry 2 } Galecki, et al. Standards Track PAGE 33

RFC 4750 OSPFv2 MIB December 2006 ospfAreaRangeMask OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-create STATUS obsolete DESCRIPTION "The subnet mask that pertains to the net or subnet." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospfAreaRangeEntry 3 } ospfAreaRangeStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS obsolete DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfAreaRangeEntry 4 } ospfAreaRangeEffect OBJECT-TYPE SYNTAX INTEGER { advertiseMatching (1), doNotAdvertiseMatching (2) } MAX-ACCESS read-create STATUS obsolete DESCRIPTION "Subnets subsumed by ranges either trigger the advertisement of the indicated summary (advertiseMatching) or result in the subnet's not being advertised at all outside the area." DEFVAL { advertiseMatching } ::= { ospfAreaRangeEntry 5 } -- OSPF Host Table ospfHostTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfHostEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The Host/Metric Table indicates what hosts are directly Galecki, et al. Standards Track PAGE 34

RFC 4750 OSPFv2 MIB December 2006 attached to the router, what metrics and types of service should be advertised for them, and what areas they are found within." REFERENCE "OSPF Version 2, Appendix C.7 Host route parameters" ::= { ospf 6 } ospfHostEntry OBJECT-TYPE SYNTAX OspfHostEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A metric to be advertised, for a given type of service, when a given host is reachable. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile storage." INDEX { ospfHostIpAddress, ospfHostTOS } ::= { ospfHostTable 1 } OspfHostEntry ::= SEQUENCE { ospfHostIpAddress IpAddress, ospfHostTOS TOSType, ospfHostMetric Metric, ospfHostStatus RowStatus, ospfHostAreaID AreaID, ospfHostCfgAreaID AreaID } ospfHostIpAddress OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The IP address of the host." REFERENCE "OSPF Version 2, Appendix C.7 Host route parameters" ::= { ospfHostEntry 1 } Galecki, et al. Standards Track PAGE 35

RFC 4750 OSPFv2 MIB December 2006 ospfHostTOS OBJECT-TYPE SYNTAX TOSType MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The Type of Service of the route being configured." REFERENCE "OSPF Version 2, Appendix C.7 Host route parameters" ::= { ospfHostEntry 2 } ospfHostMetric OBJECT-TYPE SYNTAX Metric MAX-ACCESS read-create STATUS current DESCRIPTION "The metric to be advertised." REFERENCE "OSPF Version 2, Appendix C.7 Host route parameters" ::= { ospfHostEntry 3 } ospfHostStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfHostEntry 4 } ospfHostAreaID OBJECT-TYPE SYNTAX AreaID MAX-ACCESS read-only STATUS deprecated DESCRIPTION "The OSPF area to which the host belongs. Deprecated by ospfHostCfgAreaID." REFERENCE "OSPF Version 2, Appendix C.7 Host parameters" ::= { ospfHostEntry 5 } ospfHostCfgAreaID OBJECT-TYPE SYNTAX AreaID Galecki, et al. Standards Track PAGE 36

RFC 4750 OSPFv2 MIB December 2006 MAX-ACCESS read-create STATUS current DESCRIPTION "To configure the OSPF area to which the host belongs." REFERENCE "OSPF Version 2, Appendix C.7 Host parameters" ::= { ospfHostEntry 6 } -- OSPF Interface Table ospfIfTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfIfEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The OSPF Interface Table describes the interfaces from the viewpoint of OSPF. It augments the ipAddrTable with OSPF specific information." REFERENCE "OSPF Version 2, Appendix C.3 Router interface parameters" ::= { ospf 7 } ospfIfEntry OBJECT-TYPE SYNTAX OspfIfEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The OSPF interface entry describes one interface from the viewpoint of OSPF. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile storage." INDEX { ospfIfIpAddress, ospfAddressLessIf } ::= { ospfIfTable 1 } OspfIfEntry ::= SEQUENCE { ospfIfIpAddress IpAddress, ospfAddressLessIf InterfaceIndexOrZero, ospfIfAreaId AreaID, ospfIfType INTEGER, ospfIfAdminStat Galecki, et al. Standards Track PAGE 37

RFC 4750 OSPFv2 MIB December 2006 Status, ospfIfRtrPriority DesignatedRouterPriority, ospfIfTransitDelay UpToMaxAge, ospfIfRetransInterval UpToMaxAge, ospfIfHelloInterval HelloRange, ospfIfRtrDeadInterval PositiveInteger, ospfIfPollInterval PositiveInteger, ospfIfState INTEGER, ospfIfDesignatedRouter IpAddress, ospfIfBackupDesignatedRouter IpAddress, ospfIfEvents Counter32, ospfIfAuthKey OCTET STRING, ospfIfStatus RowStatus, ospfIfMulticastForwarding INTEGER, ospfIfDemand TruthValue, ospfIfAuthType OspfAuthenticationType, ospfIfLsaCount Gauge32, ospfIfLsaCksumSum Unsigned32, ospfIfDesignatedRouterId RouterID, ospfIfBackupDesignatedRouterId RouterID } ospfIfIpAddress OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The IP address of this OSPF interface." Galecki, et al. Standards Track PAGE 38

RFC 4750 OSPFv2 MIB December 2006 ::= { ospfIfEntry 1 } ospfAddressLessIf OBJECT-TYPE SYNTAX InterfaceIndexOrZero MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "For the purpose of easing the instancing of addressed and addressless interfaces; this variable takes the value 0 on interfaces with IP addresses and the corresponding value of ifIndex for interfaces having no IP address." ::= { ospfIfEntry 2 } ospfIfAreaId OBJECT-TYPE SYNTAX AreaID MAX-ACCESS read-create STATUS current DESCRIPTION "A 32-bit integer uniquely identifying the area to which the interface connects. Area ID 0.0.0.0 is used for the OSPF backbone." DEFVAL { '00000000'H } -- 0.0.0.0 ::= { ospfIfEntry 3 } ospfIfType OBJECT-TYPE SYNTAX INTEGER { broadcast (1), nbma (2), pointToPoint (3), pointToMultipoint (5) } MAX-ACCESS read-create STATUS current DESCRIPTION "The OSPF interface type. By way of a default, this field may be intuited from the corresponding value of ifType. Broadcast LANs, such as Ethernet and IEEE 802.5, take the value 'broadcast', X.25 and similar technologies take the value 'nbma', and links that are definitively point to point take the value 'pointToPoint'." ::= { ospfIfEntry 4 } ospfIfAdminStat OBJECT-TYPE SYNTAX Status Galecki, et al. Standards Track PAGE 39

RFC 4750 OSPFv2 MIB December 2006 MAX-ACCESS read-create STATUS current DESCRIPTION "The OSPF interface's administrative status. The value formed on the interface, and the interface will be advertised as an internal route to some area. The value 'disabled' denotes that the interface is external to OSPF." DEFVAL { enabled } ::= { ospfIfEntry 5 } ospfIfRtrPriority OBJECT-TYPE SYNTAX DesignatedRouterPriority MAX-ACCESS read-create STATUS current DESCRIPTION "The priority of this interface. Used in multi-access networks, this field is used in the designated router election algorithm. The value 0 signifies that the router is not eligible to become the designated router on this particular network. In the event of a tie in this value, routers will use their Router ID as a tie breaker." DEFVAL { 1 } ::= { ospfIfEntry 6 } ospfIfTransitDelay OBJECT-TYPE SYNTAX UpToMaxAge UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The estimated number of seconds it takes to transmit a link state update packet over this interface. Note that the minimal value SHOULD be 1 second." DEFVAL { 1 } ::= { ospfIfEntry 7 } ospfIfRetransInterval OBJECT-TYPE SYNTAX UpToMaxAge UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The number of seconds between link state advertisement retransmissions, for adjacencies belonging to this interface. This value is also used when retransmitting Galecki, et al. Standards Track PAGE 40

RFC 4750 OSPFv2 MIB December 2006 database description and Link State request packets. Note that minimal value SHOULD be 1 second." DEFVAL { 5 } ::= { ospfIfEntry 8 } ospfIfHelloInterval OBJECT-TYPE SYNTAX HelloRange UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The length of time, in seconds, between the Hello packets that the router sends on the interface. This value must be the same for all routers attached to a common network." DEFVAL { 10 } ::= { ospfIfEntry 9 } ospfIfRtrDeadInterval OBJECT-TYPE SYNTAX PositiveInteger UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The number of seconds that a router's Hello packets have not been seen before its neighbors declare the router down. This should be some multiple of the Hello interval. This value must be the same for all routers attached to a common network." DEFVAL { 40 } ::= { ospfIfEntry 10 } ospfIfPollInterval OBJECT-TYPE SYNTAX PositiveInteger UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The larger time interval, in seconds, between the Hello packets sent to an inactive non-broadcast multi-access neighbor." DEFVAL { 120 } ::= { ospfIfEntry 11 } ospfIfState OBJECT-TYPE SYNTAX INTEGER { down (1), loopback (2), waiting (3), Galecki, et al. Standards Track PAGE 41

RFC 4750 OSPFv2 MIB December 2006 pointToPoint (4), designatedRouter (5), backupDesignatedRouter (6), otherDesignatedRouter (7) } MAX-ACCESS read-only STATUS current DESCRIPTION "The OSPF Interface State." DEFVAL { down } ::= { ospfIfEntry 12 } ospfIfDesignatedRouter OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only STATUS current DESCRIPTION "The IP address of the designated router." DEFVAL { '00000000'H } -- 0.0.0.0 ::= { ospfIfEntry 13 } ospfIfBackupDesignatedRouter OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only STATUS current DESCRIPTION "The IP address of the backup designated router." DEFVAL { '00000000'H } -- 0.0.0.0 ::= { ospfIfEntry 14 } ospfIfEvents OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of times this OSPF interface has changed its state or an error has occurred. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ospfDiscontinuityTime." ::= { ospfIfEntry 15 } ospfIfAuthKey OBJECT-TYPE SYNTAX OCTET STRING (SIZE (0..256)) MAX-ACCESS read-create STATUS current Galecki, et al. Standards Track PAGE 42

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The cleartext password used as an OSPF authentication key when simplePassword security is enabled. This object does not access any OSPF cryptogaphic (e.g., MD5) authentication key under any circumstance. If the key length is shorter than 8 octets, the agent will left adjust and zero fill to 8 octets. Unauthenticated interfaces need no authentication key, and simple password authentication cannot use a key of more than 8 octets. Note that the use of simplePassword authentication is NOT recommended when there is concern regarding attack upon the OSPF system. SimplePassword authentication is only sufficient to protect against accidental misconfigurations because it re-uses cleartext passwords [RFC 1704]. When read, ospfIfAuthKey always returns an octet string of length zero." REFERENCE "OSPF Version 2, Section 9 The Interface Data Structure" DEFVAL { '0000000000000000'H } -- 0.0.0.0.0.0.0.0 ::= { ospfIfEntry 16 } ospfIfStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfIfEntry 17 } ospfIfMulticastForwarding OBJECT-TYPE SYNTAX INTEGER { blocked (1), -- no multicast forwarding multicast (2), -- using multicast address unicast (3) -- to each OSPF neighbor Galecki, et al. Standards Track PAGE 43

RFC 4750 OSPFv2 MIB December 2006 } MAX-ACCESS read-create STATUS current DESCRIPTION "The way multicasts should be forwarded on this interface: not forwarded, forwarded as data link multicasts, or forwarded as data link unicasts. Data link multicasting is not meaningful on point-to-point and NBMA interfaces, and setting ospfMulticastForwarding to 0 effectively disables all multicast forwarding." DEFVAL { blocked } ::= { ospfIfEntry 18 } ospfIfDemand OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-create STATUS current DESCRIPTION "Indicates whether Demand OSPF procedures (hello suppression to FULL neighbors and setting the DoNotAge flag on propagated LSAs) should be performed on this interface." DEFVAL { false } ::= { ospfIfEntry 19 } ospfIfAuthType OBJECT-TYPE SYNTAX OspfAuthenticationType MAX-ACCESS read-create STATUS current DESCRIPTION "The authentication type specified for an interface. Note that this object can be used to engage in significant attacks against an OSPF router." REFERENCE "OSPF Version 2, Appendix D Authentication" DEFVAL { none } -- no authentication, by default ::= { ospfIfEntry 20 } ospfIfLsaCount OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "The total number of link-local link state advertisements in this interface's link-local link state database." ::= { ospfIfEntry 21 } Galecki, et al. Standards Track PAGE 44

RFC 4750 OSPFv2 MIB December 2006 ospfIfLsaCksumSum OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The 32-bit unsigned sum of the Link State Advertisements' LS checksums contained in this interface's link-local link state database. The sum can be used to determine if there has been a change in the interface's link state database and to compare the interface link state database of routers attached to the same subnet." ::= { ospfIfEntry 22 } ospfIfDesignatedRouterId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS read-only STATUS current DESCRIPTION "The Router ID of the designated router." ::= { ospfIfEntry 23 } ospfIfBackupDesignatedRouterId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS read-only STATUS current DESCRIPTION "The Router ID of the backup designated router." ::= { ospfIfEntry 24 } -- OSPF Interface Metric Table ospfIfMetricTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfIfMetricEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The Metric Table describes the metrics to be advertised for a specified interface at the various types of service. As such, this table is an adjunct of the OSPF Interface Table. Types of service, as defined by RFC 791, have the ability to request low delay, high bandwidth, or reliable linkage. For the purposes of this specification, the measure of bandwidth: Galecki, et al. Standards Track PAGE 45

RFC 4750 OSPFv2 MIB December 2006 Metric = referenceBandwidth / ifSpeed is the default value. The default reference bandwidth is 10^8. For multiple link interfaces, note that ifSpeed is the sum of the individual link speeds. This yields a number having the following typical values: Network Type/bit rate Metric >= 100 MBPS 1 Ethernet/802.3 10 E1 48 T1 (ESF) 65 64 KBPS 1562 56 KBPS 1785 19.2 KBPS 5208 9.6 KBPS 10416 Routes that are not specified use the default (TOS 0) metric. Note that the default reference bandwidth can be configured using the general group object ospfReferenceBandwidth." REFERENCE "OSPF Version 2, Appendix C.3 Router interface parameters" ::= { ospf 8 } ospfIfMetricEntry OBJECT-TYPE SYNTAX OspfIfMetricEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A particular TOS metric for a non-virtual interface identified by the interface index. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile storage." REFERENCE "OSPF Version 2, Appendix C.3 Router interface parameters" INDEX { ospfIfMetricIpAddress, ospfIfMetricAddressLessIf, ospfIfMetricTOS } ::= { ospfIfMetricTable 1 } Galecki, et al. Standards Track PAGE 46

RFC 4750 OSPFv2 MIB December 2006 OspfIfMetricEntry ::= SEQUENCE { ospfIfMetricIpAddress IpAddress, ospfIfMetricAddressLessIf InterfaceIndexOrZero, ospfIfMetricTOS TOSType, ospfIfMetricValue Metric, ospfIfMetricStatus RowStatus } ospfIfMetricIpAddress OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The IP address of this OSPF interface. On row creation, this can be derived from the instance." ::= { ospfIfMetricEntry 1 } ospfIfMetricAddressLessIf OBJECT-TYPE SYNTAX InterfaceIndexOrZero MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "For the purpose of easing the instancing of addressed and addressless interfaces; this variable takes the value 0 on interfaces with IP addresses and the value of ifIndex for interfaces having no IP address. On row creation, this can be derived from the instance." ::= { ospfIfMetricEntry 2 } ospfIfMetricTOS OBJECT-TYPE SYNTAX TOSType MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The Type of Service metric being referenced. On row creation, this can be derived from the instance." ::= { ospfIfMetricEntry 3 } Galecki, et al. Standards Track PAGE 47

RFC 4750 OSPFv2 MIB December 2006 ospfIfMetricValue OBJECT-TYPE SYNTAX Metric MAX-ACCESS read-create STATUS current DESCRIPTION "The metric of using this Type of Service on this interface. The default value of the TOS 0 metric is 10^8 / ifSpeed." ::= { ospfIfMetricEntry 4 } ospfIfMetricStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfIfMetricEntry 5 } -- OSPF Virtual Interface Table ospfVirtIfTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfVirtIfEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Information about this router's virtual interfaces that the OSPF Process is configured to carry on." REFERENCE "OSPF Version 2, Appendix C.4 Virtual link parameters" ::= { ospf 9 } ospfVirtIfEntry OBJECT-TYPE SYNTAX OspfVirtIfEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Information about a single virtual interface. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile storage." Galecki, et al. Standards Track PAGE 48

RFC 4750 OSPFv2 MIB December 2006 INDEX { ospfVirtIfAreaId, ospfVirtIfNeighbor } ::= { ospfVirtIfTable 1 } OspfVirtIfEntry ::= SEQUENCE { ospfVirtIfAreaId AreaID, ospfVirtIfNeighbor RouterID, ospfVirtIfTransitDelay UpToMaxAge, ospfVirtIfRetransInterval UpToMaxAge, ospfVirtIfHelloInterval HelloRange, ospfVirtIfRtrDeadInterval PositiveInteger, ospfVirtIfState INTEGER, ospfVirtIfEvents Counter32, ospfVirtIfAuthKey OCTET STRING, ospfVirtIfStatus RowStatus, ospfVirtIfAuthType OspfAuthenticationType, ospfVirtIfLsaCount Gauge32, ospfVirtIfLsaCksumSum Unsigned32 } ospfVirtIfAreaId OBJECT-TYPE SYNTAX AreaID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The transit area that the virtual link traverses. By definition, this is not 0.0.0.0." ::= { ospfVirtIfEntry 1 } ospfVirtIfNeighbor OBJECT-TYPE SYNTAX RouterID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current Galecki, et al. Standards Track PAGE 49

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The Router ID of the virtual neighbor." ::= { ospfVirtIfEntry 2 } ospfVirtIfTransitDelay OBJECT-TYPE SYNTAX UpToMaxAge UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The estimated number of seconds it takes to transmit a Link State update packet over this interface. Note that the minimal value SHOULD be 1 second." DEFVAL { 1 } ::= { ospfVirtIfEntry 3 } ospfVirtIfRetransInterval OBJECT-TYPE SYNTAX UpToMaxAge UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The number of seconds between link state avertisement retransmissions, for adjacencies belonging to this interface. This value is also used when retransmitting database description and Link State request packets. This value should be well over the expected round-trip time. Note that the minimal value SHOULD be 1 second." DEFVAL { 5 } ::= { ospfVirtIfEntry 4 } ospfVirtIfHelloInterval OBJECT-TYPE SYNTAX HelloRange UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The length of time, in seconds, between the Hello packets that the router sends on the interface. This value must be the same for the virtual neighbor." DEFVAL { 10 } ::= { ospfVirtIfEntry 5 } ospfVirtIfRtrDeadInterval OBJECT-TYPE Galecki, et al. Standards Track PAGE 50

RFC 4750 OSPFv2 MIB December 2006 SYNTAX PositiveInteger UNITS "seconds" MAX-ACCESS read-create STATUS current DESCRIPTION "The number of seconds that a router's Hello packets have not been seen before its neighbors declare the router down. This should be some multiple of the Hello interval. This value must be the same for the virtual neighbor." DEFVAL { 60 } ::= { ospfVirtIfEntry 6 } ospfVirtIfState OBJECT-TYPE SYNTAX INTEGER { down (1), -- these use the same encoding pointToPoint (4) -- as the ospfIfTable } MAX-ACCESS read-only STATUS current DESCRIPTION "OSPF virtual interface states." DEFVAL { down } ::= { ospfVirtIfEntry 7 } ospfVirtIfEvents OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of state changes or error events on this virtual link. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ospfDiscontinuityTime." ::= { ospfVirtIfEntry 8 } ospfVirtIfAuthKey OBJECT-TYPE SYNTAX OCTET STRING (SIZE(0..256)) MAX-ACCESS read-create STATUS current DESCRIPTION "The cleartext password used as an OSPF authentication key when simplePassword security is enabled. This object does not access any OSPF cryptogaphic (e.g., MD5) authentication key under any circumstance. Galecki, et al. Standards Track PAGE 51

RFC 4750 OSPFv2 MIB December 2006 If the key length is shorter than 8 octets, the agent will left adjust and zero fill to 8 octets. Unauthenticated interfaces need no authentication key, and simple password authentication cannot use a key of more than 8 octets. Note that the use of simplePassword authentication is NOT recommended when there is concern regarding attack upon the OSPF system. SimplePassword authentication is only sufficient to protect against accidental misconfigurations because it re-uses cleartext passwords. [RFC 1704] When read, ospfIfAuthKey always returns an octet string of length zero." REFERENCE "OSPF Version 2, Section 9 The Interface Data Structure" DEFVAL { '0000000000000000'H } -- 0.0.0.0.0.0.0.0 ::= { ospfVirtIfEntry 9 } ospfVirtIfStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfVirtIfEntry 10 } ospfVirtIfAuthType OBJECT-TYPE SYNTAX OspfAuthenticationType MAX-ACCESS read-create STATUS current DESCRIPTION "The authentication type specified for a virtual interface. Note that this object can be used to engage in significant attacks against an OSPF router." REFERENCE "OSPF Version 2, Appendix E Authentication" DEFVAL { none } -- no authentication, by default Galecki, et al. Standards Track PAGE 52

RFC 4750 OSPFv2 MIB December 2006 ::= { ospfVirtIfEntry 11 } ospfVirtIfLsaCount OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "The total number of link-local link state advertisements in this virtual interface's link-local link state database." ::= { ospfVirtIfEntry 12 } ospfVirtIfLsaCksumSum OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The 32-bit unsigned sum of the link state advertisements' LS checksums contained in this virtual interface's link-local link state database. The sum can be used to determine if there has been a change in the virtual interface's link state database, and to compare the virtual interface link state database of the virtual neighbors." ::= { ospfVirtIfEntry 13 } -- OSPF Neighbor Table ospfNbrTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfNbrEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A table describing all non-virtual neighbors in the locality of the OSPF router." REFERENCE "OSPF Version 2, Section 10 The Neighbor Data Structure" ::= { ospf 10 } ospfNbrEntry OBJECT-TYPE SYNTAX OspfNbrEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The information regarding a single neighbor. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile Galecki, et al. Standards Track PAGE 53

RFC 4750 OSPFv2 MIB December 2006 storage." REFERENCE "OSPF Version 2, Section 10 The Neighbor Data Structure" INDEX { ospfNbrIpAddr, ospfNbrAddressLessIndex } ::= { ospfNbrTable 1 } OspfNbrEntry ::= SEQUENCE { ospfNbrIpAddr IpAddress, ospfNbrAddressLessIndex InterfaceIndexOrZero, ospfNbrRtrId RouterID, ospfNbrOptions Integer32, ospfNbrPriority DesignatedRouterPriority, ospfNbrState INTEGER, ospfNbrEvents Counter32, ospfNbrLsRetransQLen Gauge32, ospfNbmaNbrStatus RowStatus, ospfNbmaNbrPermanence INTEGER, ospfNbrHelloSuppressed TruthValue, ospfNbrRestartHelperStatus INTEGER, ospfNbrRestartHelperAge Unsigned32, ospfNbrRestartHelperExitReason INTEGER } ospfNbrIpAddr OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The IP address this neighbor is using in its IP source address. Note that, on addressless links, this will not be 0.0.0.0 but the Galecki, et al. Standards Track PAGE 54

RFC 4750 OSPFv2 MIB December 2006 address of another of the neighbor's interfaces." ::= { ospfNbrEntry 1 } ospfNbrAddressLessIndex OBJECT-TYPE SYNTAX InterfaceIndexOrZero MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "On an interface having an IP address, zero. On addressless interfaces, the corresponding value of ifIndex in the Internet Standard MIB. On row creation, this can be derived from the instance." ::= { ospfNbrEntry 2 } ospfNbrRtrId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS read-only STATUS current DESCRIPTION "A 32-bit integer (represented as a type IpAddress) uniquely identifying the neighboring router in the Autonomous System." DEFVAL { '00000000'H } -- 0.0.0.0 ::= { ospfNbrEntry 3 } ospfNbrOptions OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "A bit mask corresponding to the neighbor's options field. Bit 0, if set, indicates that the system will operate on Type of Service metrics other than TOS 0. If zero, the neighbor will ignore all metrics except the TOS 0 metric. Bit 1, if set, indicates that the associated area accepts and operates on external information; if zero, it is a stub area. Bit 2, if set, indicates that the system is capable of routing IP multicast datagrams, that is that it implements the multicast extensions to OSPF. Galecki, et al. Standards Track PAGE 55

RFC 4750 OSPFv2 MIB December 2006 Bit 3, if set, indicates that the associated area is an NSSA. These areas are capable of carrying type-7 external advertisements, which are translated into type-5 external advertisements at NSSA borders." REFERENCE "OSPF Version 2, Section 12.1.2 Options" DEFVAL { 0 } ::= { ospfNbrEntry 4 } ospfNbrPriority OBJECT-TYPE SYNTAX DesignatedRouterPriority MAX-ACCESS read-create STATUS current DESCRIPTION "The priority of this neighbor in the designated router election algorithm. The value 0 signifies that the neighbor is not eligible to become the designated router on this particular network." DEFVAL { 1 } ::= { ospfNbrEntry 5 } ospfNbrState OBJECT-TYPE SYNTAX INTEGER { down (1), attempt (2), init (3), twoWay (4), exchangeStart (5), exchange (6), loading (7), full (8) } MAX-ACCESS read-only STATUS current DESCRIPTION "The state of the relationship with this neighbor." REFERENCE "OSPF Version 2, Section 10.1 Neighbor States" DEFVAL { down } ::= { ospfNbrEntry 6 } ospfNbrEvents OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION Galecki, et al. Standards Track PAGE 56

RFC 4750 OSPFv2 MIB December 2006 "The number of times this neighbor relationship has changed state or an error has occurred. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ospfDiscontinuityTime." ::= { ospfNbrEntry 7 } ospfNbrLsRetransQLen OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current length of the retransmission queue." ::= { ospfNbrEntry 8 } ospfNbmaNbrStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfNbrEntry 9 } ospfNbmaNbrPermanence OBJECT-TYPE SYNTAX INTEGER { dynamic (1), -- learned through protocol permanent (2) -- configured address } MAX-ACCESS read-only STATUS current DESCRIPTION "This variable displays the status of the entry; 'dynamic' and 'permanent' refer to how the neighbor became known." DEFVAL { permanent } ::= { ospfNbrEntry 10 } ospfNbrHelloSuppressed OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-only Galecki, et al. Standards Track PAGE 57

RFC 4750 OSPFv2 MIB December 2006 STATUS current DESCRIPTION "Indicates whether Hellos are being suppressed to the neighbor." ::= { ospfNbrEntry 11 } ospfNbrRestartHelperStatus OBJECT-TYPE SYNTAX INTEGER { notHelping (1), helping (2) } MAX-ACCESS read-only STATUS current DESCRIPTION "Indicates whether the router is acting as a graceful restart helper for the neighbor." ::= { ospfNbrEntry 12 } ospfNbrRestartHelperAge OBJECT-TYPE SYNTAX Unsigned32 UNITS "seconds" MAX-ACCESS read-only STATUS current DESCRIPTION "Remaining time in current OSPF graceful restart interval, if the router is acting as a restart helper for the neighbor." ::= { ospfNbrEntry 13 } ospfNbrRestartHelperExitReason OBJECT-TYPE SYNTAX INTEGER { none (1), -- not attempted inProgress (2), -- restart in -- progress completed (3), -- successfully -- completed timedOut (4), -- timed out topologyChanged (5) -- aborted due to -- topology -- change. } MAX-ACCESS read-only STATUS current DESCRIPTION "Describes the outcome of the last attempt at acting as a graceful restart helper for the neighbor." ::= { ospfNbrEntry 14 } -- OSPF Virtual Neighbor Table Galecki, et al. Standards Track PAGE 58

RFC 4750 OSPFv2 MIB December 2006 ospfVirtNbrTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfVirtNbrEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table describes all virtual neighbors. Since virtual links are configured in the Virtual Interface Table, this table is read-only." REFERENCE "OSPF Version 2, Section 15 Virtual Links" ::= { ospf 11 } ospfVirtNbrEntry OBJECT-TYPE SYNTAX OspfVirtNbrEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Virtual neighbor information." INDEX { ospfVirtNbrArea, ospfVirtNbrRtrId } ::= { ospfVirtNbrTable 1 } OspfVirtNbrEntry ::= SEQUENCE { ospfVirtNbrArea AreaID, ospfVirtNbrRtrId RouterID, ospfVirtNbrIpAddr IpAddress, ospfVirtNbrOptions Integer32, ospfVirtNbrState INTEGER, ospfVirtNbrEvents Counter32, ospfVirtNbrLsRetransQLen Gauge32, ospfVirtNbrHelloSuppressed TruthValue, ospfVirtNbrRestartHelperStatus INTEGER, ospfVirtNbrRestartHelperAge Unsigned32, ospfVirtNbrRestartHelperExitReason INTEGER } ospfVirtNbrArea OBJECT-TYPE Galecki, et al. Standards Track PAGE 59

RFC 4750 OSPFv2 MIB December 2006 SYNTAX AreaID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The Transit Area Identifier." ::= { ospfVirtNbrEntry 1 } ospfVirtNbrRtrId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "A 32-bit integer uniquely identifying the neighboring router in the Autonomous System." ::= { ospfVirtNbrEntry 2 } ospfVirtNbrIpAddr OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only STATUS current DESCRIPTION "The IP address this virtual neighbor is using." ::= { ospfVirtNbrEntry 3 } ospfVirtNbrOptions OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "A bit mask corresponding to the neighbor's options field. Bit 1, if set, indicates that the system will operate on Type of Service metrics other than TOS 0. If zero, the neighbor will ignore all metrics except the TOS 0 metric. Bit 2, if set, indicates that the system is network multicast capable, i.e., that it implements OSPF multicast routing." ::= { ospfVirtNbrEntry 4 } ospfVirtNbrState OBJECT-TYPE SYNTAX INTEGER { down (1), attempt (2), Galecki, et al. Standards Track PAGE 60

RFC 4750 OSPFv2 MIB December 2006 init (3), twoWay (4), exchangeStart (5), exchange (6), loading (7), full (8) } MAX-ACCESS read-only STATUS current DESCRIPTION "The state of the virtual neighbor relationship." ::= { ospfVirtNbrEntry 5 } ospfVirtNbrEvents OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of times this virtual link has changed its state or an error has occurred. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ospfDiscontinuityTime." ::= { ospfVirtNbrEntry 6 } ospfVirtNbrLsRetransQLen OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current length of the retransmission queue." ::= { ospfVirtNbrEntry 7 } ospfVirtNbrHelloSuppressed OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-only STATUS current DESCRIPTION "Indicates whether Hellos are being suppressed to the neighbor." ::= { ospfVirtNbrEntry 8 } ospfVirtNbrRestartHelperStatus OBJECT-TYPE SYNTAX INTEGER { notHelping (1), helping (2) } Galecki, et al. Standards Track PAGE 61

RFC 4750 OSPFv2 MIB December 2006 MAX-ACCESS read-only STATUS current DESCRIPTION "Indicates whether the router is acting as a graceful restart helper for the neighbor." ::= { ospfVirtNbrEntry 9 } ospfVirtNbrRestartHelperAge OBJECT-TYPE SYNTAX Unsigned32 UNITS "seconds" MAX-ACCESS read-only STATUS current DESCRIPTION "Remaining time in current OSPF graceful restart interval, if the router is acting as a restart helper for the neighbor." ::= { ospfVirtNbrEntry 10 } ospfVirtNbrRestartHelperExitReason OBJECT-TYPE SYNTAX INTEGER { none (1), -- not attempted inProgress (2), -- restart in -- progress completed (3), -- successfully -- completed timedOut (4), -- timed out topologyChanged (5) -- aborted due to -- topology -- change. } MAX-ACCESS read-only STATUS current DESCRIPTION "Describes the outcome of the last attempt at acting as a graceful restart helper for the neighbor." ::= { ospfVirtNbrEntry 11 } -- OSPF Link State Database, External ospfExtLsdbTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfExtLsdbEntry MAX-ACCESS not-accessible STATUS deprecated DESCRIPTION "The OSPF Process's external LSA link state database. This table is identical to the OSPF LSDB Table in format, but contains only external link state advertisements. The purpose is to allow external Galecki, et al. Standards Track PAGE 62

RFC 4750 OSPFv2 MIB December 2006 LSAs to be displayed once for the router rather than once in each non-stub area. Note that external LSAs are also in the AS-scope link state database." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements" ::= { ospf 12 } ospfExtLsdbEntry OBJECT-TYPE SYNTAX OspfExtLsdbEntry MAX-ACCESS not-accessible STATUS deprecated DESCRIPTION "A single link state advertisement." INDEX { ospfExtLsdbType, ospfExtLsdbLsid, ospfExtLsdbRouterId } ::= { ospfExtLsdbTable 1 } OspfExtLsdbEntry ::= SEQUENCE { ospfExtLsdbType INTEGER, ospfExtLsdbLsid IpAddress, ospfExtLsdbRouterId RouterID, ospfExtLsdbSequence Integer32, ospfExtLsdbAge Integer32, ospfExtLsdbChecksum Integer32, ospfExtLsdbAdvertisement OCTET STRING } ospfExtLsdbType OBJECT-TYPE SYNTAX INTEGER { asExternalLink (5) } MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS deprecated DESCRIPTION "The type of the link state advertisement. Each link state type has a separate advertisement format." REFERENCE Galecki, et al. Standards Track PAGE 63

RFC 4750 OSPFv2 MIB December 2006 "OSPF Version 2, Appendix A.4.1 The Link State Advertisement header" ::= { ospfExtLsdbEntry 1 } ospfExtLsdbLsid OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS deprecated DESCRIPTION "The Link State ID is an LS Type Specific field containing either a Router ID or an IP address; it identifies the piece of the routing domain that is being described by the advertisement." REFERENCE "OSPF Version 2, Section 12.1.4 Link State ID" ::= { ospfExtLsdbEntry 2 } ospfExtLsdbRouterId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS deprecated DESCRIPTION "The 32-bit number that uniquely identifies the originating router in the Autonomous System." REFERENCE "OSPF Version 2, Appendix C.1 Global parameters" ::= { ospfExtLsdbEntry 3 } ospfExtLsdbSequence OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS deprecated DESCRIPTION "The sequence number field is a signed 32-bit integer. It starts with the value '80000001'h, or -'7FFFFFFF'h, and increments until '7FFFFFFF'h. Thus, a typical sequence number will be very negative. It is used to detect old and duplicate link state advertisements. The space of sequence numbers is linearly ordered. The larger the sequence number, the more recent the advertisement." REFERENCE "OSPF Version 2, Section 12.1.6 LS sequence number" ::= { ospfExtLsdbEntry 4 } Galecki, et al. Standards Track PAGE 64

RFC 4750 OSPFv2 MIB December 2006 ospfExtLsdbAge OBJECT-TYPE SYNTAX Integer32 -- Should be 0..MaxAge, except when -- doNotAge bit is set UNITS "seconds" MAX-ACCESS read-only STATUS deprecated DESCRIPTION "This field is the age of the link state advertisement in seconds." REFERENCE "OSPF Version 2, Section 12.1.1 LS age" ::= { ospfExtLsdbEntry 5 } ospfExtLsdbChecksum OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS deprecated DESCRIPTION "This field is the checksum of the complete contents of the advertisement, excepting the age field. The age field is excepted so that an advertisement's age can be incremented without updating the checksum. The checksum used is the same that is used for ISO connectionless datagrams; it is commonly referred to as the Fletcher checksum." REFERENCE "OSPF Version 2, Section 12.1.7 LS checksum" ::= { ospfExtLsdbEntry 6 } ospfExtLsdbAdvertisement OBJECT-TYPE SYNTAX OCTET STRING (SIZE(36)) MAX-ACCESS read-only STATUS deprecated DESCRIPTION "The entire link state advertisement, including its header." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements" ::= { ospfExtLsdbEntry 7 } -- OSPF Use of the CIDR Route Table ospfRouteGroup OBJECT IDENTIFIER ::= { ospf 13 } -- The IP Forwarding Table defines a number of objects for use by -- the routing protocol to externalize its information. Most of Galecki, et al. Standards Track PAGE 65

RFC 4750 OSPFv2 MIB December 2006 -- the variables (ipForwardDest, ipForwardMask, ipForwardPolicy, -- ipForwardNextHop, ipForwardIfIndex, ipForwardType, -- ipForwardProto, ipForwardAge, and ipForwardNextHopAS) are -- defined there. -- Those that leave some discretion are defined here. -- ipCidrRouteProto is, of course, ospf (13). -- ipCidrRouteAge is the time since the route was first -- calculated, as opposed to the time since the last SPF run. -- ipCidrRouteInfo is an OBJECT IDENTIFIER for use by the routing -- protocol. The following values shall be found there depending -- on the way the route was calculated. ospfIntraArea OBJECT IDENTIFIER ::= { ospfRouteGroup 1 } ospfInterArea OBJECT IDENTIFIER ::= { ospfRouteGroup 2 } ospfExternalType1 OBJECT IDENTIFIER ::= { ospfRouteGroup 3 } ospfExternalType2 OBJECT IDENTIFIER ::= { ospfRouteGroup 4 } -- ipCidrRouteMetric1 is, by definition, the primary routing -- metric. Therefore, it should be the metric that route -- selection is based on. For intra-area and inter-area routes, -- it is an OSPF metric. For External Type 1 (comparable value) -- routes, it is an OSPF metric plus the External Metric. For -- external Type 2 (non-comparable value) routes, it is the -- external metric. -- ipCidrRouteMetric2 is, by definition, a secondary routing -- metric. Therefore, it should be the metric that breaks a tie -- among routes having equal metric1 values and the same -- calculation rule. For intra-area, inter-area routes, and -- External Type 1 (comparable value) routes, it is unused. For -- External Type 2 (non-comparable value) routes, it is the metric -- to the AS border router. -- ipCidrRouteMetric3, ipCidrRouteMetric4, and ipCidrRouteMetric5 -- are unused. -- The OSPF Area Aggregate Table -- -- This table replaces the OSPF Area Summary Table, being an -- extension of that for CIDR routers. ospfAreaAggregateTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfAreaAggregateEntry MAX-ACCESS not-accessible STATUS current Galecki, et al. Standards Track PAGE 66

RFC 4750 OSPFv2 MIB December 2006 DESCRIPTION "The Area Aggregate Table acts as an adjunct to the Area Table. It describes those address aggregates that are configured to be propagated from an area. Its purpose is to reduce the amount of information that is known beyond an Area's borders. It contains a set of IP address ranges specified by an IP address/IP network mask pair. For example, a class B address range of X.X.X.X with a network mask of 255.255.0.0 includes all IP addresses from X.X.0.0 to X.X.255.255. Note that if ranges are configured such that one range subsumes another range (e.g., 10.0.0.0 mask 255.0.0.0 and 10.1.0.0 mask 255.255.0.0), the most specific match is the preferred one." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospf 14 } ospfAreaAggregateEntry OBJECT-TYPE SYNTAX OspfAreaAggregateEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A single area aggregate entry. Information in this table is persistent and when this object is written the entity SHOULD save the change to non-volatile storage." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" INDEX { ospfAreaAggregateAreaID, ospfAreaAggregateLsdbType, ospfAreaAggregateNet, ospfAreaAggregateMask } ::= { ospfAreaAggregateTable 1 } OspfAreaAggregateEntry ::= SEQUENCE { ospfAreaAggregateAreaID AreaID, ospfAreaAggregateLsdbType INTEGER, ospfAreaAggregateNet IpAddress, ospfAreaAggregateMask IpAddress, ospfAreaAggregateStatus Galecki, et al. Standards Track PAGE 67

RFC 4750 OSPFv2 MIB December 2006 RowStatus, ospfAreaAggregateEffect INTEGER, ospfAreaAggregateExtRouteTag Unsigned32 } ospfAreaAggregateAreaID OBJECT-TYPE SYNTAX AreaID MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The area within which the address aggregate is to be found." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospfAreaAggregateEntry 1 } ospfAreaAggregateLsdbType OBJECT-TYPE SYNTAX INTEGER { summaryLink (3), nssaExternalLink (7) } MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The type of the address aggregate. This field specifies the Lsdb type that this address aggregate applies to." REFERENCE "OSPF Version 2, Appendix A.4.1 The Link State Advertisement header" ::= { ospfAreaAggregateEntry 2 } ospfAreaAggregateNet OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The IP address of the net or subnet indicated by the range." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospfAreaAggregateEntry 3 } Galecki, et al. Standards Track PAGE 68

RFC 4750 OSPFv2 MIB December 2006 ospfAreaAggregateMask OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only -- read-only since originally an -- SMIv1 index STATUS current DESCRIPTION "The subnet mask that pertains to the net or subnet." REFERENCE "OSPF Version 2, Appendix C.2 Area parameters" ::= { ospfAreaAggregateEntry 4 } ospfAreaAggregateStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object permits management of the table by facilitating actions such as row creation, construction, and destruction. The value of this object has no effect on whether other objects in this conceptual row can be modified." ::= { ospfAreaAggregateEntry 5 } ospfAreaAggregateEffect OBJECT-TYPE SYNTAX INTEGER { advertiseMatching (1), doNotAdvertiseMatching (2) } MAX-ACCESS read-create STATUS current DESCRIPTION "Subnets subsumed by ranges either trigger the advertisement of the indicated aggregate (advertiseMatching) or result in the subnet's not being advertised at all outside the area." DEFVAL { advertiseMatching } ::= { ospfAreaAggregateEntry 6 } ospfAreaAggregateExtRouteTag OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-create STATUS current DESCRIPTION "External route tag to be included in NSSA (type-7) LSAs." Galecki, et al. Standards Track PAGE 69

RFC 4750 OSPFv2 MIB December 2006 DEFVAL { 0 } ::= { ospfAreaAggregateEntry 7 } -- OSPF Link State Database, link-local for non-virtual links ospfLocalLsdbTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfLocalLsdbEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The OSPF Process's link-local link state database for non-virtual links. This table is identical to the OSPF LSDB Table in format, but contains only link-local Link State Advertisements for non-virtual links. The purpose is to allow link-local LSAs to be displayed for each non-virtual interface. This table is implemented to support type-9 LSAs that are defined in 'The OSPF Opaque LSA Option'." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements and The OSPF Opaque LSA Option" ::= { ospf 17 } ospfLocalLsdbEntry OBJECT-TYPE SYNTAX OspfLocalLsdbEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A single link state advertisement." INDEX { ospfLocalLsdbIpAddress, ospfLocalLsdbAddressLessIf, ospfLocalLsdbType, ospfLocalLsdbLsid, ospfLocalLsdbRouterId } ::= { ospfLocalLsdbTable 1 } OspfLocalLsdbEntry ::= SEQUENCE { ospfLocalLsdbIpAddress IpAddress, ospfLocalLsdbAddressLessIf InterfaceIndexOrZero, ospfLocalLsdbType INTEGER, ospfLocalLsdbLsid IpAddress, ospfLocalLsdbRouterId RouterID, Galecki, et al. Standards Track PAGE 70

RFC 4750 OSPFv2 MIB December 2006 ospfLocalLsdbSequence Integer32, ospfLocalLsdbAge Integer32, ospfLocalLsdbChecksum Integer32, ospfLocalLsdbAdvertisement OCTET STRING } ospfLocalLsdbIpAddress OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS not-accessible STATUS current DESCRIPTION "The IP address of the interface from which the LSA was received if the interface is numbered." REFERENCE "OSPF Version 2, Appendix C.3 Interface parameters" ::= { ospfLocalLsdbEntry 1 } ospfLocalLsdbAddressLessIf OBJECT-TYPE SYNTAX InterfaceIndexOrZero MAX-ACCESS not-accessible STATUS current DESCRIPTION "The interface index of the interface from which the LSA was received if the interface is unnumbered." REFERENCE "OSPF Version 2, Appendix C.3 Interface parameters" ::= { ospfLocalLsdbEntry 2 } ospfLocalLsdbType OBJECT-TYPE SYNTAX INTEGER { localOpaqueLink (9) } MAX-ACCESS not-accessible STATUS current DESCRIPTION "The type of the link state advertisement. Each link state type has a separate advertisement format." REFERENCE "OSPF Version 2, Appendix A.4.1 The Link State Advertisement header" ::= { ospfLocalLsdbEntry 3 } ospfLocalLsdbLsid OBJECT-TYPE Galecki, et al. Standards Track PAGE 71

RFC 4750 OSPFv2 MIB December 2006 SYNTAX IpAddress MAX-ACCESS not-accessible STATUS current DESCRIPTION "The Link State ID is an LS Type Specific field containing a 32-bit identifier in IP address format; it identifies the piece of the routing domain that is being described by the advertisement." REFERENCE "OSPF Version 2, Section 12.1.4 Link State ID" ::= { ospfLocalLsdbEntry 4 } ospfLocalLsdbRouterId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS not-accessible STATUS current DESCRIPTION "The 32-bit number that uniquely identifies the originating router in the Autonomous System." REFERENCE "OSPF Version 2, Appendix C.1 Global parameters" ::= { ospfLocalLsdbEntry 5 } ospfLocalLsdbSequence OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "The sequence number field is a signed 32-bit integer. It starts with the value '80000001'h, or -'7FFFFFFF'h, and increments until '7FFFFFFF'h. Thus, a typical sequence number will be very negative. It is used to detect old and duplicate link state advertisements. The space of sequence numbers is linearly ordered. The larger the sequence number, the more recent the advertisement." REFERENCE "OSPF Version 2, Section 12.1.6 LS sequence number" ::= { ospfLocalLsdbEntry 6 } ospfLocalLsdbAge OBJECT-TYPE SYNTAX Integer32 -- Should be 0..MaxAge, except when -- doNotAge bit is set UNITS "seconds" MAX-ACCESS read-only STATUS current DESCRIPTION Galecki, et al. Standards Track PAGE 72

RFC 4750 OSPFv2 MIB December 2006 "This field is the age of the link state advertisement in seconds." REFERENCE "OSPF Version 2, Section 12.1.1 LS age" ::= { ospfLocalLsdbEntry 7 } ospfLocalLsdbChecksum OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "This field is the checksum of the complete contents of the advertisement, excepting the age field. The age field is excepted so that an advertisement's age can be incremented without updating the checksum. The checksum used is the same that is used for ISO connectionless datagrams; it is commonly referred to as the Fletcher checksum." REFERENCE "OSPF Version 2, Section 12.1.7 LS checksum" ::= { ospfLocalLsdbEntry 8 } ospfLocalLsdbAdvertisement OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1..65535)) MAX-ACCESS read-only STATUS current DESCRIPTION "The entire link state advertisement, including its header. Note that for variable length LSAs, SNMP agents may not be able to return the largest string size." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements" ::= { ospfLocalLsdbEntry 9 } -- OSPF Link State Database, link-local for virtual Links ospfVirtLocalLsdbTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfVirtLocalLsdbEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The OSPF Process's link-local link state database for virtual links. Galecki, et al. Standards Track PAGE 73

RFC 4750 OSPFv2 MIB December 2006 This table is identical to the OSPF LSDB Table in format, but contains only link-local Link State Advertisements for virtual links. The purpose is to allow link-local LSAs to be displayed for each virtual interface. This table is implemented to support type-9 LSAs that are defined in 'The OSPF Opaque LSA Option'." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements and The OSPF Opaque LSA Option" ::= { ospf 18 } ospfVirtLocalLsdbEntry OBJECT-TYPE SYNTAX OspfVirtLocalLsdbEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A single link state advertisement." INDEX { ospfVirtLocalLsdbTransitArea, ospfVirtLocalLsdbNeighbor, ospfVirtLocalLsdbType, ospfVirtLocalLsdbLsid, ospfVirtLocalLsdbRouterId } ::= { ospfVirtLocalLsdbTable 1 } OspfVirtLocalLsdbEntry ::= SEQUENCE { ospfVirtLocalLsdbTransitArea AreaID, ospfVirtLocalLsdbNeighbor RouterID, ospfVirtLocalLsdbType INTEGER, ospfVirtLocalLsdbLsid IpAddress, ospfVirtLocalLsdbRouterId RouterID, ospfVirtLocalLsdbSequence Integer32, ospfVirtLocalLsdbAge Integer32, ospfVirtLocalLsdbChecksum Integer32, ospfVirtLocalLsdbAdvertisement OCTET STRING } ospfVirtLocalLsdbTransitArea OBJECT-TYPE Galecki, et al. Standards Track PAGE 74

RFC 4750 OSPFv2 MIB December 2006 SYNTAX AreaID MAX-ACCESS not-accessible STATUS current DESCRIPTION "The transit area that the virtual link traverses. By definition, this is not 0.0.0.0." REFERENCE "OSPF Version 2, Appendix C.3 Interface parameters" ::= { ospfVirtLocalLsdbEntry 1 } ospfVirtLocalLsdbNeighbor OBJECT-TYPE SYNTAX RouterID MAX-ACCESS not-accessible STATUS current DESCRIPTION "The Router ID of the virtual neighbor." REFERENCE "OSPF Version 2, Appendix C.3 Interface parameters" ::= { ospfVirtLocalLsdbEntry 2 } ospfVirtLocalLsdbType OBJECT-TYPE SYNTAX INTEGER { localOpaqueLink (9) } MAX-ACCESS not-accessible STATUS current DESCRIPTION "The type of the link state advertisement. Each link state type has a separate advertisement format." REFERENCE "OSPF Version 2, Appendix A.4.1 The Link State Advertisement header" ::= { ospfVirtLocalLsdbEntry 3 } ospfVirtLocalLsdbLsid OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS not-accessible STATUS current DESCRIPTION "The Link State ID is an LS Type Specific field containing a 32-bit identifier in IP address format; it identifies the piece of the routing domain that is being described by the advertisement." REFERENCE "OSPF Version 2, Section 12.1.4 Link State ID" ::= { ospfVirtLocalLsdbEntry 4 } ospfVirtLocalLsdbRouterId OBJECT-TYPE SYNTAX RouterID Galecki, et al. Standards Track PAGE 75

RFC 4750 OSPFv2 MIB December 2006 MAX-ACCESS not-accessible STATUS current DESCRIPTION "The 32-bit number that uniquely identifies the originating router in the Autonomous System." REFERENCE "OSPF Version 2, Appendix C.1 Global parameters" ::= { ospfVirtLocalLsdbEntry 5 } ospfVirtLocalLsdbSequence OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "The sequence number field is a signed 32-bit integer. It starts with the value '80000001'h, or -'7FFFFFFF'h, and increments until '7FFFFFFF'h. Thus, a typical sequence number will be very negative. It is used to detect old and duplicate link state advertisements. The space of sequence numbers is linearly ordered. The larger the sequence number, the more recent the advertisement." REFERENCE "OSPF Version 2, Section 12.1.6 LS sequence number" ::= { ospfVirtLocalLsdbEntry 6 } ospfVirtLocalLsdbAge OBJECT-TYPE SYNTAX Integer32 -- Should be 0..MaxAge, except when -- doNotAge bit is set UNITS "seconds" MAX-ACCESS read-only STATUS current DESCRIPTION "This field is the age of the link state advertisement in seconds." REFERENCE "OSPF Version 2, Section 12.1.1 LS age" ::= { ospfVirtLocalLsdbEntry 7 } ospfVirtLocalLsdbChecksum OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "This field is the checksum of the complete contents of the advertisement, excepting the age field. The age field is excepted so that Galecki, et al. Standards Track PAGE 76

RFC 4750 OSPFv2 MIB December 2006 an advertisement's age can be incremented without updating the checksum. The checksum used is the same that is used for ISO connectionless datagrams; it is commonly referred to as the Fletcher checksum." REFERENCE "OSPF Version 2, Section 12.1.7 LS checksum" ::= { ospfVirtLocalLsdbEntry 8 } ospfVirtLocalLsdbAdvertisement OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1..65535)) MAX-ACCESS read-only STATUS current DESCRIPTION "The entire link state advertisement, including its header." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements. Note that for variable length LSAs, SNMP agents may not be able to return the largest string size." ::= { ospfVirtLocalLsdbEntry 9 } -- OSPF Link State Database, AS-scope ospfAsLsdbTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfAsLsdbEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The OSPF Process's AS-scope LSA link state database. The database contains the AS-scope Link State Advertisements from throughout the areas that the device is attached to. This table is identical to the OSPF LSDB Table in format, but contains only AS-scope Link State Advertisements. The purpose is to allow AS-scope LSAs to be displayed once for the router rather than once in each non-stub area." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements" ::= { ospf 19 } ospfAsLsdbEntry OBJECT-TYPE SYNTAX OspfAsLsdbEntry Galecki, et al. Standards Track PAGE 77

RFC 4750 OSPFv2 MIB December 2006 MAX-ACCESS not-accessible STATUS current DESCRIPTION "A single link state advertisement." INDEX { ospfAsLsdbType, ospfAsLsdbLsid, ospfAsLsdbRouterId } ::= { ospfAsLsdbTable 1 } OspfAsLsdbEntry ::= SEQUENCE { ospfAsLsdbType INTEGER, ospfAsLsdbLsid IpAddress, ospfAsLsdbRouterId RouterID, ospfAsLsdbSequence Integer32, ospfAsLsdbAge Integer32, ospfAsLsdbChecksum Integer32, ospfAsLsdbAdvertisement OCTET STRING } ospfAsLsdbType OBJECT-TYPE SYNTAX INTEGER { asExternalLink (5), asOpaqueLink (11) } MAX-ACCESS not-accessible STATUS current DESCRIPTION "The type of the link state advertisement. Each link state type has a separate advertisement format." REFERENCE "OSPF Version 2, Appendix A.4.1 The Link State Advertisement header" ::= { ospfAsLsdbEntry 1 } ospfAsLsdbLsid OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS not-accessible STATUS current DESCRIPTION "The Link State ID is an LS Type Specific field containing either a Router ID or an IP address; Galecki, et al. Standards Track PAGE 78

RFC 4750 OSPFv2 MIB December 2006 it identifies the piece of the routing domain that is being described by the advertisement." REFERENCE "OSPF Version 2, Section 12.1.4 Link State ID" ::= { ospfAsLsdbEntry 2 } ospfAsLsdbRouterId OBJECT-TYPE SYNTAX RouterID MAX-ACCESS not-accessible STATUS current DESCRIPTION "The 32-bit number that uniquely identifies the originating router in the Autonomous System." REFERENCE "OSPF Version 2, Appendix C.1 Global parameters" ::= { ospfAsLsdbEntry 3 } ospfAsLsdbSequence OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "The sequence number field is a signed 32-bit integer. It starts with the value '80000001'h, or -'7FFFFFFF'h, and increments until '7FFFFFFF'h. Thus, a typical sequence number will be very negative. It is used to detect old and duplicate link state advertisements. The space of sequence numbers is linearly ordered. The larger the sequence number, the more recent the advertisement." REFERENCE "OSPF Version 2, Section 12.1.6 LS sequence number" ::= { ospfAsLsdbEntry 4 } ospfAsLsdbAge OBJECT-TYPE SYNTAX Integer32 -- Should be 0..MaxAge, except when -- doNotAge bit is set UNITS "seconds" MAX-ACCESS read-only STATUS current DESCRIPTION "This field is the age of the link state advertisement in seconds." REFERENCE "OSPF Version 2, Section 12.1.1 LS age" ::= { ospfAsLsdbEntry 5 } Galecki, et al. Standards Track PAGE 79

RFC 4750 OSPFv2 MIB December 2006 ospfAsLsdbChecksum OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "This field is the checksum of the complete contents of the advertisement, excepting the age field. The age field is excepted so that an advertisement's age can be incremented without updating the checksum. The checksum used is the same that is used for ISO connectionless datagrams; it is commonly referred to as the Fletcher checksum." REFERENCE "OSPF Version 2, Section 12.1.7 LS checksum" ::= { ospfAsLsdbEntry 6 } ospfAsLsdbAdvertisement OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1..65535)) MAX-ACCESS read-only STATUS current DESCRIPTION "The entire link state advertisement, including its header." REFERENCE "OSPF Version 2, Section 12 Link State Advertisements. Note that for variable length LSAs, SNMP agents may not be able to return the largest string size." ::= { ospfAsLsdbEntry 7 } -- OSPF Area LSA Counter Table ospfAreaLsaCountTable OBJECT-TYPE SYNTAX SEQUENCE OF OspfAreaLsaCountEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table maintains per-area, per-LSA-type counters" ::= { ospf 20 } ospfAreaLsaCountEntry OBJECT-TYPE SYNTAX OspfAreaLsaCountEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry with a number of link advertisements Galecki, et al. Standards Track PAGE 80

RFC 4750 OSPFv2 MIB December 2006 of a given type for a given area." INDEX { ospfAreaLsaCountAreaId, ospfAreaLsaCountLsaType } ::= { ospfAreaLsaCountTable 1 } OspfAreaLsaCountEntry ::= SEQUENCE { ospfAreaLsaCountAreaId AreaID, ospfAreaLsaCountLsaType INTEGER, ospfAreaLsaCountNumber Gauge32 } ospfAreaLsaCountAreaId OBJECT-TYPE SYNTAX AreaID MAX-ACCESS not-accessible STATUS current DESCRIPTION "This entry Area ID." ::= { ospfAreaLsaCountEntry 1 } ospfAreaLsaCountLsaType OBJECT-TYPE SYNTAX INTEGER { routerLink (1), networkLink (2), summaryLink (3), asSummaryLink (4), multicastLink (6), nssaExternalLink (7), areaOpaqueLink (10) } MAX-ACCESS not-accessible STATUS current DESCRIPTION "This entry LSA type." ::= { ospfAreaLsaCountEntry 2 } ospfAreaLsaCountNumber OBJECT-TYPE SYNTAX Gauge32 MAX-ACCESS read-only STATUS current DESCRIPTION "Number of LSAs of a given type for a given area." ::= { ospfAreaLsaCountEntry 3 } -- conformance information Galecki, et al. Standards Track PAGE 81

RFC 4750 OSPFv2 MIB December 2006 ospfConformance OBJECT IDENTIFIER ::= { ospf 15 } ospfGroups OBJECT IDENTIFIER ::= { ospfConformance 1 } ospfCompliances OBJECT IDENTIFIER ::= { ospfConformance 2 } -- compliance statements ospfCompliance MODULE-COMPLIANCE STATUS deprecated DESCRIPTION "The compliance statement for OSPF systems conforming to RFC 1850." MODULE -- this module MANDATORY-GROUPS { ospfBasicGroup, ospfAreaGroup, ospfStubAreaGroup, ospfIfGroup, ospfIfMetricGroup, ospfVirtIfGroup, ospfNbrGroup, ospfVirtNbrGroup, ospfAreaAggregateGroup } GROUP ospfHostGroup DESCRIPTION "This group is mandatory for OSPF systems that support attached hosts." GROUP ospfLsdbGroup DESCRIPTION "This group is mandatory for OSPF systems that display their per-area link state database." GROUP ospfExtLsdbGroup DESCRIPTION "This group is mandatory for OSPF systems that display their external link state database." ::= { ospfCompliances 1 } ospfCompliance2 MODULE-COMPLIANCE STATUS current DESCRIPTION "The compliance statement." MODULE -- this module MANDATORY-GROUPS { ospfBasicGroup2, ospfAreaGroup2, ospfStubAreaGroup, ospfIfGroup2, Galecki, et al. Standards Track PAGE 82

RFC 4750 OSPFv2 MIB December 2006 ospfIfMetricGroup, ospfVirtIfGroup2, ospfNbrGroup2, ospfVirtNbrGroup2, ospfAreaAggregateGroup2 } GROUP ospfHostGroup2 DESCRIPTION "This group is mandatory for OSPF systems that support attached hosts." GROUP ospfLsdbGroup DESCRIPTION "This group is mandatory for OSPF systems that display their per-area link state database." GROUP ospfAsLsdbGroup DESCRIPTION "This group is mandatory for OSPF systems that display their AS-scope link state database." GROUP ospfLocalLsdbGroup DESCRIPTION "This group is mandatory for OSPF systems that display their per-link link state database for non-virtual links." GROUP ospfVirtLocalLsdbGroup DESCRIPTION "This group is mandatory for OSPF systems that display their per-link link state database for virtual links." GROUP ospfAreaLsaCountGroup DESCRIPTION "This group is mandatory for OSPF systems that display per-area, per-LSA-type counters." ::= { ospfCompliances 2 } ospfComplianceObsolete MODULE-COMPLIANCE STATUS obsolete DESCRIPTION "Contains obsolete object groups." MODULE -- this module GROUP ospfAreaRangeGroup DESCRIPTION "This group is obsolete, and it is mandatory only for non-Classless Inter-Domain Routing (CIDR) OSPF systems that support multiple areas." GROUP ospfObsoleteGroup DESCRIPTION "This group contains obsolete objects, which are no longer required for OSPF systems." ::= { ospfCompliances 3 } Galecki, et al. Standards Track PAGE 83

RFC 4750 OSPFv2 MIB December 2006 -- units of conformance ospfBasicGroup OBJECT-GROUP OBJECTS { ospfRouterId, ospfAdminStat, ospfVersionNumber, ospfAreaBdrRtrStatus, ospfASBdrRtrStatus, ospfExternLsaCount, ospfExternLsaCksumSum, ospfTOSSupport, ospfOriginateNewLsas, ospfRxNewLsas, ospfExtLsdbLimit, ospfMulticastExtensions, ospfExitOverflowInterval, ospfDemandExtensions } STATUS deprecated DESCRIPTION "These objects are used to monitor/manage global OSPF parameters. This object group conforms to RFC 1850." ::= { ospfGroups 1 } ospfAreaGroup OBJECT-GROUP OBJECTS { ospfAreaId, ospfImportAsExtern, ospfSpfRuns, ospfAreaBdrRtrCount, ospfAsBdrRtrCount, ospfAreaLsaCount, ospfAreaLsaCksumSum, ospfAreaSummary, ospfAreaStatus } STATUS deprecated DESCRIPTION "These objects are used for OSPF systems supporting areas per RFC 1850." ::= { ospfGroups 2 } ospfStubAreaGroup OBJECT-GROUP OBJECTS { ospfStubAreaId, ospfStubTOS, Galecki, et al. Standards Track PAGE 84

RFC 4750 OSPFv2 MIB December 2006 ospfStubMetric, ospfStubStatus, ospfStubMetricType } STATUS current DESCRIPTION "These objects are used for OSPF systems supporting stub areas." ::= { ospfGroups 3 } ospfLsdbGroup OBJECT-GROUP OBJECTS { ospfLsdbAreaId, ospfLsdbType, ospfLsdbLsid, ospfLsdbRouterId, ospfLsdbSequence, ospfLsdbAge, ospfLsdbChecksum, ospfLsdbAdvertisement } STATUS current DESCRIPTION "These objects are used for OSPF systems that display their link state database." ::= { ospfGroups 4 } ospfAreaRangeGroup OBJECT-GROUP OBJECTS { ospfAreaRangeAreaId, ospfAreaRangeNet, ospfAreaRangeMask, ospfAreaRangeStatus, ospfAreaRangeEffect } STATUS obsolete DESCRIPTION "These objects are used for non-CIDR OSPF systems that support multiple areas. This object group is obsolete." ::= { ospfGroups 5 } ospfHostGroup OBJECT-GROUP OBJECTS { ospfHostIpAddress, ospfHostTOS, ospfHostMetric, ospfHostStatus, Galecki, et al. Standards Track PAGE 85

RFC 4750 OSPFv2 MIB December 2006 ospfHostAreaID } STATUS deprecated DESCRIPTION "These objects are used for OSPF systems that support attached hosts." ::= { ospfGroups 6 } ospfIfGroup OBJECT-GROUP OBJECTS { ospfIfIpAddress, ospfAddressLessIf, ospfIfAreaId, ospfIfType, ospfIfAdminStat, ospfIfRtrPriority, ospfIfTransitDelay, ospfIfRetransInterval, ospfIfHelloInterval, ospfIfRtrDeadInterval, ospfIfPollInterval, ospfIfState, ospfIfDesignatedRouter, ospfIfBackupDesignatedRouter, ospfIfEvents, ospfIfAuthType, ospfIfAuthKey, ospfIfStatus, ospfIfMulticastForwarding, ospfIfDemand } STATUS deprecated DESCRIPTION "These objects are used to monitor/manage OSPF interfaces. This object group conforms to RFC 1850." ::= { ospfGroups 7 } ospfIfMetricGroup OBJECT-GROUP OBJECTS { ospfIfMetricIpAddress, ospfIfMetricAddressLessIf, ospfIfMetricTOS, ospfIfMetricValue, ospfIfMetricStatus } STATUS current DESCRIPTION "These objects are used for OSPF systems for supporting Galecki, et al. Standards Track PAGE 86

RFC 4750 OSPFv2 MIB December 2006 interface metrics." ::= { ospfGroups 8 } ospfVirtIfGroup OBJECT-GROUP OBJECTS { ospfVirtIfAreaId, ospfVirtIfNeighbor, ospfVirtIfTransitDelay, ospfVirtIfRetransInterval, ospfVirtIfHelloInterval, ospfVirtIfRtrDeadInterval, ospfVirtIfState, ospfVirtIfEvents, ospfVirtIfAuthType, ospfVirtIfAuthKey, ospfVirtIfStatus } STATUS deprecated DESCRIPTION "These objects are used for OSPF systems for supporting virtual interfaces. This object group conforms to RFC 1850." ::= { ospfGroups 9 } ospfNbrGroup OBJECT-GROUP OBJECTS { ospfNbrIpAddr, ospfNbrAddressLessIndex, ospfNbrRtrId, ospfNbrOptions, ospfNbrPriority, ospfNbrState, ospfNbrEvents, ospfNbrLsRetransQLen, ospfNbmaNbrStatus, ospfNbmaNbrPermanence, ospfNbrHelloSuppressed } STATUS deprecated DESCRIPTION "These objects are used to monitor/manage OSPF neighbors. This object group conforms to RFC 1850." ::= { ospfGroups 10 } ospfVirtNbrGroup OBJECT-GROUP OBJECTS { ospfVirtNbrArea, ospfVirtNbrRtrId, Galecki, et al. Standards Track PAGE 87

RFC 4750 OSPFv2 MIB December 2006 ospfVirtNbrIpAddr, ospfVirtNbrOptions, ospfVirtNbrState, ospfVirtNbrEvents, ospfVirtNbrLsRetransQLen, ospfVirtNbrHelloSuppressed } STATUS deprecated DESCRIPTION "These objects are used to monitor/manage OSPF virtual neighbors. This object group conforms to RFC 1850." ::= { ospfGroups 11 } ospfExtLsdbGroup OBJECT-GROUP OBJECTS { ospfExtLsdbType, ospfExtLsdbLsid, ospfExtLsdbRouterId, ospfExtLsdbSequence, ospfExtLsdbAge, ospfExtLsdbChecksum, ospfExtLsdbAdvertisement } STATUS deprecated DESCRIPTION "These objects are used for OSPF systems that display their link state database. This object group conforms to RFC 1850. This object group is replaced by the ospfAsLsdbGroup in order to support any AS-scope LSA type in a single table." ::= { ospfGroups 12 } ospfAreaAggregateGroup OBJECT-GROUP OBJECTS { ospfAreaAggregateAreaID, ospfAreaAggregateLsdbType, ospfAreaAggregateNet, ospfAreaAggregateMask, ospfAreaAggregateStatus, ospfAreaAggregateEffect } STATUS deprecated DESCRIPTION "These objects are used for OSPF systems to support network prefix aggregation across areas." Galecki, et al. Standards Track PAGE 88

RFC 4750 OSPFv2 MIB December 2006 ::= { ospfGroups 13 } ospfLocalLsdbGroup OBJECT-GROUP OBJECTS { ospfLocalLsdbSequence, ospfLocalLsdbAge, ospfLocalLsdbChecksum, ospfLocalLsdbAdvertisement } STATUS current DESCRIPTION "These objects are used for OSPF systems that display their link-local link state databases for non-virtual links." ::= { ospfGroups 14 } ospfVirtLocalLsdbGroup OBJECT-GROUP OBJECTS { ospfVirtLocalLsdbSequence, ospfVirtLocalLsdbAge, ospfVirtLocalLsdbChecksum, ospfVirtLocalLsdbAdvertisement } STATUS current DESCRIPTION "These objects are used for OSPF systems that display their link-local link state databases for virtual links." ::= { ospfGroups 15 } ospfAsLsdbGroup OBJECT-GROUP OBJECTS { ospfAsLsdbSequence, ospfAsLsdbAge, ospfAsLsdbChecksum, ospfAsLsdbAdvertisement } STATUS current DESCRIPTION "These objects are used for OSPF systems that display their AS-scope link state database." ::= { ospfGroups 16 } ospfBasicGroup2 OBJECT-GROUP OBJECTS { ospfRouterId, ospfAdminStat, ospfVersionNumber, Galecki, et al. Standards Track PAGE 89

RFC 4750 OSPFv2 MIB December 2006 ospfAreaBdrRtrStatus, ospfASBdrRtrStatus, ospfExternLsaCount, ospfExternLsaCksumSum, ospfTOSSupport, ospfOriginateNewLsas, ospfRxNewLsas, ospfExtLsdbLimit, ospfMulticastExtensions, ospfExitOverflowInterval, ospfDemandExtensions, ospfRFC1583Compatibility, ospfOpaqueLsaSupport, ospfReferenceBandwidth, ospfRestartSupport, ospfRestartInterval, ospfRestartStrictLsaChecking, ospfRestartStatus, ospfRestartAge, ospfRestartExitReason, ospfAsLsaCount, ospfAsLsaCksumSum, ospfStubRouterSupport, ospfStubRouterAdvertisement, ospfDiscontinuityTime } STATUS current DESCRIPTION "These objects are used to monitor/manage OSPF global parameters." ::= { ospfGroups 17 } ospfAreaGroup2 OBJECT-GROUP OBJECTS { ospfAreaId, ospfImportAsExtern, ospfSpfRuns, ospfAreaBdrRtrCount, ospfAsBdrRtrCount, ospfAreaLsaCount, ospfAreaLsaCksumSum, ospfAreaSummary, ospfAreaStatus, ospfAreaNssaTranslatorRole, ospfAreaNssaTranslatorState, ospfAreaNssaTranslatorStabilityInterval, ospfAreaNssaTranslatorEvents } Galecki, et al. Standards Track PAGE 90

RFC 4750 OSPFv2 MIB December 2006 STATUS current DESCRIPTION "These objects are used by OSPF systems to support areas." ::= { ospfGroups 18 } ospfIfGroup2 OBJECT-GROUP OBJECTS { ospfIfIpAddress, ospfAddressLessIf, ospfIfAreaId, ospfIfType, ospfIfAdminStat, ospfIfRtrPriority, ospfIfTransitDelay, ospfIfRetransInterval, ospfIfHelloInterval, ospfIfRtrDeadInterval, ospfIfPollInterval, ospfIfState, ospfIfDesignatedRouter, ospfIfBackupDesignatedRouter, ospfIfEvents, ospfIfAuthType, ospfIfAuthKey, ospfIfStatus, ospfIfMulticastForwarding, ospfIfDemand, ospfIfLsaCount, ospfIfLsaCksumSum } STATUS current DESCRIPTION "These objects are used to monitor/manage OSPF interfaces." ::= { ospfGroups 19 } ospfVirtIfGroup2 OBJECT-GROUP OBJECTS { ospfVirtIfAreaId, ospfVirtIfNeighbor, ospfVirtIfTransitDelay, ospfVirtIfRetransInterval, ospfVirtIfHelloInterval, ospfVirtIfRtrDeadInterval, ospfVirtIfState, ospfVirtIfEvents, ospfVirtIfAuthType, ospfVirtIfAuthKey, Galecki, et al. Standards Track PAGE 91

RFC 4750 OSPFv2 MIB December 2006 ospfVirtIfStatus, ospfVirtIfLsaCount, ospfVirtIfLsaCksumSum, ospfIfDesignatedRouterId, ospfIfBackupDesignatedRouterId } STATUS current DESCRIPTION "These objects are used to monitor/manage OSPF virtual interfaces." ::= { ospfGroups 20 } ospfNbrGroup2 OBJECT-GROUP OBJECTS { ospfNbrIpAddr, ospfNbrAddressLessIndex, ospfNbrRtrId, ospfNbrOptions, ospfNbrPriority, ospfNbrState, ospfNbrEvents, ospfNbrLsRetransQLen, ospfNbmaNbrStatus, ospfNbmaNbrPermanence, ospfNbrHelloSuppressed, ospfNbrRestartHelperStatus, ospfNbrRestartHelperAge, ospfNbrRestartHelperExitReason } STATUS current DESCRIPTION "These objects are used to monitor/manage OSPF neighbors." ::= { ospfGroups 21 } ospfVirtNbrGroup2 OBJECT-GROUP OBJECTS { ospfVirtNbrArea, ospfVirtNbrRtrId, ospfVirtNbrIpAddr, ospfVirtNbrOptions, ospfVirtNbrState, ospfVirtNbrEvents, ospfVirtNbrLsRetransQLen, ospfVirtNbrHelloSuppressed, ospfVirtNbrRestartHelperStatus, ospfVirtNbrRestartHelperAge, ospfVirtNbrRestartHelperExitReason Galecki, et al. Standards Track PAGE 92

RFC 4750 OSPFv2 MIB December 2006 } STATUS current DESCRIPTION "These objects are used to monitor/manage OSPF virtual neighbors." ::= { ospfGroups 22 } ospfAreaAggregateGroup2 OBJECT-GROUP OBJECTS { ospfAreaAggregateAreaID, ospfAreaAggregateLsdbType, ospfAreaAggregateNet, ospfAreaAggregateMask, ospfAreaAggregateStatus, ospfAreaAggregateEffect, ospfAreaAggregateExtRouteTag } STATUS current DESCRIPTION "These objects are used for OSPF systems to support network prefix aggregation across areas." ::= { ospfGroups 23 } ospfAreaLsaCountGroup OBJECT-GROUP OBJECTS { ospfAreaLsaCountNumber } STATUS current DESCRIPTION "These objects are used for OSPF systems that display per-area, per-LSA-type counters." ::= { ospfGroups 24 } ospfHostGroup2 OBJECT-GROUP OBJECTS { ospfHostIpAddress, ospfHostTOS, ospfHostMetric, ospfHostStatus, ospfHostCfgAreaID } STATUS current DESCRIPTION "These objects are used for OSPF systems that support attached hosts." ::= { ospfGroups 25 } -- This object group is included for SMI conformance. It is not a Galecki, et al. Standards Track PAGE 93

RFC 4750 OSPFv2 MIB December 2006 -- mandatory group for compliance with this MIB ospfObsoleteGroup OBJECT-GROUP OBJECTS { ospfAuthType } STATUS obsolete DESCRIPTION "These objects are obsolete and are no longer required for OSPF systems. They are placed into this group for SMI conformance." ::= { ospfGroups 26 } END 4. OSPF Trap Overview 4.1. Introduction OSPF is an event-driven routing protocol, where an event can be a change in an OSPF interface's link-level status, the expiration of an OSPF timer, or the reception of an OSPF protocol packet. Many of the actions that OSPF takes as a result of these events will result in a change of the routing topology. As routing topologies become large and complex, it is often difficult to locate the source of a topology change or unpredicted routing path by polling a large number or routers. Because of the difficulty of polling a large number of devices, a more prudent approach is for devices to notify a network manager of potentially critical OSPF events using SNMP traps. This section defines a set of traps, objects, and mechanisms to enhance the ability to manage IP internetworks that use OSPF as their Interior Gateway Protocol (IGP). It is an optional but very useful extension to the OSPF MIB. Galecki, et al. Standards Track PAGE 94

RFC 4750 OSPFv2 MIB December 2006 4.2. Approach The mechanism for sending traps is straightforward. When an exception event occurs, the application notifies the local agent, who sends a trap to the appropriate SNMP management stations. The message includes the trap type and may include a list of trap- specific variables. Section 5 gives the trap definitions, which includes the variable lists. The Router ID of the originator of the trap is included in the variable list so that the network manager may easily determine the source of the trap. To limit the frequency of OSPF traps, the following additional mechanisms are suggested. 4.3. Ignoring Initial Activity The majority of critical events occur when OSPF is enabled on a router, at which time the designated router is elected and neighbor adjacencies are formed. During this initial period, a potential flood of traps is unnecessary since the events are expected. To avoid unnecessary traps, a router should not originate expected OSPF interface-related traps until two of that interface's dead timer intervals have elapsed. The expected OSPF interface traps are ospfIfStateChange, ospfVirtIfStateChange, ospfNbrStateChange, ospfVirtNbrStateChange, ospfTxRetransmit, and ospfVirtIfTxRetransmit. Additionally, ospfMaxAgeLsa and ospfOriginateLsa traps should not be originated until two dead timer intervals have elapsed where the dead timer interval used should be the dead timer with the smallest value. 4.4. Throttling Traps The mechanism for throttling the traps is similar to the mechanism explained in RFC 1224 [RFC 1224]. The basic premise of the throttling mechanism is that of a sliding window, defined in seconds and an upper bound on the number of traps that may be generated within this window. Note that unlike RFC 1224, traps are not sent to inform the network manager that the throttling mechanism has kicked in. A single window should be used to throttle all OSPF trap types except for the ospfLsdbOverflow and the ospfLsdbApproachingOverflow traps, which should not be throttled. For example, with a window time of 3, an upper bound of 3, and events to cause trap types 1, 3, 5, and 7 (4 traps within a 3-second period), the type-7 (the 4th) trap should not be generated. Appropriate values are 7 traps with a window time of 10 seconds. Galecki, et al. Standards Track PAGE 95

RFC 4750 OSPFv2 MIB December 2006 4.5. One Trap Per OSPF Event Several of the traps defined in section 5 are generated as the result of finding an unusual condition while parsing an OSPF packet or a processing a timer event. There may be more than one unusual condition detected while handling the event. For example, a link state update packet may contain several retransmitted link state advertisements (LSAs), or a retransmitted database description packet may contain several database description entries. To limit the number of traps and variables, OSPF should generate at most one trap per OSPF event. Only the variables associated with the first unusual condition should be included with the trap. Similarly, if more than one type of unusual condition is encountered while parsing the packet, only the first event will generate a trap. 4.6. Polling Event Counters Many of the tables in the OSPF MIB contain generalized event counters. By enabling the traps defined in this document, a network manager can obtain more specific information about these events. A network manager may want to poll these event counters and enable specific OSPF traps when a particular counter starts increasing abnormally. The following table shows the relationship between the event counters defined in the OSPF MIB and the trap types. Counter32 Trap Type ----------------------- ------------------------ ospfOriginateNewLsas ospfOriginateLsa ospfIfEvents ospfIfStateChange ospfConfigError ospfIfAuthFailure ospfRxBadPacket ospfTxRetransmit ospfVirtIfEvents ospfVirtIfStateChange ospfVirtIfConfigError ospfVirtIfAuthFailure ospfVirtIfRxBadPacket ospfVirtIfTxRetransmit ospfNbrEvents ospfNbrStateChange ospfVirtNbrEvents ospfVirtNbrStateChange ospfExternLSACount ospfLsdbApproachingOverflow ospfExternLSACount ospfLsdbOverflow Galecki, et al. Standards Track PAGE 96

RFC 4750 OSPFv2 MIB December 2006 4.7. Translating Notification Parameters The definition of the OSPF notifications pre-dates the RFC 2578 [RFC 2578] requirement of having a zero value for the penultimate sub-identifier for translating SNMPv2/SNMPv3 trap parameters to SNMPv1 trap parameters. RFC 3584 [RFC 3584], section 3, defines the translation rules that can be implemented by intermediate proxy- agents or multi-lingual agents to convert SNMPv2/SNMPv3 notifications to SNMPv1 notifications and vice versa. The conversion is not reversible, that is, a conversion to one SNMP version and then back again will result in an incorrectly formatted version of the notification. According to the rules specified in RFC 3584, section 3.1, translation of OSPF notifications from SNMPv1 to SNMPv2/SNMPv3 would result in the SNMPv2/SNMPv3 snmpTrapOID being the concatenation of the SNMPv1 'enterprise' parameter and two additional sub-identifiers, '0' and the SNMPv1 'specific-trap' parameter. According to the rules specified in RFC 3584, section 3.2, translation of OSPF notifications from SNMPv2/SNMPv3 to SNMPv1, as the notifications are defined in this MIB, would result in the SNMPv1 'enterprise' parameter being set to the SNMPv2/SNMPv3 snmpTrapOID parameter value with the last sub-identifier removed and the 'specific-trap' parameter being set to the last sub-identifier of the SNMPv2/SNMPv3 snmpTrapOID parameter. Note that a notification originated from an SNMPv1 agent will not be converted into the same notification that would be originated from a native SNMPv2/SNMPv3 agent. 4.8. Historical Artifacts The MIB modules that are updated by this document were originally written in SMIv1 for SNMPv1 when only traps were used. Since this version of the MIB module is written in SMIv2, it should be understood that all types of notifications, trap and inform PDUs, may be used by native SNMPv2 and SNMPv3 agents, although only traps are mentioned. Also, for backwards compatibility, the OSPF Trap module remains rooted at {ospf 16}. Galecki, et al. Standards Track PAGE 97

RFC 4750 OSPFv2 MIB December 2006 5. OSPF Trap Definitions OSPF-TRAP-MIB DEFINITIONS ::= BEGIN IMPORTS MODULE-IDENTITY, OBJECT-TYPE, NOTIFICATION-TYPE, IpAddress FROM SNMPv2-SMI MODULE-COMPLIANCE, OBJECT-GROUP, NOTIFICATION-GROUP FROM SNMPv2-CONF ospfRouterId, ospfIfIpAddress, ospfAddressLessIf, ospfIfState, ospfVirtIfAreaId, ospfVirtIfNeighbor, ospfVirtIfState, ospfNbrIpAddr, ospfNbrAddressLessIndex, ospfNbrRtrId, ospfNbrState, ospfVirtNbrArea, ospfVirtNbrRtrId, ospfVirtNbrState, ospfLsdbType, ospfLsdbLsid, ospfLsdbRouterId, ospfLsdbAreaId, ospfExtLsdbLimit, ospf, ospfAreaId, ospfAreaNssaTranslatorState, ospfRestartStatus, ospfRestartInterval, ospfRestartExitReason, ospfNbrRestartHelperStatus, ospfNbrRestartHelperAge, ospfNbrRestartHelperExitReason, ospfVirtNbrRestartHelperStatus, ospfVirtNbrRestartHelperAge, ospfVirtNbrRestartHelperExitReason FROM OSPF-MIB; ospfTrap MODULE-IDENTITY LAST-UPDATED "200611100000Z" -- November 10, 2006 00:00:00 EST ORGANIZATION "IETF OSPF Working Group" CONTACT-INFO "WG E-Mail: ospf@ietf.org WG Chairs: acee@cisco.com rohit@gmail.com Editors: Dan Joyal Nortel 600 Technology Park Drive Billerica, MA 01821 djoyal@nortel.com Piotr Galecki Airvana 19 Alpha Road Chelmsford, MA 01824 pgalecki@airvana.com Spencer Giacalone CSFB Eleven Madison Ave New York, NY 10010-3629 Galecki, et al. Standards Track PAGE 98

RFC 4750 OSPFv2 MIB December 2006 spencer.giacalone@gmail.com" DESCRIPTION "The MIB module to describe traps for the OSPF Version 2 Protocol. Copyright © The IETF Trust (2006). This version of this MIB module is part of RFC 4750; see the RFC itself for full legal notices." REVISION "200611100000Z" -- November 10, 2006 00:00:00 EST DESCRIPTION "Updated for latest changes to OSPFv2: -added graceful restart related traps -added new config error types -added ospfNssaTranslatorStatusChange trap. See Appendix B of RFC 4750 for more details. This version published as part of RFC 4750" REVISION "199501201225Z" -- Fri Jan 20 12:25:50 PST 1995 DESCRIPTION "The initial SMIv2 revision of this MIB module, published in RFC 1850." ::= { ospf 16 } -- Trap Support Objects -- The following are support objects for the OSPF traps. ospfTrapControl OBJECT IDENTIFIER ::= { ospfTrap 1 } ospfTraps OBJECT IDENTIFIER ::= { ospfTrap 2 } ospfSetTrap OBJECT-TYPE SYNTAX OCTET STRING (SIZE(4)) MAX-ACCESS read-write STATUS current DESCRIPTION "A 4-octet string serving as a bit map for the trap events defined by the OSPF traps. This object is used to enable and disable specific OSPF traps where a 1 in the bit field represents enabled. The right-most bit (least significant) represents trap 0. This object is persistent and when written Galecki, et al. Standards Track PAGE 99

RFC 4750 OSPFv2 MIB December 2006 the entity SHOULD save the change to non-volatile storage." ::= { ospfTrapControl 1 } ospfConfigErrorType OBJECT-TYPE SYNTAX INTEGER { badVersion (1), areaMismatch (2), unknownNbmaNbr (3), -- Router is DR eligible unknownVirtualNbr (4), authTypeMismatch(5), authFailure (6), netMaskMismatch (7), helloIntervalMismatch (8), deadIntervalMismatch (9), optionMismatch (10), mtuMismatch (11), duplicateRouterId (12), noError (13) } MAX-ACCESS read-only STATUS current DESCRIPTION "Potential types of configuration conflicts. Used by the ospfConfigError and ospfConfigVirtError traps. When the last value of a trap using this object is needed, but no traps of that type have been sent, this value pertaining to this object should be returned as noError." ::= { ospfTrapControl 2 } ospfPacketType OBJECT-TYPE SYNTAX INTEGER { hello (1), dbDescript (2), lsReq (3), lsUpdate (4), lsAck (5), nullPacket (6) } MAX-ACCESS read-only STATUS current DESCRIPTION "OSPF packet types. When the last value of a trap using this object is needed, but no traps of that type have been sent, this value pertaining to this object should be returned as nullPacket." ::= { ospfTrapControl 3 } Galecki, et al. Standards Track PAGE 100

RFC 4750 OSPFv2 MIB December 2006 ospfPacketSrc OBJECT-TYPE SYNTAX IpAddress MAX-ACCESS read-only STATUS current DESCRIPTION "The IP address of an inbound packet that cannot be identified by a neighbor instance. When the last value of a trap using this object is needed, but no traps of that type have been sent, this value pertaining to this object should be returned as 0.0.0.0." ::= { ospfTrapControl 4 } -- Traps ospfVirtIfStateChange NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfVirtIfAreaId, ospfVirtIfNeighbor, ospfVirtIfState -- The new state } STATUS current DESCRIPTION "An ospfVirtIfStateChange trap signifies that there has been a change in the state of an OSPF virtual interface. This trap should be generated when the interface state regresses (e.g., goes from Point-to-Point to Down) or progresses to a terminal state (i.e., Point-to-Point)." ::= { ospfTraps 1 } ospfNbrStateChange NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfNbrIpAddr, ospfNbrAddressLessIndex, ospfNbrRtrId, ospfNbrState -- The new state } STATUS current DESCRIPTION "An ospfNbrStateChange trap signifies that there has been a change in the state of a non-virtual OSPF neighbor. This trap should be generated when the neighbor state regresses (e.g., goes from Attempt or Full to 1-Way or Down) or progresses to a terminal state (e.g., Galecki, et al. Standards Track PAGE 101

RFC 4750 OSPFv2 MIB December 2006 2-Way or Full). When an neighbor transitions from or to Full on non-broadcast multi-access and broadcast networks, the trap should be generated by the designated router. A designated router transitioning to Down will be noted by ospfIfStateChange." ::= { ospfTraps 2 } ospfVirtNbrStateChange NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfVirtNbrArea, ospfVirtNbrRtrId, ospfVirtNbrState -- The new state } STATUS current DESCRIPTION "An ospfVirtNbrStateChange trap signifies that there has been a change in the state of an OSPF virtual neighbor. This trap should be generated when the neighbor state regresses (e.g., goes from Attempt or Full to 1-Way or Down) or progresses to a terminal state (e.g., Full)." ::= { ospfTraps 3 } ospfIfConfigError NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfIfIpAddress, ospfAddressLessIf, ospfPacketSrc, -- The source IP address ospfConfigErrorType, -- Type of error ospfPacketType } STATUS current DESCRIPTION "An ospfIfConfigError trap signifies that a packet has been received on a non-virtual interface from a router whose configuration parameters conflict with this router's configuration parameters. Note that the event optionMismatch should cause a trap only if it prevents an adjacency from forming." ::= { ospfTraps 4 } ospfVirtIfConfigError NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfVirtIfAreaId, ospfVirtIfNeighbor, ospfConfigErrorType, -- Type of error Galecki, et al. Standards Track PAGE 102

RFC 4750 OSPFv2 MIB December 2006 ospfPacketType } STATUS current DESCRIPTION "An ospfVirtIfConfigError trap signifies that a packet has been received on a virtual interface from a router whose configuration parameters conflict with this router's configuration parameters. Note that the event optionMismatch should cause a trap only if it prevents an adjacency from forming." ::= { ospfTraps 5 } ospfIfAuthFailure NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfIfIpAddress, ospfAddressLessIf, ospfPacketSrc, -- The source IP address ospfConfigErrorType, -- authTypeMismatch or -- authFailure ospfPacketType } STATUS current DESCRIPTION "An ospfIfAuthFailure trap signifies that a packet has been received on a non-virtual interface from a router whose authentication key or authentication type conflicts with this router's authentication key or authentication type." ::= { ospfTraps 6 } ospfVirtIfAuthFailure NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfVirtIfAreaId, ospfVirtIfNeighbor, ospfConfigErrorType, -- authTypeMismatch or -- authFailure ospfPacketType } STATUS current DESCRIPTION "An ospfVirtIfAuthFailure trap signifies that a packet has been received on a virtual interface from a router whose authentication key or authentication type conflicts with this router's authentication key or authentication type." Galecki, et al. Standards Track PAGE 103

RFC 4750 OSPFv2 MIB December 2006 ::= { ospfTraps 7 } ospfIfRxBadPacket NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfIfIpAddress, ospfAddressLessIf, ospfPacketSrc, -- The source IP address ospfPacketType } STATUS current DESCRIPTION "An ospfIfRxBadPacket trap signifies that an OSPF packet has been received on a non-virtual interface that cannot be parsed." ::= { ospfTraps 8 } ospfVirtIfRxBadPacket NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfVirtIfAreaId, ospfVirtIfNeighbor, ospfPacketType } STATUS current DESCRIPTION "An ospfVirtIfRxBadPacket trap signifies that an OSPF packet has been received on a virtual interface that cannot be parsed." ::= { ospfTraps 9 } ospfTxRetransmit NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfIfIpAddress, ospfAddressLessIf, ospfNbrRtrId, -- Destination ospfPacketType, ospfLsdbType, ospfLsdbLsid, ospfLsdbRouterId } STATUS current DESCRIPTION "An ospfTxRetransmit trap signifies than an OSPF packet has been retransmitted on a non-virtual interface. All packets that may be retransmitted are associated with an LSDB entry. The LS type, LS ID, and Router ID are used to identify the LSDB entry." ::= { ospfTraps 10 } Galecki, et al. Standards Track PAGE 104

RFC 4750 OSPFv2 MIB December 2006 ospfVirtIfTxRetransmit NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfVirtIfAreaId, ospfVirtIfNeighbor, ospfPacketType, ospfLsdbType, ospfLsdbLsid, ospfLsdbRouterId } STATUS current DESCRIPTION "An ospfVirtIfTxRetransmit trap signifies than an OSPF packet has been retransmitted on a virtual interface. All packets that may be retransmitted are associated with an LSDB entry. The LS type, LS ID, and Router ID are used to identify the LSDB entry." ::= { ospfTraps 11 } ospfOriginateLsa NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfLsdbAreaId, -- 0.0.0.0 for AS Externals ospfLsdbType, ospfLsdbLsid, ospfLsdbRouterId } STATUS current DESCRIPTION "An ospfOriginateLsa trap signifies that a new LSA has been originated by this router. This trap should not be invoked for simple refreshes of LSAs (which happens every 30 minutes), but instead will only be invoked when an LSA is (re)originated due to a topology change. Additionally, this trap does not include LSAs that are being flushed because they have reached MaxAge." ::= { ospfTraps 12 } ospfMaxAgeLsa NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfLsdbAreaId, -- 0.0.0.0 for AS Externals ospfLsdbType, ospfLsdbLsid, ospfLsdbRouterId } STATUS current DESCRIPTION Galecki, et al. Standards Track PAGE 105

RFC 4750 OSPFv2 MIB December 2006 "An ospfMaxAgeLsa trap signifies that one of the LSAs in the router's link state database has aged to MaxAge." ::= { ospfTraps 13 } ospfLsdbOverflow NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfExtLsdbLimit } STATUS current DESCRIPTION "An ospfLsdbOverflow trap signifies that the number of LSAs in the router's link state database has exceeded ospfExtLsdbLimit." ::= { ospfTraps 14 } ospfLsdbApproachingOverflow NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfExtLsdbLimit } STATUS current DESCRIPTION "An ospfLsdbApproachingOverflow trap signifies that the number of LSAs in the router's link state database has exceeded ninety percent of ospfExtLsdbLimit." ::= { ospfTraps 15 } ospfIfStateChange NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfIfIpAddress, ospfAddressLessIf, ospfIfState -- The new state } STATUS current DESCRIPTION "An ospfIfStateChange trap signifies that there has been a change in the state of a non-virtual OSPF interface. This trap should be generated when the interface state regresses (e.g., goes from Dr to Down) or progresses to a terminal state (i.e., Point-to-Point, DR Other, Dr, or Backup)." ::= { ospfTraps 16 } ospfNssaTranslatorStatusChange NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap Galecki, et al. Standards Track PAGE 106

RFC 4750 OSPFv2 MIB December 2006 ospfAreaId, ospfAreaNssaTranslatorState -- The current translation -- status } STATUS current DESCRIPTION "An ospfNssaTranslatorStatusChange trap indicates that there has been a change in the router's ability to translate OSPF type-7 LSAs into OSPF type-5 LSAs. This trap should be generated when the translator status transitions from or to any defined status on a per-area basis." ::= { ospfTraps 17 } ospfRestartStatusChange NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfRestartStatus, ospfRestartInterval, ospfRestartExitReason } STATUS current DESCRIPTION "An ospfRestartStatusChange trap signifies that there has been a change in the graceful restart state for the router. This trap should be generated when the router restart status changes." ::= { ospfTraps 18 } ospfNbrRestartHelperStatusChange NOTIFICATION-TYPE OBJECTS { ospfRouterId, -- The originator of the trap ospfNbrIpAddr, ospfNbrAddressLessIndex, ospfNbrRtrId, ospfNbrRestartHelperStatus, ospfNbrRestartHelperAge, ospfNbrRestartHelperExitReason } STATUS current DESCRIPTION "An ospfNbrRestartHelperStatusChange trap signifies that there has been a change in the graceful restart helper state for the neighbor. This trap should be generated when the neighbor restart helper status transitions for a neighbor." ::= { ospfTraps 19 } ospfVirtNbrRestartHelperStatusChange NOTIFICATION-TYPE Galecki, et al. Standards Track PAGE 107

RFC 4750 OSPFv2 MIB December 2006 OBJECTS { ospfRouterId, -- The originator of the trap ospfVirtNbrArea, ospfVirtNbrRtrId, ospfVirtNbrRestartHelperStatus, ospfVirtNbrRestartHelperAge, ospfVirtNbrRestartHelperExitReason } STATUS current DESCRIPTION "An ospfVirtNbrRestartHelperStatusChange trap signifies that there has been a change in the graceful restart helper state for the virtual neighbor. This trap should be generated when the virtual neighbor restart helper status transitions for a virtual neighbor." ::= { ospfTraps 20 } -- conformance information ospfTrapConformance OBJECT IDENTIFIER ::= { ospfTrap 3 } ospfTrapGroups OBJECT IDENTIFIER ::= { ospfTrapConformance 1 } ospfTrapCompliances OBJECT IDENTIFIER ::= { ospfTrapConformance 2 } -- compliance statements ospfTrapCompliance MODULE-COMPLIANCE STATUS obsolete DESCRIPTION "The compliance statement." MODULE -- this module MANDATORY-GROUPS { ospfTrapControlGroup } GROUP ospfTrapControlGroup DESCRIPTION "This group is optional but recommended for all OSPF systems." ::= { ospfTrapCompliances 1 } ospfTrapCompliance2 MODULE-COMPLIANCE STATUS current DESCRIPTION "The compliance statement." MODULE -- this module MANDATORY-GROUPS { ospfTrapControlGroup, ospfTrapEventGroup } OBJECT ospfConfigErrorType MIN-ACCESS accessible-for-notify DESCRIPTION "This object is only required to be supplied within notifications." Galecki, et al. Standards Track PAGE 108

RFC 4750 OSPFv2 MIB December 2006 OBJECT ospfPacketType MIN-ACCESS accessible-for-notify DESCRIPTION "This object is only required to be supplied within notifications." OBJECT ospfPacketSrc MIN-ACCESS accessible-for-notify DESCRIPTION "This object is only required to be supplied within notifications." ::= { ospfTrapCompliances 2 } -- units of conformance ospfTrapControlGroup OBJECT-GROUP OBJECTS { ospfSetTrap, ospfConfigErrorType, ospfPacketType, ospfPacketSrc } STATUS current DESCRIPTION "These objects are required to control traps from OSPF systems." ::= { ospfTrapGroups 1 } ospfTrapEventGroup NOTIFICATION-GROUP NOTIFICATIONS { ospfVirtIfStateChange, ospfNbrStateChange, ospfVirtNbrStateChange, ospfIfConfigError, ospfVirtIfConfigError, ospfIfAuthFailure, ospfVirtIfAuthFailure, ospfIfRxBadPacket, ospfVirtIfRxBadPacket, ospfTxRetransmit, ospfVirtIfTxRetransmit, ospfOriginateLsa, ospfMaxAgeLsa, ospfLsdbOverflow, ospfLsdbApproachingOverflow, ospfIfStateChange, ospfNssaTranslatorStatusChange, ospfRestartStatusChange, ospfNbrRestartHelperStatusChange, ospfVirtNbrRestartHelperStatusChange } Galecki, et al. Standards Track PAGE 109

RFC 4750 OSPFv2 MIB December 2006 STATUS current DESCRIPTION "A grouping of OSPF trap events, as specified in NOTIFICATION-TYPE constructs." ::= { ospfTrapGroups 2 } END 6. Security Considerations There are a number of management objects defined in this MIB that have a MAX-ACCESS clause of read-write and/or read-create. Such objects may be considered sensitive or vulnerable in some network environments. The support for SET operations in a non-secure environment without proper protection can have a negative effect on network operations. It is recommended that attention be specifically given to implementing the MAX-ACCESS clause in a number of objects, including ospfIfAuthKey, ospfIfAuthType, ospfVirtIfAuthKey, and ospfVirtIfAuthType in scenarios that DO NOT use SNMPv3 strong security (i.e., authentication and encryption). Extreme caution must be used to minimize the risk of cascading security vulnerabilities when SNMPv3 strong security is not used. When SNMPv3 strong security is not used, these objects should have access of read-only, not read-create. SNMPv1 by itself is not a secure environment. Even if the network itself is secure (for example by using IPsec), even then, there is no control as to who on the secure network is allowed to access and GET/SET (read/change/create/delete) the objects in this MIB. It is recommended that the implementers consider the security features as provided by the SNMPv3 framework. Specifically, the use of the User-based Security Model RFC 3414 [RFC 3414] and the View- based Access Control Model RFC 3415 [RFC 3415] is recommended. It is then a customer/user responsibility to ensure that the SNMP entity giving access to an instance of this MIB, is properly configured to give access to the objects only to those principals (users) that have legitimate rights to indeed GET or SET (change/create/delete) them. Galecki, et al. Standards Track PAGE 110

RFC 4750 OSPFv2 MIB December 2006 7. IANA Considerations The MIB module in this document uses the following IANA-assigned OBJECT IDENTIFIER values recorded in the SMI Numbers registry: Descriptor OBJECT IDENTIFIER value ---------- ----------------------- ospf { mib-2 14 } 8. Acknowledgements This document was produced by the OSPF Working Group and is based on the MIB for OSPF version 2 by Rob Coltun and Fred Baker [RFC 1850]. The editors would like to acknowledge John Moy, Rob Coltun, Randall Atkinson, David T. Perkins, Ken Chapman, Brian Field, Acee Lindem, Vishwas Manral, Roy Jose, Don Goodspeed, Vivek Dubey, Keith McCloghrie, Bill Fenner, and Dan Romascanu for their constructive comments. 9. References 9.1. Normative References [RFC 2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC 2578] McCloghrie, K., Perkins, D., and J. Schoenwaelder, "Structure of Management Information Version 2 (SMIv2)", STD 58, RFC 2578, April 1999. [RFC 2579] McCloghrie, K., Perkins, D., and J. Schoenwaelder, "Textual Conventions for SMIv2", STD 58, RFC 2579, April 1999. [RFC 2580] McCloghrie, K., Perkins, D., and J. Schoenwaelder, "Conformance Statements for SMIv2", STD 58, RFC 2580, April 1999. 9.2 Informative References [RFC 1224] Steinberg, L., "Techniques for managing asynchronously generated alerts", RFC 1224, May 1991. [RFC 1704] Haller, N. and R. Atkinson, "On Internet Authentication", RFC 1704, October 1994. [RFC 1765] Moy, J., "OSPF Database Overflow", RFC 1765, March 1995. Galecki, et al. Standards Track PAGE 111

RFC 4750 OSPFv2 MIB December 2006 [RFC 1793] Moy, J., "Extending OSPF to Support Demand Circuits", RFC 1793, April 1995. [RFC 1850] Baker, F. and R. Coltun, "OSPF Version 2 Management Information Base", RFC 1850, November 1995. [RFC 2328] Moy, J., "OSPF Version 2", STD 54, RFC 2328, April 1998. [RFC 2370] Coltun, R., "The OSPF Opaque LSA Option", RFC 2370, July 1998. [RFC 3101] Murphy, P., "The OSPF Not-So-Stubby Area (NSSA) Option", RFC 3101, January 2003. [RFC 3410] Case, J., Mundy, R., Partain, D., and B. Stewart, "Introduction and Applicability Statements for Internet- Standard Management Framework", RFC 3410, December 2002. [RFC 3414] Blumenthal, U. and B. Wijnen, "User-based Security Model (USM) for version 3 of the Simple Network Management Protocol (SNMPv3)", STD 62, RFC 3414, December 2002. [RFC 3415] Wijnen, B., Presuhn, R., and K. McCloghrie, "View-based Access Control Model (VACM) for the Simple Network Management Protocol (SNMP)", STD 62, RFC 3415, December 2002. [RFC 3584] Frye, R., Levi, D., Routhier, S., and B. Wijnen, "Coexistence between Version 1, Version 2, and Version 3 of the Internet-standard Network Management Framework", BCP 74, RFC 3584, August 2003. [RFC 3623] Moy, J., Pillay-Esnault, P., and A. Lindem, "Graceful OSPF Restart", RFC 3623, November 2003. [RFC 791] Postel, J., "Internet Protocol", STD 5, RFC 791, September 1981. [RFC 3411] Harrington, D., Presuhn, R., and B. Wijnen, "An Architecture for Describing Simple Network Management Protocol (SNMP) Management Frameworks", STD 62, RFC 3411, December 2002. [RFC 1583] Moy, J., "OSPF Version 2", RFC 1583, March 1994. Galecki, et al. Standards Track PAGE 112

RFC 4750 OSPFv2 MIB December 2006 Appendix A. TOS Support For backward compatibility with previous versions of the OSPF MIB specification, TOS-specific information has been retained in this document, though the TOS routing option has been deleted from OSPF [RFC 2328]. Appendix B. Changes from RFC 1850 This section documents the differences between this memo and RFC 1850. Appendix B.1. General Group Changes Added object ospfRFC1583Compatibility to indicate support with "RFC 1583 Compatibility" [RFC 1583]. This object has DEFVAL of "enabled". Added object ospfReferenceBandwidth to allow configuration of a reference bandwidth for calculation of default interface metrics. Added objects ospfRestartSupport, ospfRestartInterval, ospfRestartAge, ospfRestartStrictLsaChecking, and ospfRestartExitReason to support graceful restart. Added objects ospfStubRouterSupport and ospfStubRouteAdvertisement to support stub routers. Added object ospfDiscontinuityTime in order for a management entity to detect counter discontinuity events. Appendix B.2. OSPF NSSA Enhancement Support Added new objects to OspfAreaTable including the following: -ospfAreaNssaTranslatorRole to indicate the configured NSSA translation role. -ospfAreaNssaTranslatorState to indicate the current NSSA translation role. -ospfAreaNssaTranslatorStabilityInterval to indicate time to continue to perform at current translation status. -ospfAreaNssaTranslatorEvents to indicate the number of times OSPF translation state has changed. Added new object ospfAreaAggregateExtRouteTag to ospfAreaAggregateTable. Galecki, et al. Standards Track PAGE 113

RFC 4750 OSPFv2 MIB December 2006 Added new object ospfNssaTranslatorStatusChange to ospfTraps in OSPF-TRAP-MIB DEFINITIONS. Added ospfAreaId to IMPORTS in OSPF-TRAP-MIB DEFINITIONS to support ospfNssaTranslatorStatusChange. Added ospfAreaExtNssaTranslatorStatus to IMPORTS in OSPF-TRAP-MIB DEFINITIONS to support ospfNssaTranslatorStatusChange. Modified the DESCRIPTION clause of the ospfAreaSummary object in the ospfAreaTable to indicate support for NSSA. Modified the DESCRIPTION clause of the ospfImportAsExtern object in the ospfAreaTable for clarity. Appendix B.3. Opaque LSA Support Added object ospfOpaqueLsaSupport to ospfGeneralGroup to indicate support of OSPF Opaque LSAs. Created ospfLocalLsdbTable, for link-local (type-9) LSA support. This table is indexed by the following: -ospflocalLsdbIpAddress -ospfLocalLsdbAddressLessIf -ospfLocalLsdbType -ospfLocalLsdbLsid -ospfLocalLsdbRouterId ospfLocalLsdbTable contains the following (columnar) objects: -ospfLocalLsdbSequence, to indicate LSA instance -ospfLocalLsdbAge -ospfLocalLsdbChecksum -ospfLocalLsdbAdvertisement, containing the entire LSA Created ospfVirLocalLsdbTable, for link-local (type-9) LSA support on virtual links. This table is indexed by the following: -ospfVirtLocalLsdbTransitArea Galecki, et al. Standards Track PAGE 114

RFC 4750 OSPFv2 MIB December 2006 -ospfVirtLocalLsdbNeighbor, to indicate the router ID of the virtual neighbor -ospfVirLocalLsdbType -ospfVirLocalLsdbLsid -ospfVirLocalLsdbRouterId ospfVirLocalLsdbTable contains the following (columnar) objects: -ospfVirLocalLsdbSequence, to indicate LSA instance -ospfVirLocalLsdbAge -ospfVirLocalLsdbChecksum -ospfVirLocalLsdbAdvertisement, containing the entire LSA Added objects to ospfIfTable to support link-local (type-9) LSAs, including the following: -ospfIfLsaCount -ospfIfLsaCksumSum, to indicate the sum of the type-9 link state advertisement checksums on this interface Added objects to ospfVirIfTable, to support link-local (type-9) LSAs on virtual links, including the following: -ospfVirIfLsaCount -ospfVirIfLsaCksumSum, to indicate the sum of the type-9 link state advertisement checksums on this link To support area scope (type-10) LSAs, the enumeration areaOpaqueLink (10) was added to ospfLsdbType in the ospfLsdbTable. Created ospfAsLsdbTable, for AS-scope LSA support. This table is indexed by the following: -ospfAsLsdbType -ospfAsLsdbLsid -ospfAsLsdbRouterId ospfAsLsdbTable contains the following (columnar) objects: Galecki, et al. Standards Track PAGE 115

RFC 4750 OSPFv2 MIB December 2006 -ospfAsLsdbSequence, to indicate LSA instance -ospfAsLsdbAge -ospfAsLsdbChecksum -ospfAsLsdbAdvertisement, containing the entire LSA Appendix B.4. Graceful Restart Support Added objects ospfRestartSupport, ospfRestartInterval, ospfRestartAge, ospfRestartStrictLsaChecking, and ospfRestartExitReason to general group. Added objects ospfNbrRestartHelperStatus, ospfNbrRestartHelperAge, and ospfNbrRestartHelperExitReason to OspfNbrTable. Added objects ospfVirtNbrRestartHelperStatus, ospfVirtNbrRestartHelperAge, and ospfVirtNbrRestartHelperExitReason to OspfVirtNbrTable. Appendix B.5. OSPF Compliances New compliance statements were added for new and for obsoleted conformance groups. These statements include the following: -ospfCompliance2 -ospfComplianceObsolete New conformance groups were created to support new objects added to the group. These groups include the following: -ospfBasicGroup2 -ospfAreaGroup2 -ospfIfGroup2 -ospfVirtIfGroup2 -ospfNbrGroup2 -ospfVirtNbrGroup2 -ospfAreaAggregateGroup2 Added completely new conformance groups, including the following: Galecki, et al. Standards Track PAGE 116

RFC 4750 OSPFv2 MIB December 2006 -ospfLocalLsdbGroup, which specifies support for link-local (type-9) LSAs -ospfVirtLocalLsdbGroup, which specifies support for link-local (type-9) LSAs on virtual links -ospfObsoleteGroup, for obsolete objects and SMI compatibility Appendix B.6. OSPF Authentication and Security As there has been significant concern in the community regarding cascading security vulnerabilities, the following changes have been incorporated: -Modified the DESCRIPTION clause of ospfIfAuthKey due to security concerns and to increase clarity -Modified the DESCRIPTION clause of ospfVirtIfAuthKey due to security concerns and to increase clarity -Modified the DESCRIPTION clause of ospfIfAuthType due to security concerns and to increase clarity -Modified the DESCRIPTION clause of ospfVirtIfType due to security concerns and to increase clarity -Modified the OSPF MIB MODULE DESCRIPTION due to security concerns and to include a reference to the Security Considerations section in this document that will transcend compilation -Modified the Security Considerations section to provide detail Appendix B.7. OSPF Trap MIB Added ospfTrapEventGroup. Added importation of NOTIFICATION-GROUP. Changed the STATUS of the ospfTrapCompliance MODULE-COMPLIANCE construct to obsolete. Added ospfTrapCompliance2 MODULE-COMPLIANCE construct, which replaces ospfTrapCompliance. OspfTrapCompliance includes an updated MANDATORY-GROUPS clause and new MIN-ACCESS specifications. Added mtuMismatch enumeration to ospfConfigErrorType object in ospfTrapControl to imply MTU mismatch trap generation. in ospfIfConfigError. Galecki, et al. Standards Track PAGE 117

RFC 4750 OSPFv2 MIB December 2006 Added noError enumeration to ospfConfigErrorType object for situations when traps are requested but none have been sent. Updated the DESCRIPTION clause accordingly. Added nullPacket enumeration to ospfPacketType object for situations when traps are requested but none have been sent. Updated the DESCRIPTION clause accordingly. Updated the DESCRIPTION clause of ospfPacketSrc for situations when traps are requested, but none have been sent. Added NOTIFICATION-TYPE for ospfRestartStatusChange. Added NOTIFICATION-TYPE for ospfNbrRestartHelperStatusChange. Added NOTIFICATION-TYPE for ospfVirtNbrRestartHelperStatusChange. Appendix B.8. Miscellaneous Various sections have been moved or modified for clarity. Most of these changes are semantic in nature and include, but are not limited to the following: -The OSPF overview section's format was revised. Unneeded information was removed. Removed information includes OSPF TOS default values. -The trap overview section's format and working were revised. Unneeded information was removed. -Modified the DESCRIPTION clause of "Status" "TEXTUAL-CONVENTION" for clarity. -The Updates section was moved from the overview to its own section. -Updated "REFERENCE" clauses in all objects, as needed. -Modified the SEQUENCE of the OspfIfTable to reflect the true order of the objects in the table. -Modified the DESCRIPTION clause of all row management objects for clarity. Added ospfHostCfgAreaID to object to Host table with read-create access. Deprecated ospfHostAreaID. Galecki, et al. Standards Track PAGE 118

RFC 4750 OSPFv2 MIB December 2006 Added importation of InterfaceIndexOrZero from IF-MIB. This TEXTUAL-CONVENTION will replace the InterfaceIndex TEXTUAL- CONVENTION. Changed the SYNTAX clause of ospfNbrAddressLessIndex to use the semantically identical InterfaceIndexOrZero TEXTUAL-CONVENTION, as permitted by the SMI. Changed the STATUS clause of the TEXTUAL-CONVENTION InterfaceIndex to obsolete and modified the DESCRIPTION accordingly. Changed the SYNTAX clause of ospfAddressLessIf to use the semantically identical InterfaceIndexOrZero TEXTUAL-CONVENTION, as permitted by the SMI. Changed the SYNTAX clause of ospfIfMetricAddressLessIf to use the semantically identical InterfaceIndexOrZero TEXTUAL-CONVENTION, as permitted by the SMI. Changed importation of mib-2 from RFC 1213-MIB to SNMPv2-SMI Added Intellectual Property Rights section. Updated REVISION DESCRIPTION clauses with description of major MIB modifications. Moved all relevant MIB comments to objects' DESCRIPTION clauses. Added reasoning for object deprecation. Added persistence information for read-write, read-create objects. Described conditions when columns can be modified in RowStatus managed rows as required by RFC 2579. Defined OspfAuthenticationType TC and modified authentication type objects to use the new type. Made index objects of new tables not accessible. Added the UNITS clause to several objects. Added ospfIfDesignatedRouterId and ospfIfBackupDesignatedRouterId to the OspfIfEntry. Added the area LSA counter table. Added IANA Considerations section. Galecki, et al. Standards Track PAGE 119

RFC 4750 OSPFv2 MIB December 2006 Authors' Addresses Dan Joyal (Editor) Nortel, Inc. 600 Technology Park Drive Billerica, MA 01821 USA EMail: djoyal@nortel.com Piotr Galecki (Editor) Airvana, Inc. 19 Alpha Road Chelmsford, MA 01824 USA EMail: pgalecki@airvana.com Spencer Giacalone (Editor) CSFB Eleven Madison Ave New York, NY 10010-3629 USA EMail: spencer.giacalone@gmail.com Fred Baker Cisco Systems 1121 Via Del Rey Santa Barbara, California 93117 USA EMail: fred@cisco.com Rob Coltun Touch Acoustra 3204 Brooklawn Terrace Chevy Chase, MD 20815 USA EMail: undisclosed Galecki, et al. Standards Track PAGE 120

RFC 4750 OSPFv2 MIB December 2006 Full Copyright Statement Copyright © The IETF Trust (2006). This document is subject to the rights, licenses and restrictions contained in BCP 78, and except as set forth therein, the authors retain all their rights. This document and the information contained herein are provided on an "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY, THE IETF TRUST, AND THE INTERNET ENGINEERING TASK FORCE DISCLAIM 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. Intellectual Property The IETF takes no position regarding the validity or scope of any Intellectual Property Rights 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; nor does it represent that it has made any independent effort to identify any such rights. Information on the procedures with respect to rights in RFC documents can be found in BCP 78 and BCP 79. Copies of IPR disclosures made to the IETF Secretariat 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 implementers or users of this specification can be obtained from the IETF on-line IPR repository at http://www.ietf.org/ipr. The IETF invites any interested party to bring to its attention any copyrights, patents or patent applications, or other proprietary rights that may cover technology that may be required to implement this standard. Please address the information to the IETF at ietf-ipr@ietf.org. Acknowledgement Funding for the RFC Editor function is currently provided by the Internet Society. Galecki, et al. Standards Track PAGE 121

OSPF Version 2 Management Information Base RFC TOTAL SIZE: 222459 bytes PUBLICATION DATE: Tuesday, December 12th, 2006 LEGAL RIGHTS: The IETF Trust (see BCP 78)


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