Google      
  WWW DocMirror.net

[ RFC2019 | RFC Index | Protocol Standards | Linux Docs | FreeBSD Docs | RFC2021 ]

RFC 2020








Network Working Group                                           J. Flick
Request for Comments: 2020                               Hewlett Packard
Category: Standards Track                                   October 1996


       Definitions of Managed Objects for IEEE 802.12 Interfaces

Status of this Memo

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

Table of Contents

 1.  Introduction ...............................................    1
 2.  Object Definitions .........................................    2
 3.  Overview ...................................................    2
 3.1.  MAC Addresses ............................................    3
 3.2.  Relation to RFC 1213 .....................................    3
 3.3.  Relation to RFC 1573 .....................................    3
 3.3.1.  Layering Model .........................................    4
 3.3.2.  Virtual Circuits .......................................    4
 3.3.3.  ifTestTable ............................................    4
 3.3.4.  ifRcvAddressTable ......................................    4
 3.3.5.  ifPhysAddress ..........................................    4
 3.3.6.  Specific Interface MIB Objects .........................    5
 3.4.  Relation to RFC 1643, RFC 1650, and RFC 1748 .............    8
 3.5.  Relation to RFC 1749 .....................................    8
 3.6.  Master Mode Operation ....................................    9
 3.7.  Normal and High Priority Counters ........................    9
 3.8.  IEEE 802.12 Training Frames ..............................   10
 3.9.  Mapping of IEEE 802.12 Managed Objects ...................   12
 4.  Definitions ................................................   14
 5.  Acknowledgements ...........................................   30
 6.  References .................................................   30
 7.  Security Considerations ....................................   31
 8.  Author's Address ...........................................   31

1.  Introduction

   This memo defines a portion of the Management Information Base (MIB)
   for use with network management protocols in TCP/IP-based internets.
   In particular, it defines objects for managing network interfaces
   based on IEEE 802.12.




Flick                       Standards Track                     [Page 1]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


2.  Object Definitions

   Management information is viewed as a collection of managed objects,
   residing in a virtual information store, termed the Management
   Information Base (MIB).  Collections of related objects are defined
   in MIB modules.  MIB modules are written using a subset of Abstract
   Syntax Notation One (ASN.1) [1] termed the Structure of Management
   Information (SMI) [2].  In particular, each object type is named by
   an OBJECT IDENTIFIER, an administratively assigned name.  The object
   type together with an object instance serves to uniquely identify a
   specific instantiation of the object.  For human convenience, we
   often use a textual string, termed the descriptor, to refer to the
   object type.

3.  Overview

   Instances of these object types represent attributes of an interface
   to an IEEE 802.12 communications medium.  At present, IEEE 802.12
   media are identified by one value of the ifType object in the
   Internet-standard MIB:

      ieee80212(55)

   For this interface, the value of the ifSpecific variable in the MIB-
   II [5] has the OBJECT IDENTIFIER value:

      dot12MIB    OBJECT IDENTIFIER ::= { transmission 45 }

   The values for the ifType object are defined by the IANAifType
   textual convention.  The Internet Assigned Numbers Authority (IANA)
   is responsible for the assignment of all Internet numbers, including
   new ifType values.  Therefore, IANA is responsible for maintaining
   the definition of this textual convention.  The current definition of
   the IANAifType textual convention is available from IANA's World Wide
   Web server at:

         http://www.iana.org/iana/

   The definitions presented here are based on the IEEE Standard
   802.12-1995, [6] Clause 13 "Layer management functions and services",
   and Annex C "GDMO Specifications for Demand Priority Managed
   Objects".  Implementors of these MIB objects should note that the
   IEEE document explicitly describes (in the form of Pascal pseudocode)
   when, where, and how various MAC attributes are measured.  The IEEE
   document also describes the effects of MAC actions that may be
   invoked by manipulating instances of the MIB objects defined here.





Flick                       Standards Track                     [Page 2]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


   To the extent that some of the attributes defined in [6] are
   represented by previously defined objects in the Internet-standard
   MIB [5] or in the Evolution of the Interfaces Group of MIB-II [7],
   such attributes are not redundantly represented by objects defined in
   this memo.  Among the attributes represented by objects defined in
   other memos are the number of octets transmitted or received on a
   particular interface, the MAC address of an interface, and multicast
   information associated with an interface.

3.1.  MAC Addresses

   All representations of MAC addresses in this MIB module, and in other
   related MIB modules (like RFC 1573), are in "canonical" order defined
   by 802.1a, i.e., as if it were transmitted least significant bit
   first.  This is true even if the interface is operating in token ring
   framing mode, which requires MAC addresses to be transmitted most
   significant bit first.

3.2.  Relation to RFC 1213

   This section applies only when this MIB is used in conjunction with
   the "old" (i.e., pre-RFC 1573) interface group.

   The relationship between an IEEE 802.12 interface and an interface in
   the context of the Internet-standard MIB is one-to-one.  As such, the
   value of an ifIndex object instance can be directly used to identify
   corresponding instances of the objects defined herein.

3.3.  Relation to RFC 1573

   RFC 1573, the Interface MIB Evolution, requires that any MIB which is
   an adjunct of the Interface MIB, clarify specific areas within the
   Interface MIB.  These areas are intentionally left vague in RFC 1573
   to avoid over constraining the MIB, thereby precluding management of
   certain media-types.

   An agent which implements this MIB module must support the
   ifGeneralGroup, ifStackGroup, ifHCPacketGroup, and ifRcvAddressGroup
   of RFC 1573.

   Section 3.3 of RFC 1573 enumerates several areas which a media-
   specific MIB must clarify.  In addition, there are some objects in
   RFC 1573 for which additional clarification of how to apply them to
   an IEEE 802.12 interface would be helpful.  Each of these areas is
   addressed in a following subsection.  The implementor is referred to
   RFC 1573 in order to understand the general intent of these areas.





Flick                       Standards Track                     [Page 3]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


3.3.1.  Layering Model

   For the typical usage of this MIB module, there will be no sub-layers
   "above" or "below" the 802.12 Interface.  However, this MIB module
   does not preclude such layering.

3.3.2.  Virtual Circuits

   This medium does not support virtual circuits and this area is not
   applicable to this MIB.

3.3.3.  ifTestTable

   This MIB does not define any tests for media instrumented by this
   MIB.  Implementation of the ifTestTable is not required.  An
   implementation may optionally implement the ifTestTable to execute
   vendor specific tests.

3.3.4.  ifRcvAddressTable

   This table contains all IEEE addresses, unicast, multicast, and
   broadcast, for which this interface will receive packets and forward
   them up to a higher layer entity for consumption.  In addition, when
   the interface is using 802.5 framing mode, the ifRcvAddressTable will
   contain the functional address mask.

   In the event that the interface is part of a MAC bridge, this table
   does not include unicast addresses which are accepted for possible
   forwarding out some other port.  This table is explicitly not
   intended to provide a bridge address filtering mechanism.

3.3.5.  ifPhysAddress

   This object contains the IEEE 802.12 address which is placed in the
   source-address field of any frames that originate at this interface.
   Usually this will be kept in ROM on the interface hardware.  Some
   systems may set this address via software.

   In a system where there are several such addresses the designer has a
   tougher choice.  The address chosen should be the one most likely to
   be of use to network management (e.g.  the address placed in ARP
   responses for systems which are primarily IP systems).

   If the designer truly can not choose, use of the factory-provided ROM
   address is suggested.

   If the address can not be determined, an octet string of zero length
   should be returned.



Flick                       Standards Track                     [Page 4]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


   The address is stored in binary in this object.  The address is
   stored in "canonical" bit order, that is, the Group Bit is positioned
   as the low-order bit of the first octet.  Thus, the first byte of a
   multicast address would have the bit 0x01 set.  This is true even
   when the interface is using token ring framing mode, which transmits
   addresses high-order bit first.

3.3.6.  Specific Interface MIB Objects

   The following table provides specific implementation guidelines for
   the interface group objects in the conformance groups listed above.

     Object                 Use for an 802.12 Interface

     ifIndex                Each 802.12 interface is represented by an
                            ifEntry.  Interface tables in this MIB
                            module are indexed by ifIndex.

     ifDescr                Refer to [7].

     ifType                 The IANA reserved value for 802.12 - 55.

     ifMtu                  The value of ifMtu on an 802.12 interface
                            will depend on the type of framing that is
                            in use on that interface.  Changing the
                            dot12DesiredFramingType may have the effect
                            of changing ifMtu after the next time that
                            the interface trains.  When
                            dot12CurrentFramingType is equal to
                            frameType88023, ifMtu will be equal to
                            1500.  When dot12CurrentFramingType is
                            equal to frameType88025, ifMtu will be
                            4464.

     ifSpeed                The speed of the interface in bits per
                            second.  For current 802.12
                            implementations, this will be equal to
                            100,000,000 (100 million).

     ifPhysAddress          See Section 3.3.5.











Flick                       Standards Track                     [Page 5]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


     ifAdminStatus          Write access is not required.  Support for
                            'testing' is not required.  Setting this
                            object to 'up' will cause dot12Commands to
                            be set to 'open'.  Setting this object to
                            'down' will cause dot12Commands to be set
                            to 'close'.  Setting dot12Commands to
                            'open' will set this object to 'up'.
                            Setting dot12Commands to 'close' will set
                            this object to 'down'.  Setting
                            dot12Commands to 'reset' will have no
                            effect on this object.

     ifOperStatus           When dot12Status is equal to 'opened', this
                            object will be equal to 'up'.  When
                            dot12Status is equal to 'closed', 'opening',
                            'openFailure' or 'linkFailure', this object
                            will be equal to 'down'.  Support for
                            'testing' is not required, but may be used
                            to indicate that a vendor specific test is
                            in progress.  The value 'dormant' has no
                            meaning for an IEEE 802.12 interface.

     ifLastChange           Refer to [7].

     ifInOctets             The number of octets in valid MAC frames
                            received on this interface, including the
                            MAC header and FCS.

     ifInUcastPkts          Refer to [7].

     ifInDiscards           Refer to [7].

     ifInErrors             The sum for this interface of
                            dot12InIPMErrors,
                            dot12InOversizeFrameErrors,
                            dot12InDataErrors, and any additional
                            internal errors that may occur in an
                            implementation.

     ifInUnknownProtos      Refer to [7].

     ifOutOctets            The number of octets transmitted in MAC
                            frames on this interface, including the MAC
                            header and FCS.

     ifOutUcastPkts         Refer to [7].

     ifOutDiscards          Refer to [7].



Flick                       Standards Track                     [Page 6]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


     ifOutErrors            The number of implementation-specific
                            internal transmit errors on this interface.

     ifName                 Locally-significant textual name for the
                            interface (e.g. vg0).

     ifInMulticastPkts      Refer to [7].  When dot12CurrentFramingType
                            is frameType88025, this count includes
                            packets addressed to functional addresses.

     ifInBroadcastPkts      Refer to [7].

     ifOutMulticastPkts     Refer to [7].  When dot12CurrentFramingType
                            is frameType88025, this count includes
                            packets addressed to functional addresses.

     ifOutBroadcastPkts     Refer to [7].

     ifHCInOctets           64-bit version of ifInOctets.

     ifHCOutOctets          64-bit version of ifOutOctets

     ifHC*Pkts              Not required for 100 MBit interfaces.
                            Future IEEE 802.12 interfaces which operate
                            at higher speeds may require implementation
                            of these counters, but such interfaces are
                            beyond the scope of this memo.

     ifLinkUpDownTrapEnable Refer to [7].  Default is 'enabled'.

     ifHighSpeed            The speed of the interface in millions of
                            bits per second.  For current 802.12
                            implementations, this will be equal to 100.

     ifPromiscuousMode      Reflects whether the interface has
                            successfully trained and is currently
                            operating in promiscuous mode.
                            dot12DesiredPromiscStatus is used to select
                            the promiscuous mode to be requested in the
                            next training attempt.  Setting
                            ifPromiscuousMode will update
                            dot12DesiredPromiscStatus and cause the
                            interface to attempt to retrain using the
                            new promiscuous mode.  After the interface
                            has retrained, ifPromiscuousMode will
                            reflect the mode that is in use, not the
                            mode that was requested.




Flick                       Standards Track                     [Page 7]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


     ifConnectorPresent     This will normally be 'true'.

     ifStackHigherLayer     Refer to section 3.3.1
     ifStackLowerLayer
     ifStackStatus

     ifRcvAddressAddress    Refer to section 3.3.4.
     ifRcvAddressStatus
     ifRcvAddressType

3.4.  Relation to RFC 1643, RFC 1650, and RFC 1748

   An IEEE 802.12 interface can be configured to operate in either
   ethernet or token ring framing mode.  An IEEE 802.12 interface uses
   the frame format for the configured framing mode, but does not use
   the media access protocol for ethernet or token ring.  Instead, IEEE
   802.12 defines its own media access protocol, the Demand Priority
   Access Method (DPAM).

   There are existing standards-track MIB modules for instrumenting
   ethernet-like interfaces and token ring interfaces.  At the time of
   this writing, they are: STD 50, RFC 1643, "Definitions of Managed
   Objects for Ethernet-like Interface Types" [8]; RFC 1650,
   "Definitions of Managed Objects for Ethernet-like Interface Types
   using SMIv2" [9]; and RFC 1748, "IEEE 802.5 MIB using SMIv2" [10].
   These MIB modules are designed to instrument the media access
   protocol for these respective technologies.  Since IEEE 802.12
   interfaces do not implement either of these media access protocols,
   an agent should not implement RFC 1643, RFC 1650, or RFC 1748 for
   IEEE 802.12 interfaces.

3.5.  Relation to RFC 1749

   When an IEEE 802.12 interface is operating in token ring framing
   mode, and the end node supports token ring source routing, the agent
   should implement RFC 1749, the IEEE 802.5 Station Source Routing MIB
   [11] for those interfaces.














Flick                       Standards Track                     [Page 8]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


3.6.  Master Mode Operation

   In an IEEE 802.12 network, "master" devices act as network
   controllers to decide when to grant requesting end-nodes permission
   to transmit.  These master devices may be repeaters, or other active
   controller devices such as switches.

   Devices which do not act as network controllers, such as end-nodes or
   passive switches, are considered to be operating in "slave" mode.

   The dot12ControlMode object indicates if the interface is operating
   in master mode or slave mode.

3.7.  Normal and High Priority Counters

   The IEEE 802.12 interface MIB does not provide normal priority
   transmit counters.  Standardization of normal priority transmit
   counters could not be justified -- ifOutUcastPkts,
   ifOutMulticastPkts, ifOutBroadcastPkts, ifOutOctets,
   dot12OutHighPriorityFrames, and dot12OutHighPriorityOctets should
   suffice.  More precisely, the number of normal priority frames
   transmitted can be calculated as:

       outNormPriorityFrames = ifOutUcastPkts             +
                               ifOutMulticastPkts         +
                               ifOutBroadcastPkts         -
                               dot12OutHighPriorityFrames

   The number of normal priority octets transmitted can be calculated
   as:

       outNormPriorityOctets = ifOutOctets                -
                               dot12OutHighPriorityOctets

   On the other hand, normal priority receive counters are provided.
   The main reason for this is that the normal priority and high
   priority counters include errored frames, whereas the ifIn*Pkts and
   ifInOctets do not include errored frames.  dot12InNormPriorityFrames
   could be calculated, but the calculation is tedious:

       inNormPriorityFrames = ifInUcastPkts              +
                              ifInMulticastPkts          +
                              ifInBroadcastPkts          +
                              dot12InNullAddressedFrames +
                              ifInErrors                 +
                              ifInDiscards               +
                              ifInUnknownProtos          -
                              dot12InHighPriorityFrames



Flick                       Standards Track                     [Page 9]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


   dot12InNormPriorityOctets includes octets in unreadable frames, which
   is not available elsewhere.  The number of octets in unreadable
   frames can be calculated as:

       octetsInUnreadableFrames = dot12InNormPriorityOctets +
                                  dot12InHighPriorityOctets -
                                  ifInOctets

   Also, the total traffic at this interface can be calculated as:

       traffic = dot12InNormPriorityOctets +
                 dot12InHighPriorityOctets +
                 ifOutOctets

   In other words, the normal priority receive counters were deemed
   useful, whereas the normal priority transmit counters can be easily
   calculated from other available counters.

3.8.  IEEE 802.12 Training Frames

   Training frames are special MAC frames that are used only during link
   initialization.  Training frames are initially constructed by the
   device at the lower end of a link, which is the slave mode device for
   the link.  The training frame format is as follows:

       +----+----+------------+--------------+----------+-----+
       | DA | SA | Req Config | Allow Config |   Data   | FCS |
       +----+----+------------+--------------+----------+-----+

               DA = destination address (six octets)
               SA = source address (six octets)
               Req Config = requested configuration (2 octets)
               Allow Config = allowed configuration (2 octets)
               Data = data (594 to 675 octets)
               FCS = frame check sequence (4 octets)

   Training frames are always sent with a null destination address.  To
   pass training, an end node must use its source address in the source
   address field of the training frame.  A repeater may use a non-null
   source address if it has one, or it may use a null source address.











Flick                       Standards Track                    [Page 10]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


   The requested configuration field allows the slave mode device to
   inform the master mode device about itself and to request
   configuration options.  The training response frame from the master
   mode device contains the slave mode device's requested configuration
   from the training request frame.  The currently defined format of the
   requested configuration field as defined in the IEEE Standard
   802.12-1995 standard is shown below.  Please refer to the most
   current version of the IEEE document for a more up to date
   description of this field.  In particular, the reserved bits may be
   used in later versions of the standard.

       First Octet:       Second Octet:

        7 6 5 4 3 2 1 0    7 6 5 4 3 2 1 0
       +-+-+-+-+-+-+-+-+  +-+-+-+-+-+-+-+-+
       |v|v|v|r|r|r|r|r|  |r|r|r|F|F|P|P|R|
       +-+-+-+-+-+-+-+-+  +-+-+-+-+-+-+-+-+

       vvv: The version of the 802.12 training protocol with which
            the training initiator is compliant.  The current version
            is 100.
       r:   Reserved bits (set to zero)
       FF:  00 = frameType88023
            01 = frameType88025
            10 = reserved
            11 = frameTypeEither
       PP:  00 = singleAddressMode
            01 = promiscuousMode
            10 = reserved
            11 = reserved
       R:   0  = the training initiator is an end node
            1  = the training initiator is a repeater

   The allowed configuration field allows the master mode device to
   respond with the allowed configuration.  The slave mode device sets
   the contents of this field to all zero bits.  The master mode device
   sets the allowed configuration field as follows:

       First Octet:       Second Octet:

        7 6 5 4 3 2 1 0    7 6 5 4 3 2 1 0
       +-+-+-+-+-+-+-+-+  +-+-+-+-+-+-+-+-+
       |v|v|v|D|C|N|r|r|  |r|r|r|F|F|P|P|R|
       +-+-+-+-+-+-+-+-+  +-+-+-+-+-+-+-+-+

       vvv: The version of the 802.12 training protocol with which
            the training responder is compliant.  The current version
            is 100.



Flick                       Standards Track                    [Page 11]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


       D:   0  = No duplicate address has been detected.
            1  = Duplicate address has been detected
       C:   0  = The requested configuration is compatible with the
                 network.
            1  = The requested configuration is not compatible with
                 the network.  In this case, the FF, PP, and R bits
                 indicate the configuration that would be allowed.
       N:   0  = Access will be allowed, providing the configuration
                 is compatible (C = 0).
            1  = Access is not granted because of security
                 restrictions
       r:   Reserved bits (set to zero)
       FF:  00 = frameType88023 will be used
            01 = frameType88025 will be used
            10 = reserved
            11 = reserved
       PP:  00 = singleAddressMode
            01 = promiscuousMode
            10 = reserved
            11 = reserved
       R:   0  = Requested access as an end node is allowed
            1  = Requested access as a repeater is allowed

   Again, note that the most recent version of the IEEE 802.12 standard
   should be consulted for the most up to date definition of the
   requested configuration and allowed configuration fields.

   The data field contains between 594 and 675 octets and is filled in
   by the training initiator.  The first 55 octets may be used for
   vendor specific protocol information.  The remaining octets are all
   zeros.  The length of the training frame combined with the
   requirement that 24 consecutive training frames be received without
   error to complete training ensures that marginal links will not
   complete training.

3.9.  Mapping of IEEE 802.12 Managed Objects

   The following table lists all the managed objects defined for
   oEndNode in the IEEE 802.12 Standard, and the corresponding SNMP
   objects.

   IEEE 802.12 Managed Object            Corresponding SNMP Object

   oEndNode
     .aBroadcastFramesReceived           IF-MIB - ifInBroadcastPkts
     .aBroadcastFramesTransmitted        IF-MIB - ifOutBroadcastPkts
     .aDataErrorFramesReceived           dot12InDataErrors
     .aDesiredFramingType                dot12DesiredFramingType



Flick                       Standards Track                    [Page 12]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


     .aDesiredPromiscuousStatus          dot12DesiredPromiscStatus
     .aFramesTransmitted                 IF-MIB - ifOutUCastPkts +
                                                  ifOutMulticastPkts +
                                                  ifOutBroadcastPkts
     .aFramingCapability                 dot12FramingCapability
     .aFunctionalAddresses               IF-MIB - ifRcvAddressTable
     .aHighPriorityFramesReceived        dot12InHighPriorityFrames
     .aHighPriorityFramesTransmitted     dot12OutHighPriorityFrames
     .aHighPriorityOctetsReceived        dot12InHighPriorityOctets or
                                         dot12InHCHighPriorityOctets
     .aHighPriorityOctetsTransmitted     dot12OutHighPriorityOctets or
                                         dot12OutHCHighPriorityOctets
     .aIPMFramesReceived                 dot12InIPMErrors
     .aLastTrainingConfig                dot12LastTrainingConfig
     .aMACID                             IF-MIB - ifIndex
     .aMACStatus                         dot12Status
     .aMACVersion                        dot12TrainingVersion
     .aMediaType                         <not yet mapped>
                                         Tranceiver MIB issue
     .aMulticastFramesReceived           IF-MIB - ifInMulticastPkts
     .aMulticastFramesTransmitted        IF-MIB - ifOutMulticastPkts
     .aMulticastReceiveStatus            IF-MIB - ifRcvAddressTable
     .aNormalPriorityFramesReceived      dot12InNormPriorityFrames
     .aNormalPriorityOctetsReceived      dot12InNormPriorityOctets or
                                         dot12InHCNormPriorityOctets
     .aNullAddressedFramesReceived       dot12InNullAddressedFrames
     .aOctetsTransmitted                 IF-MIB - ifOutOctets or
                                                  ifHCOutOctets
     .aOversizeFramesReceived            dot12InOversizeFrameErrors
     .aReadableFramesReceived            IF-MIB - ifInUcastPkts +
                                                  ifInMulticastPkts +
                                                  ifInBroadcastPkts
     .aReadableOctetsReceived            IF-MIB - ifInOctets or
                                                  ifHCInOctets
     .aReadMulticastList                 IF-MIB - ifRcvAddressTable
     .aReadWriteMACAddress               IF-MIB - ifPhysAddress
     .aTransitionsIntoTraining           dot12TransitionIntoTrainings
     .acAddGroupAddress                  IF-MIB - ifRcvAddressTable
     .acClose                            dot12Commands: 'close'
     .acDeleteGroupAddress               IF-MIB - ifRcvAddressTable
     .acExecuteSelftest                  IF-MIB - ifAdminStatus
     .acInitializeMAC                    dot12Commands: 'reset'
     .acOpen                             dot12Commands: 'open'








Flick                       Standards Track                    [Page 13]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


4.  Definitions

      DOT12-IF-MIB DEFINITIONS ::= BEGIN

          IMPORTS
              transmission, Counter32, Counter64, OBJECT-TYPE,
              MODULE-IDENTITY
                  FROM SNMPv2-SMI
              MODULE-COMPLIANCE, OBJECT-GROUP
                  FROM SNMPv2-CONF
              ifIndex
                  FROM IF-MIB;

          dot12MIB MODULE-IDENTITY
               LAST-UPDATED "9602220452Z"  -- February 22, 1996
               ORGANIZATION "IETF 100VG-AnyLAN MIB Working Group"
               CONTACT-INFO
                       "       John Flick

                       Postal: Hewlett Packard Company
                               8000 Foothills Blvd. M/S 5556
                               Roseville, CA 95747-5556
                       Tel:    +1 916 785 4018
                       Fax:    +1 916 785 3583

                       E-mail: johnf@hprnd.rose.hp.com"
               DESCRIPTION
                       "This MIB module describes objects for
                       managing IEEE 802.12 interfaces."
               ::= { transmission 45 }

          dot12MIBObjects     OBJECT IDENTIFIER ::= { dot12MIB 1 }

          dot12ConfigTable OBJECT-TYPE
              SYNTAX     SEQUENCE OF Dot12ConfigEntry
              MAX-ACCESS not-accessible
              STATUS     current
              DESCRIPTION
                      "Configuration information for a collection of
                      802.12 interfaces attached to a particular
                      system."
              ::= { dot12MIBObjects 1 }

          dot12ConfigEntry OBJECT-TYPE
              SYNTAX     Dot12ConfigEntry
              MAX-ACCESS not-accessible
              STATUS     current
              DESCRIPTION



Flick                       Standards Track                    [Page 14]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      "Configuration for a particular interface to an
                      802.12 medium."
              INDEX      { ifIndex }
              ::= { dot12ConfigTable 1 }

          Dot12ConfigEntry ::=
              SEQUENCE {
                  dot12CurrentFramingType         INTEGER,
                  dot12DesiredFramingType         INTEGER,
                  dot12FramingCapability          INTEGER,
                  dot12DesiredPromiscStatus       INTEGER,
                  dot12TrainingVersion            INTEGER,
                  dot12LastTrainingConfig         OCTET STRING,
                  dot12Commands                   INTEGER,
                  dot12Status                     INTEGER,
                  dot12ControlMode                INTEGER
              }

          dot12CurrentFramingType OBJECT-TYPE
              SYNTAX     INTEGER {
                             frameType88023(1),
                             frameType88025(2),
                             frameTypeUnknown(3)
                         }
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "When dot12DesiredFramingType is one of
                      'frameType88023' or 'frameType88025', this is the
                      type of framing asserted by the interface.

                      When dot12DesiredFramingType is 'frameTypeEither',
                      dot12CurrentFramingType shall be one of
                      'frameType88023' or 'frameType88025' when the
                      dot12Status is 'opened'.   When the dot12Status is
                      anything other than 'opened',
                      dot12CurrentFramingType shall take the value of
                      'frameTypeUnknown'."
              ::= { dot12ConfigEntry 1 }

          dot12DesiredFramingType OBJECT-TYPE
              SYNTAX     INTEGER {
                             frameType88023(1),
                             frameType88025(2),
                             frameTypeEither(3)
                         }
              MAX-ACCESS read-write
              STATUS     current



Flick                       Standards Track                    [Page 15]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


              DESCRIPTION
                      "The type of framing which will be requested by
                      the interface during the next interface MAC
                      initialization or open action.

                      In master mode, this is the framing mode which
                      will be granted by the interface.  Note that
                      for a master mode interface, this object must be
                      equal to 'frameType88023' or 'frameType88025',
                      since a master mode interface cannot grant
                      'frameTypeEither'."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aDesiredFramingType."
              ::= { dot12ConfigEntry 2 }

          dot12FramingCapability OBJECT-TYPE
              SYNTAX     INTEGER {
                             frameType88023(1),
                             frameType88025(2),
                             frameTypeEither(3)
                         }
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "The type of framing this interface is capable of
                      supporting."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aFramingCapability."
              ::= { dot12ConfigEntry 3 }

          dot12DesiredPromiscStatus OBJECT-TYPE
              SYNTAX     INTEGER {
                             singleAddressMode(1),
                             promiscuousMode(2)
                         }
              MAX-ACCESS read-write
              STATUS     current
              DESCRIPTION
                      "This object is used to select the promiscuous
                      mode that this interface will request in the next
                      training packet issued on this interface.
                      Whether the repeater grants the requested mode
                      must be verified by examining the state of the PP
                      bits in the corresponding instance of
                      dot12LastTrainingConfig.




Flick                       Standards Track                    [Page 16]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      In master mode, this object controls whether or
                      not promiscuous mode will be granted by the
                      interface when requested by the lower level
                      device.

                      Note that this object indicates the desired mode
                      for the next time the interface trains.  The
                      currently active mode will be reflected in
                      dot12LastTrainingConfig and in ifPromiscuousMode."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aDesiredPromiscuousStatus."
              ::= { dot12ConfigEntry 4 }

          dot12TrainingVersion OBJECT-TYPE
              SYNTAX     INTEGER (0..7)
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "The value that will be used in the version bits
                      (vvv bits) in training frames on this interface.
                      This is the highest version number supported by
                      this MAC."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aMACVersion."
              ::= { dot12ConfigEntry 5 }

          dot12LastTrainingConfig OBJECT-TYPE
              SYNTAX     OCTET STRING (SIZE(2))
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This 16 bit field contains the configuration
                      bits from the most recent error-free training
                      frame received during training on this interface.
                      Training request frames are received when in
                      master mode, while training response frames are
                      received in slave mode.  On master mode interfaces,
                      this object contains the contents of the
                      requested configuration field of the most recent
                      training request frame.  On slave mode interfaces,
                      this object contains the contents of the allowed
                      configuration field of the most recent training
                      response frame.  The format of the current version
                      of this field is described in section 3.8.  Please
                      refer to the most recent version of the IEEE
                      802.12 standard for the most up-to-date definition



Flick                       Standards Track                    [Page 17]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      of the format of this object."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aLastTrainingConfig."
              ::= { dot12ConfigEntry 6 }

          dot12Commands OBJECT-TYPE
              SYNTAX     INTEGER {
                             noOp(1),
                             open(2),
                             reset(3),
                             close(4)
                         }
              MAX-ACCESS read-write
              STATUS     current
              DESCRIPTION
                      "If the current value of dot12Status is 'closed',
                      setting the value of this object to 'open' will
                      change the corresponding instance of MIB-II's
                      ifAdminStatus to 'up', cause this interface to
                      enter the 'opening' state, and will cause training
                      to be initiated on this interface.  The progress
                      and success of the open is given by the values of
                      the dot12Status object.  Setting this object to
                      'open' when dot12Status has a value other than
                      'closed' has no effect.

                      Setting the corresponding instance of ifAdminStatus
                      to 'up' when the current value of dot12Status is
                      'closed' will have the same effect as setting this
                      object to 'open'.  Setting ifAdminStatus to 'up'
                      when dot12Status has a value other than 'closed'
                      has no effect.

                      Setting the value of this object to 'close' will
                      move this interface into the 'closed' state and
                      cause all transmit and receive actions to stop.
                      This object will then have to be set to 'open' in
                      order to reinitiate training.

                      Setting the corresponding instance of ifAdminStatus
                      to 'down' will have the same effect as setting this
                      object to 'close'.

                      Setting the value of this object to 'reset' when
                      the current value of dot12Status has a value other
                      than 'closed' will reset the interface.  On a
                      reset, all MIB counters should retain their values.



Flick                       Standards Track                    [Page 18]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      This will cause the MAC to initiate an
                      acInitializeMAC action as specified in IEEE 802.12.
                      This will cause training to be reinitiated on this
                      interface.  Setting this object to 'reset' when
                      dot12Status has a value of 'closed' has no effect.
                      Setting this object to 'reset' has no effect on the
                      corresponding instance of ifAdminStatus.

                      Setting the value of this object to 'noOp' has no
                      effect.

                      When read, this object will always have a value
                      of 'noOp'."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.2,
                      acOpen, acClose, acInitializeMAC.
                      Also, RFC1231 IEEE802.5 Token Ring MIB,
                      dot5Commands."
              ::= { dot12ConfigEntry 7 }

          dot12Status OBJECT-TYPE
              SYNTAX     INTEGER {
                             opened(1),
                             closed(2),
                             opening(3),
                             openFailure(5),
                             linkFailure(6)
                         }
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "The current interface status with respect to
                      training.  One of the following values:

                          opened      - Training has completed
                                        successfully.
                          closed      - MAC has been disabled by
                                        setting dot12Commands to
                                        'close'.
                          opening     - MAC is in training.  Training
                                        signals have been received.
                          openFailure - Passed 24 error-free packets,
                                        but there is a problem, noted
                                        in the training configuration
                                        bits (dot12LastTrainingConfig).
                          linkFailure - Training signals not received,
                                        or could not pass 24 error-free
                                        packets.



Flick                       Standards Track                    [Page 19]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      Whenever the dot12Commands object is set to
                      'close' or ifAdminStatus is set to 'down', the MAC
                      will go silent, dot12Status will be 'closed', and
                      ifOperStatus will be 'down'.

                      When the value of this object is equal to 'closed'
                      and the dot12Commands object is set to 'open' or
                      the ifAdminStatus object is set to 'up', training
                      will be initiated on this interface.  When the
                      value of this object is not equal to 'closed' and
                      the dot12Commands object is set to 'reset',
                      training will be reinitiated on this interface.
                      Note that sets of some other objects (e.g.
                      dot12ControlMode) or external events (e.g. MAC
                      protocol violations) may also cause training to be
                      reinitiated on this interface.

                      When training is initiated or reinitiated on an
                      interface, the end node will send Training_Up to
                      the master and initially go to the 'linkFailure'
                      state and ifOperStatus will go to 'down'.
                      When the master sends back Training_Down,
                      dot12Status will change to the 'opening' state,
                      and training packets will be transferred.

                      After all of the training packets have been
                      passed, dot12Status will change to 'linkFailure'
                      if 24 consecutive error-free packets were not
                      passed, 'opened' if 24 consecutive error-free
                      packets were passed and the training
                      configuration bits were OK, or 'openFailure' if
                      there were 24 consecutive error-free packets, but
                      there was a problem with the training
                      configuration bits.

                      When in the 'openFailure' state, the
                      dot12LastTrainingConfig object will contain the
                      configuration bits from the last training
                      packet which can be examined to determine the
                      exact reason for the training configuration
                      failure.

                      If training did not succeed (dot12Status is
                      'linkFailure' or 'openFailure), the entire
                      process will be restarted after
                      MAC_Retraining_Delay_Timer seconds.

                      If training does succeed (dot12Status changes to



Flick                       Standards Track                    [Page 20]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      'opened'), ifOperStatus will change to 'up'.  If
                      training does not succeed (dot12Status changes to
                      'linkFailure' or 'openFailure'), ifOperStatus will
                      remain 'down'."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aMACStatus."
              ::= { dot12ConfigEntry 8 }

          dot12ControlMode OBJECT-TYPE
              SYNTAX     INTEGER {
                             masterMode(1),
                             slaveMode(2),
                             learn(3)
                         }
              MAX-ACCESS read-write
              STATUS     current
              DESCRIPTION
                      "This object is used to configure and report
                      whether or not this interface is operating in
                      master mode.  In a Demand Priority network, end
                      node interfaces typically operate in slave mode,
                      while switch interfaces may control the Demand
                      Priority protocol and operate in master mode.

                      This object may be implemented as a read-only
                      object by those agents and interfaces that do not
                      implement software control of master mode.  In
                      particular, interfaces that cannot operate in
                      master mode, and interfaces on which master mode
                      is controlled by a pushbutton on the device,
                      should implement this object read-only.

                      Some interfaces do not require network management
                      configuration of this feature and can autosense
                      whether to use master mode or slave mode.  The
                      value 'learn' is used for that purpose.  While
                      autosense is taking place, the value 'learn' is
                      returned.

                      A network management operation which modifies the
                      value of dot12ControlMode causes the interface
                      to retrain."
              ::= { dot12ConfigEntry 9 }

          dot12StatTable OBJECT-TYPE
              SYNTAX     SEQUENCE OF Dot12StatEntry
              MAX-ACCESS not-accessible



Flick                       Standards Track                    [Page 21]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


              STATUS     current
              DESCRIPTION
                      "Statistics for a collection of 802.12 interfaces
                      attached to a particular system."
              ::= { dot12MIBObjects 2 }

          dot12StatEntry OBJECT-TYPE
              SYNTAX     Dot12StatEntry
              MAX-ACCESS not-accessible
              STATUS     current
              DESCRIPTION
                      "Statistics for a particular interface to an
                      802.12 medium.  The receive statistics in this
                      table apply only to packets received by this
                      station (i.e., packets whose destination address
                      is either the local station address, the
                      broadcast address, or a multicast address that
                      this station is receiving, unless the station is
                      in promiscuous mode)."
              INDEX      { ifIndex }
              ::= { dot12StatTable 1 }

          Dot12StatEntry ::=
              SEQUENCE {
                  dot12InHighPriorityFrames       Counter32,
                  dot12InHighPriorityOctets       Counter32,
                  dot12InNormPriorityFrames       Counter32,
                  dot12InNormPriorityOctets       Counter32,
                  dot12InIPMErrors                Counter32,
                  dot12InOversizeFrameErrors      Counter32,
                  dot12InDataErrors               Counter32,
                  dot12InNullAddressedFrames      Counter32,
                  dot12OutHighPriorityFrames      Counter32,
                  dot12OutHighPriorityOctets      Counter32,
                  dot12TransitionIntoTrainings    Counter32,
                  dot12HCInHighPriorityOctets     Counter64,
                  dot12HCInNormPriorityOctets     Counter64,
                  dot12HCOutHighPriorityOctets    Counter64
              }

          dot12InHighPriorityFrames OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of high priority frames
                      that have been received on this interface.
                      Includes both good and bad high priority frames,



Flick                       Standards Track                    [Page 22]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      as well as high priority training frames.  Does
                      not include normal priority frames which were
                      priority promoted."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aHighPriorityFramesReceived."
              ::= { dot12StatEntry 1 }

          dot12InHighPriorityOctets OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of the number of octets
                      contained in high priority frames that have been
                      received on this interface. This counter is
                      incremented by OctetCount for each frame received
                      on this interface which is counted by
                      dot12InHighPriorityFrames.

                      Note that this counter will roll over very
                      quickly.  It is provided for backward
                      compatibility for Network Management protocols
                      that do not support 64 bit counters (e.g. SNMP
                      version 1)."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aHighPriorityOctetsReceived."
              ::= { dot12StatEntry 2 }

          dot12InNormPriorityFrames OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of normal priority frames
                      that have been received on this interface.
                      Includes both good and bad normal priority
                      frames, as well as normal priority training
                      frames and normal priority frames which were
                      priority promoted."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aNormalPriorityFramesReceived."
              ::= { dot12StatEntry 3 }

          dot12InNormPriorityOctets OBJECT-TYPE
              SYNTAX     Counter32



Flick                       Standards Track                    [Page 23]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of the number of octets
                      contained in normal priority frames that have
                      been received on this interface. This counter is
                      incremented by OctetCount for each frame received
                      on this interface which is counted by
                      dot12InNormPriorityFrames.

                      Note that this counter will roll over very
                      quickly.  It is provided for backward
                      compatibility for Network Management protocols
                      that do not support 64 bit counters (e.g. SNMP
                      version 1)."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aNormalPriorityOctetsReceived."
              ::= { dot12StatEntry 4 }

          dot12InIPMErrors OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of the number of frames
                      that have been received on this interface with an
                      invalid packet marker and no PMI errors.  A
                      repeater will write an invalid packet marker to
                      the end of a frame containing errors as it is
                      forwarded through the repeater to the other
                      ports.  This counter is incremented by one for
                      each frame received on this interface which has
                      had an invalid packet marker added to the end of
                      the frame."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aIPMFramesReceived."
              ::= { dot12StatEntry 5 }

          dot12InOversizeFrameErrors OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of oversize frames
                      received on this interface.  This counter is
                      incremented by one for each frame received on



Flick                       Standards Track                    [Page 24]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      this interface whose OctetCount is larger than
                      the maximum legal frame size.  The frame size
                      which causes this counter to increment is
                      dependent on the current framing type."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aOversizeFramesReceived."
              ::= { dot12StatEntry 6 }

          dot12InDataErrors OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of errored frames
                      received on this interface.  This counter is
                      incremented by one for each frame received on
                      this interface with any of the following errors:
                      bad FCS (with no IPM), PMI errors (excluding
                      frames with an IPM as the only PMI error),
                      undersize, bad start of frame delimiter, or bad
                      end of packet marker.  Does not include frames
                      counted by dot12InIPMErrors,
                      dot12InNullAddressedFrames, or
                      dot12InOversizeFrameErrors.

                      This counter indicates problems with the cable
                      directly attached to this interface, while
                      dot12InIPMErrors indicates problems with remote
                      cables."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aDataErrorFramesReceived."
              ::= { dot12StatEntry 7 }

          dot12InNullAddressedFrames OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of null addressed frames
                      received on this interface.  This counter is
                      incremented by one for each frame received on
                      this interface with a destination MAC address
                      consisting of all zero bits.  Both void and
                      training frames are included in this counter.

                      Note that since this station would normally not



Flick                       Standards Track                    [Page 25]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      receive null addressed frames, this counter is
                      only incremented when this station is operating
                      in promiscuous mode or in training."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aNullAddressedFramesReceived."
              ::= { dot12StatEntry 8 }

          dot12OutHighPriorityFrames OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This counter is incremented by one for each high
                      priority frame successfully transmitted out this
                      interface."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aHighPriorityFramesTransmitted."
              ::= { dot12StatEntry 9 }

          dot12OutHighPriorityOctets OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This counter is incremented by OctetCount for
                      each frame counted by dot12OutHighPriorityFrames.

                      Note that this counter will roll over very
                      quickly.  It is provided for backward
                      compatibility for Network Management protocols
                      that do not support 64 bit counters (e.g. SNMP
                      version 1)."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aHighPriorityOctetsTransmitted."
              ::= { dot12StatEntry 10 }

          dot12TransitionIntoTrainings OBJECT-TYPE
              SYNTAX     Counter32
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of the number of times
                      this interface has entered the training state.
                      This counter is incremented by one each time
                      dot12Status transitions to 'linkFailure' from any



Flick                       Standards Track                    [Page 26]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                      state other than 'opening' or 'openFailure'."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aTransitionsIntoTraining."
              ::= { dot12StatEntry 11 }

          dot12HCInHighPriorityOctets OBJECT-TYPE
              SYNTAX     Counter64
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of the number of octets
                      contained in high priority frames that have been
                      received on this interface. This counter is
                      incremented by OctetCount for each frame received
                      on this interface which is counted by
                      dot12InHighPriorityFrames.

                      This counter is a 64 bit version of
                      dot12InHighPriorityOctets.  It should be used by
                      Network Management protocols which support 64 bit
                      counters (e.g. SNMPv2)."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aHighPriorityOctetsReceived."
              ::= { dot12StatEntry 12 }

          dot12HCInNormPriorityOctets OBJECT-TYPE
              SYNTAX     Counter64
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This object is a count of the number of octets
                      contained in normal priority frames that have
                      been received on this interface. This counter is
                      incremented by OctetCount for each frame received
                      on this interface which is counted by
                      dot12InNormPriorityFrames.

                      This counter is a 64 bit version of
                      dot12InNormPriorityOctets.  It should be used by
                      Network Management protocols which support 64 bit
                      counters (e.g. SNMPv2)."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aNormalPriorityOctetsReceived."
              ::= { dot12StatEntry 13 }




Flick                       Standards Track                    [Page 27]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


          dot12HCOutHighPriorityOctets OBJECT-TYPE
              SYNTAX     Counter64
              MAX-ACCESS read-only
              STATUS     current
              DESCRIPTION
                      "This counter is incremented by OctetCount for
                      each frame counted by dot12OutHighPriorityFrames.

                      This counter is a 64 bit version of
                      dot12OutHighPriorityOctets.  It should be used by
                      Network Management protocols which support 64 bit
                      counters (e.g. SNMPv2)."
              REFERENCE
                      "IEEE Standard 802.12-1995, 13.2.5.2.1,
                      aHighPriorityOctetsTransmitted."
             ::= { dot12StatEntry 14 }

          -- conformance information

          dot12Conformance  OBJECT IDENTIFIER ::= { dot12MIB 2 }

          dot12Compliances  OBJECT IDENTIFIER ::= { dot12Conformance 1 }
          dot12Groups       OBJECT IDENTIFIER ::= { dot12Conformance 2 }

          -- compliance statements

          dot12Compliance MODULE-COMPLIANCE
              STATUS     current
              DESCRIPTION
                         "The compliance statement for managed network
                         entities that have 802.12 interfaces."

              MODULE  -- this module
                  MANDATORY-GROUPS { dot12ConfigGroup, dot12StatsGroup }

                  OBJECT       dot12DesiredFramingType
                  MIN-ACCESS   read-only
                  DESCRIPTION
                         "Write access to this object is not required."

                  OBJECT       dot12DesiredPromiscStatus
                  MIN-ACCESS   read-only
                  DESCRIPTION
                         "Write access to this object is not required."

                  OBJECT       dot12Commands
                  MIN-ACCESS   read-only
                  DESCRIPTION



Flick                       Standards Track                    [Page 28]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


                         "Write access to this object is not required."

                  OBJECT       dot12ControlMode
                  MIN-ACCESS   read-only
                  DESCRIPTION
                         "Write access to this object is not required."
              ::= { dot12Compliances 1 }

          -- units of conformance

          dot12ConfigGroup OBJECT-GROUP
              OBJECTS    { dot12DesiredFramingType,
                           dot12FramingCapability,
                           dot12DesiredPromiscStatus,
                           dot12TrainingVersion,
                           dot12LastTrainingConfig,
                           dot12Commands, dot12Status,
                           dot12CurrentFramingType,
                           dot12ControlMode }
              STATUS     current
              DESCRIPTION
                      "A collection of objects for managing the status
                      and configuration of IEEE 802.12 interfaces."
              ::= { dot12Groups 1 }

          dot12StatsGroup OBJECT-GROUP
              OBJECTS    { dot12InHighPriorityFrames,
                           dot12InHighPriorityOctets,
                           dot12InNormPriorityFrames,
                           dot12InNormPriorityOctets,
                           dot12InIPMErrors,
                           dot12InOversizeFrameErrors,
                           dot12InDataErrors,
                           dot12InNullAddressedFrames,
                           dot12OutHighPriorityFrames,
                           dot12OutHighPriorityOctets,
                           dot12TransitionIntoTrainings,
                           dot12HCInHighPriorityOctets,
                           dot12HCInNormPriorityOctets,
                           dot12HCOutHighPriorityOctets }
              STATUS     current
              DESCRIPTION
                      "A collection of objects providing statistics for
                      IEEE 802.12 interfaces."
              ::= { dot12Groups 2 }

      END




Flick                       Standards Track                    [Page 29]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


5.  Acknowledgements

   This document was produced by the IETF 100VG-AnyLAN Working Group.
   It is based on the work of IEEE 802.12.

6.  References

   [1]  Information processing systems - Open Systems Interconnection -
        Specification of Abstract Syntax Notation One (ASN.1),
        International Organization for Standardization.  International
        Standard 8824 (December, 1987).

   [2]  SNMPv2 Working Group, Case, J., McCloghrie, K., Rose, M., and
        S. Waldbusser, "Structure of Management Information for Version
        2 of the Simple Network Management Protocol (SNMPv2)", RFC 1902,
        SNMP Research, Inc., Cisco Systems, Inc., Dover Beach
        Consulting, Inc., International Network Services, January 1996.

   [3]  SNMPv2 Working Group, Case, J., McCloghrie, K., Rose, M., and
        S. Waldbusser, "Textual Conventions for Version 2 of the Simple
        Network Management Protocol (SNMPv2)", RFC 1903, SNMP Research,
        Inc., Cisco Systems, Inc., Dover Beach Consulting, Inc.,
        International Network Services, January 1996.

   [4]  SNMPv2 Working Group, Case, J., McCloghrie, K., Rose, M., and
        S. Waldbusser, "Conformance Statements for Version 2 of the
        Simple Network Management Protocol (SNMPv2)", RFC 1904, SNMP
        Research, Inc., Cisco Systems, Inc., Dover Beach Consulting,
        Inc., International Network Services, January 1996.

   [5]  McCloghrie, K., and M. Rose, "Management Information Base for
        Network Management of TCP/IP-based internets - MIB-II", STD 17,
        RFC 1213, Hughes LAN Systems, Performance Systems International,
        March 1991.

   [6]  IEEE, "Demand Priority Access Method, Physical Layer and
        Repeater Specifications for 100 Mb/s Operation", IEEE Standard
        802.12-1995"

   [7]  McCloghrie, K., and Kastenholz, F., "Evolution of the Interfaces
        Group of MIB-II", RFC 1573, Hughes LAN Systems, FTP Software,
        January 1994.

   [8]  Kastenholz, F., "Definitions of Managed Objects for the
        Ethernet-like Interface Types", STD 50, RFC 1643, FTP Software,
        Inc., July, 1994.





Flick                       Standards Track                    [Page 30]


RFC 2020               IEEE 802.12 Interface MIB            October 1996


   [9]  Kastenholz, F., "Definitions of Managed Objects for the
        Ethernet-like Interface Types using SMIv2", RFC 1650, FTP
        Software, Inc., August, 1994.

   [10] McCloghrie, K., and Decker, E., "IEEE 802.5 MIB using SMIv2",
        RFC 1748, Cisco Systems, Inc., December, 1994.

   [11] McCloghrie, K., Baker, F., and Decker, E., "IEEE 802.5 Station
        Source Routing MIB using SMIv2", RFC 1749, Cisco Systems, Inc.,
        December, 1994.

7.  Security Considerations

   Security issues are not discussed in this memo.

8.  Author's Address

   John Flick
   Hewlett Packard Company
   8000 Foothills Blvd. M/S 5556
   Roseville, CA 95747-5556

   Phone: +1 916 785 4018
   Email: johnf@hprnd.rose.hp.com



























Flick                       Standards Track                    [Page 31]


Hosting by: Hurra Communications Ltd.
Generated: 2007-01-26 17:59:08