Extreme Networks, Inc.
J. Flick
Hewlett-Packard Company
K. de Graaf
Argon Networks
D. Romascanu
Lucent Technologies
D. McMaster
Cisco Systems, Inc.
K. McCloghrie
Cisco Systems, Inc.
S. Roberts
Farallon Computing, Inc.
August 1999
Definitions of Managed Objects for
IEEE 802.3 Medium Attachment Units (MAUs)
Status of this Memo
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This document specifies an Internet standards track protocol for the Internet community, and requests discussion and suggestions for improvements. Please refer to the current edition of the "Internet Official Protocol Standards" (STD 1) for the standardization state and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
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Copyright © The Internet Society (1999). All Rights Reserved.
Abstract
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This memo defines a portion of the Management Information Base (MIB) for use with network management protocols in the Internet community. This memo obsoletes RFC 2239, "Definitions of Managed Objects for IEEE 802.3 Medium Attachment Units (MAUs) using SMIv2". This memo extends that specification by including management information useful for the management of 1000 Mb/s MAUs.
Ethernet technology, as defined by the 802.3 Working Group of the IEEE, continues to evolve, with scalable increases in speed, new types of cabling and interfaces, and new features. This evolution may require changes in the managed objects in order to reflect this new functionality. This document, as with other documents issued by this working group, reflects a certain stage in the evolution of Ethernet technology. In the future, this document might be revised, or new documents might be issued by the Ethernet Interfaces and Hub MIB Working Group, in order to reflect the evolution of Ethernet technology.
Table of Contents
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1. Introduction ............................................... 2 2. The SNMP Management Framework .............................. 3 3. Overview ................................................... 4 3.1. Relationship to RFC 2239 ................................. 4 3.2. Relationship to RFC 1515 ................................. 4 3.3. MAU Management ........................................... 4 3.4. Relationship to Other MIBs ............................... 5 3.4.1. Relationship to the Interfaces MIB ..................... 5 3.4.2. Relationship to the 802.3 Repeater MIB ................. 5 3.5. Management of Internal MAUs .............................. 5 4. Definitions ................................................ 6 5. Intellectual Property ...................................... 49 6. Acknowledgements ........................................... 49 7. References ................................................. 50 8. Security Considerations .................................... 52 9. Authors' Addresses ......................................... 53 10. Appendix: Change Log ....................................... 55 11. Full Copyright Statement .................................. 57
1. Introduction
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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 objects for managing IEEE 802.3 Medium Attachment Units (MAUs).
This memo also includes a MIB module. This MIB module extends the list of managed objects specified in the earlier version of this MIB: RFC 2239 [21].
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [20].
2. The SNMP Management Framework
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The SNMP Management Framework presently consists of five major components:
o An overall architecture, described in RFC 2571 [1]. o Mechanisms for describing and naming objects and events for the purpose of management. The first version of this Structure of Management Information (SMI) is called SMIv1 and described in STD 16, RFC 1155 [2], STD 16, RFC 1212 [3] and RFC 1215 [4]. The second version, called SMIv2, is described in STD 58, RFC 2578 [5], STD 58, RFC 2579 [6] and STD 58, RFC 2580 [7]. o Message protocols for transferring management information. The first version of the SNMP message protocol is called SNMPv1 and described in STD 15, RFC 1157 [8]. A second version of the SNMP message protocol, which is not an Internet standards track protocol, is called SNMPv2c and described in RFC 1901 [9] and RFC 1906 [10]. The third version of the message protocol is called SNMPv3 and described in RFC 1906 [10], RFC 2572 [11] and RFC 2574 [12]. o Protocol operations for accessing management information. The first set of protocol operations and associated PDU formats is described in STD 15, RFC 1157 [8]. A second set of protocol operations and associated PDU formats is described in RFC 1905 [13]. o A set of fundamental applications described in RFC 2573 [14] and the view-based access control mechanism described in RFC 2575 [15].
Managed objects are accessed via a virtual information store, termed the Management Information Base or MIB. Objects in the MIB are defined using the mechanisms defined in the SMI.
This memo specifies a MIB module that is compliant to the SMIv2. A MIB conforming to the SMIv1 can be produced through the appropriate translations. The resulting translated MIB must be semantically equivalent, except where objects or events are omitted because no translation is possible (use of Counter64). Some machine readable information in SMIv2 will be converted into textual descriptions in SMIv1 during the translation process. However, this loss of machine readable information is not considered to change the semantics of the MIB.
3. Overview
3.1. Relationship to RFC 2239
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This MIB is intended to be a superset of that defined by RFC 2239 [21], which will go to historic status. This MIB includes all of the objects contained in that MIB, plus several new ones which provide additional capabilities. Implementors are encouraged to support all applicable conformance groups in order to make the best use of the new functionality provided by this MIB. The new objects provide management support for:
o management of 1000 Mb/s devices o management of PAUSE negotiation o management of remote fault status
3.2. Relationship to RFC 1515
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RFC 2239 was a replacement for RFC 1515 [22], which is now historic. RFC 2239 defined a superset of RFC 1515 which contained all of the objects defined in RFC 1515, plus several new ones which provided additional capabilities. The new objects in RFC 2239 provided management support for:
o management of 100 Mb/s devices o auto-negotiation on interface MAUs o jack management
3.3. MAU Management
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Instances of these object types represent attributes of an IEEE 802.3 MAU. Several types of MAUs are defined in the IEEE 802.3 CSMA/CD standard [16]. These MAUs may be connected to IEEE 802.3 repeaters or to 802.3 (Ethernet-like) interfaces. For convenience this document refers to these devices as "repeater MAUs" and "interface MAUs."
The definitions presented here are based on Section 30.5, "Layer Management for 10, 100 & 1000 Mb/s Medium Attachment Units (MAUs)", and Annex 30A, "GDMO Specifications for 802.3 managed object classes" of IEEE Std. 802.3, 1998 edition [16]. That specification includes definitions for 10Mb/s, 100Mb/s and 1000Mb/s devices. This specification is intended to serve the same purpose: to provide for management of all types of Ethernet/802.3 MAUs.
3.4. Relationship to Other MIBs
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It is assumed that an agent implementing this MIB will also implement (at least) the 'system' group defined in MIB-II [18]. The following sections identify other MIBs that such an agent should implement.
3.4.1. Relationship to the Interfaces MIB.
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The sections of this document that define interface MAU-related objects specify an extension to the Interfaces MIB [19]. An agent implementing these interface-MAU related objects MUST also implement the relevant groups of Interface MIB. The value of the object ifMauIfIndex is the same as the value of 'ifIndex' used to instantiate the interface to which the given MAU is connected.
It is expected that an agent implementing the interface-MAU related objects in this MIB will also implement the Ethernet-like Interfaces MIB, [23].
(Note that repeater ports are not represented as interfaces in the Interface MIB.)
3.4.2. Relationship to the 802.3 Repeater MIB
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The section of this document that defines repeater MAU-related objects specifies an extension to the 802.3 Repeater MIB defined in [17]. An agent implementing these repeater-MAU related objects MUST also implement the 802.3 Repeater MIB.
The values of 'rpMauGroupIndex' and 'rpMauPortIndex' used to instantiate a repeater MAU variable SHALL be the same as the values of 'rptrPortGroupIndex' and 'rptrPortIndex' used to instantiate the port to which the given MAU is connected.
3.5. Management of Internal MAUs
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In some situations, a MAU can be "internal" -- i.e., its functionality is implemented entirely within a device. For example, a managed repeater may contain an internal repeater-MAU and/or an internal interface-MAU through which management communications originating on one of the repeater's external ports pass in order to reach the management agent associated with the repeater. Such internal MAUs may or may not be managed. If they are managed, objects describing their attributes should appear in the appropriate MIB subtree: dot3RpMauBasicGroup for internal repeater-MAUs and dot3IfMauBasicGroup for internal interface-MAUs.
4. Definitions
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MAU-MIB DEFINITIONS ::= BEGIN
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IMPORTS
Counter32, Integer32, OBJECT-TYPE, MODULE-IDENTITY, NOTIFICATION-TYPE, OBJECT-IDENTITY, mib-2 FROM SNMPv2-SMI TruthValue, TEXTUAL-CONVENTION FROM SNMPv2-TC OBJECT-GROUP, MODULE-COMPLIANCE, NOTIFICATION-GROUP FROM SNMPv2-CONF;-
mauMod MODULE-IDENTITY
LAST-UPDATED "9908240400Z" -- August 24, 1999 ORGANIZATION "IETF Ethernet Interfaces and Hub MIB Working Group" CONTACT-INFO "WG E-mail: hubmib@hprnd.rose.hp.com To subscribe: hubmib-request@hprnd.rose.hp.com Chair: Dan Romascanu Postal: Lucent Technologies Atidim Technology Park, Bldg. 3 Tel Aviv 61131 Israel Tel: +972 3 645 8414, 6458458 Fax: +972 3 648 7146 E-mail: dromasca@lucent.com-
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Editors: Andrew Smith
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Postal: Extreme Networks, Inc. 10460 Bandley Drive Cupertino, CA 95014 USA Tel: +1 408 579-2821 E-mail: andrew@extremenetworks.com John Flick Postal: Hewlett-Packard Company 8000 Foothills Blvd. M/S 5557 Roseville, CA 95747-5557 USA Tel: +1 916 785 4018 Fax: +1 916 785 1199 E-mail: johnf@rose.hp.com Kathryn de Graaf Postal: Argon Networks 25 Porter Road Littleton, MA 01460 USA Tel: +1 978 486 0665 x163 Fax: +1 978 486 9379 E-mail: kdegraaf@argon.com" DESCRIPTION "Management information for 802.3 MAUs.-
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The following reference is used throughout this MIB module:
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[IEEE 802.3 Std] refers to IEEE Std 802.3, 1998 Edition: 'Information technology - Telecommunications and information exchange between systems - Local and metropolitan area networks - Specific requirements - Part 3: Carrier sense multiple access with collision detection (CSMA/CD) access method and physical layer specifications', September 1998. Of particular interest is Clause 30, '10Mb/s, 100Mb/s and 1000Mb/s Management'." REVISION "9908240400Z" -- August 24, 1999 DESCRIPTION "This version published as RFC 2668. Updated to include support for 1000 Mb/sec MAUs and flow control negotiation." REVISION "9710310000Z" -- October 31, 1997 DESCRIPTION "This version published as RFC 2239." -
REVISION "9309300000Z" -- September 30, 1993
DESCRIPTION "Initial version, published as RFC 1515."
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::= { snmpDot3MauMgt 6 } snmpDot3MauMgt OBJECT IDENTIFIER ::= { mib-2 26 } -- textual conventions-
JackType ::= TEXTUAL-CONVENTION
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STATUS current
DESCRIPTION "Common enumeration values for repeater
and interface MAU jack types."
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SYNTAX INTEGER { other(1), rj45(2), rj45S(3), -- rj45 shielded db9(4), bnc(5), fAUI(6), -- female aui mAUI(7), -- male aui fiberSC(8), fiberMIC(9), fiberST(10), telco(11), mtrj(12), -- fiber MT-RJ hssdc(13) -- fiber channel style-2 } dot3RpMauBasicGroup OBJECT IDENTIFIER ::= { snmpDot3MauMgt 1 } dot3IfMauBasicGroup OBJECT IDENTIFIER ::= { snmpDot3MauMgt 2 } dot3BroadMauBasicGroup OBJECT IDENTIFIER ::= { snmpDot3MauMgt 3 }-
dot3IfMauAutoNegGroup
OBJECT IDENTIFIER ::= { snmpDot3MauMgt 5 }-
-- object identities for MAU types
-- (see rpMauType and ifMauType for usage)dot3MauType
OBJECT IDENTIFIER ::= { snmpDot3MauMgt 4 }-
dot3MauTypeAUI OBJECT-IDENTITY
STATUS current DESCRIPTION "no internal MAU, view from AUI" ::= { dot3MauType 1 } dot3MauType10Base5 OBJECT-IDENTITY STATUS current DESCRIPTION "thick coax MAU (per 802.3 section 8)" ::= { dot3MauType 2 } dot3MauTypeFoirl OBJECT-IDENTITY STATUS current DESCRIPTION "FOIRL MAU (per 802.3 section 9.9)" ::= { dot3MauType 3 }-
dot3MauType10Base2 OBJECT-IDENTITY
STATUS current DESCRIPTION "thin coax MAU (per 802.3 section 10)" ::= { dot3MauType 4 }-
dot3MauType10BaseT OBJECT-IDENTITY
STATUS current DESCRIPTION "UTP MAU (per 802.3 section 14). Note that it is strongly recommended that agents return either dot3MauType10BaseTHD or dot3MauType10BaseTFD if the duplex mode is known. However, management applications should be prepared to receive this MAU type value from older agent implementations." ::= { dot3MauType 5 }-
dot3MauType10BaseFP OBJECT-IDENTITY
STATUS current DESCRIPTION "passive fiber MAU (per 802.3 section 16)" ::= { dot3MauType 6 }-
dot3MauType10BaseFB OBJECT-IDENTITY
STATUS current DESCRIPTION "sync fiber MAU (per 802.3 section 17)" ::= { dot3MauType 7 }-
dot3MauType10BaseFL OBJECT-IDENTITY
STATUS current DESCRIPTION "async fiber MAU (per 802.3 section 18) Note that it is strongly recommended that agents return either dot3MauType10BaseFLHD or dot3MauType10BaseFLFD if the duplex mode is known. However, management applications should be prepared to receive this MAU type value from older agent implementations." ::= { dot3MauType 8 } dot3MauType10Broad36 OBJECT-IDENTITY STATUS current DESCRIPTION "broadband DTE MAU (per 802.3 section 11). Note that 10BROAD36 MAUs can be attached to interfaces but not to repeaters." ::= { dot3MauType 9 } ------ new since RFC 1515: dot3MauType10BaseTHD OBJECT-IDENTITY STATUS current DESCRIPTION "UTP MAU (per 802.3 section 14), half duplex mode" ::= { dot3MauType 10 }-
dot3MauType10BaseTFD OBJECT-IDENTITY
STATUS current DESCRIPTION "UTP MAU (per 802.3 section 14), full duplex mode" ::= { dot3MauType 11 }-
dot3MauType10BaseFLHD OBJECT-IDENTITY
STATUS current DESCRIPTION "async fiber MAU (per 802.3 section 18), half duplex mode" ::= { dot3MauType 12 }-
dot3MauType10BaseFLFD OBJECT-IDENTITY
STATUS current DESCRIPTION "async fiber MAU (per 802.3 section 18), full duplex mode" ::= { dot3MauType 13 }-
dot3MauType100BaseT4 OBJECT-IDENTITY
STATUS current DESCRIPTION "4 pair categ. 3 UTP (per 802.3 section 23)" ::= { dot3MauType 14 }-
dot3MauType100BaseTXHD OBJECT-IDENTITY
STATUS current DESCRIPTION "2 pair categ. 5 UTP (per 802.3 section 25), half duplex mode" ::= { dot3MauType 15 }-
dot3MauType100BaseTXFD OBJECT-IDENTITY
STATUS current DESCRIPTION "2 pair categ. 5 UTP (per 802.3 section 25), full duplex mode" ::= { dot3MauType 16 } dot3MauType100BaseFXHD OBJECT-IDENTITY STATUS current DESCRIPTION "X fiber over PMT (per 802.3 section 26), half duplex mode" ::= { dot3MauType 17 } dot3MauType100BaseFXFD OBJECT-IDENTITY STATUS current DESCRIPTION "X fiber over PMT (per 802.3 section 26), full duplex mode" ::= { dot3MauType 18 }-
dot3MauType100BaseT2HD OBJECT-IDENTITY
STATUS current DESCRIPTION "2 pair categ. 3 UTP (per 802.3 section 32), half duplex mode" ::= { dot3MauType 19 }-
dot3MauType100BaseT2FD OBJECT-IDENTITY
STATUS current DESCRIPTION "2 pair categ. 3 UTP (per 802.3 section 32), full duplex mode" ::= { dot3MauType 20 } ------ new since RFC 2239:-
dot3MauType1000BaseXHD OBJECT-IDENTITY
STATUS current DESCRIPTION "PCS/PMA (per 802.3 section 36), unknown PMD, half duplex mode" ::= { dot3MauType 21 }-
dot3MauType1000BaseXFD OBJECT-IDENTITY
STATUS current DESCRIPTION "PCS/PMA (per 802.3 section 36), unknown PMD, full duplex mode" ::= { dot3MauType 22 }-
dot3MauType1000BaseLXHD OBJECT-IDENTITY
STATUS current DESCRIPTION "Fiber over long-wavelength laser (per 802.3 section 38), half duplex mode" ::= { dot3MauType 23 }-
dot3MauType1000BaseLXFD OBJECT-IDENTITY
STATUS current DESCRIPTION "Fiber over long-wavelength laser (per 802.3 section 38), full duplex mode" ::= { dot3MauType 24 }-
dot3MauType1000BaseSXHD OBJECT-IDENTITY
STATUS current DESCRIPTION "Fiber over short-wavelength laser (per 802.3 section 38), half duplex mode" ::= { dot3MauType 25 }-
dot3MauType1000BaseSXFD OBJECT-IDENTITY
STATUS current DESCRIPTION "Fiber over short-wavelength laser (per 802.3 section 38), full duplex mode" ::= { dot3MauType 26 }-
dot3MauType1000BaseCXHD OBJECT-IDENTITY
STATUS current DESCRIPTION "Copper over 150-Ohm balanced cable (per 802.3 section 39), half duplex mode" ::= { dot3MauType 27 }-
dot3MauType1000BaseCXFD OBJECT-IDENTITY
STATUS current DESCRIPTION "Copper over 150-Ohm balanced cable (per 802.3 section 39), full duplex mode" ::= { dot3MauType 28 }-
dot3MauType1000BaseTHD OBJECT-IDENTITY
STATUS current DESCRIPTION "Four-pair Category 5 UTP (per 802.3 section 40), half duplex mode" ::= { dot3MauType 29 }-
dot3MauType1000BaseTFD OBJECT-IDENTITY
STATUS current DESCRIPTION "Four-pair Category 5 UTP (per 802.3 section 40), full duplex mode" ::= { dot3MauType 30 } -- -- The Basic Repeater MAU Table ---
rpMauTable OBJECT-TYPE
SYNTAX SEQUENCE OF RpMauEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table of descriptive and status information about the MAU(s) attached to the ports of a repeater." ::= { dot3RpMauBasicGroup 1 }-
rpMauEntry OBJECT-TYPE
SYNTAX RpMauEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the table, containing information about a single MAU." INDEX { rpMauGroupIndex, rpMauPortIndex, rpMauIndex } ::= { rpMauTable 1 } RpMauEntry ::= SEQUENCE { rpMauGroupIndex Integer32, rpMauPortIndex Integer32, rpMauIndex Integer32, rpMauType OBJECT IDENTIFIER, rpMauStatus INTEGER, rpMauMediaAvailable INTEGER, rpMauMediaAvailableStateExits Counter32, rpMauJabberState INTEGER, rpMauJabberingStateEnters Counter32, rpMauFalseCarriers Counter32 }-
rpMauGroupIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS read-only STATUS current DESCRIPTION "This variable uniquely identifies the group containing the port to which the MAU described by this entry is connected. Note: In practice, a group will generally be a field-replaceable unit (i.e., module, card, or board) that can fit in the physical system enclosure, and the group number will correspond to a number marked on the physical enclosure. The group denoted by a particular value of this object is the same as the group denoted by the same value of rptrGroupIndex." REFERENCE "Reference RFC 2108, rptrGroupIndex." ::= { rpMauEntry 1 }-
rpMauPortIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS read-only STATUS current DESCRIPTION "This variable uniquely identifies the repeater port within group rpMauGroupIndex to which the MAU described by this entry is connected." REFERENCE "Reference RFC 2108, rptrPortIndex." ::= { rpMauEntry 2 }-
rpMauIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS read-only STATUS current DESCRIPTION "This variable uniquely identifies the MAU described by this entry from among other MAUs connected to the same port (rpMauPortIndex)." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.1, aMAUID." ::= { rpMauEntry 3 }-
rpMauType OBJECT-TYPE
SYNTAX OBJECT IDENTIFIER MAX-ACCESS read-only STATUS current DESCRIPTION "This object identifies the MAU type. An initial set of MAU types are defined above. The assignment of OBJECT IDENTIFIERs to new types of MAUs is managed by the IANA. If the MAU type is unknown, the object identifier unknownMauType OBJECT IDENTIFIER ::= { 0 0 } is returned. Note that unknownMauType is a syntactically valid object identifier, and any conformant implementation of ASN.1 and the BER must be able to generate and recognize this value." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.2, aMAUType." ::= { rpMauEntry 4 }-
rpMauStatus OBJECT-TYPE
SYNTAX INTEGER { other(1), unknown(2), operational(3), standby(4), shutdown(5), reset(6) } MAX-ACCESS read-write STATUS current DESCRIPTION "The current state of the MAU. This object MAY be implemented as a read-only object by those agents and MAUs that do not implement software control of the MAU state. Some agents may not support setting the value of this object to some of the enumerated values.-
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The value other(1) is returned if the MAU is in a state other than one of the states 2 through 6.
The value unknown(2) is returned when the MAU's true state is unknown; for example, when it is being initialized.
A MAU in the operational(3) state is fully functional, operates, and passes signals to its attached DTE or repeater port in accordance to its specification.
A MAU in standby(4) state forces DI and CI to idle and the media transmitter to idle or fault, if supported. Standby(4) mode only applies to link type MAUs. The state of rpMauMediaAvailable is unaffected.
A MAU in shutdown(5) state assumes the same condition on DI, CI, and the media transmitter as though it were powered down or not connected. The MAU MAY return other(1) value for the rpMauJabberState and rpMauMediaAvailable objects when it is in this state. For an AUI, this state will remove power from the AUI.
Setting this variable to the value reset(6) resets the MAU in the same manner as a power-off, power-on cycle of at least one-half second would. The agent is not required to return the value reset (6).
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Setting this variable to the value operational(3), standby(4), or shutdown(5) causes the MAU to assume the respective state except that setting a mixing-type MAU or an AUI to standby(4) will cause the MAU to enter the shutdown state." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.7, aMAUAdminState, 30.5.1.2.2, acMAUAdminControl, and 30.5.1.2.1, acResetMAU." ::= { rpMauEntry 5 }-
rpMauMediaAvailable OBJECT-TYPE
SYNTAX INTEGER { other(1), unknown(2), available(3), notAvailable(4), remoteFault(5), invalidSignal(6), remoteJabber(7), remoteLinkLoss(8), remoteTest(9), offline(10), autoNegError(11) } MAX-ACCESS read-only STATUS current DESCRIPTION "If the MAU is a link or fiber type (FOIRL, 10BASE-T, 10BASE-F) then this is equivalent to the link test fail state/low light function. For an AUI or a coax (including broadband) MAU this indicates whether or not loopback is detected on the DI circuit. The value of this attribute persists between packets for MAU types AUI, 10BASE5, 10BASE2, 10BROAD36, and 10BASE-FP.-
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The value other(1) is returned if the mediaAvailable state is not one of 2 through 11.
The value unknown(2) is returned when the MAU's true state is unknown; for example, when it is being initialized. At power-up or following a reset, the value of this attribute will be unknown for AUI, coax, and 10BASE-FP MAUs. For these MAUs loopback will be tested on each transmission during which no collision is detected. If DI is receiving input when DO returns to IDL after a transmission and there has been no collision during the transmission then loopback will be detected. The value of this attribute will only change during non-collided transmissions for AUI, coax, and 10BASE-FP MAUs.
For 100Mbps and 1000Mbps MAUs, the enumerations match the states within the respective link integrity state diagrams, fig 32-16, 23-12 and 24-15 of sections 32, 23 and 24 of [16]. Any MAU which implements management of auto-negotiation will map remote fault indication to remote fault.
The value available(3) indicates that the link, light, or loopback is normal. The value notAvailable(4) indicates link loss, low light, or no loopback.
The value remoteFault(5) indicates that a fault has been detected at the remote end of the link. This value applies to 10BASE-FB, 100BASE-T4 Far End Fault Indication and non-specified remote faults from a system running auto-negotiation. The values remoteJabber(7), remoteLinkLoss(8), and remoteTest(9) SHOULD be used instead of remoteFault(5) where the reason for remote fault is identified in the remote signaling protocol.
The value invalidSignal(6) indicates that an invalid signal has been received from the other end of the link. InvalidSignal(6) applies only to MAUs of type 10BASE-FB.
Where an IEEE Std 802.3u-1995 clause 22 MII is present, a logic one in the remote fault bit (reference section 22.2.4.2.8 of that document) maps to the value remoteFault(5), and a logic zero in the link status bit (reference section 22.2.4.2.10 of that document) maps to the value notAvailable(4). The value notAvailable(4) takes precedence over the value remoteFault(5).
Any MAU that implements management of clause 37 Auto-Negotiation will map the received Remote Fault (RF1 and RF2) bit values for Offline to offline(10), Link Failure to remoteFault(5) and Auto-Negotiation Error to autoNegError(11)."
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REFERENCE "[IEEE 802.3 Std], 30.5.1.1.4, aMediaAvailable." ::= { rpMauEntry 6 }-
rpMauMediaAvailableStateExits OBJECT-TYPE
SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "A count of the number of times that rpMauMediaAvailable for this MAU instance leaves the state available(3). Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of rptrMonitorPortLastChange." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.5, aLoseMediaCounter. RFC 2108, rptrMonitorPortLastChange" ::= { rpMauEntry 7 }-
rpMauJabberState OBJECT-TYPE
SYNTAX INTEGER { other(1), unknown(2), noJabber(3), jabbering(4) } MAX-ACCESS read-only STATUS current DESCRIPTION "The value other(1) is returned if the jabber state is not 2, 3, or 4. The agent MUST always return other(1) for MAU type dot3MauTypeAUI.-
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The value unknown(2) is returned when the MAU's true state is unknown; for example, when it is being initialized.
If the MAU is not jabbering the agent returns noJabber(3). This is the 'normal' state.
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If the MAU is in jabber state the agent returns the jabbering(4) value." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.6, aJabber.jabberFlag." ::= { rpMauEntry 8 }-
rpMauJabberingStateEnters OBJECT-TYPE
SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "A count of the number of times that mauJabberState for this MAU instance enters the state jabbering(4). For MAUs of type dot3MauTypeAUI, dot3MauType100BaseT4, dot3MauType100BaseTX, dot3MauType100BaseFX and all 1000Mbps types, this counter will always indicate zero. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of rptrMonitorPortLastChange." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.6, aJabber.jabberCounter. RFC 2108, rptrMonitorPortLastChange" ::= { rpMauEntry 9 }-
rpMauFalseCarriers OBJECT-TYPE
SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "A count of the number of false carrier events during IDLE in 100BASE-X links. This counter does not increment at the symbol rate. It can increment after a valid carrier completion at a maximum rate of once per 100 ms until the next carrier event.-
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This counter increments only for MAUs of type dot3MauType100BaseT4, dot3MauType100BaseTX, and dot3MauType100BaseFX and all 1000Mbps types. For all other MAU types, this counter will always indicate zero.
The approximate minimum time for rollover of this counter is 7.4 hours.
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Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of rptrMonitorPortLastChange." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.10, aFalseCarriers. RFC 2108, rptrMonitorPortLastChange" ::= { rpMauEntry 10 }-
-- The rpJackTable applies to MAUs attached to repeaters -- which have one or more external jacks (connectors).
rpJackTable OBJECT-TYPE
SYNTAX SEQUENCE OF RpJackEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Information about the external jacks attached to MAUs attached to the ports of a repeater." ::= { dot3RpMauBasicGroup 2 }-
rpJackEntry OBJECT-TYPE
SYNTAX RpJackEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the table, containing information about a particular jack." INDEX { rpMauGroupIndex, rpMauPortIndex, rpMauIndex, rpJackIndex } ::= { rpJackTable 1 }-
RpJackEntry ::=
SEQUENCE { rpJackIndex Integer32, rpJackType JackType }-
rpJackIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS not-accessible STATUS current DESCRIPTION "This variable uniquely identifies the jack described by this entry from among other jacks attached to the same MAU (rpMauIndex)." ::= { rpJackEntry 1 }-
rpJackType OBJECT-TYPE
SYNTAX JackType MAX-ACCESS read-only STATUS current DESCRIPTION "The jack connector type, as it appears on the outside of the system." ::= { rpJackEntry 2 } -- -- The Basic Interface MAU Table ---
ifMauTable OBJECT-TYPE
SYNTAX SEQUENCE OF IfMauEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table of descriptive and status information about MAU(s) attached to an interface." ::= { dot3IfMauBasicGroup 1 }-
ifMauEntry OBJECT-TYPE
SYNTAX IfMauEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the table, containing information about a single MAU." INDEX { ifMauIfIndex, ifMauIndex } ::= { ifMauTable 1 }-
IfMauEntry ::=
SEQUENCE { ifMauIfIndex Integer32, ifMauIndex Integer32, ifMauType OBJECT IDENTIFIER, ifMauStatus INTEGER, ifMauMediaAvailable INTEGER, ifMauMediaAvailableStateExits Counter32, ifMauJabberState INTEGER, ifMauJabberingStateEnters Counter32, ifMauFalseCarriers Counter32, ifMauTypeList Integer32, ifMauDefaultType OBJECT IDENTIFIER, ifMauAutoNegSupported TruthValue, ifMauTypeListBits BITS }-
ifMauIfIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS read-only STATUS current DESCRIPTION "This variable uniquely identifies the interface to which the MAU described by this entry is connected." REFERENCE "RFC 1213, ifIndex" ::= { ifMauEntry 1 }-
ifMauIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS read-only STATUS current DESCRIPTION "This variable uniquely identifies the MAU described by this entry from among other MAUs connected to the same interface (ifMauIfIndex)." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.1, aMAUID." ::= { ifMauEntry 2 }-
ifMauType OBJECT-TYPE
SYNTAX OBJECT IDENTIFIER MAX-ACCESS read-only STATUS current DESCRIPTION "This object identifies the MAU type. An initial set of MAU types are defined above. The assignment of OBJECT IDENTIFIERs to new types of-
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MAUs is managed by the IANA. If the MAU type is unknown, the object identifier
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unknownMauType OBJECT IDENTIFIER ::= { 0 0 }-
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is returned. Note that unknownMauType is a syntactically valid object identifier, and any conformant implementation of ASN.1 and the BER must be able to generate and recognize this value.
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This object represents the operational type of the MAU, as determined by either (1) the result of the auto-negotiation function or (2) if auto-negotiation is not enabled or is not implemented for this MAU, by the value of the object ifMauDefaultType. In case (2), a set to the object ifMauDefaultType will force the MAU into the new operating mode." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.2, aMAUType." ::= { ifMauEntry 3 }-
ifMauStatus OBJECT-TYPE
SYNTAX INTEGER { other(1), unknown(2), operational(3), standby(4), shutdown(5), reset(6) } MAX-ACCESS read-write STATUS current DESCRIPTION "The current state of the MAU. This object MAY be implemented as a read-only object by those agents and MAUs that do not implement software control of the MAU state. Some agents may not support setting the value of this object to some of the enumerated values.-
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The value other(1) is returned if the MAU is in a state other than one of the states 2 through 6.
The value unknown(2) is returned when the MAU's true state is unknown; for example, when it is being initialized.
A MAU in the operational(3) state is fully functional, operates, and passes signals to its attached DTE or repeater port in accordance to its specification.
A MAU in standby(4) state forces DI and CI to idle and the media transmitter to idle or fault, if supported. Standby(4) mode only applies to link type MAUs. The state of ifMauMediaAvailable is unaffected.
A MAU in shutdown(5) state assumes the same condition on DI, CI, and the media transmitter as though it were powered down or not connected. The MAU MAY return other(1) value for the ifMauJabberState and ifMauMediaAvailable objects when it is in this state. For an AUI, this state will remove power from the AUI.
Setting this variable to the value reset(6) resets the MAU in the same manner as a power-off, power-on cycle of at least one-half second would. The agent is not required to return the value reset (6).
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Setting this variable to the value operational(3), standby(4), or shutdown(5) causes the MAU to assume the respective state except that setting a mixing-type MAU or an AUI to standby(4) will cause the MAU to enter the shutdown state." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.7, aMAUAdminState, 30.5.1.2.2, acMAUAdminControl, and 30.5.1.2.1, acResetMAU." ::= { ifMauEntry 4 } ifMauMediaAvailable OBJECT-TYPE SYNTAX INTEGER { other(1), unknown(2), available(3), notAvailable(4), remoteFault(5), invalidSignal(6), remoteJabber(7), remoteLinkLoss(8), remoteTest(9), offline(10), autoNegError(11) } MAX-ACCESS read-only STATUS current DESCRIPTION "If the MAU is a link or fiber type (FOIRL, 10BASE-T, 10BASE-F) then this is equivalent to the link test fail state/low light function. For an AUI or a coax (including broadband) MAU this indicates whether or not loopback is detected on the DI circuit. The value of this attribute persists between packets for MAU types AUI, 10BASE5, 10BASE2, 10BROAD36, and 10BASE-FP.-
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The value other(1) is returned if the mediaAvailable state is not one of 2 through 11.
The value unknown(2) is returned when the MAU's true state is unknown; for example, when it is being initialized. At power-up or following a reset, the value of this attribute will be unknown for AUI, coax, and 10BASE-FP MAUs. For these MAUs loopback will be tested on each transmission during which no collision is detected. If DI is receiving input when DO returns to IDL after a transmission and there has been no collision during the transmission then loopback will be detected. The value of this attribute will only change during non-collided transmissions for AUI, coax, and 10BASE-FP MAUs.
For 100Mbps and 1000Mbps MAUs, the enumerations match the states within the respective link integrity state diagrams, fig 32-16, 23-12 and 24-15 of sections 32, 23 and 24 of [16]. Any MAU which implements management of auto-negotiation will map remote fault indication to remote fault.
The value available(3) indicates that the link, light, or loopback is normal. The value notAvailable(4) indicates link loss, low light, or no loopback.
The value remoteFault(5) indicates that a fault has been detected at the remote end of the link. This value applies to 10BASE-FB, 100BASE-T4 Far End Fault Indication and non-specified remote faults from a system running auto-negotiation.
The values remoteJabber(7), remoteLinkLoss(8), and remoteTest(9) SHOULD be used instead of remoteFault(5) where the reason for remote fault is identified in the remote signaling protocol.
The value invalidSignal(6) indicates that an invalid signal has been received from the other end of the link. InvalidSignal(6) applies only to MAUs of type 10BASE-FB.
Where an IEEE Std 802.3u-1995 clause 22 MII is present, a logic one in the remote fault bit (reference section 22.2.4.2.8 of that document) maps to the value remoteFault(5), and a logic zero in the link status bit (reference section 22.2.4.2.10 of that document) maps to the value notAvailable(4). The value notAvailable(4) takes precedence over the value remoteFault(5).
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Any MAU that implements management of clause 37 Auto-Negotiation will map the received RF1 and RF2 bit values for Offline to offline(10), Link Failure to remoteFault(5) and Auto-Negotiation Error to autoNegError(11)." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.4, aMediaAvailable." ::= { ifMauEntry 5 }-
ifMauMediaAvailableStateExits OBJECT-TYPE
SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "A count of the number of times that ifMauMediaAvailable for this MAU instance leaves the state available(3). Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ifCounterDiscontinuityTime." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.5, aLoseMediaCounter. RFC 2233, ifCounterDiscontinuityTime." ::= { ifMauEntry 6 }-
ifMauJabberState OBJECT-TYPE
SYNTAX INTEGER { other(1), unknown(2), noJabber(3), jabbering(4) } MAX-ACCESS read-only STATUS current DESCRIPTION "The value other(1) is returned if the jabber state is not 2, 3, or 4. The agent MUST always return other(1) for MAU type dot3MauTypeAUI.-
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The value unknown(2) is returned when the MAU's true state is unknown; for example, when it is being initialized.
If the MAU is not jabbering the agent returns noJabber(3). This is the 'normal' state.
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If the MAU is in jabber state the agent returns the jabbering(4) value." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.6, aJabber.jabberFlag." ::= { ifMauEntry 7 }-
ifMauJabberingStateEnters OBJECT-TYPE
SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "A count of the number of times that mauJabberState for this MAU instance enters the state jabbering(4). This counter will always indicate zero for MAUs of type dot1MauTypeAUI and those of speeds above 10Mbps. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ifCounterDiscontinuityTime." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.6, aJabber.jabberCounter. RFC 2233, ifCounterDiscontinuityTime." ::= { ifMauEntry 8 }-
ifMauFalseCarriers OBJECT-TYPE
SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "A count of the number of false carrier events during IDLE in 100BASE-X and 1000BASE-X links.-
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For all other MAU types, this counter will always indicate zero. This counter does not increment at the symbol rate.
It can increment after a valid carrier completion at a maximum rate of once per 100 ms for 100BASE-X and once per 10us for 1000BASE-X until the next CarrierEvent.
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Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times as indicated by the value of ifCounterDiscontinuityTime." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.10, aFalseCarriers. RFC 2233, ifCounterDiscontinuityTime." ::= { ifMauEntry 9 }-
ifMauTypeList OBJECT-TYPE
SYNTAX Integer32 MAX-ACCESS read-only STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED **********-
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A value that uniquely identifies the set of possible IEEE 802.3 types that the MAU could be. The value is a sum which initially takes the value zero. Then, for each type capability of this MAU, 2 raised to the power noted below is added to the sum. For example, a MAU which has the capability to be only 10BASE-T would have a value of 512 (2**9). In contrast, a MAU which supports both 10Base-T (full duplex) and 100BASE-TX (full duplex) would have a value of ((2**11) + (2**16)) or 67584.
The powers of 2 assigned to the capabilities are these:
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Power Capability 0 other or unknown 1 AUI 2 10BASE-5 3 FOIRL 4 10BASE-2 5 10BASE-T duplex mode unknown 6 10BASE-FP 7 10BASE-FB 8 10BASE-FL duplex mode unknown 9 10BROAD36 10 10BASE-T half duplex mode 11 10BASE-T full duplex mode 12 10BASE-FL half duplex mode 13 10BASE-FL full duplex mode 14 100BASE-T4 15 100BASE-TX half duplex mode 16 100BASE-TX full duplex mode 17 100BASE-FX half duplex mode 18 100BASE-FX full duplex mode 19 100BASE-T2 half duplex mode 20 100BASE-T2 full duplex mode-
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If auto-negotiation is present on this MAU, this object will map to ifMauAutoNegCapability.
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This object has been deprecated in favour of ifMauTypeListBits." ::= { ifMauEntry 10 }-
ifMauDefaultType OBJECT-TYPE
SYNTAX OBJECT IDENTIFIER MAX-ACCESS read-write STATUS current DESCRIPTION "This object identifies the default administrative baseband MAU type, to be used in conjunction with the operational MAU type denoted by ifMauType.-
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The set of possible values for this object is the same as the set defined for the ifMauType object.
This object represents the administratively-configured type of the MAU. If auto-negotiation is not enabled or is not implemented for this MAU, the value of this object determines the operational type of the MAU. In this case, a set to this object will force the MAU into the specified operating mode.
If auto-negotiation is implemented and enabled for this MAU, the operational type of the MAU is determined by auto-negotiation, and the value of this object denotes the type to which the MAU will automatically revert if/when auto-negotiation is later disabled.
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NOTE TO IMPLEMENTORS: It may be necessary to provide for underlying hardware implementations which do not follow the exact behavior specified above. In particular, when ifMauAutoNegAdminStatus transitions from enabled to disabled, the agent implementation MUST ensure that the operational type of the MAU (as reported by ifMauType) correctly transitions to the value specified by this object, rather than continuing to operate at the value earlier determined by the auto-negotiation function." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.1, aMAUID, and 22.2.4.1.4." ::= { ifMauEntry 11 }-
ifMauAutoNegSupported OBJECT-TYPE
SYNTAX TruthValue MAX-ACCESS read-only STATUS current DESCRIPTION "This object indicates whether or not auto-negotiation is supported on this MAU." ::= { ifMauEntry 12 }-
ifMauTypeListBits OBJECT-TYPE
SYNTAX BITS { bOther(0), -- other or unknown bAUI(1), -- AUI b10base5(2), -- 10BASE-5 bFoirl(3), -- FOIRL b10base2(4), -- 10BASE-2 b10baseT(5), -- 10BASE-T duplex mode unknown b10baseFP(6), -- 10BASE-FP b10baseFB(7), -- 10BASE-FB b10baseFL(8), -- 10BASE-FL duplex mode unknown b10broad36(9), -- 10BROAD36 b10baseTHD(10), -- 10BASE-T half duplex mode b10baseTFD(11), -- 10BASE-T full duplex mode b10baseFLHD(12), -- 10BASE-FL half duplex mode b10baseFLFD(13), -- 10BASE-FL full duplex mode b100baseT4(14), -- 100BASE-T4 b100baseTXHD(15), -- 100BASE-TX half duplex mode b100baseTXFD(16), -- 100BASE-TX full duplex mode b100baseFXHD(17), -- 100BASE-FX half duplex mode b100baseFXFD(18), -- 100BASE-FX full duplex mode b100baseT2HD(19), -- 100BASE-T2 half duplex mode b100baseT2FD(20), -- 100BASE-T2 full duplex mode b1000baseXHD(21), -- 1000BASE-X half duplex mode b1000baseXFD(22), -- 1000BASE-X full duplex mode b1000baseLXHD(23), -- 1000BASE-LX half duplex mode b1000baseLXFD(24), -- 1000BASE-LX full duplex mode b1000baseSXHD(25), -- 1000BASE-SX half duplex mode b1000baseSXFD(26), -- 1000BASE-SX full duplex mode b1000baseCXHD(27), -- 1000BASE-CX half duplex mode b1000baseCXFD(28), -- 1000BASE-CX full duplex mode b1000baseTHD(29), -- 1000BASE-T half duplex mode b1000baseTFD(30) -- 1000BASE-T full duplex mode } MAX-ACCESS read-only STATUS current DESCRIPTION "A value that uniquely identifies the set of possible IEEE 802.3 types that the MAU could be. If auto-negotiation is present on this MAU, this object will map to ifMauAutoNegCapability. Note that this MAU may be capable of operating as a MAU type that is beyond the scope of this MIB. This is indicated by returning the bit value bOther in addition to any bit values for capabilities that are listed above." ::= { ifMauEntry 13 }-
-- The ifJackTable applies to MAUs attached to interfaces -- which have one or more external jacks (connectors).
ifJackTable OBJECT-TYPE
SYNTAX SEQUENCE OF IfJackEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Information about the external jacks attached to MAUs attached to an interface." ::= { dot3IfMauBasicGroup 2 }-
ifJackEntry OBJECT-TYPE
SYNTAX IfJackEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the table, containing information about a particular jack." INDEX { ifMauIfIndex, ifMauIndex, ifJackIndex } ::= { ifJackTable 1 }-
IfJackEntry ::=
SEQUENCE { ifJackIndex Integer32, ifJackType JackType }-
ifJackIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS not-accessible STATUS current DESCRIPTION "This variable uniquely identifies the jack described by this entry from among other jacks attached to the same MAU." ::= { ifJackEntry 1 }-
ifJackType OBJECT-TYPE
SYNTAX JackType MAX-ACCESS read-only STATUS current DESCRIPTION "The jack connector type, as it appears on the outside of the system." ::= { ifJackEntry 2 }-
-- The ifMauAutoNegTable applies to systems in which -- auto-negotiation is supported on one or more MAUs -- attached to interfaces. Note that if auto-negotiation -- is present and enabled, the ifMauType object reflects -- the result of the auto-negotiation function.
ifMauAutoNegTable OBJECT-TYPE
SYNTAX SEQUENCE OF IfMauAutoNegEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Configuration and status objects for the auto-negotiation function of MAUs attached to interfaces." ::= { dot3IfMauAutoNegGroup 1 }-
ifMauAutoNegEntry OBJECT-TYPE
SYNTAX IfMauAutoNegEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the table, containing configuration and status information for the auto-negotiation function of a particular MAU." INDEX { ifMauIfIndex, ifMauIndex } ::= { ifMauAutoNegTable 1 }-
IfMauAutoNegEntry ::=
SEQUENCE { ifMauAutoNegAdminStatus INTEGER, ifMauAutoNegRemoteSignaling INTEGER, ifMauAutoNegConfig INTEGER, ifMauAutoNegCapability Integer32, ifMauAutoNegCapAdvertised Integer32, ifMauAutoNegCapReceived Integer32, ifMauAutoNegRestart INTEGER, ifMauAutoNegCapabilityBits BITS, ifMauAutoNegCapAdvertisedBits BITS, ifMauAutoNegCapReceivedBits BITS, ifMauAutoNegRemoteFaultAdvertised INTEGER, ifMauAutoNegRemoteFaultReceived INTEGER }-
ifMauAutoNegAdminStatus OBJECT-TYPE
SYNTAX INTEGER { enabled(1), disabled(2) } MAX-ACCESS read-write STATUS current DESCRIPTION "Setting this object to enabled(1) will cause the interface which has the auto-negotiation signaling ability to be enabled.-
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If the value of this object is disabled(2) then the interface will act as it would if it had no auto-negotiation signaling. Under these conditions, an IEEE 802.3 MAU will immediately be forced to the state indicated by the value of the object ifMauDefaultType.
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NOTE TO IMPLEMENTORS: When ifMauAutoNegAdminStatus transitions from enabled to disabled, the agent implementation MUST ensure that the operational type of the MAU (as reported by ifMauType) correctly transitions to the value specified by the ifMauDefaultType object, rather than continuing to operate at the value earlier determined by the auto-negotiation function." REFERENCE "[IEEE 802.3 Std], 30.6.1.1.2, aAutoNegAdminState and 30.6.1.2.2, acAutoNegAdminControl." ::= { ifMauAutoNegEntry 1 }-
ifMauAutoNegRemoteSignaling OBJECT-TYPE
SYNTAX INTEGER { detected(1), notdetected(2) } MAX-ACCESS read-only STATUS current DESCRIPTION "A value indicating whether the remote end of the link is using auto-negotiation signaling. It takes the value detected(1) if and only if, during the previous link negotiation, FLP Bursts were received." REFERENCE "[IEEE 802.3 Std], 30.6.1.1.3, aAutoNegRemoteSignaling." ::= { ifMauAutoNegEntry 2 }-
ifMauAutoNegConfig OBJECT-TYPE
SYNTAX INTEGER { other(1), configuring(2), complete(3), disabled(4), parallelDetectFail(5) } MAX-ACCESS read-only STATUS current DESCRIPTION "A value indicating the current status of the auto-negotiation process. The enumeration parallelDetectFail(5) maps to a failure in parallel detection as defined in 28.2.3.1 of [IEEE 802.3 Std]." REFERENCE "[IEEE 802.3 Std], 30.6.1.1.4, aAutoNegAutoConfig." ::= { ifMauAutoNegEntry 4 }-
ifMauAutoNegCapability OBJECT-TYPE
SYNTAX Integer32 MAX-ACCESS read-only STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED **********-
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A value that uniquely identifies the set of capabilities of the local auto-negotiation entity. The value is a sum which initially takes the value zero. Then, for each capability of this interface, 2 raised to the power noted below is added to the sum. For example, an interface which has the capability to support only 100Base-TX half duplex would have a value of 32768 (2**15). In contrast, an interface which supports both 100Base-TX half duplex and and 100Base-TX full duplex would have a value of 98304 ((2**15) + (2**16)).
The powers of 2 assigned to the capabilities are these:
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Power Capability 0 other or unknown (1-9) (reserved) 10 10BASE-T half duplex mode 11 10BASE-T full duplex mode 12 (reserved) 13 (reserved) 14 100BASE-T4 15 100BASE-TX half duplex mode 16 100BASE-TX full duplex mode 17 (reserved) 18 (reserved) 19 100BASE-T2 half duplex mode 20 100BASE-T2 full duplex mode Note that interfaces that support this MIB may have capabilities that extend beyond the scope of this MIB. This object has been deprecated in favour of ifMauAutoNegCapabilityBits" REFERENCE "[IEEE 802.3 Std], 30.6.1.1.5, aAutoNegLocalTechnologyAbility." ::= { ifMauAutoNegEntry 5 }-
ifMauAutoNegCapAdvertised OBJECT-TYPE
SYNTAX Integer32 MAX-ACCESS read-write STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED **********-
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A value that uniquely identifies the set of capabilities advertised by the local auto-negotiation entity. Refer to ifMauAutoNegCapability for a description of the possible values of this object.
Capabilities in this object that are not available in ifMauAutoNegCapability cannot be enabled.
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This object has been deprecated in favour of ifMauAutoNegCapAdvertisedBits" REFERENCE "[IEEE 802.3 Std], 30.6.1.1.6, aAutoNegAdvertisedTechnologyAbility." ::= { ifMauAutoNegEntry 6 }-
ifMauAutoNegCapReceived OBJECT-TYPE
SYNTAX Integer32 MAX-ACCESS read-only STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED **********-
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A value that uniquely identifies the set of capabilities received from the remote auto-negotiation entity. Refer to ifMauAutoNegCapability for a description of the possible values of this object.
Note that interfaces that support this MIB may be attached to remote auto-negotiation entities which have capabilities beyond the scope of this MIB.
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This object has been deprecated in favour of ifMauAutoNegCapReceivedBits" REFERENCE "[IEEE 802.3 Std], 30.6.1.1.7, aAutoNegReceivedTechnologyAbility." ::= { ifMauAutoNegEntry 7 }-
ifMauAutoNegRestart OBJECT-TYPE
SYNTAX INTEGER { restart(1), norestart(2) } MAX-ACCESS read-write STATUS current DESCRIPTION "If the value of this object is set to restart(1) then this will force auto-negotiation to begin link renegotiation. If auto-negotiation signaling is disabled, a write to this object has no effect. Setting the value of this object to norestart(2) has no effect." REFERENCE "[IEEE 802.3 Std], 30.6.1.2.1, acAutoNegRestartAutoConfig." ::= { ifMauAutoNegEntry 8 }-
ifMauAutoNegCapabilityBits OBJECT-TYPE
SYNTAX BITS { bOther(0), -- other or unknown b10baseT(1), -- 10BASE-T half duplex mode b10baseTFD(2), -- 10BASE-T full duplex mode b100baseT4(3), -- 100BASE-T4 b100baseTX(4), -- 100BASE-TX half duplex mode b100baseTXFD(5), -- 100BASE-TX full duplex mode b100baseT2(6), -- 100BASE-T2 half duplex mode b100baseT2FD(7), -- 100BASE-T2 full duplex mode bfdxPause(8), -- PAUSE for full-duplex links bfdxAPause(9), -- Asymmetric PAUSE for full-duplex -- links bfdxSPause(10), -- Symmetric PAUSE for full-duplex -- links bfdxBPause(11), -- Asymmetric and Symmetric PAUSE for -- full-duplex links b1000baseX(12), -- 1000BASE-X, -LX, -SX, -CX half -- duplex mode b1000baseXFD(13), -- 1000BASE-X, -LX, -SX, -CX full -- duplex mode b1000baseT(14), -- 1000BASE-T half duplex mode b1000baseTFD(15) -- 1000BASE-T full duplex mode } MAX-ACCESS read-only STATUS current DESCRIPTION "A value that uniquely identifies the set of capabilities of the local auto-negotiation entity. Note that interfaces that support this MIB may have capabilities that extend beyond the scope of this MIB. Note that the local auto-negotiation entity may support some capabilities beyond the scope of this MIB. This is indicated by returning the bit value bOther in addition to any bit values for capabilities that are listed above." REFERENCE "[IEEE 802.3 Std], 30.6.1.1.5, aAutoNegLocalTechnologyAbility." ::= { ifMauAutoNegEntry 9 }-
ifMauAutoNegCapAdvertisedBits OBJECT-TYPE
SYNTAX BITS { bOther(0), -- other or unknown b10baseT(1), -- 10BASE-T half duplex mode b10baseTFD(2), -- 10BASE-T full duplex mode b100baseT4(3), -- 100BASE-T4 b100baseTX(4), -- 100BASE-TX half duplex mode b100baseTXFD(5), -- 100BASE-TX full duplex mode b100baseT2(6), -- 100BASE-T2 half duplex mode b100baseT2FD(7), -- 100BASE-T2 full duplex mode bFdxPause(8), -- PAUSE for full-duplex links bFdxAPause(9), -- Asymmetric PAUSE for full-duplex -- links bFdxSPause(10), -- Symmetric PAUSE for full-duplex -- links bFdxBPause(11), -- Asymmetric and Symmetric PAUSE for -- full-duplex links b1000baseX(12), -- 1000BASE-X, -LX, -SX, -CX half -- duplex mode b1000baseXFD(13), -- 1000BASE-X, -LX, -SX, -CX full -- duplex mode b1000baseT(14), -- 1000BASE-T half duplex mode b1000baseTFD(15) -- 1000BASE-T full duplex mode } MAX-ACCESS read-write STATUS current DESCRIPTION "A value that uniquely identifies the set of capabilities advertised by the local auto-negotiation entity. Capabilities in this object that are not available in ifMauAutoNegCapabilityBits cannot be enabled. Note that the local auto-negotiation entity may advertise some capabilities beyond the scope of this MIB. This is indicated by returning the bit value bOther in addition to any bit values for capabilities that are listed above." REFERENCE "[IEEE 802.3 Std], 30.6.1.1.6, aAutoNegAdvertisedTechnologyAbility." ::= { ifMauAutoNegEntry 10 }-
ifMauAutoNegCapReceivedBits OBJECT-TYPE
SYNTAX BITS { bOther(0), -- other or unknown b10baseT(1), -- 10BASE-T half duplex mode b10baseTFD(2), -- 10BASE-T full duplex mode b100baseT4(3), -- 100BASE-T4 b100baseTX(4), -- 100BASE-TX half duplex mode b100baseTXFD(5), -- 100BASE-TX full duplex mode b100baseT2(6), -- 100BASE-T2 half duplex mode b100baseT2FD(7), -- 100BASE-T2 full duplex mode bFdxPause(8), -- PAUSE for full-duplex links bFdxAPause(9), -- Asymmetric PAUSE for full-duplex -- links bFdxSPause(10), -- Symmetric PAUSE for full-duplex -- links bFdxBPause(11), -- Asymmetric and Symmetric PAUSE for -- full-duplex links b1000baseX(12), -- 1000BASE-X, -LX, -SX, -CX half -- duplex mode b1000baseXFD(13), -- 1000BASE-X, -LX, -SX, -CX full -- duplex mode b1000baseT(14), -- 1000BASE-T half duplex mode b1000baseTFD(15) -- 1000BASE-T full duplex mode } MAX-ACCESS read-only STATUS current DESCRIPTION "A value that uniquely identifies the set of capabilities received from the remote auto-negotiation entity. Note that interfaces that support this MIB may be attached to remote auto-negotiation entities which have capabilities beyond the scope of this MIB. This is indicated by returning the bit value bOther in addition to any bit values for capabilities that are listed above." REFERENCE "[IEEE 802.3 Std], 30.6.1.1.7, aAutoNegReceivedTechnologyAbility." ::= { ifMauAutoNegEntry 11 } ifMauAutoNegRemoteFaultAdvertised OBJECT-TYPE SYNTAX INTEGER { noError(1), offline(2), linkFailure(3), autoNegError(4) } MAX-ACCESS read-write STATUS current DESCRIPTION "A value that identifies any local fault indications that this MAU has detected and will advertise at the next auto-negotiation interaction for 1000Mbps MAUs." REFERENCE "[IEEE 802.3 Std], 30.6.1.1.6, aAutoNegAdvertisedTechnologyAbility." ::= { ifMauAutoNegEntry 12 }-
ifMauAutoNegRemoteFaultReceived OBJECT-TYPE
SYNTAX INTEGER { noError(1), offline(2), linkFailure(3), autoNegError(4) } MAX-ACCESS read-only STATUS current DESCRIPTION "A value that identifies any fault indications received from the far end of a link by the local auto-negotiation entity for 1000Mbps MAUs." REFERENCE "[IEEE 802.3 Std], 30.6.1.1.7, aAutoNegReceivedTechnologyAbility." ::= { ifMauAutoNegEntry 13 } -- -- The Basic Broadband MAU Table ---
broadMauBasicTable OBJECT-TYPE
SYNTAX SEQUENCE OF BroadMauBasicEntry MAX-ACCESS not-accessible STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED ********** Table of descriptive and status information about the broadband MAUs connected to interfaces." ::= { dot3BroadMauBasicGroup 1 }-
broadMauBasicEntry OBJECT-TYPE
SYNTAX BroadMauBasicEntry MAX-ACCESS not-accessible STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED ********** An entry in the table, containing information about a single broadband MAU." INDEX { broadMauIfIndex, broadMauIndex } ::= { broadMauBasicTable 1 }-
BroadMauBasicEntry ::=
-
SEQUENCE {
-
broadMauIfIndex Integer32,
broadMauIndex Integer32,
broadMauXmtRcvSplitType INTEGER,
broadMauXmtCarrierFreq Integer32,
broadMauTranslationFreq Integer32
}
-
-
broadMauIfIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS read-only STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED ********** This variable uniquely identifies the interface to which the MAU described by this entry is connected." REFERENCE "Reference RFC 1213, ifIndex." ::= { broadMauBasicEntry 1 }-
broadMauIndex OBJECT-TYPE
SYNTAX Integer32 (1..2147483647) MAX-ACCESS read-only STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED ********** This variable uniquely identifies the MAU connected to interface broadMauIfIndex that is described by this entry." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.1, aMAUID." ::= { broadMauBasicEntry 2 }-
broadMauXmtRcvSplitType OBJECT-TYPE
SYNTAX INTEGER { other(1), single(2), dual(3) } MAX-ACCESS read-only STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED **********-
-
-
-
-
This object indicates the type of frequency multiplexing/cabling system used to separate the transmit and receive paths for the 10BROAD36 MAU.
The value other(1) is returned if the split type is not either single or dual.
The value single(2) indicates a single cable system. The value dual(3) indicates a dual
-
-
-
-
cable system, offset normally zero." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.8, aBbMAUXmitRcvSplitType." ::= { broadMauBasicEntry 3 }-
broadMauXmtCarrierFreq OBJECT-TYPE
SYNTAX Integer32 MAX-ACCESS read-only STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED ********** This variable indicates the transmit carrier frequency of the 10BROAD36 MAU in MHz/4; that is, in units of 250 kHz." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.9, aBroadbandFrequencies.xmitCarrierFrequency." ::= { broadMauBasicEntry 4 }-
broadMauTranslationFreq OBJECT-TYPE
SYNTAX Integer32 MAX-ACCESS read-only STATUS deprecated DESCRIPTION "********* THIS OBJECT IS DEPRECATED ********** This variable indicates the translation offset frequency of the 10BROAD36 MAU in MHz/4; that is, in units of 250 kHz." REFERENCE "[IEEE 802.3 Std], 30.5.1.1.9, aBroadbandFrequencies.translationFrequency." ::= { broadMauBasicEntry 5 }-
-- Notifications for use by 802.3 MAUs
snmpDot3MauTraps OBJECT IDENTIFIER ::= { snmpDot3MauMgt 0 }-
rpMauJabberTrap NOTIFICATION-TYPE
OBJECTS { rpMauJabberState } STATUS current DESCRIPTION "This trap is sent whenever a managed repeater MAU enters the jabber state. The agent MUST throttle the generation of consecutive rpMauJabberTraps so that there is at least a five-second gap between them." REFERENCE "[IEEE 802.3 Mgt], 30.5.1.3.1, nJabber notification." ::= { snmpDot3MauTraps 1 }-
ifMauJabberTrap NOTIFICATION-TYPE
OBJECTS { ifMauJabberState } STATUS current DESCRIPTION "This trap is sent whenever a managed interface MAU enters the jabber state. The agent MUST throttle the generation of consecutive ifMauJabberTraps so that there is at least a five-second gap between them." REFERENCE "[IEEE 802.3 Mgt], 30.5.1.3.1, nJabber notification." ::= { snmpDot3MauTraps 2 } -- Conformance information mauModConf OBJECT IDENTIFIER ::= { mauMod 1 } mauModCompls OBJECT IDENTIFIER ::= { mauModConf 1 } mauModObjGrps OBJECT IDENTIFIER ::= { mauModConf 2 } mauModNotGrps OBJECT IDENTIFIER ::= { mauModConf 3 } -- Object groups-
mauRpGrpBasic OBJECT-GROUP
OBJECTS { rpMauGroupIndex, rpMauPortIndex, rpMauIndex, rpMauType, rpMauStatus, rpMauMediaAvailable, rpMauMediaAvailableStateExits, rpMauJabberState, rpMauJabberingStateEnters } STATUS current DESCRIPTION "Basic conformance group for MAUs attached to repeater ports. This group is also the conformance specification for RFC 1515 implementations." ::= { mauModObjGrps 1 }-
mauRpGrp100Mbs OBJECT-GROUP
OBJECTS { rpMauFalseCarriers } STATUS current DESCRIPTION "Conformance group for MAUs attached to repeater ports with 100 Mb/s or greater capability." ::= { mauModObjGrps 2 }-
mauRpGrpJack OBJECT-GROUP
OBJECTS { rpJackType } STATUS current DESCRIPTION "Conformance group for MAUs attached to repeater ports with managed jacks." ::= { mauModObjGrps 3 }-
mauIfGrpBasic OBJECT-GROUP
OBJECTS { ifMauIfIndex, ifMauIndex, ifMauType, ifMauStatus, ifMauMediaAvailable, ifMauMediaAvailableStateExits, ifMauJabberState, ifMauJabberingStateEnters } STATUS current DESCRIPTION "Basic conformance group for MAUs attached to interfaces. This group also provides a conformance specification for RFC 1515 implementations." ::= { mauModObjGrps 4 }-
mauIfGrp100Mbs OBJECT-GROUP
OBJECTS { ifMauFalseCarriers, ifMauTypeList, ifMauDefaultType, ifMauAutoNegSupported } STATUS deprecated DESCRIPTION "********* THIS GROUP IS DEPRECATED **********-
-
-
-
-
Conformance group for MAUs attached to interfaces with 100 Mb/s capability.
-
-
-
-
This object group has been deprecated in favor of mauIfGrpHighCapacity." ::= { mauModObjGrps 5 }-
mauIfGrpJack OBJECT-GROUP
OBJECTS { ifJackType } STATUS current DESCRIPTION "Conformance group for MAUs attached to interfaces with managed jacks." ::= { mauModObjGrps 6 }-
mauIfGrpAutoNeg OBJECT-GROUP
OBJECTS { ifMauAutoNegAdminStatus, ifMauAutoNegRemoteSignaling, ifMauAutoNegConfig, ifMauAutoNegCapability, ifMauAutoNegCapAdvertised, ifMauAutoNegCapReceived, ifMauAutoNegRestart } STATUS deprecated DESCRIPTION "********* THIS GROUP IS DEPRECATED **********-
-
-
-
-
Conformance group for MAUs attached to interfaces with managed auto-negotiation.
-
-
-
-
This object group has been deprecated in favor of mauIfGrpAutoNeg2." ::= { mauModObjGrps 7 }-
mauBroadBasic OBJECT-GROUP
OBJECTS { broadMauIfIndex, broadMauIndex, broadMauXmtRcvSplitType, broadMauXmtCarrierFreq, broadMauTranslationFreq } STATUS deprecated DESCRIPTION "********* THIS GROUP IS DEPRECATED **********-
-
-
-
-
Conformance group for broadband MAUs attached to interfaces.
-
-
-
-
This object group is deprecated. There have been no reported implementations of this group, and it was felt to be unlikely that there will be any future implementations." ::= { mauModObjGrps 8 }-
mauIfGrpHighCapacity OBJECT-GROUP
OBJECTS { ifMauFalseCarriers, ifMauTypeListBits, ifMauDefaultType, ifMauAutoNegSupported } STATUS current DESCRIPTION "Conformance group for MAUs attached to interfaces with 100 Mb/s or greater capability." ::= { mauModObjGrps 9 }-
mauIfGrpAutoNeg2 OBJECT-GROUP
OBJECTS { ifMauAutoNegAdminStatus, ifMauAutoNegRemoteSignaling, ifMauAutoNegConfig, ifMauAutoNegCapabilityBits, ifMauAutoNegCapAdvertisedBits, ifMauAutoNegCapReceivedBits, ifMauAutoNegRestart } STATUS current DESCRIPTION "Conformance group for MAUs attached to interfaces with managed auto-negotiation." ::= { mauModObjGrps 10 }-
mauIfGrpAutoNeg1000Mbps OBJECT-GROUP
OBJECTS { ifMauAutoNegRemoteFaultAdvertised, ifMauAutoNegRemoteFaultReceived } STATUS current DESCRIPTION "Conformance group for 1000Mbps MAUs attached to interfaces with managed auto-negotiation." ::= { mauModObjGrps 11 } -- Notification groups-
rpMauNotifications NOTIFICATION-GROUP
NOTIFICATIONS { rpMauJabberTrap } STATUS current DESCRIPTION "Notifications for repeater MAUs." ::= { mauModNotGrps 1 }-
ifMauNotifications NOTIFICATION-GROUP
NOTIFICATIONS { ifMauJabberTrap } STATUS current DESCRIPTION "Notifications for interface MAUs." ::= { mauModNotGrps 2 } -- Compliances-
mauModRpCompl MODULE-COMPLIANCE
STATUS deprecated DESCRIPTION "******** THIS COMPLIANCE IS DEPRECATED ********-
-
-
-
-
Compliance for MAUs attached to repeater ports.
This compliance is deprecated and replaced by mauModRpCompl2, which corrects an oversight by allowing rpMauStatus to be implemented read-only."
-
-
MODULE -- this module
-
MANDATORY-GROUPS { mauRpGrpBasic }
-
-
GROUP mauRpGrp100Mbs DESCRIPTION "Implementation of this optional group is recommended for MAUs which have 100Mb/s or greater capability." GROUP mauRpGrpJack DESCRIPTION "Implementation of this optional group is recommended for MAUs which have one or more external jacks." GROUP rpMauNotifications DESCRIPTION "Implementation of this group is recommended for MAUs attached to repeater ports." ::= { mauModCompls 1 }-
mauModIfCompl MODULE-COMPLIANCE
STATUS deprecated DESCRIPTION "******** THIS COMPLIANCE IS DEPRECATED ********-
-
-
-
-
Compliance for MAUs attached to interfaces.
This compliance is deprecated and replaced by mauModIfCompl2."
-
-
MODULE -- this module
-
MANDATORY-GROUPS { mauIfGrpBasic }
-
-
GROUP mauIfGrp100Mbs DESCRIPTION "Implementation of this optional group is recommended for MAUs which have 100Mb/s capability." GROUP mauIfGrpJack DESCRIPTION "Implementation of this optional group is recommended for MAUs which have one or more external jacks." GROUP mauIfGrpAutoNeg DESCRIPTION "Implementation of this group is mandatory for MAUs which support managed -
auto-negotiation."
-
GROUP mauBroadBasic DESCRIPTION "Implementation of this group is mandatory for broadband MAUs." GROUP ifMauNotifications DESCRIPTION "Implementation of this group is recommended for MAUs attached to interfaces." ::= { mauModCompls 2 }-
mauModIfCompl2 MODULE-COMPLIANCE
STATUS current DESCRIPTION "Compliance for MAUs attached to interfaces."-
-
MODULE -- this module
-
MANDATORY-GROUPS { mauIfGrpBasic }
-
GROUP mauIfGrpHighCapacity DESCRIPTION "Implementation of this optional group is recommended for MAUs which have 100Mb/s or greater capability." GROUP mauIfGrpJack DESCRIPTION "Implementation of this optional group is recommended for MAUs which have one or more external jacks." GROUP mauIfGrpAutoNeg2 DESCRIPTION "Implementation of this group is mandatory for MAUs which support managed auto-negotiation." GROUP mauIfGrpAutoNeg1000Mbps DESCRIPTION "Implementation of this group is mandatory for MAUs which have 1000Mb/s or greater capability and support managed auto-negotiation." GROUP ifMauNotifications DESCRIPTION "Implementation of this group is recommended for MAUs attached to interfaces." OBJECT ifMauStatus MIN-ACCESS read-only DESCRIPTION "Write access is not required." ::= { mauModCompls 3 }-
mauModRpCompl2 MODULE-COMPLIANCE
STATUS current DESCRIPTION "Compliance for MAUs attached to repeater ports."-
-
MODULE -- this module
-
MANDATORY-GROUPS { mauRpGrpBasic }
-
GROUP mauRpGrp100Mbs DESCRIPTION "Implementation of this optional group is recommended for MAUs which have 100Mb/s or greater capability." GROUP mauRpGrpJack DESCRIPTION "Implementation of this optional group is recommended for MAUs which have one or more external jacks." GROUP rpMauNotifications DESCRIPTION "Implementation of this group is recommended for MAUs attached to repeater ports." OBJECT rpMauStatus MIN-ACCESS read-only DESCRIPTION "Write access is not required." ::= { mauModCompls 4 } END -
5. Intellectual Property
-
The IETF takes no position regarding the validity or scope of any intellectual property or other rights that might be claimed to pertain to the implementation or use of the technology described in this document or the extent to which any license under such rights might or might not be available; neither does it represent that it has made any effort to identify any such rights. Information on the IETF's procedures with respect to rights in standards-track and standards-related documentation can be found in BCP-11. Copies of claims of rights made available for publication and any assurances of licenses to be made available, or the result of an attempt made to obtain a general license or permission for the use of such proprietary rights by implementors or users of this specification can be obtained from the IETF Secretariat.
The IETF invites any interested party to bring to its attention any copyrights, patents or patent applications, or other proprietary rights which may cover technology that may be required to practice this standard. Please address the information to the IETF Executive Director.
6. Acknowledgements
-
This document was produced by the IETF Ethernet Interfaces and Hub MIB Working Group, whose efforts were greatly advanced by the contributions of the following people:
-
Chuck Black
John Flick
Jeff Johnson
Leon Leong
Mike Lui
Dave Perkins
Geoff Thompson
Maurice Turcotte
Paul Woodruff
Special thanks as well to Dave Perkins for his excellent work on the SMICng compiler, which made it easy to take advantage of the latest SNMPv2 constructs in this MIB.
-
7. References
-
[1] Harrington, D., Presuhn, R. and B. Wijnen, "An Architecture for Describing SNMP Management Frameworks", RFC 2571, May 1999. [2] Rose, M. and K. McCloghrie, "Structure and Identification of Management Information for TCP/IP-based Internets", STD 16, RFC 1155, May 1990. [3] Rose, M. and K. McCloghrie, "Concise MIB Definitions", STD 16, RFC 1212, March 1991. [4] Rose, M., "A Convention for Defining Traps for use with the SNMP", RFC 1215, March 1991. [5] McCloghrie, K., Perkins, D., Schoenwaelder, J., Case, J., Rose, M. and S. Waldbusser, "Structure of Management Information Version 2 (SMIv2)", STD 58, RFC 2578, April 1999. [6] McCloghrie, K., Perkins, D., Schoenwaelder, J., Case, J., Rose, M. and S. Waldbusser, "Textual Conventions for SMIv2", STD 58, RFC 2579, April 1999. [7] McCloghrie, K., Perkins, D., Schoenwaelder, J., Case, J., Rose, M. and S. Waldbusser, "Conformance Statements for SMIv2", STD 58, RFC 2580, April 1999. [8] Case, J., Fedor, M., Schoffstall, M. and J. Davin, "Simple Network Management Protocol", STD 15, RFC 1157, May 1990. [9] Case, J., McCloghrie, K., Rose, M. and S. Waldbusser, "Introduction to Community-based SNMPv2", RFC 1901, January 1996. [10] Case, J., McCloghrie, K., Rose, M. and S. Waldbusser, "Transport Mappings for Version 2 of the Simple Network Management Protocol (SNMPv2)", RFC 1906, January 1996. [11] Case, J., Harrington, D., Presuhn, R. and B. Wijnen, "Message Processing and Dispatching for the Simple Network Management Protocol (SNMP)", RFC 2572, May 1999. [12] Blumenthal, U. and B. Wijnen, "User-based Security Model (USM) for version 3 of the Simple Network Management Protocol (SNMPv3)", RFC 2574, May 1999. [13] Case, J., McCloghrie, K., Rose, M. and S. Waldbusser, "Protocol Operations for Version 2 of the Simple Network Management Protocol (SNMPv2)", RFC 1905, January 1996. [14] Levi, D., Meyer, P. and B. Stewart, "SNMPv3 Applications", RFC 2573, May 1999. [15] Wijnen, B., Presuhn, R. and K. McCloghrie, "View-based Access Control Model (VACM) for the Simple Network Management Protocol (SNMP)", RFC 2575, May 1999. [16] IEEE, IEEE Std 802.3, 1998 Edition: "Information technology - Telecommunications and information exchange between systems - Local and metropolitan area networks - Specific requirements - Part 3: Carrier sense multiple access with collision detection (CSMA/CD) access method and physical layer specifications" (incorporating ANSI/IEEE Std. 802.3, 1996 Edition, IEEE Std. 802.3r-1996, 802.3u-1995, 802.3x&y-1997, 802.3z-1998, and 802.3aa-1998), September 1998. [17] de Graaf, K., Romascanu, D., McMaster, D. and K. McCloghrie, "Definitions of Managed Objects for IEEE 802.3 Repeater Devices using SMIv2", RFC 2108, February 1997. [18] McCloghrie, K. and M. Rose, Editors, "Management Information Base for Network Management of TCP/IP-based internets: MIB-II", STD 17, RFC 1213, March 1991. [19] McCloghrie, K. and F. Kastenholtz, "The Interfaces Group MIB using SMIv2", RFC 2233, November 1997. [20] Bradner, S., "Key words for use in RFCs to Indicate Requirements Levels", BCP 14, RFC 2119, March 1997.[21] de Graaf, K., Romascanu, D., McMaster, D., McCloghrie, K. and S.
-
Roberts, "Definitions of Managed Objects for IEEE 802.3 Medium Attachment Units (MAUs) using SMIv2", RFC 2239, November 1997.
[22] McMaster, D., McCloghrie, K. and S. Roberts, "Definitions of Managed Objects for IEEE 802.3 Medium Attachment Units (MAUs)", RFC 1515, September 1993. [23] Flick, J. and J. Johnson, "Definitions of Managed Objects for the Ethernet-like Interface Types", RFC 2665, August 1999.
8. Security Considerations
-
There are a number of management objects defined in this MIB that have a MAX-ACCESS clause of read-write. Setting these objects can have a serious effect on the operation of the network, including:
-
enabling or disabling a MAU
changing a MAU's default type
enabling, disabling or restarting autonegotiation modifying the capabilities that a MAU advertizes during-
autonegotiation.
-
Such objects may be considered sensitive or vulnerable in some network environments. The support for SET operations in a non-secure environment without proper protection can have a negative effect on network operations.
SNMPv1 by itself is such an insecure environment. Even if the network itself is secure (for example by using IPSec), even then, there is no control as to who on the secure network is allowed to access and GET/SET (read/change/create/delete) the objects in this MIB.
It is recommended that the implementers consider the security features as provided by the SNMPv3 framework. Specifically, the use of the User-based Security Model RFC 2574 [12] and the View-based Access Control Model RFC 2575 [15] is recommended.
It is then a customer/user responsibility to ensure that the SNMP entity giving access to an instance of this MIB, is properly configured to give access to those objects only to those principals (users) that have legitimate rights to access them.
-
9. Authors' Addresses
-
Andrew Smith
Extreme Networks, Inc.
3585 Monroe St.
Santa Clara, CA 95051 USAPhone: +1 408 579-2821 EMail: andrew@extremenetworks.com
John Flick
Hewlett-Packard Company
8000 Foothills Blvd. M/S 5557
Roseville, CA 95747-5557Phone: +1 916 785 4018 EMail: johnf@rose.hp.com
Kathryn de Graaf
Argon Networks
25 Porter Road
Littleton, MA 01460 USAPhone: +1 978 486 0665 x163 Fax: +1 978 486 9379 EMail: kdegraaf@argon.com
Dan Romascanu
Lucent Technologies
Atidim Technology Park, Bldg. 3
Tel Aviv 61131
IsraelPhone: 972 3 645 8414, 6458458 Fax: 972 3 648 7146 EMail: dromasca@lucent.com
Donna McMaster
Cisco Systems Inc.
170 West Tasman Drive
San Jose, CA 95134Phone: +1 408 526 5260 EMail: mcmaster@cisco.com
Keith McCloghrie
Cisco Systems Inc.
170 West Tasman Drive
San Jose, CA 95134Phone: +1 408 526 5260 EMail: kzm@cisco.com
Sam Roberts
Farallon Computing, Inc.
2470 Mariner Square Loop
Alameda, CA 94501-1010Phone: +1 510 814 5215 EMail: sroberts@farallon.com
Appendix
-
Change Log
This section enumerates the changes made to RFC 2239 to produce this document.
(1) The MODULE-IDENTITY has been updated to reflect the changes in the MIB. (2) OBJECT-IDENTITY definitions have been added for gigabit MAU types. (3) The ifMauTypeList, ifMauAutoNegCapability, ifMauAutoNegCapAdvertised and ifMauAutoNegCapReceived objects have been deprecated and replaced by ifMauTypeListBits, ifMauAutoNegCapabilityBits, ifMauAutoNegCapAdvertisedBits and ifMauAutoNegCapReceivedBits. (4) Two new objects, ifMauAutoNegRemoteFaultAdvertised and ifMauAutoNegRemoteFaultReceived have been added. (5) Enumerations for 'offline' and 'autoNegError' have been added for the rpMauMediaAvailable and ifMauMediaAvailable objects. (6) The broadMauBasicTable and mauBroadBasic object group have been deprecated. (7) The mauIfGrp100Mbs and mauIfGrpAutoNeg object groups have been deprecated and replaced by mauIfGrpHighCapacity and mauIfGrpAutoNeg2. (8) A new object group, mauIfGrpAutoNeg1000Mbps, has been added. (9) The mauModIfCompl and mauModRpCompl compliances have been deprecated and replaced by mauModIfCompl2 and mauModRpCompl2.-
(10) Added section on relationship to RFC 2239.
(11) Updated the SNMP Network Management Framework boilerplate.
(12) Refer to the Interfaces MIB, rather than the interfaces
-
group of MIB-II.
(13) Updated references to refer to latest edition of IEEE 802.3.
(14) An intellectual property notice was added, as required by
-
11. Full Copyright Statement
-
Copyright © The Internet Society (1999). All Rights Reserved.
This document and translations of it may be copied and furnished to others, and derivative works that comment on or otherwise explain it or assist in its implementation may be prepared, copied, published and distributed, in whole or in part, without restriction of any kind, provided that the above copyright notice and this paragraph are included on all such copies and derivative works. However, this document itself may not be modified in any way, such as by removing the copyright notice or references to the Internet Society or other Internet organizations, except as needed for the purpose of developing Internet standards in which case the procedures for copyrights defined in the Internet Standards process must be followed, or as required to translate it into languages other than English.
The limited permissions granted above are perpetual and will not be revoked by the Internet Society or its successors or assigns.
This document and the information contained herein is provided on an "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Acknowledgement
-
Funding for the RFC Editor function is currently provided by the Internet Society.