CCAMP Working Group                                     Thomas D. Nadeau
Internet Draft                                       Cisco Systems, Inc.
Expires: May August 2004
                                                       Cheenu Srinivasan
                                                          Bloomberg L.P.

                                                           Adrian Farrel
                                                      Old Dog Consulting

                                                                Tim Hall
                                                             Ed Harrison
                                                    Data Connection Ltd.

                                                           November 2003

                                                           February 2004

      Generalized Multiprotocol Label Switching (GMPLS) Traffic
               Engineering Management Information Base

                draft-ietf-ccamp-gmpls-te-mib-03.txt

                draft-ietf-ccamp-gmpls-te-mib-04.txt

Status of this Memo

   This document is an Internet-Draft and is in full conformance with
   all provisions of Section 10 of RFC2026.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF), its areas, and its working groups.  Note that
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   Drafts.

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   http://www.ietf.org/ietf/1id-abstracts.txt.

   The list of Internet-Draft Shadow Directories can be accessed at
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Abstract

   This memo defines an experimental portion of the Management
   Information Base (MIB) for use with network management protocols in
   the Internet community. In particular, it describes managed objects
   for Generalized Multiprotocol Label Switching (GMPLS) based traffic
   engineering.

Table of Contents

   1. Introduction                                             2
   1.1. Migration Strategy                                     3
   2. Terminology                                              3
   3. The SNMP Management Framework                            3
   4. Outline                                                  4
   4.1. Summary of GMPLS Traffic Engineering MIB Module        4
   5. Brief Description of GMPLS TE MIB Objects                4
   5.1. gmplsTunnelTable                                       4
   5.2. gmplsTunnelHopTable                                    5
   5.3. gmplsTunnelARHopTable                                  5
   5.4. gmplsTunnelCHopTable                                   5
   5.5. gmplsTunnelErrorTable                                  5
   5.6. gmplsTunnelPerfTable gmplsTunnelReversePerfTable                            5
   6. Cross-referencing to the mplsLabelTable                  5
   7. Example of GMPLS Tunnel Setup                            6
   8. GMPLS Traffic Engineering MIB Definitions                8                9
   9. Security Considerations                                 36                                 37
   10. Acknowledgments                                        37                                        38
   11. References                                             37                                             38
   11.1. Normative Refenerces                                 37                                 38
   11.2. Informational References                             39                             40
   12. Authors' Addresses                                     39                                     41
   13. Full Copyright Statement                               40                               41
   14. Intellectual Property Notice                           41
   15. Changes and Pending Work                               41
   15.1. Pending Work                                         41                           42

1. Introduction

   This memo defines a portion of the Management Information Base (MIB)
   for use with network management protocols in the Internet community.
   In particular, it describes managed objects for modeling a
   Generalized Multi-Protocol Multiprotocol Label Switching (GMPLS) [GMPLSArch] based
   traffic engineering. The tables and objects defined in this document
   extend those defined in the equivalent document for MPLS traffic
   engineering [TEMIB], and management of GMPLS traffic engineering is
   built on management of MPLS traffic engineering.

   This MIB module should be used in conjunction with the companion
   document [GMPLSLSRMIB] for GMPLS based traffic engineering
   configuration and management.

   Comments should be made direct to the CCAMP mailing list at
   ccamp@ops.ietf.org.

   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, reference
   [RFC2119].

1.1. Migration Strategy

   This MIB module extends the traffic engineering MIB module defined
   for use with MPLS [TEMIB]. It provides additions for support of GMPLS
   tunnels.

   The companion document for modeling and managing GMPLS based LSRs
   [GMPLSLSRMIB] extends MPLS LSR MIB [LSRMIB] with the same intentions.

   Textual conventions and OBJECT-IDENTIFIERS are defined in [TCMIB] and
   [GMPLSTCMIB].

2. Terminology

   This document uses terminology from the MPLS architecture document
   [RFC3031], from the GMPLS architecture document [GMPLSArch], and from
   the MPLS Label Switch Router Traffic Engineering MIB [LSRMIB]. [TEMIB]. Some frequently used terms
   are described next.

   An explicitly routed LSP (ERLSP) is referred to as a GMPLS tunnel. It
   consists of in-segment(s) and/or out-segment(s) at the egress/ingress
   LSRs, each segment being associated with one GMPLS enabled interface.
   These are also referred to as tunnel segments.

   Additionally, at an intermediate LSR, we model a connection as
   consisting of one or more in-segments and/or one or more out-
   segments. The binding or interconnection between in-segments and out-
   segments in performed using a cross-connect.

   These segment and cross-connect objects are defined in the MPLS Label
   Switch Router MIB [LSRMIB], but see also the GMPLS Label Switch
   Router MIB [GMPLSLSRMIB] for the GMPLS-specific extensions to these
   objects.

3. The SNMP 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 [RFC3410].

   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 [RFC2578], STD 58, RFC 2579 [RFC2579] and STD 58, RFC
   2580 [RFC2580].

4. Outline

   Support for GMPLS traffic-engineered tunnels requires the following
   configuration.

   - Setting up tunnels with appropriate MPLS configuration parameters
     using [TEMIB].
   - Extending the tunnels with GMPLS configuration parameters.
   - Configuring tunnel loose and strict source routed hops.

   These actions may need to be accompanied with corresponding actions
   using [LSRMIB] and [GMPLSLSRMIB] to establish and configure tunnel
   segments, if this is done manually. Also, the in-segment and out-
   segment performance tables, mplsInSegmentPerfTable and
   mplsOutSegmentPerfTable [LSRMIB], should be used to determine
   performance of the tunnels and tunnel segments although it should be
   noted that those tables may not be appropriate for measuring
   performance on some times types of GMPLS links.

4.1. Summary of GMPLS Traffic Engineering MIB Module

   The MIB objects for performing the actions listed above that cannot
   be performed solely using the MIB objects defined in [TEMIB] consist
   of the following tables.

   - Tunnel Table (gmplsTunnelTable) for providing GMPLS-specific
     tunnel configuration parameters.
   - Tunnel specified, actual, and computed hop tables
     (gmplsTunnelHopTable, gmplsTunnelARHopTable, and
     gmplsTunnelCHopTable) for providing additional configuration of
     strict and loose source routed tunnel hops.
   - Performance and error reporting tables (gmplsTunnelPerfTable (gmplsTunnelReversePerfTable
     and gmplsTunnelErrorTable).

   These tables are described in the subsequent sections.

   Additionally, this MIB module contains a new Notification.

   - The GMPLS Tunnel Down Notification (gmplsTunnelDown) is intended to
     be used in place of the mplsTunnelDown Notification defined in
     [TEMIB]. As well as indicating that a tunnel has transitioned to
     operational down state, this new Notificaiton indicates the cause
     of the failure.

5. Brief Description of GMPLS TE MIB Objects

   The objects described in this section support the functionality
   described in [RFC3473] and [RFC3472] for GMPLS tunnels.
   The tables support both manually configured and signaled tunnels.

5.1. gmplsTunnelTable

   The gmplsTunnelTable extends the MPLS traffic engineering MIB to
   allow GMPLS tunnels to be created between an LSR and a remote
   endpoint, and existing GMPLS tunnels to be reconfigured or removed.

   Note that we only support point-to-point tunnel segments, although
   multi-point-to-point and point-to-multi-point connections are
   supported by an LSR acting as a cross-connect.

   Each tunnel can thus have one out-segment originating at an LSR
   and/or one in-segment terminating at that LSR.

5.2. gmplsTunnelHopTable

   The gmplsTunnelHopTable is used to indicate additional parameters for
   the hops, strict or loose, of a GMPLS tunnel defined in
   gmplsTunnelTable, when it is established using signaling.  Multiple
   tunnels may share the same hops by pointing to the same entry in this
   table.

5.3. gmplsTunnelARHopTable

   The gmplsTunnelARHopTable is used to indicate the actual hops
   traversed by a tunnel as reported by the signaling protocol after the
   tunnel is setup.  The support of this table is optional since not all
   GMPLS signaling protocols support this feature.

5.4. gmplsTunnelCHoptable

   The gmplsTunnelCHopTable lists the actual hops computed by a
   constraint-based routing algorithm based on the gmplsTunnelHopTable.
   The support of this table is optional since not all implementations
   support computation of hop list lists using a constraint-based routing
   protocol.

5.5. gmplsTunnelErrorTable

   The gmplsTunnelErrorTable provides access to information about the
   last error that occurred on each tunnel known about by the MIB.  It
   indicates the nature of the error, when and how it was reported and
   can give recovery advice through a display string.

5.6. gmplsTunnelPerfTable

   gmplsTunnelPerfTable gmplsTunnelReversePerfTable

   gmplsTunnelReversePerfTable provides additional counters to measure
   the performance of bidirectional GMPLS tunnels in which packets are
   visible. It supplements the counters in mplsTunnelPerfTable and
   augments gmplsTunnelTable.

   Note that not all counters may be appropriate or available for some
   types of tunnel.

6. Cross-referencing to the mplsLabelTable gmplsLabelTable

   The gmplsLabelTable is found in a MIB module in [GMPLSLSRMIB] and
   provides a way to model labels in a GMPLS system where labels might
   not be simple 32 bit integers.

   The hop tables in this document (gmplsHopTable, gmplsCHopTable and
   gmplsARHopTable) use arbitrary indexes to point to entries in the
   mplsLabelTable to indicate specific label values.

   Since and the primary indexes into gmplsLabelTable are segment tables in the interface
   index [LSRMIB]
   (mplsInSegmentTable and mplsOutSegmentTable) contain objects with
   syntax MplsLabel.

   MplsLabel (defined in [TCMIB]) is a simple 32 bit 32-bit integer (gmplsLabelIndex), in systems where
   the nature that is capable of a
   representing any MPLS label is well-known, and where the label can safely
   be encoded as a most GMPLS labels. However, some
   GMPLS labels are larger than 32 bit integer (for example a conventional MPLS
   system), the gmplsLabelTable does not need to be supported in the
   code implementation bits and the index pointers to the gmplsLabelTable
   (gmplsTunnelHopExplicitLabel, gmplsTunnelHopExpRvrsLabel,
   gmplsTunnelCHopExplicitLabel, gmplsTunnelCHopExpRvrsLabel,
   gmplsTunnelARHopExplicitLabel, gmplsTunnelARHopExpRvrsLabel) may be replaced with the direct label values.

   This provides both a good way to support legacy systems of arbitrary length.
   Further, some labels that
   implement may be safely encoded in 32 bits are
   constructed from multiple sub-fields. Additionally, some GMPLS
   technologies support the previous version concatenation of this MIB [TEMIB], and individual labels to
   represent a significant
   simplification in data flow carried as multiple sub-flows.

   These GMPLS systems cases require that are limited to something other than a single, simple
   label type.

   Note that gmplsLabelTable supports concatenated labels 32-bit
   integer is made available to represent the labels. This is achieved
   through the
   use of a gmplsLabelTable contained in [GMPLSLSRMIB].

   The tables in this document and [LSRMIB] that include objects with
   syntax MplsLabel also include companion objects that are row
   pointers. If the row pointer is set to zeroDotZero (0.0) then object
   of syntax MplsLabel contains the label encoded as a 32-bit integer.
   But otherwise the row pointer indicates a row in another MIB table
   that includes the label. In these cases, the row pointer may indicate
   a row in the gmplsLabelTable.

   This provides both a good way to support legacy systems that
   implement the previous version of this MIB [TEMIB], and a significant
   simplification in GMPLS systems that are limited to a single, simple
   label type.

   Note that gmplsLabelTable supports concatenated labels through the
   use of a label sub-index (gmplsLabelSubindex).

7. Example of GMPLS Tunnel Setup

   This section contains an example of which MIB objects should be
   modified to create a GMPLS tunnel.  This example shows a best effort,
   loosely routed, bidirectional traffic engineered tunnel, which spans
   two hops of a simple network, uses Generalized Label requests with
   Lambda encoding, has label recording and shared link layer
   protection.  Note that these objects should be created on the "head-
   end" LSR.

   First in the mplsTunnelTable:
   {
     mplsTunnelIndex                = 1,
     mplsTunnelInstance             = 1,
     mplsTunnelIngressLSRId         = 123.123.125.1,
     mplsTunnelEgressLSRId          = 123.123.126.1,
     mplsTunnelName                 = "My first tunnel",
     mplsTunnelDescr                = "Here to there and back again",
     mplsTunnelIsIf                 = true (1),
     mplsTunnelXCPointer            = mplsXCIndex.3.0.0.12,
     mplsTunnelSignallingProto      = none (1),
     mplsTunnelSetupPrio            = 0,
     mplsTunnelHoldingPrio          = 0,
     mplsTunnelSessionAttributes    = recordRoute (4),
     mplsTunnelOwner                = snmp (2),
     mplsTunnelLocalProtectInUse    = false (0),
     mplsTunnelResourcePointer      = mplsTunnelResourceIndex.6,
     mplsTunnelInstancePriority     = 1,
     mplsTunnelHopTableIndex        = 1,
     mplsTunnelPrimaryInstance      = 0,
     mplsTunnelIncludeAnyAffinity   = 0,
     mplsTunnelIncludeAllAffinity   = 0,
     mplsTunnelExcludeAnyAffinity   = 0,
     mplsTunnelPathInUse            = 1,
     mplsTunnelRole                 = head(1),
     mplsTunnelRowStatus            = createAndWait (5),
   }

   In gmplsTunnelTable(1,1,123.123.125.1,123.123.126.1):
   {
     gmplsTunnelUnnumIf             = true (1),
     gmplsTunnelAttributes          = labelRecordingRequired (1),
     gmplsTunnelLSPEncoding         = tunnelLspLambda (8),
     gmplsTunnelSwitchingType       = lsc (150),
     gmplsTunnelLinkProtection      = shared (2),
     gmplsTunnelGPid                = lambda (37),
     gmplsTunnelSecondary           = false(0),
     gmplsTunnelDirection           = bidirectional (1)
     gmplsTunnelSecondary           = false(0),
     gmplsTunnelPathComp            = explicit(2),
     gmplsTunnelUpNotRecip          = 0x7B7B7D01,
     gmplsTunnelDownNotRecip        = 0x00000000,
     gmplsTunnelAdminStatusFlags    = 0 0,
     gmplsTunnelExtraParamsPtr      = 0.0
   }

   Entries in the mplsTunnelResourceTable, mplsTunnelHopTable and
   gmplsTunnelHopTable are created and activated at this time.

   In mplsTunnelResourceTable:
   {
     mplsTunnelResourceIndex        = 6,
     mplsTunnelResourceMaxRate      = 0,
     mplsTunnelResourceMeanRate     = 0,
     mplsTunnelResourceMaxBurstSize = 0,
     mplsTunnelResourceRowStatus    = createAndGo (4)
   }

   The next two instances of mplsTunnelHopEntry are used to denote the
   hops this tunnel will take across the network.

   The following denotes the beginning of the network, or the first hop.
   We have used the fictitious LSR identified by "123.123.125.1" as our
   example head-end router.

   In mplsTunnelHopTable:
   {
     mplsTunnelHopListIndex         = 1,
     mplsTunnelPathOptionIndex      = 1,
     mplsTunnelHopIndex             = 1,
     mplsTunnelHopAddrType          = ipV4 (1),
     mplsTunnelHopIpv4Addr          = 123.123.125.1,
     mplsTunnelHopIpv4PrefixLen     = 9,
     mplsTunnelHopType              = strict (1),
     mplsTunnelHopRowStatus         = createAndWait (5),
   }
   The following denotes the end of the network, or the last hop in our
   example. We have used the fictitious LSR identified by
   "123.123.126.1" as our end router.

   In mplsTunnelHopTable:
   {
     mplsTunnelHopListIndex         = 1,
     mplsTunnelPathOptionIndex      = 1,
     mplsTunnelHopIndex             = 2,
     mplsTunnelHopAddrType          = ipV4 (1),
     mplsTunnelHopIpv4Addr          = 123.123.126.1,
     mplsTunnelHopIpv4PrefixLen     = 9,
     mplsTunnelHopType              = loose (2),
     mplsTunnelHopRowStatus         = createAndGo (4)
   }

   Now an associated entry in the gmplsTunnelHopTable is created to
   provide additional GMPLS hop configuration indicating that the first
   hop is an unnumbered link using explicit forward and reverse labels.
   An entry in the gmplsLabelTable is created first to include the
   explicit label.

   In gmplsLabelTable:
   {
     gmplsLabelInterface            = 2,
     gmplsLabelIndex                = 1,
     gmplsLabelSubindex             = 0,
     gmplsLabelType                 = gmplsFreeformGeneralizedLabel(3),
     gmplsLabelFreeform             = 0xFEDCBA9876543210
     gmplsLabelRowStatus            = createAndGo(4)
   }

   In gmplsTunnelHopTable(1,1,1):
   {
     gmplsTunnelHopLabelStatuses    = forwardPresent(0)
                                                +reversePresent(1),
     gmplsTunnelHopExplicitLabel
     gmplsTunnelHopExpLabelPtr      = gmplsLabelInterface.1,
     gmplsTunnelHopExpRvrsLabel gmplsLabelTable (2, 1, 0)
     gmplsTunnelHopExpRvrsLabelPtr  = gmplsLabelInterface.2 gmplsLabelTable (2, 1, 0)
   }

   The first hop is now activated:

   In mplsTunnelHopTable(1,1,1):
   {
     mplsTunnelHopRowStatus         = active (1)
   }

   No gmplsTunnelHopEntry is created for the second hop as it contains
   no special GMPLS features.

   Finally the mplsTunnelEntry is activated:

   In mplsTunnelTable(1,1,123.123.125.1,123.123.126.1)
   {
     mplsTunnelRowStatus            = active(1)
   }

8. GMPLS Traffic Engineering MIB Definitions

   GMPLS-TE-STD-MIB DEFINITIONS ::= BEGIN

   IMPORTS
     MODULE-IDENTITY, OBJECT-TYPE OBJECT-TYPE, NOTIFICATION-TYPE,
     Integer32, Unsigned32, Counter32,
     Counter64, IpAddress IpAddress, zeroDotZero
       FROM SNMPv2-SMI
     MODULE-COMPLIANCE, OBJECT-GROUP OBJECT-GROUP, NOTIFICATION-GROUP
       FROM SNMPv2-CONF
     TruthValue, TimeStamp, DisplayString DisplayString, RowPointer
       FROM SNMPv2-TC
     InetAddressIPv4, InetAddressIPv6
     InetAddress
       FROM INET-ADDRESS-MIB
     mplsTunnelIndex, mplsTunnelInstance, mplsTunnelIngressLSRId,
     mplsTunnelEgressLSRId, mplsTunnelHopListIndex,
     mplsTunnelHopPathOptionIndex, mplsTunnelHopIndex,
     mplsTunnelARHopListIndex, mplsTunnelARHopIndex,
     mplsTunnelCHopListIndex, mplsTunnelCHopIndex,
     mplsTunnelEntry, mplsTunnelSignallingProto mplsTunnelSignallingProto,
     mplsTunnelAdminStatus, mplsTunnelOperStatus
       FROM MPLS-TE-STD-MIB
     gmplsStdMIB
       FROM GMPLS-TC-STD-MIB
   ;

   gmplsTeStdMIB MODULE-IDENTITY
         LAST-UPDATED
           "200310300900Z"
           "200402130900Z" -- 30 October 2003 13 February 2004 9:00:00 GMT" GMT
         ORGANIZATION
           "Common Control And Management Protocols (CCAMP)
            Working Group"
         CONTACT-INFO
           "       Thomas D. Nadeau
                   Cisco Systems, Inc.
            Email: tnadeau@cisco.com

                   Cheenu Srinivasan
                   Bloomberg L.P.
            Email: cheenu@bloomberg.net

                   Adrian Farrel
                   Old Dog Consulting
            Email: adrian@olddog.co.uk

                   Ed Harrison
                   Data Connection Ltd.
            Email: ed.harrison@dataconnection.com

                   Tim Hall
                   Data Connection Ltd.
            Email: timhall@dataconnection.com tim.hall@dataconnection.com

            Comments about this document should be emailed direct to the
            CCAMP working group mailing list at ccamp@ops.ietf.org"
         DESCRIPTION
           "This MIB module contains managed object definitions
            for GMPLS Traffic Engineering (TE).

            Copyright (C) The Internet Society (2003). (2004).  This
            version of this MIB module is part of RFCXXX; see
            the RFC itself for full legal notices."

   -- Revision history.
         REVISION
           "200310300900Z"
           "200402130900Z" -- 30 October 2003 13 February 2004 09:00:00 GMT
         DESCRIPTION
           "Initial revision, published as part of RFC XXXX."
   ::= { gmplsStdMIB xx }

   -- Top level components of this MIB.

   -- Notifications
   -- no notifications are currently defined.
   gmplsTeNotifications OBJECT IDENTIFIER ::= { gmplsTeStdMIB 0 }

   -- tables, scalars
   gmplsTeScalars OBJECT IDENTIFIER ::= { gmplsTeStdMIB 1 }
   gmplsTeObjects OBJECT IDENTIFIER ::= { gmplsTeStdMIB 2 }

   -- conformance
   gmplsTeConformance OBJECT IDENTIFIER ::= { gmplsTeStdMIB 3 }

   -- GMPLS Tunnel scalars.

   gmplsTunnelsConfigured OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The number of GMPLS tunnels configured on this
        device. A GMPLS tunnel is considered configured if
        an entry for the tunnel exists in the
        gmplsTunnelTable and the associated
        mplsTunnelRowStatusis active(1)."
   ::= { gmplsTeScalars 1 }

   gmplsTunnelsActive OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The number of GMPLS tunnels active on this device.
        A GMPLS tunnel is considered active if there is an
        entry in the gmplsTunnelTable and the associated
        mplsTunnelOperStatus for the tunnel is up(1)."
   ::= { gmplsTeScalars 2 }

   -- End of GMPLS Tunnel scalars.

   -- GMPLS tunnel table.

   gmplsTunnelTable OBJECT-TYPE
     SYNTAX  SEQUENCE OF GmplsTunnelEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "The gmplsTunnelTable 'extends' the mplsTunnelTable.
        It allows GMPLS tunnels to be created between an LSR
        and a remote endpoint, and existing tunnels to be
        reconfigured or removed.
        Note that only point-to-point tunnel segments are
        supported, although multi-point-to-point and point-
        to-multi-point connections are supported by an LSR
        acting as a cross-connect. Each tunnel can thus have
        one out-segment originating at this LSR and/or one
        in-segment terminating at this LSR.

        The row status of an entry in this table is
        controlled by mplsTunnelRowStatus in the
        corresponding entry in mplsTunnelTable. That is,
        it is not permitted to create a row in this table,
        nor to modify an existing row, when the
        corresponding mplsTunnelRowStatus has value
        active(1).

        The exception to this rule is the gmplsTunnelAdminStatusFlags
        object, which can be modified whilst the tunnel is active."
   ::= { gmplsTeObjects 1 }

   gmplsTunnelEntry OBJECT-TYPE
     SYNTAX  GmplsTunnelEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "An entry in this table in association with the
        corresponding entry in the mplsTunnelTable
        represents a GMPLS tunnel.
        An entry can be created by a network administrator
        or by an SNMP agent as instructed by a signaling
        protocol."
     INDEX {
       mplsTunnelIndex,
       mplsTunnelInstance,
       mplsTunnelIngressLSRId,
       mplsTunnelEgressLSRId
     }
   ::= { gmplsTunnelTable 1 }

   GmplsTunnelEntry ::= SEQUENCE {
     gmplsTunnelUnnumIf            TruthValue,
     gmplsTunnelAttributes         BITS,
     gmplsTunnelLSPEncoding        Integer32,
     gmplsTunnelSwitchingType      Integer32,
     gmplsTunnelLinkProtection     BITS,
     gmplsTunnelGPid               Integer32,
     gmplsTunnelSecondary          TruthValue,
     gmplsTunnelDirection          INTEGER,
     gmplsTunnelPathComp           INTEGER,
     gmplsTunnelUpNotRecip         IpAddress,
     gmplsTunnelDownNotRecip       IpAddress,
     gmplsTunnelAdminStatusFlags   BITS   BITS,
     gmplsTunnelExtraParamsPtr     RowPointer
   }

   gmplsTunnelUnnumIf OBJECT-TYPE
     SYNTAX  TruthValue
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "Denotes whether or not this tunnel corresponds to an
        unnumbered interface represented in the interfaces
        group table.
        This object is only used if mplsTunnelIsIf is set to
        'true'.
        If both this object and the mplsTunnelIsIf object
        are set to 'true', the originating LSR adds an
        LSP_TUNNEL_INTERFACE_ID object to the outgoing Path
        message.
        This object contains information that is only used
        by the terminating LSR."
     REFERENCE
       "1. draft-ietf-mpls-crldp-unnum-06.txt - Signalling
           Unnumbered Links in CR-LDP, Kompella, K., Rekhter, Y.
           and Kullberg, A., June 2002.
        2. Signalling
       "Signalling Unnumbered Links in RSVP-TE, Kompella, K.
           and Rekhter, Y., RFC 3477, January 2003."
     DEFVAL  { false }
   ::= { gmplsTunnelEntry 1 }

   gmplsTunnelAttributes OBJECT-TYPE
     SYNTAX BITS {
       labelRecordingDesired (0)
     }
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "This bitmask indicates optional parameters for this
        tunnel. These bits should be taken in addition to
        those defined in mplsTunnelSessionAttributes in
        order to determine the full set of options to be
        signaled (for example SESSION_ATTRIBUTES flags in
        RSVP-TE).
        The following describes these bitfields:

        labelRecordingDesired
          This flag indicates that label information should be
          included when doing a route record.  This bit is not
          valid unless the recordRoute bit is set."

     REFERENCE
       "1. RSVP-TE: Extensions to RSVP for LSP Tunnels,
           Awduche et al, RFC 3209, December 2001."
     DEFVAL  { { } }
   ::= { gmplsTunnelEntry 2 }
   gmplsTunnelLSPEncoding OBJECT-TYPE
     SYNTAX  Integer32 (0..255)
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "This object indicates the encoding of the LSP being
        requested.
        A value of zero indicates that GMPLS signaling is
        not in use. Some objects in this MIB module may be
        of use for MPLS signaling extensions that do not use
        GMPLS signaling. By setting this object to zero, an
        application may indicate that only those objects
        meaningful in MPLS should be examined.
        The values to use are currently defined in
        Generalized Multi-Protocol Label Switching (GMPLS)
        Signaling Functional Description, RFC 3471. Further
        values may be defined in future RFCs.
          tunnelLspPacket (1),
          tunnelLspEthernet (2),
          tunnelLspAnsiEtsiPdh (3),
          -- the value 4 is deprecated
          tunnelLspSdhSonet (5),
          -- the value 6 is deprecated
          tunnelLspDigitalWrapper (7),
          tunnelLspLambda (8),
          tunnelLspFiber (9),
          -- the value 10 is deprecated
          tunnelLspFiberChannel (11)"
     REFERENCE
       "1. Berger, L., et al., Generalized Multi-Protocol
           Label Switching (GMPLS) Signaling Functional
           Description, RFC 3471, January 2003."
     DEFVAL  { 0 }
   ::= { gmplsTunnelEntry 3 }

   gmplsTunnelSwitchingType OBJECT-TYPE
     SYNTAX  Integer32 (0..255)
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "Indicates the type of switching that should be performed on
        a particular link. This field is needed for links that
        advertise more than one type of switching capability. Values
        of this object are as the Switching Capability field defined
        in Internet Draft OSPF Extensions in Support of Generalized
        MPLS. Further values may be defined in future RFCs.
          unknown (0),
          psc1 (1),
          psc2 (2),
          psc3 (3),
          psc4 (4),
          l2sc (51),
          tdm (100),
          lsc (150),
          fsc (200)
        This object is only meaningful if
        gmplsTunnelLSPEncoding is not set to 0."
     REFERENCE
       "1. Kompella, K., et al., OSPF Extensions in Support
           of Generalized MPLS, draft-ietf-ccamp-ospf-gmpls-
           extensions-07.txt, May 2002,
           extensions-12.txt, October 2003, work in progress.
        2. Berger, L., et al., Generalized Multi-Protocol
           Label Switching (GMPLS) Signaling Functional
           Description, RFC 3471, January 2003."
     DEFVAL  { 0 }
   ::= { gmplsTunnelEntry 4 }

   gmplsTunnelLinkProtection OBJECT-TYPE
     SYNTAX  BITS {
       extraTraffic(0),
       unprotected(1),
       shared (2),
       dedicatedOneToOne (3),
       dedicatedOnePlusOne(4),
       enhanced(5)
     }
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "This bitmask indicates the level of link protection
        required. A value of zero (no bits set) indicates
        that any protection may be used.
        The following describes these bitfields:

        extraTraffic
          Indicates that the LSP should use links that are
          protecting other (primary) traffic.  Such LSPs may
          be preempted when the links carrying the (primary)
          traffic being protected fail.

        unprotected
          Indicates that the LSP should not use any link layer
          protection.

        shared
          Indicates that a shared link layer protection scheme,
          such as 1:N protection, should be used to support the LSP.

        dedicatedOneToOne
          Indicates that a dedicated link layer protection scheme,
          i.e., 1:1 protection, should be used to support the LSP.

        dedicatedOnePlusOne
          Indicates that a dedicated link layer protection scheme,
          i.e., 1+1 protection, should be used to support the LSP.

        enhanced
          Indicates that a protection scheme that is more reliable than
          Dedicated 1+1 should be used, e.g., 4 fiber BLSR/MS-SPRING.

        This object is only meaningful if
        gmplsTunnelLSPEncoding is not set to 0."
     DEFVAL  { { } }
   ::= { gmplsTunnelEntry 5 }
   gmplsTunnelGPid OBJECT-TYPE
     SYNTAX  Integer32 (0..65535)
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "This object indicates the payload carried by the
        LSP. It is only required when GMPLS will be used for
        this LSP.

        The values to use are currently defined in
        Generalized Multi-Protocol Label Switching (GMPLS)
        Signaling Functional Description, RFC 3471. Further
        values may be defined in future RFCs.

          unknown(0),
          asynchE4(5),
          asynchDS3T3(6),
          asynchE3(7),
          bitsynchE3(8),
          bytesynchE3(9),
          asynchDS2T2(10),
          bitsynchDS2T2(11),
          asynchE1(13),
          bytesynchE1(14),
          bytesynch31ByDS0(15),
          asynchDS1T1(16),
          bitsynchDS1T1(17),
          bytesynchDS1T1(18),
          VC11VC12(19),
          ds1SFAsynch(22),
          ds1ESFAsynch(23),
          ds3M23Asynch(24),
          ds3CBitParityAsynch(25),
          vtLovc(26),
          stsSpeHovc(27),
          posNoScramble16BitCrc(28),
          posNoScramble32BitCrc(29),
          posScramble16BitCrc(30),
          posScramble32BitCrc(31),
          atm(32)
          ethernet(33),
          sdhSonet(34),
          digitalwrapper(36),
          lambda(37),
          ansiEtsiPdh (38),
          lapsSdh (40),
          fddi (41),
          dqdb (42),
          fiberChannel3 (43),
          hdlc (44),
          ethernetV2DixOnly (45),
          ethernet802dot3Only (46)

        This object is only meaningful if
        gmplsTunnelLSPEncoding is not set to 0."
     REFERENCE
       "1. Berger, L., et al., Generalized Multi-Protocol
           Label Switching (GMPLS) Signaling Functional
           Description, RFC 3471, January 2003."
     DEFVAL  { 0 }
   ::= { gmplsTunnelEntry 6 }

   gmplsTunnelSecondary OBJECT-TYPE
     SYNTAX  TruthValue
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "Indicates that the requested LSP is a secondary LSP.

        This object is only meaningful if
        gmplsTunnelLSPEncoding is not set to 0."
     DEFVAL  { false }
   ::= { gmplsTunnelEntry 7 }

   gmplsTunnelDirection OBJECT-TYPE
     SYNTAX  INTEGER {
       forward (0),
       bidirectional (1)
     }
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "Whether this tunnel carries forward data (is
        unidirectional) or is bidirectional.
        Values of this object other than 'forward' are meaningful
        only if gmplsTunnelLSPEncoding is not set to 0."
     DEFVAL { forward }
   ::= { gmplsTunnelEntry 8 }

   gmplsTunnelPathComp OBJECT-TYPE
     SYNTAX  INTEGER {
       dynamicFull(1),-- CSPF fully computed
       explicit(2),-- fully specified path
       dynamicPartial(3) -- CSPF partially computed
     }
     MAX-ACCESS read-create
     STATUS current
     DESCRIPTION
       "This value instructs the source node on how to perform
        path computation on the explicit route specified by the
        associated entries in the gmplsTunnelHopTable.

        dynamicFull
          The user specifies at least the source and
          destination of the path and expects that the CSPF
          will calculate the remainder of the path.

        explicit
          The user specifies the entire path for the tunnel to
          take. This path may contain strict or loose hops.
          Evaluation of the explicit route will be performed
          hop by hop through the network.

        dynamicPartial
          The user specifies at least the source and
          destination of the path and expects that the CSPF
          will calculate the remainder of the path. The path
          computed by CSPF is allowed to be only partially
          computed allowing the remainder of the path to be
          filled in across the network.

        This object deprecates gmplsTunnelHopEntryPathComp."
     DEFVAL { dynamicFull }
   ::= { gmplsTunnelEntry 9 }

   gmplsTunnelUpNotRecip OBJECT-TYPE
     SYNTAX  IpAddress
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "Indicates the address of the upstream recipient for Notify
        messages relating to this tunnel.

        This object is only valid when signaling a tunnel using
        RSVP.  It is also not valid at the tail end of the tunnel.

        If set to 0, no Notify Request object will be included in
        outgoing Path messages."

     DEFVAL { '00000000'H } -- 0.0.0.0
   ::= { gmplsTunnelEntry 10 }

   gmplsTunnelDownNotRecip OBJECT-TYPE
     SYNTAX  IpAddress
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "Indicates the address of the upstream recipient for Notify
        messages relating to this tunnel.

        This object is only valid when signaling a tunnel using
        RSVP.  It is also not valid at the head end of the tunnel.

        If set to 0, no Notify Request object will be included in
        outgoing Resv messages."

     DEFVAL { '00000000'H } -- 0.0.0.0
   ::= { gmplsTunnelEntry 11 }

   gmplsTunnelAdminStatusFlags OBJECT-TYPE
      SYNTAX      BITS {
             delInProgress (0),
             adminDown (1),
             testing (2),
             reflect (31)
             }
      MAX-ACCESS   read-create
      STATUS       current
      DESCRIPTION
        "Determines the setting of the Admin Status flags in the
         Admin Status object or TLV, as described in
         RFC 3471.  Setting this field to a non-zero value will
         result in the inclusion of the admin status object on
         signaling messages.

         This value of this object can be modified when the
         corresponding mplsTunnelRowStatus and mplsTunnelAdminStatus
         is active(1).  By doing so, a new signaling message will be
         triggered including the requested Admin Status object or
         TLV."

      ::= { gmplsTunnelEntry 12 }

   -- End of gmplsTunnelTable

   -- Begin gmplsTunnelHopTable

   gmplsTunnelHopTable

   gmplsTunnelExtraParamsptr  OBJECT-TYPE
      SYNTAX  SEQUENCE OF GmplsTunnelHopEntry       RowPointer
      MAX-ACCESS not-accessible   read-create
      STATUS       current
      DESCRIPTION
       "The gmplsTunnelHopTable 'extends' the
        mplsTunnelHopTable. It is used to indicate the
        explicit labels to
        "Some Tunnels will run over transports that can
         usefully support technology-specific additional parameters
         (for example, SONET resource usage).
         Such can be used in supplied from an explicit path for a
        GMPLS external table and referenced from
         here.
         A value of zeroDotzero in this attribute indicates that there
         is no such additional information."

      DEFVAL      { zeroDotZero }
      ::= { gmplsTunnelEntry 13 }

   -- End of gmplsTunnelTable

   -- Begin gmplsTunnelHopTable

   gmplsTunnelHopTable  OBJECT-TYPE
     SYNTAX  SEQUENCE OF GmplsTunnelHopEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "The gmplsTunnelHopTable 'extends' the
        mplsTunnelHopTable. It is used to indicate the
        explicit labels to be used in an explicit path for a
        GMPLS tunnel defined in mplsTunnelTable and
        gmplsTunnelTable, when it is established using
        signaling. It does not insert new hops, but does
        define new values for hops defined in
        mplsTunnelHopTable.

        Each row in this table is indexed by the same
        indexes as mplsTunnelHopTable. It is acceptable for
        some rows in mplsTunnelHopTable to have
        corresponding entries in this table and some to have
        no corresponding entry in this table.

        The storage type for an entry in this table is
        inherited from mplsTunnelHopStorageType in the
        corresponding entry in mplsTunnelHopTable.

        The row status of an entry in this table is
        controlled by mplsTunnelHopRowStatus in the
        corresponding entry in mplsTunnelHopTable. That is,
        it is not permitted to create a row in this table,
        nor to modify an existing row, when the
        corresponding mplsTunnelHopRowStatus has value
        active(1)."
   ::= { gmplsTeObjects 2 }

   gmplsTunnelHopEntry  OBJECT-TYPE
     SYNTAX  GmplsTunnelHopEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "An entry in this table represents additions to a
        tunnel hop defined in mplsTunnelHopEntry. At an
        ingress to a tunnel an entry in this table is
        created by a network administrator for an ERLSP to
        be set up by a signaling protocol. At transit and
        egress nodes an entry in this table may be used to
        represent the explicit path instructions received
        using the signaling protocol."

     INDEX {
       mplsTunnelHopListIndex,
       mplsTunnelHopPathOptionIndex,
       mplsTunnelHopIndex
     }
   ::= { gmplsTunnelHopTable 1 }

   GmplsTunnelHopEntry ::= SEQUENCE {
     gmplsTunnelHopLabelStatuses     BITS,
     gmplsTunnelHopExplicitLabel
     gmplsTunnelHopExpLabel          Unsigned32,
     gmplsTunnelHopExpLabelPtr       RowPointer,
     gmplsTunnelHopExpRvrsLabel      Unsigned32      Unsigned32,
     gmplsTunnelHopExpRvrsLabelPtr   RowPointer
   }

   gmplsTunnelHopLabelStatuses OBJECT-TYPE
     SYNTAX  BITS {
       forwardPresent (0),
       reversePresent (1)
     }
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "This bitmask indicates the presence of labels
        indicated by the gmplsTunnelHopExplicitLabel gmplsTunnelHopExpLabel or
        gmplsTunnelHopExpLabelPtr and
        gmplsTunnelHopExpRvrsLabel or gmplsTunnelHopExpRvrsLabel
        objects.

        For the Present bits, a set bit indicates that a
        label is present for this hop in the route. This
        allows zero to be a valid label value."
   ::= { gmplsTunnelHopEntry 1 }

   gmplsTunnelHopExplicitLabel
   gmplsTunnelHopExpLabel OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "Indicates the row entry in the gmplsLabelTable
       "If gmplsTunnelHopLabelStatuses object indicates that
        defines the explicit label to use in the explicit
        route as the a
        forward path label at this point. This
        value only has meaning if the forwardPresent bit of
        gmplsTunnelHopLabelStatuses is set.
        Note that present and gmplsTunnelHopExpLabelPtr
        contains the other indexes in value zeroDotZero, then the gmplsLabelTable
        should be interpreted as follows:
        - The gmplsLabelInterface should be zero because
          this label is not tied to any specific interface use on this LSR
        - The gmplsLabelSubindex is used to represent label
          concatenations. The first (or only) component
          label SHOULD have gmplsLabelSubindex set to zero.

        This variable
        hop is only valid for settings of
        mplsTunnelHopAddrType which may be associated with a
        forward path label.
        Note that found in implementations where the label may be this object encoded within a 32 bit integer and where
        gmplsLabelTable is not implemented, this object may
        directly contain the label value to use." 32-bit integer."
   ::= { gmplsTunnelHopEntry 2 }

   gmplsTunnelHopExpRvrsLabel

   gmplsTunnelHopExpLabelPtr OBJECT-TYPE
     SYNTAX  Unsigned32  RowPointer
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "Indicates
       "If the gmplsTunnelHopLabelStatuses object indicates
        that a forward label is present, this object contains
        a pointer to a row entry in another MIB table (such as the gmplsLabelTable
        gmplsLabelTable) that
        defines contains the explicit label to use on
        this hop in the explicit
        route as forward direction.
        If the reverse path gmplsTunnelHopLabelStatuses object indicates that
        a forward label at is present and this point. This object contains the
        value only has meaning if zeroDotZero, then the label to use on this hop is
        found in the gmplsTunnelHopExpLabel object."
     DEFVAL  { zeroDotZero }
   ::= { gmplsTunnelHopEntry 3 }

   gmplsTunnelHopExpRvrsLabel OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "If the reversePresent bit of gmplsTunnelHopLabelStatuses object indicates that a
        reverse label is set.
        The same rules present and notes apply gmplsTunnelHopExpRvrsLabelPtr
        contains the value zeroDotZero, then the label to use on
        this hop is found in this object encoded as set out for
        gmplsTunnelHopExplicitLabel." a 32-bit integer."
   ::= { gmplsTunnelHopEntry 3 4 }

   gmplsTunnelHopExpRvrsLabelPtr OBJECT-TYPE
     SYNTAX  RowPointer
     MAX-ACCESS read-create
     STATUS  current
     DESCRIPTION
       "If the gmplsTunnelHopLabelStatuses object indicates
        that a reverse label is present, this object contains
        a pointer to a row in another MIB table (such as the
        gmplsLabelTable) that contains the label to use on
        this hop in the reverse direction.
        If the gmplsTunnelHopLabelStatuses object indicates that
        a reverse label is present and this object contains the
        value zeroDotZero, then the label to use on this hop is
        found in the gmplsTunnelHopExpRvrsLabel object."
     DEFVAL  { zeroDotZero }
   ::= { gmplsTunnelHopEntry 5 }

   -- End of gmplsTunnelHopTable
   -- Tunnel Actual Route Hop table.

   gmplsTunnelARHopTable  OBJECT-TYPE
     SYNTAX  SEQUENCE OF GmplsTunnelARHopEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "The gmplsTunnelARHopTable 'extends' the
        mplsTunnelARHopTable. It is used to indicate the
        labels currently in use for a GMPLS tunnel defined
        in mplsTunnelTable and gmplsTunnelTable, as reported
        by the signaling protocol. It does not insert new
        hops, but does define new values for hops defined in
        mplsTunnelARHopTable.

        Each row in this table is indexed by the same indexes as
        mplsTunnelARHopTable. It is acceptable for some rows in
        mplsTunnelARHopTable to have corresponding entries in this
        table and some to have no corresponding entry in this table.

        Note that since the information necessary to build
        entries within this table is not provided by some
        signaling protocols and might not be returned in all
        cases of other signaling protocols, implementation
        of this table and mplsTunnelARHopTable is optional.
        Furthermore, since the information in this table is
        actually provided by the signaling protocol after
        the path has been set-up, the entries in this table
        are provided only for observation, and hence, all
        variables in this table are accessible exclusively
        as read-only."
   ::= { gmplsTeObjects 3 }

   gmplsTunnelARHopEntry  OBJECT-TYPE
     SYNTAX  GmplsTunnelARHopEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "An entry in this table represents additions to a
        tunnel hop visible in mplsTunnelARHopEntry. An entry
        is created by the signaling protocol for a signaled
        ERLSP set up by the signaling protocol.

        At any node on the LSP (ingress, transit or egress)
        Thus at this table and mplsTunnelARHopTable (if the
        tables are supported and if the signaling protocol
        is recording actual route information) contains the
        actual route of the whole tunnel. If the signaling
        protocol is not recording the actual route, this
        table MAY report the information from the
        gmplsTunnelHopTable or the gmplsTunnelCHopTable.

        Note that the recording of actual labels is distinct
        from the recording of the actual route in some
        signaling protocols. This feature is enabled using
        the gmplsTunnelAttributes object."
     INDEX {
       mplsTunnelARHopListIndex,
       mplsTunnelARHopIndex
     }
   ::= { gmplsTunnelARHopTable 1 }

   GmplsTunnelARHopEntry ::= SEQUENCE {
     gmplsTunnelARHopLabelStatuses     BITS,
     gmplsTunnelARHopExplicitLabel
     gmplsTunnelARHopExpLabel          Unsigned32,
     gmplsTunnelARHopExpLabelPtr       RowPointer,
     gmplsTunnelARHopExpRvrsLabel      Unsigned32,
     gmplsTunnelARHopExpRvrsLabelPtr   RowPointer,
     gmplsTunnelARHopProtection        BITS
   }

   gmplsTunnelARHopLabelStatuses OBJECT-TYPE
     SYNTAX  BITS {
       forwardPresent (0),
       reversePresent (1),
       forwardGlobal (2),
       reverseGlobal (3)
     }
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "This bitmask indicates the presence and status of
        labels indicated by the
        gmplsTunnelARHopExplicitLabel
        gmplsTunnelARHopExpLabel or gmplsTunnelARHopExpLabelPtr and
        gmplsTunnelARHopExpRvrsLabel or gmplsTunnelARHopExpRvrsLabelPtr
        objects.
        For the Present bits, a set bit indicates that a label
        is present for this hop in the route. For the Global bits,
        a set bit indicates that the label comes from the Global
        Label Space. A clear bit indicates that this is a Per-
        Interface label. A Global bit only has meaning if the
        corresponding Present bit is set."
   ::= { gmplsTunnelARHopEntry 1 }

   gmplsTunnelARHopExplicitLabel

   gmplsTunnelARHopExpLabel OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "Indicates the row entry in
       "If the gmplsLabelTable gmplsTunnelARHopLabelStatuses object indicates
        that
        defines a forward label is present and
        gmplsTunnelARHopExpLabelPtr contains the value
        zeroDotZero, then the label in use as the forward path label on the path at this point.
        This value only has meaning if the forwardPresent
        bit of gmplsTunnelARHopLabelStatuses hop is set.

        Note that the other indexes
        found in the gmplsLabelTable
        should be interpreted as follows:
        - The gmplsLabelInterface should be zero because this object encoded within a 32-bit integer."
   ::= { gmplsTunnelARHopEntry 2 }

   gmplsTunnelARHopExpLabelPtr OBJECT-TYPE
     SYNTAX  RowPointer
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "If the gmplsTunnelARHopLabelStatuses object indicates
        that a forward label is not tied to any specific interface
          on present, this LSR
        - The gmplsLabelSubindex is used object contains
        a pointer to represent label
          concatenations. The first (or only) component
          label SHOULD have gmplsLabelSubindex set to zero.

        This variable is only valid for settings of
        mplsTunnelARHopAddrType which may be associated with a forward path label.

        Note that row in implementations where another MIB table (such as the
        gmplsLabelTable) that contains the label may be
        encoded within in use on
        this hop in the forward direction.
        If the gmplsTunnelARHopLabelStatuses object indicates that
        a 32 bit integer and where
        gmplsLabelTable forward label is not implemented, present and this object may
        directly contain contains the label
        value to use." zeroDotZero, then the label in use on this hop is
        found in the gmplsTunnelARHopExpLabel object."
   ::= { gmplsTunnelARHopEntry 2 3 }

   gmplsTunnelARHopExpRvrsLabel OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "Indicates
       "If the gmplsTunnelARHopLabelStatuses object indicates
        that a reverse label is present and
        gmplsTunnelARHopExpRvrsLabelPtr contains the value
        zeroDotZero, then the label in use on this hop is
        found in this object encoded as a 32-bit integer."
   ::= { gmplsTunnelARHopEntry 4 }

   gmplsTunnelARHopExpRvrsLabelPtr OBJECT-TYPE
     SYNTAX  RowPointer
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "If the gmplsTunnelARHopLabelStatuses object indicates
        that a reverse label is present, this object contains
        a pointer to a row entry in another MIB table (such as the gmplsLabelTable
        gmplsLabelTable) that
        defines contains the label used in use on
        this hop in the path as reverse path
        at this point.
        This value only has meaning if direction.
        If the reversePresent
        bit of gmplsTunnelARHopLabelStatuses object indicates that
        a reverse label is set.
        The same rules present and notes apply as set out for
        gmplsTunnelARHopExplicitLabel." this object contains the
        value zeroDotZero, then the label in use on this hop is
        found in the gmplsTunnelARHopExpRvrsLabel object."
   ::= { gmplsTunnelARHopEntry 3 5 }

   gmplsTunnelARHopProtection  OBJECT-TYPE
     SYNTAX  BITS {
       localAvailable (0),
       localInUse (1)
     }
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
      "Availability and usage of protection on the reported link.

       localAvailable
          Indicates that the link downstream of this node
          is protected via a local repair mechanism.
       localInUse
          Indicates that a local repair mechanism is in use to
          maintain this tunnel (usually in the face of an outage
          of the link it was previously routed over)."
   ::= { gmplsTunnelARHopEntry 4 6 }

   -- End of mplsTunnelARHopTable
   -- Tunnel Computed Hop table.

   gmplsTunnelCHopTable  OBJECT-TYPE
     SYNTAX  SEQUENCE OF GmplsTunnelCHopEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "The gmplsTunnelCHopTable 'extends' the mplsTunnelCHopTable.
        It is used to indicate additional information about the
        hops of a GMPLS tunnel defined in mplsTunnelTable and
        gmplsTunnelTable, as computed by a constraint-based
        routing protocol, based on the mplsTunnelHopTable
        and the gmplsTunnelHopTable.

        Each row in this table is indexed by the same indexes as
        mplsTunnelCHopTable. It is acceptable for some rows in
        mplsTunnelCHopTable to have corresponding entries in this
        table and some to have no corresponding entry in this table.

        Please note that since the information necessary to
        build entries within this table may not be supported
        by some LSRs, implementation of this table is optional.

        Furthermore, since the information in this table is actually
        provided by a path computation component after the path has
        been computed, the entries in this table are provided only
        for observation, and hence, all objects in this table are
        accessible exclusively as read-only."
   ::= { gmplsTeObjects 4 }

   gmplsTunnelCHopEntry  OBJECT-TYPE
     SYNTAX  GmplsTunnelCHopEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "An entry in this table represents additions to a
        computed tunnel hop visible in mplsTunnelCHopEntry.
        An entry is created by a path computation component
        based on the hops specified in the corresponding
        mplsTunnelHopTable and gmplsTunnelHopTable.

        At a transit LSR this table (if the table is
        supported) MAY contain the path computed by path
        computation engine on (or on behalf of) the transit LSR."
     INDEX {
       mplsTunnelCHopListIndex,
       mplsTunnelCHopIndex
     }
   ::= { gmplsTunnelCHopTable 1 }

   GmplsTunnelCHopEntry ::= SEQUENCE {
     gmplsTunnelCHopLabelStatuses     BITS,
     gmplsTunnelCHopExplicitLabel
     gmplsTunnelCHopExpLabel          Unsigned32,
     gmplsTunnelCHopExpLabelPtr       RowPointer,
     gmplsTunnelCHopExpRvrsLabel      Unsigned32      Unsigned32,
     gmplsTunnelCHopExpRvrsLabelPtr   RowPointer
   }
   gmplsTunnelCHopLabelStatuses OBJECT-TYPE
     SYNTAX  BITS {
       forwardPresent (0),
       reversePresent (1)
     }
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "This bitmask indicates the presence of labels indicated by the
        gmplsTunnelCHopExplicitLabel
        gmplsTunnelCHopExpLabel or gmplsTunnelCHopExpLabelPtr and
        gmplsTunnelCHopExpRvrsLabel or gmplsTunnelCHopExpRvrsLabelPtr
        objects.
        A set bit indicates that a label is present for this hop in
        the route thus allowing zero to be a valid label value."
   ::= { gmplsTunnelCHopEntry 1 }

   gmplsTunnelCHopExplicitLabel

   gmplsTunnelCHopExpLabel OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "Indicates the row entry in
       "If the gmplsLabelTable gmplsTunnelCHopLabelStatuses object indicates
        that
        defines a forward label is present and
        gmplsTunnelCHopExpLabelPtr contains the value
        zeroDotZero, then the label to use as the forward path label on the path at this point.
        This value only has meaning if the forwardPresent
        bit of gmplsTunnelCHopLabelStatuses hop is set.

        Note that the other indexes
        found in the gmplsLabelTable
        should be interpreted as follows:
        - The gmplsLabelInterface should be zero because
          this label is not tied to any specific interface
          on this LSR
        - The gmplsLabelSubindex is used to represent label
          concatenations. The first (or only) component
          label SHOULD have gmplsLabelSubindex set to zero.
        This variable is only valid for settings of
        mplsTunnelCHopAddrType which may be associated with
        a forward path label.

        Note that in implementations where the label may be object encoded within a 32 bit integer and where
        gmplsLabelTable is not implemented, this object may
        directly contain the label value to use." 32-bit integer."
   ::= { gmplsTunnelCHopEntry 2 }
   gmplsTunnelCHopExpRvrsLabel

   gmplsTunnelCHopExpLabelPtr OBJECT-TYPE
     SYNTAX  Unsigned32  RowPointer
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "Indicates
       "If the gmplsTunnelCHopLabelStatuses object indicates
        that a forward label is present, this object contains
        a pointer to a row entry in another MIB table (such as the gmplsLabelTable
        gmplsLabelTable) that
        defines contains the label to use on
        this hop in the path as reverse path
        at this point.
        This value only has meaning if forward direction.
        If the reversePresent
        bit of gmplsTunnelCHopLabelStatuses object indicates that
        a forward label is set.
        The same rules present and notes apply as set out for
        gmplsTunnelCHopExplicitLabel." this object contains the
        value zeroDotZero, then the label to use on this hop is
        found in the gmplsTunnelCHopExpLabel object."
   ::= { gmplsTunnelCHopEntry 3 }

   -- End of gmplsTunnelCHopTable

   -- GMPLS Tunnel Reverse Direction Performance Table.

   gmplsTunnelReversePerfTable

   gmplsTunnelCHopExpRvrsLabel OBJECT-TYPE
     SYNTAX  SEQUENCE OF GmplsTunnelReversePerfEntry  Unsigned32
     MAX-ACCESS not-accessible read-only
     STATUS  current
     DESCRIPTION
       "This table 'augments'
       "If the gmplsTunnelTable to provides
        per-tunnel packet performance information for the
        reverse direction of gmplsTunnelCHopLabelStatuses object indicates
        that a bidirectional tunnel. It can be
        seen as supplementing reverse label is present and
        gmplsTunnelCHopExpRvrsLabelPtr contains the mplsTunnelPerfTable which
        augments value
        zeroDotZero, then the mplsTunnelTable." label to use on this hop is
        found in this object encoded as a 32-bit integer."
   ::= { gmplsTeObjects 5 gmplsTunnelCHopEntry 4 }

   gmplsTunnelReversePerfEntry
   gmplsTunnelCHopExpRvrsLabelPtr OBJECT-TYPE
     SYNTAX  GmplsTunnelReversePerfEntry  RowPointer
     MAX-ACCESS not-accessible read-only
     STATUS  current
     DESCRIPTION
       "An entry in this table
       "If the gmplsTunnelCHopLabelStatuses object indicates
        that a reverse label is present, this object contains
        a pointer to a row in another MIB table (such as the
        gmplsLabelTable) that contains the label to use on
        this hop in the reverse direction.
        If the gmplsTunnelCHopLabelStatuses object indicates that
        a reverse label is present and this object contains the
        value zeroDotZero, then the label to use on this hop is
        found in the gmplsTunnelCHopExpRvrsLabel object."
   ::= { gmplsTunnelCHopEntry 5 }

   -- End of gmplsTunnelCHopTable

   -- GMPLS Tunnel Reverse Direction Performance Table.

   gmplsTunnelReversePerfTable  OBJECT-TYPE
     SYNTAX  SEQUENCE OF GmplsTunnelReversePerfEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "This table 'augments' the gmplsTunnelTable to provides
        per-tunnel packet performance information for the
        reverse direction of a bidirectional tunnel. It can be
        seen as supplementing the mplsTunnelPerfTable which
        augments the mplsTunnelTable."
   ::= { gmplsTeObjects 5 }

   gmplsTunnelReversePerfEntry OBJECT-TYPE
     SYNTAX  GmplsTunnelReversePerfEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "An entry in this table is created by the LSR for every
        bidirectional GMPLS tunnel where packets are visible to
        the LSR."
     AUGMENTS { gmplsTunnelEntry }
   ::= { gmplsTunnelReversePerfTable 1 }

   GmplsTunnelReversePerfEntry ::= SEQUENCE {
     gmplsTunnelReversePerfPackets     Counter32,
     gmplsTunnelReversePerfHCPackets   Counter64,
     gmplsTunnelReversePerfErrors      Counter32,
     gmplsTunnelReversePerfBytes       Counter32,
     gmplsTunnelReversePerfHCBytes     Counter64
   }
   gmplsTunnelReversePerfPackets OBJECT-TYPE
     SYNTAX  Counter32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "Number of packets forwarded on the tunnel in the
        reverse direction if it is bidirectional."
   ::= { gmplsTunnelReversePerfEntry 1 }

   gmplsTunnelReversePerfHCPackets OBJECT-TYPE
     SYNTAX  Counter64
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "High capacity counter for number of packets forwarded on
       the tunnel in the reverse direction if it is bidirectional."
   ::= { gmplsTunnelReversePerfEntry 2 }

   gmplsTunnelReversePerfErrors OBJECT-TYPE
     SYNTAX  Counter32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "Number of errored packets received on the tunnel in
        the reverse direction if it is bidirectional."
   ::= { gmplsTunnelReversePerfEntry 3 }

   gmplsTunnelReversePerfBytes OBJECT-TYPE
     SYNTAX  Counter32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "Number of bytes forwarded on the tunnel in the
        reverse direction if it is bidirectional."
   ::= { gmplsTunnelReversePerfEntry 4 }

   gmplsTunnelReversePerfHCBytes OBJECT-TYPE
     SYNTAX  Counter64
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "High capacity counter for number of bytes forwarded
        on the tunnel in the reverse direction if it is
        bidirectional."
   ::= { gmplsTunnelReversePerfEntry 5 }

   -- End of gmplsTunnelReversePerfTable
   -- GMPLS Tunnel Error Table.

   gmplsTunnelErrorTable  OBJECT-TYPE
     SYNTAX  SEQUENCE OF GmplsTunnelErrorEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "This table 'augments' the mplsTunnelTable

        This table provides per-tunnel information about
        errors. Errors may be detected locally or reported
        through the signaling protocol.

        Error reporting is not exclusive to GMPLS and this
        table may be applied in MPLS systems."
   ::= { gmplsTeObjects 6 }

   gmplsTunnelErrorEntry OBJECT-TYPE
     SYNTAX  GmplsTunnelErrorEntry
     MAX-ACCESS not-accessible
     STATUS  current
     DESCRIPTION
       "An entry in this table is created by the LSR for
        every tunnel where error information is visible to
        the LSR.
        Note that systems which read the objects in this table
        one at a time may experience a discontinuity as the
        result of a new error occurring in between object reads.
        Systems that are vulnerable to this should read
        gmplsTunnelErrorLastTime before and after reading the
        other objects."
     AUGMENTS { mplsTunnelEntry }
   ::= { gmplsTunnelErrorTable 1 }

   GmplsTunnelErrorEntry ::= SEQUENCE {
     gmplsTunnelErrorLastErrorType      INTEGER,
     gmplsTunnelErrorLastTime           TimeStamp,
     gmplsTunnelErrorReporterType       INTEGER,
     gmplsTunnelErrorReporterIpv4Addr   InetAddressIPv4,
     gmplsTunnelErrorReporterIpv6Addr   InetAddressIPv6,
     gmplsTunnelErrorReporter   InetAddress,
     gmplsTunnelErrorCode               Unsigned32,
     gmplsTunnelErrorSubcode            Unsigned32,
     gmplsTunnelErrorTLVs               OCTET STRING,
     gmplsTunnelErrorHelpString         DisplayString
   }

   gmplsTunnelErrorLastErrorType OBJECT-TYPE
     SYNTAX  INTEGER {
       noError (0),
       unknown (1),
       localProtocol (2),
       remoteProtocol (3),
       configuration (4),
       pathComputation (5),
       localResources (6)
     }
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The nature of the last error. Provides
        interpretation context for
        gmplsTunnelErrorProtocolCode and
        gmplsTunnelErrorProtocolSubcode. A value of noError
        (0) shows that there is no error associated with
        this tunnel and means that the other objects in this
        entry have no meaning."
   ::= { gmplsTunnelErrorEntry 1 }
   gmplsTunnelErrorLastTime OBJECT-TYPE
     SYNTAX  TimeStamp
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The time at which the last error occurred. This is
        presented as the value of SysUpTime when the error
        occurred or was reported to this node.
        If gmplsTunnelErrorLastErrorType has the value
        noError (0), then this object is ignored."
   ::= { gmplsTunnelErrorEntry 2 }

   gmplsTunnelErrorReporterType OBJECT-TYPE
      SYNTAX  INTEGER {
        unknown (0),
        localNode (1),
        localIpV4 (2),
        remoteIpV4 (3),
        localIpV6 (4),
        remoteIpV6 (5)
      }
      MAX-ACCESS read-only
      STATUS  current
      DESCRIPTION
        "The reporter of the last error recorded.
         This object is used principally to aid in interpretation
         of gmplsTunnelErrorReporterIpv4Addr and
         gmplsTunnelErrorReporterIpv6Addr. Where the error has
         been locally generated and there is no requirement to
         associate the error with any specific local address (such
         as an interface), the value localNode (2) may be used.
         If gmplsTunnelErrorLastError has the value noError
         (0), then this object is ignored."
   ::= { gmplsTunnelErrorEntry 3 }

   gmplsTunnelErrorReporterIpv4Addr

   gmplsTunnelErrorReporter OBJECT-TYPE
     SYNTAX  InetAddressIPv4  InetAddress
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The address of the node reporting the last error, or
        the address of the resource (such as an interface)
        associated with the error.
        If gmplsTunnelErrorLastErrorType has the value
        noError (0), then this object is ignored.
        This object only has meaning if should be interpreted in the context of
        the value of the object
        gmplsTunnelErrorReporterType gmplsTunnelErrorReporterType.
        If that object has value localIpV4 (2) or remoteIpV4 (3). (3),
        this object should be viewed as having a syntax of
        InetAddressIPv4. If gmplsTunnelErrorReporterType has
        value localIpV6 (3) or remoteIpV6 (5), this object should be
        viewed as having a syntax of InetAddressIPv6. Otherwise the
        object should contain the value zero and should be ignored."
     REFERENCE
       "RFC3291, Textual Conventions for Internet Network
        Addresses, Section 4. Usage Hints."
   ::= { gmplsTunnelErrorEntry 4 }

   gmplsTunnelErrorReporterIpv6Addr
   gmplsTunnelErrorCode OBJECT-TYPE
     SYNTAX  InetAddressIPv6  Unsigned32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The address of the node reporting the last error, or
       the address of the resource (such as an interface) primary error code associated with the last
        error.

        The interpretation of this error code depends on the
        value of gmplsTunnelErrorLastErrorType. If gmplsTunnelErrorLastErrorType has the value
        of gmplsTunnelErrorLastErrorType is noError (0), then this object is ignored.
       This object only has meaning if the object
       gmplsTunnelErrorReporterType has value localIpV6 (4)
       or remoteIpV4 (5). Otherwise the object should
       contain the value zero and should be ignored."
   ::= { gmplsTunnelErrorEntry 5 }

   gmplsTunnelErrorCode OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The primary error code associated with the last
        error.

        The interpretation of this error code depends on the
        value of gmplsTunnelErrorLastErrorType. If the value
        of gmplsTunnelErrorLastErrorType is noError (0) the
        value of (0) the
        value of this object should be 0 and should be
        ignored. If the value of
        gmplsTunnelErrorLastErrorType is localProtocol (2)
        or remoteProtocol (3) the error should be
        interpreted in the context of the signling protocol
        identified by the mplsTunnelSignallingProto object.

        Values in excess 32767 of are not used by signaling
        protocols and may safely be used as implementation-
        specific error codes. "
   ::= { gmplsTunnelErrorEntry 6 5 }

   gmplsTunnelErrorSubcode OBJECT-TYPE
     SYNTAX  Unsigned32
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The secondary error code associated with the last
        error and the protocol used to signal this tunnel.
        This value is interprettd in the context of the
        value of gmplsTunnelErrorCode.
        If the value of gmplsTunnelErrorLastErrorType is
        noError (0) the value of this object should be 0 and
        should be ignored."
   ::= { gmplsTunnelErrorEntry 6 }

   gmplsTunnelErrorTLVs OBJECT-TYPE
     SYNTAX  OCTET STRING
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "The sequence of interface identifier TLVs reported
        with the error by the protocol code. The interpretation
        of the TLVs and the encoding within the protocol are
        described in the references.
        A value of zero in the first octet indicates that no
        TLVs are present."
      REFERENCE
       "RFC3471, Generalized Multi-Protocol Label Switching
        (GMPLS) Signaling Functional Description,
        Section 9.1. Interface Identification.
        RFC3473, Generalized Multi-Protocol Label Switching
        (GMPLS) Signaling Resource ReserVation Protocol-Traffic
        Engineering (RSVP-TE) Extensions, Section 8.2. Errored
        Interface Identification"
   ::= { gmplsTunnelErrorEntry 7 }
   gmplsTunnelErrorHelpString OBJECT-TYPE
     SYNTAX  DisplayString
     MAX-ACCESS read-only
     STATUS  current
     DESCRIPTION
       "A textual string containing information about the
        last error, recovery actions and support advice. If
        there is no help string this object contains a zero
        length string.
        If the value of gmplsTunnelErrorLastErrorType is
        noError (0) this object should contain a zero length
        string, but may contain a help string indicating
        that there is no error."
   ::= { gmplsTunnelErrorEntry 8 }

   -- GMPLS Notifications.

   gmplsTunnelDown NOTIFICATION-TYPE
   OBJECTS  {
     mplsTunnelAdminStatus,
     mplsTunnelOperStatus,
     gmplsTunnelErrorLastErrorType,
     gmplsTunnelErrorReporterType,
     gmplsTunnelErrorReporter,
     gmplsTunnelErrorCode,
     gmplsTunnelErrorSubcode
   }
   STATUS      current
   DESCRIPTION
        "This notification is generated when a
         mplsTunnelOperStatus object for one of the
         configured tunnels is about to enter the down state
         from some other state (but not from the notPresent
         state). This other state is indicated by the
         included value of mplsTunnelOperStatus.
         The objects in this notification provide additional
         error information that indicates the reason why the
         tunnel has transitioned down.
         Note that an implementation SHOULD only issue one of
         mplsTunnelDown and gmplsTunnelDown for a single event
         on a single tunnel."
   ::= { gmplsTeNotifications 1 }

   -- End of notifications.

   -- Module compliance.

   gmplsTeGroups
     OBJECT IDENTIFIER ::= { gmplsTeConformance 1 }

   gmplsTeCompliances
     OBJECT IDENTIFIER ::= { gmplsTeConformance 2 }
   gmplsTeModuleCompliance MODULE-COMPLIANCE
     STATUS current
     DESCRIPTION
       "Compliance statement for agents that support the
        GMPLS TE MIB."
     MODULE -- this module

   -- The mandatory group has to be implemented by all
   -- LSRs that originate/terminate ESLSPs/tunnels.
   -- In addition, depending on the type of tunnels
   -- supported, other groups become mandatory as
   -- explained below.

   MANDATORY-GROUPS {
     gmplsTunnelGroup,
     gmplsTunnelScalarGroup
   }

-- GROUP gmplsTunnelManualGroup
--   DESCRIPTION
--     "This group is mandatory for devices which support
--      manual configuration of tunnels, in addition to
--      gmplsTunnelGroup.  The following constraints apply:
--      mplsTunnelSignallingProto should be at least read-
--      only with a value of none(1)."

   GROUP gmplsTunnelSignaledGroup
     DESCRIPTION
       "This group is mandatory for devices which support
        signaled tunnel set up, in addition to
        gmplsTunnelGroup.  The following constraints apply:

        mplsTunnelSignallingProto should be at least read-
        only returning a value of ldp(2), or rsvp(3)."

   GROUP gmplsTunnelIsNotIntfcGroup
     DESCRIPTION
       "This group is mandatory for devices which support
        tunnels that are not interfaces, in addition to
        gmplsTunnelGroup.  The following constraints apply:

        gmplsTunnelIsIf must at least be read-only returning no(0)."

   GROUP gmplsTunnelIsIntfcGroup
     DESCRIPTION
       "This group is mandatory for devices which support
        tunnels that are interfaces, in addition to
        gmplsTunnelGroup."

   GROUP gmplsTunnelOptionalGroup
     DESCRIPTION
       "Objects in this group are optional."

   GROUP gmplsTeNotificationGroup
   DESCRIPTION "This group is mandatory for those implementations
                which can implement the notifications contained
                in this group."
   -- GMPLS Tunnel scalars.
   -- All scalars have max access read-only

   -- gmplsTunnelTable

   OBJECT gmplsTunnelAttributes
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelLSPEncoding
     SYNTAX Integer32
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelSwitchingType
     SYNTAX Integer32
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelLinkProtection
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelGPid
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelSecondary
     SYNTAX TruthValue
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelDirection
     SYNTAX INTEGER {
       forward (0),
       bidirectional (1)
     }
     MIN-ACCESS  read-only
     DESCRIPTION
       "Only forward (0) is required."

   OBJECT gmplsTunnelPathComp
     SYNTAX INTEGER {
       dynamicFull(1),   -- CSPF fully computed
       explicit(2),      -- fully
       dynamicPartial(3) -- CSPF partially computed
     }

     MIN-ACCESS  read-only
     DESCRIPTION
       "Only explicit (2) is required."
   OBJECT gmplsTunnelUpNotRecip
     SYNTAX  IpAddress
     MIN-ACCESS read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelDownNotRecip
     SYNTAX  IpAddress
     MIN-ACCESS read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelAdminStatusFlags
      SYNTAX      BITS {
             delInProgress (0),
             adminDown (1),
             testing (2),
             reflect (31)
             }
      MIN-ACCESS   read-only
      DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelExtraParamsPtr
     SYNTAX  RowPointer
     MIN-ACCESS read-only
     DESCRIPTION
       "Write access is not required."

   -- gmplsTunnelHopTable

   -- gmplsTunnelHopLabelStatuses has max access read-only

   OBJECT gmplsTunnelHopExplicitLabel gmplsTunnelHopExpLabel
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelHopExpRvrsLabel gmplsTunnelHopExpLabelPtr
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   --

   OBJECT gmplsTunnelHopExpRvrsLabel
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   OBJECT gmplsTunnelHopExpRvrsLabelPtr
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   -- gmplsTunnelARHopTable
   -- all objects have max access read-only
   -- glmpsTunnelCHopTable
   -- all objects have max access read-only

   -- gmplsTunnelReversePerfTable
   -- all objects have max access read-only

   -- gmplsTunnelErrorTable
   -- all objects have max access read-only

   ::= { gmplsTeCompliances 1 }

   -- Units of conformance.

   gmplsTunnelGroup OBJECT-GROUP
     OBJECTS {
       gmplsTunnelDirection,
       gmplsTunnelReversePerfPackets,
       gmplsTunnelReversePerfHCPackets,
       gmplsTunnelReversePerfErrors,
       gmplsTunnelReversePerfBytes,
       gmplsTunnelReversePerfHCBytes,
       gmplsTunnelErrorLastErrorType,
       gmplsTunnelErrorLastTime,
       gmplsTunnelErrorReporterType,
       gmplsTunnelErrorReporterIpv4Addr,
       gmplsTunnelErrorReporterIpv6Addr,
       gmplsTunnelErrorReporter,
       gmplsTunnelErrorCode,
       gmplsTunnelErrorSubcode,
       gmplsTunnelErrorTLVs,
       gmplsTunnelErrorHelpString
     }
     STATUS  current
     DESCRIPTION
       "Necessary, but not sufficient, set of objects to implement
        tunnels.  In addition, depending on the type of the tunnels
        supported (for example, manually configured or signaled,
        persistent or non-persistent, etc.), the following other
        groups defined below are mandatory: gmplsTunnelManualGroup
        and/or gmplsTunnelSignaledGroup, gmplsTunnelIsNotIntfcGroup
        and/or gmplsTunnelIsIntfcGroup."
   ::= { gmplsTeGroups 1 }

-- gmplsTunnelManualGroup  OBJECT-GROUP
--   OBJECTS {
--     mplsTunnelSignallingProto
--   }
--   STATUS  current
--   DESCRIPTION
--     "Object(s) needed to implement manually configured
--      tunnels."
-- ::= { gmplsTeGroups 2 }
   gmplsTunnelSignaledGroup OBJECT-GROUP
     OBJECTS {
       gmplsTunnelAttributes,
       gmplsTunnelLSPEncoding,
       gmplsTunnelSwitchingType,
       gmplsTunnelLinkProtection,
       gmplsTunnelGPid,
       gmplsTunnelSecondary,
       gmplsTunnelPathComp,
       gmplsTunnelUpNotRecip,
       gmplsTunnelDownNotRecip,
       gmplsTunnelAdminStatusFlags,
       gmplsTunnelHopLabelStatuses,
       gmplsTunnelHopExplicitLabel,
       gmplsTunnelHopExpRvrsLabel
       gmplsTunnelHopExpLabel,
       gmplsTunnelHopExpLabelPtr,
       gmplsTunnelHopExpRvrsLabel,
       gmplsTunnelHopExpRvrsLabelPtr
     }

     STATUS  current
     DESCRIPTION
       "Objects needed to implement signaled tunnels."
   ::= { gmplsTeGroups 3 }

   gmplsTunnelScalarGroup OBJECT-GROUP
     OBJECTS {
       gmplsTunnelsConfigured,
       gmplsTunnelsActive
     }
     STATUS  current
     DESCRIPTION
       "Scalar objects needed to implement MPLS tunnels."
   ::= { gmplsTeGroups 4 }

   gmplsTunnelIsIntfcGroup OBJECT-GROUP
     OBJECTS {
       gmplsTunnelUnnumIf
     }
     STATUS  current
     DESCRIPTION
       "Objects needed to implement tunnels that are
        interfaces."
   ::= { gmplsTeGroups 5 }

   gmplsTunnelIsNotIntfcGroup OBJECT-GROUP
     OBJECTS {
       gmplsTunnelUnnumIf
     }
     STATUS  current
     DESCRIPTION
       "Objects needed to implement tunnels that are not
        interfaces."
   ::= { gmplsTeGroups 6 }
   gmplsTunnelOptionalGroup OBJECT-GROUP
     OBJECTS {
       gmplsTunnelExtraParamsPtr,
       gmplsTunnelARHopLabelStatuses,
       gmplsTunnelARHopExplicitLabel,
       gmplsTunnelARHopExpLabel,
       gmplsTunnelARHopExpLabelPtr,
       gmplsTunnelARHopExpRvrsLabel,
       gmplsTunnelARHopExpRvrsLabelPtr,
       gmplsTunnelARHopProtection,
       gmplsTunnelCHopLabelStatuses,
       gmplsTunnelCHopExplicitLabel,
       gmplsTunnelCHopExpRvrsLabel
       gmplsTunnelCHopExpLabel,
       gmplsTunnelCHopExpLabelPtr,
       gmplsTunnelCHopExpRvrsLabel,
       gmplsTunnelCHopExpRvrsLabelPtr
     }
     STATUS  current
     DESCRIPTION
       "The objects in this group are optional."
   ::= { gmplsTeGroups 7 }

   gmplsTeNotificationGroup NOTIFICATION-GROUP
     NOTIFICATIONS {
        gmplsTunnelDown
     }
     STATUS  current
     DESCRIPTION
       "Set of notifications implemented in this module.
        None is mandatory."
   ::= { gmplsTeGroups 8 }

   END

9. Security Considerations

   It is clear that the MIB modules described in this document in
   association with the MPLS-TE-STD-MIB are potentially useful for
   monitoring of MPLS and GMPLS tunnels. These MIB modules can also be
   used for configuration of certain objects, and anything that can be
   configured can be incorrectly configured, with potentially disastrous
   results.

   There are a number of management objects defined in these MIB modules
   with 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. These are the tables and objects and their
   sensitivity/vulnerability:

   o  the gmplsTunnelTable and gmplsTunnelHopTable collectively contain
      objects to provision GMPLS tunnels interfaces at their ingress
      LSRs. Unauthorized write access to objects in these tables, could
      result in disruption of traffic on the network. This is especially
      true if a tunnel has already been established. The use of stronger
      mechanisms such as SNMPv3 security should be considered where
      possible. Specifically, SNMPv3 VACM and USM MUST be used with any
      SNMPv3 agent which implements these MIB modules.

   Some of the readable objects in these MIB modules "i.e., objects with
   a MAX-ACCESS other than not-accessible" may be considered sensitive
   or vulnerable in some network environments. It is thus important to
   control even GET and/or NOTIFY access to these objects and possibly
   to even encrypt the values of these objects when sending them over
   the network via SNMP. These are the tables and objects and their
   sensitivity/vulnerability:

   o  the gmplsTunnelTable, gmplsTunnelHopTable, gmplsTunnelARHopTable,
      gmplsTunnelCHopTable, gmplsTunnelReversePerfTable,
      gmplsTunnelErrorTable collectively show the tunnel network
      topology and status. If an Administrator does not want to reveal
      this information, then these tables should be considered
      sensitive/vulnerable.

   SNMP versions prior to SNMPv3 did not include adequate security. 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
   these MIB modules. It is RECOMMENDED that implementers consider the
   security features as provided by the SNMPv3 framework "see [RFC3410],
   section 8", including full support for the SNMPv3 cryptographic
   mechanisms "for authentication and privacy".

   Further, deployment of SNMP versions prior to SNMPv3 is NOT
   RECOMMENDED. Instead, it is RECOMMENDED to deploy SNMPv3 and to
   enable cryptographic security.  It is then a customer/operator
   responsibility to ensure that the SNMP entity giving access to an
   instance of this MIB module, 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.

10. Acknowledgments

   This draft extends [TEMIB]. The authors would like to express their
   gratitude to all those who worked on that earlier MIB document.
   Thanks also to Tony Zinicola and Jeremy Crossen for their valuable
   contributions during an early implementation, and to Baktha
   Muralidharan for his review.

   Special thanks to Joan Cucchiara and Len Nieman for their help with
   compilation issues.

11. References

11.1. Normative References

   [RFC2119]        Bradner, S., "Key words for use in RFCs to Indicate
                    Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC2578]        McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                    Case, J., Rose, M., and S. Waldbusser, "Structure
                    of Management Information Version 2 (SMIv2)", STD
                    58, RFC 2578, April 1999.

   [RFC2579]        McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                    Case, J., Rose, M., and S. Waldbusser, "Textual
                    Conventions for SMIv2", STD 58, RFC 2579, April
                    1999.

   [RFC2580]        McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                    Case, J., Rose, M., and S. Waldbusser, "Conformance
                    Statements for SMIv2", STD 58, RFC 2580, April
                    1999.

   [RFC3031]        Rosen, E., Viswanathan, A., and R. Callon,
                    "Multiprotocol Label Switching Architecture", RFC
                    3031, January 2001.

   [RFC3209]        Awduche, D., Berger, L., Gan, D., Li, T.,
                    Srinivasan, V., and G. Swallow, "RSVP-TE:
                    Extensions to RSVP for LSP Tunnels", RFC 3209,
                    December 2001.

   [RFC3212]        Jamoussi, B., Aboul-Magd, O., Andersson, L.,
                    Ashwood-Smith, P., Hellstrand, F., Sundell, K.,
                    Callon, R., Dantu, R., Wu, L., Doolan, P., Worster,
                    T., Feldman, N., Fredette, A., Girish, M., Gray,
                    E., Halpern, J., Heinanen, J., Kilty, T., Malis,
                    A., and P. Vaananen, "Constraint-Based LSP Setup
                    using LDP", RFC 3212, December 2001."

   [RFC3471]        Berger, L. (Editor), "Generalized Multi-Protocol
                    Label Switching (GMPLS) Signaling Functional
                    Description", RFC 3471, January 2003.

   [RFC3472]        Ashwood-Smith, P., Berger, L. (Editors),
                    "Generalized MPLS Signaling - CR-LDP Extensions",
                    RFC 3472, January 2003.

   [RFC3473]        Berger, L. (Editor), "Generalized MPLS Signaling -
                    RSVP-TE Extensions", RFC 3473, January 2003.

   [RFC3477]        Kompella, K. and Rekhter, Y., "Signalling Unnumbered
                    Links in RSVP-TE", RFC 3477, January 2003.

   [RFC3480]        Kompella, K., Rekhter, Y. and Kullberg, A.,
                    "Signalling Unnumbered Links in CR-LDP", RFC 3480,
                    February 2003.

   [GMPLSArch]      Mannie, E. (Editor), "Generalized Multiprotocol
                    Label Switching (GMPLS) Architecture", Internet
                    Draft <draft-many-gmpls-architecture-07.txt>, May
                    2003, work in progress.

   [GMPLSLSRMIB]    Nadeau, T., Srinivasan, C., A., Farrel, A., Hall,
                    T., and Harrison, E., "Generalized Multiprotocol
                    Label Switching (GMPLS) Label Switching Router
                    (LSR) Management Information Base", draft-ietf-
                    ccamp-gmpls-lsr-mib-03.txt, November 2003, work in
                    progress.

   [GMPLSOSPF]      Kompella, K., et al., "OSPF Extensions in Support
                    of Generalized MPLS", draft-ietf-ccamp-ospf-gmpls-
                    extensions-11.txt, October 2002, work in progress.

   [GMPLSTCMIB]     Nadeau, T., Srinivasan, C., Farrel, A., Hall, T.,
                    and Harrison, E., "Definitions of Textual
                    Conventions for Multiprotocol Label Switching
                    (MPLS) Management", draft-ietf-ccamp-gmpls-te-mib-
                    03.txt, November 2003, work in progress.

   [LSRMIB]         Srinivasan, C., Viswanathan, A. and T. Nadeau,
                    "Multiprotocol Label Switching (MPLS) Label
                    Switching Router (LSR) Management Information
                    Base", Internet Draft <draft-ietf-mpls-lsr-mib-
                    12.txt>, August 2003, work in progress.

   [TCMIB]          Nadeau, T., Cucchiara, J. (Editors) "Definitions of
                    Textual Conventions for Multiprotocol Label
                    Switching (MPLS) Management", Internet Draft
                    <draft-ietf-mpls-tc-mib-09.txt>, August 2003, work
                    in progress.

   [TEMIB]          Nadeau, T., Srinivasan, C, Viswanathan, A.,
                    "Multiprotocol Label Switching (MPLS) Traffic
                    Engineering Management Information Base", Internet
                    Draft <draft-ietf-mpls-te-mib-12.txt>, August 2003,
                    work in progress.

11.2. Informational References

   [RFC2026]        S. Bradner, "The Internet Standards Process --
                    Revision 3", RFC 2026, October 1996.

   [RFC3413]        Levi, D., Meyer, P., Stewart, B., "SNMP
                    Applications", RFC 3413, December 2002.

   [RFC3410]        Case, J., Mundy, R., Partain, D. and B. Stewart,
                    "Introduction and Applicability Statements for
                    Internet-Standard Management Framework", RFC 3410,
                    December 2002.

   [RFC3411]        Harrington, D., Presuhn, R., and B. Wijnen, "An
                    Architecture for Describing Simple Network
                    Management Protocol (SNMP) Management Frameworks",
                    RFC 3411, December 2002.

12. Authors' Addresses

   Thomas D. Nadeau
   Cisco Systems, Inc.
   300 Apollo Drive
   Chelmsford, MA 01824
   Phone: +1-978-244-3051
   Email: tnadeau@cisco.com

   Cheenu Srinivasan
   Bloomberg L.P.
   499 Park Ave.,
   New York, NY 10022
   Phone: +1-212-893-3682
   Email: cheenu@bloomberg.net

   Adrian Farrel
   Old Dog Consulting
   Phone: +44-(0)-1978-860944
   Email: adrian@olddog.co.uk

   Tim Hall
   Data Connection Ltd.
   100 Church Street
   Enfield, Middlesex
   EN2 6BQ, UK
   Phone: +44 20 8366 1177
   Email: timhall@dataconnection.com

   Ed Harrison
   Data Connection Ltd.
   100 Church Street
   Enfield, Middlesex
   EN2 6BQ, UK
   Phone: +44 20 8366 1177
   Email: ed.harrison@dataconnection.com

13. Full Copyright Statement

   Copyright (C) The Internet Society (2003). All Rights Reserved.
   This document and translations of it may be copied and furnished to
   others, and derivative works that comment on or otherwise explain it
   or assist in its implementation may be prepared, copied, published
   and distributed, in whole or in part, without restriction of any
   kind, provided that the above copyright notice and this paragraph are
   included on all such copies and derivative works.  However, this
   document itself may not be modified in any way, such as by removing
   the copyright notice or references to the Internet Society or other
   Internet organizations, except as needed for the purpose of
   developing Internet standards in which case the procedures for
   copyrights defined in the Internet Standards process must be
   followed, or as required to translate it into languages other than
   English.

   The limited permissions granted above are perpetual and will not be
   revoked by the Internet Society or its successors or assigns. This
   document and the information contained herein is provided on an "AS
   IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK
   FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT
   LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL
   NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY
   OR FITNESS FOR A PARTICULAR PURPOSE.

14. Intellectual Property Notice

   The IETF takes no position regarding the validity or scope of any
   intellectual property or other rights that might be claimed to
   pertain to the implementation or use of the technology described in
   this document or the extent to which any license under such rights
   might or might not be available; neither does it represent that it
   has made any effort to identify any such rights.  Information on the
   IETF's procedures with respect to rights in standards-track and
   standards-related documentation can be found in BCP-11 [RFC2028].
   Copies of claims of rights made available for publication and any
   assurances of licenses to be made available, or the result of an
   attempt made to obtain a general license or permission for the use
   of such proprietary rights by implementers or users of this
   specification can be obtained from the IETF Secretariat.

   The IETF invites any interested party to bring to its attention any
   copyrights, patents or patent applications, or other proprietary
   rights that may cover technology that may be required to practice
   this standard.  Please address the information to the IETF Executive
   Director.

15. Changes and Pending Work

   This section to be removed before the draft progresses to RFC.

15.1. Pending Work

   The following work items have been identified for this draft.  They
   will be addressed in a future version.

   - Expand conformance statements to give one for monitoring only,
     and one for monitoring and control.
   - Consider a way to expose tunnel head, tunnel tail, and tunnel
     transit entries through distinct indexing or tables.
   - Provide support for configuring tunnel resources in GMPLS
     systems. For example, SONET/SDH or G.709.  This might be done
     through an arbitrary RowPointer to an external MIB.
   - Crankback request and reported information.
   - Add support for IF_ID control and error reporting.
   - Add LSR or interface config for Hellos and restart options.
   - Update enumerated types in line with latest GMPLS drafts. Examine
     how these can be managed by IANA.
   - Resolve ownership of enumerated types that are also defined in
     GMPLS or routing drafts.  These could be owned by IANA, imported
     from another MIB, or manually kept in step here.  If they are not
     maintained externally then they are likely to diverge and MIB
     implementations will need to provide mappings.
   - Update MIB description in section 5.

15.2. Changes from version 2 to version 3

   - Work on basic compilation issues.
   - Resolve defaults for objects with syntax BITS.
   - Update references.
   - Clarify which objects can be modified when rowStatus and
     adminStatus are set to active.
   - Control and reporting of upstream and downstream Notify
     Recipients.
   - Add support for control and reporting of GMPLS Administrative
     Status object.
   - Update examples.

Network Working Group                                   Thomas D. Nadeau
Internet Draft                                       Cisco Systems, Inc.
Expires: May 2004
                                                       Cheenu Srinivasan
                                                          Bloomberg L.P.

                                                           Adrian Farrel
                                                      Old Dog Consulting

                                                                Tim Hall
                                                             Ed Harrison
                                                    Data Connection Ltd.

                                                           November 2003

         Generalized Multiprotocol Label Switching (GMPLS)
      Label Switching Router (LSR) Management Information Base

              draft-ietf-ccamp-gmpls-lsr-mib-03.txt

Status of this Memo

   This document is an Internet-Draft and is in full conformance with
   all provisions of Section 10 of RFC 2026.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF), its areas, and its working groups.  Note that
   other groups may also distribute working documents as Internet-
   Drafts.

   Internet-Drafts are draft documents valid for a maximum of six
   months and may be updated, replaced, or obsoleted by other documents
   at any time.  It is inappropriate to use Internet-Drafts as
   reference material or to cite them other than as "work in progress."

   The list of current Internet-Drafts can be accessed at
   http://www.ietf.org/ietf/1id-abstracts.txt.

Abstract

   This memo defines a portion of the Management Information Base (MIB)
   for use with network management protocols in the Internet community.
   In particular, it describes managed objects to configure and/or
   monitor a Generalized Multiprotocol Label Switching (GMPLS) Label
   Switching Router (LSRs).

Table of Contents

   1. Introduction                                       2
   1.1. Migration Strategy                               2
   2. Terminology                                        3
   3. The SNMP Management Framework                      3
   4. Outline                                            3
   4.1. Summary of the GMPLS LSR MIB Module              4
   5. Bidirectional LSPs                                 4
   6. Example of LSP Setup                               5
   7. GMPLS Label Switching Router MIB Definitions       6
   8. GMPLS Label MIB Definitions                       14
   9. Security Considerations                           25
   10. Acknowledgments                                  26
   11. IANA Considerations                              27
   11.1. IANA Considerations for GMPLS-LSR-STD-MIB      27
   11.2. IANA Considerations FOR GMPLS-LABEL-STD-MIB    27
   12. References                                       27
   12.1. Normative References                           27
   12.2. Informational References                       28
   13. Authors' Addresses                               29
   14. Full Copyright Statement                         30
   15. Intellectual Property Notice                     30
   16. Changes and Pending Work                         31
   16.1. Pending Work                                   31

1. Introduction

   This memo defines a portion of the Management Information Base (MIB)
   for use with network management protocols in the Internet community.
   In particular, it describes managed objects for modeling a
   Generalized Multiprotocol Label Switching (GMPLS) [GMPLSArch] Label
   Switching Router (LSR).

   Comments should be made directly to the CCAMP mailing list at
   ccamp@ops.ietf.org.

   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, reference
   [RFC2119].

1.1. Migration Strategy

   This MIB module extends the Label Switching Router MIB module defined
   for use with MPLS [LSRMIB].  The only changes made are additions for
   support of GMPLS or changes that are necessary to support the
   increased complexity of a GMPLS system.

   The companion document modeling and managing GMPLS based traffic
   engineering [GMPLSTEMIB] extends the MPLS TE MIB module [TEMIB] with
   the same intentions.

   Textual conventions and OBJECT-IDENTIFIERS are defined in
   [GMPLSTCMIB] which extends the set of textual conventions originally
   defined in [TCMIB].

2. Terminology

   This document uses terminology from the document describing the MPLS
   architecture [RFC3031] and the GMPLS architecture [GMPLSArch].

   A label switched path (LSP) is modeled as a connection consisting of
   one or more incoming segments (in-segments) and/or one or more
   outgoing segments (out-segments) at an LSR. The association or
   interconnection of the in-segments and out-segments is accomplished
   by using a cross-connect. We use the terminology "connection" and
   "LSP" interchangeably where the meaning is clear from the context.

      in-segment     This is analogous to a GMPLS label on an interface.
      out-segment    This is analogous to a GMPLS label on an interface.
      cross-connect  This describes the conceptual connection between a
                     set of in-segments and out-segments.
                     Note that either set may be 0; that is, a cross-
                     connect may connect only out-segments together with
                     no in-segments in the case where an LSP is
                     originating on an LSR.

3. The SNMP 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 [RFC3410].

   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 [RFC2578], STD 58, RFC 2579 [RFC2579] and STD 58, RFC
   2580 [RFC2580].

4. Outline

   Configuring statically provisioned GMPLS LSPs through an LSR involves
   the following steps:

   -  Configuring an interface using the MPLS LSR MIB module.

   -  Enabling GMPLS on GMPLS capable interfaces using this MIB module.

   -  Configuring in-segments and out-segments using the MPLS LSR MIB
      module.

   -  Configuring GMPLS extensions to the in-segments and out-segments
      using this MIB module.

   -  Setting up the cross-connect table in the MPLS LSR MIB module to
      associate segments and/or to indicate connection origination and
      termination.

   -  Optionally setting up labels in the label table in this MIB module
      if the textual convention
      MplsLabel is not capable of holding the required label (for
      example, if the label requires more than 32 bits to encode it), or
      if the operator wishes to disambiguate GMPLS label types.

   -  Optionally specifying label stack actions in the MPLS LSR MIB
      module.

   -  Optionally specifying segment traffic parameters in the MPLS LSR
      MIB module.

4.1. Summary of the GMPLS LSR MIB Module

   The MIB tables in this MIB module are as follows.

   -  The interface configuration table (gmplsInterfaceTable), which
      extends mplsInterfaceTable to enable the GMPLS protocol on MPLS-
      capable interfaces.

   -  The in-segment (gmplsInSegmentTable) and out-segment
      (gmplsOutSegmentTable) tables extend mplsInSegmentTable and
      mplsOutSegmentTable to configuring GMPLS-specific parameters for
      LSP segments at an LSR.

   -  The gmplsLabelTable extends mplsLabelTable and allows Generalized
      Labels to be defined and managed in a central location.
      Generalized Labels can be of variable length and have distinct
      bit-by-bit interpretations according to the use that is made of
      them.

   These tables are described in the subsequent sections.

5. Bidirectional LSPs

   This MIB supports bidirectional LSPs as required for GMPLS.
   A single value of mplsXCIndex is shared by all of the segments for
   the entire bidirectional LSP. This facilitates a simple reference
   from [TEMIB] and [GMPLSTEMIB], and makes fate-sharing more obvious.

   It is, however, important that the direction of segments is
   understood to avoid connecting all in-segments to all out-segments.
   This is achieved by an object in each segment that indicates the
   direction of the segment with respect to data flow.

   A segment that is marked as 'forward' carries data from the 'head' of
   the LSP to the 'tail'. A segment marked as 'reverse' carries data in
   the reverse direction.

   Where an LSP is signaled using a conventional signaling protocol, the
   'head' of the LSP is the source of the signaling (also known as the
   ingress) and the 'tail' is the destination (also known as the
   egress). For manually configured LSPs an arbitrary decision must be
   made about which segments are 'forward' and which 'reverse'. For
   consistency this decision should be made across all LSRs that
   participate in the LSP by assigning 'head' and 'tail' ends to the
   LSP.

6. Example of LSP Setup

   In this section we provide a brief example of using the MIB objects
   described in section 9 to set up an LSP. While this example is not
   meant to illustrate every nuance of the MIB, it is intended as an aid
   to understanding some of the key concepts. It is meant to be read
   after going through the MIB itself. A prerequisite is an
   understanding of [LSRMIB].

   Suppose that one would like to manually create a best-effort, bi-
   directional LSP. Assume that, in the forward direction, the LSP
   enters the LSR via MPLS interface A with ifIndex 12 and exits the LSR
   via MPLS interface B with ifIndex 13. For the reverse direction, we
   assume the LSP enters via interface B and leaves via interface A
   (i.e. the forward and reverse directions use the same bi-directional
   interfaces). Let us also assume that we do not wish to have a label
   stack beneath the top label on the outgoing labeled packets. The
   following example illustrates which rows and corresponding objects
   might be created to accomplish this.

   We must first create rows in the gmplsLabelTable corresponding to the
   labels required for each of the forward and reverse direction in- and out-
   segments.  For the purpose of this example the forward and reverse labels
   on each interface will be the same, hence we need to create just two
   rows in the gmplsLabelTable - one for each interface.

   In gmplsLabelTable:
   {
     gmplsLabelInterface              = 12,
     gmplsLabelIndex                  = 1,
     gmplsLabelSubindex               = 1,
     gmplsLabelType                   = gmplsFreeformGeneralizedLabel(3),
     gmplsLabelMplsLabel              = 0,
     gmplsLabelPortWavelength         = 0,
     gmplsLabelFreeformLength         = 8,
     gmplsLabelFreeform               = 0x123456789ABCDEF0
     gmplsLabelSonetSdhSignalIndex    = 0,
     gmplsLabelSdhVc                  = 0,
     gmplsLabelSdhVcBranch            = 0,
     gmplsLabelSonetSdhBranch         = 0,
     gmplsLabelSonetSdhGroupBranch    = 0,
     gmplsLabelWavebandId             = 0,
     gmplsLabelWavebandStartLabel     = 0,
     gmplsLabelWavebandEndLabel       = 0,
     gmplsLabelRowStatus              = createAndGo(4),
     gmplsLabelStorageType            = 0
   }
   In gmplsLabelTable:
   {
     gmplsLabelInterface              = 13,
     gmplsLabelIndex                  = 1,
     gmplsLabelSubindex               = 1,
     gmplsLabelType                   = gmplsFreeformGeneralizedLabel(3),
     gmplsLabelMplsLabel              = 0,
     gmplsLabelPortWavelength         = 0,
     gmplsLabelFreeformLength         = 8,
     gmplsLabelFreeform               = 0xFEDCBA9876543210
     gmplsLabelSonetSdhSignalIndex    = 0,
     gmplsLabelSdhVc                  = 0,
     gmplsLabelSdhVcBranch            = 0,
     gmplsLabelSonetSdhBranch         = 0,
     gmplsLabelSonetSdhGroupBranch    = 0,
     gmplsLabelWavebandId             = 0,
     gmplsLabelWavebandStartLabel     = 0,
     gmplsLabelWavebandEndLabel       = 0,
     gmplsLabelRowStatus              = createAndGo(4),
     gmplsLabelStorageType            = 0
   }

   We must next create the appropriate in-segment and out-segment entries.
   These are done in [LSRMIB] using the mplsInSegmentTable and
   mplsOutSegmentTable.  Note that we use a row pointer to the two rows in the
   gmplsLableTable rather than specifying the labels explicitly in the
   in- and out-segment tables.  Also note that the row status for each row
   is set to createAndWait(5) to allow corresponding entries in the
   gmplsInSegmentTable and gmplsOutSegmentTable to be created.

   For the forward direction.

   In mplsInSegmentTable:
   {
      mplsInSegmentIndex              = 0x00000015
      mplsInSegmentLabel              = 0, -- incoming label in label table
      mplsInSegmentNPop               = 1,
      mplsInSegmentInterface          = 12, -- incoming interface

      -- RowPointer MUST point to the first accesible column.
      mplsInSegmentLabelPtr           = gmplsLabelInterface.1,
      mplsInSegmentTrafficParamPtr    = 0.0,
      mplsInSegmentRowStatus          = createAndWait(5)
   }

   In mplsOutSegmentTable:
   {
      mplsOutSegmentIndex             = 0x00000012,
      mplsOutSegmentInterface         = 13, -- outgoing interface
      mplsOutSegmentPushTopLabel      = true(1),
      mplsOutSegmentTopLabel          = 0, -- outgoing label in label table

      -- RowPointer MUST point to the first accesible column.
      mplsOutSegmentTrafficParamPtr   = 0.0,
      mplsOutSegmentLabelPtr          = gmplsLabelInterface.2,
      mplsOutSegmentRowStatus         = createAndWait(5)
   }
   For the reverse direction.

   In mplsInSegmentTable:
   {
      mplsInSegmentIndex              = 0x00000016

      mplsInSegmentLabel              = 0, -- incoming label in label table
      mplsInSegmentNPop               = 1,
      mplsInSegmentInterface          = 13, -- incoming interface

      -- RowPointer MUST point to the first accesible column.
      mplsInSegmentLabelPtr           = gmplsLabelInterface.2,
      mplsInSegmentTrafficParamPtr    = 0.0,

      mplsInSegmentRowStatus          = createAndWait(5)
   }

   In mplsOutSegmentTable:
   {
      mplsOutSegmentIndex             = 0x00000013,
      mplsOutSegmentInterface         = 12, -- outgoing interface
      mplsOutSegmentPushTopLabel      = true(1),
      mplsOutSegmentTopLabel          = 0, -- outgoing label in label table

      -- RowPointer MUST point to the first accesible column.
      mplsOutSegmentTrafficParamPtr   = 0.0,
      mplsOutSegmentLabelPtr          = gmplsLabelInterface.1,

      mplsOutSegmentRowStatus         = createAndWait(5)
   }

   These table entries are extended by entries in gmplsInSegmentTable
   and gmplsOutSegmentTable. Note that the nature of the 'extends'
   relationship is that the entry in gmplsInSegmentTable has the same
   index values as the entry in mplsInSegmentTable. Similarly, the entry
   in gmplsOutSegmentTable has the same index values as the entry in
   mplsOutSegmentTable.

   First for the forward direction:

   In gmplsInSegmentTable(0x00000015)
   {
     gmplsInSegmentDirection          = forward (1)
   }
   In gmplsOutSegmentTable(0x00000012)
   {
     gmplsOutSegmentDirection         = forward (1),
     gmplsOutSegmentTTLDecrement      = 1
   }

   Next for the reverse direction:

   In gmplsInSegmentTable(0x00000016)
   {
     gmplsInSegmentDirection          = reverse (2)
   }
   In gmplsOutSegmentTable(0x00000013)
   {
     gmplsOutSegmentDirection         = reverse (2),
     gmplsOutSegmentTTLDecrement      = 1
   }

   Next, two cross-connect entries are created in the mplsXCTable of the
   MPLS LSR MIB, thereby associating the newly created segments
   together.

   In mplsXCTable:
   {
      mplsXCIndex                = 0x01,
      mplsXCInSegmentIndex       = 0x00000015,
      mplsXCOutSegmentIndex      = 0x00000012,

      mplsXCLspId                = 0x0102 -- unique ID
      mplsXCLabelStackIndex      = 0x00, -- only a single
                                         -- outgoing label
      mplsXCRowStatus            = createAndGo(4)
   }

   In mplsXCTable:
   {
      mplsXCIndex                = 0x02,
      mplsXCInSegmentIndex       = 0x00000016,
      mplsXCOutSegmentIndex      = 0x00000013,

      mplsXCLspId                = 0x0102 -- unique ID
      mplsXCLabelStackIndex      = 0x00, -- only a single
                                         -- outgoing label
      mplsXCRowStatus            = createAndGo(4)
   }

   Finally, the in-segments and out-segments are activated.

   In mplsInSegmentTable(0x00000015):
   {
      mplsInSegmentRowStatus          = active(1)
   }

   In mplsInSegmentTable(0x00000016):
   {
      mplsInSegmentRowStatus          = active(1)
   }

   In mplsOutSegmentTable(0x00000012):
   {
      mplsOutSegmentRowStatus         = active(1)
   }

   In mplsOutSegmentTable(0x00000013):
   {
      mplsOutSegmentRowStatus         = active(1)
   }

7. GMPLS Label Switching Router MIB Definitions

   GMPLS-LSR-STD-MIB DEFINITIONS ::= BEGIN

   IMPORTS
     MODULE-IDENTITY, OBJECT-TYPE, Unsigned32
       FROM SNMPv2-SMI
     MODULE-COMPLIANCE, OBJECT-GROUP
       FROM SNMPv2-CONF
     GmplsSegmentDirection, gmplsStdMIB
       FROM GMPLS-TC-STD-MIB
     mplsInterfaceIndex, mplsInSegmentIndex, mplsOutSegmentIndex
       FROM MPLS-LSR-STD-MIB
   ;

   gmplsLsrStdMIB MODULE-IDENTITY
     LAST-UPDATED
       "200310300900Z" -- 30 October 2003 9:00:00 GMT"
     ORGANIZATION
       "Common Control And Management Protocols (CCAMP)
        Working Group"
     CONTACT-INFO
       "       Thomas D. Nadeau
               Cisco Systems, Inc.
        Email: tnadeau@cisco.com

               Cheenu Srinivasan
               Bloomberg L.P.
        Email: cheenu@bloomberg.net

               Adrian Farrel
               Old Dog Consulting
        Email: adrian@olddog.co.uk

               Ed Harrison
               Data Connection Ltd.
        Email: ed.harrison@dataconnection.com

               Tim Hall
               Data Connection Ltd.
        Email: timhall@dataconnection.com

        Comments about this document should be emailed direct to the
        CCAMP working group mailing list at ccamp@ops.ietf.org"
     DESCRIPTION
       "This MIB module contains managed object definitions
        for the Generalized Multiprotocol Label Switching
        (GMPLS) Router as defined in: Ashwood-Smith et al.,
        Generalized Multiprotocol Label Switching (GMPLS)
        Architecture, Internet Draft <draft-many-gmpls-
        architecture-01.txt>, March 2001, work in progress.

        Copyright (C) The Internet Society (2003).  This
        version of this MIB module is part of RFCXXX; see
        the RFC itself for full legal notices."
     -- Revision history.
     REVISION
       "200310300900Z" -- 30 October 2003 09:00:00 GMT

     DESCRIPTION
       "Initial revision, published as part of RFC XXXX."
   ::= { gmplsStdMIB xx }

   -- Top level components of this MIB module.

   -- Notifications
   -- no notifications are currently defined.
   gmplsLsrNotifications OBJECT IDENTIFIER ::= { gmplsLsrStdMIB 0 }

   -- Tables, Scalars
   gmplsLsrObjects       OBJECT IDENTIFIER ::= { gmplsLsrStdMIB 1 }

   -- Conformance
   gmplsLsrConformance   OBJECT IDENTIFIER ::= { gmplsLsrStdMIB 2 }

   -- GMPLS Interface Table.

   gmplsInterfaceTable OBJECT-TYPE
     SYNTAX        SEQUENCE OF GmplsInterfaceEntry
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "This table specifies per-interface GMPLS capability
        and associated information. It extends the
        information in mplsInterfaceTable."
     ::= { gmplsLsrObjects 1 }

   gmplsInterfaceEntry OBJECT-TYPE
     SYNTAX        GmplsInterfaceEntry
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "A conceptual row in this table is created
        automatically by an LSR for every interface capable
        of supporting GMPLS and which is configured to do
        so. A conceptual row in this table will exist if and
        only if a corresponding entry in mplsInterfaceTable
        exists, and a corresponding entry in ifTable exists
        with ifType = mpls(166). If the associated entry in
        ifTable is operationally disabled (thus removing the
        GMPLS capabilities on the interface) or the entry in
        mplsInterfaceTable is deleted, the corresponding
        entry in this table MUST be deleted shortly
        thereafter.

        The indexing is the same as that for mplsInterfaceTable.
        Thus, the entry with index 0 represents the per-platform
        label space and contains parameters that apply to all
        interfaces that participate in the per-platform label space."
     INDEX { mplsInterfaceIndex }
   ::= { gmplsInterfaceTable 1 }
   GmplsInterfaceEntry ::= SEQUENCE {
     gmplsInterfaceSignalingCaps      BITS
   }

   gmplsInterfaceSignalingCaps OBJECT-TYPE
     SYNTAX  BITS {
       unknown (0),
       rsvpGmpls (1),
       crldpGmpls (2), -- note the use of CR-LDP is deprecated
       otherGmpls (3)
     }
     MAX-ACCESS   read-create
     STATUS       current
     DESCRIPTION
       "Defines the signaling capabilities on this
        interface. Multiple bits may legitimately be set at
        once. Setting no bits implies that GMPLS signaling
        cannot be performed on this interface and all LSPs
        must be manually provisioned."
   ::= { gmplsInterfaceEntry 1 }

   -- End of gmplsInterfaceTable

   -- In-segment table.

   gmplsInSegmentTable  OBJECT-TYPE
     SYNTAX        SEQUENCE OF GmplsInSegmentEntry
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "This table extends the mplsInSegmentTable to provide
        GMPLS-specific information about incoming segments
        to an LSR."
   ::= { gmplsLsrObjects 2 }

   gmplsInSegmentEntry  OBJECT-TYPE
     SYNTAX        GmplsInSegmentEntry
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "An entry in this table extends the representation of
        an incoming segment represented by an entry in
        mplsInSegmentTable. An entry can be created by a
        network administrator or an SNMP agent, or a GMPLS
        signaling protocol.

        Note that the storage type for this entry SHOULD be
        inherited from the corresponding entry in the
        mplsInSegmentTable given by the value of the
        mplsInSegmentStorageType object."
     INDEX { mplsInSegmentIndex }
   ::= { gmplsInSegmentTable 1 }

   GmplsInSegmentEntry ::= SEQUENCE {
     gmplsInSegmentDirection   GmplsSegmentDirection
   }
   gmplsInSegmentDirection OBJECT-TYPE
     SYNTAX        GmplsSegmentDirection
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "This object indicates the direction of data flow on
        this segment. This object cannot be modified if
        mplsInSegmentRowStatus for the associated entry in
        the mplsInSegmentTable is active(1)."
     DEFVAL        { forward }
   ::= { gmplsInSegmentEntry 1 }

   -- End of gmplsInSegmentTable

   -- Out-segment table.

   gmplsOutSegmentTable  OBJECT-TYPE
     SYNTAX        SEQUENCE OF GmplsOutSegmentEntry
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "This table extends the mplsOutSegmentTable to
        provide GMPLS-specific information about outgoing
        segments from an LSR."
   ::= { gmplsLsrObjects 3 }

   gmplsOutSegmentEntry  OBJECT-TYPE
     SYNTAX        GmplsOutSegmentEntry
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "An entry in this table extends the representation of
        an outgoing segment represented by an entry in
        mplsOutSegmentTable. An entry can be created by a
        network administrator or an SNMP agent, or a GMPLS
        signaling protocol.
        Note that the storage type for this entry SHOULD be
        inherited from the corresponding entry in the
        mplsOutSegmentTable given by the value of the
        mplsOutSegmentStorageType object."
     INDEX  { mplsOutSegmentIndex }
   ::= { gmplsOutSegmentTable 1 }

   GmplsOutSegmentEntry ::= SEQUENCE {
     gmplsOutSegmentDirection     GmplsSegmentDirection,
     gmplsOutSegmentTTLDecrement  Unsigned32
   }

   gmplsOutSegmentDirection OBJECT-TYPE
     SYNTAX        GmplsSegmentDirection
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "This object indicates the direction of data flow on
        this segment. This object cannot be modified if
        mplsOutSegmentRowStatus for the associated entry in
        the mplsOutSegmentTable is active(1)."
     DEFVAL  { forward }
   ::= { gmplsOutSegmentEntry 1 }

   gmplsOutSegmentTTLDecrement OBJECT-TYPE
     SYNTAX        Unsigned32 (0..255)
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "This object indicates the amount by which to
        decrement the TTL of any payload packets forwarded
        on this segment if per-hop decrementing is being
        done.

        A value of zero indicates that no decrement should
        be made or that per-hop decrementing is not in
        force.

        See the gmplsTunnelTTLDecrement object in the
        gmplsTunnelTable of [GMPLSTEMIB] for a value by
        which to decrement the TTL for the whole of a
        tunnel.

        This object cannot be modified if
        mplsOutSegmentRowStatus for the associated entry in
        the mplsOutSegmentTable is active(1)."
     DEFVAL  { 0 }
   ::= { gmplsOutSegmentEntry 2 }

   -- End of gmplsOutSegmentTable

   -- Module compliance.

   gmplsLsrGroups
     OBJECT IDENTIFIER ::= { gmplsLsrConformance 1 }

   gmplsLsrCompliances
     OBJECT IDENTIFIER ::= { gmplsLsrConformance 2 }

   -- Compliance requirement for fully compliant implementations.

   gmplsLsrModuleFullCompliance MODULE-COMPLIANCE
     STATUS current
     DESCRIPTION
       "Compliance statement for agents that provide full
        support for GMPLS-LSR-STD-MIB."

     MODULE IF-MIB -- The Interfaces Group MIB, RFC 2863.

     MANDATORY-GROUPS {
       ifGeneralInformationGroup,
       ifCounterDiscontinuityGroup
     }
     MODULE MPLS-LSR-STD-MIB -- The MPLS LSR MIB

     MANDATORY-GROUPS {
       mplsInterfaceGroup,
       mplsInSegmentGroup,
       mplsOutSegmentGroup,
       mplsXCGroup,
       mplsPerfGroup,
       mplsLsrNotificationGroup
     }

     MODULE -- this module

     MANDATORY-GROUPS    {
       gmplsInterfaceGroup,
       gmplsInSegmentGroup,
       gmplsOutSegmentGroup
     }

     -- gmplsInSegmentTable

     OBJECT      gmplsInSegmentDirection
     SYNTAX      GmplsSegmentDirection
     MIN-ACCESS  read-write
     DESCRIPTION
       "Only forward(1) needs to be supported by
        implementations that only support unidirectional
        LSPs."

     -- gmplsOutSegmentTable

     OBJECT      gmplsOutSegmentDirection
     SYNTAX      GmplsSegmentDirection
     MIN-ACCESS  read-write
     DESCRIPTION
       "Only forward(1) needs to be supported by
        implementations that only support unidirectional
        LSPs."

     OBJECT      gmplsOutSegmentTTLDecrement
     SYNTAX      Unsigned32 (0..255)
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   ::= { gmplsLsrCompliances 1 }

   -- Compliance requirement for implementations that provide read-only
   -- access.

   gmplsLsrModuleReadOnlyCompliance MODULE-COMPLIANCE
     STATUS current
     DESCRIPTION
       "Compliance requirement for implementations that only
        provide read-only support for GMPLS-LSR-STD-MIB. Such
        devices can then be monitored but cannot be configured
        using this MIB modules."
     MODULE IF-MIB -- The interfaces Group MIB, RFC 2863

     MANDATORY-GROUPS {
       ifGeneralInformationGroup,
       ifCounterDiscontinuityGroup
     }

     MODULE MPLS-LSR-STD-MIB

     MANDATORY-GROUPS {
       mplsInterfaceGroup,
       mplsInSegmentGroup,
       mplsOutSegmentGroup,
       mplsXCGroup,
       mplsPerfGroup
     }

     MODULE -- this module

     MANDATORY-GROUPS {
       gmplsInterfaceGroup,
       gmplsInSegmentGroup,
       gmplsOutSegmentGroup
     }

     -- gmplsInterfaceGroup

     OBJECT      gmplsInterfaceSignalingCaps
     SYNTAX  BITS {
       unknown (0),
       rsvpGmpls (1),
       crldpGmpls (2),
       otherGmpls (3)
     }
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     -- gmplsInSegmentTable

     OBJECT      gmplsInSegmentDirection
     SYNTAX      GmplsSegmentDirection
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required. Only forward(1) needs
        to be supported by implementations that only support
        unidirectional LSPs."

     -- gmplsOutSegmentTable

     OBJECT      gmplsOutSegmentDirection
     SYNTAX      GmplsSegmentDirection
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required. Only forward(1) needs
        to be supported by implementations that only support
        unidirectional LSPs."
     OBJECT      gmplsOutSegmentTTLDecrement
     SYNTAX      Unsigned32 (0..255)
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   ::= { gmplsLsrCompliances 2 }

   -- Units of conformance.

   gmplsInterfaceGroup OBJECT-GROUP
     OBJECTS {
       gmplsInterfaceSignalingCaps
     }
     STATUS  current
     DESCRIPTION
       "Collection of objects needed for GMPLS interface
        configuration and performance information."
   ::= { gmplsLsrGroups 1 }

   gmplsInSegmentGroup  OBJECT-GROUP
     OBJECTS {
       gmplsInSegmentDirection
     }
     STATUS  current
     DESCRIPTION
       "Collection of objects needed to implement a GMPLS
        in-segment."
   ::= { gmplsLsrGroups 2 }

   gmplsOutSegmentGroup  OBJECT-GROUP
     OBJECTS {
       gmplsOutSegmentDirection,
       gmplsOutSegmentTTLDecrement
     }
     STATUS  current
     DESCRIPTION
       "Collection of objects needed to implement a GMPLS
        out-segment."
   ::= { gmplsLsrGroups 3 }

   END

8. GMPLS Label MIB Definitions

   GMPLS-LABEL-STD-MIB DEFINITIONS ::= BEGIN

   IMPORTS
     MODULE-IDENTITY, OBJECT-TYPE, Unsigned32,
     Integer32
       FROM SNMPv2-SMI
     MODULE-COMPLIANCE, OBJECT-GROUP
       FROM SNMPv2-CONF
     RowStatus, StorageType
       FROM SNMPv2-TC
     InterfaceIndexOrZero
       FROM IF-MIB
     IndexIntegerNextFree
       FROM DIFFSERV-MIB
     MplsLabel
       FROM MPLS-TC-STD-MIB
     GmplsGeneralizedLabelTypes, GmplsFreeformLabel,
     gmplsStdMIB
       FROM GMPLS-TC-STD-MIB
   ;

   gmplsLabelStdMIB MODULE-IDENTITY
     LAST-UPDATED
       "200310300900Z" -- 30 October 2003 9:00:00 GMT"
     ORGANIZATION
       "Common Control And Management Protocols (CCAMP)
        Working Group"
     CONTACT-INFO
       "       Thomas D. Nadeau
               Cisco Systems, Inc.
        Email: tnadeau@cisco.com

               Cheenu Srinivasan
               Bloomberg L.P.
        Email: cheenu@bloomberg.net

               Adrian Farrel
               Old Dog Consulting
        Email: adrian@olddog.co.uk

               Ed Harrison
               Data Connection Ltd.
        Email: ed.harrison@dataconnection.com

               Tim Hall
               Data Connection Ltd.
        Email: timhall@dataconnection.com

        Comments about this document should be emailed direct to the
        CCAMP working group mailing list at ccamp@ops.ietf.org"
     DESCRIPTION
       "This MIB module contains managed object definitions
        for labels within GMPLS systems."

     -- Revision history.
     REVISION
       "200310300900Z" -- 30 October 2003 09:00:00 GMT
     DESCRIPTION
       "Initial revision, published as part of RFC XXXX."
   ::= { gmplsStdMIB xx }

   -- Top level components of this MIB module.

   -- Notifications
   -- no notifications are currently defined.
   gmplsLabelNotifications   OBJECT IDENTIFIER ::= { gmplsLabelStdMIB 0 }
   -- Tables, Scalars
   gmplsLabelObjects         OBJECT IDENTIFIER ::= { gmplsLabelStdMIB 1 }

   -- Conformance
   gmplsLabelConformance     OBJECT IDENTIFIER ::= { gmplsLabelStdMIB 2 }

   -- GMPLS Label Table.

  gmplsLabelIndexNext OBJECT-TYPE
     SYNTAX        IndexIntegerNextFree
     MAX-ACCESS    read-only
     STATUS        current
     DESCRIPTION
         "This object contains an unused value for
          gmplsLabelIndex, or a zero to indicate
          that no unused value exists or is available.

          An management application wishing to create
          a row in the gmplsLabelTable may read this
          object and then attempt to create a row in
          the table. If row creation fails (because
          another application has already created a row
          with the supplied index) the management
          application should read this object again
          to get a new index value.

          When a row is created in the gmplsLabelTable
          with the gmplsLabelIndex value held by this
          object, an implementation MUST change the value
          in this object.
         "
     ::= { gmplsLabelObjects 1 }

   gmplsLabelTable OBJECT-TYPE
     SYNTAX        SEQUENCE OF GmplsLabelEntry
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "Table of GMPLS Labels.  This table allows the
        representation of the more complex label forms
        required for GMPLS which cannot be held within the
        textual convention MplsLabel. That is labels that
        cannot be encoded within 32 bits. It is,
        nevertheless also capable of holding 32 bit labels
        or regular MPLS labels if desired.

        Each entry in this table represents an individual
        GMPLS label value.  Labels in the tables in other
        MIBs are referred to using row pointer into this
        table. The indexing of this table provides for
        arbitrary indexing and also for concatenation of
        labels."
   ::= { gmplsLabelObjects 2 }
   gmplsLabelEntry OBJECT-TYPE
     SYNTAX        GmplsLabelEntry
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "An entry in this table represents a single label
        value. There are three indexes into the table.
        -  The interface index may be helpful to distinguish
           which labels are in use on which interfaces or to
           handle cases where there are a very large number
           of labels in use in the system. When label
           representation is desired to apply to the whole
           system or when it is not important to distinguish
           labels by their interfaces, this index MAY be set
           to zero.
        -  The label index provides a way of identifying the
           label.
        -  The label sub-index is only used for concatenated
           labels. It identifies each component label. When
           non-concatenated labels are used, this index
           SHOULD be set to zero.

        A storage type object is supplied to control the
        storage type for each entry, but implementations
        should note that the storage type of conceptual rows
        in other tables that include row pointers to an
        entry in this table SHOULD dictate the storage type
        of the rows in this table where the row in the other
        table is more persistent."
     INDEX {
       gmplsLabelInterface,
       gmplsLabelIndex,
       gmplsLabelSubindex }
   ::= { gmplsLabelTable 1 }

   GmplsLabelEntry ::= SEQUENCE {
     gmplsLabelInterface           InterfaceIndexOrZero,
     gmplsLabelIndex               Unsigned32,
     gmplsLabelSubindex            Unsigned32,
     gmplsLabelType                GmplsGeneralizedLabelTypes,
     gmplsLabelMplsLabel           MplsLabel,
     gmplsLabelPortWavelength      Unsigned32,
     gmplsLabelFreeformLength      Integer32,
     gmplsLabelFreeform            GmplsFreeformLabel,
     gmplsLabelSonetSdhSignalIndex Integer32,
     gmplsLabelSdhVc               Integer32,
     gmplsLabelSdhVcBranch         Integer32,
     gmplsLabelSonetSdhBranch      Integer32,
     gmplsLabelSonetSdhGroupBranch Integer32,
     gmplsLabelWavebandId          Unsigned32,
     gmplsLabelWavebandStart       Unsigned32,
     gmplsLabelWavebandEnd         Unsigned32,
     gmplsLabelRowStatus           RowStatus,
     gmplsLabelStorageType         StorageType
   }
   gmplsLabelInterface OBJECT-TYPE
     SYNTAX        InterfaceIndexOrZero
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "The interface on which this label is used. If the
        label has or could have applicability across the
        whole system, this object SHOULD be set to zero."
   ::= { gmplsLabelEntry 1 }

   gmplsLabelIndex OBJECT-TYPE
     SYNTAX        Unsigned32 (0..4294967295)
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "An arbitrary index into the table to identify a
        label.
        Note that implementations that are representing 32
        bit labels within this table MAY choose to align
        this index with the value of the label, but should
        be aware of the implications of sparsely populated
        tables.
        A management application may read the gmplsLabelIndexNext
        object to find a suitable value for this object."
   ::= { gmplsLabelEntry 2 }

   gmplsLabelSubindex OBJECT-TYPE
     SYNTAX        Unsigned32 (0..4294967295)
     MAX-ACCESS    not-accessible
     STATUS        current
     DESCRIPTION
       "In conjunction with gmplsLabelInterface and
        gmplsLabelIndex, this object uniquely identifies
        this row. This sub-index allows a single GMPLS label
        to be defined as a concatenation of labels.  This is
        particularly useful in TDM.
        The ordering of sub-labels is strict with the sub-
        label with lowest gmplsLabelSubindex appearing
        first. Note that all sub-labels of a single GMPLS
        label must share the same gmplsLabelInterface and
        gmplsLabelIndex values. For labels that are not
        composed of concatenated sub-labels, this value
        SHOULD be set to zero."
   ::= { gmplsLabelEntry 3 }

   gmplsLabelType OBJECT-TYPE
     SYNTAX        GmplsGeneralizedLabelTypes
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "Identifies the type of this label. Note that this
        object does not determine whether MPLS or GMPLS
        signaling is in use: a value of gmplsMplsLabel (1)
        denotes that a 23 bit MPLS packet label is present,
        but does not describe whether this is signaled using
        MPLS or GMPLS.

        The value of this object helps determine which of
        the following objects are valid.
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 4 }

   gmplsLabelMplsLabel OBJECT-TYPE
     SYNTAX         MplsLabel
     MAX-ACCESS     read-create
     STATUS         current
     DESCRIPTION
       "The value of an MPLS label (that is a packet label)
        if this table is used to store it. This may be used
        in MPLS systems even though the label values can be
        adequately stored in the MPLS MIB modules. Further,
        in mixed MPLS and GMPLS systems it may be
        advantageous to store all labels in a single label
        table. Lastly, in GMPLS systems where packet labels
        are used (that is in systems that use GMPLS
        signaling and GMPLS labels for packet switching) it
        may be desirable to use this table.
        This object is only valid if gmplsLabelType is set
        to gmplsMplsLabel (1).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 6 }

   gmplsLabelPortWavelength OBJECT-TYPE
     SYNTAX        Unsigned32
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The value of a Port or Wavelength Label when carried
        as a Generalized Label. Only valid if gmplsLabelType
        is set to gmplsPortWavelengthLabel(2).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 7 }

   gmplsLabelFreeformLength OBJECT-TYPE
     SYNTAX        Integer32 (1..64)
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The length of a freeform Generalized Label indicated

        in the gmplsFreeformLabel object.  Only valid if
        gmplsLabelType is set to
        gmplsFreeformGeneralizedLabel(3).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 8 }

   gmplsLabelFreeform OBJECT-TYPE
     SYNTAX        GmplsFreeformLabel
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The value of a freeform Generalized Label that does
        not conform to one of the standardized label
        encoding or that an implementation chooses to

        represent as an octet string without further
        decoding. The length of this object is given by the
        value of gmplsFreeformLength.  Only valid if
        gmplsLabelType is set to
        gmplsFreeformGeneralizedLabel(3).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 9 }

   gmplsLabelSonetSdhSignalIndex OBJECT-TYPE
     SYNTAX        Integer32 (0..4095)
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
      "The Signal Index value (S) of a SONET or SDH
       Generalized Label. Zero indicates that this field is
       not significant. Only valid if gmplsLabelType is set
       to gmplsSonetLabel(4) or gmplsSdhLabel(5).
       This object cannot be modified if
       gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 10 }

   gmplsLabelSdhVc OBJECT-TYPE
     SYNTAX        Integer32 (0..15)
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
      "The VC Indicator (U) of an SDH Generalized Label.
       Zero indicates that this field is non-significant.
       Only valid if gmplsLabelType is set to
       gmplsSdhLabel(5).
       This object cannot be modified if
       gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 11 }

   gmplsLabelSdhVcBranch OBJECT-TYPE
     SYNTAX        Integer32 (0..15)
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The VC Branch Indicator (K) of an SDH Generalized
        Label. Zero indicates that this field is non-
        significant. Only valid if gmplsLabelType is set to
        gmplsSdhLabel(5).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 12 }

   gmplsLabelSonetSdhBranch OBJECT-TYPE
     SYNTAX        Integer32 (0..15)
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The Branch Indicator (L) of a SONET or SDH
        Generalized Label. Zero indicates that this field is
        non-significant. Only valid gmplsLabelType is set to
        gmplsSonetLabel(4) or gmplsSdhLabel(5).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 13 }

   gmplsLabelSonetSdhGroupBranch OBJECT-TYPE
     SYNTAX        Integer32 (0..15)
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The Group Branch Indicator (M) of a SONET or SDH
        Generalized Label. Zero indicates that this field is
        non-significant. Only valid if gmplsLabelType is set
        to gmplsSonetLabel(4) or gmplsSdhLabel(5).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 14 }

   gmplsLabelWavebandId OBJECT-TYPE
     SYNTAX        Unsigned32
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The waveband identifier component of a waveband
        label. Only valid if gmplsLabelType is set to
        gmplsWavebandLabel(6).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 15 }

   gmplsLabelWavebandStart OBJECT-TYPE
     SYNTAX        Unsigned32
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The starting label component of a waveband label.
        Only valid if gmplsLabelType is set to
        gmplsWavebandLabel(6).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 16 }

   gmplsLabelWavebandEnd OBJECT-TYPE
     SYNTAX        Unsigned32
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "The end label component of a waveband label. Only
        valid if gmplsLabelType is set to
        gmplsWavebandLabel(6).
        This object cannot be modified if
        gmplsLabelRowStatus is active(1)."
   ::= { gmplsLabelEntry 17 }
   gmplsLabelRowStatus OBJECT-TYPE
     SYNTAX        RowStatus
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "This variable is used to create, modify, and/or
        delete a row in this table. When a row in this
        table has a row in the active(1) state, no
        objects in this row can be modified except the
        gmplsLabelRowStatus and gmplsLabelStorageType."
   ::= { gmplsLabelEntry 18 }

   gmplsLabelStorageType OBJECT-TYPE
     SYNTAX        StorageType
     MAX-ACCESS    read-create
     STATUS        current
     DESCRIPTION
       "This variable indicates the storage type for this
        object.

        The agent MUST ensure that this object's value
        remains consistent with the storage type of any rows
        in other tables that contain pointers to this row.
        In particular, the storage type of this row must be
        at least as permanent as that of any row that point
        to it.

        Conceptual rows having the value 'permanent' need
        not allow write-access to any columnar objects in
        the row."
     REFERENCE
       "See RFC2579."
     DEFVAL { volatile }
   ::= { gmplsLabelEntry 19 }

   -- End of GMPLS Label Table

   -- Module compliance.

   gmplsLabelGroups
     OBJECT IDENTIFIER ::= { gmplsLabelConformance 1 }

   gmplsLabelCompliances
     OBJECT IDENTIFIER ::= { gmplsLabelConformance 2 }

   gmplsLabelModuleFullCompliance MODULE-COMPLIANCE
     STATUS current
     DESCRIPTION
       "Compliance statement for agents that support
        the GMPLS Label MIB module."
     MODULE -- this module

     -- The mandatory groups have to be implemented by
     -- LSRs claiming support for this MIB module. This MIB module is,
     -- however, not mandatory for a working implementation of a GMPLS
     -- LSR with full MIB support if the GMPLS labels in use can be
     -- represented within a 32 bit quantity.

     MANDATORY-GROUPS {
       gmplsLabelTableGroup
     }

     -- Units of conformance.

     GROUP gmplsLabelTableGroup
     DESCRIPTION
       "This group is mandatory for devices which support
        the gmplsLabelTable."

     GROUP gmplsLabelPacketGroup
     DESCRIPTION
       "This group extends gmplsLabelTableGroup for
        implementations that support packet labels."

     GROUP gmplsLabelPortWavelengthGroup
     DESCRIPTION
       "This group extends gmplsLabelTableGroup for
        implementations that support port and wavelength
        labels."

     GROUP gmplsLabelFreeformGroup
     DESCRIPTION
       "This group extends gmplsLabelTableGroup for
        implementations that support freeform labels."

     GROUP gmplsLabelSonetSdhGroup
     DESCRIPTION
       "This group extends gmplsLabelTableGroup for
        implementations that support SONET or SDH labels."

     GROUP gmplsLabelWavebandGroup
     DESCRIPTION
       "This group extends gmplsLabelTableGroup for
        implementations that support Waveband labels."

     -- gmplsLabelTable

     OBJECT      gmplsLabelType
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelMplsLabel
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."
     OBJECT      gmplsLabelPortWavelength
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelFreeformLength
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelFreeform
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelSonetSdhSignalIndex
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelSdhVc
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelSdhVcBranch
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelSonetSdhBranch
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelSonetSdhGroupBranch
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelWavebandId
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelWavebandStart
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

     OBJECT      gmplsLabelWavebandEnd
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."
     OBJECT       gmplsLabelRowStatus
     SYNTAX       RowStatus {
       active(1),
       notInService(2)
     }
     WRITE-SYNTAX RowStatus {
       active(1),
       notInService(2),
       createAndGo(4),
       destroy(6)
     }
     DESCRIPTION
       "Support for notInService, createAndWait and notReady
        is not required."

     OBJECT      gmplsLabelStorageType
     MIN-ACCESS  read-only
     DESCRIPTION
       "Write access is not required."

   ::= { gmplsLabelCompliances 1 }

   -- Units of conformance.

   gmplsLabelTableGroup OBJECT-GROUP
     OBJECTS {
       gmplsLabelIndexNext,
       gmplsLabelType,
       gmplsLabelRowStatus,
       gmplsLabelStorageType
     }
     STATUS  current
     DESCRIPTION
       "Necessary, but not sufficient, set of objects to
        implement label table support.  In addition,
        depending on the type of labels supported (for
        example, wavelength labels), the following other
        groups defined below are mandatory:
        gmplsLabelPacketGroup and/or
        gmplsLabelPortWavelengthGroup and/or
        gmplsLabelFreeformGroup and/or
        gmplsLabelSonetSdhGroup."
   ::= { gmplsLabelGroups 1 }

   gmplsLabelPacketGroup OBJECT-GROUP
     OBJECTS {
       gmplsLabelMplsLabel
     }
     STATUS  current
     DESCRIPTION
       "Object needed to implement Packet (MPLS) labels."
   ::= { gmplsLabelGroups 2 }
   gmplsLabelPortWavelengthGroup OBJECT-GROUP
     OBJECTS {
       gmplsLabelPortWavelength
     }
     STATUS  current
     DESCRIPTION
       "Object needed to implement Port and Wavelength
        labels."
   ::= { gmplsLabelGroups 3 }

   gmplsLabelFreeformGroup OBJECT-GROUP
     OBJECTS {
       gmplsLabelFreeformLength,
       gmplsLabelFreeform
     }
     STATUS  current
     DESCRIPTION
       "Object needed to implement Freeform labels."
   ::= { gmplsLabelGroups 4 }

   gmplsLabelSonetSdhGroup OBJECT-GROUP
     OBJECTS {
       gmplsLabelSonetSdhSignalIndex,
       gmplsLabelSdhVc,
       gmplsLabelSdhVcBranch,
       gmplsLabelSonetSdhBranch,
       gmplsLabelSonetSdhGroupBranch
     }
     STATUS  current
     DESCRIPTION
       "Object needed to implement SONET and SDH labels."
   ::= { gmplsLabelGroups 5 }

   gmplsLabelWavebandGroup OBJECT-GROUP
     OBJECTS {
       gmplsLabelWavebandId,
       gmplsLabelWavebandStart,
       gmplsLabelWavebandEnd
     }
     STATUS  current
     DESCRIPTION
       "Object needed to implement Waveband labels."
   ::= { gmplsLabelGroups 6 }

   END

9. Security Considerations

   It is clear that the MIB modules described in this document in
   association with the MPLS-LSR-STD-MIB are potentially useful for
   monitoring of GMPLS LSRs. These MIB modules can also be used for
   configuration of certain objects, and anything that can be configured
   can be incorrectly configured, with potentially disastrous results.

   There are a number of management objects defined in these MIB modules
   with 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. These are the tables and objects and their
   sensitivity/vulnerability:

   o  the gmplsInterfaceTable, gmplsInSegmentTable, gmplsOutSegmentTable
      and gmplsLabelTable collectively contain objects to provision
      GMPLS interfaces, LSPs and their associated parameters on a Label
      Switching Router (LSR). Unauthorized write access to objects in
      these tables, could result in disruption of traffic on the
      network. This is especially true if an LSP has already been
      established. The use of stronger mechanisms such as SNMPv3
      security should be considered where possible. Specifically, SNMPv3
      VACM and USM MUST be used with any SNMPv3 agent which implements
      these MIB modules.

   Some of the readable objects in these MIB modules "i.e., objects with
   a MAX-ACCESS other than not-accessible" may be considered sensitive
   or vulnerable in some network environments. It is thus important to
   control even GET and/or NOTIFY access to these objects and possibly
   to even encrypt the values of these objects when sending them over
   the network via SNMP. These are the tables and objects and their
   sensitivity/vulnerability:

   o  the gmplsInterfaceTable, gmplsInSegmentTable, gmplsOutSegmentTable
      and gmplsLabelTable collectively show the LSP network topology and
      its capabilities. If an Administrator does not want to reveal this
      information, then these tables should be considered
      sensitive/vulnerable.

   SNMP versions prior to SNMPv3 did not include adequate security. 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
   these MIB modules. It is RECOMMENDED that implementers consider the
   security features as provided by the SNMPv3 framework "see [RFC3410],
   section 8", including full support for the SNMPv3 cryptographic
   mechanisms "for authentication and privacy".

   Further, deployment of SNMP versions prior to SNMPv3 is NOT
   RECOMMENDED. Instead, it is RECOMMENDED to deploy SNMPv3 and to
   enable cryptographic security.  It is then a customer/operator
   responsibility to ensure that the SNMP entity giving access to an
   instance of this MIB module, 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.

10. Acknowledgments

   This draft extends [LSRMIB]. The authors would like to express their
   gratitude to all those who worked on that earlier MIB document.

   The authors would like to express their thanks to Dan Joyle for his
   careful review and comments on early versions of the Label Table.
   Special thanks to Joan Cucchiara and Len Nieman for their help with
   compilation issues.

11. IANA Considerations

   MPLS related standards track MIB modules are rooted under the
   mplsStdMIB subtree.

   One of the MIB modules contained in this document extends tables
   contained in MPLS MIB modules.

   As requested in requested in the GMPLS-TC-STD-MIB [GMPLSTCMIB] the
   two MIB modules contained in this document should be placed in the
   mplsStdMIB subtree as well.

   New assignments can only be made via a Standards Action as specified
   in [RFC2434].

11.1. IANA Considerations for GMPLS-LSR-STD-MIB

   The IANA is requested to assign { mplsStdMIB xx } to the
   GMPLS-LSR-STD-MIB module specified in this document.

11.2. IANA Considerations for GMPLS-LABEL-STD-MIB

   The IANA is requested to assign { mplsStdMIB xx } to the
   GMPLS-LABEL-STD-MIB module specified in this document.

12. References

12.1. Normative References

   [RFC2119]         Bradner, S., "Key words for use in RFCs to Indicate
                     Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC2578]         McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                     Case, J., Rose, M., and S. Waldbusser, "Structure
                     of Management Information Version 2 (SMIv2)", STD
                     58, RFC 2578, April 1999.

   [RFC2579]         McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                     Case, J., Rose, M., and S. Waldbusser, "Textual
                     Conventions for SMIv2", STD 58, RFC 2579, April
                     1999.

   [RFC2580]         McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                     Case, J., Rose, M., and S. Waldbusser, "Conformance
                     Statements for SMIv2", STD 58, RFC 2580, April
                     1999.

   [RFC2863]         McCloghrie, K. and F. Kastenholtz, "The Interfaces
                     Group MIB", RFC 2863, June 2000.

   [GMPLSArch]       Mannie, E. (Editor), "Generalized Multiprotocol
                     Label Switching (GMPLS) Architecture", Internet
                     Draft <draft-many-gmpls-architecture-07.txt>, May
                     2003, work in progress.

   [GMPLSSonetSDH]   Mannie, E., Papadimitriou, D. (Editors),
                     "Generalized Multi-Protocol Label Switching
                     Extensions for SONET and SDH Control", Internet
                     Draft <draft-ietf-ccamp-gmpls-sonet-sdh-08.txt>,
                     February 2003, work in progress.

   [GMPLSTCMIB]      Nadeau, T., Srinivasan, C., Farrel, A., Hall, T.,
                     and Harrison, E., "Definitions of Textual
                     Conventions for Multiprotocol Label Switching
                     (MPLS) Management", draft-ietf-ccamp-gmpls-te-mib-
                     03.txt, November 2003, work in progress.

   [GMPLSTEMIB]      Nadeau, T., Srinivasan, C., Farrel, A., Hall, T.,
                     and Harrison, E., "Generalized Multiprotocol Label
                     Switching (GMPLS) Traffic Engineering Management
                     Information Base", draft-ietf-ccamp-gmpls-te-mib-
                     03.txt, November 2003, work in progress.

   [TCMIB]           Nadeau, T., Cucchiara, J. (Editors) "Definitions of
                     Textual Conventions for Multiprotocol Label
                     Switching (MPLS) Management", Internet Draft
                     <draft-ietf-mpls-tc-mib-09.txt>, August 2003, work
                     in progress.

   [LSRMIB]          Srinivasan, C., Viswanathan, A. and T. Nadeau,
                     "Multiprotocol Label Switching (MPLS) Label
                     Switching Router (LSR) Management Information
                     Base", Internet Draft <draft-ietf-mpls-lsr-mib-
                     12.txt>, August 2003, work in progress.

12.2. Informational References

   [RFC2026]         S. Bradner, "The Internet Standards Process --
                     Revision 3", RFC 2026, October 1996.

   [RFC2434]         Narten, T. and H. Alvestrand, "Guidelines for
                     Writing an IANA Considerations Section in RFCs",
                     BCP: 26, RFC 2434, October 1998.

   [RFC3031]         Rosen, E., Viswanathan, A., and R. Callon,
                     "Multiprotocol Label Switching Architecture", RFC
                     3031, January 2001.

   [RFC3209]         Awduche, D., Berger, L., Gan, D., Li, T.,
                     Srinivasan, V., and G. Swallow, "RSVP-TE:
                     Extensions to RSVP for LSP Tunnels", RFC 3209,
                     December 2001.

   [RFC3212]         Jamoussi, B., Aboul-Magd, O., Andersson, L.,
                     Ashwood-Smith, P., Hellstrand, F., Sundell, K.,
                     Callon, R., Dantu, R., Wu, L., Doolan, P., Worster,
                     T., Feldman, N., Fredette, A., Girish, M., Gray,
                     E., Halpern, J., Heinanen, J., Kilty, T., Malis,
                     A., and P. Vaananen, "Constraint-Based LSP Setup
                     using LDP", RFC 3212, December 2001."
   [RFC3410]         Case, J., Mundy, R., Partain, D. and B. Stewart,
                     "Introduction and Applicability Statements for
                     Internet-Standard Management Framework", RFC 3410,
                     December 2002.

   [RFC3411]         Harrington, D., Presuhn, R., and B. Wijnen, "An
                     Architecture for Describing Simple Network
                     Management Protocol (SNMP) Management Frameworks",
                     RFC 3411, December 2002.

   [RFC3413]         Levi, D., Meyer, P., Stewart, B., "SNMP
                     Applications", RFC 3413, December 2002.

   [RFC3471]         Berger, L. (Editor), "Generalized Multi-Protocol
                     Label Switching (GMPLS) Signaling Functional
                     Description", RFC 3471, January 2003.

   [RFC3472]         Ashwood-Smith, P., Berger, L. (Editors),
                     "Generalized MPLS Signaling - CR-LDP Extensions",
                     RFC 3472, January 2003.

   [RFC3473]         Berger, L. (Editor), "Generalized MPLS Signaling -
                     RSVP-TE Extensions", RFC 3473 January 2003.

   [TEMIB]           Nadeau, T., Srinivasan, C, Viswanathan, A.,
                     "Multiprotocol Label Switching (MPLS) Traffic
                     Engineering Management Information Base", Internet
                     Draft <draft-ietf-mpls-te-mib-12.txt>, August 2003,
                     work in progress.

13. Authors' Addresses

   Thomas D. Nadeau
   Cisco Systems, Inc.
   300 Apollo Drive
   Chelmsford, MA 01824
   Phone: +1-978-244-3051
   Email: tnadeau@cisco.com

   Cheenu Srinivasan
   Bloomberg L.P.
   499 Park Ave.,
   New York, NY 10022
   Phone: +1-212-893-3682
   Email: cheenu@bloomberg.net

   Adrian Farrel
   Old Dog Consulting
   Phone: +44-(0)-1978-860944
   Email: adrian@olddog.co.uk

   Tim Hall
   Data Connection Ltd.
   100 Church Street
   Enfield, Middlesex, EN2 6BQ, UK
   Phone: +44 20 8366 1177
   Email: timhall@dataconnection.com
   Ed Harrison
   Data Connection Ltd.
   100 Church Street
   Enfield, Middlesex, EN2 6BQ, UK
   Phone: +44 20 8366 1177
   Email: ed.harrison@dataconnection.com

14. Full Copyright Statement

   Copyright (C) The Internet Society (2003). All Rights Reserved.

   This document and translations of it may be copied and furnished to
   others, and derivative works that comment on or otherwise explain it
   or assist in its implementation may be prepared, copied, published
   and distributed, in whole or in part, without restriction of any
   kind, provided that the above copyright notice and this paragraph
   are included on all such copies and derivative works.  However, this
   document itself may not be modified in any way, such as by removing
   the copyright notice or references to the Internet Society or other
   Internet organizations, except as needed for the purpose of
   developing Internet standards in which case the procedures for
   copyrights defined in the Internet Standards process must be
   followed, or as required to translate it into languages other than
   English.

   The limited permissions granted above are perpetual and will not be
   revoked by the Internet Society or its successors or assigns. This
   document and the information contained herein is provided on an "AS
   IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK
   FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT
   NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN
   WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
   MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.

15. Intellectual Property Notice

   The IETF takes no position regarding the validity or scope of any
   intellectual property or other rights that might be claimed to
   pertain to the implementation or use of the technology described in
   this document or the extent to which any license under such rights
   might or might not be available; neither does it represent that it
   has made any effort to identify any such rights.  Information on the
   IETF's procedures with respect to rights in standards-track and
   standards-related documentation can be found in BCP-11 [RFC2028].

   Copies of claims of rights made available for publication and any
   assurances of licenses to be made available, or the result of an
   attempt made to obtain a general license or permission for the use
   of such proprietary rights by implementers or users of this
   specification can be obtained from the IETF Secretariat.

   The IETF invites any interested party to bring to its attention any
   copyrights, patents or patent applications, or other proprietary
   rights that may cover technology that may be required to practice
   this standard.  Please address the information to the IETF Executive
   Director.

16. Changes and Pending Work

   This section must be removed before the draft progresses to RFC.

16.1. Pending Work

   The following work items have been identified for this draft. They
   will be addressed in a future version.

   - Expand conformance statements to give one for monitoring only,
     and one for monitoring and control.
   - Provide support for monitoring tunnel resources in GMPLS systems.
     For example, SONET/SDH or G.709.  This might be done through an
     arbitrary RowPointer to an external MIB.
   - Extend the performance tables from the MPLS-LSR-MIB for
     technology-specific GMPLS LSPs.
   - Determine whether the 'discriminated union' in the Label Table is
     good MIB.

16.1. Changes from version 2 to version 3

   - Work on basic compilation issues.
   - Provide a next index object to supply the next available
     arbitrary index into the Label Table.
   - Update references.
   - Update examples.

Network Working Group                                   Thomas D. Nadeau
Internet Draft                                       Cisco Systems, Inc.
Expires: May 2004
                                                       Cheenu Srinivasan
                                                          Bloomberg L.P.

                                                           Adrian Farrel
                                                      Old Dog Consulting

                                                                Tim Hall
                                                             Ed Harrison
                                                    Data Connection Ltd.

                                                           November 2003

     Definitions of Textual Conventions for Generalized Multi-Protocol
                  Label Switching (GMPLS) Management

                 draft-ietf-ccamp-gmpls-tc-mib-03.txt

Status of this Memo

   This document is an Internet-Draft and is in full conformance with
   all provisions of Section 10 of RFC 2026.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF), its areas, and its working groups.  Note that
   other groups may also distribute working documents as Internet-
   Drafts.

   Internet-Drafts are draft documents valid for a maximum of six months
   and may be updated, replaced, or obsoleted by other documents at any
   time.  It is inappropriate to use Internet-Drafts as reference
   material or to cite them other than as "work in progress."

   The list of current Internet-Drafts can be accessed at
   http://www.ietf.org/ietf/1id-abstracts.txt.

Abstract

   This document defines a Management Information Base (MIB) module
   which contains Textual Conventions to represent commonly used
   Generalized Multi-Protocol Label Switching (GMPLS) management
   information. The intent is that these TEXTUAL CONVENTIONS (TCs) will
   be imported and used in GMPLS related MIB modules that would
   otherwise define their own representations.

Table of Contents

   1. Introduction                                     2
   2. The SNMP Management Framework                    2
   3. GMPLS Textual Conventions MIB Definitions        3
   4. Security Considerations                          5
   5. IANA Considerations                              5
   6. References                                       5
   6.1. Normative References                           5
   6.2. Informational References                       6
   7. Authors' Addresses                               7
   8. Full Copyright Statement                         7
   9. Intellectual Property Notice                     8

1. Introduction

   This document defines a MIB module which contains Textual Conventions
   for Generalized Multi-Protocol Label Switching (GMPLS) networks.
   These Textual Conventions should be imported by MIB modules which
   manage GMPLS networks.

   This MIB module supplements the MIB module in [TCMIB] that defines
   Textual Conventions for Multiprotocol Label Switching (MPLS)
   Management. [TCMIB] may continue to be used without this MIB module
   in networks that support only MPLS.

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in RFC 2119 [RFC2119].

   Comments should be made directly to the CCAMP mailing list at
   ccamp@ops.ietf.org.

   For an introduction to the concepts of GMPLS, see [GMPLSArch].

2. The SNMP 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 [RFC3410].

   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 [RFC2578], STD 58, RFC 2579 [RFC2579] and STD 58, RFC 2580
   [RFC2580].

3. GMPLS Textual Conventions MIB Definitions

   GMPLS-TC-STD-MIB DEFINITIONS ::= BEGIN

   IMPORTS
     MODULE-IDENTITY
       FROM SNMPv2-SMI
     transmission
       FROM SNMPv2-SMI
     TEXTUAL-CONVENTION
       FROM SNMPv2-TC
   ;

   gmplsTCStdMIB MODULE-IDENTITY
     LAST-UPDATED
       "200310300900Z" -- 30 October 2003 9:00:00 GMT"
     ORGANIZATION "Common Control And Management Protocols (CCAMP)
                   Working Group"
     CONTACT-INFO
       "       Thomas D. Nadeau
               Cisco Systems, Inc.
        Email: tnadeau@cisco.com

               Cheenu Srinivasan
               Bloomberg L.P.
        Email: cheenu@bloomberg.net

               Adrian Farrel
               Old Dog Consulting
        Email: adrian@olddog.co.uk

               Ed Harrison
               Data Connection Ltd.
        Email: ed.harrison@dataconnection.com

               Tim Hall
               Data Connection Ltd.
        Email: timhall@dataconnection.com

        Comments about this document should be emailed direct to the
        CCAMP working group mailing list at ccamp@ops.ietf.org"
     DESCRIPTION
       "Copyright (C) The Internet Society (2003). This version of this
        MIB module is part of RFCXXX; see the RFC itself for full legal
        notices.

        This MIB module defines Textual Conventions for concepts used in
        Generalized Multi-Protocol Label Switching (GMPLS) networks."

   -- Revision history.
     REVISION
       "200310300900Z" -- 30 October 2003 09:00:00 GMT
     DESCRIPTION
       "Initial version published as part of RFC XXXX."
     -- Please see the IANA Considerations Section.
     -- The requested gmplsStdMIB subId is xx, i.e.
   ::= { gmplsStdMIB xx }
   gmplsStdMIB OBJECT IDENTIFIER
     -- This object identifier needs to be assigned by IANA.
     -- Since mpls has been assigned an ifType of 166 we recommend
     -- that this OID be 166 as well, i.e.
   ::= { transmission XXX }

   -- Textual Conventions (sorted alphabetically).

   GmplsFreeformLabel ::= TEXTUAL-CONVENTION
     STATUS      current
     DESCRIPTION
       "This value represents a freeform generalized MPLS Label. This
        can be used to represent label types which are not standard
        in the drafts. It may also be used by systems that do not
        wish to represent the labels using the specific label types."
     SYNTAX OCTET STRING (SIZE (0..64))

   GmplsGeneralizedLabelTypes ::= TEXTUAL-CONVENTION
     STATUS      current
     DESCRIPTION
       "Determines the interpretation that should be applied to a
        label."
     SYNTAX INTEGER {
       gmplsMplsLabel(1),
       gmplsPortWavelengthLabel(2),
       gmplsFreeformGeneralizedLabel(3),
       gmplsSonetLabel(4),
       gmplsSdhLabel(5),
       gmplsWavebandLabel(6)
     }

   GmplsSegmentDirection ::= TEXTUAL-CONVENTION
     STATUS      current
     DESCRIPTION
       "The direction of data flow on an LSP segment with respect to the
        head of the LSP.

        Where an LSP is signaled using a conventional signaling
        protocol, the 'head' of the LSP is the source of the signaling
        (also known as the ingress) and the 'tail' is the destination
        (also known as the egress).

        For manually configured LSPs an arbitrary decision must be made
        about which LER is the 'head'."
     SYNTAX  INTEGER {
       forward(1),
       reverse(2)
     }

   END

4. Security Considerations

   This module does not define any management objects. Instead, it
   defines a set of textual conventions which may be used by other GMPLS
   MIB modules to define management objects.

   Meaningful security considerations can only be written in the MIB
   modules that define management objects. Therefore, this document has
   no impact on the security of on the Internet.

5. IANA Considerations

   IANA secure network is requested allowed
   to make a MIB OID assignment under access and GET/SET "read/change/create/delete" the transmission
   branch, objects in
   these MIB modules. It is RECOMMENDED that is, assign implementers consider the gmplsStdMIB under { transmission 166 }.

   This sub-id is requested because 166 is
   security features as provided by the ifType SNMPv3 framework "see [RFC3410],
   section 8", including full support for mpls(166) the SNMPv3 cryptographic
   mechanisms "for authentication and privacy".

   Further, deployment of SNMP versions prior to SNMPv3 is available under transmission.

   In NOT
   RECOMMENDED. Instead, it is RECOMMENDED to deploy SNMPv3 and to
   enable cryptographic security.  It is then a customer/operator
   responsibility to ensure that the future, GMPLS related standards track SNMP entity giving access to an
   instance of this MIB modules should be
   rooted under the mplsStdMIB (sic) subtree. IANA module, is requested properly configured to
   manage that namespace. New assignments can give access to
   the objects only be made via a
   Standards Action as specified in [RFC2434]. to those principals "users" that have legitimate
   rights to indeed GET or SET "change/create/delete" them.

10. Acknowledgments

   This document also requests IANA extends [TEMIB]. The authors would like to assign { gmplsStdMIB xx } express
   their gratitude to the
   GMPLS-TC-STD-MIB specified in this all those who worked on that earlier MIB document.

6.
   Thanks also to Tony Zinicola and Jeremy Crossen for their valuable
   contributions during an early implementation, and to Baktha
   Muralidharan for his review.

   Special thanks to Joan Cucchiara and Len Nieman for their help with
   compilation issues.

11. References

6.1.

11.1. Normative References

   [RFC2119]        Bradner, S., "Key words for use in RFCs to Indicate
                    Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC2578]        McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                    Case, J., Rose, M. M., and S. Waldbusser, "Structure
                    of Management Information Version 2 (SMIv2)", STD
                    58, RFC 2578, April 1999.

   [RFC2579]        McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                    Case, J., Rose, M. M., and S. Waldbusser, "Textual
                    Conventions for SMIv2", STD 58, RFC 2579, April
                    1999.

   [RFC2580]        McCloghrie, K., Perkins, D., Schoenwaelder, J.,
                    Case, J., Rose, M. M., and S. Waldbusser, "Conformance
                    Statements for SMIv2", STD 58, RFC 2580, April 1999.

   [RFC3471]        Berger, L. (Editor), "Generalized Multi-Protocol
                    Label Switching (GMPLS) Signaling Functional
                    Description", RFC 3471, January 2003.

   [GMPLSArch]      Mannie, E. (Editor), "Generalized Multiprotocol
                    Label Switching (GMPLS) Architecture", Internet
                    Draft <draft-many-gmpls-architecture-07.txt>, May
                    2003, work in progress.

6.2. Informational References

   [RFC2434]        Narten, T. and H. Alvestrand, "Guidelines for
                    Writing an IANA Considerations Section in RFCs",
                    BCP: 26, RFC 2434, October 1998.
                    1999.

   [RFC3031]        Rosen, E., Viswananthan, Viswanathan, A., and R. Callon,
                    Multiprotocol
                    "Multiprotocol Label Switching Architecture", RFC
                    3031, January 2001.

   [RFC3209]        Awduche, D., Berger, L., Gan, D., Li, T.,
                    Srinivasan, V., and G. Swallow, G., "RSVP-TE:
                    Extensions to RSVP for LSP Tunnels", RFC 3209,
                    December 2001.

   [RFC3212]        Jamoussi, B., (editor), et. al. Aboul-Magd, O., Andersson, L.,
                    Ashwood-Smith, P., Hellstrand, F., Sundell, K.,
                    Callon, R., Dantu, R., Wu, L., Doolan, P., Worster,
                    T., Feldman, N., Fredette, A., Girish, M., Gray,
                    E., Halpern, J., Heinanen, J., Kilty, T., Malis,
                    A., and P. Vaananen, "Constraint-Based LSP Setup
                    using LDP", RFC 3212, January 2002.

   [RFC3410]        Case, December 2001.

   [RFC3291]        Daniele, M., Haberman, B., Routhier, S.,
                    Schoenwaelder, J., Mundy, R., Partain, D. and B. Stewart,
                    "Introduction and Applicability Statements Braunschweig, TU, "Textual
                    Conventions for
                    Internet-Standard Management Framework", Internet Network Addresses",
                    RFC3291, May 2002

   [RFC3471]        Berger, L. (Editor), "Generalized Multi-Protocol
                    Label Switching (GMPLS) Signaling Functional
                    Description", RFC 3410,
                    December 2002. 3471, January 2003.

   [RFC3472]        Ashwood-Smith, P., Berger, L. (Editors),
                    "Generalized MPLS Signaling - CR-LDP Extensions",
                    RFC 3472, January 2003.

   [RFC3473]        Berger, L. (Editor), "Generalized MPLS Signaling -
                    RSVP-TE Extensions", RFC 3473 3473, January 2003.

   [RFC3477]        Kompella, K. and Rekhter, Y., "Signalling Unnumbered
                    Links in RSVP-TE", RFC 3477, January 2003.

   [GMPLSSonetSDH]

   [RFC3480]        Kompella, K., Rekhter, Y. and Kullberg, A.,
                    "Signalling Unnumbered Links in CR-LDP", RFC 3480,
                    February 2003.

   [GMPLSArch]      Mannie, E., Papadimitriou, D. (Editors), E. (Editor), "Generalized Multi-Protocol Multiprotocol
                    Label Switching
                    Extensions for SONET and SDH Control", Internet
                    Draft <draft-ietf-ccamp-gmpls-sonet-sdh-08.txt>,
                    February (GMPLS) Architecture",
                    draft-many-gmpls-architecture-07.txt, May
                    2003, work in progress.

   [GMPLSLSRMIB]    Nadeau, T., Srinivasan, C., A., Farrel, A., Hall,
                    T., and Harrison, E., " Generalized "Generalized Multiprotocol
                    Label Switching (GMPLS) Label Switching Router
                    (LSR) Management Information Base", draft-ietf-ccamp-
                    gmpls-lsr-mib-03.txt, November draft-ietf-
                    ccamp-gmpls-lsr-mib-04.txt, February 2004, work in
                    progress.

   [GMPLSOSPF]      Kompella, K., et al., "OSPF Extensions in Support
                    of Generalized MPLS", draft-ietf-ccamp-ospf-gmpls-
                    extensions-12.txt, October 2003, work in progress.

   [GMPLSTEMIB]

   [GMPLSTCMIB]     Nadeau, T., Srinivasan, C., Farrel, A., Hall, T.,
                    and Harrison, E., "Generalized "Definitions of Textual
                    Conventions for Multiprotocol Label Switching (GMPLS) Traffic Engineering
                    (MPLS) Management", draft-ietf-ccamp-gmpls-te-mib-
                    04.txt, February 2004, work in progress.

   [LSRMIB]         Srinivasan, C., Viswanathan, A. and T. Nadeau,
                    "Multiprotocol Label Switching (MPLS) Label
                    Switching Router (LSR) Management Information
                    Base", draft-ietf-ccamp-gmpls-te-mib-
                    03.txt, draft-ietf-mpls-lsr-mib-14.txt, November
                    2003, work in progress.

   [TCMIB]          Nadeau, T., Cucchiara, J. (Editors) "Definitions of
                    Textual Conventions for Multiprotocol Label
                    Switching (MPLS) Management", Internet Draft
                    <draft-ietf-mpls-tc-mib-09.txt>, August 2003,
                    work in progress.

7. Acknowledgements

   Special thanks to Joan Cucchiara Multiprotocol Label
                    Switching (MPLS) Management",
                    draft-ietf-mpls-tc-mib-10.txt, November 2003, work
                    in progress.

   [TEMIB]          Nadeau, T., Srinivasan, C, Viswanathan, A.,
                    "Multiprotocol Label Switching (MPLS) Traffic
                    Engineering Management Information Base",
                    draft-ietf-mpls-te-mib-14.txt, November 2003,
                    work in progress.

11.2. Informational References

   [RFC2026]        S. Bradner, "The Internet Standards Process --
                    Revision 3", RFC 2026, October 1996.

   [RFC3413]        Levi, D., Meyer, P., Stewart, B., "SNMP
                    Applications", RFC 3413, December 2002.

   [RFC3410]        Case, J., Mundy, R., Partain, D. and B. Stewart,
                    "Introduction and Applicability Statements for
                    Internet-Standard Management Framework", RFC 3410,
                    December 2002.

   [RFC3411]        Harrington, D., Presuhn, R., and B. Wijnen, "An
                    Architecture for her help with compilation
   issues.

8. Describing Simple Network
                    Management Protocol (SNMP) Management Frameworks",
                    RFC 3411, December 2002.

12. Authors' Addresses

   Thomas D. Nadeau
   Cisco Systems, Inc.
   300 Apollo Drive
   Chelmsford, MA 01824
   Phone: +1-978-244-3051
   Email: tnadeau@cisco.com

   Cheenu Srinivasan
   Bloomberg L.P.
   499 Park Ave.,
   New York, NY 10022
   Phone: +1-212-893-3682
   Email: cheenu@bloomberg.net

   Adrian Farrel
   Old Dog Consulting
   Phone: +44-(0)-1978-860944
   Email: adrian@olddog.co.uk

   Tim Hall
   Data Connection Ltd.
   100 Church Street
   Enfield, Middlesex
   EN2 6BQ, UK
   Phone: +44 20 8366 1177
   Email: timhall@dataconnection.com tim.hall@dataconnection.com

   Ed Harrison
   Data Connection Ltd.
   100 Church Street
   Enfield, Middlesex
   EN2 6BQ, UK
   Phone: +44 20 8366 1177
   Email: ed.harrison@dataconnection.com

9.

13. Full Copyright Statement

   Copyright (C) The Internet Society (2003). (2004). All Rights Reserved.
   This document and translations of it may be copied and furnished to
   others, and derivative works that comment on or otherwise explain it
   or assist in its implementation may be prepared, copied, published
   and distributed, in whole or in part, without restriction of any
   kind, provided that the above copyright notice and this paragraph are
   included on all such copies and derivative works.  However, this
   document itself may not be modified in any way, such as by removing
   the copyright notice or references to the Internet Society or other
   Internet organizations, except as needed for the purpose of
   developing Internet standards in which case the procedures for
   copyrights defined in the Internet Standards process must be
   followed, or as required to translate it into languages other than
   English.

   The limited permissions granted above are perpetual and will not be
   revoked by the Internet Society or its successors or assigns. This
   document and the information contained herein is provided on an "AS
   IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK
   FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT
   LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL
   NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY
   OR FITNESS FOR A PARTICULAR PURPOSE.

10.

14. Intellectual Property Notice

   The IETF takes no position regarding the validity or scope of any
   intellectual property or other rights that might be claimed to
   pertain to the implementation or use of the technology described in
   this document or the extent to which any license under such rights
   might or might not be available; neither does it represent that it
   has made any effort to identify any such rights.  Information on the
   IETF's procedures with respect to rights in standards-track and
   standards-related documentation can be found in BCP-11 [RFC2028].

   Copies of claims of rights made available for publication and any
   assurances of licenses to be made available, or the result of an
   attempt made to obtain a general license or permission for the use
   of such proprietary rights by implementers or users of this
   specification can be obtained from the IETF Secretariat.

   The IETF invites any interested party to bring to its attention any
   copyrights, patents or patent applications, or other proprietary
   rights that may cover technology that may be required to practice
   this standard.  Please address the information to the IETF Executive
   Director.

15. Changes and Pending Work

   This section to be removed before the draft progresses to RFC.

15.1. Pending Work

   The following work items have been identified for this draft.  They
   will be addressed in a future version.

   - Expand conformance statements to give one for monitoring only,
     and one for monitoring and control.

15.2. Changes from version 3 to version 4

   - Provide a way to configure additional tunnel parameters such as
     tunnel resources through an arbitrary row pointer.
   - Update references.
   - Change reporting IP addresses to use InetAddress syntax
   - Add support for IF_ID error reporting.
   - Add a new notification, gmplsTunnelDown, containing cause
     information.
   - Clarify relationship to the gmplsLabelTable.
   - Update descriptive text.
   - Bring usage of labels in line with latest [LSRMIB].

15.3. Changes from version 2 to version 3

   - Work on basic compilation issues.
   - Resolve defaults for objects with syntax BITS.
   - Update references.
   - Clarify which objects can be modified when rowStatus and
     adminStatus are set to active.
   - Control and reporting of upstream and downstream Notify
     Recipients.
   - Add support for control and reporting of GMPLS Administrative
     Status object.
   - Update examples.