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+Network Working Group G. Roeck, Editor
+Request for Comments: 2127 cisco Systems
+Category: Standards Track March 1997
+
+
+ ISDN 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 defines a minimal set of managed objects for SNMP-
+ based management of ISDN terminal interfaces. ISDN interfaces are
+ supported on a variety of equipment (for data and voice) including
+ terminal adapters, bridges, hosts, and routers.
+
+ 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.
+
+ The current version of this document reflects changes made during the
+ last call period and the IESG review.
+
+Table of Contents
+
+ 1 The SNMPv2 Network Management Framework ...................... 2
+ 2 Object Definitions ........................................... 2
+ 3 Overview ..................................................... 3
+ 3.1 Structure of the MIB ....................................... 3
+ 3.1.1 General Description ...................................... 3
+ 3.2 Relationship to the Interfaces MIB ......................... 4
+ 3.2.1 Layering Model ........................................... 4
+ 3.2.2 ifTestTable .............................................. 8
+ 3.2.3 ifRcvAddressTable ........................................ 8
+ 3.2.4 ifEntry .................................................. 8
+
+
+
+Roeck Standards Track [Page 1]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ 3.2.4.1 ifEntry for a Basic Rate hardware interface ............ 8
+ 3.2.4.2 ifEntry for a B channel ................................ 9
+ 3.2.4.3 ifEntry for LAPD (D channel Data Link Layer) ........... 10
+ 3.2.4.4 ifEntry for a signaling channel ........................ 12
+ 3.3 Relationship to other MIBs ................................. 14
+ 3.3.1 Relationship to the DS1/E1 MIB ........................... 14
+ 3.3.2 Relationship to the DS0 and DS0Bundle MIBs ............... 14
+ 3.3.3 Relationship to the Dial Control MIB ..................... 14
+ 3.4 ISDN interface specific information and implementation hints
+ ........................................................... 14
+ 3.4.1 ISDN leased lines ........................................ 14
+ 3.4.2 Hyperchannels ............................................ 15
+ 3.4.3 D channel backup and NFAS trunks ......................... 16
+ 3.4.4 X.25 based packet-mode service in B and D channels ....... 16
+ 3.4.5 SPID handling ............................................ 17
+ 3.4.6 Closed User Groups ....................................... 17
+ 3.4.7 Provision of point-to-point line topology ................ 18
+ 3.4.8 Speech and audio bearer capability information elements .. 18
+ 3.4.9 Attaching incoming calls to router ports ................. 19
+ 3.4.10 Usage of isdnMibDirectoryGroup and isdnDirectoryTable ... 20
+ 4 Definitions .................................................. 21
+ 5 Acknowledgments .............................................. 47
+ 6 References ................................................... 47
+ 7 Security Considerations ...................................... 49
+ 8 Author's Address ............................................. 49
+
+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.
+
+2. 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)
+
+
+
+Roeck Standards Track [Page 2]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ 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.
+
+3. Overview
+
+3.1. Structure of the MIB
+
+ For managing ISDN interfaces, the following information is necessary:
+
+ o Information for managing physical interfaces. In case of ISDN
+ primary rate, this are usually T1 or E1 lines, being managed in
+ the DS1/E1 MIB [12]. For Basic Rate lines, physical interfaces
+ are managed by this MIB.
+
+ o Information for managing B channels.
+
+ o Information for managing signaling channels.
+
+ o Optionally, information for managing Terminal Endpoints (TE).
+ A Terminal Endpoint is a link layer connection to a switch.
+
+ o Optionally, information for managing a list of directory numbers.
+
+ In order to manage connections over ISDN lines, the management of
+ peer information and call history information is required as well.
+ This information is defined in the Dial Control MIB [15].
+
+ The purpose for splitting the required information in two MIBs is to
+ be able to use parts of this information for non-ISDN interfaces as
+ well. In particular, the Dial Control MIB might also be used for
+ other types of interfaces, e.g. modems or X.25 virtual connections.
+
+ Within this document, information has been structured into five
+ groups, which are described in the following chapters.
+
+3.1.1. General Description
+
+ This MIB controls all aspects of ISDN interfaces. It consists of
+ five groups.
+
+ o The isdnMibBasicRateGroup is used to provide information
+ regarding physical Basic Rate interfaces.
+
+ o The isdnMibBearerGroup is used to control B (bearer) channels.
+
+
+
+Roeck Standards Track [Page 3]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ It supports configuration parameters as well as statistical
+ information related to B channels.
+
+ o The isdnMibSignalingGroup is used to control D (delta) channels.
+ There are three tables in this group. The isdnSignalingTable and
+ isdnSignalingStatsTable support ISDN Network Layer configuration
+ and statistics. The isdnLapdTable supports ISDN Data Link Layer
+ (LAPD) configuration and statistics.
+
+ o The optional isdnMibEndpointGroup can be used to specify
+ Terminal Endpoints. It is required only if there are non-ISDN
+ endpoints defined for a given D channel, or if additional
+ information like Terminal Endpoint Identifier (TEI) values or
+ Service Profile IDentifiers (SPID) is required to identify a
+ given ISDN user.
+
+ o The optional isdnMibDirectoryGroup can be used to specify a
+ list of directory numbers for each signaling channel. It is
+ required only if the directory numbers to be accepted differ
+ from the isdnSignalingCallingAddress as specified in the
+ isdnSignalingTable.
+
+3.2. Relationship to the Interfaces MIB
+
+ This section clarifies the relationship of this MIB to the Interfaces
+ MIB [11]. 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.
+
+3.2.1. Layering Model
+
+ An ISDN interface usually consists of a D channel and a number of B
+ channels, all of which are layered on top of a physical interface.
+
+ Furthermore, there are multiple interface layers for each D channel.
+ There are Data Link Layer (LAPD) as well as Network Layer entities.
+
+ This is accomplished in this MIB by creating a logical interface
+ (ifEntry) for each of the D channel entities and a logical interface
+ (ifEntry) for each of the B channels. These are then correlated to
+ each other and to the physical interface using the ifStack table of
+ the Interfaces MIB [11].
+
+
+
+
+
+
+
+
+Roeck Standards Track [Page 4]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ The basic model, therefore, looks something like this:
+
+ | |
+ +--+ +--+
+ | D ch. |
+ |Layer 3|
+ +--+ +--+
+ | | | | | | <== interface to upper
+ +--+ +--+ +--+ +--+ +--+ +--+ layers, to be provided
+ | D ch. | | B | | B | by ifStack table
+ |Layer 2| |channel| .... |channel|
+ +--+ +--+ +--+ +--+ +--+ +--+
+ | | | | | | <== attachment to physical
+ +--+ +--------+ +------------+ +----+ interfaces, to be provided
+ | physical interface | by ifStack table
+ | (S/T, U or T1/E1) |
+ +-----------------------------------+
+ Mapping of B/D channels to physical interfaces
+
+ Each D channel can support multiple Terminal Endpoints. Terminal
+ Endpoints can either be one or multiple ISDN signaling channels, or
+ channels supporting X.25 based packet mode services.
+
+ To accomplish this, there can be multiple Network Layer entities on
+ top of each ISDN Data Link Layer (LAPD) interface. The detailed
+ model therefore looks something like this, including interface types
+ as examples:
+
+ +------+ +----+ +----+
+ |x25ple| |isdn| |isdn| Terminal Endpoints (X.25 or ISDN)
+ +--+---+ +-+--+ +-+--+
+ | | |
+ | +------+ | | | <== Interface to upper layers,
+ | | +------------+ | | to be provided by ifStack
+ | | | | | table
+ ++-+-++ +-+-+ +-+-+
+ |lapd | D channel |ds0| |ds0| B channels
+ +--+--+ Data Link Layer +-+-+ +-+-+
+ | | |
+ +--+----------------------+------+--------------------+
+ | ds1 or isdns/isdnu |
+ +-----------------------------------------------------+
+
+ Detailed interface mapping
+
+ IfEntries are maintained for each D channel Network Layer entity
+ (Terminal Endpoint), for LAPD and for each B channel.
+
+
+
+
+Roeck Standards Track [Page 5]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ The ifType for a Terminal Endpoint can be isdn(63) for ISDN signaling
+ channels or x25ple(40) for X.25 based packet mode services. The
+ ifType for D channel Data Link Layer (LAPD) interfaces is lapd(77).
+ The ifType for B channels is ds0(81). The ifType for physical
+ interfaces is the matching IANA ifType, usually ds1(18) for Primary
+ Rate interfaces or isdns(75)/isdnu(76) for Basic Rate interfaces.
+
+ The ifStackTable is used to map B channels and LAPD interfaces to
+ physical interfaces and to map D channel Network Layer interfaces
+ (Terminal Endpoints) to LAPD.
+
+ In the example given above, the assignment of index values could for
+ example be as follows:
+
+ifIndex ifType ISDN MIB tables Description
+ indexed by ifIndex
+
+ 1 isdns(75) isdnBasicRateTable Basic Rate physical interface
+ 2 lapd(77) isdnLapdTable LAPD interface
+ 3 x25ple(40) isdnEndpointTable X.25 Packet Layer
+ 4 isdn(63) isdnSignalingTable ISDN signaling channel #1
+ isdnEndpointTable
+ 5 isdn(63) isdnSignalingTable ISDN signaling channel #2
+ isdnEndpointTable
+ 6 ds0(81) isdnBearerTable B channel #1
+ 7 ds0(81) isdnBearerTable B channel #2
+ 8 ppp(23) peer entry #1 (see below)
+ 9 ppp(23) peer entry #2 (see below)
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Roeck Standards Track [Page 6]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ The corresponding ifStack table entries would then be:
+
+ ifStackTable Entries
+
+ HigherLayer LowerLayer
+ 0 3
+ 0 4
+ 0 5
+ 0 8
+ 0 9
+ 1 0
+ 2 1
+ 3 2
+ 4 2
+ 5 2
+ 6 1
+ 7 1
+ 8 6
+ 9 7
+
+ Mapping of B channels to upper interface layers is usually done using
+ the Dial Control MIB. For example, mapping on top of B channels might
+ look as follows:
+
++-------------------------------------------------------+
+| 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
+
+
+
+
+
+
+Roeck Standards Track [Page 7]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ In this model, ifEntries are maintained for each peer. Each peer is
+ required to have an associated ifEntry. This interface can be of any
+ kind, e.g. PPP or LAPB.
+
+ The Dial Control MIB can be used for all types of demand-access
+ interfaces, e.g., ISDN, modems or X.25 virtual connections.
+
+3.2.2. ifTestTable
+
+ The ifTestTable is not supported by this MIB.
+
+3.2.3. ifRcvAddressTable
+
+ The ifRcvAddressTable is not supported by this MIB.
+
+3.2.4. ifEntry
+
+3.2.4.1. ifEntry for a Basic Rate hardware interface
+
+ The ifGeneralGroup is supported for Basic Rate hardware interfaces.
+
+ ifTable Comments
+ ============== ===========================================
+ ifIndex Each ISDN Basic Rate hardware interface is
+ represented by an ifEntry.
+
+ ifDescr Textual port description.
+
+ ifType The IANA value of isdns(75) or isdnu(76),
+ whichever is appropriate.
+
+ ifSpeed The overall bandwidth of this interface.
+
+ ifPhysAddress Return an empty string.
+
+ ifAdminStatus The administrative status of the ISDN interface.
+
+ ifOperStatus The current operational status of this interface.
+ The operational status is dormant(5) if
+ the interface is in standby mode, i.e. connected
+ to the network, but without call activity.
+ The operational status is down(2) if the hardware
+ has detected that there is no layer 1 connection
+ to the switch.
+ For other values, refer to the Interfaces MIB.
+
+ ifLastChange Refer to the Interfaces MIB.
+
+
+
+
+Roeck Standards Track [Page 8]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ ifLinkUpDownTrapEnable
+ Refer to the Interfaces MIB.
+
+ ifConnectorPresent
+ Refer to the Interfaces MIB.
+
+ ifHighSpeed Return zero.
+
+ ifName Refer to the Interfaces MIB.
+
+3.2.4.2. ifEntry for a B channel
+
+ The ifEntry for a B channel supports the ifGeneralGroup of the
+ Interfaces MIB.
+
+ ifTable Comments
+ ============== ===========================================
+ ifIndex Each ISDN B channel is represented by an ifEntry.
+
+ ifDescr Textual port description.
+
+ ifType The IANA value of ds0(81).
+
+ ifSpeed The bandwidth of this B channel.
+ Usually, this is the value of 56000 or 64000.
+
+ ifPhysAddress Return an empty string.
+
+ ifAdminStatus The administrative status of this interface.
+
+ ifOperStatus The current operational status of this interface.
+ Note that dormant(5) is explicitly being used
+ as defined in the Interfaces MIB.
+ For other values, refer to the Interfaces MIB.
+
+ ifLastChange Refer to the Interfaces MIB.
+
+ ifLinkUpDownTrapEnable
+ Refer to the Interfaces MIB.
+
+ ifConnectorPresent
+ Refer to the Interfaces MIB.
+
+ ifHighSpeed Return zero.
+
+ ifName Refer to the Interfaces MIB.
+
+
+
+
+
+Roeck Standards Track [Page 9]
+
+RFC 2127 ISDN MIB March 1997
+
+
+3.2.4.3. ifEntry for LAPD (D channel Data Link Layer)
+
+ The ifEntry for LAPD (D channel Data Link Layer) supports the
+ ifGeneralGroup and the ifPacketGroup of the Interfaces MIB.
+
+ ifTable Comments
+ ============== ===========================================
+ ifIndex Each ISDN D channel Data Link layer is represented
+ by an ifEntry.
+
+ ifDescr Textual port description.
+
+ ifType The IANA value of lapd(77).
+
+ ifSpeed The bandwidth of this interface. Usually, this is
+ the value of 16000 for basic rate interfaces or
+ 64000 for primary rate interfaces.
+
+ ifPhysAddress Return an empty string.
+
+ ifAdminStatus The administrative status of this interface.
+
+ ifOperStatus The current operational status of the ISDN
+ LAPD interface. The operational status is
+ dormant(5) if the interface is in standby mode
+ (see Q.931 [8], Annex F, D channel backup
+ procedures).
+ For other values, refer to the Interfaces MIB.
+
+ ifLastChange Refer to the Interfaces MIB.
+
+ ifLinkUpDownTrapEnable
+ Refer to the Interfaces MIB.
+
+ ifConnectorPresent
+ Refer to the Interfaces MIB.
+
+ ifHighSpeed Return zero.
+
+ ifName Refer to the Interfaces MIB.
+
+ ifMtu The size of the largest frame which can be
+ sent/received on this interface,
+ specified in octets. Usually, this is the
+ default value of 260 as specified in Q.921
+ [6], chapter 5.9.3.
+
+
+
+
+
+Roeck Standards Track [Page 10]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ ifInOctets The total number of octets received on this
+ interface.
+
+ ifInUcastPkts The number of frames received on this interface
+ whose address is not TEI=127.
+
+ ifInNUcastPkts Deprecated. Return the number of frames
+ received on this interface with TEI=127.
+
+ ifInMulticastPkts Return zero.
+
+ ifInBroadcastPkts Return the number of frames received
+ on this interface with TEI=127.
+
+ ifInDiscards The total number of received frames which have
+ been discarded.
+ The possible reasons are: buffer shortage.
+
+ ifInErrors The number of inbound frames that contained
+ errors preventing them from being deliverable
+ to LAPD.
+
+ ifInUnknownProtos The number of frames with known TEI, but unknown
+ SAPI (Service Access Point Identifier,
+ see Q.921 [6], chapter 3.3.3).
+
+ ifOutOctets The total number of octets transmitted on this
+ interface.
+
+ ifOutUcastPkts The number of frames transmitted on this
+ interface whose address is not TEI=127.
+
+ ifOutNUcastPkts Deprecated. Return the number of frames
+ transmitted on this interface with TEI=127.
+
+ ifOutMulticastPkts
+ Return zero.
+
+ ifOutBroadcastPkts
+ Return the number of frames transmitted
+ on this interface with TEI=127.
+
+ ifOutDiscards The total number of outbound frames which
+ were discarded. Possible reasons are:
+ buffer shortage.
+
+ ifOutErrors The number of frames which could not be
+ transmitted due to errors.
+
+
+
+Roeck Standards Track [Page 11]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ ifOutQlen Deprecated. Return zero.
+
+ ifSpecific Deprecated. Return {0 0}.
+
+3.2.4.4. ifEntry for a signaling channel
+
+ The ifEntry for a signaling channel supports the ifGeneralGroup and
+ the ifPacketGroup of the Interfaces MIB.
+
+ ifTable Comments
+ ============== ===========================================
+ ifIndex Each ISDN signaling channel is represented by
+ an ifEntry.
+
+ ifDescr Textual port description.
+
+ ifType The IANA value of isdn(63).
+
+ ifSpeed The bandwidth of this signaling channel. Usually,
+ this is the same value as for LAPD, i.e. 16000
+ for basic rate interfaces or 64000 for primary rate
+ interfaces.
+
+ ifPhysAddress The ISDN address assigned to this signaling channel.
+ This is a copy of isdnSignalingCallingAddress.
+
+ ifAdminStatus The administrative status of the signaling channel.
+
+ ifOperStatus The current operational status of this signaling
+ channel. The operational status is dormant(5) if
+ the signaling channel is currently not activated.
+ For other values, refer to the Interfaces MIB.
+
+ ifLastChange Refer to the Interfaces MIB.
+
+ ifLinkUpDownTrapEnable
+ Refer to the Interfaces MIB.
+
+ ifConnectorPresent
+ Refer to the Interfaces MIB.
+
+ ifHighSpeed Return zero.
+
+ ifName Refer to the Interfaces MIB.
+
+
+
+
+
+
+
+Roeck Standards Track [Page 12]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ ifMtu The size of the largest frame which can be
+ sent/received on this signaling channel,
+ specified in octets. Usually, this is the
+ default value of 260 as specified in Q.921
+ [6], chapter 5.9.3.
+
+ ifInOctets The total number of octets received on this
+ signaling channel.
+
+ ifInUcastPkts The number of frames received which are targeted
+ to this channel.
+
+ ifInNUcastPkts Deprecated. Return the number of frames
+ received on this signaling channel with TEI=127.
+
+ ifInMulticastPkts Return zero.
+
+ ifInBroadcastPkts Return the number of frames received
+ on this signaling channel with TEI=127.
+
+ ifInDiscards The total number of received frames which have been
+ discarded.
+ The possible reasons are: buffer shortage.
+
+ ifInErrors The number of inbound frames that contained
+ errors preventing them from being deliverable
+ to the signaling channel.
+
+ ifInUnknownProtos Return zero.
+
+ ifOutOctets The total number of octets transmitted on this
+ signaling channel.
+
+ ifOutUcastPkts The number of frames transmitted on this
+ signaling channel whose address is not TEI=127.
+
+ ifOutNUcastPkts Deprecated. Return the number of frames
+ transmitted on this signaling channel with TEI=127.
+
+ ifOutMulticastPkts
+ Return zero.
+
+ ifOutBroadcastPkts
+ Return the number of frames transmitted
+ on this signaling channel with TEI=127.
+
+
+
+
+
+
+Roeck Standards Track [Page 13]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ ifOutDiscards The total number of outbound frames which
+ were discarded. Possible reasons are:
+ buffer shortage.
+
+ ifOutErrors The number of frames which could not be
+ transmitted due to errors.
+
+ ifOutQlen Deprecated. Return zero.
+
+ ifSpecific Deprecated. Return {0 0}.
+
+3.3. Relationship to other MIBs
+
+3.3.1. Relationship to the DS1/E1 MIB
+
+ Implementation of the DS1/E1 MIB [12] is not required for supporting
+ this MIB. It is however recommended to implement the DS1/E1 MIB on
+ entities supporting Primary Rate interfaces.
+
+3.3.2. Relationship to the DS0 and DS0Bundle MIBs
+
+ Implementation of the DS0 MIB [13] is optional.
+
+ Implementation of the DS0Bundle MIB [13] may be required only if
+ hyperchannels are to be supported, depending on the multiplexing
+ scheme used in a given implementation. See chapter 3.4.2 for details
+ on how to implement hyperchannels.
+
+3.3.3. Relationship to the Dial Control MIB
+
+ Implementation of the Dial Control MIB [15] is required.
+
+3.4. ISDN interface specific information and implementation hints
+
+3.4.1. ISDN leased lines
+
+ ISDN leased lines can be specified on a per-B-channel basis. To do
+ so, the value of isdnBearerChannelType has to be set to leased(2).
+ There is no signaling protocol support for leased line B channels,
+ since there is no signaling protocol action for these kinds of
+ interfaces.
+
+
+
+
+
+
+
+
+
+
+Roeck Standards Track [Page 14]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ If there is no signaling support available for an ISDN interface,
+ this must be specified in the appropriate interface specific table.
+ For Basic Rate interfaces, isdnBasicRateSignalMode of
+ isdnBasicRateTable must be set to inactive(2). For Primary Rate
+ interfaces, dsx1SignalMode of dsx1ConfigTable in DS1/E1 MIB [12] must
+ be set to none(1). There are no isdnLapdTable or isdnSignalingTable
+ entries for such interfaces.
+
+ Depending on the leased line type and the service provider, the D
+ channel can be used for data transfer. If this is the case the D
+ channel interface type is ds0(81) instead of lapd(77) and its usage
+ is identical to B channel usage if there is no signaling channel
+ available.
+
+ For a Primary Rate interface which is entirely used as a leased line,
+ there is no ISDN specific information available or required. Such
+ leased lines can entirely be handled by the DS1/E1 MIB.
+
+3.4.2. Hyperchannels
+
+ The active switch protocol defines if hyperchannels are supported,
+ and the actual support is implementation dependent. Hyperchannel
+ connections will be requested by the interface user at call setup
+ time, e.g. by the peer connection handling procedures.
+
+ In the ISDN MIB, the isdnBearerMultirate object of isdnBearerTable
+ can be used to check if hyperchannels are being used for an active
+ call.
+
+ If hyperchannels are being used, multiplexing between the
+ encapsulation layer and the B channels is required, since there is
+ one encapsulation layer interface connected to several B channel
+ interfaces. This can be accomplished in two ways.
+
+ o The DS0Bundle MIB [13] can be used to provide the multiplexing.
+ See the DS0Bundle MIB document for details.
+
+ o The ifStackTable can be used to provide the multiplexing. In
+ this case, there are several ifStackTable entries with the same
+ value of HigherLayer, and different values of LowerLayer.
+
+ It is up to the implementor to decide which multiplexing scheme to
+ use.
+
+ Each hyperchannel call is treated as one call in the
+ isdnSignalingStatsTable, independent of the number of B channels
+ involved.
+
+
+
+
+Roeck Standards Track [Page 15]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ For a hyperchannel call, all objects in the isdnBearerTable entries
+ related to this call (i.e., all isdnBearerTable entries associated to
+ B channels used by the hyperchannel) have identical values. The
+ related objects in the isdnBearerTable are:
+
+
+ isdnBearerPeerAddress
+ isdnBearerPeerSubAddress
+ isdnBearerCallOrigin
+ isdnBearerInfoType
+ isdnBearerMultirate
+ isdnBearerCallSetupTime
+ isdnBearerCallConnectTime
+ isdnBearerChargedUnits
+
+3.4.3. D channel backup and NFAS trunks
+
+ D channel backup is defined in Q.931 [8], Annex F. It describes Non-
+ Associated signaling and its use and functionality is basically
+ identical to Non Facility Associated Signaling (NFAS) trunks.
+
+ Non Facility Accociated Signaling (NFAS) basically means that a D
+ channel on a PRI interface is used to manage calls on other PRI
+ trunks. This is required in North America for H11 channels, since
+ all 24 time slots are being used for B channels.
+
+ According to Q.931, Annex F, the D channel backup feature can be
+ provided on a subscription basis and is network dependent. The D
+ channel backup procedure is described in detail in Q.931.
+
+ For D channel backup, the controlling isdnSignalingTable entry is
+ layered on top of all attached LAPD interfaces. This layering is
+ done using the ifStack table. There is only one active LAPD
+ interface, however. Inactive LAPD interfaces have an ifOperStatus of
+ dormant(5).
+
+ NFAS trunks are also handled using the ifStack table. In this case, a
+ signaling channel is layered on top of a LAPD interface as well as on
+ top of all physical interfaces which are controlled by the signaling
+ channel, but do not supply a D channel.
+
+3.4.4. X.25 based packet-mode service in B and D channels
+
+ X.25 based packet mode service over B channels can be handled using
+ the Dial Control MIB by creating an appropriate peer entry. The peer
+ entry ifType can then be x25(5), thus providing access to X.25
+ service.
+
+
+
+
+Roeck Standards Track [Page 16]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ X.25 based packet mode service over D channels can be handled by
+ creating an ifEndpointTable entry with an isdnEndpointIfType of
+ x25ple(40). The upper protocol layers can then be attached to this
+ interface using the ifStack table.
+
+3.4.5. SPID handling
+
+ Service Profile IDentifiers (SPIDs) are defined for BRI interfaces
+ only, and being used in North America. SPIDs are required for DMS-
+ 100, NI-1 and NI-2, and are optional for 5ESS. A switch can define
+ up to 8 SPIDs per BRI.
+
+ Each Terminal Endpoint has a SPID assigned. It is normally built
+ from the party number (calling address for outgoing calls) with a
+ number of digits prepended and appended. Since each network appears
+ to be different, both the calling address and the SPID have to be
+ stored.
+
+ The SPID identifies the particular services that have been
+ provisioned for a terminal. If there are two B channels on a BRI,
+ there can be two SPIDs, one for each of the two B channels. There
+ can also be a single SPID, providing access to both B channels.
+
+ The SPID gets registered with the switch after link establishment.
+ There is one data link for each SPID. As part of terminal
+ registration, an EID (Endpoint IDentifier) is defined by the switch.
+ On incoming calls, the switch may provide the EID, a called party
+ number, or both, depending on the ISDN code implemented in the
+ switch.
+
+ The EID has two bytes: USID (User Service IDentifier) and TID
+ (Terminal IDentifier). These are later used by some of the software
+ versions running on the switch side (e.g. compliant with NI-1, 5ESS
+ custom) to broadcast SETUP messages with these included, so the
+ correct endpoint would accept the call. Other switch software
+ versions identify the endpoint with the Called Party Number.
+
+ In the ISDN MIB, the SPID can be entered using the isdnEndpointSpid
+ object of isdnEndpointTable. The isdnSignalingCallingAddress,
+ already being used to specify the calling number, cannot be used to
+ record the SPID since the values of the SPID and the Calling Address
+ may differ and both may be required to be present.
+
+3.4.6. Closed User Groups
+
+ Closed User Groups (CUG), as defined in I.255.1 [14], are supported
+ for circuit mode calls by ETSI (ETS 300 138) and 1TR6. In these
+ networks, an ISDN address can have one or more Closed User Groups
+
+
+
+Roeck Standards Track [Page 17]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ assigned. If there is more than one Closed User Group assigned to a
+ given address, one of those is the preferred Closed User Group. For
+ such addresses, only calls from assigned Closed User Groups are
+ accepted by the network.
+
+ Thus, Closed User Groups are a parameter for peer entries and are
+ defined in the Dial Control MIB. A peer entry attached to a Closed
+ User Group has to point to an ISDN interface which is attached to the
+ Closed User Group in question.
+
+3.4.7. Provision of point-to-point line topology
+
+ In the ISDN standards, there are two different meanings for the term
+ "point-to-point".
+
+ In ISDN standards, the term point-to-point are usually used for data
+ link connections, i.e. layer 2 connections, where each layer 2
+ connection from the TE to the network is a single point-to-point
+ connection. Multiple connections of this kind may exist on one
+ physical (layer 1) connection, however, and in case of Basic Rate
+ interfaces there may be several TE's connected to one physical line
+ to the network.
+
+ The second meaning of "point-to-point" refers to the line topology,
+ i.e. to layer 1 connections. For Primary Rate interfaces, the line
+ topology is always point-to-point. For Basic Rate interfaces, layer
+ 1 point-to- point connections do exist in several countries, usually
+ being used for connecting PBX systems to the network.
+
+ The second meaning (layer 1 connections) is what will be referred to
+ as "point-to-point" connection throughout this document.
+
+ For Basic Rate interfaces, the isdnBasicRateTable object
+ isdnBasicRateLineTopology can be used to select the line topology.
+
+3.4.8. Speech and audio bearer capability information elements
+
+ The objects speech(2), audio31(6) and audio7(7), as being used in
+ isdnBearerInfoType, refer to the Speech, 3.1 kHz Audio and old 7 kHz
+ Audio (now Multi-use) bearer capabilities for ISDN, as defined in
+ Q.931 [8], chapter 4.5.5, octet 3 of bearer capability information
+ element.
+
+ These capabilities are signaling artifices that allow networks to do
+ certain things with the call. It is up to the network to decide what
+ to do.
+
+
+
+
+
+Roeck Standards Track [Page 18]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ The Speech Bearer Capability means that speech is being carried over
+ the channel, as in two people talking. This would be POTS-type
+ speech. The network may compress this, encrypt it or whatever it
+ wants with it as long as it delivers POTS quality speech to the other
+ end. In other words, a modem is not guaranteed to work over this
+ connection.
+
+ The 3.1 kHz Audio capability indicates that the network carries the
+ 3.1 kHz bandwidth across the network. This would (theoretically)
+ allow modem signals to be carried across the network. In the US, the
+ network automatically enters a capability of 3.1 kHz Audio on calls
+ coming into the ISDN from a POTS network. This capability restricts
+ the network from interfering with the data channel in a way that
+ would corrupt the 3.1 kHz VoiceBand data.
+
+ 7 kHz Audio was meant to signal the use of a higher quality audio
+ connection (e.g., music from radio). It was changed to Multi-Use
+ capability to allow it to be used for video-conferencing with fall
+ back to audio.
+
+ In some cases, the Speech or 3.1 kHz Bearer Capability provides a 56
+ kbit/s data path through the network. Therefore, some people are
+ setting up calls with the Speech or 3.1 kHz BC and transmitting 56
+ kbit/s data over the connection. This is usually to take advantage
+ of favorable tariffs for Speech as opposed to Data.
+
+ On the incoming side, the equipment is usually configured to ignore
+ the Bearer Capability and either answer all Speech calls as 56 kbit/s
+ data or to use one Directory Number for real speech and another for
+ data.
+
+3.4.9. Attaching incoming calls to router ports
+
+ In ISDN, there are several ways to identify an incoming call and to
+ attach a router port to this call.
+
+ o The call can be identified and attached to a router port using
+ the ISDN Calling Address, that is, the peer ISDN address. Since
+ the peer address is defined in a Dial Control MIB configuration
+ entry for this peer, this would be the most natural way to
+ attach an incoming call to a router port.
+
+ In this configuration, only a single isdnSignalingTable entry is
+ required for each physical ISDN interface. Unfortunately, the
+ ISDN Calling Address is not available in all countries and/or
+ switch protocols. Therefore, other means for attaching incoming
+ calls to router ports must be provided.
+
+
+
+
+Roeck Standards Track [Page 19]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ o The call can also be identified and attached to a router port
+ using the ISDN Called Address. In this case, a distinct ISDN
+ address or subaddress must be specified for each of the router
+ ports. This can be accomplished in the ISDN MIB by creating a
+ isdnSignalingTable entry for each of the router ports, and by
+ connecting Dial Control MIB peer entries to the thereby created
+ interface using the dialCtlPeerCfgLowerIf object of
+ dialCtlPeerCfgTable.
+
+ If this type of router port identification is used in an
+ implementation, it is up to the implementor to decide if there
+ should be distinct TEI values assigned for each of the
+ isdnSignalingTable entries. For this reason, the
+ isdnEndpointTable permits specifying the same TEI value in
+ multiple entries. It is recommended to use dynamic TEI
+ assignment whenever possible.
+
+ The implementor should be aware that this type of configuration
+ requires a lot of configuration work for the customer, since an
+ entry in isdnSignalingTable must be created for each of the
+ router ports.
+
+ o Incoming calls can also be identified and attached to router
+ ports using a higher layer functionality, such as PPP
+ authentication. Defining this functionality is outside the
+ scope of this document.
+
+3.4.10. Usage of isdnMibDirectoryGroup and isdnDirectoryTable
+
+ In some switch protocol or PBX implementations, the Called Number
+ Information Element on incoming calls can differ from the Calling
+ Number on outgoing calls. Sometimes, the Called Number can be
+ different for incoming Local Calls, Long Distance Calls and
+ International Calls. For Hunt Groups, the Called Number can be any
+ of the numbers in the Hunt Group.
+
+ The isdnDirectoryTable can be used to specify all these numbers.
+
+ Entries in the isdnDirectoryTable are always connected to specific
+ isdnSignalingTable entries. No ifEntry is created for
+ isdnDirectoryTable entries. Therefore, the isdnDirectoryTable can
+ not be used to attach incoming calls to router ports. For router
+ port identification, isdnSignalingTable entries should be created
+ instead.
+
+
+
+
+
+
+
+Roeck Standards Track [Page 20]
+
+RFC 2127 ISDN MIB March 1997
+
+
+4. Definitions
+
+ISDN-MIB DEFINITIONS ::= BEGIN
+
+IMPORTS
+ MODULE-IDENTITY,
+ NOTIFICATION-TYPE,
+ OBJECT-TYPE,
+ Counter32,
+ Gauge32,
+ Integer32
+ FROM SNMPv2-SMI
+ DisplayString,
+ TruthValue,
+ TimeStamp,
+ RowStatus,
+ TestAndIncr,
+ TEXTUAL-CONVENTION
+ FROM SNMPv2-TC
+ MODULE-COMPLIANCE,
+ OBJECT-GROUP,
+ NOTIFICATION-GROUP
+ FROM SNMPv2-CONF
+ ifIndex,
+ InterfaceIndex
+ FROM IF-MIB
+ IANAifType
+ FROM IANAifType-MIB
+ transmission
+ FROM RFC1213-MIB;
+
+isdnMib MODULE-IDENTITY
+ LAST-UPDATED "9609231642Z" -- Sep 23, 1996
+ ORGANIZATION "IETF ISDN MIB 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 the
+ management of ISDN interfaces."
+ ::= { transmission 20 }
+
+-- The ISDN hardware interface (BRI or PRI) is represented
+
+
+
+Roeck Standards Track [Page 21]
+
+RFC 2127 ISDN MIB March 1997
+
+
+-- by a media specific ifEntry.
+--
+-- For basic rate lines, the media specifics for the physical interface
+-- is defined in the physical interface group of the ISDN MIB.
+-- The ifType for physical basic rate interfaces is isdns(75)
+-- or isdnu(76), whichever is appropriate.
+--
+-- For primary rate, the media specifics are defined in the Trunk
+-- MIB and the ifType has a value of ds1(18).
+
+-- Each signaling channel is represented by an entry
+-- in the isdnSignalingTable.
+-- The signaling channel has an ifType value of isdn(63).
+-- Each B channel is also represented as an entry
+-- in the ifTable. The B channels have an ifType value
+-- of ds0(81).
+-- This model is used while defining objects and tables
+-- for management.
+-- The ISDN MIB allows sub-layers. For example, the data transfer
+-- over a B channel may take place with PPP encapsulation. While the
+-- ISDN MIB describes the D and B channels, a media specific MIB
+-- for PPP can be used on a layered basis. This is as per
+-- the interfaces MIB.
+
+-- Textual conventions
+
+IsdnSignalingProtocol ::= TEXTUAL-CONVENTION
+ STATUS current
+ DESCRIPTION
+ "This data type is used as the syntax of the
+ isdnSignalingProtocol object in the
+ definition of ISDN-MIB's isdnSignalingTable.
+
+ The definition of this textual convention with the
+ addition of newly assigned values is published
+ periodically by the IANA, in either the Assigned
+ Numbers RFC, or some derivative of it specific to
+ Internet Network Management number assignments. (The
+ latest arrangements can be obtained by contacting the
+ IANA.)
+
+ Requests for new values should be made to IANA via
+ email (iana@iana.org)."
+ SYNTAX INTEGER {
+ other(1), -- none of the following
+ dss1(2), -- ITU DSS1 (formerly CCITT) Q.931
+ etsi(3), -- Europe / ETSI ETS300-102
+ -- plus supplementary services
+
+
+
+Roeck Standards Track [Page 22]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ -- (ETSI 300-xxx)
+ -- note that NET3, NET5 define
+ -- test procedures for ETS300-102
+ -- and have been replaced by
+ -- I-CTR 3 and I-CTR 4.
+ dass2(4), -- U.K. / DASS2 (PRI)
+ ess4(5), -- U.S.A. / AT&T 4ESS
+ ess5(6), -- U.S.A. / AT&T 5ESS
+ dms100(7), -- U.S.A. / Northern Telecom DMS100
+ dms250(8), -- U.S.A. / Northern Telecom DMS250
+ ni1(9), -- U.S.A. / National ISDN 1 (BRI)
+ ni2(10), -- U.S.A. / National ISDN 2 (BRI, PRI)
+ ni3(11), -- U.S.A. / next one
+ vn2(12), -- France / VN2
+ vn3(13), -- France / VN3
+ vn4(14), -- France / VN4 (ETSI with changes)
+ vn6(15), -- France / VN6 (ETSI with changes)
+ -- delta document CSE P 10-21 A
+ -- test document CSE P 10-20 A
+ kdd(16), -- Japan / KDD
+ ins64(17), -- Japan / NTT INS64
+ ins1500(18), -- Japan / NTT INS1500
+ itr6(19), -- Germany/ 1TR6 (BRI, PRI)
+ cornet(20), -- Germany/ Siemens HiCom CORNET
+ ts013(21), -- Australia / TS013
+ -- (formerly TPH 1962, BRI)
+ ts014(22), -- Australia / TS014
+ -- (formerly TPH 1856, PRI)
+ qsig(23), -- Q.SIG
+ swissnet2(24), -- SwissNet-2
+ swissnet3(25) -- SwissNet-3
+ }
+
+-- Isdn Mib objects definitions
+
+isdnMibObjects OBJECT IDENTIFIER ::= { isdnMib 1 }
+
+-- ISDN physical interface group
+
+-- This group describes physical basic rate interfaces.
+
+isdnBasicRateGroup OBJECT IDENTIFIER ::= { isdnMibObjects 1 }
+
+isdnBasicRateTable OBJECT-TYPE
+ SYNTAX SEQUENCE OF IsdnBasicRateEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+
+
+
+Roeck Standards Track [Page 23]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ "Table containing configuration and operational
+ parameters for all physical Basic Rate
+ interfaces on this managed device."
+ ::= { isdnBasicRateGroup 1 }
+
+isdnBasicRateEntry OBJECT-TYPE
+ SYNTAX IsdnBasicRateEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "An entry in the ISDN Basic Rate Table."
+ INDEX { ifIndex }
+ ::= { isdnBasicRateTable 1 }
+
+IsdnBasicRateEntry ::= SEQUENCE {
+ isdnBasicRateIfType INTEGER,
+ isdnBasicRateLineTopology INTEGER,
+ isdnBasicRateIfMode INTEGER,
+ isdnBasicRateSignalMode INTEGER
+ }
+
+isdnBasicRateIfType OBJECT-TYPE
+ SYNTAX INTEGER {
+ isdns(75),
+ isdnu(76)
+ }
+ MAX-ACCESS read-write
+ STATUS current
+ DESCRIPTION
+ "The physical interface type. For 'S/T' interfaces,
+ also called 'Four-wire Basic Access Interface',
+ the value of this object is isdns(75).
+ For 'U' interfaces, also called 'Two-wire Basic
+ Access Interface', the value of this object is
+ isdnu(76)."
+ ::= { isdnBasicRateEntry 1 }
+
+isdnBasicRateLineTopology OBJECT-TYPE
+ SYNTAX INTEGER {
+ pointToPoint(1),
+ pointToMultipoint(2)
+ }
+ MAX-ACCESS read-write
+ STATUS current
+ DESCRIPTION
+ "The line topology to be used for this interface.
+ Note that setting isdnBasicRateIfType to isdns(75)
+ does not necessarily mean a line topology of
+
+
+
+Roeck Standards Track [Page 24]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ point-to-multipoint."
+ ::= { isdnBasicRateEntry 2 }
+
+isdnBasicRateIfMode OBJECT-TYPE
+ SYNTAX INTEGER {
+ te(1),
+ nt(2)
+ }
+ MAX-ACCESS read-write
+ STATUS current
+ DESCRIPTION
+ "The physical interface mode. For TE mode, the value
+ of this object is te(1). For NT mode, the value
+ of this object is nt(2)."
+ ::= { isdnBasicRateEntry 3 }
+
+isdnBasicRateSignalMode OBJECT-TYPE
+ SYNTAX INTEGER {
+ active(1),
+ inactive(2)
+ }
+ MAX-ACCESS read-write
+ STATUS current
+ DESCRIPTION
+ "The signaling channel operational mode for this interface.
+ If active(1) there is a signaling channel on this
+ interface. If inactive(2) a signaling channel is
+ not available."
+ ::= { isdnBasicRateEntry 4 }
+
+-- The B channel (bearer channel) group
+
+-- Note that disconnects can explicitely be handled using the
+-- ifStack table. If a connection is to be disconnected,
+-- the according ifStack entry has to be removed.
+-- More specifically, the ifStackTable entry which binds the high-layer
+-- ifTable entry (and related dialCtlNbrCfgTable entry) to the
+-- B channel ifTable entry (and related isdnBearerTable entry)
+-- during an active call has to be removed.
+
+isdnBearerGroup OBJECT IDENTIFIER ::= { isdnMibObjects 2 }
+
+isdnBearerTable OBJECT-TYPE
+ SYNTAX SEQUENCE OF IsdnBearerEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "This table defines port specific operational, statistics
+
+
+
+Roeck Standards Track [Page 25]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ and active call data for ISDN B channels. Each entry
+ in this table describes one B (bearer) channel."
+ ::= { isdnBearerGroup 1 }
+
+isdnBearerEntry OBJECT-TYPE
+ SYNTAX IsdnBearerEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "Operational and statistics information relating to
+ one port. A port is a single B channel."
+ INDEX { ifIndex }
+ ::= { isdnBearerTable 1 }
+
+IsdnBearerEntry ::=
+ SEQUENCE {
+ isdnBearerChannelType INTEGER,
+ isdnBearerOperStatus INTEGER,
+ isdnBearerChannelNumber INTEGER,
+ isdnBearerPeerAddress DisplayString,
+ isdnBearerPeerSubAddress DisplayString,
+ isdnBearerCallOrigin INTEGER,
+ isdnBearerInfoType INTEGER,
+ isdnBearerMultirate TruthValue,
+ isdnBearerCallSetupTime TimeStamp,
+ isdnBearerCallConnectTime TimeStamp,
+ isdnBearerChargedUnits Gauge32
+ }
+
+isdnBearerChannelType OBJECT-TYPE
+ SYNTAX INTEGER {
+ dialup(1),
+ leased(2)
+ }
+ MAX-ACCESS read-write
+ STATUS current
+ DESCRIPTION
+ "The B channel type. If the B channel is connected
+ to a dialup line, this object has a value of
+ dialup(1). In this case, it is controlled by
+ an associated signaling channel. If the B channel
+ is connected to a leased line, this object has
+ a value of leased(2). For leased line B channels, there
+ is no signaling channel control available."
+ ::= { isdnBearerEntry 1 }
+
+isdnBearerOperStatus OBJECT-TYPE
+ SYNTAX INTEGER {
+
+
+
+Roeck Standards Track [Page 26]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ idle(1),
+ connecting(2),
+ connected(3),
+ active(4)
+ }
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The current call control state for this port.
+ idle(1): The B channel is idle.
+ No call or call attempt is going on.
+ connecting(2): A connection attempt (outgoing call)
+ is being made on this interface.
+ connected(3): An incoming call is in the process
+ of validation.
+ active(4): A call is active on this interface."
+ ::= { isdnBearerEntry 2 }
+
+isdnBearerChannelNumber OBJECT-TYPE
+ SYNTAX INTEGER (1..30)
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The identifier being used by a signaling protocol
+ to identify this B channel, also referred to as
+ B channel number. If the Agent also supports the DS0 MIB,
+ the values of isdnBearerChannelNumber and dsx0Ds0Number
+ must be identical for a given B channel."
+ ::= { isdnBearerEntry 3 }
+
+isdnBearerPeerAddress OBJECT-TYPE
+ SYNTAX DisplayString
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The ISDN address the current or last call is or was
+ connected to.
+
+ In some cases, the format of this information can not
+ be predicted, since it largely depends on the type
+ of switch or PBX the device is connected to. Therefore,
+ the detailed format of this information is not
+ specified and is implementation dependent.
+
+ If possible, the agent should supply this information
+ using the E.164 format. In this case, the number must
+ start with '+'. Otherwise, IA5 number digits must be used.
+
+
+
+
+Roeck Standards Track [Page 27]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ If the peer ISDN address is not available,
+ this object has a length of zero."
+ REFERENCE
+ "ITU-T E.164, Q.931 chapter 4.5.10"
+ ::= { isdnBearerEntry 4 }
+
+isdnBearerPeerSubAddress OBJECT-TYPE
+ SYNTAX DisplayString
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The ISDN subaddress the current or last call is or was
+ connected to.
+
+ The subaddress is an user supplied string of up to 20
+ IA5 characters and is transmitted transparently through
+ the network.
+
+ If the peer subaddress is not available, this object
+ has a length of zero."
+ REFERENCE
+ "ITU-T I.330, Q.931 chapter 4.5.11"
+ ::= { isdnBearerEntry 5 }
+
+isdnBearerCallOrigin OBJECT-TYPE
+ SYNTAX INTEGER {
+ unknown(1),
+ originate(2),
+ answer(3),
+ callback(4)
+ }
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The call origin for the current or last call. If since
+ system startup there was no call on this interface,
+ this object has a value of unknown(1)."
+ ::= { isdnBearerEntry 6 }
+
+isdnBearerInfoType OBJECT-TYPE
+ SYNTAX INTEGER {
+ unknown(1),
+ speech(2),
+ unrestrictedDigital(3), -- as defined in Q.931
+ unrestrictedDigital56(4), -- with 56k rate adaption
+ restrictedDigital(5),
+ audio31(6), -- 3.1 kHz audio
+ audio7(7), -- 7 kHz audio
+
+
+
+Roeck Standards Track [Page 28]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ video(8),
+ packetSwitched(9)
+ }
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The Information Transfer Capability for the current
+ or last call.
+
+ speech(2) refers to a non-data connection, whereas
+ audio31(6) and audio7(7) refer to data mode connections.
+
+ Note that Q.931, chapter 4.5.5, originally defined
+ audio7(7) as '7 kHz audio' and now defines it as
+ 'Unrestricted digital information with tones/
+ announcements'.
+
+ If since system startup there has been no call on this
+ interface, this object has a value of unknown(1)."
+ REFERENCE
+ "Q.931 [8], chapter 4.5.5, octet 3 of bearer capability
+ information element, combined with the User Rate
+ (as defined in octets 5 and 5a to 5d), if rate adaption
+ is being used."
+ ::= { isdnBearerEntry 7 }
+
+isdnBearerMultirate OBJECT-TYPE
+ SYNTAX TruthValue
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "This flag indicates if the current or last call used
+ multirate. The actual information transfer rate,
+ in detail specified in octet 4.1 (rate multiplier),
+ is the sum of all B channel ifSpeed values for
+ the hyperchannel.
+
+ If since system startup there was no call on this
+ interface, this object has a value of false(2)."
+ REFERENCE
+ "Q.931 [8], chapter 4.5.5."
+ ::= { isdnBearerEntry 8 }
+
+isdnBearerCallSetupTime OBJECT-TYPE
+ SYNTAX TimeStamp
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+
+
+
+Roeck Standards Track [Page 29]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ "The value of sysUpTime when the ISDN setup message for
+ the current or last call was sent or received. If since
+ system startup there has been no call on this interface,
+ this object has a value of zero."
+ ::= { isdnBearerEntry 9 }
+
+isdnBearerCallConnectTime OBJECT-TYPE
+ SYNTAX TimeStamp
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The value of sysUpTime when the ISDN connect message for
+ the current or last call was sent or received. If since
+ system startup there has been no call on this interface,
+ this object has a value of zero."
+ ::= { isdnBearerEntry 10 }
+
+isdnBearerChargedUnits OBJECT-TYPE
+ SYNTAX Gauge32
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The number of charged units for the current or last
+ connection. For incoming calls or if charging information
+ is not supplied by the switch, the value of this object
+ is zero."
+ ::= { isdnBearerEntry 11 }
+
+-- ISDN signaling group
+
+isdnSignalingGroup OBJECT IDENTIFIER ::= { isdnMibObjects 3 }
+
+-- signaling channel configuration table
+-- There is one entry in this table for each Terminal Endpoint
+-- (link layer connection to the switch).
+-- Usually, there is one endpoint per D channel. In some
+-- cases, however, there can be multiple endpoints.
+-- Thus, entries in this table can be created and deleted.
+-- This also means the creation of an associated ifEntry.
+--
+-- D channel backup and NFAS trunks are handled using the
+-- ifStack table.
+-- In case of D channel backup, there are multiple
+-- Data Link Layer (LAPD) interfaces. Only one interface is
+-- active; all others are dormant(5).
+-- In case of NFAS trunks, one lower interface is the
+-- LAPD interface, while the other lower interfaces are physical
+-- interfaces.
+
+
+
+Roeck Standards Track [Page 30]
+
+RFC 2127 ISDN MIB March 1997
+
+
+-- If directory number and calling address differ from each other
+-- or multiple directory numbers are being used,
+-- the isdnDirectoryTable has to be used to enter such
+-- directory numbers.
+
+isdnSignalingGetIndex OBJECT-TYPE
+ SYNTAX TestAndIncr
+ MAX-ACCESS read-write
+ STATUS current
+ DESCRIPTION
+ "The recommended procedure for selecting a new index for
+ isdnSignalingTable row creation is to GET the value of
+ this object, and then to SET the object with the same
+ value. If the SET operation succeeds, the manager can use
+ this value as an index to create a new row in this table."
+ REFERENCE
+ "RFC1903, TestAndIncr textual convention."
+ ::= { isdnSignalingGroup 1 }
+
+isdnSignalingTable OBJECT-TYPE
+ SYNTAX SEQUENCE OF IsdnSignalingEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "ISDN signaling table containing configuration and
+ operational parameters for all ISDN signaling
+ channels on this managed device."
+ ::= { isdnSignalingGroup 2 }
+
+isdnSignalingEntry OBJECT-TYPE
+ SYNTAX IsdnSignalingEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "An entry in the ISDN Signaling Table. To create a new
+ entry, only isdnSignalingProtocol needs to be specified
+ before isdnSignalingStatus can become active(1)."
+ INDEX { isdnSignalingIndex }
+ ::= { isdnSignalingTable 1 }
+
+IsdnSignalingEntry ::= SEQUENCE {
+ isdnSignalingIndex INTEGER,
+ isdnSignalingIfIndex InterfaceIndex,
+ isdnSignalingProtocol IsdnSignalingProtocol,
+ isdnSignalingCallingAddress DisplayString,
+ isdnSignalingSubAddress DisplayString,
+ isdnSignalingBchannelCount Integer32,
+ isdnSignalingInfoTrapEnable INTEGER,
+
+
+
+Roeck Standards Track [Page 31]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ isdnSignalingStatus RowStatus
+ }
+
+isdnSignalingIndex OBJECT-TYPE
+ SYNTAX INTEGER (1..2147483647)
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "The index value which uniquely identifies an entry
+ in the isdnSignalingTable."
+ ::= { isdnSignalingEntry 1 }
+
+isdnSignalingIfIndex OBJECT-TYPE
+ SYNTAX InterfaceIndex
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The ifIndex value of the interface associated with this
+ signaling channel."
+ ::= { isdnSignalingEntry 2 }
+
+isdnSignalingProtocol OBJECT-TYPE
+ SYNTAX IsdnSignalingProtocol
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "The particular protocol type supported by the
+ switch providing access to the ISDN network
+ to which this signaling channel is connected."
+ ::= { isdnSignalingEntry 3 }
+
+isdnSignalingCallingAddress OBJECT-TYPE
+ SYNTAX DisplayString
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "The ISDN Address to be assigned to this signaling
+ channel. More specifically, this is the 'Calling Address
+ information element' as being passed to the switch
+ in outgoing call setup messages.
+
+ It can be an EAZ (1TR6), a calling number (DSS1, ETSI)
+ or any other number necessary to identify a signaling
+ interface. If there is no such number defined or required,
+ this is a zero length string. It is represented in
+ DisplayString form.
+
+ Incoming calls can also be identified by this number.
+
+
+
+Roeck Standards Track [Page 32]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ If the Directory Number, i.e. the Called Number in
+ incoming calls, is different to this number, the
+ isdnDirectoryTable has to be used to specify all
+ possible Directory Numbers.
+
+ The format of this information largely depends on the type
+ of switch or PBX the device is connected to. Therefore,
+ the detailed format of this information is not
+ specified and is implementation dependent.
+
+ If possible, the agent should implement this information
+ using the E.164 number format. In this case, the number
+ must start with '+'. Otherwise, IA5 number digits must
+ be used."
+ REFERENCE
+ "ITU-T E.164, Q.931 chapter 4.5.10"
+ DEFVAL { "" }
+ ::= { isdnSignalingEntry 4 }
+
+isdnSignalingSubAddress OBJECT-TYPE
+ SYNTAX DisplayString
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "Supplementary information to the ISDN address assigned
+ to this signaling channel. Usually, this is the
+ subaddress as defined in Q.931.
+ If there is no such number defined or required, this is
+ a zero length string.
+ The subaddress is used for incoming calls as well as
+ for outgoing calls.
+ The subaddress is an user supplied string of up to 20
+ IA5 characters and is transmitted transparently through
+ the network."
+ REFERENCE
+ "ITU-T I.330, Q.931 chapter 4.5.11"
+ DEFVAL { "" }
+ ::= { isdnSignalingEntry 5 }
+
+isdnSignalingBchannelCount OBJECT-TYPE
+ SYNTAX Integer32 (1..65535)
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "The total number of B channels (bearer channels)
+ managed by this signaling channel. The default value
+ of this object depends on the physical interface type
+ and is either 2 for Basic Rate interfaces or
+
+
+
+Roeck Standards Track [Page 33]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ 24 (30) for Primary Rate interfaces."
+ ::= { isdnSignalingEntry 6 }
+
+isdnSignalingInfoTrapEnable OBJECT-TYPE
+ SYNTAX INTEGER {
+ enabled(1),
+ disabled(2)
+ }
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "Indicates whether isdnMibCallInformation traps
+ should be generated for calls on this signaling
+ channel."
+ DEFVAL { disabled }
+ ::= { isdnSignalingEntry 7 }
+
+isdnSignalingStatus OBJECT-TYPE
+ SYNTAX RowStatus
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "This object is used to create and delete rows in the
+ isdnSignalingTable."
+ ::= { isdnSignalingEntry 8 }
+
+-- Signaling channel statistics table
+-- There is one entry for each signaling connection
+-- in this table.
+-- Note that the ifEntry also has some statistics information.
+
+isdnSignalingStatsTable OBJECT-TYPE
+ SYNTAX SEQUENCE OF IsdnSignalingStatsEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "ISDN signaling table containing statistics
+ information for all ISDN signaling channels
+ on this managed device.
+ Only statistical information which is not already being
+ counted in the ifTable is being defined in this table."
+ ::= { isdnSignalingGroup 3 }
+
+isdnSignalingStatsEntry OBJECT-TYPE
+ SYNTAX IsdnSignalingStatsEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+
+
+
+Roeck Standards Track [Page 34]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ "An entry in the ISDN Signaling statistics Table."
+ AUGMENTS { isdnSignalingEntry }
+ ::= { isdnSignalingStatsTable 1 }
+
+IsdnSignalingStatsEntry ::= SEQUENCE {
+ isdnSigStatsInCalls Counter32,
+ isdnSigStatsInConnected Counter32,
+ isdnSigStatsOutCalls Counter32,
+ isdnSigStatsOutConnected Counter32,
+ isdnSigStatsChargedUnits Counter32
+ }
+
+isdnSigStatsInCalls OBJECT-TYPE
+ SYNTAX Counter32
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The number of incoming calls on this interface."
+ ::= { isdnSignalingStatsEntry 1 }
+
+isdnSigStatsInConnected OBJECT-TYPE
+ SYNTAX Counter32
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The number of incoming calls on this interface
+ which were actually connected."
+ ::= { isdnSignalingStatsEntry 2 }
+
+isdnSigStatsOutCalls OBJECT-TYPE
+ SYNTAX Counter32
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The number of outgoing calls on this interface."
+ ::= { isdnSignalingStatsEntry 3 }
+
+isdnSigStatsOutConnected OBJECT-TYPE
+ SYNTAX Counter32
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The number of outgoing calls on this interface
+ which were actually connected."
+ ::= { isdnSignalingStatsEntry 4 }
+
+isdnSigStatsChargedUnits OBJECT-TYPE
+ SYNTAX Counter32
+
+
+
+Roeck Standards Track [Page 35]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The number of charging units on this interface 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, are counted here."
+ ::= { isdnSignalingStatsEntry 5 }
+
+--
+-- The LAPD table
+
+isdnLapdTable OBJECT-TYPE
+ SYNTAX SEQUENCE OF IsdnLapdEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "Table containing configuration and statistics
+ information for all LAPD (D channel Data Link)
+ interfaces on this managed device.
+ Only statistical information which is not already being
+ counted in the ifTable is being defined in this table."
+ ::= { isdnSignalingGroup 4 }
+
+isdnLapdEntry OBJECT-TYPE
+ SYNTAX IsdnLapdEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "An entry in the LAPD Table."
+ INDEX { ifIndex }
+ ::= { isdnLapdTable 1 }
+
+IsdnLapdEntry ::= SEQUENCE {
+ isdnLapdPrimaryChannel TruthValue,
+ isdnLapdOperStatus INTEGER,
+ isdnLapdPeerSabme Counter32,
+ isdnLapdRecvdFrmr Counter32
+ }
+
+isdnLapdPrimaryChannel OBJECT-TYPE
+ SYNTAX TruthValue
+ MAX-ACCESS read-write
+ STATUS current
+ DESCRIPTION
+ "If set to true(1), this D channel is the designated
+ primary D channel if D channel backup is active.
+
+
+
+Roeck Standards Track [Page 36]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ There must be exactly one primary D channel
+ configured. If D channel backup is not used, this
+ object has a value of true(1)."
+ REFERENCE
+ "Q.931 [8], Annex F, D channel backup procedures."
+ ::= { isdnLapdEntry 1 }
+
+isdnLapdOperStatus OBJECT-TYPE
+ SYNTAX INTEGER {
+ inactive(1),
+ l1Active(2),
+ l2Active(3)
+ }
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The operational status of this interface:
+
+ inactive all layers are inactive
+ l1Active layer 1 is activated,
+ layer 2 datalink not established
+ l2Active layer 1 is activated,
+ layer 2 datalink established."
+ ::= { isdnLapdEntry 2 }
+
+isdnLapdPeerSabme OBJECT-TYPE
+ SYNTAX Counter32
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The number of peer SABME frames received on this
+ interface. This is the number of peer-initiated
+ new connections on this interface."
+ ::= { isdnLapdEntry 3 }
+
+isdnLapdRecvdFrmr OBJECT-TYPE
+ SYNTAX Counter32
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The number of LAPD FRMR response frames received.
+ This is the number of framing errors on this
+ interface."
+ ::= { isdnLapdEntry 4 }
+
+--
+-- Optional groups follow here.
+
+
+
+
+Roeck Standards Track [Page 37]
+
+RFC 2127 ISDN MIB March 1997
+
+
+-- The Terminal Endpoint group and table
+
+-- This table is required only if TEI values or SPID numbers
+-- have to be entered.
+-- The ifIndex values for this table are identical to those of
+-- the isdnSignalingChannel table.
+
+isdnEndpointGroup OBJECT IDENTIFIER ::= { isdnMibObjects 4 }
+
+isdnEndpointGetIndex OBJECT-TYPE
+ SYNTAX TestAndIncr
+ MAX-ACCESS read-write
+ STATUS current
+ DESCRIPTION
+ "The recommended procedure for selecting a new index for
+ isdnEndpointTable row creation is to GET the value of
+ this object, and then to SET the object with the same
+ value. If the SET operation succeeds, the manager can use
+ this value as an index to create a new row in this table."
+ REFERENCE
+ "RFC1903, TestAndIncr textual convention."
+ ::= { isdnEndpointGroup 1 }
+
+isdnEndpointTable OBJECT-TYPE
+ SYNTAX SEQUENCE OF IsdnEndpointEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "Table containing configuration for Terminal
+ Endpoints."
+ ::= { isdnEndpointGroup 2 }
+
+isdnEndpointEntry OBJECT-TYPE
+ SYNTAX IsdnEndpointEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "An entry in the Terminal Endpoint Table. The value
+ of isdnEndpointIfType must be supplied for a row
+ in this table to become active."
+ INDEX { isdnEndpointIndex }
+ ::= { isdnEndpointTable 1 }
+
+IsdnEndpointEntry ::= SEQUENCE {
+ isdnEndpointIndex INTEGER,
+ isdnEndpointIfIndex InterfaceIndex,
+ isdnEndpointIfType IANAifType,
+ isdnEndpointTeiType INTEGER,
+
+
+
+Roeck Standards Track [Page 38]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ isdnEndpointTeiValue INTEGER,
+ isdnEndpointSpid DisplayString,
+ isdnEndpointStatus RowStatus
+ }
+
+isdnEndpointIndex OBJECT-TYPE
+ SYNTAX INTEGER (1..2147483647)
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "The index value which uniquely identifies an entry
+ in the isdnEndpointTable."
+ ::= { isdnEndpointEntry 1 }
+
+isdnEndpointIfIndex OBJECT-TYPE
+ SYNTAX InterfaceIndex
+ MAX-ACCESS read-only
+ STATUS current
+ DESCRIPTION
+ "The ifIndex value of the interface associated with this
+ Terminal Endpoint."
+ ::= { isdnEndpointEntry 2 }
+
+isdnEndpointIfType OBJECT-TYPE
+ SYNTAX IANAifType
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "The interface type for this Terminal Endpoint.
+ Interface types of x25ple(40) and isdn(63) are allowed.
+ The interface type is identical to the value of
+ ifType in the associated ifEntry."
+ ::= { isdnEndpointEntry 3 }
+
+isdnEndpointTeiType OBJECT-TYPE
+ SYNTAX INTEGER {
+ dynamic(1),
+ static(2)
+ }
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "The type of TEI (Terminal Endpoint Identifier)
+ used for this Terminal Endpoint. In case of dynamic(1),
+ the TEI value is selected by the switch. In
+ case of static(2), a valid TEI value has to be
+ entered in the isdnEndpointTeiValue object.
+ The default value for this object depends on the
+
+
+
+Roeck Standards Track [Page 39]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ interface type as well as the Terminal Endpoint type.
+ On Primary Rate interfaces the default value is
+ static(2). On Basic Rate interfaces the default value
+ is dynamic(1) for isdn(63) Terminal Endpoints and
+ static(2) for x25ple(40) Terminal Endpoints."
+ ::= { isdnEndpointEntry 4 }
+
+isdnEndpointTeiValue OBJECT-TYPE
+ SYNTAX INTEGER ( 0..255 )
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "The TEI (Terminal Endpoint Identifier) value
+ for this Terminal Endpoint. If isdnEndpointTeiType
+ is set to static(2), valid numbers are 0..63,
+ while otherwise the value is set internally.
+ The default value of this object is 0 for static
+ TEI assignment.
+ The default value for dynamic TEI assignment is also
+ 0 as long as no TEI has been assigned. After TEI
+ assignment, the assigned TEI value is returned."
+ ::= { isdnEndpointEntry 5 }
+
+isdnEndpointSpid OBJECT-TYPE
+ SYNTAX DisplayString
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "The Service profile IDentifier (SPID) information
+ for this Terminal Endpoint.
+
+ The SPID is composed of 9-20 numeric characters.
+
+ This information has to be defined in addition to
+ the local number for some switch protocol types,
+ e.g. Bellcore NI-1 and NI-2.
+
+ If this object is not required, it is a
+ zero length string."
+ REFERENCE
+ "Bellcore SR-NWT-001953, Generic Guidelines for ISDN
+ Terminal Equipment on Basic Access Interfaces,
+ Chapter 8.5.1."
+ DEFVAL { "" }
+ ::= { isdnEndpointEntry 6 }
+
+isdnEndpointStatus OBJECT-TYPE
+ SYNTAX RowStatus
+
+
+
+Roeck Standards Track [Page 40]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "This object is used to create and delete rows in the
+ isdnEndpointTable."
+ ::= { isdnEndpointEntry 7 }
+
+--
+-- The Directory Number group
+--
+
+isdnDirectoryGroup OBJECT IDENTIFIER ::= { isdnMibObjects 5 }
+
+isdnDirectoryTable OBJECT-TYPE
+ SYNTAX SEQUENCE OF IsdnDirectoryEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "Table containing Directory Numbers."
+ ::= { isdnDirectoryGroup 1 }
+
+isdnDirectoryEntry OBJECT-TYPE
+ SYNTAX IsdnDirectoryEntry
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "An entry in the Directory Number Table. All objects
+ in an entry must be set for a new row to become active."
+ INDEX { isdnDirectoryIndex }
+ ::= { isdnDirectoryTable 1 }
+
+IsdnDirectoryEntry ::= SEQUENCE {
+ isdnDirectoryIndex INTEGER,
+ isdnDirectoryNumber DisplayString,
+ isdnDirectorySigIndex INTEGER,
+ isdnDirectoryStatus RowStatus
+ }
+
+isdnDirectoryIndex OBJECT-TYPE
+ SYNTAX INTEGER ( 1..'7fffffff'h )
+ MAX-ACCESS not-accessible
+ STATUS current
+ DESCRIPTION
+ "The index value which uniquely identifies an entry
+ in the isdnDirectoryTable."
+ ::= { isdnDirectoryEntry 1 }
+
+isdnDirectoryNumber OBJECT-TYPE
+
+
+
+Roeck Standards Track [Page 41]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ SYNTAX DisplayString
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "A Directory Number. Directory Numbers are used
+ to identify incoming calls on the signaling
+ channel given in isdnDirectorySigIndex.
+
+ The format of this information largely depends on the type
+ of switch or PBX the device is connected to. Therefore,
+ the detailed format of this information is not
+ specified and is implementation dependent.
+
+ If possible, the agent should implement this information
+ using the E.164 number format. In this case, the number
+ must start with '+'. Otherwise, IA5 number digits must
+ be used."
+ REFERENCE
+ "ITU-T E.164, Q.931 chapter 4.5.10"
+ ::= { isdnDirectoryEntry 2 }
+
+isdnDirectorySigIndex OBJECT-TYPE
+ SYNTAX INTEGER (1..2147483647)
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "An index pointing to an ISDN signaling channel.
+ Incoming calls are accepted on this
+ signaling channel if the isdnDirectoryNumber is
+ presented as Called Number in the SETUP message."
+ ::= { isdnDirectoryEntry 3 }
+
+isdnDirectoryStatus OBJECT-TYPE
+ SYNTAX RowStatus
+ MAX-ACCESS read-create
+ STATUS current
+ DESCRIPTION
+ "This object is used to create and delete rows in the
+ isdnDirectoryTable."
+ ::= { isdnDirectoryEntry 4 }
+
+-- Traps
+
+isdnMibTrapPrefix OBJECT IDENTIFIER ::= { isdnMib 2 }
+isdnMibTraps OBJECT IDENTIFIER ::= { isdnMibTrapPrefix 0 }
+
+isdnMibCallInformation NOTIFICATION-TYPE
+ OBJECTS {
+
+
+
+Roeck Standards Track [Page 42]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ ifIndex, -- isdnBearerTable ifIndex
+ isdnBearerOperStatus,
+ isdnBearerPeerAddress,
+ isdnBearerPeerSubAddress,
+ isdnBearerCallSetupTime,
+ isdnBearerInfoType,
+ isdnBearerCallOrigin
+ }
+ STATUS current
+ DESCRIPTION
+ "This trap/inform is sent to the manager under the
+ following condidions:
+ - on incoming calls for each call which is rejected for
+ policy reasons (e.g. unknown neighbor or access
+ violation)
+ - on outgoing calls whenever a call attempt is determined
+ to have ultimately failed. In the event that call retry
+ is active, then this will be after all retry attempts
+ have failed.
+ - whenever a call connects. In this case, the object
+ isdnBearerCallConnectTime should be included in the
+ trap.
+
+ Only one such trap is sent in between successful or
+ unsuccessful call attempts from or to a single neighbor;
+ subsequent call attempts result in no trap.
+
+ If the Dial Control MIB objects dialCtlNbrCfgId and
+ dialCtlNbrCfgIndex are known by the entity generating
+ this trap, both objects should be included in the trap
+ as well. The receipt of this trap with no dial neighbor
+ information indicates that the manager must poll the
+ callHistoryTable of the Dial Control MIB to see what
+ changed."
+ ::= { isdnMibTraps 1 }
+
+--
+-- conformance information
+--
+
+isdnMibConformance OBJECT IDENTIFIER ::= { isdnMib 2 }
+isdnMibCompliances OBJECT IDENTIFIER ::= { isdnMibConformance 1 }
+isdnMibGroups OBJECT IDENTIFIER ::= { isdnMibConformance 2 }
+
+-- compliance statements
+
+isdnMibCompliance MODULE-COMPLIANCE
+ STATUS current
+
+
+
+Roeck Standards Track [Page 43]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ DESCRIPTION
+ "The compliance statement for entities which implement
+ the ISDN MIB."
+ MODULE -- this module
+
+-- unconditionally mandatory groups
+ MANDATORY-GROUPS {
+ isdnMibSignalingGroup,
+ isdnMibBearerGroup,
+ isdnMibNotificationsGroup
+ }
+
+-- conditionally mandatory group
+ GROUP isdnMibBasicRateGroup
+ DESCRIPTION
+ "The isdnMibBasicRateGroup is mandatory for entities
+ supporting ISDN Basic Rate interfaces."
+
+-- optional groups
+ GROUP isdnMibEndpointGroup
+ DESCRIPTION
+ "Implementation of this group is optional for all systems
+ that attach to ISDN interfaces."
+
+ GROUP isdnMibDirectoryGroup
+ DESCRIPTION
+ "Implementation of this group is optional for all systems
+ that attach to ISDN interfaces."
+
+ OBJECT isdnBasicRateIfType
+ MIN-ACCESS read-only
+ DESCRIPTION
+ "It is conformant to implement this object as read-only."
+
+ OBJECT isdnBasicRateLineTopology
+ MIN-ACCESS read-only
+ DESCRIPTION
+ "It is conformant to implement this object as read-only."
+
+ OBJECT isdnBasicRateIfMode
+ MIN-ACCESS read-only
+ DESCRIPTION
+ "It is conformant to implement this object as read-only."
+
+ OBJECT isdnBasicRateSignalMode
+ MIN-ACCESS read-only
+ DESCRIPTION
+ "It is conformant to implement this object as read-only."
+
+
+
+Roeck Standards Track [Page 44]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ ::= { isdnMibCompliances 1 }
+
+-- units of conformance
+
+isdnMibBasicRateGroup OBJECT-GROUP
+ OBJECTS {
+ isdnBasicRateIfType,
+ isdnBasicRateLineTopology,
+ isdnBasicRateIfMode,
+ isdnBasicRateSignalMode
+ }
+ STATUS current
+ DESCRIPTION
+ "A collection of objects required for ISDN Basic Rate
+ physical interface configuration and statistics."
+ ::= { isdnMibGroups 1 }
+
+isdnMibBearerGroup OBJECT-GROUP
+ OBJECTS {
+ isdnBearerChannelType,
+ isdnBearerOperStatus,
+ isdnBearerChannelNumber,
+ isdnBearerPeerAddress,
+ isdnBearerPeerSubAddress,
+ isdnBearerCallOrigin,
+ isdnBearerInfoType,
+ isdnBearerMultirate,
+ isdnBearerCallSetupTime,
+ isdnBearerCallConnectTime,
+ isdnBearerChargedUnits
+ }
+ STATUS current
+ DESCRIPTION
+ "A collection of objects required for ISDN Bearer channel
+ control and statistics."
+ ::= { isdnMibGroups 2 }
+
+isdnMibSignalingGroup OBJECT-GROUP
+ OBJECTS {
+ isdnSignalingGetIndex,
+ isdnSignalingIfIndex,
+ isdnSignalingProtocol,
+ isdnSignalingCallingAddress,
+ isdnSignalingSubAddress,
+ isdnSignalingBchannelCount,
+ isdnSignalingInfoTrapEnable,
+ isdnSignalingStatus,
+ isdnSigStatsInCalls,
+
+
+
+Roeck Standards Track [Page 45]
+
+RFC 2127 ISDN MIB March 1997
+
+
+ isdnSigStatsInConnected,
+ isdnSigStatsOutCalls,
+ isdnSigStatsOutConnected,
+ isdnSigStatsChargedUnits,
+ isdnLapdPrimaryChannel,
+ isdnLapdOperStatus,
+ isdnLapdPeerSabme,
+ isdnLapdRecvdFrmr
+ }
+ STATUS current
+ DESCRIPTION
+ "A collection of objects required for ISDN D channel
+ configuration and statistics."
+ ::= { isdnMibGroups 3 }
+
+isdnMibEndpointGroup OBJECT-GROUP
+ OBJECTS {
+ isdnEndpointGetIndex,
+ isdnEndpointIfIndex,
+ isdnEndpointIfType,
+ isdnEndpointTeiType,
+ isdnEndpointTeiValue,
+ isdnEndpointSpid,
+ isdnEndpointStatus
+ }
+ STATUS current
+ DESCRIPTION
+ "A collection of objects describing Terminal Endpoints."
+ ::= { isdnMibGroups 4 }
+
+isdnMibDirectoryGroup OBJECT-GROUP
+ OBJECTS {
+ isdnDirectoryNumber,
+ isdnDirectorySigIndex,
+ isdnDirectoryStatus
+ }
+ STATUS current
+ DESCRIPTION
+ "A collection of objects describing directory numbers."
+ ::= { isdnMibGroups 5 }
+
+isdnMibNotificationsGroup NOTIFICATION-GROUP
+ NOTIFICATIONS { isdnMibCallInformation }
+ STATUS current
+ DESCRIPTION
+ "The notifications which a ISDN MIB entity is
+ required to implement."
+ ::= { isdnMibGroups 6 }
+
+
+
+Roeck Standards Track [Page 46]
+
+RFC 2127 ISDN MIB March 1997
+
+
+END
+
+
+5. Acknowledgments
+
+ This document was produced by the ISDN MIB Working Group. Special
+ thanks is due to the following persons:
+
+ Ed Alcoff
+ Fred Baker
+ Scott Bradner
+ Bibek A. Das
+ Maria Greene
+ Ken Grigg
+ Stefan Hochuli
+ Jeffrey T. Johnson
+ Glenn Kime
+ Oliver Korfmacher
+ Kedar Madineni
+ Bill Miskovetz
+ Mike O'Dowd
+ David M. Piscitello
+ Lisa A. Phifer
+ Randy Roberts
+ Hascall H. Sharp
+ John Shriver
+ Robert Snyder
+ Bob Stewart
+ Ron Stoughton
+ James Watt
+
+6. 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.
+
+
+
+
+Roeck Standards Track [Page 47]
+
+RFC 2127 ISDN MIB March 1997
+
+
+[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 Signaling System No. 1
+ (DSS 1) - ISDN User-Network Interface Data Link Layer - General
+ Aspects Rec. Q.920.
+
+[6] ITU-T Recommendation "Digital subscriber Signaling System No. 1
+ (DSS 1) - ISDN User-Network Interface - Data Link Layer
+ Specification Rec. Q.921.
+
+[7] ITU-T Recommendation "Digital subscriber Signaling System No. 1
+ (DSS 1) - ISDN Data Link Layer Specification for Frame Mode Bearer
+ Services (LAPF) Rec. Q.922.
+
+[8] ITU-T Recommendation "Digital subscriber Signaling System No. 1
+ (DSS 1) - ISDN user-network interface layer 3 specification for
+ basic call control", Rec. Q.931(I.451), March 1993.
+
+[9] ITU-T Recommendation "Generic procedures for the control of ISDN
+ supplementary services ISDN user-network interface layer 3
+ specification", Rec. Q.932(I.452).
+
+[10] ITU-T Recommendation "Digital subscriber Signaling System No. 1
+ (DSS 1) - Signaling specification for frame-mode basic call
+ control", Rec. Q.933.
+
+[11] McCloghrie, K. and F. Kastenholz, "Evolution of the Interfaces
+ Group of MIB-II", RFC 1573, Hughes LAN Systems, FTP Software,
+ January 1994.
+
+[12] Fowler, D., "Definitions of Managed Objects for the DS1/E1/DS2/E2
+ Interface Types", Work in Progress.
+
+[13] Fowler, D., "Definitions of Managed Objects for the DS0 and
+ DS0Bundle Interface Types", Work in Progress.
+
+[14] ITU-T Recommendation "Integrated Services Digital Network (ISDN)
+ General Structure and Service Capabilities - Closed User Group",
+ Rec. I.255.1.
+
+[15] Roeck, G., "Dial Control Management Information Base", RFC 2128,
+ March 1997.
+
+
+
+
+
+
+
+Roeck Standards Track [Page 48]
+
+RFC 2127 ISDN MIB March 1997
+
+
+7. Security Considerations
+
+ Security issues are not discussed in this memo.
+
+8. 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
+
+
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+