% Librarian T09-20b3&b2R5AaglatmInterfaceConfTable aglatmInterfaceDs3PlcpTable#aglatmInterfaceNoTrafficEnforcementaglatmInterfaceSonetTCTabler&aglatmInterfaceTrafficEnforcementType1&aglatmInterfaceTrafficEnforcementType2&aglatmInterfaceTrafficEnforcementType3 &aglatmInterfaceTrafficEnforcementType4&aglatmInterfaceTrafficEnforcementType5&aglatmInterfaceTrafficEnforcementType6ndexaglInterfaceATMOAMStatusaglInterfaceATMScrambeStatusisticalTablennapdebrNportSnapNameStatusTebrNportSnapNameTable`ebrNportSnapProtoTabledNebrNportSnapSvcTable?*ebrNportStaticDAFilterCharacteristicsTable;ebrNportStaticDATableP*ebrNportStaticSAFilterCharacteristicsTableLnebrNportStaticSATablelebrNportSwManualFilterjRebrNportSwTablefanSpeed$floodBytesPurgedfloodBytesSent: floodGeezers floodHogsfloodLocalCopyPacketsDelivered floodLosers\floodMulticastRateons&aglatmInterfaceTrafficEnforcementType6aglInterfaceATMScrambeStatusaglInterfaceDS3E3ModeaglInterfaceSonetIndex"aglInterfaceTrafficRateGranularityaglVCConnectionTableEntryStatusarpAgentarpStatisticalTable copyActionebrNportDAMatrixName"ebrNportDefaultMatrixAllowedToGoTo ebrNportFppnManualFilter ebrNportMatrixFppnRowStatusebrNportMatrixNameRowTableebrNportSANameTablehtPowerOutputPower ttSizee3]p%ebrNportSapFilterCharacteristicsTableebrNportSapMatrixNameebrNportSapNameSapebrNportSapNameStatusebrNportSapNameTableWebrNportSapProtoTable[.ebrNportSapSvcTablef&ebrNportSnapFilterCharacteristicsTableebrNportSnapMatrixNameebrNportSnapNameSnapBebrNportMatrixNameTable6ebrNportNamedDefaultMatrixIrebrNportPortNumTable&ebrNportSAMatrixName&ebrNportSANameSA'HebrNportSANameStatus%ebrNportSANameTable-ebrNportMatrixFppnRowTableebrNportMatrixFppnValue-ebrNportMatrixNameRowStatus+ebrNportMatrixNameRowTable leftFanStatus|leftPowerInputSource} leftPowerOutputPower{leftPowerStatusj$maximumGIGAswitchMIBVersionSupportedtfmgmtMemoryActiontmgmtMemoryAvail$minimumGIGAswitchMIBVersionSupported"mopDestination mPortEnable mPortMACIndex0 mPortSMTIndex mPortTablexpscBackplaneStatuswpscFwImageStatusvpscFwRevv0pscHwRevvf pscStatusrightFanStatuszLrightPowerInputSource{LrightPowerOutputPower8ebrNportManualFilter+ebrNportMatrixAllowedToGoTo.ebrNportMatrixFppnAllowedToGoTo0ebrNportMatrixFppnRowStatusYzrightPowerStatus}scpSlot* slotCardFwRev slotCardHwRev~slotCardStatus slotCardType~* slotIndex}l slotNumber}n slotTable snmpDuplicateDiscardIntervalx`temperatureWarningtftpDestination|transferActionNtransferFileName transferSizetransferStatusttSizeZfloodPacketsFilteredHfloodPacketsPurgedfloodPacketsSentfloodQuotaClassfloodQuotaQualifierfloodSinglePathDiscards floodTablefloodUnknownUnicastRate&fppnBridgePortNumber fppnIfIndexrfppnPortOfThatSlotfppnSlotNumber( fppnTablegigaStpPortIfIndex2gigaStpPortSpanningTreeEnableFgigaStpPortTablevkeyswitchPositionfloodBytesSent: floodGeezers floodHogsfloodLocalCopyPacketsDeliveredfloodLocalCopyPacketsDiscarded floodLosers\floodMulticastRate3ebrNportDefaultMatrixFppnValue7ebrNportDefaultMatrixRowTable0ebrNportDefaultMatrixValue:ebrNportFppnManualFilter LebrNportDANameDA!JebrNportDANameStatusBebrNportDANameTableEebrNportDASvcTable7$"ebrNportDefaultMatrixAllowedToGoToB copyStatus copyToSlotcopyTypeqcutThroughFppnTablencutThroughTablejdeleteTransfer!*ebrNportDAMatrixNamearpTimeoutInSeconds batteryCharge4 batteryStatusR batteryTest batteryUsingxcabinetTemperature@ copyActionarpFramesDiscardedarpFramesFloodedXarpPeriodBetweenRequestszarpRepliesTransmittedarpRequestRetriesarpStatisticalTableaglsonetLineCurrentTable\aglsonetMediumTableaglsonetPathCurrentTableaglsonetSectionCurrentTable~aglVCConnectionAALTypehaglVCConnectionAdminStatus(aglVCConnectionOperStatusaglVCConnectionPortAaglVCConnectionPortAVci^aglVCConnectionPortAVpi&aglVCConnectionPortBaglVCConnectionPortBVciaglVCConnectionPortBVpi^aglVCConnectionTablezaglVCConnectionTableEntryStatusarpAgent#aglVCConnectionTrafficShaperAvgRatet-aglVCConnectionTrafficShaperMinGuaranteedRate$aglVCConnectionTrafficShaperPeakRate $aglVCConnectionTrafficShaperPriority\aglVCConnectionTrafficTypearpAgentb(1 minimumGIGAswitchMIBVersionSupported 8 When new GIGAswitch MIBs are released to the public,0 they will be given new version numbers. The: implementation strategy allows multiple versions to be; supported simultaneously. MIB versions greater than or. equal to this version are still supported. wwb(1 maximumGIGAswitchMIBVersionSupported 8 When new GIGAswitch MIBs are released to the public,0 they will be given new version numbers. The: implementation strategy allows multiple versions to be8 supported simultaneously. MIB versions less than or< equal to this version are still supported. A management7 station may load a MIB which is not supported until' the GIGAswitch software is updated. wwb1 ebrNportMatrixNameTable2 ebrNportMatrixNameEntry2 ebrNportMatrixName % ::= { ebrNportMatrixNameEntry 1 }# ebrNportMatrixValue OBJECT-TYPE$  SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION: "A matrix is expressed using a shorthand that says wha2 ebrNportMatrixStatuswwb1 ebrNportMatrixFppnValue: A matrix is expressed using a shorthand that says what. input ports can talk to what output ports.& An examples of a specification is:. 1.1,2.1-14.2:1.1-14.2; 2.2:5.3,6.4; 10.3:;= Semicolons separate expressions. Within each expression,@ the colon has a left hand side and a right hand side. Front? panel ports on the left hand side can send packets to frontA panel ports on the right hand side. Commas separate items in< a list of front panel ports. Hyphens are short-hand forC specifying a range of numbers. If there is no right hand side,@ the front panel ports on the left cannot send packets to anyB front panel port (unless the matrix is combined with some someC other matrix in a filter specification, or  unless the filter is overridden).> Front panel port numbers are of the form (slot.connector),= where slot is the slot number the module is plugged into,: and connector is the connector number specified on the front of the card.< A matrix will read back in a form equivalent to the form6 written. It may not read back exactly as written.@ No single matrix defines whether a packet arriving on a portB is forwarded to its destination. Various destination address,B source address, protocol, and default filtering specifications> are combined to determine whether the packet is forwarded.A If the ebrNportMatrixFppnValue is changed, all filters using  it are immediately updated.9 Managers may not specify both ebrNportMatrixValue and< ebrNportMatrixFppnValue at the same time to set an entry in this table.wwb1 ebrNportSapNameTable2 ebrNportSapNameEntry  INDEX { ebrNportSapName }" ::= { ebrNportSapNameTable 1 } EbrNportSapNameEntry ::= SEQUENCE {# ebrNportSapName DisplayString,$ ebrNportSapNameSap OCTET STRING,( ebrNportSapMatrixName DisplayString, ebrNportSapNameDisp INTEGER,! ebrNportSapNameStatus INTEGER } ebrNportSapName OBJECT-TYPE$ SYNTAX DisplayString (SIZE (32)) ACCESS read-only STATUS mandatoryH DESCRIPTION "This name for a portion of a filter is whatever the usewwb1 ebrNportSapNameSap The one-byte SAP.B Changes to ebrNportSapProtoTable for this SAP are denied while= filtering of the SAP is specified by reference to a named matrix using this table.wwb1 ebrNportSapMatrixName " ::= { ebrNportSapNameEntry 3 }# ebrNportSapNameDisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION wwb1 ebrNportSapNameStatus A This object specifies the permanence of the associated filter@ matrix, and also provides a means to delete a filter matrix.8 Writing invalid(1) to the object removes the filter.D Writing permanent(2) value to the object indicates the filter is$ preserved across a bridge reset. wwb1 ebrNportSnapNameTable2 ebrNportSnapNameEntry  INDEX { ebrNportSnapName }# ::= { ebrNportSnapNameTable 1 } EbrNportSnapNameEntry ::= SEQUENCE {# ebrNportSnapName DisplayString,& ebrNportSnapNameSnap OCTET STRING,) ebrNportSnapMatrixName DisplayString,! ebrNportSnapNameDisp INTEGER," ebrNportSnapNameStatus INTEGER } ebrNportSnapName OBJECT-TYPE$ SYNTAX DisplayString (SIZE (32)) ACCESS read-only STATUS mandatoryH DESCRIPTION "This name for a portion of a filter is whatever the usewwb1 ebrNportSnapNameSnap The five-byte PID.B Changes to ebrNportSnapProtoTable for this protocol are deniedB while filtering of the protocol is specified by reference to a" named matrix using this table.wwb1 ebrNportSnapMatrixName # ::= { ebrNportSnapNameEntry 3 }$ ebrNportSnapNameDisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION wwb1 ebrNportSnapNameStatus A This object specifies the permanence of the associated filter@ matrix, and also provides a means to delete a filter matrix.8 Writing invalid(1) to the object removes the filter.D Writing permanent(2) value to the object indicates the filter is$ preserved across a bridge reset. wwb1 ebrNportDANameTable2 ebrNportDANameEntry  INDEX { ebrNportDAName }! ::= { ebrNportDANameTable 1 } EbrNportDANameEntry ::= SEQUENCE {"! ebrNportDAName DisplayString," ebrNportDANameDA OCTET STRING,' ebrNportDAMatrixName DisplayString, ebrNportDANameDisp INTEGER, ebrNportDANameStatus INTEGER } ebrNportDAName OBJECT-TYPE$ SYNTAX DisplayString (SIZE (32)) ACCESS read-only STATUS mandatory DESCRIPTION wwb1 ebrNportDANameDA@ Changes to ebrNportStaticDATable for this address are deniedA while filtering of the address is specified by reference to a" "named matrix using this table.ww-b1 ebrNportDAMatrixName ! ::= { ebrNportDANameEntry 3 }" ebrNportDANameDisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION ww-b1 ebrNportDANameStatus 7 other(1) - This entry is currently in use, but the : conditions under which it will remain so are different7 from eac #h of the following values. Like other uses9 of 'other' in MIBs, this value may not be assigned to the object.C invalid(2) - Writing this value to the object removes the entryB permanent(3) - Writing this value to the object indicates that1 the entry is preserved across a bridge reset.? deleteOnReset(4) - Writing this value removes the permanent8 entry characteristic. The entry is deleted upon the2 next bridge reset (SCP or GIGAswitch failure).: Writing dele $teOnReset is not supported. SNMP does not9 currently model viewing the non-volatile and volatile4 data structures independently, which can lead to9 unexpectedly having no filter if a reset occurs while6 temporarily trying a change to an existing filter.: Writes of this value will result in a bad value return: status. It is present for consistency with the Bridge4 MIB (RFC 1286), which describes address filters.A deleteOnTimeout(5) - Writing this value removes the pe %rmanent: entry characteristic. Since the timers used for aging; information within the bridge are hidden from the user,2 the change may in fact take place immediately.< Writing deleteOnTimeout is not supported. SNMP does not9 currently model viewing the non-volatile and volatile4 data structures independently, which can lead to9 unexpectedly having no filter if a reset occurs while6 temporarily trying a change to an existing filter.: Writes of this value will &result in a bad value return: status. It is present for consistency with the Bridge4 MIB (RFC 1286), which describes address filters. ww-b1 ebrNportSANameTable2 ebrNportSANameEntry  INDEX { ebrNportSAName }! ::= { ebrNportSANameTable 1 } EbrNportSANameEntry ::= SEQUENCE {" ebrNportSAName DisplayString," ebrNportSANameSA OCTET STRING,' ebrNportSAMatrixName DisplayString, ebrNportSANameDisp INTEGER, ebrNportSA'NameStatus INTEGER } ebrNportSAName OBJECT-TYPE$ SYNTAX DisplayString (SIZE (32)) ACCESS read-only STATUS mandatory DESCRIPTION ww-b1 ebrNportSANameSA The six-byte source address.@ Changes to ebrNportStaticSATable for this address are deniedA while filtering of the address is specified by reference to a" named matrix using this table.ww-b1 ebrNportSAMatrixName ! ::= { ebrNportSANameEntry 3 }" (ebrNportSANameDisp OBJECT-TYPE SYNTAX INTEGER { portMask(1), alwaysFilter(2), alwaysForward(3), lockdown(4), lockdownportmask(5), filter(6) } ACCESS read-write STATUS mandatory DESCRIPTIONB "This object specifies how to interpret the ebrNportPortNum anww-b1 ebrNportSANameStatus 7 other(1) - This entry is currently in use, but the : conditions under which it will remain so are different7 from each )of the following values. Like other uses9 of 'other' in MIBs, this value may not be assigned to the object.C invalid(2) - Writing this value to the object removes the entryB permanent(3) - Writing this value to the object indicates that1 the entry is preserved across a bridge reset.? deleteOnReset(4) - Writing this value removes the permanent8 entry characteristic. The entry is deleted upon the2 next bridge reset (SCP or GIGAswitch failure).: Writing delete *OnReset is not supported. SNMP does not9 currently model viewing the non-volatile and volatile4 data structures independently, which can lead to9 unexpectedly having no filter if a reset occurs while6 temporarily trying a change to an existing filter.: Writes of this value will result in a bad value return: status. It is present for consistency with the Bridge4 MIB (RFC 1286), which describes address filters.A deleteOnTimeout(5) - Writing this value removes the perm +anent: entry characteristic. Since the timers used for aging; information within the bridge are hidden from the user,2 the change may in fact take place immediately.< Writing deleteOnTimeout is not supported. SNMP does not9 currently model viewing the non-volatile and volatile4 data structures independently, which can lead to9 unexpectedly having no filter if a reset occurs while6 temporarily trying a change to an existing filter.: Writes of this value will re,sult in a bad value return: status. It is present for consistency with the Bridge4 MIB (RFC 1286), which describes address filters. ww9b1 ebrNportMatrixNameRowTable2 ebrNportMatrixNameRowEntry2 ebrNportmatrixName2 ebrNportMatrixReceivePort> A bridge port number. Zero is treated as in other tables,< and is short-hand for all rows not previously mentioned.ww9b1 ebrNportMatrixAllowedToGoTo= Just like all the other Go -Tos. The set of ports to which: frames received from a specific port are allowed to be forwarded.= Each octet of this object specifies a set of eight ports,6 with the first octet specifying ports 1 through 8,6 the second octet specifying port 9 through 16 etc.: Within each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 bit represents the highest numbered port. If a7 bit has a value of '1', then the correspondi.ng port4 is included in the set of ports; the port is not+ included if its bit has a value of '0'.> If the ebrNportMatrixAllowedToGoTo is changed, all filters% using it are immediately updated.ww9b1 ebrNportMatrixNameRowStatusww9b1 ebrNportMatrixFppnRowTable2 ebrNportMatrixFppnRowEntry2 ebrNportmatrixname!2 ebrNportMatrixFppnReceivePort> Front panel port numbers are of the form (slot.connector),= where slot is the /slot number the module is plugged into,: and connector is the connector number specified on the front of the card.? To avoid the syntactic ambiguity, the slot number must take> two characters. For example, front panel port number 3.1 @ must be typed by 03.1. 0.0 is treated as in other tables, < and is short-hand for all rows not previously mentioned.wwb#1 ebrNportMatrixFppnAllowedToGoTo= Just like all the other GoTos. The set of ports to whic 0h: frames received from a specific port are allowed to be forwarded.= Each octet of this object specifies a set of eight ports,6 with the first octet specifying ports 1 through 8,6 the second octet specifying port 9 through 16 etc.: Within each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 bit represents the highest numbered port. If a7 bit has a value of '1', then the corresponding port4 is included in t1he set of ports; the port is not+ included if its bit has a value of '0'.B If the ebrNportMatrixFppnAllowedToGoTo is changed, all filters% using it are immediately updated.wwb1 ebrNportMatrixFppnRowStatuswwb1 ebrNportDefaultMatrixValue: A matrix is expressed using a shorthand that says what. input ports can talk to what output ports.& An examples of a specification is:( 11:1; 1:3-5; 2:0,3; 4-7,9:4-7,9; 10:= Semicolons2 separate expressions. Within each expression,A the colon has a left hand side and a right hand side. Bridge@ ports on the left hand side can send packets to bridge ports? on the right hand side. Commas separate items in a list of@ bridge ports. Hyphens are short-hand for specifying a rangeA of numbers. If there is no right hand side, the bridge portsB on the left cannot send packets to any bridge port (unless the> matrix is combined with some some other matrix in 3a filter7 specification, or unless the filter is overridden).1 Bridge port numbers are specified in decimal.< A matrix will read back in a form equivalent to the form6 written. It may not read back exactly as written.@ No single matrix defines whether a packet arriving on a portB is forwarded to its destination. Various destination address,B source address, protocol, and default filtering specifications> are combined to determine whether the packet is forwarded.; 4 Unspecified rows are set to one's, which means that the9 corresponding input ports can communicate with every  output port. wwab"1 ebrNportDefaultMatrixFppnValue: A matrix is expressed using a shorthand that says what9 input front panel ports can talk to what output front panel ports.& An examples of a specification is:. 1.1,2.1-14.2:1.1-14.2; 2.2:5.3,6.4; 10.3:;= Semicolons separate expressions. Within each expression,@ the colo5n has a left hand side and a right hand side. Front? panel ports on the left hand side can send packets to frontA panel ports on the right hand side. Commas separate items in< a list of front panel ports. Hyphens are short-hand forC specifying a range of numbers. If there is no right hand side,@ the front panel ports on the left cannot send packets to anyB front panel port (unless the matrix is combined with some someC other matrix in a filter specification, or unles 6s the filter is overridden).> Front panel port numbers are of the form (slot.connector),= where slot is the slot number the module is plugged into,: and connector is the connector number specified on the front of the card.< A matrix will read back in a form equivalent to the form6 written. It may not read back exactly as written.@ No single matrix defines whether a packet arriving on a portB is forwarded to its destination. Various destination address,B so 7urce address, protocol, and default filtering specifications> are combined to determine whether the packet is forwarded.; Unspecified rows are set to one's, which means that the9 corresponding input ports can communicate with every  output port. wwab1 ebrNportNamedDefaultMatrix= When a matrix name is written to this object, the default9 matrix is set to the matrix if and only if the matrix exists.A Unspecified rows in the matrix are s8et to one's, which means B that the corresponding input ports can communicate with every  output port. wwab!1 ebrNportDefaultMatrixRowTable!2 ebrNportDefaultMatrixRowEntry$2 ebrNportDefaultMatrixReceivePort A bridge port number.wwab&1 ebrNportDefaultMatrixAllowedToGoTo> The set of ports to which frames received from a specific 0 port are allowed to be forwarded by default.= Each octet of this object specifies a set 9of eight ports,6 with the first octet specifying ports 1 through 8,6 the second octet specifying port 9 through 16 etc.: Within each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 bit represents the highest numbered port. If a7 bit has a value of '1', then the corresponding port4 is included in the set of ports; the port is not+ included if its bit has a value of '0'. wwab1 ebrNportManu :alFilter6 The list of bridge ports in manual mode is listed.@ Manual mode means that the bridge purges the learned entriesB for that port from its forwarding database, stops its learning? process on that port, and forwards to that port only framesB with destination and source addresses that have been specified via management.@ A comma-separated list of bridge ports, with hyphens used toA abbreviate ranges, is supported. The bridge port numbers are in decimal. ; wwMb1 ebrNportFppnManualFilter; The list of front panel ports in manual mode is listed.@ Manual mode means that the bridge purges the learned entriesB for that port from its forwarding database, stops its learning? process on that port, and forwards to that port only framesB with destination and source addresses that have been specified via management.C A comma-separated list of front panel ports, with hyphens used ) to abbreviate rang <es, is supported. > Front panel port numbers are of the form (slot.connector),= where slot is the slot number the module is plugged into,: and connector is the connector number specified on the front of the card. wwMb1 ebrNportStaticDATable@ This table contains management-specified destination address? filtering information about unicast and multicast addresses> for N-port bridges. In RFC 1286 lingo, static objects areB those objects =which have been specified by network management.2 ebrNportStaticDAEntryA Information about a specific MAC address for which the bridge= has some management-specified forwarding and/or filtering information.2 ebrNportDAAddress- The destination MAC Address in a frame to5 which this entry's filtering information applies.2 ebrNportDAReceivePort7 The port from which a frame must be received to use4 the corresponding ebrNportDAAllowedToGoTo field.B A valu >e of zero indicates that this entry applies on all ports? of the bridge for which there is no other applicable entry.2 ebrNportDAAllowedToGoTo2 The set of ports to which frames received from< a specific port and destined to the address specified by2 ebrNportDAAddress are allowed to be forwarded.= Each octet of this object specifies a set of eight ports,6 with the first octet specifying ports 1 through 8,6 the second octet specifying port 9 through 16 etc.: Within ? each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 bit represents the highest numbered port. If a7 bit has a value of '1', then the corresponding port4 is included in the set of ports; the port is not+ included if its bit has a value of '0'.A Filter matrix rows can be initialized or overwritten, but not5 deleted. Only whole matrices are deleted via the< characteristics table. To produce the equivalent of row<@ deletion, set the GoTo according to the following table: Disp GoTo" filter/portMask 0xFFFFFFFFF0 alwaysFilter 0xFFFFFFFFF0 alwaysForward 0 wwMb.1 ebrNportStaticDAFilterCharacteristicsTableB A table that contains information about how static destinationB address filters (for unicast and multicast addresses) are usedA within N-port bridges. Static objects are those objects which. have been specified by network management..2 A ebrNportStaticDAFilterCharacteristicsEntry? Information about a specific static MAC destination address) filter's usage within N-port bridges.2 ebrNportDestinationAddress@ The destination MAC Address in a frame to which this entry's> information applies. The value of this object is the same as ebrNportDAAddress.2 ebrNportDADispB This object specifies how to interpret the ebrNportPortNum and$ ebrNportDAAllowedToGoTo objects.> filter(1) : The filtering for Bthis address is specified by the filter matrix.= alwaysFilter(2) : Frames destined to address are filtered6 regardless of any other alwaysForward dispositions9 based on the frame's source address or protocol type.8 The filtering information is specified by the filter matrix.< alwaysForward(3) : Frames destined to address are always. forwarded to ebrNportPortNum if specified.1 The filter matrix is used to specify ports to1 which frames may be sent. In both Ccases, this6 disposition overrides filters based on the frame's; source address or protocol type, unless either of those, filters has an alwaysFilter disposition. 2 ebrNportDAStatus 7 other(1) - This entry is currently in use, but the : conditions under which it will remain so are different7 from each of the following values. Like other uses9 of 'other' in MIBs, this value may not be assigned to the object.C invalid(2) - Writing this value to t Dhe object removes the entryB permanent(3) - Writing this value to the object indicates that1 the entry is preserved across a bridge reset.? deleteOnReset(4) - Writing this value removes the permanent8 entry characteristic. The entry is deleted upon the2 next bridge reset (SCP or GIGAswitch failure).: Writing deleteOnReset is not supported. SNMP does not9 currently model viewing the non-volatile and volatile4 data structures independently, which can lead to9 un Eexpectedly having no filter if a reset occurs while6 temporarily trying a change to an existing filter.: Writes of this value will result in a bad value return: status. It is present for consistency with the Bridge4 MIB (RFC 1286), which describes address filters.A deleteOnTimeout(5) - Writing this value removes the permanent: entry characteristic. Since the timers used for aging; information within the bridge are hidden from the user,2 the change may in fact take Fplace immediately.< Writing deleteOnTimeout is not supported. SNMP does not9 currently model viewing the non-volatile and volatile4 data structures independently, which can lead to9 unexpectedly having no filter if a reset occurs while6 temporarily trying a change to an existing filter.: Writes of this value will result in a bad value return: status. It is present for consistency with the Bridge4 MIB (RFC 1286), which describes address filters. ww Gnb1 ebrNportDASvcTable@ A table that contains resource information about unicast and7 multicast destination addresses for N-port bridges.2 ebrNportDASvcEntryA Resource information about a specific MAC destination address for N-port bridges.2 ebrNportSvcAddress@ The destination MAC Address in a frame to which this entry's! resource information applies.2 ebrNportSvc> The service class used to allocate resources and implement7 service policy wit Hhin the bridge. The service class? associated with a frame is a function of either the frame's< destination address or the frame's protocol. The default? value for this field is 0. This value is used to assign the? single path service class in the absence of a service class@ associated with the frame's protocol. There are 16 possible> service classes, 0-15. The ebrNportSvc allows 32 values to> be specified. The specification of a value greater than 15@ is used to c Ionnote that the service class (ebrNportSvc-16),< is to be associated with the frame and that this service= class has precedence over a service class associated with a frame's protocol.A Service classes 1-11 are reserved for internal or future use. 2 ebrNportSvcStatus A This object specifies the permanence of the specified service> class usage, and also provides a means to delete an entry.7 Writing invalid(1) to the object removes the entry.C WritinJg permanent(2) value to the object indicates the entry is$ preserved across a bridge reset. wwnb1 ebrNportPortNumTable5 A table that contains static (i.e., configured by4 network management) information about the bridge7 port on which unicast or multicast addresses reside on N-port bridges.2 ebrNportPortNumEntry- Information about a specific MAC address.2 ebrNportPortNumAddress> The MAC Address to which this entry's information appl Kies.2 ebrNportPortNum1 The Port Number to which this address will be8 translated (to which frames destined for the address9 will be forwarded). There are some filtering nuances7 for addresses with specified port numbers which are< determined by the source address and destination address' filter disposition characteristics.) If zero, no port number is specified.< This value is a giganet destination address instead of a1 bridge port number if it is greater Lthan 127.2 ebrNportPortNumStatus 9 This object specifies the permanence of the specified> information, and also provides a means to delete an entry.7 Writing invalid(1) to the object removes the entry.C Writing permanent(2) value to the object indicates the entry is$ preserved across a bridge reset. 2 ebrNportFppnPortNum= The Front Panel Port Number to which this address will be8 translated (to which frames destined for the address9 will be forw Marded). There are some filtering nuances: for addresses with specified front panel port numbers ? which are determined by the source address and destination / address filter disposition characteristics.5 Managers may not specify both ebrNportPortNum and9 ebrNportFppnPortNum at the same time to set an entry  in this table.wwnb1 ebrNportStaticSATable9 A table that contains static source address filtering9 information about unicast and mult Nicast addresses for: N-port bridges. Static objects are those objects which. have been specified by network management.2 ebrNportStaticSAEntry: Information about a specific MAC address for which the6 bridge has some static forwarding and/or filtering information.2 ebrNportSAAddress; The source MAC Address in a frame to which this entry's" filtering information applies.2 ebrNportSAReceivePort7 The port from which a frame must be received to use4 th Oe corresponding ebrNportSAAllowedToGoTo field.< A value of zero indicates that this entry applies on all> ports of the bridge for which there is no other applicable entry.2 ebrNportSAAllowedToGoTo2 The set of ports to which frames received from= a specific port and sourced from the address specified by2 ebrNportSAAddress are allowed to be forwarded.= Each octet of this object specifies a set of eight ports,6 with the first octet specifying ports 1 through 8,6 P the second octet specifying port 9 through 16 etc.: Within each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 bit represents the highest numbered port. If a7 bit has a value of '1', then the corresponding port4 is included in the set of ports; the port is not+ included if its bit has a value of '0'.A Filter matrix rows can be initialized or overwritten, but not5 deleted. Only whole matrices are deleted via theQ< characteristics table. To produce the equivalent of row< deletion, set the GoTo according to the following table: Disp GoTo" filter/portMask 0xFFFFFFFFF0 alwaysFilter 0xFFFFFFFFF0 alwaysForward 0 wwb.1 ebrNportStaticSAFilterCharacteristicsTable= A table that contains information about how static source= address filters (for unicast and multicast addresses) are used within N-port bridges..2 ebrNportStaticSAFilterCh RaracteristicsEntry: Static source address filter usage for N-port bridges.2 ebrNportSourceAddress; The source MAC Address in a frame to which this entry's9 information applies. The value of this object is the same as ebrNportSAAddress.2 ebrNportSADispB This object specifies how to interpret the ebrNportPortNum and, and the ebrNportSAAllowedToGoTo objects.7 portMask(1) : The static filtering for this address& is specified by the filter matrix.: alwaysFi Slter(2) : Frames sourced from this address are2 filtered regardless of any other alwaysForward9 dispositions based on the frame's destination address9 or protocol type. The static filtering information is# specified by the filter matrix.; alwaysForward(3) : Frames sourced from this address are0 sent to ports specified in the filter matrix2 regardless of any DA or protocol filter with a8 disposition of filter. The alwaysForward disposition5 also overrides a forwa Trding disposition of filter( in the default filter matrix object.8 Filters with a disposition of alwaysFilter are never superceded.3 lockdown (4) : Frames sourced from this address6 are ONLY forwarded if received on the same port as ebrNportPortNum.; lockdownportmask (5) : Frames sourced from this address6 are ONLY forwarded if received on the same port as5 ebrNportPortNum AND if the frame is destined to a5 permitted port as specified by the filter matrix U.5 filter(6) : The static filtering for this address6 is specified by the filter matrix. portMask(1) is, the different name with the same effect. 2 ebrNportSAStatus 7 other(1) - This entry is currently in use, but the : conditions under which it will remain so are different7 from each of the following values. Like other uses9 of 'other' in MIBs, this value may not be assigned to the object.C invalid(2) - Writing this value to the object remove Vs the entryB permanent(3) - Writing this value to the object indicates that1 the entry is preserved across a bridge reset.? deleteOnReset(4) - Writing this value removes the permanent8 entry characteristic. The entry is deleted upon the2 next bridge reset (SCP or GIGAswitch failure).: Writing deleteOnReset is not supported. SNMP does not9 currently model viewing the non-volatile and volatile4 data structures independently, which can lead to9 unexpectedly havin Wg no filter if a reset occurs while6 temporarily trying a change to an existing filter.: Writes of this value will result in a bad value return: status. It is present for consistency with the Bridge4 MIB (RFC 1286), which describes address filters.A deleteOnTimeout(5) - Writing this value removes the permanent: entry characteristic. Since the timers used for aging; information within the bridge are hidden from the user,2 the change may in fact take place immediatel Xy.< Writing deleteOnTimeout is not supported. SNMP does not9 currently model viewing the non-volatile and volatile4 data structures independently, which can lead to9 unexpectedly having no filter if a reset occurs while6 temporarily trying a change to an existing filter.: Writes of this value will result in a bad value return: status. It is present for consistency with the Bridge4 MIB (RFC 1286), which describes address filters. ww-|b1 eb YrNportSapProtoTable5 A table that contains filtering information about4 802.2 SAPs in the DSAP field for N-port bridges.2 ebrNportSapProtoEntry5 A table that contains filtering information about4 802.2 SAPs in the DSAP field for N-port bridges.2 ebrNportSapValue3 The 802.2 DSAP in a frame to which this entry's" filtering information applies.2 ebrNportSapReceivePort7 "The port from which a frame must be received to us2 ebrNportSapAllowedToGoTo2 The Zset of ports to which frames received from5 a specific port and containing the DSAP in an 802+ frame specified by ebrNportSapValue are allowed to be forwarded.= Each octet of this object specifies a set of eight ports,6 with the first octet specifying ports 1 through 8,6 the second octet specifying port 9 through 16 etc.: Within each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 bit represents the highest numbe [red port. If a7 bit has a value of '1', then the corresponding port4 is included in the set of ports; the port is not+ included if its bit has a value of '0'.A Filter matrix rows can be initialized or overwritten, but not5 deleted. Only whole matrices are deleted via the< characteristics table. To produce the equivalent of row< deletion, set the GoTo according to the following table: Disp GoTo" filter/portMask 0xFFFFFFFFF0 alwaysFilter 0xFFFFFFF\FF0 alwaysForward 0 ww-|b1 ebrNportSapSvcTable> A table that contains resource information (e.g., queuing): about 802.2 SAPs in the DSAP field for N-port bridges.2 ebrNportSapSvcEntry= Resource information about an 802.2 SAP in the DSAP field for N-port bridges.2 ebrNportSapSvcSapValue3 The 802.2 DSAP in a frame to which this entry's! resource information applies.2 ebrNportSapSvc> The service class used to allocate res ]ources and implement7 service policy within the bridge. The service class? associated with a frame is a function of either the frame's< destination address or the frame's protocol. The default? value for this field is 0. This value is used to assign the> single path service class in the absence of an overriding? service class associated with the frame's destination addr.0 There are 16 possible service classes, 0-15.A Service classes 1-11 are reserved for internal o^r future use. 2 ebrNportSapSvcStatus A This object specifies the permanence of the specified service> class usage, and also provides a means to delete an entry.7 Writing invalid(1) to the object removes the entry.C Writing permanent(2) value to the object indicates the entry is$ preserved across a bridge reset. ww-|b)1 ebrNportSapFilterCharacteristicsTable: A table that contains information about how 802.2 DSAP+ filters are used _ within N-port bridges.)2 ebrNportSapFilterCharacteristicsEntry/ 802.2 DSAP filter usage for N-port bridges.,2 ebrNportSapFilterCharacteristicsSapValue3 The 802.2 DSAP in a frame to which this entry's5 information applies. The value of this object is! the same as ebrNportSapValue.2 ebrNportSapDisp. This object specifies how to interpret the: ebrNportSapAllowedToGoTo values for the specified SAP.> filter(1) : The filtering for this SAP is specified by the ` filter matrix.7 alwaysFilter(2) : Frames of this SAP (protocol) are2 filtered regardless of any other alwaysForward. dispositions based on the frame's address.1 The filtering information is specified by the filter matrix.9 alwaysForward(3) : Frames for this SAP (protocol) are0 sent to ports specified in the filter matrix+ regardless of any address filter with a8 disposition of filter. The alwaysForward disposition5 also overrides a forwarding dispositioan of filter( in the default filter matrix object.8 Filters with a disposition of alwaysFilter are never superceded. 2 ebrNportSapStatus A This object specifies the permanence of the associated filter@ matrix, and also provides a means to delete a filter matrix.8 Writing invalid(1) to the object removes the filter.D Writing permanent(2) value to the object indicates the filter is$ preserved across a bridge reset. wwb1 ebrN bportSnapProtoTable5 A table that contains filtering information about7 5-byte SNAP Protocol IDs (PIDs) for N-port bridges.2 ebrNportSnapProtoEntry5 A table that contains filtering information about7 5-byte SNAP Protocol IDs (PIDs) for N-port bridges.2 ebrNportSnapValue< The SNAP Protocol ID (PID) in an 802 frame to which this* entry's filtering information applies.2 ebrNportSnapReceivePort7 "The port from which a frame must be received to us2 ebrNport cSnapAllowedToGoTo2 The set of ports to which frames received from5 a specific port and containing the SNAP PID in an0 802 frame specified by ebrNportSnapValue are allowed to be forwarded.= Each octet of this object specifies a set of eight ports,6 with the first octet specifying ports 1 through 8,6 the second octet specifying port 9 through 16 etc.: Within each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 dbit represents the highest numbered port. If a7 bit has a value of '1', then the corresponding port4 is included in the set of ports; the port is not+ included if its bit has a value of '0'.A Filter matrix rows can be initialized or overwritten, but not5 deleted. Only whole matrices are deleted via the< characteristics table. To produce the equivalent of row< deletion, set the GoTo according to the following table: Disp GoTo" filter/portMask 0xFFFFFFFFeF0 alwaysFilter 0xFFFFFFFFF0 alwaysForward 0 wwb1 ebrNportSnapSvcTable> A table that contains resource information (e.g., queuing)= about 5-byte SNAP Protocol IDs (PIDs) for N-port bridges.2 ebrNportSnapSvcEntry> Resource information about a 5-byte SNAP Protocol ID (PID) for N-port bridges.2 ebrNportSnapSvcSnapValue? The SNAP Protocol ID (PID) in a frame to which this entry's! resource information applies.2 ebrNport fSnapSvc> The service class used to allocate resources and implement7 service policy within the bridge. The service class? associated with a frame is a function of either the frame's< destination address or the frame's protocol. The default? value for this field is 0. This value is used to assign the> single path service class in the absence of an overriding? service class associated with the frame's destination addr.0 There are 16 possible service classes, 0-15.Ag Service classes 1-11 are reserved for internal or future use. 2 ebrNportSnapSvcStatus A This object specifies the permanence of the specified service> class usage, and also provides a means to delete an entry.7 Writing invalid(1) to the object removes the entry.C Writing permanent(2) value to the object indicates the entry is$ preserved across a bridge reset. wwb*1 ebrNportSnapFilterCharacteristicsTable@ A table that contains hinformation about how SNAP Protocol ID1 (PID) filters are used within N-port bridges.*2 ebrNportSnapFilterCharacteristicsEntryA 802.2 SNAP Protocol ID (PID) filter usage for N-port bridges..2 ebrNportSnapFilterCharacteristicsSnapValue? The SNAP Protocol ID (PID) in a frame to which this entry'sA information applies. The value of this object is the same as ebrNportSnapValue.2 ebrNportSnapDisp. This object specifies how to interpret the@ ebrNportSnapAllowedToG ioTo values for the specified SNAP PID.2 filter(1) : The filtering for this Protocol ID& is specified by the filter matrix.4 alwaysFilter(2) : Frames of this Protocol ID are2 filtered regardless of any other alwaysForward. dispositions based on the frame's address.1 The filtering information is specified by the filter matrix.6 alwaysForward(3) : Frames for this Protocol ID are0 sent to ports specified in the filter matrix+ regardless of any address filter with ja8 disposition of filter. The alwaysForward disposition5 also overrides a forwarding disposition of filter( in the default filter matrix object.8 Filters with a disposition of alwaysFilter are never superceded. 2 ebrNportSnapStatus A This object specifies the permanence of the associated filter@ matrix, and also provides a means to delete a filter matrix.8 Writing invalid(1) to the object removes the filter.D Writing permanent(2) value to the objekct indicates the filter is$ preserved across a bridge reset. wwmb1 ebrNportSwTable3 This table describes the default filter matrix.2 ebrNportSwEntry; The entry describes a row of the default filter matrix.2 ebrNportSwReceivePort< The bridge port on which a frame must be received to use4 the corresponding ebrNportSwAllowedToGoTo field.B A value of zero indicates that this entry applies on all portsB of the bridge for which there is n lo other management-specified entry.2 ebrNportSwAllowedToGoTo< This object specifies the default forwarding disposition= after all DA, SA, and protocol filters have been applied.= For those cases where no filter applies to the frame, the9 forwarding disposition for the frames received on theA ebrNportSwReceivePort interface and sent to one or all of the, bridge's interfaces is determined by the# ebrNportSwAllowedToGoTo object.= Each octet of this object sp mecifies a set of eight ports,6 with the first octet specifying ports 1 through 8,6 the second octet specifying port 9 through 16 etc.: Within each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 bit represents the highest numbered port. If a7 bit has a value of '1', then the corresponding port4 is included in the set of ports; the port is not+ included if its bit has a value of '0'. wwmb1 n ebrNportSwManualFilter; A switch that controls address filtering. Specifying a9 one in a bit position says that the port is in manual mode.= Each octet of this object specifies a set of eight ports,6 with the first octet specifying ports 1 through 8,6 the second octet specifying port 9 through 16 etc.: Within each octet, the most significant bit represents7 the lowest numbered port, and the least significant3 bit represents the highest numbered port. If a o7 bit has a value of '1', then the corresponding port4 is included in the set of ports; the port is not+ included if its bit has a value of '0'.@ Manual mode means that the bridge purges the learned entriesB for that port from its forwarding database, stops its learning? process on that port, and forwards to that port only framesB with destination and source addresses that have been specified via management.wwmb1 cutThroughTableA This t pable controls the enabling of some hardware performanceB enhancements that avoid store-and-forward delays during packet" forwarding, whenever possible.2 cutThroughEntry? Information about the enabling of some hardware performanceC enhancements that avoid store-and-forward delays for a specific bridge port.2 cutThroughBridgePort> The dot1dBasePort bridge port number for this table entry.2 cutThroughInbound? If true, some hardware performance enhancements ar qe enabled< to avoid store-and-forward delays when packets enter the GIGAswitch.> If false, the whole packet is buffered on the line card at< which the packet enters the GIGAswitch before it is sent? to the line card at which the packet leaves the GIGAswitch.$ Cut-through is normally enabled.2 cutThroughOutbound? If true, some hardware performance enhancements are enabled< to avoid store-and-forward delays when packets leave the GIGAswitch.> If false, rthe whole packet is buffered on the line card at< which the packet leaves the GIGAswitch before it is sent out of the GIGAswitch.$ Cut-through is normally enabled.wwmb1 cutThroughFppnTableA This table controls the enabling of some hardware performanceB enhancements that avoid store-and-forward delays during packet" forwarding, whenever possible.2 cutThroughFppnEntry? Information about the enabling of some hardware performanceC enhancemen sts that avoid store-and-forward delays for a specific front panel port.2 cutThroughFppnPort5 The front panel port number for this table entry.> Front panel port numbers are of the form (slot.connector),= where slot is the slot number the module is plugged into,: and connector is the connector number specified on the front of the card. 2 cutThroughFppnInbound? If true, some hardware performance enhancements are enabled< to avoid store-and-forward del tays when packets enter the GIGAswitch.> If false, the whole packet is buffered on the line card at< which the packet enters the GIGAswitch before it is sent? to the line card at which the packet leaves the GIGAswitch.$ Cut-through is normally enabled.2 cutThroughFppnOutbound? If true, some hardware performance enhancements are enabled< to avoid store-and-forward delays when packets leave the GIGAswitch.> If false, the whole packet is buffered on the line cuard at< which the packet leaves the GIGAswitch before it is sent out of the GIGAswitch.$ Cut-through is normally enabled.ww b1 mgmtMemoryAvail- The number of unused bytes of management , memory available on the clock card. The * management memory is used for storing  management parameters.ww b1 mgmtMemoryAction7 This object, when read, returns a value of other(1): unless it is in the middle of rewriting the manage vment7 memory. At such times, it will return rewriting(3).8 The state will revert to other(1) when the action is completed.: Setting this variable to rewrite(2) will cause the SCP7 to attempt to rewrite the management Memory on the ; clock-card. Attempts to set this variable to all other values result in an error./ Rewriting the management memory gets rid of0 duplicate entries, and thus may increase the3 available space. This action should be allowed3 w to complete before intentionally removing power from the SCP or clock card. ww b 1 pscStatus4 The status of the Power System Controller (PSC).ww b 1 pscFwRev8 The firmware revision of the Power System Controller (PSC).ww b 1 pscHwRev8 The hardware revision of the Power System Controller (PSC).ww b1 keyswitchPosition0 Indicates the position of the keyswitch. The- kexyswitch position determines the type of/ access allowed to network management and to out-of-band management.1 For SNMP access, secure means no SNMP access.4 Local means read-only SNMP access. Other values0 allow read-write SNMP access. All access is7 still subject to the community string, IP address,% and privileged port restrictions. wwb1 pscFwImageStatus, The status of the PSC firmware image. If the value of this object isy+ downloadRequired(2), the manager should- download a new firmware image to the PSC., This can be done by using objects in the gigaUpgradeSoftware group.wwb1 pscBackplaneStatus' Status of the GIGAswitch backplane.wwb1 cabinetTemperature The cabinet temperature.wwb1 temperatureWarning- The value of this variable determines how/ the SCP responds to a condition of too high0 or too low cab zinet temperature, or both both5 fans inoperative. If the value is heedWarning(1) 6 the system will be shut down when the temperature 6 goes outside the designed limits or both fans are 2 inoperative. If the value is ignoreWarning(2),3 the system will continue to operate when either of these conditions occur.4 Setting this variable to ignoreWarning(2) allows4 the manager to cause a system that is too hot or4 too cold to continue to run. This variable will 4 al{so allow both fans to be inoperative and still2 allow the system to continue to run. Managers 4 should note that doing so may be detrimental to  the equipment. 7 This object has a default value of heedWarning(1)."wwb1 rightPowerStatus' The status of the right power unit.wwb1 rightPowerInputSource- The input source of the right power unit.8 A value of ACline(1) is returned if the power supply is connected to an AC |line.: A value of DC48V(2) is returned if the power supply is8 connected to a 48 volt DC (telecommunications) line.; A value of none(3) is returned if the power unit is not present or not powered on.8 See the batteryUsing object to see if the battery or$ this power source is being used. ww Eb1 rightPowerOutputPower/ Output power of right power unit, in watts.ww Eb1 leftPowerStatus& The status of the left power uni}t.ww Eb1 leftPowerInputSource, The input source of the left power unit.8 A value of ACline(1) is returned if the power supply is connected to an AC line.: A value of DC48V(2) is returned if the power supply is8 connected to a 48 volt DC (telecommunications) line.; A value of none(3) is returned if the power unit is not present or not powered on.8 See the batteryUsing object to see if the battery or$ this power source is being used. ~ww Eb1 leftPowerOutputPower. Output power of left power unit, in watts.ww Eb1 slotNumber# The number of slots in the box.ww Eb 1 scpSlot* Identifies the slot the Switch Control0 Processor (SCP) occupies. A value of 0 will . be returned if an SCP has not been chosen.ww Eb 1 slotTable3 Describes the current configuration of the box. 2 slotEntry* The description and status of the card plugged into the slot.ww Eb 1 slotIndex1 The slot number. Varies from 1 to slotNumber.ww Eb1 slotCardStatus+ The status of the card. If the value is1 read as notPresent(1), then the entire entry ! should be considered invalid.. Writing a value of powerDown(2) will cause- the SCP to power down the card. Writing a- value of powerUp(3) will cause the SCP to* power up the card. Writing a value of2 powerDownThenUp(4) will cause the SCP to power3 cycle the line card. Attempts to set any other+ values will result in a badValue error.2 The clock and crossbar cards cannot be powered9 up or down through this object. They are fundamental5 to the GIGAswitch's operation. Unpopulated slots3 are notPresent(1), and can not be powered up or down. wwb1 slotCardType The type of the Card.wwb1 slotCardHwRev- The Hardware revision number of the card.wwb1 slotCardFwRev- The Firmware revision number of the card.wwb 1 fanSpeed The speed of the fans./ Set this variable to maximum(1) for maximum) cooling where noise does not matter. , Set this variable to normal(2) to cause / fan speeds to be under temperature control.wwb1 rightFanStatus% The status of the right fan tray.wwb1 leftFanStatus$ The status of the left fan tray.wwb1 batteryStatus% The status of the backup battery.wwb1 batteryUsing4 The source of power being used for the box. The3 value batteryPower(2) indicates that the backup7 battery unit is being used to power the GIGAswitch.1 The external power line can be either AC or a- 48 volt DC telecommunications power line. wwb1 batteryCharge+ The charge-level o f the backup battery.. Meaningful only if the battery is present.wwb1 batteryTest5 Only the value test(3) can be written. Writes of other values are erroneous.2 This shows the result of the last battery test7 performed. Testing the battery is risky, since the5 GIGAswitch is temporarily switched to run off the4 battery, and if the battery-backup system is not8 working properly, the GIGAswitch fails and restarts.. Meaningful only if the battery is present. wwb 1 fppnTable9 A list of front panel port number to MIB-II interface number mappings. 2 fppnEntry7 Assigns the MIB-II interface ifIndex for a physical+ datalink (cable) connection to the box.wwMRb1 fppnSlotNumber* The 1-based slot number of the module.wwMRb1 fppnPortOfThatSlot/ The 1-based media connection to the module.wwMRb1 fppnIfIndex The assigned MIB-II ifIndex.wwMRb1 fppnBridgePortNumber* The assigned Bridge MIB dot1dBasePort.wwMRb1 mPortTable A list of mPort entries.2 mPortEntry2 A collection of objects containing information for a given mPort MAC entitywwMRb1 mPortSMTIndex> The value of the SMT index associated with this mPort MAC.wwMRb1 mPortMACIndex> The value of the MAC index associated with this mPort MAC.wwMRb1 mPortEnable3 When true, this link will be enabled to operate% in concentrator mode, i.e. mport.wwMRb1 floodUnknownUnicastRate5 The maximum bytes-per-second bandwidth of packets9 multicast because the destination address was not yet learned by the bridge.wwb1 floodMulticastRate5 The maximum bytes-per-second bandwidth of packets2 multicast because the destination address is a multicast address.wwb1 floodTable1 Detailed view of the bridge flooding process.2 floodEntry1 Flooding state for a packet class and source.wwb1 floodQuotaQualifier9 The quota qualifier describes an incoming or outgoing9 port. It is a linear index to the port starting from9 1. If n is the quota qualifier for the first port of5 a two port line card, the quota qualifier for the: second port is n + 1. The clock card and the crossbar; have zero port, so the index must be skipped over those; slots. This numbering scheme may be changed as we have four port line cards.wwb1 floodQuotaClass1 The quota class describes the type of packet.0 Four packet types are classified as follows:$ 1 - Unknown Destination Packets, 2 - Multicast Packets, 3 - IS-IS Packets, 4 - Bursty Control Packetswwb1 floodBytesSent 9 This object is the count of bytes in flooded packets.3 It does not include filtered packets or packets7 discarded due to buffer limitations. Each packet is6 counted once, regardless of the number of outbound" links to which it was flooded. wwb1 floodPacketsSent0 This object is the count of flooded packets.3 It does not include filtered packets or packets7 discarded due to buffer limitations. Each packet is6 counted once, regardless of the number of outbound" links to which it was flooded. wwb1 floodGeezers 9 This object is the count of packets that could not be: flooded because they had remained in the SCP or in the inbound linecard too long. wwb1 floodLosers 8 This object is the count of packets discarded by the9 SCP flooding software (at the interrupt level) due to insufficient buffering. wwb 1 floodHogs 8 This object is the count of packets for which buffer; quota conversion to flooding software optimistic quotas9 failed. This includes packets that were discarded as3 well as packets that were successfully flooded. ww zb1 floodSinglePathDiscards 4 This object is the count of packets discarded to7 prevent packet misordering. Certain protocol types; are considered single-path and may not be delivered out6 of order. If the Destination Address for a packet7 having a single-path protocol type is learned while4 the packet is buffered by the flooding software,8 the packet must be discarded (since line cards would; have been directly forwarding packets using the learned; address while packets received earlier were buffered on the SCP). ww zb1 floodPacketsFiltered 8 This object is the count of packets discarded by the7 flooding software because user-configured filtering3 resulted in no allowed outbound transmit ports. ww zb1 floodPacketsPurged 8 This object is the count of packets discarded due to9 the incoming link leaving FORWARDING state while they' were buffered by flooding software. ww zb1 floodBytesPurged : This object is the byte count in packets discarded due7 to the incoming link leaving FORWARDING state while, they were buffered by flooding software. ww zb"1 floodLocalCopyPacketsDelivered ; This object is the count of multicast packets addressed1 to software modules in the SCP that have been, successfully delivered to those modules. ww zb"1 floodLocalCopyPacketsDiscarded ; This object is the count of multicast packets addressed: to software modules in the SCP that, because of buffer9 limitations, could not be delivered to those modules. wwb1 tftpDestinationwwb1 mopDestinationwwb1 transferFileNamewwb1 transferActionwwb1 transferStatuswwb1 transferSizewwb1 copyToSlot. The slot number of the card which is to be upgraded.6 The object may not be set until the last requested copy succeeds or fails.wwb 1 copyType The type of the image.9 The object is set after a transfer succeeds or fails.wwb1 copyAction1 To initiate a software upgrade of a card, set this object." If copyToSlot is non-zero, and# copyType has a value other than, 'none', and transferStatus has the value0 'success', a software upgrade of the card is attempted. 4 The handler double-checks that the slot requires/ software of the expected type, and provides6 demultiplexing when multiple images may be sent to: the same slot. The power system controller is updated0 by sending its image to the clock card slot.6 The object may not be set until the last requested2 transfer succeeds, and the last requested copy succeeds or fails.0 Reading this object always returns the value none(1).wwb1 copyStatusww b1 deleteTransfer: When read, this object indicates whether the result of7 a file transfer is still present. The value e xists7 indicates that the transferred file is present; the2 value notExist indicates that no file has been, transferred or that it has been deleted.6 Writing the value exists is an error. Writing the0 value notExist deletes the transferred file.6 The object may not be set until the last requested8 transfer succeeds or fails. It may not be set while" a copy is in progress, either.ww b1 arpTimeoutInSeconds3 The maximum amount of time an IP to LAN address9 translation will be used if it cannot be re-verified.ww b1 arpPeriodBetweenRequests3 The time, in seconds, between ARP requests that; are used to verify or to discover an IP to LAN address  translation.ww b1 arpRequestRetries7 The number of times ARP requests are used to verify4 or to discover an IP to LAN address translation.ww b 1 arpAgentww b1 arpStatisticalTable2 arpStatisticalEntry2 arpStatisticalIfIndex2 arpUnicastReceived2 arpBroadcastReceivedww b1 arpRepliesTransmittedww b1 arpFramesFloodedww b1 arpFramesDiscardedwwb 1 snmpDuplicateDiscardIntervalwwb1 gigaStpPortTable A list of gigaStp entries 2 gigaStpPortEntrywwb1 gigaStpPortIfIndex3 The value of the interface associated with this spanning tree port.wwb!1 gigaStpPortSpanningTreeEnable8 When true, this interface will be enabled to operate! as part of the spanning tree.wwb 1 ttSizewwb1 aglInterfaceConfTable 3 This table contains the AGL specific interface 0 configuration parameters, one entry per ATM  interface port. 2 aglInterfaceConfEntry 2 This list contains ATM interface configuration# parameters and state variables. wwb1 aglInterfaceIndex 4 The value of this object identifies the AGL port7 interface for which this entry contains management  information. wwb1 aglInterfacePhyType 9 Indicates the type of physical interface used on the 5 ATM port. Two physical layer types are supported: 1. STS3c/STM1 2. DS3/E35 The type is unknown if the port is not present or) its physical layer type is not known. wwb&1 aglInterfaceTrafficRateGranularity 5 Indicates the granularity in cell/s for assigning3 peak, average and minimum guaranteed rates for 7 traffic shaped circuits on the AGL port. This value8 also represents the minimum rate in cells/s that can9 be assigned to a circuit. The rates subscribed to in 6 the aglVCConnectionTable will be set to a multiple of this rate. ww-b1  aglInterfaceSonetTable 3 This table contains the AGL specific interface 7 configuration parameters for the SONET/SDH physical layer. 2 aglInterfaceSonetEntry 8 This list contains SONET/SDH interface configuration# parameters and state variables. ww-b1 aglInterfaceSonetIndex 0 The value of this object identifies the AGL 0 port interface for which this entry contains. management information and is the same as   aglInterfaceIndex. ww-b1 aglInterfaceSonetMode 6 Specifies whether the PHY operates in SONET STS-3c5 or SDH STM-1 mode. The following code points are used: 1 SONET STS-3c 2 SDH STM-1 ww-b1 aglInterfaceSonetTiming 5 Specifies whether the PHY operates in loop-timing7 or local-timing mode. In loop-timing, the recovered6 clock from the receive signal is used directly to 7 time transmit data. Hence, the PHY is synchronized : to the far-end transmitter. In local timing, transmit 7 data is timed from a local oscillator of frequency 6 155.52 MHz (20ppm). The following code points are used: 1 loop-timing 2 local-timing ww-b1 aglInterfaceDS3E3Table 2 This table contains the AGL specific interface4 configuration parameters for the DS3/E3 physical layer. 2 aglInterfaceDS3E3Entry 5 This list contains DS3/E3 interface configuration# parameters and state variables. ww-b1 aglInterfaceDS3E3Index / The value of this object identifies the AGL0 port interface for which this entry contains- management information and is the same as aglInterfaceIndex. ww-b1 aglInterfaceDS3E3Mode 4 Specifies whether the DS3/E3 PHY operates in low5 power mode for short distances or high power mode7 for longer distances. The following code points are used: 1 low-power 2 high-power ww-b1 aglInterfaceDS3E3Plcp 2 Specifies whether ATM cells may be mapped into4 the DS3 PLCP. In the enabled mode, PLCP framing+ and timing is applied to each ATM cell. wwB b1 aglVCConnectionTable 2 This table contains AGL ATM VCC configuration 3 and performance parameters and state variables.2 Each entry represents a bidirectional traffic flow. 2 aglVCConnectionTableEntry  A bidirectional circuit. wwB b1 aglVCConnectionPortA / The value of this object identifies the AGL2 ATM port A of the VCC segment for FDDI-bridged! and ATM-to-ATM circuit types. wwB b1 aglVCConnectionPortAVpi 2 The VPI value at port A for the bidirectional 1 circuit. The maximum VPI value cannot exceed 7  the number supported by the atmInterfaceMaxVpiBits 3 at AGL ATM port A. This value is used for both  transmit and receive VPIs  wwB b1 aglVCConnectionPortAVci ' The VCI value at the port A for the1 bidirectional circuit. The VCI values from 0 . to 31 are reserved. The maximum VCI value. cannot exceed the number supported by the 1 atmInterfaceMaxVciBits specified for the AGL , ATM port A. This value is used for both  transmit and receive VCIs  wwB b1 aglVCConnectionPortB / The value of this object identifies the AGL0 ATM port B of the VCC segment for ATM-to-ATM2 circuit types. For FDDI-bridged circuit types  this value should be zero.  ww b1 aglVCConnectionPortBVpi 2 The VPI value at port B for the bidirectional / ATM-to-ATM circuit. The maximum VPI value . cannot exceed the number supported by the - atmInterfaceMaxVpiBits at AGL ATM port B.5 This value is used for both transmit and receive 7 VPIs. For other circuit types this value should be zero. ww b1 aglVCConnectionPortBVci ' The VCI value at the port B for the5 bidirectional ATM-to-ATM circuit. The VCI values 5 from 0 to 31 are reserved. The maximum VCI value. cannot exceed the number supported by the 1 atmInterfaceMaxVciBits specified for the AGL 5 ATM port B. This value is used for both transmit 9 and receive VCIs. For other circuit types this value  should be zero. ww b#1 aglVCConnectionTableEntryStatus ) The status column used for creating, ' and deleting bidirectional circuit ' entries in the agl virtual channel  connection table. ww b1 aglVCConnectionTrafficType 3 The value of this object identifies the circuit5 type and characteristics of a particular circuit .1 There are two types of connections supported: 1. FDDI-bridged 2. ATM-to-ATM4 An FDDI-bridged circuit carries all bridged FDDI9 traffic on AGL ATM port A. No information is required4 to be entered for Port B. Only one bridged FDDI 6 circuit per AGL ATM port is supported. The packet 3 format on this circuit is VC based multiplexed ! bridged FDDI as per RFC 1483.8 An ATM-to-ATM circuit carries arbitrary packet types6 between circuits specified on Port A and Port B of5 the GIGAswitch. Multiple ATM-to-ATM circuits are  supported per AGL ATM port. ww b1 aglVCConnectionAALType 5 The value of this object identifies the AAL type 0 that should be used on a particular circuit. ww b1 aglVCConnectionOperStatus 0 This object indicates the operational status- of the VCC, i.e., whether the managed VCC- segment is up or down. In the down state,- no cells can get across this VCC segment.1 The status is unknown if the OAM is disabled. ww b1 aglVCConnectionAdminStatus , This object indicates the desired status- of the VCC, i.e., whether the managed VCC3 segment is enabled or disabled. In the disabled1 state, no cells can be passed across this VCC segment. ww b(1 aglVCConnectionTrafficShaperPeakRate 7 The value of this object specifies the peak rate in8 cells/s that should be used on a particular circuit.3 The peak rate will be set to a multiple of the 3 aglInterfaceTrafficRateGranularity close to the user specified input. ww-Pb'1 aglVCConnectionTrafficShaperAvgRate 3 The value of this object specifies the average 4 (sustained) rate in cells/s that should be used 7 on a particular circuit. The average rate must be 7 less than or equal to the peak rate and it will be 5 set to a multiple of the aglInterfaceTrafficRate-2 Granularity close to the user specified input. "ww-Pb11 aglVCConnectionTrafficShaperMinGuaranteedRate 3 The value of this object specifies the minimum 3 guaranteed rate in cells/s that should be used 2 on a particular circuit. For VBR traffic AGL 9 allows the possibility of overbooking link bandwidth 6 (up to 1200%) to achive statistical multiplexing. 8 This parameter specifies the minimum peak bandwidth 3 that you want to guarantee to the circuit. The 7 minimum guaranteed rate must be less than or equal 6 to the peak rate and it will be set to a multiple 3 of the aglInterfaceTrafficRateGranularity close to the user specified input. ww-Pb(1 aglVCConnectionTrafficShaperPriority : The value of this object specifies the priority which 1 should be given to this circuit in assigning 3 opportunistic bandwidth that arises from AGL's ! bandwidth overbooking policy. ww-Pb1 aglInterfaceATMTable 2 This table contains AGL ATM interface specific settable parameters. 2 aglInterfaceATMTableEntry $ The list of settable parameters. ww-Pb1 aglInterfaceATMIndex 4 The value of this object identifies the AGL port6 interface for which this entry contains management5 information and is the same as aglInterfaceIndex. ww-Pb 1 aglInterfaceATMScrambeStatus , This object indicates the desired status0 of the cell scramble module. In the enabled0 state, outgoing cells are scrambed and input cells are descrambled. ww-Pb1 aglInterfaceATMOAMStatus , This object indicates the desired status/ of the OAM module in the default circuit. + In the enabled state, normal OAM cells $ are exchanged between the peers. ww-Pb'1 aglatmInterfaceNoTrafficEnforcement8 This identifies the no ATM traffic enforcement type.wwb*1 aglatmInterfaceTrafficEnforcementType1: This identifies the ATM traffic enforcement type is 1./ For type 1 traffic enforcement, parameter 17 specifies CLP=0+1 peak traffic. Parameters 2, 3, 41 and 5 are not used. The peak rate is measured in cells per second.wwb*1 aglatmInterfaceTrafficEnforcementType2: This identifies &aglInterfaceSonetModeaglInterfaceSonetTableaglInterfaceSonetTiming4"aglInterfaceTrafficRateGranularity the ATM traffic enforcement type is 2./ For type 2 traffic enforcement, parameter 1. specifies CLP=0 peak traffic and parameter7 2 specifies CLP=0+1 peak traffic. Parameters 3, 4,1 and 5 are not used. The peak rate is measured in cells per second.wwb*1 aglatmInterfaceTrafficEnforcementType3: This identifies the ATM traffic enforcement type is 3./ For type 3 traffic enforcement, parameter 1- specifies CLP=0+1 peak traffic, parameter5 2 specifies CLP=0 sustained rate, and parameter 35 specifies CLP=0 maximum burst size. Parameters 41 and 5 are not used. The peak rate is measured7 in cells per second. The sustained rate is measured< in cells per second and burst size is measured in cells.wwb*1 aglatmInterfaceTrafficEnforcementType4: This identifies the ATM traffic enforcement type is 4./ For type 4 traffic enforcement, parameter 1+ specifies CLP=0 peak traffic, parameter5 aglInterfaceDS3E3Plcp.aglInterfaceDS3E3Table6aglInterfaceIndexaglInterfacePhyType4aglInterfaceSonetIndexebrNportSnapNameSnapfloodBytesPurged floodMulticastRate keyswitchPositionrightPowerOutputPower ttSize'ebrNportSANameTablettSize 2 specifies CLP=0+1 peak traffic, and parameter 3- specifies tagging (e.g., a value 1 may be, used to indicate tagging). Parameters 41 and 5 are not used. The peak rate is measured in cells per second.wwb*1 aglatmInterfaceTrafficEnforcementType5: This identifies the ATM traffic enforcement type is 5./ For type 5 traffic enforcement, parameter 1- specifies CLP=0+1 peak traffic, parameter1 2 specifies CLP=0 sustained rate, parameter 35 specifies CLP=0 maximum burst size, and parameter/ 4 specifies tagging (e.g., a value 1 may be) used to indicate tagging). Parameter 5 is not used.wwb*1 aglatmInterfaceTrafficEnforcementType6: This identifies the ATM traffic enforcement type is 6./ For type 6 traffic enforcement, parameter 1- specifies CLP=0+1 peak traffic, parameter7 2 specifies CLP=0+1 sustained rate, and parameter 3) specifies CLP=0+1 maximum burst size.$ Parameters 4 and 5 are not used.wwm]b*1 aglatmInterfaceTrafficEnforcementType7: This identifies the ATM traffic enforcement type is 7./ For type 7 traffic enforcement, parameter 10 specifies CLP=0+1 peak traffic and parameter# 2 specifies best effort traffic, (e.g., a value 1 may be used to indicate> best effort traffic). Parameters 3, 4 and 5 are not used.wwm]b1 aglatmInterfaceConfTable9 This table contains ATM local interface configp>aglInterfaceATMTableaglInterfaceConfTablepaglInterfaceDS3E3Index\aglInterfaceDS3E3Modeuration' parameters and state variables, one! entry per ATM interface port.2 aglatmInterfaceConfEntry2 This list contains ATM interface configuration# parameters and state variables.2 aglatmInterfaceIndex4 The value of this object identifies the ATM port+ interface for which this entry contains management information.2 aglatmInterfaceMaxVpcs+ The maximum number of VPCs supported at this ATM interface.2 aglatmInterfaceMaxVccs+ The maximum number of VCCs supported at the ATM interface.2 aglatmInterfaceConfVpcs) The number of VPCs configured for use at this ATM interface.2 aglatmInterfaceConfVccs) The number of VCCs configured for use at the ATM interface.#2 aglatmInterfaceMaxActiveVpiBits* The maximum number of active VPI bits, configured for use at the ATM interface.#2 aglatmInterfaceMaxActiveVciBits) The maximum number of active VCI bits- configured for use at this ATM interface.2 aglatmInterfaceIlmiVpiVci0 The decimal value of the three octet VPI/VCI, field that identifies the VCC supporting" the ILMI at the ATM interface.* If the value of this object is greater0 than 16777215 then the ILMI is not supported at the ATM interface.' The default VPI/VCI values for ILMI are VPI=0 and VCI=16.2 aglatmInterfaceSpecific4 This object points to the additional information0 specific to ATM interfaces. For example, if1 Enterprise specific objects have been defined, in addition to this MIB module, then the+ value of this object refers to that MIB. defining these objects. If the additional. information is not present, then the value should be {0 0}.wwm]b1 aglatmInterfaceDs3PlcpTable. This table contains ATM interface DS3 PLCP1 parameters and state variables, one entry per ATM interface port.2 aglatmInterfaceDs3PlcpEntry. This list contains DS3 PLC P parameters and) state variables at the ATM interface.2 aglatmInterfaceDs3PlcpIndex/ The value of this object identifies the ATM' interface port for which this entry. contains management information and is the" same as the atmInterfaceIndex.2 aglatmInterfaceDs3PlcpSEFSs0 A DS3 Severely Errored Framing Second (SEFS)& is a count of one-second intervals% containing one or more SEF event.$2 aglatmInterfaceDs3PlcpAlarmState* This variable indicates if there is an. alarm present for the DS3 PLCP. The value/ receivedFarEndAlarm means that the DS3 PLCP# has received an incoming Yellow, Signal, the value incomingLOF means that3 the DS3 PLCP has declared a loss of frame (LOF), failure condition, and the value noAlarm+ means that there are no alarms present.2 aglatmInterfaceDs3PlcpUASs- The counter associated with the number of0 Unavailable Seconds encountered by the PLCP.wwM&#b1 aglatmIn$&aglatmInterfaceTrafficEnforcementType7aglInterfaceATMIndexaglInterfaceATMOAMStatusaglInterfaceATMScrambeStatus terfaceSonetTCTable. This table contains ATM interface SONET TC, Sublayer parameters and state variables,% one entry per ATM interface port.2 aglatmInterfaceSonetTCEntry3 This list contains SONET TC Sublayer parameters- and state variables at the ATM interface.2 aglatmInterfaceSonetTCIndex/ The value of this object identifies the ATM' interface port for which this entry* contains management information and is& the same as the atmInterfaceIndex.#2 aglatmInterfaceSonetTCOCDEvents' The number of times the Out of Cell- Delineation (OCD) events occur. If seven+ consecutive ATM cells have Header Error2 Control (HEC) violations, an OCD event occurs.6 A high number of OCD events may indicate a problem with the SONET TC Sublayer.$2 aglatmInterfaceSonetTCAlarmState* This variable indicates if there is an7 alarm present for the SONET TC Sublayer. The value' lcdFailure indicates that a Loss of1 Cell Delineation (LCD) failure state has been' declared for the SONET TC Sublayer.wwM&#b1 aglsonetMediumTable The SONET/SDH Medium table.2 aglsonetMediumEntry+ An entry in the SONET/SDH Medium table.2 aglsonetMediumIfIndex7 An index value that uniquely identifies a SONET/SDH" Medium/Section/Line Interface.2 aglsonetMediumType, This variable identifies whether a SONET2 or a SDH signal is used across this interface.2 aglsonetMediumTimeEl apsed, The number of seconds, including partial5 seconds, that have elapsed since the beginning of) the current error-measurement period. 2 aglsonetMediumValidIntervals4 The number of previous intervals for which valid6 data has been stored. A SONET device must support at least n intervals. The minimum value of n is 4. The default of n is 32.! The maximum value of n is 96.- The value of this object will be n unless1 the device was brought onlin e within the last7 (nx15) minutes, in which case the value will be the9 number of complete 15 minute intervals the device has been online.2 aglsonetMediumLineCoding/ This variable describes the line coding for1 this interface. The B3ZS and CMI are used for3 electrical SONET/SDH signals (STS-1 and STS-3)./ The Non-Return to Zero (NRZ) and the Return3 to Zero are used for optical SONET/SDH signals.2 aglsonetMediumLineType- This variable describes the line type for& this interface. The line types are Short and Long Range5 Single Mode fiber or Multi-Mode fiber interfaces,4 and coax and UTP for electrical interfaces. The9 value sonetOther should be used when the Line Type is! not one of the listed values.#2 aglsonetMediumCircuitIdentifier+ This variable contains the transmission( vendor's circuit identifier, for the, purpose of facilitating troubleshooting.ww$b1 aglsonetSectionCurrentTable( The SONET/SDH Section Current table.2 aglsonetSectionCurrentEntry4 An entry in the SONET/SDH Section Current table.!2 aglsonetSectionCurrentIfIndex1 The index value which uniquely identifies the, SONET/SDH Medium/Section/Line Interface. 2 aglsonetSectionCurrentStatus This variable indicates the status of the interface. The sonetSectionStatus is a bit map represented as a sum, therefore,% it can represent multiple defects simultaneously.& The sonetSectionNoDefect should be set if and only if no other flag is set." The various bit positions are: 1 sonetSectionNoDefect 2 sonetSectionLOS 4 sonetSectionLOF2 aglsonetSectionCurrentESs5 The counter associated with the number of Errored& Seconds encountered by a SONET/SDH. Section in the current 15 minute interval.2 aglsonetSectionCurrentSESs- The counter associated with the number of Severely Errored Seconds8 encountered by a SONET/SDH Section in the current 15 minute interval.2 aglsonetSectionCurrentSEFSs- The counter associated with the number of$ Severely Errored Framing Seconds5 encountered by a SONET/SDH Section in the current 15 minute interval.2 aglsonetSectionCurrentCVs4 The counter associated with the number of Coding Violations encountered by a8 SONET/SDH Section in the current 15 minute interval.ww$b1 aglsonetLineCurrentTable% The SONET/SDH Line Current table.2 aglsonetLineCurrentEntry1 An entry in the SONET/SDH Line Current table.2 aglsonetLineCurrentIfIndex1 The index value which uniquely identifies the$ SONET/SDH Medium/Line Interface.2 aglsonetLineCurrentStatus This variable indicates the status of the interface. The sonetLineStatus is a bit map represented as a sum, therefore,% it can represent multiple defects simultaneously.# The sonetLineNoDefect should be set if and only if no other flag is set." The various bit positions are: 1 sonetLineNoDefect 2 sonetLineAIS 4 sonetLineRDI2 aglsonetLineCurrentESs5 The counter associated with the number of Errored& Seconds encountered by a SONET/SDH+ Line in the current 15 minute interval.2 aglsonetLineCurrentSESs- The counter associated with the number of Severely Errored Seconds5 encountered by a SONET/SDH Line in the current 15 minute interval.2 aglsonetLineCurrentCVs4 The counter associated with the number of Coding Violations encountered by a5 SONET/SDH Line in the current 15 minute interval.2 aglsonetLineCurrentUASs- The counter associated with the number of Unavailable Seconds5 encountered by a SONET/SDH Line in the current 15 minute interval.ww3&b1 aglsonetPathCurrentTable% The SONET/SDH Path Current table.2 agls onetPathCurrentEntry1 An entry in the SONET/SDH Path Current table.2 aglsonetPathCurrentIfIndex7 An index value that uniquely identifies a SONET/SDH Path Interface.2 aglsonetPathCurrentWidth4 A value that indicates the type of the SONET/SDH, Path. For SONET, the assigned types are4 the STS-Nc SPEs, where N = 1, 3, 12, 24, and 48.8 STS-1 is equal to 51.84 Mbps. For SDH, the assigned5 types are the STM-Nc VCs, where N = 1, 4, and 16.2 aglsonetPathCurrentStatus This variable indicates the status of the interface. The sonetPathStatus is a bit map represented as a sum, therefore,% it can represent multiple defects simultaneously.# The sonetPathNoDefect should be set if and only if no other flag is set." The various bit positions are: 1 sonetPathNoDefect 2 sonetPathSTSLOP 4 sonetPathSTSAIS 8 sonetPathSTSRDI 16 sonetPathUnequipped% 32 sonetPathSignalLabelMismatch2 aglsonetPathCurrentESs5 The counter associated with the number of Errored& Seconds encountered by a SONET/SDH+ Path in the current 15 minute interval.2 aglsonetPathCurrentSESs- The counter associated with the number of Severely Errored Seconds5 encountered by a SONET/SDH Path in the current 15 minute interval.2 aglsonetPathCurrentCVs4 The counter associated with the number of Coding Violations encountered by a5 SONET/SDH Path in the current 15 minute interval.2 aglsonetPathCurrentUASs- The counter associated with the number of Unavailable Seconds( encountered by a Path in the current 15 minute, interval.ww3&be PBEAUDOIN $minimumGIGAswitchMIBVersionSupported$maximumGIGAswitchMIBVersionSupportedebrNportMatrixNameTableebrNportMatrixFppnValueebrNportSapNameTableebrNportSapNameSapebrNportSapMatrixNameebrNportSapNameStatusebrNportSnapNameTableebrNportSnapNameSnapebrNportSnapMatrixNameebrNportSnapNameStatusebrNportDANameTableebrNportDANameDAebrNportDAMatrixNameebrNportDANameStatusebrNportSANameTableebrNportSANameSAebrNportSAMatrixNameebrNportSANameStatusebrNportMatrixNameRowTableebrNportMatrixAllowedToGoToebrNportMatrixNameRowStatusebrNportMatrixFppnRowTableebrNportMatrixFppnAllowedToGoToebrNportMatrixFppnRowStatusebrNportDefaultMatrixValueebrNportDefaultMatrixFppnValueebrNportNamedDefaultMatrixebrNportDefaultMatrixRowTable"ebrNportDefaultMatrixAllowedToGoToebrNportManualFilterebrNportFppnManualFilterebrNportStaticDATable*ebrNportStaticDAFilterCharacteristicsTableebrNportDASvcTableebrNportPortNumTableebrNportStaticSATable*ebrNportStaticSAFilterCharacteristicsTableebrNportSapProtoTableebrNportSapSvcTable%ebrNportSapFilterCharacteristicsTableebrNportSnapProtoTableebrNportSnapSvcTable&ebrNportSnapFilterCharacteristicsTableebrNportSwTableebrNportSwManualFiltercutThroughTablecutThroughFppnTablemgmtMemoryAvailmgmtMemoryAction pscStatuspscFwRevpscHwRevkeyswitchPositionpscFwImageStatuspscBackplaneStatuscabinetTemperaturetemperatureWarningrightPowerStatusrightPowerInputSourcerightPowerOutputPowerleftPowerStatusleftPowerInputSourceleftPowerOutputPower slotNumberscpSlot slotTable slotIndexslotCardStatus slotCardType slotCardHwRev slotCardFwRevfanSpeedrightFanStatus leftFanStatus batteryStatus batteryUsing batteryCharge batteryTest fppnTablefppnSlotNumberfppnPortOfThatSlot fppnIfIndexfppnBridgePortNumber mPortTable mPortSMTIndex mPortMACIndex mPortEnablefloodUnknownUnicastRatefloodMulticastRate floodTablefloodQuotaQualifierfloodQuotaClassfloodBytesSentfloodPacketsSent floodGeezers floodLosers floodHogsfloodSinglePathDiscardsfloodPacketsFiltered)3&bK PBEAUDOIN floodPacketsPurgedfloodBytesPurgedfloodLocalCopyPacketsDeliveredfloodLocalCopyPacketsDiscardedtftpDestinationmopDestinationtransferFileNametransferActiontransferStatus transferSize copyToSlotcopyType copyAction copyStatusdeleteTransferarpTimeoutInSecondsarpPeriodBetweenRequestsarpRequestRetriesarpAgentarpStatisticalTablearpRepliesTransmittedarpFramesFloodedarpFramesDiscardedsnmpDuplicateDiscardIntervalgigaStpPortTablegigaStpPortIfIndexgigaStpPortSpanningTreeEnablettSizeaglInterfaceConfTableaglInterfaceIndexaglInterfacePhyType"aglInterfaceTrafficRateGranularityaglInterfaceSonetTableaglInterfaceSonetIndexaglInterfaceSonetModeaglInterfaceSonetTimingaglInterfaceDS3E3TableaglInterfaceDS3E3IndexaglInterfaceDS3E3ModeaglInterfaceDS3E3PlcpaglVCConnectionTableaglVCConnectionPortAaglVCConnectionPortAVpiaglVCConnectionPortAVciaglVCConnectionPortBaglVCConnectionPortBVpiaglVCConnectionPortBVciaglVCConnectionTableEntryStatusaglVCConnectionTrafficTypeaglVCConnectionAALTypeaglVCConnectionOperStatusaglVCConnectionAdminStatus$aglVCConnectionTrafficShaperPeakRate#aglVCConnectionTrafficShaperAvgRate-aglVCConnectionTrafficShaperMinGuaranteedRate$aglVCConnectionTrafficShaperPriorityaglInterfaceATMTableaglInterfaceATMIndexaglInterfaceATMScrambeStatusaglInterfaceATMOAMStatus#aglatmInterfaceNoTrafficEnforcement&aglatmInterfaceTrafficEnforcementType1&aglatmInterfaceTrafficEnforcementType2&aglatmInterfaceTrafficEnforcementType3&aglatmInterfaceTrafficEnforcementType4&aglatmInterfaceTrafficEnforcementType5&aglatmInterfaceTrafficEnforcementType6&aglatmInterfaceTrafficEnforcementType7aglatmInterfaceConfTableaglatmInterfaceDs3PlcpTableaglatmInterfaceSonetTCTableaglsonetMediumTableaglsonetSectionCurrentTableaglsonetLineCurrentTableaglsonetPathCurrentTable