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rfc:rfc2128

Network Working Group G. Roeck, Editor Request for Comments: 2128 cisco Systems Category: Standards Track March 1997

        Dial Control Management Information Base using SMIv2

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.

Abstract

 This memo defines a portion of the Management Information Base (MIB)
 for use with network management protocols in the Internet community.
 In particular, it describes managed objects used for managing demand
 access circuits, including ISDN.
 This document specifies a MIB module in a manner that is compliant to
 the SNMPv2 SMI.  The set of objects is consistent with the SNMP
 framework and existing SNMP standards.
 This document is a product of the ISDN MIB working group within the
 Internet Engineering Task Force.  Comments are solicited and should
 be addressed to the working group's mailing list at isdn-
 mib@cisco.com and/or the author.

Table of Contents

 1 The SNMPv2 Network Management Framework ......................    2
 1.1 Object Definitions .........................................    2
 2 Overview .....................................................    2
 2.1 Structure of MIB ...........................................    2
 2.2 Relationship to the Interfaces MIB .........................    3
 2.2.1 Layering Model and Virtual Circuits ......................    3
 2.2.2 ifTestTable ..............................................    4
 2.2.3 ifRcvAddressTable ........................................    4
 2.2.3.1 ifEntry for a single peer ..............................    5
 2.3 Multilink and backup line support ..........................    5
 2.4 Support for generic peers ..................................    5
 3 Definitions ..................................................    6
 3.1 Dial Control MIB ...........................................    6
 4 Acknowledgments ..............................................   32
 5 References ...................................................   33

Roeck Standards Track [Page 1] RFC 2128 Dial Control MIB March 1997

 6 Security Considerations ......................................   33
 7 Author's Address .............................................   34

1. The SNMPv2 Network Management Framework

 The SNMPv2 Network Management Framework presently consists of three
 major components.  They are:
 o    the SMI, described in RFC 1902 [1] - the mechanisms used for
      describing and naming objects for the purpose of management.
 o    the MIB-II, STD 17, RFC 1213 [2] - the core set of managed
      objects for the Internet suite of protocols.
 o    the protocol, STD 15, RFC 1157 [3] and/or RFC 1905 [4], -
      the protocol for accessing managed objects.
 The Framework permits new objects to be defined for the purpose of
 experimentation and evaluation.

1.1. Object Definitions

 Managed objects are accessed via a virtual information store, termed
 the Management Information Base or MIB.  Objects in the MIB are
 defined using the subset of Abstract Syntax Notation One (ASN.1)
 defined in the SMI.  In particular, each object type is named by an
 OBJECT IDENTIFIER, an administratively assigned name.  The object
 type together with an object instance serves to uniquely identify a
 specific instantiation of the object.  For human convenience, we
 often use a textual string, termed the descriptor, to refer to the
 object type.

2. Overview

2.1. Structure of MIB

 Managing demand access circuits requires the following groups of
 information:
 o    General configuration information.
 o    Information to describe peer configuration and peer statistics.
      In this respect, peer configuration means information on how to
      connect to peers on outgoing calls, how to identify peers on
      incoming calls, and other call related configuration
      information.
 o    Information to store active call information.

Roeck Standards Track [Page 2] RFC 2128 Dial Control MIB March 1997

 o    Information to retain call history.
 The MIB, therefore, is structured into four groups.
 o    The dialCtlConfiguration group is used to specify general
      configuration information.
 o    The dialCtlPeer group is used to describe peer configuration
      and peer statistics.
 o    The callActive group is used to store active call information.
 o    The callHistory group is used to store call history information.
      These calls could be circuit switched or they could be virtual
      circuits. History of each and every call is stored, of successful
      calls as well as unsuccessful and rejected calls.  An entry will
      be created when a call is cleared.

2.2. Relationship to the Interfaces MIB

 This section clarifies the relationship of this MIB to the Interfaces
 MIB [8].  Several areas of correlation are addressed in the following
 subsections.  The implementor is referred to the Interfaces MIB
 document in order to understand the general intent of these areas.

2.2.1. Layering Model and Virtual Circuits

 On an occasional access channel, there are a number of peer systems
 that are permitted to call or be called, all of which need to be
 treated as active from a routing viewpoint, but most of which have no
 call in progress at any given time.
 On dialup interfaces, this is further complicated by the fact that
 calls to a given peer float from channel to channel. One cannot
 definitively say "I call this peer on that interface." It is
 necessary, therefore, to provide a mapping algorithm between the
 low-level interfaces, and the various logical interfaces supporting
 the peers.  This is solved by creating a logical interface (ifEntry)
 for each peer and a logical interface (ifEntry) for each low-level
 interface.  These are then correlated using the ifStackTable.
 The low-level interfaces are either physical interfaces, e.g.  modem
 interfaces, or logical interfaces, e.g. ISDN B channels, which then
 in turn are layered on top of physical ISDN interfaces.

Roeck Standards Track [Page 3] RFC 2128 Dial Control MIB March 1997

 The model, therefore, looks something like this, taking ISDN as an
 example:

+——————————————————-+

Network Layer Protocol

+——+ +——-+ +——-+ +——-+ +——-+ +——+

     | |       | |       | |       | |       | | <== appears active
   +-+ +-+   +-+ +-+   +-+ +-+   +-+ +-+   +-+ +-+
   | PPP |   | PPP |   | F/R |   | PPP |   | F/R |
   | for |   | for |   | for |   | for |   | for |   ifEntry with
   |Peer1|   |Peer2|   |switch   |Peer3|   |switch   shadow PeerEntry
   |     |   |     |   |  A  |   |     |   |  B  |
   +-+ +-+   +-+ +-+   +-+ +-+   +-+ +-+   +-+ +-+
               | |                 | |           <== some actually are
  +--+ +--+ +--+ +--+ +--+ +--+ +--+ +--+ +--+ +--+
  |   B   | |   B   | |   B   | |   B   | |   B   |
  |channel| |channel| |channel| |channel| |channel|
  +--+ +--+ +--+ +--+ +--+ +--+ +--+ +--+ +--+ +--+
     | |       | |       | |       | |       | |

+——+ +——-+ +——-+ +——-+ +——-+ +——+

Basic/Primary Rate Interface

+——————————————————-+

 Mapping of IP interfaces to Called Peers to B Channels
 IfEntries are maintained for each peer.
 In this model, each peer is required to have an associated
 encapsulation layer interface. This interface can be of any kind,
 e.g. PPP or LAPB.
 In order to specify the network address for a given peer, one would
 then usually add a routing/forwarding table entry, pointing to the
 encapsulation layer interface through which this peer can be reached.

2.2.2. ifTestTable

 The ifTestTable usage is defined in the MIBs defining the
 encapsulation below the network layer.  For example, if PPP
 encapsulation is being used, the ifTestTable is defined by PPP.

2.2.3. ifRcvAddressTable

 The ifRcvAddressTable usage is defined in the MIBs defining the
 encapsulation below the network layer.  For example, if PPP
 encapsulation is being used, the ifRcvAddressTable is defined by PPP.

Roeck Standards Track [Page 4] RFC 2128 Dial Control MIB March 1997

2.2.3.1. ifEntry for a single peer

 IfEntries are defined in the MIBs defining the encapsulation below
 the network layer.  For example, if PPP encapsulation is being used,
 the ifEntry is defined by PPP.
 ifEntries will never be created by the Dial Control MIB.  The Dial
 Control MIB always depends on some other ifIndex of some set of
 ifTypes.  That is, to create an entry in the Dial Control MIB, the
 base ifEntry must already have been created through some other
 mechanism.
 The Dial Control entry does have its own RowStatus, permitting the
 Dial Control supplementary information to come and go, but not
 otherwise disturbing the ifIndex to which it is attached.  If in a
 given implementation the two are tightly bound, deleting the ifEntry
 may have the side effect of deleting the Dial Control entry.

2.3. Multilink and backup line support

 In order to support multilink and backup procedures, there may be
 several entries for a single peer in the dialCtlPeerCfgTable.
 A single peer is identified using the dialCtlPeerCfgId object of the
 dialCtlPeerCfgTable.  There may be several entries in
 dialCtlPeerCfgTable with the same value of dialCtlPeerCfgId, but
 different ifIndex values.  Each of those entries will then describe a
 possible connection to the same peer.  Such entries can then be used
 to handle multilink as well as backup procedures, e.g. by bundling
 the attached ifEntries using PPP multilink.

2.4. Support for generic peers

 Generic peers can for example be supported by permitting wild-card
 characters (e.g., '?' or '*') in dialCtlPeerCfgAnswerAddress.  A
 number to be accepted could then be defined as partly (e.g., '*1234')
 or entirely generic (e.g., '*').
 A detailed specification of such a functionality is outside the scope
 of this document.
 However, the implementor should be aware that supporting generic
 peers may cause a security hole.  The user would not know where a
 call is from, which could potentially allow unauthorized access.

Roeck Standards Track [Page 5] RFC 2128 Dial Control MIB March 1997

3. Definitions

3.1. Dial Control MIB

DIAL-CONTROL-MIB DEFINITIONS ::= BEGIN

IMPORTS

      MODULE-IDENTITY,
      NOTIFICATION-TYPE,
      OBJECT-TYPE,
      Unsigned32
              FROM SNMPv2-SMI
      TEXTUAL-CONVENTION,
      DisplayString,
      TimeStamp,
      RowStatus
               FROM SNMPv2-TC
      MODULE-COMPLIANCE,
      OBJECT-GROUP,
      NOTIFICATION-GROUP
              FROM SNMPv2-CONF
      IANAifType
              FROM IANAifType-MIB
      ifOperStatus,
      ifIndex,
      InterfaceIndex,
      InterfaceIndexOrZero
              FROM IF-MIB
      transmission
              FROM RFC1213-MIB;

dialControlMib MODULE-IDENTITY

      LAST-UPDATED    "9609231544Z" -- Sep 23, 1996
      ORGANIZATION    "IETF ISDN Working Group"
      CONTACT-INFO
          "        Guenter Roeck
           Postal: cisco Systems
                   170 West Tasman Drive
                   San Jose, CA 95134
                   U.S.A.
           Phone:  +1 408 527 3143
           E-mail: groeck@cisco.com"
      DESCRIPTION
          "The MIB module to describe peer information for
           demand access and possibly other kinds of interfaces."
      ::= { transmission 21 }

AbsoluteCounter32 ::= TEXTUAL-CONVENTION

Roeck Standards Track [Page 6] RFC 2128 Dial Control MIB March 1997

      STATUS      current
      DESCRIPTION
          "Represents a Counter32-like value that starts at zero,
           does not decrease, and does not wrap. This may be used
           only in situations where wrapping is not possible or
           extremely unlikely. Should such a counter overflow,
           it locks at the maxium value of 4,294,967,295.
           The primary use of this type of counter is situations
           where a counter value is to be recorded as history
           and is thus no longer subject to reading for changing
           values."
      SYNTAX      Unsigned32

– Dial Control Mib objects definitions

dialControlMibObjects OBJECT IDENTIFIER ::= { dialControlMib 1 }

– General configuration group

dialCtlConfiguration OBJECT IDENTIFIER ::= { dialControlMibObjects 1 }

– general configuration data/parameters

dialCtlAcceptMode OBJECT-TYPE

      SYNTAX INTEGER {
          acceptNone(1),
          acceptAll(2),
          acceptKnown(3)
      }
      MAX-ACCESS  read-write
      STATUS      current
      DESCRIPTION
          "The security level for acceptance of incoming calls.
           acceptNone(1)  - incoming calls will not be accepted
           acceptAll(2)   - incoming calls will be accepted,
                            even if there is no matching entry
                            in the dialCtlPeerCfgTable
           acceptKnown(3) - incoming calls will be accepted only
                            if there is a matching entry in the
                            dialCtlPeerCfgTable
          "
      ::= { dialCtlConfiguration 1 }

dialCtlTrapEnable OBJECT-TYPE

      SYNTAX      INTEGER {
          enabled(1),
          disabled(2)

Roeck Standards Track [Page 7] RFC 2128 Dial Control MIB March 1997

      }
      MAX-ACCESS  read-write
      STATUS      current
      DESCRIPTION
          "This object indicates whether dialCtlPeerCallInformation
           and dialCtlPeerCallSetup traps should be generated for
           all peers. If the value of this object is enabled(1),
           traps will be generated for all peers. If the value
           of this object is disabled(2), traps will be generated
           only for peers having dialCtlPeerCfgTrapEnable set
           to enabled(1)."
      DEFVAL      { disabled }
      ::= { dialCtlConfiguration 2 }

– Peer group

dialCtlPeer OBJECT IDENTIFIER ::= { dialControlMibObjects 2 }

– peer configuration table

dialCtlPeerCfgTable OBJECT-TYPE

      SYNTAX      SEQUENCE OF DialCtlPeerCfgEntry
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "The list of peers from which the managed device
           will accept calls or to which it will place them."
     ::= { dialCtlPeer 1 }

dialCtlPeerCfgEntry OBJECT-TYPE

      SYNTAX      DialCtlPeerCfgEntry
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "Configuration data for a single Peer. This entry is
           effectively permanent, and contains information
           to identify the peer, how to connect to the peer,
           how to identify the peer and its permissions.
           The value of dialCtlPeerCfgOriginateAddress must be
           specified before a new row in this table can become
           active(1). Any writeable parameters in an existing entry
           can be modified while the entry is active. The modification
           will take effect when the peer in question will be
           called the next time.
           An entry in this table can only be created if the
           associated ifEntry already exists."
      INDEX       { dialCtlPeerCfgId, ifIndex }

Roeck Standards Track [Page 8] RFC 2128 Dial Control MIB March 1997

    ::= { dialCtlPeerCfgTable 1 }

DialCtlPeerCfgEntry ::= SEQUENCE {

          dialCtlPeerCfgId                 INTEGER,
          dialCtlPeerCfgIfType             IANAifType,
          dialCtlPeerCfgLowerIf            InterfaceIndexOrZero,
          dialCtlPeerCfgOriginateAddress   DisplayString,
          dialCtlPeerCfgAnswerAddress      DisplayString,
          dialCtlPeerCfgSubAddress         DisplayString,
          dialCtlPeerCfgClosedUserGroup    DisplayString,
          dialCtlPeerCfgSpeed              INTEGER,
          dialCtlPeerCfgInfoType           INTEGER,
          dialCtlPeerCfgPermission         INTEGER,
          dialCtlPeerCfgInactivityTimer    INTEGER,
          dialCtlPeerCfgMinDuration        INTEGER,
          dialCtlPeerCfgMaxDuration        INTEGER,
          dialCtlPeerCfgCarrierDelay       INTEGER,
          dialCtlPeerCfgCallRetries        INTEGER,
          dialCtlPeerCfgRetryDelay         INTEGER,
          dialCtlPeerCfgFailureDelay       INTEGER,
          dialCtlPeerCfgTrapEnable         INTEGER,
          dialCtlPeerCfgStatus             RowStatus
      }

dialCtlPeerCfgId OBJECT-TYPE

      SYNTAX      INTEGER (1..2147483647)
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "This object identifies a single peer. There may
           be several entries in this table for one peer,
           defining different ways of reaching this peer.
           Thus, there may be several entries in this table
           with the same value of dialCtlPeerCfgId.
           Multiple entries for one peer may be used to support
           multilink as well as backup lines.
           A single peer will be identified by a unique value
           of this object. Several entries for one peer MUST
           have the same value of dialCtlPeerCfgId, but different
           ifEntries and thus different values of ifIndex."
      ::= { dialCtlPeerCfgEntry 1 }

dialCtlPeerCfgIfType OBJECT-TYPE

      SYNTAX      IANAifType
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "The interface type to be used for calling this peer.

Roeck Standards Track [Page 9] RFC 2128 Dial Control MIB March 1997

           In case of ISDN, the value of isdn(63) is to be used."
      DEFVAL      { other }
      ::= { dialCtlPeerCfgEntry 2 }

dialCtlPeerCfgLowerIf OBJECT-TYPE

      SYNTAX      InterfaceIndexOrZero
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "ifIndex value of an interface the peer will have to be
           called on. For example, on an ISDN interface, this can be
           the ifIndex value of a D channel or the ifIndex value of a
           B channel, whatever is appropriate for a given peer.
           As an example, for Basic Rate leased lines it will be
           necessary to specify a B channel ifIndex, while for
           semi-permanent connections the D channel ifIndex has
           to be specified.
           If the interface can be dynamically assigned, this object
           has a value of zero."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 3 }

dialCtlPeerCfgOriginateAddress OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "Call Address at which the peer will be called.
           Think of this as the set of characters following 'ATDT '
           or the 'phone number' included in a D channel call request.
           The structure of this information will be switch type
           specific. If there is no address information required
           for reaching the peer, i.e., for leased lines,
           this object will be a zero length string."
      ::= { dialCtlPeerCfgEntry 4 }

dialCtlPeerCfgAnswerAddress OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "Calling Party Number information element, as for example
           passed in an ISDN SETUP message by a PBX or switch,
           for incoming calls.
           This address can be used to identify the peer.
           If this address is either unknown or identical
           to dialCtlPeerCfgOriginateAddress, this object will be

Roeck Standards Track [Page 10] RFC 2128 Dial Control MIB March 1997

           a zero length string."
      DEFVAL      { "" }
      ::= { dialCtlPeerCfgEntry 5 }

dialCtlPeerCfgSubAddress OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "Subaddress at which the peer will be called.
           If the subaddress is undefined for the given media or
           unused, this is a zero length string."
      DEFVAL      { "" }
      ::= { dialCtlPeerCfgEntry 6 }

dialCtlPeerCfgClosedUserGroup OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "Closed User Group at which the peer will be called.
           If the Closed User Group is undefined for the given media
           or unused, this is a zero length string."
      REFERENCE
          "Q.931, chapter 4.6.1."
      DEFVAL      { "" }
      ::= { dialCtlPeerCfgEntry 7 }

dialCtlPeerCfgSpeed OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "The desired information transfer speed in bits/second
           when calling this peer.
           The detailed media specific information, e.g. information
           type and information transfer rate for ISDN circuits,
           has to be extracted from this object.
           If the transfer speed to be used is unknown or the default
           speed for this type of interfaces, the value of this object
           may be zero."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 8 }

dialCtlPeerCfgInfoType OBJECT-TYPE

      SYNTAX      INTEGER {
          other(1),
          speech(2),

Roeck Standards Track [Page 11] RFC 2128 Dial Control MIB March 1997

          unrestrictedDigital(3),     -- 64k/s data
          unrestrictedDigital56(4),   -- with 56k rate adaption
          restrictedDigital(5),
          audio31(6),                 -- 3.1 kHz audio
          audio7(7),                  -- 7 kHz audio
          video(8),
          packetSwitched(9),
          fax(10)
      }
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "The Information Transfer Capability to be used when
           calling this peer.
           speech(2) refers to a non-data connection, whereas
           audio31(6) and audio7(7) refer to data mode
           connections."
      DEFVAL      { other }
      ::= { dialCtlPeerCfgEntry 9 }

dialCtlPeerCfgPermission OBJECT-TYPE

      SYNTAX      INTEGER {
          originate(1),
          answer(2),
          both(3),               -- both originate & answer
          callback(4),
          none(5)
      }
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "Applicable permissions. callback(4) either rejects the
           call and then calls back, or uses the 'Reverse charging'
           information element if it is available.
           Note that callback(4) is supposed to control charging, not
           security, and applies to callback prior to accepting a
           call. Callback for security reasons can be handled using
           PPP callback."
      DEFVAL      { both }
      ::= { dialCtlPeerCfgEntry 10 }

dialCtlPeerCfgInactivityTimer OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      UNITS       "seconds"
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION

Roeck Standards Track [Page 12] RFC 2128 Dial Control MIB March 1997

          "The connection will be automatically disconnected
           if no longer carrying useful data for a time
           period, in seconds, specified in this object.
           Useful data in this context refers to forwarding
           packets, including routing information; it
           excludes the encapsulator maintenance frames.
           A value of zero means the connection will not be
           automatically taken down due to inactivity,
           which implies that it is a dedicated circuit."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 11 }

dialCtlPeerCfgMinDuration OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "Minimum duration of a call in seconds, starting from the
           time the call is connected until the call is disconnected.
           This is to accomplish the fact that in most countries
           charging applies to units of time, which should be matched
           as closely as possible."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 12 }

dialCtlPeerCfgMaxDuration OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "Maximum call duration in seconds. Zero means 'unlimited'."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 13 }

dialCtlPeerCfgCarrierDelay OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      UNITS       "seconds"
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "The call timeout time in seconds. The default value
           of zero means that the call timeout as specified for
           the media in question will apply."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 14 }

dialCtlPeerCfgCallRetries OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)

Roeck Standards Track [Page 13] RFC 2128 Dial Control MIB March 1997

      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "The number of calls to a non-responding address
           that may be made. A retry count of zero means
           there is no bound. The intent is to bound
           the number of successive calls to an address
           which is inaccessible, or which refuses those calls.
           Some countries regulate the number of call retries
           to a given peer that can be made."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 15 }

dialCtlPeerCfgRetryDelay OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      UNITS       "seconds"
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "The time in seconds between call retries if a peer
           cannot be reached.
           A value of zero means that call retries may be done
           without any delay."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 16 }

dialCtlPeerCfgFailureDelay OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      UNITS       "seconds"
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "The time in seconds after which call attempts are
           to be placed again after a peer has been noticed
           to be unreachable, i.e. after dialCtlPeerCfgCallRetries
           unsuccessful call attempts.
           A value of zero means that a peer will not be called
           again after dialCtlPeerCfgCallRetries unsuccessful call
           attempts."
      DEFVAL      { 0 }
      ::= { dialCtlPeerCfgEntry 17 }

dialCtlPeerCfgTrapEnable OBJECT-TYPE

      SYNTAX      INTEGER {
          enabled(1),
          disabled(2)
      }

Roeck Standards Track [Page 14] RFC 2128 Dial Control MIB March 1997

      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "This object indicates whether dialCtlPeerCallInformation
           and dialCtlPeerCallSetup traps should be generated for
           this peer."
      DEFVAL      { disabled }
      ::= { dialCtlPeerCfgEntry 18 }

dialCtlPeerCfgStatus OBJECT-TYPE

      SYNTAX      RowStatus
      MAX-ACCESS  read-create
      STATUS      current
      DESCRIPTION
          "Status of one row in this table."
      ::= { dialCtlPeerCfgEntry 19 }

– Peer statistics table

dialCtlPeerStatsTable OBJECT-TYPE

      SYNTAX      SEQUENCE OF DialCtlPeerStatsEntry
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "Statistics information for each peer entry.
           There will be one entry in this table for each entry
           in the dialCtlPeerCfgTable."
     ::= { dialCtlPeer 2 }

dialCtlPeerStatsEntry OBJECT-TYPE

      SYNTAX      DialCtlPeerStatsEntry
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "Statistics information for a single Peer. This entry
           is effectively permanent, and contains information
           describing the last call attempt as well as supplying
           statistical information."
      AUGMENTS    { dialCtlPeerCfgEntry }
    ::= { dialCtlPeerStatsTable 1 }

DialCtlPeerStatsEntry ::=

      SEQUENCE {
          dialCtlPeerStatsConnectTime          AbsoluteCounter32,
          dialCtlPeerStatsChargedUnits         AbsoluteCounter32,
          dialCtlPeerStatsSuccessCalls         AbsoluteCounter32,
          dialCtlPeerStatsFailCalls            AbsoluteCounter32,
          dialCtlPeerStatsAcceptCalls          AbsoluteCounter32,

Roeck Standards Track [Page 15] RFC 2128 Dial Control MIB March 1997

          dialCtlPeerStatsRefuseCalls          AbsoluteCounter32,
          dialCtlPeerStatsLastDisconnectCause  OCTET STRING,
          dialCtlPeerStatsLastDisconnectText   DisplayString,
          dialCtlPeerStatsLastSetupTime        TimeStamp
      }

dialCtlPeerStatsConnectTime OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      UNITS       "seconds"
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "Accumulated connect time to the peer since system startup.
           This is the total connect time, i.e. the connect time
           for outgoing calls plus the time for incoming calls."
      ::= { dialCtlPeerStatsEntry 1 }

dialCtlPeerStatsChargedUnits OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The total number of charging units applying to this
           peer since system startup.
           Only the charging units applying to the local interface,
           i.e. for originated calls or for calls with 'Reverse
           charging' being active, will be counted here."
      ::= { dialCtlPeerStatsEntry 2 }

dialCtlPeerStatsSuccessCalls OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "Number of completed calls to this peer."
      ::= { dialCtlPeerStatsEntry 3 }

dialCtlPeerStatsFailCalls OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "Number of failed call attempts to this peer since system
           startup."
      ::= { dialCtlPeerStatsEntry 4 }

dialCtlPeerStatsAcceptCalls OBJECT-TYPE

      SYNTAX      AbsoluteCounter32

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      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "Number of calls from this peer accepted since system
           startup."
      ::= { dialCtlPeerStatsEntry 5 }

dialCtlPeerStatsRefuseCalls OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "Number of calls from this peer refused since system
           startup."
      ::= { dialCtlPeerStatsEntry 6 }

dialCtlPeerStatsLastDisconnectCause OBJECT-TYPE

      SYNTAX      OCTET STRING (SIZE (0..4))
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The encoded network cause value associated with the last
           call.
           This object will be updated whenever a call is started
           or cleared.
           The value of this object will depend on the interface type
           as well as on the protocol and protocol version being
           used on this interface. Some references for possible cause
           values are given below."
      REFERENCE
          "- Bellcore SR-NWT-001953, Generic Guidelines for
             ISDN Terminal Equipment On Basic Access Interfaces,
             chapter 5.2.5.8.
           - Bellcore SR-NWT-002343, ISDN Primary Rate Interface
             Generic Guidelines for Customer Premises Equipment,
             chapter 8.2.5.8.
           - ITU-T Q.931, Appendix I.
           - ITU-T X.25, CAUSE and DIAGNOSTIC field values.
           - German Telekom FTZ 1TR6, chapter 3.2.3.4.4.4."
      ::= { dialCtlPeerStatsEntry 7 }

dialCtlPeerStatsLastDisconnectText OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "ASCII text describing the reason for the last call
           termination.

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           This object exists because it would be impossible for
           a management station to store all possible cause values
           for all types of interfaces. It should be used only if
           a management station is unable to decode the value of
           dialCtlPeerStatsLastDisconnectCause.
           This object will be updated whenever a call is started
           or cleared."
      ::= { dialCtlPeerStatsEntry 8 }

dialCtlPeerStatsLastSetupTime OBJECT-TYPE

      SYNTAX      TimeStamp
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The value of sysUpTime when the last call to this peer
           was started.
           For ISDN media, this will be the time when the setup
           message was received from or sent to the network.
           This object will be updated whenever a call is started
           or cleared."
      ::= { dialCtlPeerStatsEntry 9 }

– – the active call group –

callActive OBJECT IDENTIFIER ::= { dialControlMibObjects 3 }

– callActiveTable – Table to store active call information. – These calls could be circuit switched or they could – be virtual circuits. – An entry will be created when a call is started and deleted – when a call is cleared.

callActiveTable OBJECT-TYPE

      SYNTAX      SEQUENCE OF CallActiveEntry
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "A table containing information about active
           calls to a specific destination."
      ::= { callActive 1 }

callActiveEntry OBJECT-TYPE

      SYNTAX      CallActiveEntry
      MAX-ACCESS  not-accessible

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      STATUS      current
      DESCRIPTION
          "The information regarding a single active Connection.
           An entry in this table will be created when a call is
           started. An entry in this table will be deleted when
           an active call clears."
      INDEX       { callActiveSetupTime, callActiveIndex }
      ::= { callActiveTable 1 }

CallActiveEntry ::=

      SEQUENCE {
          callActiveSetupTime                  TimeStamp,
          callActiveIndex                      INTEGER,
          callActivePeerAddress                DisplayString,
          callActivePeerSubAddress             DisplayString,
          callActivePeerId                     INTEGER,
          callActivePeerIfIndex                INTEGER,
          callActiveLogicalIfIndex             InterfaceIndexOrZero,
          callActiveConnectTime                TimeStamp,
          callActiveCallState                  INTEGER,
          callActiveCallOrigin                 INTEGER,
          callActiveChargedUnits               AbsoluteCounter32,
          callActiveInfoType                   INTEGER,
          callActiveTransmitPackets            AbsoluteCounter32,
          callActiveTransmitBytes              AbsoluteCounter32,
          callActiveReceivePackets             AbsoluteCounter32,
          callActiveReceiveBytes               AbsoluteCounter32
      }

callActiveSetupTime OBJECT-TYPE

      SYNTAX      TimeStamp
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "The value of sysUpTime when the call associated to this
           entry was started. This will be useful for an NMS to
           retrieve all calls after a specific time. Also, this object
           can be useful in finding large delays between the time the
           call was started and the time the call was connected.
           For ISDN media, this will be the time when the setup
           message was received from or sent to the network."
      ::= { callActiveEntry 1 }

callActiveIndex OBJECT-TYPE

      SYNTAX      INTEGER (1..'7fffffff'h)
      MAX-ACCESS  not-accessible
      STATUS      current

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      DESCRIPTION
          "Small index variable to distinguish calls that start in
           the same hundredth of a second."
      ::= { callActiveEntry 2 }

callActivePeerAddress OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number this call is connected to. If the number is
           not available, then it will have a length of zero."
      ::= { callActiveEntry 3 }

callActivePeerSubAddress OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The subaddress this call is connected to. If the subaddress
           is undefined or not available, this will be a zero length
           string."
      ::= { callActiveEntry 4 }

callActivePeerId OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "This is the Id value of the peer table entry
           to which this call was made. If a peer table entry
           for this call does not exist or is unknown, the value
           of this object will be zero."
      ::= { callActiveEntry 5 }

callActivePeerIfIndex OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "This is the ifIndex value of the peer table entry
           to which this call was made. If a peer table entry
           for this call does not exist or is unknown, the value
           of this object will be zero."
      ::= { callActiveEntry 6 }

callActiveLogicalIfIndex OBJECT-TYPE

      SYNTAX      InterfaceIndexOrZero

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      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "This is the ifIndex value of the logical interface through
           which this call was made. For ISDN media, this would be
           the ifIndex of the B channel which was used for this call.
           If the ifIndex value is unknown, the value of this object
           will be zero."
      ::= { callActiveEntry 7 }

callActiveConnectTime OBJECT-TYPE

      SYNTAX      TimeStamp
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The value of sysUpTime when the call was connected.
           If the call is not connected, this object will have a
           value of zero."
      ::= { callActiveEntry 8 }

callActiveCallState OBJECT-TYPE

      SYNTAX      INTEGER {
          unknown(1),
          connecting(2),
          connected(3),
          active(4)
      }
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The current call state.
           unknown(1)     - The call state is unknown.
           connecting(2)  - A connection attempt (outgoing call)
                            is being made.
           connected(3)   - An incoming call is in the process
                            of validation.
           active(4)      - The call is active.
          "
      ::= { callActiveEntry 9 }

callActiveCallOrigin OBJECT-TYPE

      SYNTAX      INTEGER {
          originate(1),
          answer(2),
          callback(3)
      }
      MAX-ACCESS  read-only
      STATUS      current

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      DESCRIPTION
          "The call origin."
      ::= { callActiveEntry 10 }

callActiveChargedUnits OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number of charged units for this connection.
           For incoming calls or if charging information is
           not supplied by the switch, the value of this object
           will be zero."
      ::= { callActiveEntry 11 }

callActiveInfoType OBJECT-TYPE

      SYNTAX      INTEGER {
          other(1),                   -- e.g. for non-isdn media
          speech(2),
          unrestrictedDigital(3),     -- 64k/s data
          unrestrictedDigital56(4),   -- with 56k rate adaption
          restrictedDigital(5),
          audio31(6),                 -- 3.1 kHz audio
          audio7(7),                  -- 7 kHz audio
          video(8),
          packetSwitched(9),
          fax(10)
      }
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The information type for this call."
      ::= { callActiveEntry 12 }

callActiveTransmitPackets OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS     current
      DESCRIPTION
          "The number of packets which were transmitted for this
           call."
      ::= { callActiveEntry 13 }

callActiveTransmitBytes OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION

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          "The number of bytes which were transmitted for this
           call."
      ::= { callActiveEntry 14 }

callActiveReceivePackets OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number of packets which were received for this
           call."
      ::= { callActiveEntry 15 }

callActiveReceiveBytes OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number of bytes which were received for this call."
      ::= { callActiveEntry 16 }

– – the call history group –

callHistory OBJECT IDENTIFIER ::= { dialControlMibObjects 4 }

callHistoryTableMaxLength OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      MAX-ACCESS  read-write
      STATUS      current
      DESCRIPTION
          "The upper limit on the number of entries that the
           callHistoryTable may contain.  A value of 0
           will prevent any history from being retained. When
           this table is full, the oldest entry will be deleted
           and the new one will be created."
      ::= { callHistory 1 }

callHistoryRetainTimer OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      UNITS       "minutes"
      MAX-ACCESS  read-write
      STATUS      current
      DESCRIPTION
          "The minimum amount of time that an callHistoryEntry
           will be maintained before being deleted. A value of
           0 will prevent any history from being retained in the

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           callHistoryTable, but will neither prevent callCompletion
           traps being generated nor affect other tables."
      ::= { callHistory 2 }

– callHistoryTable – Table to store the past call information. The Destination number – and the call connect and disconnect time, the disconnection cause – are stored. These calls could be circuit switched or they could – be virtual circuits. History of each and every call is stored, – of successful calls as well as of unsuccessful and rejected calls. – An entry will be created when a call is cleared.

callHistoryTable OBJECT-TYPE

      SYNTAX      SEQUENCE OF CallHistoryEntry
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "A table containing information about specific
           calls to a specific destination."
      ::= { callHistory 3 }

callHistoryEntry OBJECT-TYPE

      SYNTAX      CallHistoryEntry
      MAX-ACCESS  not-accessible
      STATUS      current
      DESCRIPTION
          "The information regarding a single Connection."
      INDEX       { callActiveSetupTime, callActiveIndex }
      ::= { callHistoryTable 1 }

CallHistoryEntry ::=

      SEQUENCE {
          callHistoryPeerAddress               DisplayString,
          callHistoryPeerSubAddress            DisplayString,
          callHistoryPeerId                    INTEGER,
          callHistoryPeerIfIndex               INTEGER,
          callHistoryLogicalIfIndex            InterfaceIndex,
          callHistoryDisconnectCause           OCTET STRING,
          callHistoryDisconnectText            DisplayString,
          callHistoryConnectTime               TimeStamp,
          callHistoryDisconnectTime            TimeStamp,
          callHistoryCallOrigin                INTEGER,
          callHistoryChargedUnits              AbsoluteCounter32,
          callHistoryInfoType                  INTEGER,
          callHistoryTransmitPackets           AbsoluteCounter32,
          callHistoryTransmitBytes             AbsoluteCounter32,
          callHistoryReceivePackets            AbsoluteCounter32,

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          callHistoryReceiveBytes              AbsoluteCounter32
      }

callHistoryPeerAddress OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number this call was connected to. If the number is
           not available, then it will have a length of zero."
      ::= { callHistoryEntry 1 }

callHistoryPeerSubAddress OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The subaddress this call was connected to. If the subaddress
           is undefined or not available, this will be a zero length
           string."
      ::= { callHistoryEntry 2 }

callHistoryPeerId OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "This is the Id value of the peer table entry
           to which this call was made. If a peer table entry
           for this call does not exist, the value of this object
           will be zero."
      ::= { callHistoryEntry 3 }

callHistoryPeerIfIndex OBJECT-TYPE

      SYNTAX      INTEGER (0..2147483647)
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "This is the ifIndex value of the peer table entry
           to which this call was made. If a peer table entry
           for this call does not exist, the value of this object
           will be zero."
      ::= { callHistoryEntry 4 }

callHistoryLogicalIfIndex OBJECT-TYPE

      SYNTAX      InterfaceIndex
      MAX-ACCESS  read-only
      STATUS      current

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      DESCRIPTION
          "This is the ifIndex value of the logical interface through
           which this call was made. For ISDN media, this would be
           the ifIndex of the B channel which was used for this call."
      ::= { callHistoryEntry 5 }

callHistoryDisconnectCause OBJECT-TYPE

      SYNTAX      OCTET STRING (SIZE (0..4))
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The encoded network cause value associated with this call.
           The value of this object will depend on the interface type
           as well as on the protocol and protocol version being
           used on this interface. Some references for possible cause
           values are given below."
      REFERENCE
          "- Bellcore SR-NWT-001953, Generic Guidelines for
             ISDN Terminal Equipment On Basic Access Interfaces,
             chapter 5.2.5.8.
           - Bellcore SR-NWT-002343, ISDN Primary Rate Interface
             Generic Guidelines for Customer Premises Equipment,
             chapter 8.2.5.8.
           - ITU-T Q.931, Appendix I.
           - ITU-T X.25, CAUSE and DIAGNOSTIC field values.
           - German Telekom FTZ 1TR6, chapter 3.2.3.4.4.4."
      ::= { callHistoryEntry 6 }

callHistoryDisconnectText OBJECT-TYPE

      SYNTAX      DisplayString
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "ASCII text describing the reason for call termination.
           This object exists because it would be impossible for
           a management station to store all possible cause values
           for all types of interfaces. It should be used only if
           a management station is unable to decode the value of
           dialCtlPeerStatsLastDisconnectCause."
      ::= { callHistoryEntry 7 }

callHistoryConnectTime OBJECT-TYPE

      SYNTAX      TimeStamp
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION

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          "The value of sysUpTime when the call was connected."
      ::= { callHistoryEntry 8 }

callHistoryDisconnectTime OBJECT-TYPE

      SYNTAX      TimeStamp
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The value of sysUpTime when the call was disconnected."
      ::= { callHistoryEntry 9 }

callHistoryCallOrigin OBJECT-TYPE

      SYNTAX      INTEGER {
          originate(1),
          answer(2),
          callback(3)
      }
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The call origin."
      ::= { callHistoryEntry 10 }

callHistoryChargedUnits OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number of charged units for this connection.
           For incoming calls or if charging information is
           not supplied by the switch, the value of this object
           will be zero."
      ::= { callHistoryEntry 11 }

callHistoryInfoType OBJECT-TYPE

      SYNTAX      INTEGER {
          other(1),                   -- e.g. for non-isdn media
          speech(2),
          unrestrictedDigital(3),     -- 64k/s data
          unrestrictedDigital56(4),   -- with 56k rate adaption
          restrictedDigital(5),
          audio31(6),                 -- 3.1 kHz audio
          audio7(7),                  -- 7 kHz audio
          video(8),
          packetSwitched(9),
          fax(10)
      }
      MAX-ACCESS  read-only

Roeck Standards Track [Page 27] RFC 2128 Dial Control MIB March 1997

      STATUS      current
      DESCRIPTION
          "The information type for this call."
      ::= { callHistoryEntry 12 }

callHistoryTransmitPackets OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS     current
      DESCRIPTION
          "The number of packets which were transmitted while this
           call was active."
      ::= { callHistoryEntry 13 }

callHistoryTransmitBytes OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number of bytes which were transmitted while this
           call was active."
      ::= { callHistoryEntry 14 }

callHistoryReceivePackets OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number of packets which were received while this
           call was active."
      ::= { callHistoryEntry 15 }

callHistoryReceiveBytes OBJECT-TYPE

      SYNTAX      AbsoluteCounter32
      MAX-ACCESS  read-only
      STATUS      current
      DESCRIPTION
          "The number of bytes which were received while this
           call was active."
      ::= { callHistoryEntry 16 }

– Traps related to Connection management

dialControlMibTrapPrefix OBJECT IDENTIFIER ::= { dialControlMib 2 } dialControlMibTraps OBJECT IDENTIFIER ::= { dialControlMibTrapPrefix 0 }

dialCtlPeerCallInformation NOTIFICATION-TYPE

      OBJECTS {

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          callHistoryPeerId,
          callHistoryPeerIfIndex,
          callHistoryLogicalIfIndex,
          ifOperStatus,
          callHistoryPeerAddress,
          callHistoryPeerSubAddress,
          callHistoryDisconnectCause,
          callHistoryConnectTime,
          callHistoryDisconnectTime,
          callHistoryInfoType,
          callHistoryCallOrigin
      }
      STATUS      current
      DESCRIPTION
          "This trap/inform is sent to the manager whenever
           a successful call clears, or a failed call attempt
           is determined to have ultimately failed. In the
           event that call retry is active, then this is after
           all retry attempts have failed. However, only one such
           trap is sent in between successful call attempts;
           subsequent call attempts result in no trap.
           ifOperStatus will return the operational status of the
           virtual interface associated with the peer to whom
           this call was made to."
   ::= { dialControlMibTraps 1 }

dialCtlPeerCallSetup NOTIFICATION-TYPE

      OBJECTS {
          callActivePeerId,
          callActivePeerIfIndex,
          callActiveLogicalIfIndex,
          ifOperStatus,
          callActivePeerAddress,
          callActivePeerSubAddress,
          callActiveInfoType,
          callActiveCallOrigin
      }
      STATUS      current
      DESCRIPTION
          "This trap/inform is sent to the manager whenever
           a call setup message is received or sent.
           ifOperStatus will return the operational status of the
           virtual interface associated with the peer to whom
           this call was made to."
   ::= { dialControlMibTraps 2 }

– conformance information

Roeck Standards Track [Page 29] RFC 2128 Dial Control MIB March 1997

dialControlMibConformance OBJECT IDENTIFIER ::=

                              { dialControlMib 3 }

dialControlMibCompliances OBJECT IDENTIFIER ::=

                              { dialControlMibConformance 1 }

dialControlMibGroups OBJECT IDENTIFIER ::=

                              { dialControlMibConformance 2 }

– compliance statements

dialControlMibCompliance MODULE-COMPLIANCE

      STATUS      current
      DESCRIPTION
          "The compliance statement for entities which
           implement the DIAL CONTROL MIB"
      MODULE      -- this module
      MANDATORY-GROUPS
          { dialControlGroup, callActiveGroup, callHistoryGroup,
            callNotificationsGroup }
      ::= { dialControlMibCompliances 1 }

– units of conformance

dialControlGroup OBJECT-GROUP

      OBJECTS {
          dialCtlAcceptMode,
          dialCtlTrapEnable,
          dialCtlPeerCfgIfType,
          dialCtlPeerCfgLowerIf,
          dialCtlPeerCfgOriginateAddress,
          dialCtlPeerCfgAnswerAddress,
          dialCtlPeerCfgSubAddress,
          dialCtlPeerCfgClosedUserGroup,
          dialCtlPeerCfgSpeed,
          dialCtlPeerCfgInfoType,
          dialCtlPeerCfgPermission,
          dialCtlPeerCfgInactivityTimer,
          dialCtlPeerCfgMinDuration,
          dialCtlPeerCfgMaxDuration,
          dialCtlPeerCfgCarrierDelay,
          dialCtlPeerCfgCallRetries,
          dialCtlPeerCfgRetryDelay,
          dialCtlPeerCfgFailureDelay,
          dialCtlPeerCfgTrapEnable,
          dialCtlPeerCfgStatus,
          dialCtlPeerStatsConnectTime,
          dialCtlPeerStatsChargedUnits,
          dialCtlPeerStatsSuccessCalls,
          dialCtlPeerStatsFailCalls,

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          dialCtlPeerStatsAcceptCalls,
          dialCtlPeerStatsRefuseCalls,
          dialCtlPeerStatsLastDisconnectCause,
          dialCtlPeerStatsLastDisconnectText,
          dialCtlPeerStatsLastSetupTime
      }
      STATUS      current
      DESCRIPTION
          "A collection of objects providing the DIAL CONTROL
           capability."
      ::= { dialControlMibGroups 1 }

callActiveGroup OBJECT-GROUP

      OBJECTS {
          callActivePeerAddress,
          callActivePeerSubAddress,
          callActivePeerId,
          callActivePeerIfIndex,
          callActiveLogicalIfIndex,
          callActiveConnectTime,
          callActiveCallState,
          callActiveCallOrigin,
          callActiveChargedUnits,
          callActiveInfoType,
          callActiveTransmitPackets,
          callActiveTransmitBytes,
          callActiveReceivePackets,
          callActiveReceiveBytes
      }
      STATUS      current
      DESCRIPTION
          "A collection of objects providing the active call
           capability."
      ::= { dialControlMibGroups 2 }

callHistoryGroup OBJECT-GROUP

      OBJECTS {
          callHistoryTableMaxLength,
          callHistoryRetainTimer,
          callHistoryPeerAddress,
          callHistoryPeerSubAddress,
          callHistoryPeerId,
          callHistoryPeerIfIndex,
          callHistoryLogicalIfIndex,
          callHistoryDisconnectCause,
          callHistoryDisconnectText,
          callHistoryConnectTime,
          callHistoryDisconnectTime,

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          callHistoryCallOrigin,
          callHistoryChargedUnits,
          callHistoryInfoType,
          callHistoryTransmitPackets,
          callHistoryTransmitBytes,
          callHistoryReceivePackets,
          callHistoryReceiveBytes
      }
      STATUS      current
      DESCRIPTION
          "A collection of objects providing the Call History
           capability."
      ::= { dialControlMibGroups 3 }

callNotificationsGroup NOTIFICATION-GROUP

  NOTIFICATIONS { dialCtlPeerCallInformation, dialCtlPeerCallSetup }
  STATUS        current
  DESCRIPTION
          "The notifications which a Dial Control MIB entity is
           required to implement."
  ::= { dialControlMibGroups 4 }

END

4. Acknowledgments

 This document was produced by the ISDN MIB Working Group.  Special
 thanks is due to the following persons:
         Ed Alcoff
         Fred Baker
         Bibek A. Das
         Ken Grigg
         Jeffrey T. Johnson
         Glenn Kime
         Oliver Korfmacher
         Kedar Madineni
         Bill Miskovetz
         David M. Piscitello
         Lisa A. Phifer
         Randy Roberts
         Hascall H. Sharp
         Hongchi Shih
         Robert Snyder
         Bob Stewart
         Ron Stoughton
         James Watt

Roeck Standards Track [Page 32] RFC 2128 Dial Control MIB March 1997

5. References

[1] SNMPv2 Working Group, Case, J., McCloghrie, K., Rose, M., and

   S. Waldbusser, "Structure of Management Information for Version 2
   of the Simple Network Management Protocol (SNMPv2)", RFC 1902,
   January 1996.

[2] McCloghrie, K., and M. Rose, Editors, "Management Information Base

   for Network Management of TCP/IP-based internets: MIB-II", STD 17,
   RFC 1213, Hughes LAN Systems, Performance Systems International,
   March 1991.

[3] Case, J., Fedor, M., Schoffstall, M., and J. Davin, "A Simple

   Network Management Protocol (SNMP)", STD 15, RFC 1157, SNMP
   Research, Performance Systems International, MIT Lab for Computer
   Science, May 1990.

[4] SNMPv2 Working Group, 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.

[5] ITU-T Recommendation "Digital subscriber Signalling System No. 1

   (DSS 1) - ISDN user-network interface layer 3 specification for
   basic call control", Rec. Q.931(I.451), March 1993.

[6] ITU-T Recommendation "Generic procedures for the control of ISDN

   supplementary services ISDN user-network interface layer 3
   specification", Rec. Q.932(I.452).

[7] ITU-T Recommendation "Digital subscriber Signalling System No. 1

   (DSS 1) - Signalling specification for frame-mode basic call
   control", Rec. Q.933.

[8] McCloghrie, K. and F. Kastenholz, "Evolution of the Interfaces

   Group of MIB-II", RFC 1573, Hughes LAN Systems, FTP Software,
   January 1994.

6. Security Considerations

 Information in this MIB may be used by upper protocol layers for
 security purpose.
 The implementor should be aware that supporting generic peers as
 described in section 3.4 may cause a security hole.  The user would
 not know where a call is from, which could potentially allow
 unauthorized access if there is no other authentication scheme, e.g.
 PPP authentication, available.

Roeck Standards Track [Page 33] RFC 2128 Dial Control MIB March 1997

7. Author's Address

 Guenter Roeck
 cisco Systems
 170 West Tasman Drive
 San Jose, CA 95134
 U.S.A.
 Phone: +1 408 527 3143
 EMail: groeck@cisco.com

Roeck Standards Track [Page 34]

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