RFC 2819 Remote Network Monitoring Management Information Base

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INTERNET STANDARD
Errata Exist
Network Working Group                                       S. Waldbusser
Request for Comments: 2819                            Lucent Technologies
STD: 59                                                          May 2000
Obsoletes: 1757
Category: Standards Track


         Remote Network Monitoring Management Information Base

Status of this Memo

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

Copyright Notice

   Copyright (C) The Internet Society (2000).  All Rights Reserved.

Abstract

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

   This memo obsoletes RFC 1757. This memo extends that specification by
   documenting the RMON MIB in SMIv2 format while remaining semantically
   identical to the existing SMIv1-based MIB.




















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Table of Contents

   1 The SNMP Management Framework ..............................   2
   2 Overview ...................................................   3
   2.1 Remote Network Management Goals ..........................   4
   2.2 Textual Conventions ......................................   5
   2.3 Structure of MIB .........................................   5
   2.3.1 The Ethernet Statistics Group ..........................   6
   2.3.2 The History Control Group ..............................   6
   2.3.3 The Ethernet History Group .............................   6
   2.3.4 The Alarm Group ........................................   7
   2.3.5 The Host Group .........................................   7
   2.3.6 The HostTopN Group .....................................   7
   2.3.7 The Matrix Group .......................................   7
   2.3.8 The Filter Group .......................................   7
   2.3.9 The Packet Capture Group ...............................   8
   2.3.10 The Event Group .......................................   8
   3 Control of Remote Network Monitoring Devices ...............   8
   3.1  Resource  Sharing  Among Multiple Management Stations ...   9
   3.2 Row Addition Among Multiple Management Stations ..........  10
   4 Conventions ................................................  11
   5 Definitions ................................................  12
   6 Security Considerations ....................................  94
   7 Acknowledgments ............................................  95
   8 Author's Address ...........................................  95
   9 References .................................................  95
   10 Intellectual Property .....................................  97
   11 Full Copyright Statement ..................................  98

1.  The SNMP Management Framework

   The SNMP Management Framework presently consists of five major
   components:

   o  An overall architecture, described in RFC 2571 [1].

   o  Mechanisms for describing and naming objects and events for the
      purpose of management. The first version of this Structure of
      Management Information (SMI) is called SMIv1 and described in STD
      16, RFC 1155 [2], STD 16, RFC 1212 [3] and RFC 1215 [4]. The
      second version, called SMIv2, is described in STD 58, RFC 2578
      [5], RFC 2579 [6] and RFC 2580 [7].

   o  Message protocols for transferring management information. The
      first version of the SNMP message protocol is called SNMPv1 and
      described in STD 15, RFC 1157 [8]. A second version of the SNMP
      message protocol, which is not an Internet standards track
      protocol, is called SNMPv2c and described in RFC 1901 [9] and RFC



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      1906 [10]. The third version of the message protocol is called
      SNMPv3 and described in RFC 1906 [10], RFC 2572 [11] and RFC 2574
      [12].

   o  Protocol operations for accessing management information. The
      first set of protocol operations and associated PDU formats is
      described in STD 15, RFC 1157 [8]. A second set of protocol
      operations and associated PDU formats is described in RFC 1905
      [13].

   o  A set of fundamental applications described in RFC 2573 [14] and
      the view-based access control mechanism described in RFC 2575
      [15].

   A more detailed introduction to the current SNMP Management Framework
   can be found in RFC 2570 [22].

   Managed objects are accessed via a virtual information store, termed
   the Management Information Base or MIB.  Objects in the MIB are
   defined using the mechanisms defined in the SMI.

   This memo specifies a MIB module that is compliant to the SMIv2. A
   MIB conforming to the SMIv1 can be produced through the appropriate
   translations. The resulting translated MIB must be semantically
   equivalent, except where objects or events are omitted because no
   translation is possible (use of Counter64). Some machine readable
   information in SMIv2 will be converted into textual descriptions in
   SMIv1 during the translation process.  However, this loss of machine
   readable information is not considered to change the semantics of the
   MIB.

2.  Overview

   Remote network monitoring devices, often called monitors or probes,
   are instruments that exist for the purpose of managing a network.
   Often these remote probes are stand-alone devices and devote
   significant internal resources for the sole purpose of managing a
   network.  An organization may employ many of these devices, one per
   network segment, to manage its internet.  In addition, these devices
   may be used for a network management service provider to access a
   client network, often geographically remote.

   The objects defined in this document are intended as an interface
   between an RMON agent and an RMON management application and are not
   intended for direct manipulation by humans.  While some users may
   tolerate the direct display of some of these objects, few will





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   tolerate the complexity of manually manipulating objects to
   accomplish row creation.  These functions should be handled by the
   management application.

   While most of the objects in this document are suitable for the
   management of any type of network, there are some which are specific
   to managing Ethernet networks.  These are the objects in the
   etherStatsTable, the etherHistoryTable, and some attributes of the
   filterPktStatus and capturBufferPacketStatus objects.  The design of
   this MIB allows similar objects to be defined for other network
   types.  It is intended that future versions of this document and
   additional documents will define extensions for other network types.

   There are a number of companion documents to the RMON MIB. The Token
   Ring RMON MIB [19] provides objects specific to managing Token Ring
   networks. The RMON-2 MIB [20] extends RMON by providing RMON analysis
   up to the application layer. The SMON MIB [21] extends RMON by
   providing RMON analysis for switched networks.

2.1.  Remote Network Management Goals

   o  Offline Operation
        There are sometimes conditions when a management station will
        not be in constant contact with its remote monitoring devices.
        This is sometimes by design in an attempt to lower
        communications costs (especially when communicating over a WAN
        or dialup link), or by accident as network failures affect the
        communications between the management station and the probe.

        For this reason, this MIB allows a probe to be configured to
        perform diagnostics and to collect statistics continuously, even
        when communication with the management station may not be
        possible or efficient.  The probe may then attempt to notify the
        management station when an exceptional condition occurs.  Thus,
        even in circumstances where communication between management
        station and probe is not continuous, fault, performance, and
        configuration information may be continuously accumulated and
        communicated to the management station conveniently and
        efficiently.

   o  Proactive Monitoring
        Given the resources available on the monitor, it is potentially
        helpful for it continuously to run diagnostics and to log
        network performance.  The monitor is always available at the
        onset of any failure.  It can notify the management station of
        the failure and can store historical statistical information





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        about the failure.  This historical information can be played
        back by the management station in an attempt to perform further
        diagnosis into the cause of the problem.

   o  Problem Detection and Reporting
        The monitor can be configured to recognize conditions, most
        notably error conditions, and continuously to check for them.
        When one of these conditions occurs, the event may be logged,
        and management stations may be notified in a number of ways.

   o  Value Added Data
        Because a remote monitoring device represents a network resource
        dedicated exclusively to network management functions, and
        because it is located directly on the monitored portion of the
        network, the remote network monitoring device has the
        opportunity to add significant value to the data it collects.
        For instance, by highlighting those hosts on the network that
        generate the most traffic or errors, the probe can give the
        management station precisely the information it needs to solve a
        class of problems.

   o  Multiple Managers
        An organization may have multiple management stations for
        different units of the organization, for different functions
        (e.g. engineering and operations), and in an attempt to provide
        disaster recovery.  Because environments with multiple
        management stations are common, the remote network monitoring
        device has to deal with more than own management station,
        potentially using its resources concurrently.

2.2.  Textual Conventions

   Two new data types are introduced as a textual convention in this MIB
   document, OwnerString and EntryStatus.

2.3.  Structure of MIB

   The objects are arranged into the following groups:

         - ethernet statistics

         - history control

         - ethernet history

         - alarm

         - host



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         - hostTopN

         - matrix

         - filter

         - packet capture

         - event

   These groups are the basic unit of conformance.  If a remote
   monitoring device implements a group, then it must implement all
   objects in that group.  For example, a managed agent that implements
   the host group must implement the hostControlTable, the hostTable and
   the hostTimeTable. While this section provides an overview of
   grouping and conformance information for this MIB, the authoritative
   reference for such information is contained in the MODULE-COMPLIANCE
   and OBJECT-GROUP macros later in this MIB.

   All groups in this MIB are optional.  Implementations of this MIB
   must also implement the system group of MIB-II [16] and the IF-MIB
   [17].  MIB-II may also mandate the implementation of additional
   groups.

   These groups are defined to provide a means of assigning object
   identifiers, and to provide a method for implementors of managed
   agents to know which objects they must implement.

2.3.1.  The Ethernet Statistics Group

   The ethernet statistics group contains statistics measured by the
   probe for each monitored Ethernet interface on this device.  This
   group consists of the etherStatsTable.

2.3.2.  The History Control Group

   The history control group controls the periodic statistical sampling
   of data from various types of networks.  This group consists of the
   historyControlTable.

2.3.3.  The Ethernet History Group

   The ethernet history group records periodic statistical samples from
   an ethernet network and stores them for later retrieval.  This group
   consists of the etherHistoryTable.






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2.3.4.  The Alarm Group

   The alarm group periodically takes statistical samples from variables
   in the probe and compares them to previously configured thresholds.
   If the monitored variable crosses a threshold, an event is generated.

   A hysteresis mechanism is implemented to limit the generation of
   alarms.  This group consists of the alarmTable and requires the
   implementation of the event group.

2.3.5.  The Host Group

   The host group contains statistics associated with each host
   discovered on the network.  This group discovers hosts on the network
   by keeping a list of source and destination MAC Addresses seen in
   good packets promiscuously received from the network.  This group
   consists of the hostControlTable, the hostTable, and the
   hostTimeTable.

2.3.6.  The HostTopN Group

   The hostTopN group is used to prepare reports that describe the hosts
   that top a list ordered by one of their statistics.  The available
   statistics are samples of one of their base statistics over an
   interval specified by the management station.  Thus, these statistics
   are rate based.  The management station also selects how many such
   hosts are reported.  This group consists of the hostTopNControlTable
   and the hostTopNTable, and requires the implementation of the host
   group.

2.3.7.  The Matrix Group

   The matrix group stores statistics for conversations between sets of
   two addresses.  As the device detects a new conversation, it creates
   a new entry in its tables.  This group consists of the
   matrixControlTable, the matrixSDTable and the matrixDSTable.

2.3.8.  The Filter Group

   The filter group allows packets to be matched by a filter equation.
   These matched packets form a data stream that may be captured or may
   generate events.  This group consists of the filterTable and the
   channelTable.








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2.3.9.  The Packet Capture Group

   The Packet Capture group allows packets to be captured after they
   flow through a channel.  This group consists of the
   bufferControlTable and the captureBufferTable, and requires the
   implementation of the filter group.

2.3.10.  The Event Group

   The event group controls the generation and notification of events
   from this device.  This group consists of the eventTable and the
   logTable.

3.  Control of Remote Network Monitoring Devices

   Due to the complex nature of the available functions in these
   devices, the functions often need user configuration.  In many cases,
   the function requires parameters to be set up for a data collection
   operation.  The operation can proceed only after these parameters are
   fully set up.

   Many functional groups in this MIB have one or more tables in which
   to set up control parameters, and one or more data tables in which to
   place the results of the operation.  The control tables are typically
   read-write in nature, while the data tables are typically read-only.
   Because the parameters in the control table often describe resulting
   data in the data table, many of the parameters can be modified only
   when the control entry is invalid.  Thus, the method for modifying
   these parameters is to invalidate the control entry, causing its
   deletion and the deletion of any associated data entries, and then
   create a new control entry with the proper parameters.  Deleting the
   control entry also gives a convenient method for reclaiming the
   resources used by the associated data.

   Some objects in this MIB provide a mechanism to execute an action on
   the remote monitoring device.  These objects may execute an action as
   a result of a change in the state of the object.  For those objects
   in this MIB, a request to set an object to the same value as it
   currently holds would thus cause no action to occur.

   To facilitate control by multiple managers, resources have to be
   shared among the managers.  These resources are typically the memory
   and computation resources that a function requires.








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3.1.  Resource Sharing Among Multiple Management Stations

   When multiple management stations wish to use functions that compete
   for a finite amount of resources on a device, a method to facilitate
   this sharing of resources is required.  Potential conflicts include:

      o  Two management stations wish to simultaneously use resources
         that together would exceed the capability of the device.
      o  A management station uses a significant amount of resources for
         a long period of time.
      o  A management station uses resources and then crashes,
         forgetting to free the resources so others may use them.

   A mechanism is provided for each management station initiated
   function in this MIB to avoid these conflicts and to help resolve
   them when they occur.  Each function has a label identifying the
   initiator (owner) of the function.  This label is set by the
   initiator to provide for the following possibilities:

      o  A management station may recognize resources it owns and no
         longer needs.
      o  A network operator can find the management station that owns
         the resource and negotiate for it to be freed.
      o  A network operator may decide to unilaterally free resources
         another network operator has reserved.
      o  Upon initialization, a management station may recognize
         resources it had reserved in the past.  With this information
         it may free the resources if it no longer needs them.

   Management stations and probes should support any format of the owner
   string dictated by the local policy of the organization.  It is
   suggested that this name contain one or more of the following: IP
   address, management station name, network manager's name, location,
   or phone number.  This information will help users to share the
   resources more effectively.

   There is often default functionality that the device or the
   administrator of the probe (often the network administrator) wishes
   to set up.  The resources associated with this functionality are then
   owned by the device itself or by the network administrator, and are
   intended to be long-lived.  In this case, the device or the
   administrator will set the relevant owner object to a string starting
   with 'monitor'.  Indiscriminate modification of the monitor-owned
   configuration by network management stations is discouraged.  In
   fact, a network management station should only modify these objects
   under the direction of the administrator of the probe.





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   Resources on a probe are scarce and are typically allocated when
   control rows are created by an application.  Since many applications
   may be using a probe simultaneously, indiscriminate allocation of
   resources to particular applications is very likely to cause resource
   shortages in the probe.

   When a network management station wishes to utilize a function in a
   monitor, it is encouraged to first scan the control table of that
   function to find an instance with similar parameters to share.  This
   is especially true for those instances owned by the monitor, which
   can be assumed to change infrequently.  If a management station
   decides to share an instance owned by another management station, it
   should understand that the management station that owns the instance
   may indiscriminately modify or delete it.

   It should be noted that a management application should have the most
   trust in a monitor-owned row because it should be changed very
   infrequently.  A row owned by the management application is less
   long-lived because a network administrator is more likely to re-
   assign resources from a row that is in use by one user than from a
   monitor-owned row that is potentially in use by many users.  A row
   owned by another application would be even less long-lived because
   the other application may delete or modify that row completely at its
   discretion.

3.2.  Row Addition Among Multiple Management Stations

   The addition of new rows is achieved using the method described in
   RFC 1905 [13].  In this MIB, rows are often added to a table in order
   to configure a function.  This configuration usually involves
   parameters that control the operation of the function.  The agent
   must check these parameters to make sure they are appropriate given
   restrictions defined in this MIB as well as any implementation
   specific restrictions such as lack of resources.  The agent
   implementor may be confused as to when to check these parameters and
   when to signal to the management station that the parameters are
   invalid.  There are two opportunities:

      o  When the management station sets each parameter object.

      o  When the management station sets the entry status object to
         valid.

   If the latter is chosen, it would be unclear to the management
   station which of the several parameters was invalid and caused the
   badValue error to be emitted.  Thus, wherever possible, the
   implementor should choose the former as it will provide more
   information to the management station.



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   A problem can arise when multiple management stations attempt to set
   configuration information simultaneously using SNMP.  When this
   involves the addition of a new conceptual row in the same control
   table, the managers may collide, attempting to create the same entry.
   To guard against these collisions, each such control entry contains a
   status object with special semantics that help to arbitrate among the
   managers.  If an attempt is made with the row addition mechanism to
   create such a status object and that object already exists, an error
   is returned.  When more than one manager simultaneously attempts to
   create the same conceptual row, only the first can succeed.  The
   others will receive an error.

   When a manager wishes to create a new control entry, it needs to
   choose an index for that row.  It may choose this index in a variety
   of ways, hopefully minimizing the chances that the index is in use by
   another manager.  If the index is in use, the mechanism mentioned
   previously will guard against collisions.  Examples of schemes to
   choose index values include random selection or scanning the control
   table looking for the first unused index.  Because index values may
   be any valid value in the range and they are chosen by the manager,
   the agent must allow a row to be created with any unused index value
   if it has the resources to create a new row.

   Some tables in this MIB reference other tables within this MIB.  When
   creating or deleting entries in these tables, it is generally
   allowable for dangling references to exist.  There is no defined
   order for creating or deleting entries in these tables.

4.  Conventions

   The following conventions are used throughout the RMON MIB and its
   companion documents.

   Good Packets

   Good packets are error-free packets that have a valid frame length.
   For example, on Ethernet, good packets are error-free packets that
   are between 64 octets long and 1518 octets long.  They follow the
   form defined in IEEE 802.3 section 3.2.all.

   Bad Packets

   Bad packets are packets that have proper framing and are therefore
   recognized as packets, but contain errors within the packet or have
   an invalid length.  For example, on Ethernet, bad packets have a
   valid preamble and SFD, but have a bad CRC, or are either shorter
   than 64 octets or longer than 1518 octets.




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5.  Definitions

 RMON-MIB DEFINITIONS ::= BEGIN

     IMPORTS
         MODULE-IDENTITY, OBJECT-TYPE, OBJECT-IDENTITY,
         NOTIFICATION-TYPE, mib-2, Counter32,
         Integer32, TimeTicks                   FROM SNMPv2-SMI

         TEXTUAL-CONVENTION, DisplayString      FROM SNMPv2-TC

         MODULE-COMPLIANCE, OBJECT-GROUP,
         NOTIFICATION-GROUP                     FROM SNMPv2-CONF;


 --  Remote Network Monitoring MIB

 rmonMibModule MODULE-IDENTITY
     LAST-UPDATED "200005110000Z"  -- 11 May, 2000
     ORGANIZATION "IETF RMON MIB Working Group"
     CONTACT-INFO
         "Steve Waldbusser
         Phone: +1-650-948-6500
         Fax:   +1-650-745-0671
         Email: waldbusser@nextbeacon.com"
     DESCRIPTION
         "Remote network monitoring devices, often called
         monitors or probes, are instruments that exist for
         the purpose of managing a network. This MIB defines
         objects for managing remote network monitoring devices."

     REVISION "200005110000Z"    -- 11 May, 2000
     DESCRIPTION
         "Reformatted into SMIv2 format.

         This version published as RFC 2819."

     REVISION "199502010000Z" -- 1 Feb, 1995
     DESCRIPTION
         "Bug fixes, clarifications and minor changes based on
         implementation experience, published as RFC1757 [18].

         Two changes were made to object definitions:

         1) A new status bit has been defined for the
         captureBufferPacketStatus object, indicating that the
         packet order within the capture buffer may not be identical to
         the packet order as received off the wire.  This bit may only



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         be used for packets transmitted by the probe.  Older NMS
         applications can safely ignore this status bit, which might be
         used by newer agents.

         2) The packetMatch trap has been removed.  This trap was never
         actually 'approved' and was not added to this document along
         with the risingAlarm and fallingAlarm traps. The packetMatch
         trap could not be throttled, which could cause disruption of
         normal network traffic under some circumstances. An NMS should
         configure a risingAlarm threshold on the appropriate
         channelMatches instance if a trap is desired for a packetMatch
         event. Note that logging of packetMatch events is still
         supported--only trap generation for such events has been
         removed.

         In addition, several clarifications to individual object
         definitions have been added to assist agent and NMS
         implementors:

         - global definition of 'good packets' and 'bad packets'

         - more detailed text governing conceptual row creation and
           modification

         - instructions for probes relating to interface changes and
           disruptions

         - clarification of some ethernet counter definitions

         - recommended formula for calculating network utilization

         - clarification of channel and captureBuffer behavior for some
           unusual conditions

         - examples of proper instance naming for each table"

     REVISION "199111010000Z"    -- 1 Nov, 1991
     DESCRIPTION
         "The original version of this MIB, published as RFC1271."
     ::= { rmonConformance 8 }

     rmon    OBJECT IDENTIFIER ::= { mib-2 16 }


     -- textual conventions

 OwnerString ::= TEXTUAL-CONVENTION
     STATUS current



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     DESCRIPTION
         "This data type is used to model an administratively
         assigned name of the owner of a resource. Implementations
         must accept values composed of well-formed NVT ASCII
         sequences. In addition, implementations should accept
         values composed of well-formed UTF-8 sequences.

         It is suggested that this name contain one or more of
         the following: IP address, management station name,
         network manager's name, location, or phone number.
         In some cases the agent itself will be the owner of
         an entry.  In these cases, this string shall be set
         to a string starting with 'monitor'.

         SNMP access control is articulated entirely in terms
         of the contents of MIB views; access to a particular
         SNMP object instance depends only upon its presence
         or absence in a particular MIB view and never upon
         its value or the value of related object instances.
         Thus, objects of this type afford resolution of
         resource contention only among cooperating
         managers; they realize no access control function
         with respect to uncooperative parties."
     SYNTAX OCTET STRING (SIZE (0..127))

 EntryStatus ::= TEXTUAL-CONVENTION
     STATUS current
     DESCRIPTION
         "The status of a table entry.

         Setting this object to the value invalid(4) has the
         effect of invalidating the corresponding entry.
         That is, it effectively disassociates the mapping
         identified with said entry.
         It is an implementation-specific matter as to whether
         the agent removes an invalidated entry from the table.
         Accordingly, management stations must be prepared to
         receive tabular information from agents that corresponds
         to entries currently not in use.  Proper
         interpretation of such entries requires examination
         of the relevant EntryStatus object.

         An existing instance of this object cannot be set to
         createRequest(2).  This object may only be set to
         createRequest(2) when this instance is created.  When
         this object is created, the agent may wish to create
         supplemental object instances with default values
         to complete a conceptual row in this table.  Because the



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         creation of these default objects is entirely at the option
         of the agent, the manager must not assume that any will be
         created, but may make use of any that are created.
         Immediately after completing the create operation, the agent
         must set this object to underCreation(3).

         When in the underCreation(3) state, an entry is allowed to
         exist in a possibly incomplete, possibly inconsistent state,
         usually to allow it to be modified in multiple PDUs.  When in
         this state, an entry is not fully active.
         Entries shall exist in the underCreation(3) state until
         the management station is finished configuring the entry
         and sets this object to valid(1) or aborts, setting this
         object to invalid(4).  If the agent determines that an
         entry has been in the underCreation(3) state for an
         abnormally long time, it may decide that the management
         station has crashed.  If the agent makes this decision,
         it may set this object to invalid(4) to reclaim the
         entry.  A prudent agent will understand that the
         management station may need to wait for human input
         and will allow for that possibility in its
         determination of this abnormally long period.

         An entry in the valid(1) state is fully configured and
         consistent and fully represents the configuration or
         operation such a row is intended to represent.  For
         example, it could be a statistical function that is
         configured and active, or a filter that is available
         in the list of filters processed by the packet capture
         process.

         A manager is restricted to changing the state of an entry in
         the following ways:

              To:       valid  createRequest  underCreation  invalid
         From:
         valid             OK             NO             OK       OK
         createRequest    N/A            N/A            N/A      N/A
         underCreation     OK             NO             OK       OK
         invalid           NO             NO             NO       OK
         nonExistent       NO             OK             NO       OK

         In the table above, it is not applicable to move the state
         from the createRequest state to any other state because the
         manager will never find the variable in that state.  The
         nonExistent state is not a value of the enumeration, rather
         it means that the entryStatus variable does not exist at all.




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         An agent may allow an entryStatus variable to change state in
         additional ways, so long as the semantics of the states are
         followed.  This allowance is made to ease the implementation of
         the agent and is made despite the fact that managers should
         never exercise these additional state transitions."
     SYNTAX INTEGER {
                valid(1),
                createRequest(2),
                underCreation(3),
                invalid(4)
            }

     statistics        OBJECT IDENTIFIER ::= { rmon 1 }
     history           OBJECT IDENTIFIER ::= { rmon 2 }
     alarm             OBJECT IDENTIFIER ::= { rmon 3 }
     hosts             OBJECT IDENTIFIER ::= { rmon 4 }
     hostTopN          OBJECT IDENTIFIER ::= { rmon 5 }
     matrix            OBJECT IDENTIFIER ::= { rmon 6 }
     filter            OBJECT IDENTIFIER ::= { rmon 7 }
     capture           OBJECT IDENTIFIER ::= { rmon 8 }
     event             OBJECT IDENTIFIER ::= { rmon 9 }
     rmonConformance   OBJECT IDENTIFIER ::= { rmon 20 }

 -- The Ethernet Statistics Group
 --
 -- Implementation of the Ethernet Statistics group is optional.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The ethernet statistics group contains statistics measured by the
 -- probe for each monitored interface on this device.  These
 -- statistics take the form of free running counters that start from
 -- zero when a valid entry is created.
 --
 -- This group currently has statistics defined only for
 -- Ethernet interfaces.  Each etherStatsEntry contains statistics
 -- for one Ethernet interface.  The probe must create one
 -- etherStats entry for each monitored Ethernet interface
 -- on the device.

 etherStatsTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF EtherStatsEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of Ethernet statistics entries."
     ::= { statistics 1 }




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 etherStatsEntry OBJECT-TYPE
     SYNTAX     EtherStatsEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A collection of statistics kept for a particular
         Ethernet interface.  As an example, an instance of the
         etherStatsPkts object might be named etherStatsPkts.1"
     INDEX { etherStatsIndex }
     ::= { etherStatsTable 1 }

 EtherStatsEntry ::= SEQUENCE {
     etherStatsIndex                    Integer32,
     etherStatsDataSource               OBJECT IDENTIFIER,
     etherStatsDropEvents               Counter32,
     etherStatsOctets                   Counter32,
     etherStatsPkts                     Counter32,
     etherStatsBroadcastPkts            Counter32,
     etherStatsMulticastPkts            Counter32,
     etherStatsCRCAlignErrors           Counter32,
     etherStatsUndersizePkts            Counter32,
     etherStatsOversizePkts             Counter32,
     etherStatsFragments                Counter32,
     etherStatsJabbers                  Counter32,
     etherStatsCollisions               Counter32,
     etherStatsPkts64Octets             Counter32,
     etherStatsPkts65to127Octets        Counter32,
     etherStatsPkts128to255Octets       Counter32,
     etherStatsPkts256to511Octets       Counter32,
     etherStatsPkts512to1023Octets      Counter32,
     etherStatsPkts1024to1518Octets     Counter32,
     etherStatsOwner                    OwnerString,
     etherStatsStatus                   EntryStatus
 }

 etherStatsIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The value of this object uniquely identifies this
         etherStats entry."
     ::= { etherStatsEntry 1 }

 etherStatsDataSource OBJECT-TYPE
     SYNTAX     OBJECT IDENTIFIER
     MAX-ACCESS read-create
     STATUS     current



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     DESCRIPTION
         "This object identifies the source of the data that
         this etherStats entry is configured to analyze.  This
         source can be any ethernet interface on this device.
         In order to identify a particular interface, this object
         shall identify the instance of the ifIndex object,
         defined in RFC 2233 [17], for the desired interface.
         For example, if an entry were to receive data from
         interface #1, this object would be set to ifIndex.1.

         The statistics in this group reflect all packets
         on the local network segment attached to the identified
         interface.

         An agent may or may not be able to tell if fundamental
         changes to the media of the interface have occurred and
         necessitate an invalidation of this entry.  For example, a
         hot-pluggable ethernet card could be pulled out and replaced
         by a token-ring card.  In such a case, if the agent has such
         knowledge of the change, it is recommended that it
         invalidate this entry.

         This object may not be modified if the associated
         etherStatsStatus object is equal to valid(1)."
     ::= { etherStatsEntry 2 }

 etherStatsDropEvents OBJECT-TYPE
     SYNTAX     Counter32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of events in which packets
         were dropped by the probe due to lack of resources.
         Note that this number is not necessarily the number of
         packets dropped; it is just the number of times this
         condition has been detected."
     ::= { etherStatsEntry 3 }

 etherStatsOctets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of octets of data (including
         those in bad packets) received on the
         network (excluding framing bits but including
         FCS octets).



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         This object can be used as a reasonable estimate of
         10-Megabit ethernet utilization.  If greater precision is
         desired, the etherStatsPkts and etherStatsOctets objects
         should be sampled before and after a common interval.  The
         differences in the sampled values are Pkts and Octets,
         respectively, and the number of seconds in the interval is
         Interval.  These values are used to calculate the Utilization
         as follows:

                          Pkts * (9.6 + 6.4) + (Octets * .8)
          Utilization = -------------------------------------
                                  Interval * 10,000

         The result of this equation is the value Utilization which
         is the percent utilization of the ethernet segment on a
         scale of 0 to 100 percent."
     ::= { etherStatsEntry 4 }

 etherStatsPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets (including bad packets,
         broadcast packets, and multicast packets) received."
     ::= { etherStatsEntry 5 }

 etherStatsBroadcastPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of good packets received that were
         directed to the broadcast address.  Note that this
         does not include multicast packets."
     ::= { etherStatsEntry 6 }

 etherStatsMulticastPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of good packets received that were
         directed to a multicast address.  Note that this number
         does not include packets directed to the broadcast



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         address."
     ::= { etherStatsEntry 7 }

 etherStatsCRCAlignErrors OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets received that
         had a length (excluding framing bits, but
         including FCS octets) of between 64 and 1518
         octets, inclusive, but had either a bad
         Frame Check Sequence (FCS) with an integral
         number of octets (FCS Error) or a bad FCS with
         a non-integral number of octets (Alignment Error)."
     ::= { etherStatsEntry 8 }

 etherStatsUndersizePkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets received that were
         less than 64 octets long (excluding framing bits,
         but including FCS octets) and were otherwise well
         formed."
     ::= { etherStatsEntry 9 }

 etherStatsOversizePkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets received that were
         longer than 1518 octets (excluding framing bits,
         but including FCS octets) and were otherwise
         well formed."
     ::= { etherStatsEntry 10 }

 etherStatsFragments OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION



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         "The total number of packets received that were less than
         64 octets in length (excluding framing bits but including
         FCS octets) and had either a bad Frame Check Sequence
         (FCS) with an integral number of octets (FCS Error) or a
         bad FCS with a non-integral number of octets (Alignment
         Error).

         Note that it is entirely normal for etherStatsFragments to
         increment.  This is because it counts both runts (which are
         normal occurrences due to collisions) and noise hits."
     ::= { etherStatsEntry 11 }

 etherStatsJabbers OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets received that were
         longer than 1518 octets (excluding framing bits,
         but including FCS octets), and had either a bad
         Frame Check Sequence (FCS) with an integral number
         of octets (FCS Error) or a bad FCS with a non-integral
         number of octets (Alignment Error).

         Note that this definition of jabber is different
         than the definition in IEEE-802.3 section 8.2.1.5
         (10BASE5) and section 10.3.1.4 (10BASE2).  These
         documents define jabber as the condition where any
         packet exceeds 20 ms.  The allowed range to detect
         jabber is between 20 ms and 150 ms."
     ::= { etherStatsEntry 12 }

 etherStatsCollisions OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Collisions"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The best estimate of the total number of collisions
         on this Ethernet segment.

         The value returned will depend on the location of the
         RMON probe. Section 8.2.1.3 (10BASE-5) and section
         10.3.1.3 (10BASE-2) of IEEE standard 802.3 states that a
         station must detect a collision, in the receive mode, if
         three or more stations are transmitting simultaneously.  A
         repeater port must detect a collision when two or more



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         stations are transmitting simultaneously.  Thus a probe
         placed on a repeater port could record more collisions
         than a probe connected to a station on the same segment
         would.

         Probe location plays a much smaller role when considering
         10BASE-T.  14.2.1.4 (10BASE-T) of IEEE standard 802.3
         defines a collision as the simultaneous presence of signals
         on the DO and RD circuits (transmitting and receiving
         at the same time).  A 10BASE-T station can only detect
         collisions when it is transmitting.  Thus probes placed on
         a station and a repeater, should report the same number of
         collisions.

         Note also that an RMON probe inside a repeater should
         ideally report collisions between the repeater and one or
         more other hosts (transmit collisions as defined by IEEE
         802.3k) plus receiver collisions observed on any coax
         segments to which the repeater is connected."
     ::= { etherStatsEntry 13 }

 etherStatsPkts64Octets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets (including bad
         packets) received that were 64 octets in length
         (excluding framing bits but including FCS octets)."
     ::= { etherStatsEntry 14 }

 etherStatsPkts65to127Octets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets (including bad
         packets) received that were between
         65 and 127 octets in length inclusive
         (excluding framing bits but including FCS octets)."
     ::= { etherStatsEntry 15 }

 etherStatsPkts128to255Octets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only



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     STATUS     current
     DESCRIPTION
         "The total number of packets (including bad
         packets) received that were between
         128 and 255 octets in length inclusive
         (excluding framing bits but including FCS octets)."
     ::= { etherStatsEntry 16 }

 etherStatsPkts256to511Octets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets (including bad
         packets) received that were between
         256 and 511 octets in length inclusive
         (excluding framing bits but including FCS octets)."
     ::= { etherStatsEntry 17 }

 etherStatsPkts512to1023Octets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets (including bad
         packets) received that were between
         512 and 1023 octets in length inclusive
         (excluding framing bits but including FCS octets)."
     ::= { etherStatsEntry 18 }

 etherStatsPkts1024to1518Octets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets (including bad
         packets) received that were between
         1024 and 1518 octets in length inclusive
         (excluding framing bits but including FCS octets)."
     ::= { etherStatsEntry 19 }

 etherStatsOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current



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     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."
     ::= { etherStatsEntry 20 }

 etherStatsStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this etherStats entry."
     ::= { etherStatsEntry 21 }

 -- The History Control Group

 -- Implementation of the History Control group is optional.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The history control group controls the periodic statistical
 -- sampling of data from various types of networks.  The
 -- historyControlTable stores configuration entries that each
 -- define an interface, polling period, and other parameters.
 -- Once samples are taken, their data is stored in an entry
 -- in a media-specific table.  Each such entry defines one
 -- sample, and is associated with the historyControlEntry that
 -- caused the sample to be taken.  Each counter in the
 -- etherHistoryEntry counts the same event as its similarly-named
 -- counterpart in the etherStatsEntry, except that each value here
 -- is a cumulative sum during a sampling period.
 --
 -- If the probe keeps track of the time of day, it should start
 -- the first sample of the history at a time such that
 -- when the next hour of the day begins, a sample is
 -- started at that instant.  This tends to make more
 -- user-friendly reports, and enables comparison of reports
 -- from different probes that have relatively accurate time
 -- of day.
 --
 -- The probe is encouraged to add two history control entries
 -- per monitored interface upon initialization that describe a short
 -- term and a long term polling period.  Suggested parameters are 30
 -- seconds for the short term polling period and 30 minutes for
 -- the long term period.

 historyControlTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF HistoryControlEntry
     MAX-ACCESS not-accessible



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     STATUS     current
     DESCRIPTION
         "A list of history control entries."
     ::= { history 1 }

 historyControlEntry OBJECT-TYPE
     SYNTAX     HistoryControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of parameters that set up a periodic sampling of
         statistics.  As an example, an instance of the
         historyControlInterval object might be named
         historyControlInterval.2"
     INDEX { historyControlIndex }
     ::= { historyControlTable 1 }

 HistoryControlEntry ::= SEQUENCE {
     historyControlIndex             Integer32,
     historyControlDataSource        OBJECT IDENTIFIER,
     historyControlBucketsRequested  Integer32,
     historyControlBucketsGranted    Integer32,
     historyControlInterval          Integer32,
     historyControlOwner             OwnerString,
     historyControlStatus            EntryStatus
 }

 historyControlIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry in the
         historyControl table.  Each such entry defines a
         set of samples at a particular interval for an
         interface on the device."
     ::= { historyControlEntry 1 }

 historyControlDataSource OBJECT-TYPE
     SYNTAX     OBJECT IDENTIFIER
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "This object identifies the source of the data for
         which historical data was collected and
         placed in a media-specific table on behalf of this
         historyControlEntry.  This source can be any
         interface on this device.  In order to identify



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         a particular interface, this object shall identify
         the instance of the ifIndex object, defined
         in  RFC 2233 [17], for the desired interface.
         For example, if an entry were to receive data from
         interface #1, this object would be set to ifIndex.1.

         The statistics in this group reflect all packets
         on the local network segment attached to the identified
         interface.

         An agent may or may not be able to tell if fundamental
         changes to the media of the interface have occurred and
         necessitate an invalidation of this entry.  For example, a
         hot-pluggable ethernet card could be pulled out and replaced
         by a token-ring card.  In such a case, if the agent has such
         knowledge of the change, it is recommended that it
         invalidate this entry.

         This object may not be modified if the associated
         historyControlStatus object is equal to valid(1)."
     ::= { historyControlEntry 2 }

 historyControlBucketsRequested OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The requested number of discrete time intervals
         over which data is to be saved in the part of the
         media-specific table associated with this
         historyControlEntry.

         When this object is created or modified, the probe
         should set historyControlBucketsGranted as closely to
         this object as is possible for the particular probe
         implementation and available resources."
     DEFVAL { 50 }
     ::= { historyControlEntry 3 }

 historyControlBucketsGranted OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of discrete sampling intervals
         over which data shall be saved in the part of
         the media-specific table associated with this
         historyControlEntry.



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         When the associated historyControlBucketsRequested
         object is created or modified, the probe
         should set this object as closely to the requested
         value as is possible for the particular
         probe implementation and available resources.  The
         probe must not lower this value except as a result
         of a modification to the associated
         historyControlBucketsRequested object.

         There will be times when the actual number of
         buckets associated with this entry is less than
         the value of this object.  In this case, at the
         end of each sampling interval, a new bucket will
         be added to the media-specific table.

         When the number of buckets reaches the value of
         this object and a new bucket is to be added to the
         media-specific table, the oldest bucket associated
         with this historyControlEntry shall be deleted by
         the agent so that the new bucket can be added.

         When the value of this object changes to a value less
         than the current value, entries are deleted
         from the media-specific table associated with this
         historyControlEntry.  Enough of the oldest of these
         entries shall be deleted by the agent so that their
         number remains less than or equal to the new value of
         this object.

         When the value of this object changes to a value greater
         than the current value, the number of associated media-
         specific entries may be allowed to grow."
     ::= { historyControlEntry 4 }

 historyControlInterval OBJECT-TYPE
     SYNTAX     Integer32 (1..3600)
     UNITS      "Seconds"
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The interval in seconds over which the data is
         sampled for each bucket in the part of the
         media-specific table associated with this
         historyControlEntry.  This interval can
         be set to any number of seconds between 1 and
         3600 (1 hour).

         Because the counters in a bucket may overflow at their



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         maximum value with no indication, a prudent manager will
         take into account the possibility of overflow in any of
         the associated counters.  It is important to consider the
         minimum time in which any counter could overflow on a
         particular media type and set the historyControlInterval
         object to a value less than this interval.  This is
         typically most important for the 'octets' counter in any
         media-specific table.  For example, on an Ethernet
         network, the etherHistoryOctets counter could overflow
         in about one hour at the Ethernet's maximum
         utilization.

         This object may not be modified if the associated
         historyControlStatus object is equal to valid(1)."
     DEFVAL { 1800 }
     ::= { historyControlEntry 5 }

 historyControlOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."
     ::= { historyControlEntry 6 }

 historyControlStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this historyControl entry.

         Each instance of the media-specific table associated
         with this historyControlEntry will be deleted by the agent
         if this historyControlEntry is not equal to valid(1)."
     ::= { historyControlEntry 7 }

 -- The Ethernet History Group

 -- Implementation of the Ethernet History group is optional.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The Ethernet History group records periodic statistical samples
 -- from a network and stores them for later retrieval.
 -- Once samples are taken, their data is stored in an entry
 -- in a media-specific table.  Each such entry defines one



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 -- sample, and is associated with the historyControlEntry that
 -- caused the sample to be taken.  This group defines the
 -- etherHistoryTable, for Ethernet networks.
 --

 etherHistoryTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF EtherHistoryEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of Ethernet history entries."
     ::= { history 2 }

 etherHistoryEntry OBJECT-TYPE
     SYNTAX     EtherHistoryEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "An historical sample of Ethernet statistics on a particular
         Ethernet interface.  This sample is associated with the
         historyControlEntry which set up the parameters for
         a regular collection of these samples.  As an example, an
         instance of the etherHistoryPkts object might be named
         etherHistoryPkts.2.89"
     INDEX { etherHistoryIndex , etherHistorySampleIndex }
     ::= { etherHistoryTable 1 }

 EtherHistoryEntry ::= SEQUENCE {
     etherHistoryIndex                 Integer32,
     etherHistorySampleIndex           Integer32,
     etherHistoryIntervalStart         TimeTicks,
     etherHistoryDropEvents            Counter32,
     etherHistoryOctets                Counter32,
     etherHistoryPkts                  Counter32,
     etherHistoryBroadcastPkts         Counter32,
     etherHistoryMulticastPkts         Counter32,
     etherHistoryCRCAlignErrors        Counter32,
     etherHistoryUndersizePkts         Counter32,
     etherHistoryOversizePkts          Counter32,
     etherHistoryFragments             Counter32,
     etherHistoryJabbers               Counter32,
     etherHistoryCollisions            Counter32,
     etherHistoryUtilization           Integer32
 }

 etherHistoryIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only



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     STATUS     current
     DESCRIPTION
         "The history of which this entry is a part.  The
         history identified by a particular value of this
         index is the same history as identified
         by the same value of historyControlIndex."
     ::= { etherHistoryEntry 1 }

 etherHistorySampleIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..2147483647)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies the particular
         sample this entry represents among all samples
         associated with the same historyControlEntry.
         This index starts at 1 and increases by one
         as each new sample is taken."
     ::= { etherHistoryEntry 2 }

 etherHistoryIntervalStart OBJECT-TYPE
     SYNTAX     TimeTicks
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The value of sysUpTime at the start of the interval
         over which this sample was measured.  If the probe
         keeps track of the time of day, it should start
         the first sample of the history at a time such that
         when the next hour of the day begins, a sample is
         started at that instant.  Note that following this
         rule may require the probe to delay collecting the
         first sample of the history, as each sample must be
         of the same interval.  Also note that the sample which
         is currently being collected is not accessible in this
         table until the end of its interval."
     ::= { etherHistoryEntry 3 }

 etherHistoryDropEvents OBJECT-TYPE
     SYNTAX     Counter32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of events in which packets
         were dropped by the probe due to lack of resources
         during this sampling interval.  Note that this number
         is not necessarily the number of packets dropped, it
         is just the number of times this condition has been



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         detected."
     ::= { etherHistoryEntry 4 }

 etherHistoryOctets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of octets of data (including
         those in bad packets) received on the
         network (excluding framing bits but including
         FCS octets)."
     ::= { etherHistoryEntry 5 }

 etherHistoryPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets (including bad packets)
         received during this sampling interval."
     ::= { etherHistoryEntry 6 }

 etherHistoryBroadcastPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of good packets received during this
         sampling interval that were directed to the
         broadcast address."
     ::= { etherHistoryEntry 7 }

 etherHistoryMulticastPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of good packets received during this
         sampling interval that were directed to a
         multicast address.  Note that this number does not
         include packets addressed to the broadcast address."
     ::= { etherHistoryEntry 8 }




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 etherHistoryCRCAlignErrors OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets received during this
         sampling interval that had a length (excluding
         framing bits but including FCS octets) between
         64 and 1518 octets, inclusive, but had either a bad Frame
         Check Sequence (FCS) with an integral number of octets
         (FCS Error) or a bad FCS with a non-integral number
         of octets (Alignment Error)."
     ::= { etherHistoryEntry 9 }

 etherHistoryUndersizePkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets received during this
         sampling interval that were less than 64 octets
         long (excluding framing bits but including FCS
         octets) and were otherwise well formed."
     ::= { etherHistoryEntry 10 }

 etherHistoryOversizePkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets received during this
         sampling interval that were longer than 1518
         octets (excluding framing bits but including
         FCS octets) but were otherwise well formed."
     ::= { etherHistoryEntry 11 }

 etherHistoryFragments OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The total number of packets received during this
         sampling interval that were less than 64 octets in
         length (excluding framing bits but including FCS



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         octets) had either a bad Frame Check Sequence (FCS)
         with an integral number of octets (FCS Error) or a bad
         FCS with a non-integral number of octets (Alignment
         Error).

         Note that it is entirely normal for etherHistoryFragments to
         increment.  This is because it counts both runts (which are
         normal occurrences due to collisions) and noise hits."
     ::= { etherHistoryEntry 12 }

 etherHistoryJabbers OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets received during this
         sampling interval that were longer than 1518 octets
         (excluding framing bits but including FCS octets),
         and  had either a bad Frame Check Sequence (FCS)
         with an integral number of octets (FCS Error) or
         a bad FCS with a non-integral number of octets
         (Alignment Error).

         Note that this definition of jabber is different
         than the definition in IEEE-802.3 section 8.2.1.5
         (10BASE5) and section 10.3.1.4 (10BASE2).  These
         documents define jabber as the condition where any
         packet exceeds 20 ms.  The allowed range to detect
         jabber is between 20 ms and 150 ms."
     ::= { etherHistoryEntry 13 }

 etherHistoryCollisions OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Collisions"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The best estimate of the total number of collisions
         on this Ethernet segment during this sampling
         interval.

         The value returned will depend on the location of the
         RMON probe. Section 8.2.1.3 (10BASE-5) and section
         10.3.1.3 (10BASE-2) of IEEE standard 802.3 states that a
         station must detect a collision, in the receive mode, if
         three or more stations are transmitting simultaneously.  A
         repeater port must detect a collision when two or more



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         stations are transmitting simultaneously.  Thus a probe
         placed on a repeater port could record more collisions
         than a probe connected to a station on the same segment
         would.

         Probe location plays a much smaller role when considering
         10BASE-T.  14.2.1.4 (10BASE-T) of IEEE standard 802.3
         defines a collision as the simultaneous presence of signals
         on the DO and RD circuits (transmitting and receiving
         at the same time).  A 10BASE-T station can only detect
         collisions when it is transmitting.  Thus probes placed on
         a station and a repeater, should report the same number of
         collisions.

         Note also that an RMON probe inside a repeater should
         ideally report collisions between the repeater and one or
         more other hosts (transmit collisions as defined by IEEE
         802.3k) plus receiver collisions observed on any coax
         segments to which the repeater is connected."
     ::= { etherHistoryEntry 14 }

 etherHistoryUtilization OBJECT-TYPE
     SYNTAX     Integer32 (0..10000)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The best estimate of the mean physical layer
         network utilization on this interface during this
         sampling interval, in hundredths of a percent."
     ::= { etherHistoryEntry 15 }

 -- The Alarm Group

 -- Implementation of the Alarm group is optional. The Alarm Group
 -- requires the implementation of the Event group.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The Alarm group periodically takes statistical samples from
 -- variables in the probe and compares them to thresholds that have
 -- been configured.  The alarm table stores configuration
 -- entries that each define a variable, polling period, and
 -- threshold parameters.  If a sample is found to cross the
 -- threshold values, an event is generated.  Only variables that
 -- resolve to an ASN.1 primitive type of INTEGER (INTEGER, Integer32,
 -- Counter32, Counter64, Gauge32, or TimeTicks) may be monitored in
 -- this way.
 --



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 -- This function has a hysteresis mechanism to limit the generation
 -- of events.  This mechanism generates one event as a threshold
 -- is crossed in the appropriate direction.  No more events are
 -- generated for that threshold until the opposite threshold is
 -- crossed.
 --
 -- In the case of a sampling a deltaValue, a probe may implement
 -- this mechanism with more precision if it takes a delta sample
 -- twice per period, each time comparing the sum of the latest two
 -- samples to the threshold.  This allows the detection of threshold
 -- crossings that span the sampling boundary.  Note that this does
 -- not require any special configuration of the threshold value.
 -- It is suggested that probes implement this more precise algorithm.

 alarmTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF AlarmEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of alarm entries."
     ::= { alarm 1 }

 alarmEntry OBJECT-TYPE
     SYNTAX     AlarmEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of parameters that set up a periodic checking
         for alarm conditions.  For example, an instance of the
         alarmValue object might be named alarmValue.8"
     INDEX { alarmIndex }
     ::= { alarmTable 1 }

 AlarmEntry ::= SEQUENCE {
     alarmIndex                    Integer32,
     alarmInterval                 Integer32,
     alarmVariable                 OBJECT IDENTIFIER,
     alarmSampleType               INTEGER,
     alarmValue                    Integer32,
     alarmStartupAlarm             INTEGER,
     alarmRisingThreshold          Integer32,
     alarmFallingThreshold         Integer32,
     alarmRisingEventIndex         Integer32,
     alarmFallingEventIndex        Integer32,
     alarmOwner                    OwnerString,
     alarmStatus                   EntryStatus
 }




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 alarmIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry in the
         alarm table.  Each such entry defines a
         diagnostic sample at a particular interval
         for an object on the device."
     ::= { alarmEntry 1 }

 alarmInterval OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Seconds"
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The interval in seconds over which the data is
         sampled and compared with the rising and falling
         thresholds.  When setting this variable, care
         should be taken in the case of deltaValue
         sampling - the interval should be set short enough
         that the sampled variable is very unlikely to
         increase or decrease by more than 2^31 - 1 during
         a single sampling interval.

         This object may not be modified if the associated
         alarmStatus object is equal to valid(1)."
     ::= { alarmEntry 2 }

 alarmVariable OBJECT-TYPE
     SYNTAX     OBJECT IDENTIFIER
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The object identifier of the particular variable to be
         sampled.  Only variables that resolve to an ASN.1 primitive
         type of INTEGER (INTEGER, Integer32, Counter32, Counter64,
         Gauge, or TimeTicks) may be sampled.

         Because SNMP access control is articulated entirely
         in terms of the contents of MIB views, no access
         control mechanism exists that can restrict the value of
         this object to identify only those objects that exist
         in a particular MIB view.  Because there is thus no
         acceptable means of restricting the read access that
         could be obtained through the alarm mechanism, the
         probe must only grant write access to this object in



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         those views that have read access to all objects on
         the probe.

         During a set operation, if the supplied variable name is
         not available in the selected MIB view, a badValue error
         must be returned.  If at any time the variable name of
         an established alarmEntry is no longer available in the
         selected MIB view, the probe must change the status of
         this alarmEntry to invalid(4).

         This object may not be modified if the associated
         alarmStatus object is equal to valid(1)."
     ::= { alarmEntry 3 }

 alarmSampleType OBJECT-TYPE
     SYNTAX     INTEGER {
                  absoluteValue(1),
                  deltaValue(2)
                }
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The method of sampling the selected variable and
         calculating the value to be compared against the
         thresholds.  If the value of this object is
         absoluteValue(1), the value of the selected variable
         will be compared directly with the thresholds at the
         end of the sampling interval.  If the value of this
         object is deltaValue(2), the value of the selected
         variable at the last sample will be subtracted from
         the current value, and the difference compared with
         the thresholds.

         This object may not be modified if the associated
         alarmStatus object is equal to valid(1)."
     ::= { alarmEntry 4 }

 alarmValue OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The value of the statistic during the last sampling
         period.  For example, if the sample type is deltaValue,
         this value will be the difference between the samples
         at the beginning and end of the period.  If the sample
         type is absoluteValue, this value will be the sampled
         value at the end of the period.



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         This is the value that is compared with the rising and
         falling thresholds.

         The value during the current sampling period is not
         made available until the period is completed and will
         remain available until the next period completes."
     ::= { alarmEntry 5 }

 alarmStartupAlarm OBJECT-TYPE
     SYNTAX     INTEGER {
                  risingAlarm(1),
                  fallingAlarm(2),
                  risingOrFallingAlarm(3)
                }
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The alarm that may be sent when this entry is first
         set to valid.  If the first sample after this entry
         becomes valid is greater than or equal to the
         risingThreshold and alarmStartupAlarm is equal to
         risingAlarm(1) or risingOrFallingAlarm(3), then a single
         rising alarm will be generated.  If the first sample
         after this entry becomes valid is less than or equal
         to the fallingThreshold and alarmStartupAlarm is equal
         to fallingAlarm(2) or risingOrFallingAlarm(3), then a
         single falling alarm will be generated.

         This object may not be modified if the associated
         alarmStatus object is equal to valid(1)."
     ::= { alarmEntry 6 }

 alarmRisingThreshold OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "A threshold for the sampled statistic.  When the current
         sampled value is greater than or equal to this threshold,
         and the value at the last sampling interval was less than
         this threshold, a single event will be generated.
         A single event will also be generated if the first
         sample after this entry becomes valid is greater than or
         equal to this threshold and the associated
         alarmStartupAlarm is equal to risingAlarm(1) or
         risingOrFallingAlarm(3).

         After a rising event is generated, another such event



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         will not be generated until the sampled value
         falls below this threshold and reaches the
         alarmFallingThreshold.

         This object may not be modified if the associated
         alarmStatus object is equal to valid(1)."
     ::= { alarmEntry 7 }

 alarmFallingThreshold OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "A threshold for the sampled statistic.  When the current
         sampled value is less than or equal to this threshold,
         and the value at the last sampling interval was greater than
         this threshold, a single event will be generated.
         A single event will also be generated if the first
         sample after this entry becomes valid is less than or
         equal to this threshold and the associated
         alarmStartupAlarm is equal to fallingAlarm(2) or
         risingOrFallingAlarm(3).

         After a falling event is generated, another such event
         will not be generated until the sampled value
         rises above this threshold and reaches the
         alarmRisingThreshold.

         This object may not be modified if the associated
         alarmStatus object is equal to valid(1)."
     ::= { alarmEntry 8 }

 alarmRisingEventIndex OBJECT-TYPE
     SYNTAX     Integer32 (0..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The index of the eventEntry that is
         used when a rising threshold is crossed.  The
         eventEntry identified by a particular value of
         this index is the same as identified by the same value
         of the eventIndex object.  If there is no
         corresponding entry in the eventTable, then
         no association exists.  In particular, if this value
         is zero, no associated event will be generated, as
         zero is not a valid event index.

         This object may not be modified if the associated



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         alarmStatus object is equal to valid(1)."
     ::= { alarmEntry 9 }

 alarmFallingEventIndex OBJECT-TYPE
     SYNTAX     Integer32 (0..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The index of the eventEntry that is
         used when a falling threshold is crossed.  The
         eventEntry identified by a particular value of
         this index is the same as identified by the same value
         of the eventIndex object.  If there is no
         corresponding entry in the eventTable, then
         no association exists.  In particular, if this value
         is zero, no associated event will be generated, as
         zero is not a valid event index.

         This object may not be modified if the associated
         alarmStatus object is equal to valid(1)."
     ::= { alarmEntry 10 }

 alarmOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."
     ::= { alarmEntry 11 }

 alarmStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this alarm entry."
     ::= { alarmEntry 12 }

 -- The Host Group

 -- Implementation of the Host group is optional.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The host group discovers new hosts on the network by
 -- keeping a list of source and destination MAC Addresses seen
 -- in good packets.  For each of these addresses, the host group



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 -- keeps a set of statistics.  The hostControlTable controls
 -- which interfaces this function is performed on, and contains
 -- some information about the process.  On behalf of each
 -- hostControlEntry, data is collected on an interface and placed
 -- in both the hostTable and the hostTimeTable.  If the
 -- monitoring device finds itself short of resources, it may
 -- delete entries as needed.  It is suggested that the device
 -- delete the least recently used entries first.

 -- The hostTable contains entries for each address discovered on
 -- a particular interface.  Each entry contains statistical
 -- data about that host.  This table is indexed by the
 -- MAC address of the host, through which a random access
 -- may be achieved.

 -- The hostTimeTable contains data in the same format as the
 -- hostTable, and must contain the same set of hosts, but is
 -- indexed using hostTimeCreationOrder rather than hostAddress.
 -- The hostTimeCreationOrder is an integer which reflects
 -- the relative order in which a particular entry was discovered
 -- and thus inserted into the table.  As this order, and thus
 -- the index, is among those entries currently in the table,
 -- the index for a particular entry may change if an
 -- (earlier) entry is deleted.  Thus the association between
 -- hostTimeCreationOrder and hostTimeEntry may be broken at
 -- any time.

 -- The hostTimeTable has two important uses.  The first is the
 -- fast download of this potentially large table.  Because the
 -- index of this table runs from 1 to the size of the table,
 -- inclusive, its values are predictable.  This allows very
 -- efficient packing of variables into SNMP PDU's and allows
 -- a table transfer to have multiple packets outstanding.
 -- These benefits increase transfer rates tremendously.

 -- The second use of the hostTimeTable is the efficient discovery
 -- by the management station of new entries added to the table.
 -- After the management station has downloaded the entire table,
 -- it knows that new entries will be added immediately after the
 -- end of the current table.  It can thus detect new entries there
 -- and retrieve them easily.

 -- Because the association between hostTimeCreationOrder and
 -- hostTimeEntry may be broken at any time, the management
 -- station must monitor the related hostControlLastDeleteTime
 -- object.  When the management station thus detects a deletion,
 -- it must assume that any such associations have been broken,
 -- and invalidate any it has stored locally.  This includes



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 -- restarting any download of the hostTimeTable that may have been
 -- in progress, as well as rediscovering the end of the
 -- hostTimeTable so that it may detect new entries.  If the
 -- management station does not detect the broken association,
 -- it may continue to refer to a particular host by its
 -- creationOrder while unwittingly retrieving the data associated
 -- with another host entirely.  If this happens while downloading
 -- the host table, the management station may fail to download
 -- all of the entries in the table.


 hostControlTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF HostControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of host table control entries."
     ::= { hosts 1 }

 hostControlEntry OBJECT-TYPE
     SYNTAX     HostControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of parameters that set up the discovery of hosts
         on a particular interface and the collection of statistics
         about these hosts.  For example, an instance of the
         hostControlTableSize object might be named
         hostControlTableSize.1"
     INDEX { hostControlIndex }
     ::= { hostControlTable 1 }

 HostControlEntry ::= SEQUENCE {

     hostControlIndex            Integer32,
     hostControlDataSource       OBJECT IDENTIFIER,
     hostControlTableSize        Integer32,
     hostControlLastDeleteTime   TimeTicks,
     hostControlOwner            OwnerString,
     hostControlStatus           EntryStatus
 }

 hostControlIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry in the



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         hostControl table.  Each such entry defines
         a function that discovers hosts on a particular interface
         and places statistics about them in the hostTable and
         the hostTimeTable on behalf of this hostControlEntry."
     ::= { hostControlEntry 1 }

 hostControlDataSource OBJECT-TYPE
     SYNTAX     OBJECT IDENTIFIER
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "This object identifies the source of the data for
         this instance of the host function.  This source
         can be any interface on this device.  In order
         to identify a particular interface, this object shall
         identify the instance of the ifIndex object, defined
         in RFC 2233 [17], for the desired interface.
         For example, if an entry were to receive data from
         interface #1, this object would be set to ifIndex.1.

         The statistics in this group reflect all packets
         on the local network segment attached to the identified
         interface.

         An agent may or may not be able to tell if fundamental
         changes to the media of the interface have occurred and
         necessitate an invalidation of this entry.  For example, a
         hot-pluggable ethernet card could be pulled out and replaced
         by a token-ring card.  In such a case, if the agent has such
         knowledge of the change, it is recommended that it
         invalidate this entry.

         This object may not be modified if the associated
         hostControlStatus object is equal to valid(1)."
     ::= { hostControlEntry 2 }

 hostControlTableSize OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of hostEntries in the hostTable and the
         hostTimeTable associated with this hostControlEntry."
     ::= { hostControlEntry 3 }

 hostControlLastDeleteTime OBJECT-TYPE
     SYNTAX     TimeTicks
     MAX-ACCESS read-only



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     STATUS     current
     DESCRIPTION
         "The value of sysUpTime when the last entry
         was deleted from the portion of the hostTable
         associated with this hostControlEntry.  If no
         deletions have occurred, this value shall be zero."
     ::= { hostControlEntry 4 }

 hostControlOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."
     ::= { hostControlEntry 5 }

 hostControlStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this hostControl entry.

         If this object is not equal to valid(1), all associated
         entries in the hostTable, hostTimeTable, and the
         hostTopNTable shall be deleted by the agent."
     ::= { hostControlEntry 6 }

 hostTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF HostEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of host entries."
     ::= { hosts 2 }

 hostEntry OBJECT-TYPE
     SYNTAX     HostEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A collection of statistics for a particular host that has
         been discovered on an interface of this device.  For example,
         an instance of the hostOutBroadcastPkts object might be
         named hostOutBroadcastPkts.1.6.8.0.32.27.3.176"
     INDEX { hostIndex, hostAddress }
     ::= { hostTable 1 }



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 HostEntry ::= SEQUENCE {
     hostAddress             OCTET STRING,
     hostCreationOrder       Integer32,
     hostIndex               Integer32,
     hostInPkts              Counter32,
     hostOutPkts             Counter32,
     hostInOctets            Counter32,
     hostOutOctets           Counter32,
     hostOutErrors           Counter32,
     hostOutBroadcastPkts    Counter32,
     hostOutMulticastPkts    Counter32
 }

 hostAddress OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The physical address of this host."
     ::= { hostEntry 1 }

 hostCreationOrder OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that defines the relative ordering of
         the creation time of hosts captured for a
         particular hostControlEntry.  This index shall
         be between 1 and N, where N is the value of
         the associated hostControlTableSize.  The ordering
         of the indexes is based on the order of each entry's
         insertion into the table, in which entries added earlier
         have a lower index value than entries added later.

         It is important to note that the order for a
         particular entry may change as an (earlier) entry
         is deleted from the table.  Because this order may
         change, management stations should make use of the
         hostControlLastDeleteTime variable in the
         hostControlEntry associated with the relevant
         portion of the hostTable.  By observing
         this variable, the management station may detect
         the circumstances where a previous association
         between a value of hostCreationOrder
         and a hostEntry may no longer hold."
     ::= { hostEntry 2 }




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 hostIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The set of collected host statistics of which
         this entry is a part.  The set of hosts
         identified by a particular value of this
         index is associated with the hostControlEntry
         as identified by the same value of hostControlIndex."
     ::= { hostEntry 3 }

 hostInPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of good packets transmitted to this
         address since it was added to the hostTable."
     ::= { hostEntry 4 }

 hostOutPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets, including bad packets, transmitted
         by this address since it was added to the hostTable."
     ::= { hostEntry 5 }

 hostInOctets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of octets transmitted to this address since
         it was added to the hostTable (excluding framing
         bits but including FCS octets), except for those
         octets in bad packets."
     ::= { hostEntry 6 }

 hostOutOctets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Octets"
     MAX-ACCESS read-only



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     STATUS     current
     DESCRIPTION
         "The number of octets transmitted by this address since
         it was added to the hostTable (excluding framing
         bits but including FCS octets), including those
         octets in bad packets."
     ::= { hostEntry 7 }

 hostOutErrors OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of bad packets transmitted by this address
         since this host was added to the hostTable."
     ::= { hostEntry 8 }

 hostOutBroadcastPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of good packets transmitted by this
         address that were directed to the broadcast address
         since this host was added to the hostTable."
     ::= { hostEntry 9 }

 hostOutMulticastPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of good packets transmitted by this
         address that were directed to a multicast address
         since this host was added to the hostTable.
         Note that this number does not include packets
         directed to the broadcast address."
     ::= { hostEntry 10 }

 -- host Time Table

 hostTimeTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF HostTimeEntry
     MAX-ACCESS not-accessible
     STATUS     current



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     DESCRIPTION
         "A list of time-ordered host table entries."
     ::= { hosts 3 }

 hostTimeEntry OBJECT-TYPE
     SYNTAX     HostTimeEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A collection of statistics for a particular host that has
         been discovered on an interface of this device.  This
         collection includes the relative ordering of the creation
         time of this object.  For example, an instance of the
         hostTimeOutBroadcastPkts object might be named
         hostTimeOutBroadcastPkts.1.687"
     INDEX { hostTimeIndex, hostTimeCreationOrder }
     ::= { hostTimeTable 1 }

 HostTimeEntry ::= SEQUENCE {
     hostTimeAddress              OCTET STRING,
     hostTimeCreationOrder        Integer32,
     hostTimeIndex                Integer32,
     hostTimeInPkts               Counter32,
     hostTimeOutPkts              Counter32,
     hostTimeInOctets             Counter32,
     hostTimeOutOctets            Counter32,
     hostTimeOutErrors            Counter32,
     hostTimeOutBroadcastPkts     Counter32,
     hostTimeOutMulticastPkts     Counter32
 }

 hostTimeAddress OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The physical address of this host."
     ::= { hostTimeEntry 1 }

 hostTimeCreationOrder OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry in
         the hostTime table among those entries associated
         with the same hostControlEntry.  This index shall
         be between 1 and N, where N is the value of



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         the associated hostControlTableSize.  The ordering
         of the indexes is based on the order of each entry's
         insertion into the table, in which entries added earlier
         have a lower index value than entries added later.
         Thus the management station has the ability to
         learn of new entries added to this table without
         downloading the entire table.

         It is important to note that the index for a
         particular entry may change as an (earlier) entry
         is deleted from the table.  Because this order may
         change, management stations should make use of the
         hostControlLastDeleteTime variable in the
         hostControlEntry associated with the relevant
         portion of the hostTimeTable.  By observing
         this variable, the management station may detect
         the circumstances where a download of the table
         may have missed entries, and where a previous
         association between a value of hostTimeCreationOrder
         and a hostTimeEntry may no longer hold."
     ::= { hostTimeEntry 2 }

 hostTimeIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The set of collected host statistics of which
         this entry is a part.  The set of hosts
         identified by a particular value of this
         index is associated with the hostControlEntry
         as identified by the same value of hostControlIndex."
     ::= { hostTimeEntry 3 }

 hostTimeInPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of good packets transmitted to this
         address since it was added to the hostTimeTable."
     ::= { hostTimeEntry 4 }

 hostTimeOutPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only



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     STATUS     current
     DESCRIPTION
         "The number of packets, including bad packets, transmitted
         by this address since it was added to the hostTimeTable."
     ::= { hostTimeEntry 5 }

 hostTimeInOctets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of octets transmitted to this address since
         it was added to the hostTimeTable (excluding framing
         bits but including FCS octets), except for those
         octets in bad packets."
     ::= { hostTimeEntry 6 }

 hostTimeOutOctets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of octets transmitted by this address since
         it was added to the hostTimeTable (excluding framing
         bits but including FCS octets), including those
         octets in bad packets."
     ::= { hostTimeEntry 7 }

 hostTimeOutErrors OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of bad packets transmitted by this address
         since this host was added to the hostTimeTable."
     ::= { hostTimeEntry 8 }

 hostTimeOutBroadcastPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of good packets transmitted by this
         address that were directed to the broadcast address



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         since this host was added to the hostTimeTable."
     ::= { hostTimeEntry 9 }

 hostTimeOutMulticastPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of good packets transmitted by this
         address that were directed to a multicast address
         since this host was added to the hostTimeTable.
         Note that this number does not include packets directed
         to the broadcast address."
     ::= { hostTimeEntry 10 }

 -- The Host Top "N" Group

 -- Implementation of the Host Top N group is optional. The Host Top N
 -- group requires the implementation of the host group.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The Host Top N group is used to prepare reports that describe
 -- the hosts that top a list ordered by one of their statistics.
 -- The available statistics are samples of one of their
 -- base statistics, over an interval specified by the management
 -- station.  Thus, these statistics are rate based.  The management
 -- station also selects how many such hosts are reported.

 -- The hostTopNControlTable is used to initiate the generation of
 -- such a report.  The management station may select the parameters
 -- of such a report, such as which interface, which statistic,
 -- how many hosts, and the start and stop times of the sampling.
 -- When the report is prepared, entries are created in the
 -- hostTopNTable associated with the relevant hostTopNControlEntry.
 -- These entries are static for each report after it has been
 -- prepared.

 hostTopNControlTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF HostTopNControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of top N host control entries."
     ::= { hostTopN 1 }

 hostTopNControlEntry OBJECT-TYPE



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     SYNTAX     HostTopNControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A set of parameters that control the creation of a report
         of the top N hosts according to several metrics.  For
         example, an instance of the hostTopNDuration object might
         be named hostTopNDuration.3"
     INDEX { hostTopNControlIndex }
     ::= { hostTopNControlTable 1 }

 HostTopNControlEntry ::= SEQUENCE {
     hostTopNControlIndex    Integer32,
     hostTopNHostIndex       Integer32,
     hostTopNRateBase        INTEGER,
     hostTopNTimeRemaining   Integer32,
     hostTopNDuration        Integer32,
     hostTopNRequestedSize   Integer32,
     hostTopNGrantedSize     Integer32,
     hostTopNStartTime       TimeTicks,
     hostTopNOwner           OwnerString,
     hostTopNStatus          EntryStatus
 }

 hostTopNControlIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry
         in the hostTopNControl table.  Each such
         entry defines one top N report prepared for
         one interface."
     ::= { hostTopNControlEntry 1 }

 hostTopNHostIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The host table for which a top N report will be prepared
         on behalf of this entry.  The host table identified by a
         particular value of this index is associated with the same
         host table as identified by the same value of
         hostIndex.

         This object may not be modified if the associated
         hostTopNStatus object is equal to valid(1)."



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     ::= { hostTopNControlEntry 2 }

 hostTopNRateBase OBJECT-TYPE
     SYNTAX     INTEGER {
                  hostTopNInPkts(1),
                  hostTopNOutPkts(2),
                  hostTopNInOctets(3),
                  hostTopNOutOctets(4),
                  hostTopNOutErrors(5),
                  hostTopNOutBroadcastPkts(6),
                  hostTopNOutMulticastPkts(7)
                }
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The variable for each host that the hostTopNRate
         variable is based upon.

         This object may not be modified if the associated
         hostTopNStatus object is equal to valid(1)."
     ::= { hostTopNControlEntry 3 }

 hostTopNTimeRemaining OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Seconds"
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The number of seconds left in the report currently being
         collected.  When this object is modified by the management
         station, a new collection is started, possibly aborting
         a currently running report.  The new value is used
         as the requested duration of this report, which is
         loaded into the associated hostTopNDuration object.

         When this object is set to a non-zero value, any
         associated hostTopNEntries shall be made
         inaccessible by the monitor.  While the value of this
         object is non-zero, it decrements by one per second until
         it reaches zero.  During this time, all associated
         hostTopNEntries shall remain inaccessible.  At the time
         that this object decrements to zero, the report is made
         accessible in the hostTopNTable.  Thus, the hostTopN
         table needs to be created only at the end of the collection
         interval."
     DEFVAL { 0 }
     ::= { hostTopNControlEntry 4 }




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 hostTopNDuration OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Seconds"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of seconds that this report has collected
         during the last sampling interval, or if this
         report is currently being collected, the number
         of seconds that this report is being collected
         during this sampling interval.

         When the associated hostTopNTimeRemaining object is set,
         this object shall be set by the probe to the same value
         and shall not be modified until the next time
         the hostTopNTimeRemaining is set.

         This value shall be zero if no reports have been
         requested for this hostTopNControlEntry."
     DEFVAL { 0 }
     ::= { hostTopNControlEntry 5 }

 hostTopNRequestedSize OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The maximum number of hosts requested for the top N
         table.

         When this object is created or modified, the probe
         should set hostTopNGrantedSize as closely to this
         object as is possible for the particular probe
         implementation and available resources."
     DEFVAL { 10 }
     ::= { hostTopNControlEntry 6 }

 hostTopNGrantedSize OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The maximum number of hosts in the top N table.

         When the associated hostTopNRequestedSize object is
         created or modified, the probe should set this
         object as closely to the requested value as is possible
         for the particular implementation and available



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         resources. The probe must not lower this value except
         as a result of a set to the associated
         hostTopNRequestedSize object.

         Hosts with the highest value of hostTopNRate shall be
         placed in this table in decreasing order of this rate
         until there is no more room or until there are no more
         hosts."
     ::= { hostTopNControlEntry 7 }

 hostTopNStartTime OBJECT-TYPE
     SYNTAX     TimeTicks
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The value of sysUpTime when this top N report was
         last started.  In other words, this is the time that
         the associated hostTopNTimeRemaining object was
         modified to start the requested report."
     ::= { hostTopNControlEntry 8 }

 hostTopNOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."
     ::= { hostTopNControlEntry 9 }

 hostTopNStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this hostTopNControl entry.

         If this object is not equal to valid(1), all associated
         hostTopNEntries shall be deleted by the agent."
     ::= { hostTopNControlEntry 10 }

 hostTopNTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF HostTopNEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of top N host entries."
     ::= { hostTopN 2 }



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 hostTopNEntry OBJECT-TYPE
     SYNTAX     HostTopNEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A set of statistics for a host that is part of a top N
         report.  For example, an instance of the hostTopNRate
         object might be named hostTopNRate.3.10"
     INDEX { hostTopNReport, hostTopNIndex }
     ::= { hostTopNTable 1 }

 HostTopNEntry ::= SEQUENCE {
     hostTopNReport                Integer32,
     hostTopNIndex                 Integer32,
     hostTopNAddress               OCTET STRING,
     hostTopNRate                  Integer32
 }

 hostTopNReport OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "This object identifies the top N report of which
         this entry is a part.  The set of hosts
         identified by a particular value of this
         object is part of the same report as identified
         by the same value of the hostTopNControlIndex object."
     ::= { hostTopNEntry 1 }

 hostTopNIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry in
         the hostTopN table among those in the same report.
         This index is between 1 and N, where N is the
         number of entries in this table.  Increasing values
         of hostTopNIndex shall be assigned to entries with
         decreasing values of hostTopNRate until index N
         is assigned to the entry with the lowest value of
         hostTopNRate or there are no more hostTopNEntries."
     ::= { hostTopNEntry 2 }

 hostTopNAddress OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-only



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     STATUS     current
     DESCRIPTION
         "The physical address of this host."
     ::= { hostTopNEntry 3 }

 hostTopNRate OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The amount of change in the selected variable
         during this sampling interval.  The selected
         variable is this host's instance of the object
         selected by hostTopNRateBase."
     ::= { hostTopNEntry 4 }

 -- The Matrix Group

 -- Implementation of the Matrix group is optional.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The Matrix group consists of the matrixControlTable, matrixSDTable
 -- and the matrixDSTable.  These tables store statistics for a
 -- particular conversation between two addresses.  As the device
 -- detects a new conversation, including those to a non-unicast
 -- address, it creates a new entry in both of the matrix tables.
 -- It must only create new entries based on information
 -- received in good packets.  If the monitoring device finds
 -- itself short of resources, it may delete entries as needed.
 -- It is suggested that the device delete the least recently used
 -- entries first.

 matrixControlTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF MatrixControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of information entries for the
         traffic matrix on each interface."
     ::= { matrix 1 }

 matrixControlEntry OBJECT-TYPE
     SYNTAX     MatrixControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "Information about a traffic matrix on a particular



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         interface.  For example, an instance of the
         matrixControlLastDeleteTime object might be named
         matrixControlLastDeleteTime.1"
     INDEX { matrixControlIndex }
     ::= { matrixControlTable 1 }

 MatrixControlEntry ::= SEQUENCE {
     matrixControlIndex           Integer32,
     matrixControlDataSource      OBJECT IDENTIFIER,
     matrixControlTableSize       Integer32,
     matrixControlLastDeleteTime  TimeTicks,
     matrixControlOwner           OwnerString,
     matrixControlStatus          EntryStatus
 }

 matrixControlIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry in the
         matrixControl table.  Each such entry defines
         a function that discovers conversations on a particular
         interface and places statistics about them in the
         matrixSDTable and the matrixDSTable on behalf of this
         matrixControlEntry."
     ::= { matrixControlEntry 1 }

 matrixControlDataSource OBJECT-TYPE
     SYNTAX     OBJECT IDENTIFIER
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "This object identifies the source of
         the data from which this entry creates a traffic matrix.
         This source can be any interface on this device.  In
         order to identify a particular interface, this object
         shall identify the instance of the ifIndex object,
         defined in RFC 2233 [17], for the desired
         interface.  For example, if an entry were to receive data
         from interface #1, this object would be set to ifIndex.1.

         The statistics in this group reflect all packets
         on the local network segment attached to the identified
         interface.

         An agent may or may not be able to tell if fundamental
         changes to the media of the interface have occurred and



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         necessitate an invalidation of this entry.  For example, a
         hot-pluggable ethernet card could be pulled out and replaced
         by a token-ring card.  In such a case, if the agent has such
         knowledge of the change, it is recommended that it
         invalidate this entry.

         This object may not be modified if the associated
         matrixControlStatus object is equal to valid(1)."
     ::= { matrixControlEntry 2 }

 matrixControlTableSize OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of matrixSDEntries in the matrixSDTable
         for this interface.  This must also be the value of
         the number of entries in the matrixDSTable for this
         interface."
     ::= { matrixControlEntry 3 }

 matrixControlLastDeleteTime OBJECT-TYPE
     SYNTAX     TimeTicks
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The value of sysUpTime when the last entry
         was deleted from the portion of the matrixSDTable
         or matrixDSTable associated with this matrixControlEntry.
         If no deletions have occurred, this value shall be
         zero."
     ::= { matrixControlEntry 4 }

 matrixControlOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."
     ::= { matrixControlEntry 5 }

 matrixControlStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this matrixControl entry.



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         If this object is not equal to valid(1), all associated
         entries in the matrixSDTable and the matrixDSTable
         shall be deleted by the agent."
     ::= { matrixControlEntry 6 }

 matrixSDTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF MatrixSDEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of traffic matrix entries indexed by
         source and destination MAC address."
     ::= { matrix 2 }

 matrixSDEntry OBJECT-TYPE
     SYNTAX     MatrixSDEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A collection of statistics for communications between
         two addresses on a particular interface.  For example,
         an instance of the matrixSDPkts object might be named
         matrixSDPkts.1.6.8.0.32.27.3.176.6.8.0.32.10.8.113"
     INDEX { matrixSDIndex,
             matrixSDSourceAddress, matrixSDDestAddress }
     ::= { matrixSDTable 1 }

 MatrixSDEntry ::= SEQUENCE {
     matrixSDSourceAddress       OCTET STRING,
     matrixSDDestAddress         OCTET STRING,
     matrixSDIndex               Integer32,
     matrixSDPkts                Counter32,
     matrixSDOctets              Counter32,
     matrixSDErrors              Counter32
 }

 matrixSDSourceAddress OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The source physical address."
     ::= { matrixSDEntry 1 }

 matrixSDDestAddress OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-only
     STATUS     current



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     DESCRIPTION
         "The destination physical address."
     ::= { matrixSDEntry 2 }

 matrixSDIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The set of collected matrix statistics of which
         this entry is a part.  The set of matrix statistics
         identified by a particular value of this index
         is associated with the same matrixControlEntry
         as identified by the same value of matrixControlIndex."
     ::= { matrixSDEntry 3 }

 matrixSDPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets transmitted from the source
         address to the destination address (this number includes
         bad packets)."
     ::= { matrixSDEntry 4 }

 matrixSDOctets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of octets (excluding framing bits but
         including FCS octets) contained in all packets
         transmitted from the source address to the
         destination address."
     ::= { matrixSDEntry 5 }

 matrixSDErrors OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of bad packets transmitted from
         the source address to the destination address."
     ::= { matrixSDEntry 6 }



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 -- Traffic matrix tables from destination to source

 matrixDSTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF MatrixDSEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of traffic matrix entries indexed by
         destination and source MAC address."
     ::= { matrix 3 }

 matrixDSEntry OBJECT-TYPE
     SYNTAX     MatrixDSEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A collection of statistics for communications between
         two addresses on a particular interface.  For example,
         an instance of the matrixSDPkts object might be named
         matrixSDPkts.1.6.8.0.32.10.8.113.6.8.0.32.27.3.176"
     INDEX { matrixDSIndex,
             matrixDSDestAddress, matrixDSSourceAddress }
     ::= { matrixDSTable 1 }

 MatrixDSEntry ::= SEQUENCE {
     matrixDSSourceAddress       OCTET STRING,
     matrixDSDestAddress         OCTET STRING,
     matrixDSIndex               Integer32,
     matrixDSPkts                Counter32,
     matrixDSOctets              Counter32,
     matrixDSErrors              Counter32
 }

 matrixDSSourceAddress OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The source physical address."
     ::= { matrixDSEntry 1 }

 matrixDSDestAddress OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The destination physical address."
     ::= { matrixDSEntry 2 }



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 matrixDSIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The set of collected matrix statistics of which
         this entry is a part.  The set of matrix statistics
         identified by a particular value of this index
         is associated with the same matrixControlEntry
         as identified by the same value of matrixControlIndex."
     ::= { matrixDSEntry 3 }

 matrixDSPkts OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets transmitted from the source
         address to the destination address (this number includes
         bad packets)."
     ::= { matrixDSEntry 4 }

 matrixDSOctets OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of octets (excluding framing bits
         but including FCS octets) contained in all packets
         transmitted from the source address to the
         destination address."
     ::= { matrixDSEntry 5 }

 matrixDSErrors OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of bad packets transmitted from
         the source address to the destination address."
     ::= { matrixDSEntry 6 }

 -- The Filter Group

 -- Implementation of the Filter group is optional.



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 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The Filter group allows packets to be captured with an
 -- arbitrary filter expression.  A logical data and
 -- event stream or "channel" is formed by the packets
 -- that match the filter expression.
 --
 -- This filter mechanism allows the creation of an arbitrary
 -- logical expression with which to filter packets.  Each
 -- filter associated with a channel is OR'ed with the others.
 -- Within a filter, any bits checked in the data and status are
 -- AND'ed with respect to other bits in the same filter.  The
 -- NotMask also allows for checking for inequality.  Finally,
 -- the channelAcceptType object allows for inversion of the
 -- whole equation.
 --
 -- If a management station wishes to receive a trap to alert it
 -- that new packets have been captured and are available for
 -- download, it is recommended that it set up an alarm entry that
 -- monitors the value of the relevant channelMatches instance.
 --
 -- The channel can be turned on or off, and can also
 -- generate events when packets pass through it.

 filterTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF FilterEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of packet filter entries."
     ::= { filter 1 }

 filterEntry OBJECT-TYPE
     SYNTAX     FilterEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A set of parameters for a packet filter applied on a
         particular interface.  As an example, an instance of the
         filterPktData object might be named filterPktData.12"
     INDEX { filterIndex }
     ::= { filterTable 1 }

 FilterEntry ::= SEQUENCE {
     filterIndex                 Integer32,
     filterChannelIndex          Integer32,
     filterPktDataOffset         Integer32,



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     filterPktData               OCTET STRING,
     filterPktDataMask           OCTET STRING,
     filterPktDataNotMask        OCTET STRING,
     filterPktStatus             Integer32,
     filterPktStatusMask         Integer32,
     filterPktStatusNotMask      Integer32,
     filterOwner                 OwnerString,
     filterStatus                EntryStatus
 }

 filterIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry
         in the filter table.  Each such entry defines
         one filter that is to be applied to every packet
         received on an interface."
     ::= { filterEntry 1 }

 filterChannelIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "This object identifies the channel of which this filter
         is a part.  The filters identified by a particular value
         of this object are associated with the same channel as
         identified by the same value of the channelIndex object."
     ::= { filterEntry 2 }

 filterPktDataOffset OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Octets"
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The offset from the beginning of each packet where
         a match of packet data will be attempted.  This offset
         is measured from the point in the physical layer
         packet after the framing bits, if any.  For example,
         in an Ethernet frame, this point is at the beginning of
         the destination MAC address.

         This object may not be modified if the associated
         filterStatus object is equal to valid(1)."
     DEFVAL { 0 }



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     ::= { filterEntry 3 }

 filterPktData OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The data that is to be matched with the input packet.
         For each packet received, this filter and the accompanying
         filterPktDataMask and filterPktDataNotMask will be
         adjusted for the offset.  The only bits relevant to this
         match algorithm are those that have the corresponding
         filterPktDataMask bit equal to one.  The following three
         rules are then applied to every packet:

         (1) If the packet is too short and does not have data
             corresponding to part of the filterPktData, the packet
             will fail this data match.

         (2) For each relevant bit from the packet with the
             corresponding filterPktDataNotMask bit set to zero, if
             the bit from the packet is not equal to the corresponding
             bit from the filterPktData, then the packet will fail
             this data match.

         (3) If for every relevant bit from the packet with the
             corresponding filterPktDataNotMask bit set to one, the
             bit from the packet is equal to the corresponding bit
             from the filterPktData, then the packet will fail this
             data match.

         Any packets that have not failed any of the three matches
         above have passed this data match.  In particular, a zero
         length filter will match any packet.

         This object may not be modified if the associated
         filterStatus object is equal to valid(1)."
     ::= { filterEntry 4 }

 filterPktDataMask OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The mask that is applied to the match process.
         After adjusting this mask for the offset, only those
         bits in the received packet that correspond to bits set
         in this mask are relevant for further processing by the



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         match algorithm.  The offset is applied to filterPktDataMask
         in the same way it is applied to the filter.  For the
         purposes of the matching algorithm, if the associated
         filterPktData object is longer than this mask, this mask is
         conceptually extended with '1' bits until it reaches the
         length of the filterPktData object.

         This object may not be modified if the associated
         filterStatus object is equal to valid(1)."
     ::= { filterEntry 5 }

 filterPktDataNotMask OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The inversion mask that is applied to the match
         process.  After adjusting this mask for the offset,
         those relevant bits in the received packet that correspond
         to bits cleared in this mask must all be equal to their
         corresponding bits in the filterPktData object for the packet
         to be accepted.  In addition, at least one of those relevant
         bits in the received packet that correspond to bits set in
         this mask must be different to its corresponding bit in the
         filterPktData object.

         For the purposes of the matching algorithm, if the associated
         filterPktData object is longer than this mask, this mask is
         conceptually extended with '0' bits until it reaches the
         length of the filterPktData object.

         This object may not be modified if the associated
         filterStatus object is equal to valid(1)."
     ::= { filterEntry 6 }

 filterPktStatus OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status that is to be matched with the input packet.
         The only bits relevant to this match algorithm are those that
         have the corresponding filterPktStatusMask bit equal to one.
         The following two rules are then applied to every packet:

         (1) For each relevant bit from the packet status with the
             corresponding filterPktStatusNotMask bit set to zero, if
             the bit from the packet status is not equal to the



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             corresponding bit from the filterPktStatus, then the
             packet will fail this status match.

         (2) If for every relevant bit from the packet status with the
             corresponding filterPktStatusNotMask bit set to one, the
             bit from the packet status is equal to the corresponding
             bit from the filterPktStatus, then the packet will fail
             this status match.

         Any packets that have not failed either of the two matches
         above have passed this status match.  In particular, a zero
         length status filter will match any packet's status.

         The value of the packet status is a sum.  This sum
         initially takes the value zero.  Then, for each
         error, E, that has been discovered in this packet,
         2 raised to a value representing E is added to the sum.
         The errors and the bits that represent them are dependent
         on the media type of the interface that this channel
         is receiving packets from.

         The errors defined for a packet captured off of an
         Ethernet interface are as follows:

             bit #    Error
                 0    Packet is longer than 1518 octets
                 1    Packet is shorter than 64 octets
                 2    Packet experienced a CRC or Alignment error

         For example, an Ethernet fragment would have a
         value of 6 (2^1 + 2^2).

         As this MIB is expanded to new media types, this object
         will have other media-specific errors defined.

         For the purposes of this status matching algorithm, if the
         packet status is longer than this filterPktStatus object,
         this object is conceptually extended with '0' bits until it
         reaches the size of the packet status.

         This object may not be modified if the associated
         filterStatus object is equal to valid(1)."
     ::= { filterEntry 7 }

 filterPktStatusMask OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-create
     STATUS     current



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     DESCRIPTION
         "The mask that is applied to the status match process.
         Only those bits in the received packet that correspond to
         bits set in this mask are relevant for further processing
         by the status match algorithm.  For the purposes
         of the matching algorithm, if the associated filterPktStatus
         object is longer than this mask, this mask is conceptually
         extended with '1' bits until it reaches the size of the
         filterPktStatus.  In addition, if a packet status is longer
         than this mask, this mask is conceptually extended with '0'
         bits until it reaches the size of the packet status.

         This object may not be modified if the associated
         filterStatus object is equal to valid(1)."
     ::= { filterEntry 8 }

 filterPktStatusNotMask OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The inversion mask that is applied to the status match
         process.  Those relevant bits in the received packet status
         that correspond to bits cleared in this mask must all be
         equal to their corresponding bits in the filterPktStatus
         object for the packet to be accepted.  In addition, at least
         one of those relevant bits in the received packet status
         that correspond to bits set in this mask must be different
         to its corresponding bit in the filterPktStatus object for
         the packet to be accepted.

         For the purposes of the matching algorithm, if the associated
         filterPktStatus object or a packet status is longer than this
         mask, this mask is conceptually extended with '0' bits until
         it reaches the longer of the lengths of the filterPktStatus
         object and the packet status.

         This object may not be modified if the associated
         filterStatus object is equal to valid(1)."
     ::= { filterEntry 9 }

 filterOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."



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     ::= { filterEntry 10 }

 filterStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this filter entry."
     ::= { filterEntry 11 }

 channelTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF ChannelEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of packet channel entries."
     ::= { filter 2 }

 channelEntry OBJECT-TYPE
     SYNTAX     ChannelEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A set of parameters for a packet channel applied on a
         particular interface.  As an example, an instance of the
         channelMatches object might be named channelMatches.3"
     INDEX { channelIndex }
     ::= { channelTable 1 }

 ChannelEntry ::= SEQUENCE {
     channelIndex                 Integer32,
     channelIfIndex               Integer32,
     channelAcceptType            INTEGER,
     channelDataControl           INTEGER,
     channelTurnOnEventIndex      Integer32,
     channelTurnOffEventIndex     Integer32,
     channelEventIndex            Integer32,
     channelEventStatus           INTEGER,
     channelMatches               Counter32,
     channelDescription           DisplayString,
     channelOwner                 OwnerString,
     channelStatus                EntryStatus
 }

 channelIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current



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     DESCRIPTION
         "An index that uniquely identifies an entry in the channel
         table.  Each such entry defines one channel, a logical
         data and event stream.

         It is suggested that before creating a channel, an
         application should scan all instances of the
         filterChannelIndex object to make sure that there are no
         pre-existing filters that would be inadvertently be linked
         to the channel."
     ::= { channelEntry 1 }

 channelIfIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The value of this object uniquely identifies the
         interface on this remote network monitoring device to which
         the associated filters are applied to allow data into this
         channel.  The interface identified by a particular value
         of this object is the same interface as identified by the
         same value of the ifIndex object, defined in RFC 2233 [17].

         The filters in this group are applied to all packets on
         the local network segment attached to the identified
         interface.

         An agent may or may not be able to tell if fundamental
         changes to the media of the interface have occurred and
         necessitate an invalidation of this entry.  For example, a
         hot-pluggable ethernet card could be pulled out and replaced
         by a token-ring card.  In such a case, if the agent has such
         knowledge of the change, it is recommended that it
         invalidate this entry.

         This object may not be modified if the associated
         channelStatus object is equal to valid(1)."
     ::= { channelEntry 2 }

 channelAcceptType OBJECT-TYPE
     SYNTAX     INTEGER {
                  acceptMatched(1),
                  acceptFailed(2)
                }
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION



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         "This object controls the action of the filters
         associated with this channel.  If this object is equal
         to acceptMatched(1), packets will be accepted to this
         channel if they are accepted by both the packet data and
         packet status matches of an associated filter.  If
         this object is equal to acceptFailed(2), packets will
         be accepted to this channel only if they fail either
         the packet data match or the packet status match of
         each of the associated filters.

         In particular, a channel with no associated filters will
         match no packets if set to acceptMatched(1) case and will
         match all packets in the acceptFailed(2) case.

         This object may not be modified if the associated
         channelStatus object is equal to valid(1)."
     ::= { channelEntry 3 }

 channelDataControl OBJECT-TYPE
     SYNTAX     INTEGER {
                  on(1),
                  off(2)
                }
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "This object controls the flow of data through this channel.
         If this object is on(1), data, status and events flow
         through this channel.  If this object is off(2), data,
         status and events will not flow through this channel."
     DEFVAL { off }
     ::= { channelEntry 4 }

 channelTurnOnEventIndex OBJECT-TYPE
     SYNTAX     Integer32 (0..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The value of this object identifies the event
         that is configured to turn the associated
         channelDataControl from off to on when the event is
         generated.  The event identified by a particular value
         of this object is the same event as identified by the
         same value of the eventIndex object.  If there is no
         corresponding entry in the eventTable, then no
         association exists.  In fact, if no event is intended
         for this channel, channelTurnOnEventIndex must be
         set to zero, a non-existent event index.



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         This object may not be modified if the associated
         channelStatus object is equal to valid(1)."
     ::= { channelEntry 5 }

 channelTurnOffEventIndex OBJECT-TYPE
     SYNTAX     Integer32 (0..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The value of this object identifies the event
         that is configured to turn the associated
         channelDataControl from on to off when the event is
         generated.  The event identified by a particular value
         of this object is the same event as identified by the
         same value of the eventIndex object.  If there is no
         corresponding entry in the eventTable, then no
         association exists.  In fact, if no event is intended
         for this channel, channelTurnOffEventIndex must be
         set to zero, a non-existent event index.

         This object may not be modified if the associated
         channelStatus object is equal to valid(1)."
     ::= { channelEntry 6 }

 channelEventIndex OBJECT-TYPE
     SYNTAX     Integer32 (0..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The value of this object identifies the event
         that is configured to be generated when the
         associated channelDataControl is on and a packet
         is matched.  The event identified by a particular value
         of this object is the same event as identified by the
         same value of the eventIndex object.  If there is no
         corresponding entry in the eventTable, then no
         association exists.  In fact, if no event is intended
         for this channel, channelEventIndex must be
         set to zero, a non-existent event index.

         This object may not be modified if the associated
         channelStatus object is equal to valid(1)."
     ::= { channelEntry 7 }

 channelEventStatus OBJECT-TYPE
     SYNTAX     INTEGER {
                  eventReady(1),
                  eventFired(2),



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                  eventAlwaysReady(3)
                }
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The event status of this channel.

         If this channel is configured to generate events
         when packets are matched, a means of controlling
         the flow of those events is often needed.  When
         this object is equal to eventReady(1), a single
         event may be generated, after which this object
         will be set by the probe to eventFired(2).  While
         in the eventFired(2) state, no events will be
         generated until the object is modified to
         eventReady(1) (or eventAlwaysReady(3)).  The
         management station can thus easily respond to a
         notification of an event by re-enabling this object.

         If the management station wishes to disable this
         flow control and allow events to be generated
         at will, this object may be set to
         eventAlwaysReady(3).  Disabling the flow control
         is discouraged as it can result in high network
         traffic or other performance problems."
     DEFVAL { eventReady }
     ::= { channelEntry 8 }

 channelMatches OBJECT-TYPE
     SYNTAX     Counter32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of times this channel has matched a packet.
         Note that this object is updated even when
         channelDataControl is set to off."
     ::= { channelEntry 9 }

 channelDescription OBJECT-TYPE
     SYNTAX     DisplayString (SIZE (0..127))
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "A comment describing this channel."
     ::= { channelEntry 10 }

 channelOwner OBJECT-TYPE



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     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."
     ::= { channelEntry 11 }

 channelStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this channel entry."
     ::= { channelEntry 12 }

 -- The Packet Capture Group

 -- Implementation of the Packet Capture group is optional. The Packet
 -- Capture Group requires implementation of the Filter Group.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The Packet Capture group allows packets to be captured
 -- upon a filter match.  The bufferControlTable controls
 -- the captured packets output from a channel that is
 -- associated with it.  The captured packets are placed
 -- in entries in the captureBufferTable.  These entries are
 -- associated with the bufferControlEntry on whose behalf they
 -- were stored.

 bufferControlTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF BufferControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of buffers control entries."
     ::= { capture 1 }

 bufferControlEntry OBJECT-TYPE
     SYNTAX     BufferControlEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A set of parameters that control the collection of a stream
         of packets that have matched filters.  As an example, an
         instance of the bufferControlCaptureSliceSize object might
         be named bufferControlCaptureSliceSize.3"



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     INDEX { bufferControlIndex }
     ::= { bufferControlTable 1 }

 BufferControlEntry ::= SEQUENCE {
     bufferControlIndex                Integer32,
     bufferControlChannelIndex         Integer32,
     bufferControlFullStatus           INTEGER,
     bufferControlFullAction           INTEGER,
     bufferControlCaptureSliceSize     Integer32,
     bufferControlDownloadSliceSize    Integer32,
     bufferControlDownloadOffset       Integer32,
     bufferControlMaxOctetsRequested   Integer32,
     bufferControlMaxOctetsGranted     Integer32,
     bufferControlCapturedPackets      Integer32,
     bufferControlTurnOnTime           TimeTicks,
     bufferControlOwner                OwnerString,
     bufferControlStatus               EntryStatus
 }

 bufferControlIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry
         in the bufferControl table.  The value of this
         index shall never be zero.  Each such
         entry defines one set of packets that is
         captured and controlled by one or more filters."
     ::= { bufferControlEntry 1 }

 bufferControlChannelIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "An index that identifies the channel that is the
         source of packets for this bufferControl table.
         The channel identified by a particular value of this
         index is the same as identified by the same value of
         the channelIndex object.

         This object may not be modified if the associated
         bufferControlStatus object is equal to valid(1)."
     ::= { bufferControlEntry 2 }

 bufferControlFullStatus OBJECT-TYPE
     SYNTAX     INTEGER {



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                  spaceAvailable(1),
                  full(2)
                }
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "This object shows whether the buffer has room to
         accept new packets or if it is full.

         If the status is spaceAvailable(1), the buffer is
         accepting new packets normally.  If the status is
         full(2) and the associated bufferControlFullAction
         object is wrapWhenFull, the buffer is accepting new
         packets by deleting enough of the oldest packets
         to make room for new ones as they arrive.  Otherwise,
         if the status is full(2) and the
         bufferControlFullAction object is lockWhenFull,
         then the buffer has stopped collecting packets.

         When this object is set to full(2) the probe must
         not later set it to spaceAvailable(1) except in the
         case of a significant gain in resources such as
         an increase of bufferControlOctetsGranted.  In
         particular, the wrap-mode action of deleting old
         packets to make room for newly arrived packets
         must not affect the value of this object."
     ::= { bufferControlEntry 3 }

 bufferControlFullAction OBJECT-TYPE
     SYNTAX     INTEGER {
                  lockWhenFull(1),
                  wrapWhenFull(2)    -- FIFO
                }
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "Controls the action of the buffer when it
         reaches the full status.  When in the lockWhenFull(1)
         state and a packet is added to the buffer that
         fills the buffer, the bufferControlFullStatus will
         be set to full(2) and this buffer will stop capturing
         packets."
     ::= { bufferControlEntry 4 }

 bufferControlCaptureSliceSize OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Octets"
     MAX-ACCESS read-create



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     STATUS     current
     DESCRIPTION
         "The maximum number of octets of each packet
         that will be saved in this capture buffer.
         For example, if a 1500 octet packet is received by
         the probe and this object is set to 500, then only
         500 octets of the packet will be stored in the
         associated capture buffer.  If this variable is set
         to 0, the capture buffer will save as many octets
         as is possible.

         This object may not be modified if the associated
         bufferControlStatus object is equal to valid(1)."
     DEFVAL { 100 }
     ::= { bufferControlEntry 5 }

 bufferControlDownloadSliceSize OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Octets"
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The maximum number of octets of each packet
         in this capture buffer that will be returned in
         an SNMP retrieval of that packet.  For example,
         if 500 octets of a packet have been stored in the
         associated capture buffer, the associated
         bufferControlDownloadOffset is 0, and this
         object is set to 100, then the captureBufferPacket
         object that contains the packet will contain only
         the first 100 octets of the packet.

         A prudent manager will take into account possible
         interoperability or fragmentation problems that may
         occur if the download slice size is set too large.
         In particular, conformant SNMP implementations are not
         required to accept messages whose length exceeds 484
         octets, although they are encouraged to support larger
         datagrams whenever feasible."
     DEFVAL { 100 }
     ::= { bufferControlEntry 6 }

 bufferControlDownloadOffset OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Octets"
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION



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         "The offset of the first octet of each packet
         in this capture buffer that will be returned in
         an SNMP retrieval of that packet.  For example,
         if 500 octets of a packet have been stored in the
         associated capture buffer and this object is set to
         100, then the captureBufferPacket object that
         contains the packet will contain bytes starting
         100 octets into the packet."
     DEFVAL { 0 }
     ::= { bufferControlEntry 7 }

 bufferControlMaxOctetsRequested OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Octets"
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The requested maximum number of octets to be
         saved in this captureBuffer, including any
         implementation-specific overhead. If this variable
         is set to -1, the capture buffer will save as many
         octets as is possible.

         When this object is created or modified, the probe
         should set bufferControlMaxOctetsGranted as closely
         to this object as is possible for the particular probe
         implementation and available resources.  However, if
         the object has the special value of -1, the probe
         must set bufferControlMaxOctetsGranted to -1."
     DEFVAL { -1 }
     ::= { bufferControlEntry 8 }

 bufferControlMaxOctetsGranted OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The maximum number of octets that can be
         saved in this captureBuffer, including overhead.
         If this variable is -1, the capture buffer will save
         as many octets as possible.

         When the bufferControlMaxOctetsRequested object is
         created or modified, the probe should set this object
         as closely to the requested value as is possible for the
         particular probe implementation and available resources.
         However, if the request object has the special value



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         of -1, the probe must set this object to -1.

         The probe must not lower this value except as a result of
         a modification to the associated
         bufferControlMaxOctetsRequested object.

         When this maximum number of octets is reached
         and a new packet is to be added to this
         capture buffer and the corresponding
         bufferControlFullAction is set to wrapWhenFull(2),
         enough of the oldest packets associated with this
         capture buffer shall be deleted by the agent so
         that the new packet can be added.  If the corresponding
         bufferControlFullAction is set to lockWhenFull(1),
         the new packet shall be discarded.  In either case,
         the probe must set bufferControlFullStatus to
         full(2).

         When the value of this object changes to a value less
         than the current value, entries are deleted from
         the captureBufferTable associated with this
         bufferControlEntry.  Enough of the
         oldest of these captureBufferEntries shall be
         deleted by the agent so that the number of octets
         used remains less than or equal to the new value of
         this object.

         When the value of this object changes to a value greater
         than the current value, the number of associated
         captureBufferEntries may be allowed to grow."
     ::= { bufferControlEntry 9 }

 bufferControlCapturedPackets OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Packets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of packets currently in this captureBuffer."
     ::= { bufferControlEntry 10 }

 bufferControlTurnOnTime OBJECT-TYPE
     SYNTAX     TimeTicks
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The value of sysUpTime when this capture buffer was
         first turned on."



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     ::= { bufferControlEntry 11 }

 bufferControlOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it."
     ::= { bufferControlEntry 12 }

 bufferControlStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this buffer Control Entry."
     ::= { bufferControlEntry 13 }

 captureBufferTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF CaptureBufferEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of packets captured off of a channel."
     ::= { capture 2 }

 captureBufferEntry OBJECT-TYPE
     SYNTAX     CaptureBufferEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A packet captured off of an attached network.  As an
         example, an instance of the captureBufferPacketData
         object might be named captureBufferPacketData.3.1783"
     INDEX { captureBufferControlIndex, captureBufferIndex }
     ::= { captureBufferTable 1 }

 CaptureBufferEntry ::= SEQUENCE {
     captureBufferControlIndex   Integer32,
     captureBufferIndex          Integer32,
     captureBufferPacketID       Integer32,
     captureBufferPacketData     OCTET STRING,
     captureBufferPacketLength   Integer32,
     captureBufferPacketTime     Integer32,
     captureBufferPacketStatus   Integer32
 }




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 captureBufferControlIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The index of the bufferControlEntry with which
         this packet is associated."
     ::= { captureBufferEntry 1 }

 captureBufferIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..2147483647)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry
         in the captureBuffer table associated with a
         particular bufferControlEntry.  This index will
         start at 1 and increase by one for each new packet
         added with the same captureBufferControlIndex.

         Should this value reach 2147483647, the next packet
         added with the same captureBufferControlIndex shall
         cause this value to wrap around to 1."
     ::= { captureBufferEntry 2 }

 captureBufferPacketID OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that describes the order of packets
         that are received on a particular interface.
         The packetID of a packet captured on an
         interface is defined to be greater than the
         packetID's of all packets captured previously on
         the same interface.  As the captureBufferPacketID
         object has a maximum positive value of 2^31 - 1,
         any captureBufferPacketID object shall have the
         value of the associated packet's packetID mod 2^31."
     ::= { captureBufferEntry 3 }

 captureBufferPacketData OBJECT-TYPE
     SYNTAX     OCTET STRING
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The data inside the packet, starting at the beginning
         of the packet plus any offset specified in the



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         associated bufferControlDownloadOffset, including any
         link level headers.  The length of the data in this object
         is the minimum of the length of the captured packet minus
         the offset, the length of the associated
         bufferControlCaptureSliceSize minus the offset, and the
         associated bufferControlDownloadSliceSize.  If this minimum
         is less than zero, this object shall have a length of zero."
     ::= { captureBufferEntry 4 }

 captureBufferPacketLength OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Octets"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The actual length (off the wire) of the packet stored
         in this entry, including FCS octets."
     ::= { captureBufferEntry 5 }

 captureBufferPacketTime OBJECT-TYPE
     SYNTAX     Integer32
     UNITS      "Milliseconds"
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The number of milliseconds that had passed since
         this capture buffer was first turned on when this
         packet was captured."
     ::= { captureBufferEntry 6 }

 captureBufferPacketStatus OBJECT-TYPE
     SYNTAX     Integer32
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "A value which indicates the error status of this packet.

         The value of this object is defined in the same way as
         filterPktStatus.  The value is a sum.  This sum
         initially takes the value zero.  Then, for each
         error, E, that has been discovered in this packet,
         2 raised to a value representing E is added to the sum.

         The errors defined for a packet captured off of an
         Ethernet interface are as follows:

             bit #    Error
                 0    Packet is longer than 1518 octets



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                 1    Packet is shorter than 64 octets
                 2    Packet experienced a CRC or Alignment error
                 3    First packet in this capture buffer after
                      it was detected that some packets were
                      not processed correctly.
                 4    Packet's order in buffer is only approximate
                      (May only be set for packets sent from
                      the probe)

         For example, an Ethernet fragment would have a
         value of 6 (2^1 + 2^2).

         As this MIB is expanded to new media types, this object
         will have other media-specific errors defined."
     ::= { captureBufferEntry 7 }

 -- The Event Group

 -- Implementation of the Event group is optional.
 -- Consult the MODULE-COMPLIANCE macro for the authoritative
 -- conformance information for this MIB.
 --
 -- The Event group controls the generation and notification
 -- of events from this device.  Each entry in the eventTable
 -- describes the parameters of the event that can be triggered.
 -- Each event entry is fired by an associated condition located
 -- elsewhere in the MIB.  An event entry may also be associated
 -- with a function elsewhere in the MIB that will be executed
 -- when the event is generated.  For example, a channel may
 -- be turned on or off by the firing of an event.
 --
 -- Each eventEntry may optionally specify that a log entry
 -- be created on its behalf whenever the event occurs.
 -- Each entry may also specify that notification should
 -- occur by way of SNMP trap messages.  In this case, the
 -- community for the trap message is given in the associated
 -- eventCommunity object.  The enterprise and specific trap
 -- fields of the trap are determined by the condition that
 -- triggered the event.  Two traps are defined: risingAlarm and
 -- fallingAlarm.  If the eventTable is triggered by a condition
 -- specified elsewhere, the enterprise and specific trap fields
 -- must be specified for traps generated for that condition.

 eventTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF EventEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION



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         "A list of events to be generated."
     ::= { event 1 }

 eventEntry OBJECT-TYPE
     SYNTAX     EventEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A set of parameters that describe an event to be generated
         when certain conditions are met.  As an example, an instance
         of the eventLastTimeSent object might be named
         eventLastTimeSent.6"
     INDEX { eventIndex }
     ::= { eventTable 1 }

 EventEntry ::= SEQUENCE {
     eventIndex          Integer32,
     eventDescription    DisplayString,
     eventType           INTEGER,
     eventCommunity      OCTET STRING,
     eventLastTimeSent   TimeTicks,
     eventOwner          OwnerString,
     eventStatus         EntryStatus
 }

 eventIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry in the
         event table.  Each such entry defines one event that
         is to be generated when the appropriate conditions
         occur."
     ::= { eventEntry 1 }

 eventDescription OBJECT-TYPE
     SYNTAX     DisplayString (SIZE (0..127))
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "A comment describing this event entry."
     ::= { eventEntry 2 }

 eventType OBJECT-TYPE
     SYNTAX     INTEGER {
                  none(1),
                  log(2),



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                  snmptrap(3),    -- send an SNMP trap
                  logandtrap(4)
                }
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The type of notification that the probe will make
         about this event.  In the case of log, an entry is
         made in the log table for each event.  In the case of
         snmp-trap, an SNMP trap is sent to one or more
         management stations."
     ::= { eventEntry 3 }

 eventCommunity OBJECT-TYPE
     SYNTAX     OCTET STRING (SIZE (0..127))
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "If an SNMP trap is to be sent, it will be sent to
         the SNMP community specified by this octet string."
     ::= { eventEntry 4 }

 eventLastTimeSent OBJECT-TYPE
     SYNTAX     TimeTicks
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The value of sysUpTime at the time this event
         entry last generated an event.  If this entry has
         not generated any events, this value will be
         zero."
     ::= { eventEntry 5 }

 eventOwner OBJECT-TYPE
     SYNTAX     OwnerString
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The entity that configured this entry and is therefore
         using the resources assigned to it.

         If this object contains a string starting with 'monitor'
         and has associated entries in the log table, all connected
         management stations should retrieve those log entries,
         as they may have significance to all management stations
         connected to this device"
     ::= { eventEntry 6 }




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 eventStatus OBJECT-TYPE
     SYNTAX     EntryStatus
     MAX-ACCESS read-create
     STATUS     current
     DESCRIPTION
         "The status of this event entry.

         If this object is not equal to valid(1), all associated
         log entries shall be deleted by the agent."
     ::= { eventEntry 7 }

 --
 logTable OBJECT-TYPE
     SYNTAX     SEQUENCE OF LogEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A list of events that have been logged."
     ::= { event 2 }

 logEntry OBJECT-TYPE
     SYNTAX     LogEntry
     MAX-ACCESS not-accessible
     STATUS     current
     DESCRIPTION
         "A set of data describing an event that has been
         logged.  For example, an instance of the logDescription
         object might be named logDescription.6.47"
     INDEX { logEventIndex, logIndex }
     ::= { logTable 1 }

 LogEntry ::= SEQUENCE {
     logEventIndex           Integer32,
     logIndex                Integer32,
     logTime                 TimeTicks,
     logDescription          DisplayString
 }

 logEventIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..65535)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The event entry that generated this log
         entry.  The log identified by a particular
         value of this index is associated with the same
         eventEntry as identified by the same value
         of eventIndex."



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     ::= { logEntry 1 }

 logIndex OBJECT-TYPE
     SYNTAX     Integer32 (1..2147483647)
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An index that uniquely identifies an entry
         in the log table amongst those generated by the
         same eventEntries.  These indexes are
         assigned beginning with 1 and increase by one
         with each new log entry.  The association
         between values of logIndex and logEntries
         is fixed for the lifetime of each logEntry.
         The agent may choose to delete the oldest
         instances of logEntry as required because of
         lack of memory.  It is an implementation-specific
         matter as to when this deletion may occur."
     ::= { logEntry 2 }

 logTime OBJECT-TYPE
     SYNTAX     TimeTicks
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "The value of sysUpTime when this log entry was created."
     ::= { logEntry 3 }

 logDescription OBJECT-TYPE
     SYNTAX     DisplayString (SIZE (0..255))
     MAX-ACCESS read-only
     STATUS     current
     DESCRIPTION
         "An implementation dependent description of the
         event that activated this log entry."
     ::= { logEntry 4 }

 --  Remote Network Monitoring Traps

 rmonEventsV2 OBJECT-IDENTITY
     STATUS      current
     DESCRIPTION "Definition point for RMON notifications."
     ::= { rmon 0 }

 risingAlarm NOTIFICATION-TYPE
     OBJECTS  { alarmIndex, alarmVariable, alarmSampleType,
                alarmValue, alarmRisingThreshold }
     STATUS   current



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     DESCRIPTION
         "The SNMP trap that is generated when an alarm
         entry crosses its rising threshold and generates
         an event that is configured for sending SNMP
         traps."
     ::= { rmonEventsV2 1 }

 fallingAlarm NOTIFICATION-TYPE
     OBJECTS { alarmIndex, alarmVariable, alarmSampleType,
               alarmValue, alarmFallingThreshold }
     STATUS    current
     DESCRIPTION
         "The SNMP trap that is generated when an alarm
         entry crosses its falling threshold and generates
         an event that is configured for sending SNMP
         traps."
     ::= { rmonEventsV2 2 }

 -- Conformance information

 rmonCompliances OBJECT IDENTIFIER ::= { rmonConformance 9 }
 rmonGroups      OBJECT IDENTIFIER ::= { rmonConformance 10 }

 -- Compliance Statements
 rmonCompliance MODULE-COMPLIANCE
     STATUS current
     DESCRIPTION
         "The requirements for conformance to the RMON MIB. At least
         one of the groups in this module must be implemented to
         conform to the RMON MIB. Implementations of this MIB
         must also implement the system group of MIB-II [16] and the
         IF-MIB [17]."
     MODULE -- this module

       GROUP rmonEtherStatsGroup
           DESCRIPTION
               "The RMON Ethernet Statistics Group is optional."

       GROUP rmonHistoryControlGroup
           DESCRIPTION
               "The RMON History Control Group is optional."

       GROUP rmonEthernetHistoryGroup
           DESCRIPTION
               "The RMON Ethernet History Group is optional."

       GROUP rmonAlarmGroup
           DESCRIPTION



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               "The RMON Alarm Group is optional."

       GROUP rmonHostGroup
           DESCRIPTION
               "The RMON Host Group is mandatory when the
               rmonHostTopNGroup is implemented."

       GROUP rmonHostTopNGroup
           DESCRIPTION
               "The RMON Host Top N Group is optional."

       GROUP rmonMatrixGroup
           DESCRIPTION
               "The RMON Matrix Group is optional."

       GROUP rmonFilterGroup
           DESCRIPTION
               "The RMON Filter Group is mandatory when the
               rmonPacketCaptureGroup is implemented."

       GROUP rmonPacketCaptureGroup
           DESCRIPTION
               "The RMON Packet Capture Group is optional."

       GROUP rmonEventGroup
           DESCRIPTION
               "The RMON Event Group is mandatory when the
               rmonAlarmGroup is implemented."
     ::= { rmonCompliances 1 }

     rmonEtherStatsGroup OBJECT-GROUP
         OBJECTS {
             etherStatsIndex, etherStatsDataSource,
             etherStatsDropEvents, etherStatsOctets, etherStatsPkts,
             etherStatsBroadcastPkts, etherStatsMulticastPkts,
             etherStatsCRCAlignErrors, etherStatsUndersizePkts,
             etherStatsOversizePkts, etherStatsFragments,
             etherStatsJabbers, etherStatsCollisions,
             etherStatsPkts64Octets, etherStatsPkts65to127Octets,
             etherStatsPkts128to255Octets,
             etherStatsPkts256to511Octets,
             etherStatsPkts512to1023Octets,
             etherStatsPkts1024to1518Octets,
             etherStatsOwner, etherStatsStatus
         }
         STATUS current
         DESCRIPTION
             "The RMON Ethernet Statistics Group."



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         ::= { rmonGroups 1 }

     rmonHistoryControlGroup OBJECT-GROUP
         OBJECTS {
             historyControlIndex, historyControlDataSource,
             historyControlBucketsRequested,
             historyControlBucketsGranted, historyControlInterval,
             historyControlOwner, historyControlStatus
         }
         STATUS current
         DESCRIPTION
             "The RMON History Control Group."
         ::= { rmonGroups 2 }

     rmonEthernetHistoryGroup OBJECT-GROUP
         OBJECTS {
             etherHistoryIndex, etherHistorySampleIndex,
             etherHistoryIntervalStart, etherHistoryDropEvents,
             etherHistoryOctets, etherHistoryPkts,
             etherHistoryBroadcastPkts, etherHistoryMulticastPkts,
             etherHistoryCRCAlignErrors, etherHistoryUndersizePkts,
             etherHistoryOversizePkts, etherHistoryFragments,
             etherHistoryJabbers, etherHistoryCollisions,
             etherHistoryUtilization
         }
         STATUS current
         DESCRIPTION
             "The RMON Ethernet History Group."
         ::= { rmonGroups 3 }

     rmonAlarmGroup OBJECT-GROUP
         OBJECTS {
             alarmIndex, alarmInterval, alarmVariable,
             alarmSampleType, alarmValue, alarmStartupAlarm,
             alarmRisingThreshold, alarmFallingThreshold,
             alarmRisingEventIndex, alarmFallingEventIndex,
             alarmOwner, alarmStatus
         }
         STATUS current
         DESCRIPTION
             "The RMON Alarm Group."
         ::= { rmonGroups 4 }

     rmonHostGroup OBJECT-GROUP
         OBJECTS {
             hostControlIndex, hostControlDataSource,
             hostControlTableSize, hostControlLastDeleteTime,
             hostControlOwner, hostControlStatus,



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             hostAddress, hostCreationOrder, hostIndex,
             hostInPkts, hostOutPkts, hostInOctets,
             hostOutOctets, hostOutErrors, hostOutBroadcastPkts,
             hostOutMulticastPkts, hostTimeAddress,
             hostTimeCreationOrder, hostTimeIndex,
             hostTimeInPkts, hostTimeOutPkts, hostTimeInOctets,
             hostTimeOutOctets, hostTimeOutErrors,
             hostTimeOutBroadcastPkts, hostTimeOutMulticastPkts
         }
         STATUS current
         DESCRIPTION
             "The RMON Host Group."
         ::= { rmonGroups 5 }

     rmonHostTopNGroup OBJECT-GROUP
         OBJECTS {
             hostTopNControlIndex, hostTopNHostIndex,
             hostTopNRateBase, hostTopNTimeRemaining,
             hostTopNDuration, hostTopNRequestedSize,
             hostTopNGrantedSize, hostTopNStartTime,
             hostTopNOwner, hostTopNStatus,
             hostTopNReport, hostTopNIndex,
             hostTopNAddress, hostTopNRate
         }
         STATUS current
         DESCRIPTION
             "The RMON Host Top 'N' Group."
         ::= { rmonGroups 6 }

     rmonMatrixGroup OBJECT-GROUP
         OBJECTS {
             matrixControlIndex, matrixControlDataSource,
             matrixControlTableSize, matrixControlLastDeleteTime,
             matrixControlOwner, matrixControlStatus,
             matrixSDSourceAddress, matrixSDDestAddress,
             matrixSDIndex, matrixSDPkts,
             matrixSDOctets, matrixSDErrors,
             matrixDSSourceAddress, matrixDSDestAddress,
             matrixDSIndex, matrixDSPkts,
             matrixDSOctets, matrixDSErrors
         }
         STATUS current
         DESCRIPTION
             "The RMON Matrix Group."
         ::= { rmonGroups 7 }

     rmonFilterGroup OBJECT-GROUP
         OBJECTS {



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             filterIndex, filterChannelIndex, filterPktDataOffset,
             filterPktData, filterPktDataMask,
             filterPktDataNotMask, filterPktStatus,
             filterPktStatusMask, filterPktStatusNotMask,
             filterOwner, filterStatus,
             channelIndex, channelIfIndex, channelAcceptType,
             channelDataControl, channelTurnOnEventIndex,
             channelTurnOffEventIndex, channelEventIndex,
             channelEventStatus, channelMatches,
             channelDescription, channelOwner, channelStatus
         }
         STATUS current
         DESCRIPTION
             "The RMON Filter Group."
         ::= { rmonGroups 8 }

     rmonPacketCaptureGroup OBJECT-GROUP
         OBJECTS {
             bufferControlIndex, bufferControlChannelIndex,
             bufferControlFullStatus, bufferControlFullAction,
             bufferControlCaptureSliceSize,
             bufferControlDownloadSliceSize,
             bufferControlDownloadOffset,
             bufferControlMaxOctetsRequested,
             bufferControlMaxOctetsGranted,
             bufferControlCapturedPackets,
             bufferControlTurnOnTime,
             bufferControlOwner, bufferControlStatus,
             captureBufferControlIndex, captureBufferIndex,
             captureBufferPacketID, captureBufferPacketData,
             captureBufferPacketLength, captureBufferPacketTime,
             captureBufferPacketStatus
         }
         STATUS current
         DESCRIPTION
             "The RMON Packet Capture Group."
         ::= { rmonGroups 9 }

     rmonEventGroup OBJECT-GROUP
         OBJECTS {
             eventIndex, eventDescription, eventType,
             eventCommunity, eventLastTimeSent,
             eventOwner, eventStatus,
             logEventIndex, logIndex, logTime,
             logDescription
         }
         STATUS current
         DESCRIPTION



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             "The RMON Event Group."
         ::= { rmonGroups 10 }

     rmonNotificationGroup NOTIFICATION-GROUP
         NOTIFICATIONS { risingAlarm, fallingAlarm }
         STATUS        current
         DESCRIPTION
             "The RMON Notification Group."
         ::= { rmonGroups 11 }
 END

6.  Security Considerations

   In order to implement this MIB, a probe must capture all packets on
   the locally-attached network, including packets between third
   parties.  These packets are analyzed to collect network addresses,
   protocol usage information, and conversation statistics. Data of this
   nature may be considered sensitive in some environments. In such
   environments the administrator may wish to restrict SNMP access to
   the probe.

   This MIB also includes functions for returning the contents of
   captured packets, potentially including sensitive user data or
   passwords. It is recommended that SNMP access to these functions be
   restricted.

   There are a number of management objects defined in this MIB that
   have a MAX-ACCESS clause of read-write and/or read-create.  Such
   objects may be considered sensitive or vulnerable in some network
   environments.  The support for SET operations in a non-secure
   environment without proper protection can have a negative effect on
   network operations.

   SNMPv1 by itself is not a secure environment.  Even if the network
   itself is secure (for example by using IPSec), even then, there is no
   control as to who on the secure network is allowed to access and
   GET/SET (read/change/create/delete) the objects in this MIB.

   It is recommended that the implementors consider the security
   features as provided by the SNMPv3 framework.  Specifically, the use
   of the User-based Security Model RFC 2574 [12] and the View-based
   Access Control Model RFC 2575 [15] is recommended.

   It is then a customer/user responsibility to ensure that the SNMP
   entity giving access to an instance of this MIB, is properly
   configured to give access to the objects only to those principals
   (users) that have legitimate rights to indeed GET or SET
   (change/create/delete) them.



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7.  Acknowledgments

   This document was produced by the IETF Remote Network Monitoring
   Working Group.

8.  Author's Address

   Steve Waldbusser

   Phone: +1-650-948-6500
   Fax:   +1-650-745-0671
   Email: waldbusser@nextbeacon.com

9.  References

   [1]  Harrington, D., Presuhn, R., and B. Wijnen, "An Architecture for
        Describing SNMP Management Frameworks", RFC 2571, April 1999.

   [2]  Rose, M. and K. McCloghrie, "Structure and Identification of
        Management Information for TCP/IP-based Internets", STD 16, RFC
        1155, May 1990.

   [3]  Rose, M. and K. McCloghrie, "Concise MIB Definitions", STD 16,
        RFC 1212, March 1991.

   [4]  Rose, M., "A Convention for Defining Traps for use with the
        SNMP", RFC 1215, March 1991.

   [5]  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.

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

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

   [8]  Case, J., Fedor, M., Schoffstall, M. and J. Davin, "Simple
        Network Management Protocol", STD 15, RFC 1157, May 1990.

   [9]  Case, J., McCloghrie, K., Rose, M. and S. Waldbusser,
        "Introduction to Community-based SNMPv2", RFC 1901, January
        1996.





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   [10] Case, J., McCloghrie, K., Rose, M. and S. Waldbusser, "Transport
        Mappings for Version 2 of the Simple Network Management Protocol
        (SNMPv2)", RFC 1906, January 1996.

   [11] Case, J., Harrington D., Presuhn R. and B. Wijnen, "Message
        Processing and Dispatching for the Simple Network Management
        Protocol (SNMP)", RFC 2572, April 1999.

   [12] Blumenthal, U. and B. Wijnen, "User-based Security Model (USM)
        for version 3 of the Simple Network Management Protocol
        (SNMPv3)", RFC 2574, April 1999.

   [13] Case, J., McCloghrie, K., Rose, M. and S. Waldbusser, "Protocol
        Operations for Version 2 of the Simple Network Management
        Protocol (SNMPv2)", RFC 1905, January 1996.

   [14] Levi, D., Meyer, P. and B. Stewart, "SNMPv3 Applications", RFC
        2573, April 1999.

   [15] Wijnen, B., Presuhn, R. and K. McCloghrie, "View-based Access
        Control Model (VACM) for the Simple Network Management Protocol
        (SNMP)", RFC 2575, April 1999.

   [16] McCloghrie, K. and M. Rose, Editors, "Management Information
        Base for Network Management of TCP/IP-based internets: MIB-II",
        STD 17, RFC 1213, March 1991.

   [17] McCloghrie, K. and F. Kastenholz, "The Interfaces Group MIB
        using SMIv2", RFC 2233, November 1997.

   [18] Waldbusser, S., "Remote Network Monitoring MIB", RFC 1757,
        February 1995.

   [19] Waldbusser, S., "Token Ring Extensions to the Remote Network
        Monitoring MIB", RFC 1513, September 1993.

   [20] Waldbusser, S., "Remote Network Monitoring Management
        Information Base Version 2 using SMIv2", RFC 2021, January 1997.

   [21] Waterman, R., Lahaye, B., Romascanu, D. and S.  Waldbusser,
        "Remote Network Monitoring MIB Extensions for Switched Networks
        Version 1.0", RFC 2613, June 1999.

   [22] Case, J., Mundy, R., Partain, D. and B. Stewart, "Introduction
        to Version 3 of the Internet-standard Network Management
        Framework", RFC 2570, April 1999.





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RFC 2819             Remote Network Monitoring MIB              May 2000


10.  Intellectual Property

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RFC 2819             Remote Network Monitoring MIB              May 2000


11.  Full Copyright Statement

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