-- The GIGAswitch MIB version gigaversion1 -- Thu Jul 9 11:11:11 EDT 1998 GIGASWITCH-MIB DEFINITIONS ::= BEGIN IMPORTS Counter, Gauge, enterprises, IpAddress FROM RFC1155-SMI OBJECT-TYPE FROM RFC-1212 DisplayString, ifIndex FROM RFC1213-MIB; -- DEC-MIB { iso org(3) dod(6) internet(1) private (4) enterprises(1) 36 } dec OBJECT IDENTIFIER ::= { enterprises 36 } ema OBJECT IDENTIFIER ::= { dec 2 } sysobjid OBJECT IDENTIFIER ::= { ema 15 } bridges OBJECT IDENTIFIER ::= { sysobjid 3 } gigaswitch OBJECT IDENTIFIER ::= { bridges 3 } minimumGIGAswitchMIBVersionSupported OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " When new GIGAswitch MIBs are released to the public, 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. " ::= { gigaswitch 1 } maximumGIGAswitchMIBVersionSupported OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " When new GIGAswitch MIBs are released to the public, they will be given new version numbers. The implementation strategy allows multiple versions to be supported simultaneously. MIB versions less than or equal to this version are still supported. A management station may load a MIB which is not supported until the GIGAswitch software is updated. " ::= { gigaswitch 2 } gigaversion1 OBJECT IDENTIFIER ::= { gigaswitch 3 } gigaBox OBJECT IDENTIFIER ::= { gigaversion1 1 } gigaBridge OBJECT IDENTIFIER ::= { gigaversion1 2 } gigaUpgradeSoftware OBJECT IDENTIFIER ::= { gigaversion1 3 } gigaIP OBJECT IDENTIFIER ::= { gigaversion1 4 } gigaSets OBJECT IDENTIFIER ::= { gigaversion1 5 } gigaSnmpDebug OBJECT IDENTIFIER ::= { gigaversion1 6 } gigaXglEthernetGroup OBJECT IDENTIFIER ::= { gigaversion1 7 } serviceClassAssignments OBJECT IDENTIFIER ::= { gigaBridge 5 } filterByReferencedExpression OBJECT IDENTIFIER ::= { gigaBridge 1 } ebrNportMatrixNameTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportMatrixNameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table allows filter matrices to be succinctly specified and named. These matrices may later be used and combined in filter specifications." ::= { filterByReferencedExpression 1 } ebrNportMatrixNameEntry OBJECT-TYPE SYNTAX EbrNportMatrixNameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A particular named filter matrix." INDEX { ebrNportMatrixName } ::= { ebrNportMatrixNameTable 1 } EbrNportMatrixNameEntry ::= SEQUENCE { ebrNportMatrixName DisplayString, ebrNportMatrixValue DisplayString, ebrNportMatrixStatus INTEGER, ebrNportMatrixFppnValue DisplayString } ebrNportMatrixName OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-only STATUS mandatory DESCRIPTION "This name for a filter matrix is whatever the user likes, as long as it is a unique filter matrix name." ::= { ebrNportMatrixNameEntry 1 } ebrNportMatrixValue OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "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: Semicolons separate expressions. Within each expression, 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 range of numbers. If there is no right hand side, the bridge ports on the left cannot send packets to any bridge port (unless the matrix is combined with some some other matrix in a filter specification, or unless the filter is overridden). Bridge port numbers are specified in decimal. A matrix will read back in a form equivalent to the form written. It may not read back exactly as written. No single matrix defines whether a packet arriving on a port is forwarded to its destination. Various destination address, source address, protocol, and default filtering specifications are combined to determine whether the packet is forwarded. If the ebrNportMatrixValue is changed, all filters using it are immediately updated." ::= { ebrNportMatrixNameEntry 2 } ebrNportMatrixStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION "Assigning the value invalid will result in an error while the matrix is still reference by some filter. All matrices are permanent; it is their usage which may or may not be temporary." ::= { ebrNportMatrixNameEntry 3 } ebrNportMatrixFppnValue OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "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 front panel ports on the right hand side. Commas separate items in a list of front panel ports. Hyphens are short-hand for specifying a range of numbers. If there is no right hand side, the front panel ports on the left cannot send packets to any front panel port (unless the matrix is combined with some some 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 form written. It may not read back exactly as written. No single matrix defines whether a packet arriving on a port is forwarded to its destination. Various destination address, source address, protocol, and default filtering specifications are combined to determine whether the packet is forwarded. If the ebrNportMatrixFppnValue is changed, all filters using it are immediately updated. Managers may not specify both ebrNportMatrixValue and ebrNportMatrixFppnValue at the same time to set an entry in this table." ::= { ebrNportMatrixNameEntry 4 } ebrNportSapNameTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSapNameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The filters specified by SAP protocol." ::= { filterByReferencedExpression 2 } ebrNportSapNameEntry OBJECT-TYPE SYNTAX EbrNportSapNameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A portion of a particular filter for a particular SAP protocol." 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 mandatory DESCRIPTION "This name for a portion of a filter is whatever the user likes, as long as it is a unique ebrNportSapName. The combination of ebrNportSapNameSap and ebrNportSapMatrixName is unique within this table. Insertions of new names for pre-existing combinations will be denied. ebrNportSapName is present and is the index to give a mnemonic handle on the combination of SAP and matrix for purposes of discussion and of access through the network management station user interface. SAPs, for example, are often just meaningless numbers unless laborious steps are taken to interpret them. " ::= { ebrNportSapNameEntry 1 } ebrNportSapNameSap OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1)) ACCESS read-write STATUS mandatory DESCRIPTION "The one-byte SAP. Changes to ebrNportSapProtoTable for this SAP are denied while filtering of the SAP is specified by reference to a named matrix using this table." ::= { ebrNportSapNameEntry 2 } ebrNportSapMatrixName OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "A ebrNportMatrixName. Multiple matrices for the same SAP are combined using an elementwise-OR operator." ::= { ebrNportSapNameEntry 3 } ebrNportSapNameDisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION " filter(1) : The filtering for this SAP is specified by the filter matrix. alwaysFilter(2) : Frames of this SAP (protocol) are filtered regardless of any other alwaysForward dispositions based on the frame's address. The filtering information is specified by the filter matrix. alwaysForward(3) : Frames for this SAP (protocol) are sent to ports specified in the filter matrix regardless of any address filter with a disposition of filter. The alwaysForward disposition also overrides a forwarding disposition of filter in the default filter matrix object. Filters with a disposition of alwaysFilter are never superceded. Setting this object will cause a side effect on the ebrNportSapFilterCharacteristicsTable entry for this SAP. It is here to group information for window-based forms. Setting this object will also cause a side effect on other entries in this table with the same SAP value. " ::= { ebrNportSapNameEntry 4 } ebrNportSapNameStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object specifies the permanence of the associated filter matrix, and also provides a means to delete a filter matrix. Writing invalid(1) to the object removes the filter. Writing permanent(2) value to the object indicates the filter is preserved across a bridge reset. " ::= { ebrNportSapNameEntry 5 } ebrNportSnapNameTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSnapNameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The filters specified by Protocol ID for the SNAP SAP." ::= { filterByReferencedExpression 3 } ebrNportSnapNameEntry OBJECT-TYPE SYNTAX EbrNportSnapNameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A portion of a particular filter for a particular Protocol ID." 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 mandatory DESCRIPTION "This name for a portion of a filter is whatever the user likes, as long as it is a unique ebrNportSnapName. The combination of ebrNportSnapNameSnap and ebrNportSnapMatrixName is unique within this table. Insertions of new names for pre-existing combinations will be denied. ebrNportSnapName is present and is the index to give a mnemonic handle on the combination of protocol and matrix for purposes of discussion and of access through the network management station user interface. Protocol IDs, for example, are often just meaningless numbers unless laborious steps are taken to interpret them. " ::= { ebrNportSnapNameEntry 1 } ebrNportSnapNameSnap OBJECT-TYPE SYNTAX OCTET STRING (SIZE (5)) ACCESS read-write STATUS mandatory DESCRIPTION "The five-byte PID. Changes to ebrNportSnapProtoTable for this protocol are denied while filtering of the protocol is specified by reference to a named matrix using this table." ::= { ebrNportSnapNameEntry 2 } ebrNportSnapMatrixName OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "A ebrNportMatrixName. Multiple matrices for the same PID are combined using an elementwise-OR operator." ::= { ebrNportSnapNameEntry 3 } ebrNportSnapNameDisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION " filter(1) : The filtering for this Protocol ID is specified by the filter matrix. alwaysFilter(2) : Frames of this Protocol ID are filtered regardless of any other alwaysForward dispositions based on the frame's address. The filtering information is specified by the filter matrix. alwaysForward(3) : Frames for this Protocol ID are sent to ports specified in the filter matrix regardless of any address filter with a disposition of filter. The alwaysForward disposition also overrides a forwarding disposition of filter in the default filter matrix object. Filters with a disposition of alwaysFilter are never superceded. Setting this object will cause a side effect on the ebrNportSnapFilterCharacteristicsTable entry for this protocol. It is here to group information for window-based forms. Setting this object will also cause a side effect onother entries in this table with the same protocol value. " ::= { ebrNportSnapNameEntry 4 } ebrNportSnapNameStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object specifies the permanence of the associated filter matrix, and also provides a means to delete a filter matrix. Writing invalid(1) to the object removes the filter. Writing permanent(2) value to the object indicates the filter is preserved across a bridge reset. " ::= { ebrNportSnapNameEntry 5 } ebrNportDANameTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportDANameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The filters specified by destination address." ::= { filterByReferencedExpression 4 } ebrNportDANameEntry OBJECT-TYPE SYNTAX EbrNportDANameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A portion of a particular filter for a particular destination address." 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 " This name for a portion of a filter is whatever the user likes, as long as it is a unique ebrNportDAName. The combination of ebrNportDANameDA and ebrNportDAMatrixName is unique within this table. Insertions of new names for pre-existing combinations will be denied. ebrNportDAName is present and is the index to give a mnemonic handle on the combination of address and matrix for purposes of discussion and of access through the network management station user interface. Addresses, for example, are often just meaningless numbers unless laborious steps are taken to interpret them. " ::= { ebrNportDANameEntry 1 } ebrNportDANameDA OBJECT-TYPE SYNTAX OCTET STRING (SIZE (6)) ACCESS read-write STATUS mandatory DESCRIPTION "The six-byte destination address. Changes to ebrNportStaticDATable for this address are denied while filtering of the address is specified by reference to a named matrix using this table." ::= { ebrNportDANameEntry 2 } ebrNportDAMatrixName OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "A ebrNportMatrixName. Multiple matrices for the same address are combined using an elementwise-OR operator." ::= { ebrNportDANameEntry 3 } ebrNportDANameDisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION " filter(1) : The filtering for this address is specified by the filter matrix. alwaysFilter(2) : Frames destined to address are filtered regardless of any other alwaysForward dispositions based on the frame's source address or protocol type. The filtering information is specified by the filter matrix. alwaysForward(3) : Frames destined to address are always forwarded to ebrNportPortNum if specified. The filter matrix is used to specify ports to which frames may be sent. In both cases, this disposition overrides filters based on the frame's source address or protocol type, unless either of those filters has an alwaysFilter disposition. Setting this object will side effect the ebrNportStaticDAFilterCharacteristicsTable entry for this address. It is here to group information for window-based forms. Setting this object will also cause a side effect on other entries in this table with the same address. " ::= { ebrNportDANameEntry 4 } ebrNportDANameStatus OBJECT-TYPE SYNTAX INTEGER { other(1), invalid(2), permanent(3), deleteOnReset(4), deleteOnTimeout(5) } ACCESS read-write STATUS mandatory DESCRIPTION " other(1) - This entry is currently in use, but the conditions under which it will remain so are different from each of the following values. Like other uses of 'other' in MIBs, this value may not be assigned to the object. invalid(2) - Writing this value to the object removes the entry permanent(3) - Writing this value to the object indicates that the entry is preserved across a bridge reset. deleteOnReset(4) - Writing this value removes the permanent entry characteristic. The entry is deleted upon the next bridge reset (SCP or GIGAswitch failure). Writing deleteOnReset is not supported. SNMP does not currently model viewing the non-volatile and volatile data structures independently, which can lead to unexpectedly having no filter if a reset occurs while 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 Bridge MIB (RFC 1286), which describes address filters. 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, the change may in fact take place immediately. Writing deleteOnTimeout is not supported. SNMP does not currently model viewing the non-volatile and volatile data structures independently, which can lead to unexpectedly having no filter if a reset occurs while 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 Bridge MIB (RFC 1286), which describes address filters. " ::= { ebrNportDANameEntry 5 } ebrNportSANameTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSANameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The filters specified by source address." ::= { filterByReferencedExpression 5 } ebrNportSANameEntry OBJECT-TYPE SYNTAX EbrNportSANameEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A portion of a particular filter for a particular source address." INDEX { ebrNportSAName } ::= { ebrNportSANameTable 1 } EbrNportSANameEntry ::= SEQUENCE { ebrNportSAName DisplayString, ebrNportSANameSA OCTET STRING, ebrNportSAMatrixName DisplayString, ebrNportSANameDisp INTEGER, ebrNportSANameStatus INTEGER } ebrNportSAName OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-only STATUS mandatory DESCRIPTION " This name for a portion of a filter is whatever the user likes, as long as it is a unique ebrNportSAName. The combination of ebrNportSANameSA and ebrNportSAMatrixName is unique within this table. Insertions of new names for pre-existing combinations will be denied. ebrNportSAName is present and is the index to give a mnemonic handle on the combination of address and matrix for purposes of discussion and of access through the network management station user interface. Addresses, for example, are often just meaningless numbers unless laborious steps are taken to interpret them. " ::= { ebrNportSANameEntry 1 } ebrNportSANameSA OBJECT-TYPE SYNTAX OCTET STRING (SIZE (6)) ACCESS read-write STATUS mandatory DESCRIPTION "The six-byte source address. Changes to ebrNportStaticSATable for this address are denied while filtering of the address is specified by reference to a named matrix using this table." ::= { ebrNportSANameEntry 2 } ebrNportSAMatrixName OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "A ebrNportMatrixName. Multiple matrices for the same address are combined using an elementwise-OR operator." ::= { ebrNportSANameEntry 3 } ebrNportSANameDisp OBJECT-TYPE SYNTAX INTEGER { portMask(1), alwaysFilter(2), alwaysForward(3), lockdown(4), lockdownportmask(5), filter(6) } ACCESS read-write STATUS mandatory DESCRIPTION "This object specifies how to interpret the ebrNportPortNum and the ebrNportSAMatrixName objects. portMask(1) : The static filtering for this address is specified by the filter matrix. alwaysFilter(2) : Frames sourced from this address are filtered regardless of any other alwaysForward dispositions based on the frame's destination address or protocol type. The static filtering information is specified by the filter matrix. alwaysForward(3) : Frames sourced from this address are sent to ports specified in the filter matrix regardless of any DA or protocol filter with a disposition of filter. The alwaysForward disposition also overrides a forwarding disposition of filter in the default filter matrix object. Filters with a disposition of alwaysFilter are never superceded. lockdown (4) : Frames sourced from this address are ONLY forwarded if received on the same port as ebrNportPortNum. lockdownportmask (5) : Frames sourced from this address are ONLY forwarded if received on the same port as ebrNportPortNum AND if the frame is destined to a permitted port as specified by the filter matrix. filter(6) : The static filtering for this address is specified by the filter matrix. portMask(1) is the different name with the same effect. Setting this object will side effect the ebrNportStaticSAFilterCharacteristicsTable entry for this address. It is here to group information for window-based forms. Setting this object will also cause a side effect on other entries in this table with the same address. " ::= { ebrNportSANameEntry 4 } ebrNportSANameStatus OBJECT-TYPE SYNTAX INTEGER { other(1), invalid(2), permanent(3), deleteOnReset(4), deleteOnTimeout(5) } ACCESS read-write STATUS mandatory DESCRIPTION " other(1) - This entry is currently in use, but the conditions under which it will remain so are different from each of the following values. Like other uses of 'other' in MIBs, this value may not be assigned to the object. invalid(2) - Writing this value to the object removes the entry permanent(3) - Writing this value to the object indicates that the entry is preserved across a bridge reset. deleteOnReset(4) - Writing this value removes the permanent entry characteristic. The entry is deleted upon the next bridge reset (SCP or GIGAswitch failure). Writing deleteOnReset is not supported. SNMP does not currently model viewing the non-volatile and volatile data structures independently, which can lead to unexpectedly having no filter if a reset occurs while 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 Bridge MIB (RFC 1286), which describes address filters. 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, the change may in fact take place immediately. Writing deleteOnTimeout is not supported. SNMP does not currently model viewing the non-volatile and volatile data structures independently, which can lead to unexpectedly having no filter if a reset occurs while 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 Bridge MIB (RFC 1286), which describes address filters. " ::= { ebrNportSANameEntry 5 } ebrNportMatrixNameRowTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportMatrixNameRowEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table is another view of ebrNportMatrixNameTable. Changes to this table cause changes to ebrNportMatrixNameTable. Users or programs can choose whichever matrix specification language they feel more comfortable with. This table also side-steps issues of the worst-case ascii representation length on the part of either ebrNportMatrixNameTable or the management station interface. " ::= { filterByReferencedExpression 8 } ebrNportMatrixNameRowEntry OBJECT-TYPE SYNTAX EbrNportMatrixNameRowEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A particular row of a particular named filter matrix." INDEX { ebrNportmatrixName, ebrNportMatrixReceivePort } ::= { ebrNportMatrixNameRowTable 1 } EbrNportMatrixNameRowEntry ::= SEQUENCE { ebrNportmatrixName DisplayString, ebrNportMatrixReceivePort INTEGER, ebrNportMatrixAllowedToGoTo OCTET STRING, ebrNportMatrixNameRowStatus INTEGER } ebrNportmatrixName OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-only STATUS mandatory DESCRIPTION " This name for a filter matrix is whatever the user likes, as long as it is a unique filter matrix name. Same as ebrNportMatrixName. " ::= { ebrNportMatrixNameRowEntry 1 } ebrNportMatrixReceivePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "A bridge port number. Zero is treated as in other tables, and is short-hand for all rows not previously mentioned." ::= { ebrNportMatrixNameRowEntry 2 } ebrNportMatrixAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-write STATUS mandatory DESCRIPTION "Just like all the other GoTos. 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, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port 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." ::= { ebrNportMatrixNameRowEntry 3 } ebrNportMatrixNameRowStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " Assigning the value invalid will delete the row of the matrix. Attempting to delete the last ebrNportmatrixName entry for a matrix will result in an error while the matrix is still reference by some filter. All matrices are permanent; it is their usage which may or may not be temporary. " ::= { ebrNportMatrixNameRowEntry 4 } ebrNportMatrixFppnRowTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportMatrixFppnRowEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table is yet another view of ebrNportMatrixNameTable. Changes to this table cause changes to ebrNportMatrixNameTable. Users or programs can choose whichever matrix specification language they feel more comfortable with. This table also side-steps issues of the worst-case ascii representation length on the part of either ebrNportMatrixNameTable or the management station interface. " ::= { filterByReferencedExpression 11 } ebrNportMatrixFppnRowEntry OBJECT-TYPE SYNTAX EbrNportMatrixFppnRowEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A particular row of a particular named filter matrix." INDEX { ebrNportmatrixname, ebrNportMatrixFppnReceivePort } ::= { ebrNportMatrixFppnRowTable 1 } EbrNportMatrixFppnRowEntry ::= SEQUENCE { ebrNportmatrixname DisplayString, ebrNportMatrixFppnReceivePort DisplayString, ebrNportMatrixFppnAllowedToGoTo OCTET STRING, ebrNportMatrixFppnRowStatus INTEGER } ebrNportmatrixname OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-only STATUS mandatory DESCRIPTION " This name for a filter matrix is whatever the user likes, as long as it is a unique filter matrix name. Same as ebrNportMatrixName. " ::= { ebrNportMatrixFppnRowEntry 1 } ebrNportMatrixFppnReceivePort OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION " 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." ::= { ebrNportMatrixFppnRowEntry 2 } ebrNportMatrixFppnAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-write STATUS mandatory DESCRIPTION "Just like all the other GoTos. 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, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port is included in the set of ports; the port is not included if its bit has a value of '0'. If the ebrNportMatrixFppnAllowedToGoTo is changed, all filters using it are immediately updated." ::= { ebrNportMatrixFppnRowEntry 3 } ebrNportMatrixFppnRowStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " Assigning the value invalid will delete the row of the matrix. Attempting to delete the last ebrNportmatrixname entry for a matrix will result in an error while the matrix is still reference by some filter. All matrices are permanent; it is their usage which may or may not be temporary. " ::= { ebrNportMatrixFppnRowEntry 4 } ebrNportDefaultMatrixValue OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "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: Semicolons separate expressions. Within each expression, 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 range of numbers. If there is no right hand side, the bridge ports on the left cannot send packets to any bridge port (unless the matrix is combined with some some other matrix in a filter specification, or unless the filter is overridden). Bridge port numbers are specified in decimal. A matrix will read back in a form equivalent to the form written. It may not read back exactly as written. No single matrix defines whether a packet arriving on a port is forwarded to its destination. Various destination address, source 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 the corresponding input ports can communicate with every output port. " ::= { filterByReferencedExpression 6 } ebrNportDefaultMatrixFppnValue OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "A matrix is expressed using a shorthand that says what 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 colon has a left hand side and a right hand side. Front panel ports on the left hand side can send packets to front panel ports on the right hand side. Commas separate items in a list of front panel ports. Hyphens are short-hand for specifying a range of numbers. If there is no right hand side, the front panel ports on the left cannot send packets to any front panel port (unless the matrix is combined with some some 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 form written. It may not read back exactly as written. No single matrix defines whether a packet arriving on a port is forwarded to its destination. Various destination address, source 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 the corresponding input ports can communicate with every output port. " ::= { filterByReferencedExpression 9 } ebrNportNamedDefaultMatrix OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "When a matrix name is written to this object, the default matrix is set to the matrix if and only if the matrix exists. Unspecified rows in the matrix are set to one's, which means that the corresponding input ports can communicate with every output port. " ::= { filterByReferencedExpression 12 } ebrNportDefaultMatrixRowTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportDefaultMatrixRowEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table is another view of ebrNportDefaultMatrixValue. " ::= { filterByReferencedExpression 13 } ebrNportDefaultMatrixRowEntry OBJECT-TYPE SYNTAX EbrNportDefaultMatrixRowEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " A particular row of the default matrix. " INDEX { ebrNportDefaultMatrixReceivePort } ::= { ebrNportDefaultMatrixRowTable 1 } EbrNportDefaultMatrixRowEntry ::= SEQUENCE { ebrNportDefaultMatrixReceivePort INTEGER, ebrNportDefaultMatrixAllowedToGoTo OCTET STRING } ebrNportDefaultMatrixReceivePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "A bridge port number." ::= { ebrNportDefaultMatrixRowEntry 1 } ebrNportDefaultMatrixAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-only STATUS mandatory DESCRIPTION "The set of ports to which frames received from a specific port are allowed to be forwarded by default. Each octet of this object specifies a set of eight ports, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port is included in the set of ports; the port is not included if its bit has a value of '0'. " ::= { ebrNportDefaultMatrixRowEntry 2 } ebrNportManualFilter OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "The list of bridge ports in manual mode is listed. Manual mode means that the bridge purges the learned entries for that port from its forwarding database, stops its learning process on that port, and forwards to that port only frames with destination and source addresses that have been specified via management. A comma-separated list of bridge ports, with hyphens used to abbreviate ranges, is supported. The bridge port numbers are in decimal. " ::= { filterByReferencedExpression 7 } ebrNportFppnManualFilter OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "The list of front panel ports in manual mode is listed. Manual mode means that the bridge purges the learned entries for that port from its forwarding database, stops its learning process on that port, and forwards to that port only frames with destination and source addresses that have been specified via management. A comma-separated list of front panel ports, with hyphens used to abbreviate ranges, 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. " ::= { filterByReferencedExpression 10 } ebrNportFloodMatrixValue OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "A flood matrix is expressed using a shorthand that says what input ports can be flooded to what output ports. Unspecified rows are set to one's, which means that the corresponding input ports can be flooded to every output port. " ::= { filterByReferencedExpression 14 } ebrNportFloodMatrixFppnValue OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "A flood matrix is expressed using a shorthand that says what input front panel ports can be flooded to what output front panel ports. Unspecified rows are set to one's, which means that the corresponding input ports can be flooded to every output port. " ::= { filterByReferencedExpression 15 } ebrNportNamedFloodMatrix OBJECT-TYPE SYNTAX DisplayString (SIZE (32)) ACCESS read-write STATUS mandatory DESCRIPTION "When a matrix name is written to this object, the flood matrix is set to the matrix if and only if the matrix exists. Unspecified rows in the matrix are set to one's, which means that the corresponding input ports can be flooded to every output port. " ::= { filterByReferencedExpression 16 } ebrNportFloodMatrixRowTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportFloodMatrixRowEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table is another view of ebrNportFloodMatrixValue. " ::= { filterByReferencedExpression 17 } ebrNportFloodMatrixRowEntry OBJECT-TYPE SYNTAX EbrNportFloodMatrixRowEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " A particular row of the flood matrix. " INDEX { ebrNportFloodMatrixReceivePort } ::= { ebrNportFloodMatrixRowTable 1 } EbrNportFloodMatrixRowEntry ::= SEQUENCE { ebrNportFloodMatrixReceivePort INTEGER, ebrNportFloodMatrixAllowedToGoTo OCTET STRING } ebrNportFloodMatrixReceivePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "A bridge port number." ::= { ebrNportFloodMatrixRowEntry 1 } ebrNportFloodMatrixAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-only STATUS mandatory DESCRIPTION "The set of ports to which frames received from a specific port are allowed to be flooded by default. " ::= { ebrNportFloodMatrixRowEntry 2 } -- -- these are bridge objects over and above what is required by -- the Bridge MIB [2] -- filterByBitmapValue OBJECT IDENTIFIER ::= { gigaBridge 2 } -- Static Database for N port bridges -- See ebrNportStaticDAFilterCharacteristicsTable for how to delete -- (c.f., overwrite portions of) filter matrices. ebrNportStaticDATable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportStaticDAEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table contains management-specified destination address filtering information about unicast and multicast addresses for N-port bridges. In RFC 1286 lingo, static objects are those objects which have been specified by network management." ::= { filterByBitmapValue 5 } ebrNportStaticDAEntry OBJECT-TYPE SYNTAX EbrNportStaticDAEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Information about a specific MAC address for which the bridge has some management-specified forwarding and/or filtering information." INDEX { ebrNportDAAddress, ebrNportDAReceivePort } ::= { ebrNportStaticDATable 1 } EbrNportStaticDAEntry ::= SEQUENCE { ebrNportDAAddress OCTET STRING, ebrNportDAReceivePort INTEGER, ebrNportDAAllowedToGoTo OCTET STRING } ebrNportDAAddress OBJECT-TYPE SYNTAX OCTET STRING (SIZE (6)) ACCESS read-write STATUS mandatory DESCRIPTION "The destination MAC Address in a frame to which this entry's filtering information applies." ::= { ebrNportStaticDAEntry 1 } ebrNportDAReceivePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The port from which a frame must be received to use the corresponding ebrNportDAAllowedToGoTo field. A value of zero indicates that this entry applies on all ports of the bridge for which there is no other applicable entry." ::= { ebrNportStaticDAEntry 2 } ebrNportDAAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-write STATUS mandatory DESCRIPTION "The set of ports to which frames received from a specific port and destined to the address specified by ebrNportDAAddress are allowed to be forwarded. Each octet of this object specifies a set of eight ports, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port is included in the set of ports; the port is not included if its bit has a value of '0'. Filter matrix rows can be initialized or overwritten, but not 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 " ::= { ebrNportStaticDAEntry 3 } -- The filtering information is modelled, and implemented, using filter -- matrices. The use (disposition) and permanence (status) of the -- filtering information therefore is on a per matrix, not a per row or -- per element basis. The use and permanence are independent of the -- receiving bridge port. Thus we model it in a table distinct from -- receive port/goto for emphasis. -- Basically, it was hard enough getting the minmap bits into the data -- structure used by the bridge coders. Adding per-row status didn't fly, -- and per-row disposition is nonsense. -- -- Were we to model these with the receive port/goto, writing the -- disposition or permanence of one filter matrix row would cause a -- side effect on the values in all the other rows. Also, when dumping -- the table, a lot of redundant information would be presented. ebrNportStaticDAFilterCharacteristicsTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportStaticDAFilterCharacteristicsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains information about how static destination address filters (for unicast and multicast addresses) are used within N-port bridges. Static objects are those objects which have been specified by network management." ::= { filterByBitmapValue 6 } ebrNportStaticDAFilterCharacteristicsEntry OBJECT-TYPE SYNTAX EbrNportStaticDAFilterCharacteristicsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Information about a specific static MAC destination address filter's usage within N-port bridges." INDEX { ebrNportDestinationAddress } ::= { ebrNportStaticDAFilterCharacteristicsTable 1 } EbrNportStaticDAFilterCharacteristicsEntry ::= SEQUENCE { ebrNportDestinationAddress OCTET STRING, ebrNportDADisp INTEGER, ebrNportDAStatus INTEGER } ebrNportDestinationAddress OBJECT-TYPE SYNTAX OCTET STRING (SIZE (6)) ACCESS read-write STATUS mandatory DESCRIPTION "The destination MAC Address in a frame to which this entry's information applies. The value of this object is the same as ebrNportDAAddress." ::= { ebrNportStaticDAFilterCharacteristicsEntry 1 } -- Implementations may require a filter matrix to already exist, or to be -- simultaneously specified, when writing Disp/Status values. ebrNportDADisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION "This object specifies how to interpret the ebrNportPortNum and ebrNportDAAllowedToGoTo objects. filter(1) : The filtering for this address is specified by the filter matrix. alwaysFilter(2) : Frames destined to address are filtered regardless of any other alwaysForward dispositions based on the frame's source address or protocol type. The filtering information is specified by the filter matrix. alwaysForward(3) : Frames destined to address are always forwarded to ebrNportPortNum if specified. The filter matrix is used to specify ports to which frames may be sent. In both cases, this disposition overrides filters based on the frame's source address or protocol type, unless either of those filters has an alwaysFilter disposition. " ::= { ebrNportStaticDAFilterCharacteristicsEntry 2 } ebrNportDAStatus OBJECT-TYPE SYNTAX INTEGER { other(1), invalid(2), permanent(3), deleteOnReset(4), deleteOnTimeout(5) } ACCESS read-write STATUS mandatory DESCRIPTION " other(1) - This entry is currently in use, but the conditions under which it will remain so are different from each of the following values. Like other uses of 'other' in MIBs, this value may not be assigned to the object. invalid(2) - Writing this value to the object removes the entry permanent(3) - Writing this value to the object indicates that the entry is preserved across a bridge reset. deleteOnReset(4) - Writing this value removes the permanent entry characteristic. The entry is deleted upon the next bridge reset (SCP or GIGAswitch failure). Writing deleteOnReset is not supported. SNMP does not currently model viewing the non-volatile and volatile data structures independently, which can lead to unexpectedly having no filter if a reset occurs while 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 Bridge MIB (RFC 1286), which describes address filters. 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, the change may in fact take place immediately. Writing deleteOnTimeout is not supported. SNMP does not currently model viewing the non-volatile and volatile data structures independently, which can lead to unexpectedly having no filter if a reset occurs while 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 Bridge MIB (RFC 1286), which describes address filters. " ::= { ebrNportStaticDAFilterCharacteristicsEntry 3 } -- The service class information applies on a box-wide basis, and is -- independent of the receiving bridge port. Thus we model it in a -- table distinct from ebrNportStaticDATable for emphasis. -- -- Service class and filtering information can be manipulated -- independently. ebrNportDASvcTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportDASvcEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains resource information about unicast and multicast destination addresses for N-port bridges." ::= { serviceClassAssignments 3 } ebrNportDASvcEntry OBJECT-TYPE SYNTAX EbrNportDASvcEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Resource information about a specific MAC destination address for N-port bridges." INDEX { ebrNportSvcAddress } ::= { ebrNportDASvcTable 1 } EbrNportDASvcEntry ::= SEQUENCE { ebrNportSvcAddress OCTET STRING, ebrNportSvc INTEGER, ebrNportSvcStatus INTEGER } ebrNportSvcAddress OBJECT-TYPE SYNTAX OCTET STRING (SIZE (6)) ACCESS read-write STATUS mandatory DESCRIPTION "The destination MAC Address in a frame to which this entry's resource information applies." ::= { ebrNportDASvcEntry 1 } ebrNportSvc OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The service class used to allocate resources and implement 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 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 connote 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. Service classes 1-11 are reserved for internal or future use. " ::= { ebrNportDASvcEntry 2 } ebrNportSvcStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object specifies the permanence of the specified service class usage, and also provides a means to delete an entry. Writing invalid(1) to the object removes the entry. Writing permanent(2) value to the object indicates the entry is preserved across a bridge reset. " ::= { ebrNportDASvcEntry 3 } -- The port number information applies on a box-wide basis, and is -- independent of the receiving bridge port. Thus we model it in a -- table distinct from ebrNportStaticDATable/ebrNportStaticSATable -- for emphasis. ebrNportPortNumTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportPortNumEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains static (i.e., configured by network management) information about the bridge port on which unicast or multicast addresses reside on N-port bridges." ::= { gigaBridge 3 } ebrNportPortNumEntry OBJECT-TYPE SYNTAX EbrNportPortNumEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Information about a specific MAC address." INDEX { ebrNportPortNumAddress } ::= { ebrNportPortNumTable 1 } EbrNportPortNumEntry ::= SEQUENCE { ebrNportPortNumAddress OCTET STRING, ebrNportPortNum INTEGER, ebrNportPortNumStatus INTEGER, ebrNportFppnPortNum DisplayString } ebrNportPortNumAddress OBJECT-TYPE SYNTAX OCTET STRING (SIZE (6)) ACCESS read-write STATUS mandatory DESCRIPTION "The MAC Address to which this entry's information applies." ::= { ebrNportPortNumEntry 1 } ebrNportPortNum OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The Port Number to which this address will be translated (to which frames destined for the address will be forwarded). There are some filtering nuances 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 a bridge port number if it is greater than 127." ::= { ebrNportPortNumEntry 2 } ebrNportPortNumStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object specifies the permanence of the specified information, and also provides a means to delete an entry. Writing invalid(1) to the object removes the entry. Writing permanent(2) value to the object indicates the entry is preserved across a bridge reset. " ::= { ebrNportPortNumEntry 3 } ebrNportFppnPortNum OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION "The Front Panel Port Number to which this address will be translated (to which frames destined for the address will be forwarded). 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. Managers may not specify both ebrNportPortNum and ebrNportFppnPortNum at the same time to set an entry in this table." ::= { ebrNportPortNumEntry 4 } -- See ebrNportStaticSAFilterCharacteristicsTable for how to delete -- (c.f., overwrite portions of) filter matrices. ebrNportStaticSATable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportStaticSAEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains static source address filtering information about unicast and multicast addresses for N-port bridges. Static objects are those objects which have been specified by network management." ::= { filterByBitmapValue 7 } ebrNportStaticSAEntry OBJECT-TYPE SYNTAX EbrNportStaticSAEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Information about a specific MAC address for which the bridge has some static forwarding and/or filtering information." INDEX { ebrNportSAAddress, ebrNportSAReceivePort } ::= { ebrNportStaticSATable 1 } EbrNportStaticSAEntry ::= SEQUENCE { ebrNportSAAddress OCTET STRING, ebrNportSAReceivePort INTEGER, ebrNportSAAllowedToGoTo OCTET STRING } ebrNportSAAddress OBJECT-TYPE SYNTAX OCTET STRING (SIZE (6)) ACCESS read-write STATUS mandatory DESCRIPTION "The source MAC Address in a frame to which this entry's filtering information applies." ::= { ebrNportStaticSAEntry 1 } ebrNportSAReceivePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The port from which a frame must be received to use the 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." ::= { ebrNportStaticSAEntry 2 } ebrNportSAAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-write STATUS mandatory DESCRIPTION "The set of ports to which frames received from a specific port and sourced from the address specified by ebrNportSAAddress are allowed to be forwarded. Each octet of this object specifies a set of eight ports, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port is included in the set of ports; the port is not included if its bit has a value of '0'. Filter matrix rows can be initialized or overwritten, but not 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 " ::= { ebrNportStaticSAEntry 3 } -- The filtering information is modelled, and implemented, using filter -- matrices. The use (disposition) and permanence (status) of the filtering -- information therefore is on a per matrix, not a per row or per element -- basis. The use and permanence are independent of the receiving bridge -- port. Thus we model it in a table distinct from receive port/goto -- for emphasis. -- Basically, it was hard enough getting the minmap bits into the data -- structure used by the bridge coders. Adding per-row status didn't fly, -- and per-row disposition is nonsense. -- -- Were we to model these with the receive port/goto, writing the -- disposition or permanence of one filter matrix row would cause a -- side effect on the values in all the other rows. Also, when dumping -- the table, a lot of redundant information would be presented. ebrNportStaticSAFilterCharacteristicsTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportStaticSAFilterCharacteristicsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains information about how static source address filters (for unicast and multicast addresses) are used within N-port bridges." ::= { filterByBitmapValue 8 } ebrNportStaticSAFilterCharacteristicsEntry OBJECT-TYPE SYNTAX EbrNportStaticSAFilterCharacteristicsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Static source address filter usage for N-port bridges." INDEX { ebrNportSourceAddress } ::= { ebrNportStaticSAFilterCharacteristicsTable 1 } EbrNportStaticSAFilterCharacteristicsEntry ::= SEQUENCE { ebrNportSourceAddress OCTET STRING, ebrNportSADisp INTEGER, ebrNportSAStatus INTEGER } ebrNportSourceAddress OBJECT-TYPE SYNTAX OCTET STRING (SIZE (6)) ACCESS read-write STATUS mandatory DESCRIPTION "The source MAC Address in a frame to which this entry's information applies. The value of this object is the same as ebrNportSAAddress." ::= { ebrNportStaticSAFilterCharacteristicsEntry 1 } -- Implementations may require a filter matrix to already exist, or to be -- simultaneously specified, when writing Disp/Status values. ebrNportSADisp OBJECT-TYPE SYNTAX INTEGER { portMask(1), alwaysFilter(2), alwaysForward(3), lockdown(4), lockdownportmask(5), filter(6) } ACCESS read-write STATUS mandatory DESCRIPTION "This object specifies how to interpret the ebrNportPortNum and and the ebrNportSAAllowedToGoTo objects. portMask(1) : The static filtering for this address is specified by the filter matrix. alwaysFilter(2) : Frames sourced from this address are filtered regardless of any other alwaysForward dispositions based on the frame's destination address or protocol type. The static filtering information is specified by the filter matrix. alwaysForward(3) : Frames sourced from this address are sent to ports specified in the filter matrix regardless of any DA or protocol filter with a disposition of filter. The alwaysForward disposition also overrides a forwarding disposition of filter in the default filter matrix object. Filters with a disposition of alwaysFilter are never superceded. lockdown (4) : Frames sourced from this address are ONLY forwarded if received on the same port as ebrNportPortNum. lockdownportmask (5) : Frames sourced from this address are ONLY forwarded if received on the same port as ebrNportPortNum AND if the frame is destined to a permitted port as specified by the filter matrix. filter(6) : The static filtering for this address is specified by the filter matrix. portMask(1) is the different name with the same effect. " ::= { ebrNportStaticSAFilterCharacteristicsEntry 2 } ebrNportSAStatus OBJECT-TYPE SYNTAX INTEGER { other(1), invalid(2), permanent(3), deleteOnReset(4), deleteOnTimeout(5) } ACCESS read-write STATUS mandatory DESCRIPTION " other(1) - This entry is currently in use, but the conditions under which it will remain so are different from each of the following values. Like other uses of 'other' in MIBs, this value may not be assigned to the object. invalid(2) - Writing this value to the object removes the entry permanent(3) - Writing this value to the object indicates that the entry is preserved across a bridge reset. deleteOnReset(4) - Writing this value removes the permanent entry characteristic. The entry is deleted upon the next bridge reset (SCP or GIGAswitch failure). Writing deleteOnReset is not supported. SNMP does not currently model viewing the non-volatile and volatile data structures independently, which can lead to unexpectedly having no filter if a reset occurs while 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 Bridge MIB (RFC 1286), which describes address filters. 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, the change may in fact take place immediately. Writing deleteOnTimeout is not supported. SNMP does not currently model viewing the non-volatile and volatile data structures independently, which can lead to unexpectedly having no filter if a reset occurs while 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 Bridge MIB (RFC 1286), which describes address filters. " ::= { ebrNportStaticSAFilterCharacteristicsEntry 3 } -- Protocol Database for N-port bridges -- See ebrNportSapFilterCharacteristicsTable for how to delete (c.f., -- overwrite portions of) filter matrices. ebrNportSapProtoTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSapProtoEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains filtering information about 802.2 SAPs in the DSAP field for N-port bridges." ::= { filterByBitmapValue 1 } ebrNportSapProtoEntry OBJECT-TYPE SYNTAX EbrNportSapProtoEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains filtering information about 802.2 SAPs in the DSAP field for N-port bridges." INDEX { ebrNportSapValue, ebrNportSapReceivePort } ::= { ebrNportSapProtoTable 1 } EbrNportSapProtoEntry ::= SEQUENCE { ebrNportSapValue OCTET STRING, ebrNportSapReceivePort INTEGER, ebrNportSapAllowedToGoTo OCTET STRING } ebrNportSapValue OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1)) ACCESS read-write STATUS mandatory DESCRIPTION "The 802.2 DSAP in a frame to which this entry's filtering information applies." ::= { ebrNportSapProtoEntry 1 } ebrNportSapReceivePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The port from which a frame must be received to use the corresponding ebrNportSapAllowedToGoTo. A value of zero indicates that this entry applies on all ports of the bridge for which there is no other applicable entry." ::= { ebrNportSapProtoEntry 2 } ebrNportSapAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-write STATUS mandatory DESCRIPTION "The set of ports to which frames received from 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, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port is included in the set of ports; the port is not included if its bit has a value of '0'. Filter matrix rows can be initialized or overwritten, but not 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 " ::= { ebrNportSapProtoEntry 3 } -- The service class information applies on a box-wide basis, and is -- independent of the receiving bridge port. Thus we model it in a -- table distinct from ebrNportSapProtoTable for emphasis. -- -- Since the ebrNportSapSvcTable and ebrNportSapProtoTable have independent -- status values, the service class and filtering information can be -- manipulated independently. ebrNportSapSvcTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSapSvcEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains resource information (e.g., queuing) about 802.2 SAPs in the DSAP field for N-port bridges." ::= { serviceClassAssignments 1 } ebrNportSapSvcEntry OBJECT-TYPE SYNTAX EbrNportSapSvcEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Resource information about an 802.2 SAP in the DSAP field for N-port bridges." INDEX { ebrNportSapSvcSapValue } ::= { ebrNportSapSvcTable 1 } EbrNportSapSvcEntry ::= SEQUENCE { ebrNportSapSvcSapValue INTEGER, ebrNportSapSvc INTEGER, ebrNportSapSvcStatus INTEGER, ebrNportSapSinglePath DisplayString } ebrNportSapSvcSapValue OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The 802.2 DSAP in a frame to which this entry's resource information applies." ::= { ebrNportSapSvcEntry 1 } ebrNportSapSvc OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The service class used to allocate resources and implement 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. There are 16 possible service classes, 0-15. Service classes 1-11 are reserved for internal or future use. " ::= { ebrNportSapSvcEntry 2 } ebrNportSapSvcStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object specifies the permanence of the specified service class usage, and also provides a means to delete an entry. Writing invalid(1) to the object removes the entry. Writing permanent(2) value to the object indicates the entry is preserved across a bridge reset. " ::= { ebrNportSapSvcEntry 3 } ebrNportSapSinglePath OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " The ebrNportSapSinglePath object is used to set the single path ports for a ebrNportSapSvcSapValue. The default is to not use the default (single path) service class. ebrNportSapSinglePath is expressed using a shorthand that specifies which physical ports are to be set to the default (single path) service class. An example of a specification would be : (1,6-9,21) where commas separate physical ports and hyphens are short-hand for specifying a range of numbers. This example would assign physical ports 1,6,7,8,9, and 21 to use the default (single path) service class, for the given ebrNportSapSvcSapValue. Physical port numbers are specified in decimal. A ebrNportSapSinglePath will read back in a form equivalent to the form written. It may not read back exactly as written. " ::= { ebrNportSapSvcEntry 4 } -- The filtering information is modelled, and implemented, using filter -- matrices. The use (disposition) and permanence (status) of the filtering -- information therefore is on a per matrix, not a per row or per element -- basis. The use and permanence are independent of the receiving bridge -- port. Thus we model it in a table distinct from receive port/goto -- for emphasis. -- Basically, it was hard enough getting the minmap bits into the data -- structure used by the bridge coders. Adding per-row status didn't fly, -- and per-row disposition is nonsense. -- -- Were we to model these with the receive port/goto, writing the -- disposition or permanence of one filter matrix row would cause a -- side effect on the values in all the other rows. Also, when dumping -- the table, a lot of redundant information would be presented. ebrNportSapFilterCharacteristicsTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSapFilterCharacteristicsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains information about how 802.2 DSAP filters are used within N-port bridges." ::= { filterByBitmapValue 2 } ebrNportSapFilterCharacteristicsEntry OBJECT-TYPE SYNTAX EbrNportSapFilterCharacteristicsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "802.2 DSAP filter usage for N-port bridges." INDEX { ebrNportSapFilterCharacteristicsSapValue } ::= { ebrNportSapFilterCharacteristicsTable 1 } EbrNportSapFilterCharacteristicsEntry ::= SEQUENCE { ebrNportSapFilterCharacteristicsSapValue OCTET STRING, ebrNportSapDisp INTEGER, ebrNportSapStatus INTEGER } ebrNportSapFilterCharacteristicsSapValue OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1)) ACCESS read-write STATUS mandatory DESCRIPTION "The 802.2 DSAP in a frame to which this entry's information applies. The value of this object is the same as ebrNportSapValue." ::= { ebrNportSapFilterCharacteristicsEntry 1 } ebrNportSapDisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION "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. alwaysFilter(2) : Frames of this SAP (protocol) are filtered regardless of any other alwaysForward dispositions based on the frame's address. The filtering information is specified by the filter matrix. alwaysForward(3) : Frames for this SAP (protocol) are sent to ports specified in the filter matrix regardless of any address filter with a disposition of filter. The alwaysForward disposition also overrides a forwarding disposition of filter in the default filter matrix object. Filters with a disposition of alwaysFilter are never superceded. " ::= { ebrNportSapFilterCharacteristicsEntry 2 } ebrNportSapStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object specifies the permanence of the associated filter matrix, and also provides a means to delete a filter matrix. Writing invalid(1) to the object removes the filter. Writing permanent(2) value to the object indicates the filter is preserved across a bridge reset. " ::= { ebrNportSapFilterCharacteristicsEntry 3 } -- See ebrNportSnapFilterCharacteristicsTable for how to delete -- (c.f., overwrite portions of) filter matrices ebrNportSnapProtoTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSnapProtoEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains filtering information about 5-byte SNAP Protocol IDs (PIDs) for N-port bridges." ::= { filterByBitmapValue 3 } ebrNportSnapProtoEntry OBJECT-TYPE SYNTAX EbrNportSnapProtoEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains filtering information about 5-byte SNAP Protocol IDs (PIDs) for N-port bridges." INDEX { ebrNportSnapValue, ebrNportSnapReceivePort } ::= { ebrNportSnapProtoTable 1 } EbrNportSnapProtoEntry ::= SEQUENCE { ebrNportSnapValue OCTET STRING, ebrNportSnapReceivePort INTEGER, ebrNportSnapAllowedToGoTo OCTET STRING } ebrNportSnapValue OBJECT-TYPE SYNTAX OCTET STRING (SIZE (5)) ACCESS read-write STATUS mandatory DESCRIPTION "The SNAP Protocol ID (PID) in an 802 frame to which this entry's filtering information applies." ::= { ebrNportSnapProtoEntry 1 } ebrNportSnapReceivePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The port from which a frame must be received to use the corresponding ebrNportSnapAllowedToGoTo. A value of zero indicates that this entry applies on all ports of the bridge for which there is no other applicable entry." ::= { ebrNportSnapProtoEntry 2 } ebrNportSnapAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-write STATUS mandatory DESCRIPTION "The set of ports to which frames received from a specific port and containing the SNAP PID in an 802 frame specified by ebrNportSnapValue are allowed to be forwarded. Each octet of this object specifies a set of eight ports, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port is included in the set of ports; the port is not included if its bit has a value of '0'. Filter matrix rows can be initialized or overwritten, but not 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 " ::= { ebrNportSnapProtoEntry 3 } -- The service class information applies on a box-wide basis, and is -- independent of the receiving bridge port. Thus we model it in a -- table distinct from ebrNportSnapProtoTable for emphasis. -- -- Since the ebrNportSnapSvcTable and ebrNportSnapProtoTable have -- independent status values, the service class and filtering information -- can be manipulated independently. ebrNportSnapSvcTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSnapSvcEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains resource information (e.g., queuing) about 5-byte SNAP Protocol IDs (PIDs) for N-port bridges." ::= { serviceClassAssignments 2 } ebrNportSnapSvcEntry OBJECT-TYPE SYNTAX EbrNportSnapSvcEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Resource information about a 5-byte SNAP Protocol ID (PID) for N-port bridges." INDEX { ebrNportSnapSvcSnapValue } ::= { ebrNportSnapSvcTable 1 } EbrNportSnapSvcEntry ::= SEQUENCE { ebrNportSnapSvcSnapValue OCTET STRING, ebrNportSnapSvc INTEGER, ebrNportSnapSvcStatus INTEGER, ebrNportSnapSinglePath DisplayString } ebrNportSnapSvcSnapValue OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1)) ACCESS read-write STATUS mandatory DESCRIPTION "The SNAP Protocol ID (PID) in a frame to which this entry's resource information applies." ::= { ebrNportSnapSvcEntry 1 } ebrNportSnapSvc OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The service class used to allocate resources and implement 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. There are 16 possible service classes, 0-15. Service classes 1-11 are reserved for internal or future use. " ::= { ebrNportSnapSvcEntry 2 } ebrNportSnapSvcStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object specifies the permanence of the specified service class usage, and also provides a means to delete an entry. Writing invalid(1) to the object removes the entry. Writing permanent(2) value to the object indicates the entry is preserved across a bridge reset. " ::= { ebrNportSnapSvcEntry 3 } ebrNportSnapSinglePath OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " The ebrNportSnapSinglePath object is used to set the single path ports for a ebrNportSnapSvcSnapValue. The default is to not use the default (single path) service class. ebrNportSnapSinglePath is expressed using a shorthand that specifies which physical ports are to be set to the default (single path) service class. An example of a specification would be : (1,6-9,21) where commas separate physical ports and hyphens are short-hand for specifying a range of numbers. This example would assign physical ports 1,6,7,8,9, and 21 to use the default (single path) service class, for the given ebrNportSnapSvcSnapValue. Physical port numbers are specified in decimal. A ebrNportSnapSinglePath will read back in a form equivalent to the form written. It may not read back exactly as written. " ::= { ebrNportSnapSvcEntry 4 } -- The filtering information is modelled, and implemented, using filter -- matrices. The use (disposition) and permanence (status) of the filtering -- information therefore is on a per matrix, not a per row or per element -- basis. The use and permanence are independent of the receiving bridge -- port. Thus we model it in a table distinct from receive port/goto -- for emphasis. -- Basically, it was hard enough getting the minmap bits into the data -- structure used by the bridge coders. Adding per-row status didn't fly, -- and per-row disposition is nonsense. -- -- Were we to model these with the receive port/goto, writing the -- disposition or permanence of one filter matrix row would cause a -- side effect on the values in all the other rows. Also, when dumping -- the table, a lot of redundant information would be presented. ebrNportSnapFilterCharacteristicsTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSnapFilterCharacteristicsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A table that contains information about how SNAP Protocol ID (PID) filters are used within N-port bridges." ::= { filterByBitmapValue 4 } ebrNportSnapFilterCharacteristicsEntry OBJECT-TYPE SYNTAX EbrNportSnapFilterCharacteristicsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "802.2 SNAP Protocol ID (PID) filter usage for N-port bridges." INDEX { ebrNportSnapFilterCharacteristicsSnapValue } ::= { ebrNportSnapFilterCharacteristicsTable 1 } EbrNportSnapFilterCharacteristicsEntry ::= SEQUENCE { ebrNportSnapFilterCharacteristicsSnapValue OCTET STRING, ebrNportSnapDisp INTEGER, ebrNportSnapStatus INTEGER } ebrNportSnapFilterCharacteristicsSnapValue OBJECT-TYPE SYNTAX OCTET STRING (SIZE (1)) ACCESS read-write STATUS mandatory DESCRIPTION "The SNAP Protocol ID (PID) in a frame to which this entry's information applies. The value of this object is the same as ebrNportSnapValue." ::= { ebrNportSnapFilterCharacteristicsEntry 1 } ebrNportSnapDisp OBJECT-TYPE SYNTAX INTEGER { filter(1), alwaysFilter(2), alwaysForward(3) } ACCESS read-write STATUS mandatory DESCRIPTION "This object specifies how to interpret the ebrNportSnapAllowedToGoTo values for the specified SNAP PID. filter(1) : The filtering for this Protocol ID is specified by the filter matrix. alwaysFilter(2) : Frames of this Protocol ID are filtered regardless of any other alwaysForward dispositions based on the frame's address. The filtering information is specified by the filter matrix. alwaysForward(3) : Frames for this Protocol ID are sent to ports specified in the filter matrix regardless of any address filter with a disposition of filter. The alwaysForward disposition also overrides a forwarding disposition of filter in the default filter matrix object. Filters with a disposition of alwaysFilter are never superceded. " ::= { ebrNportSnapFilterCharacteristicsEntry 2 } ebrNportSnapStatus OBJECT-TYPE SYNTAX INTEGER { invalid(1), permanent(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object specifies the permanence of the associated filter matrix, and also provides a means to delete a filter matrix. Writing invalid(1) to the object removes the filter. Writing permanent(2) value to the object indicates the filter is preserved across a bridge reset. " ::= { ebrNportSnapFilterCharacteristicsEntry 3 } ebrNportSwTable OBJECT-TYPE SYNTAX SEQUENCE OF EbrNportSwEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table describes the default filter matrix." ::= { filterByBitmapValue 9 } ebrNportSwEntry OBJECT-TYPE SYNTAX EbrNportSwEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The entry describes a row of the default filter matrix." INDEX { ebrNportSwReceivePort } ::= { ebrNportSwTable 1 } EbrNportSwEntry ::= SEQUENCE { ebrNportSwReceivePort INTEGER, ebrNportSwAllowedToGoTo OCTET STRING } ebrNportSwReceivePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The bridge port on which a frame must be received to use the corresponding ebrNportSwAllowedToGoTo field. A value of zero indicates that this entry applies on all ports of the bridge for which there is no other management-specified entry." ::= { ebrNportSwEntry 1 } ebrNportSwAllowedToGoTo OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-write STATUS mandatory DESCRIPTION "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, the forwarding disposition for the frames received on the ebrNportSwReceivePort interface and sent to one or all of the bridge's interfaces is determined by the ebrNportSwAllowedToGoTo object. Each octet of this object specifies a set of eight ports, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port is included in the set of ports; the port is not included if its bit has a value of '0'. " ::= { ebrNportSwEntry 2 } ebrNportSwManualFilter OBJECT-TYPE SYNTAX OCTET STRING (SIZE (8)) ACCESS read-write STATUS mandatory DESCRIPTION "A switch that controls address filtering. Specifying a one in a bit position says that the port is in manual mode. Each octet of this object specifies a set of eight ports, with the first octet specifying ports 1 through 8, the second octet specifying port 9 through 16 etc. Within each octet, the most significant bit represents the lowest numbered port, and the least significant bit represents the highest numbered port. If a bit has a value of '1', then the corresponding port 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 entries for that port from its forwarding database, stops its learning process on that port, and forwards to that port only frames with destination and source addresses that have been specified via management." ::= { filterByBitmapValue 10 } cutThrough OBJECT IDENTIFIER ::= { gigaBridge 7 } cutThroughTable OBJECT-TYPE SYNTAX SEQUENCE OF CutThroughEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table controls the enabling of some hardware performance enhancements that avoid store-and-forward delays during packet forwarding, whenever possible." ::= { cutThrough 1 } cutThroughEntry OBJECT-TYPE SYNTAX CutThroughEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Information about the enabling of some hardware performance enhancements that avoid store-and-forward delays for a specific bridge port." INDEX { cutThroughBridgePort } ::= { cutThroughTable 1 } CutThroughEntry ::= SEQUENCE { cutThroughBridgePort INTEGER, cutThroughInbound INTEGER, cutThroughOutbound INTEGER } cutThroughBridgePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The dot1dBasePort bridge port number for this table entry." ::= { cutThroughEntry 1 } cutThroughInbound OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION "If true, some hardware performance enhancements are 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." ::= { cutThroughEntry 2 } cutThroughOutbound OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION "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 card at which the packet leaves the GIGAswitch before it is sent out of the GIGAswitch. Cut-through is normally enabled." ::= { cutThroughEntry 3 } cutThroughFppnTable OBJECT-TYPE SYNTAX SEQUENCE OF CutThroughFppnEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table controls the enabling of some hardware performance enhancements that avoid store-and-forward delays during packet forwarding, whenever possible." ::= { cutThrough 2 } cutThroughFppnEntry OBJECT-TYPE SYNTAX CutThroughFppnEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Information about the enabling of some hardware performance enhancements that avoid store-and-forward delays for a specific front panel port." INDEX { cutThroughFppnPort } ::= { cutThroughFppnTable 1 } CutThroughFppnEntry ::= SEQUENCE { cutThroughFppnPort DisplayString, cutThroughFppnInbound INTEGER, cutThroughFppnOutbound INTEGER } cutThroughFppnPort OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION "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. " ::= { cutThroughFppnEntry 1 } cutThroughFppnInbound OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION "If true, some hardware performance enhancements are 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." ::= { cutThroughFppnEntry 2 } cutThroughFppnOutbound OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION "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 card at which the packet leaves the GIGAswitch before it is sent out of the GIGAswitch. Cut-through is normally enabled." ::= { cutThroughFppnEntry 3 } -- the gigaBox group -- subgroups under the gigaBox group clockCard OBJECT IDENTIFIER ::= { gigaBox 1 } psc OBJECT IDENTIFIER ::= { gigaBox 2 } powerSupply OBJECT IDENTIFIER ::= { gigaBox 3 } slot OBJECT IDENTIFIER ::= { gigaBox 4 } fan OBJECT IDENTIFIER ::= { gigaBox 5 } battery OBJECT IDENTIFIER ::= { gigaBox 6 } fppn OBJECT IDENTIFIER ::= { gigaBox 7 } lineCard OBJECT IDENTIFIER ::= { gigaBox 8 } led OBJECT IDENTIFIER ::= { gigaBox 9 } -- The clockCard subgroup -- clock card Firmware and hardware rev can be obtained from -- slotTable. would be redundant if placed here too. mgmtMemoryAvail OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The number of unused bytes of management memory available on the clock card. The management memory is used for storing management parameters." ::= { clockCard 1 } mgmtMemoryAction OBJECT-TYPE SYNTAX INTEGER { other(1), rewrite(2), rewriting(3), clearAndLock(4), locked(5) } ACCESS read-write STATUS mandatory DESCRIPTION "This object, when read, returns a value of other(1) unless it is in the middle of rewriting the management memory. At such times, it will return rewriting(3). The state will revert to other(1) when the action is completed. Setting this variable to rewrite(2) will cause the SCP 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 of duplicate entries, and thus may increase the available space. This action should be allowed to complete before intentionally removing power from the SCP or clock card. If the value is set to clearAndLock(4), management memory is completely erased. From this point on, SNMP operations that write management memory will fail, except for sets to the mgmtMemoryData object. In fact, the clearAndLock action must be set before management memory can be re-written using the mgmtMemoryData object. The GIGAswitch must be rebooted after the clearAndLock action (and after it has been re-written, if so desired) in order to allow future SNMP operations to be logged to management memory. " ::= { clockCard 2 } mgmtMemoryTable OBJECT-TYPE SYNTAX SEQUENCE OF MgmtMemoryEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The table for managing management memory." ::= { clockCard 3 } mgmtMemoryEntry OBJECT-TYPE SYNTAX MgmtMemoryEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A record of management memory." INDEX { mgmtMemoryIndex } ::= { mgmtMemoryTable 1 } MgmtMemoryEntry ::= SEQUENCE { mgmtMemoryIndex INTEGER, mgmtMemoryData OCTET STRING (SIZE(1..80)) } mgmtMemoryIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Index of 80 byte binary records" ::= { mgmtMemoryEntry 1 } mgmtMemoryData OBJECT-TYPE SYNTAX OCTET STRING (SIZE(1..80)) ACCESS read-write STATUS mandatory DESCRIPTION " SNMP object mgmtMemoryData allows the user to read management memory and, with certain restrictions, to write it as well. In particular, this object allows the user to read a management memory image and, at a later time, restore it. Management memory is accessed in uninterpreted 80-byte binary records, numbered starting from 1. As a result, doing a GET of instance number N will return bytes 80*(N-1) through 80*N-1 from management memory. If an attempt is made to read beyond the end of written flash, an error is returned; if a read of a record spans the end of written flash, only the valid data is returned. To restore a management memory image, management memory must first be cleared and locked using the clearAndLock action on the mgmtMemoryAction object. Then management memory may be written sequentially, writing 80 bytes at a time until the last write, at which point less than 80 bytes may be written. During this operation, and until the GIGAswitch is rebooted, other SNMP sets requiring writes to management memory may not be done. It is therefore recommended that the GIGAswitch be booted as soon as possible after management memory has been restored. Any attempt to write a management memory record out of sequence, for example writing record 5 followed by record 4 or record 7, results in an error. " ::= { mgmtMemoryEntry 2 } -- The psc subgroup (Power System Controller) pscStatus OBJECT-TYPE SYNTAX INTEGER { notPresent(1), okay(2), fault(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The status of the Power System Controller (PSC)." ::= { psc 1 } pscFwRev OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION "The firmware revision of the Power System Controller (PSC)." ::= { psc 2 } pscHwRev OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION "The hardware revision of the Power System Controller (PSC)." ::= { psc 3 } keyswitchPosition OBJECT-TYPE SYNTAX INTEGER { fault(1), secure(2), local(3), remote(4), worldAccess(5) } ACCESS read-only STATUS mandatory DESCRIPTION "Indicates the position of the keyswitch. The keyswitch position determines the type of access allowed to network management and to out-of-band management. For SNMP access, secure means no SNMP access. Local means read-only SNMP access. Other values allow read-write SNMP access. All access is still subject to the community string, IP address, and privileged port restrictions. " ::= { psc 4 } pscFwImageStatus OBJECT-TYPE SYNTAX INTEGER { okay(1), downloadRequired(2) } ACCESS read-only STATUS mandatory DESCRIPTION "The status of the PSC firmware image. If the value of this object is downloadRequired(2), the manager should download a new firmware image to the PSC. This can be done by using objects in the gigaUpgradeSoftware group." ::= { psc 5 } pscBackplaneStatus OBJECT-TYPE SYNTAX INTEGER { okay(1), fault(2) } ACCESS read-only STATUS mandatory DESCRIPTION "Status of the GIGAswitch backplane." ::= { psc 6 } cabinetTemperature OBJECT-TYPE SYNTAX INTEGER { normal(1), high(2), excessivelyHigh(3), low(4), excessivelyLow(5) } ACCESS read-only STATUS mandatory DESCRIPTION "The cabinet temperature." ::= { psc 7 } temperatureWarning OBJECT-TYPE SYNTAX INTEGER { heedWarning(1), ignoreWarning(2) } ACCESS read-write STATUS mandatory DESCRIPTION "The value of this variable determines how the SCP responds to a condition of too high or too low cabinet temperature, or both both fans inoperative. If the value is heedWarning(1) the system will be shut down when the temperature goes outside the designed limits or both fans are inoperative. If the value is ignoreWarning(2), the system will continue to operate when either of these conditions occur. Setting this variable to ignoreWarning(2) allows the manager to cause a system that is too hot or too cold to continue to run. This variable will also allow both fans to be inoperative and still allow the system to continue to run. Managers should note that doing so may be detrimental to the equipment. This object has a default value of heedWarning(1)." ::= { psc 8 } -- The powerSupply subgroup rightPowerStatus OBJECT-TYPE SYNTAX INTEGER { notPresent(1), okay(2), fault(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The status of the right power unit." ::= { powerSupply 1 } rightPowerInputSource OBJECT-TYPE SYNTAX INTEGER { acLine(1), dc48V(2), none(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The input source of the right power unit. 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 is 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. See the batteryUsing object to see if the battery or this power source is being used. " ::= { powerSupply 2 } rightPowerOutputPower OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Output power of right power unit, in watts." ::= { powerSupply 3 } leftPowerStatus OBJECT-TYPE SYNTAX INTEGER { notPresent(1), okay(2), fault(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The status of the left power unit." ::= { powerSupply 4 } leftPowerInputSource OBJECT-TYPE SYNTAX INTEGER { acLine(1), dc48V(2), none(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The input source of the left power unit. 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 is 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. See the batteryUsing object to see if the battery or this power source is being used. " ::= { powerSupply 5 } leftPowerOutputPower OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Output power of left power unit, in watts." ::= { powerSupply 6 } -- The slot subgroup slotNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The number of slots in the box." ::= { slot 1 } scpSlot OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Identifies the slot the Switch Control Processor (SCP) occupies. A value of 0 will be returned if an SCP has not been chosen." ::= { slot 2 } slotTable OBJECT-TYPE SYNTAX SEQUENCE OF SlotEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Describes the current configuration of the box." ::= { slot 3 } slotEntry OBJECT-TYPE SYNTAX SlotEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The description and status of the card plugged into the slot." INDEX { slotIndex } ::= { slotTable 1 } SlotEntry ::= SEQUENCE { slotIndex INTEGER, slotCardStatus INTEGER, slotCardType INTEGER, slotCardHwRev DisplayString, slotCardFwRev DisplayString } slotIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The slot number. Varies from 1 to slotNumber." ::= { slotEntry 1 } slotCardStatus OBJECT-TYPE SYNTAX INTEGER { notPresent(1), powerDown(2), -- present but not poweredUp powerUp(3), -- present and poweredUp powerDownThenUp(4), -- for upgrading the FGL FW fault(5), revisionMismatch(6), selfTestInProgress(7) } ACCESS read-write STATUS mandatory DESCRIPTION "The status of the card. If the value is 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 of powerDownThenUp(4) will cause the SCP to power cycle the line card. Attempts to set any other values will result in a badValue error. The clock and crossbar cards cannot be powered up or down through this object. They are fundamental to the GIGAswitch's operation. Unpopulated slots are notPresent(1), and can not be powered up or down. " ::= { slotEntry 2 } slotCardType OBJECT-TYPE SYNTAX INTEGER { other(1), -- none of the following fgl2(2), cbs36(3), switchEngine(4), clockCard(5), agl-2(6), fgl4(7), agl-2-plus(8), xgl2(9), xgl4(10), gs2000(11), gs2000-plus(12) } ACCESS read-only STATUS mandatory DESCRIPTION "The type of the Card." ::= { slotEntry 3 } slotCardHwRev OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION "The Hardware revision number of the card." ::= { slotEntry 4 } slotCardFwRev OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION "The Firmware revision number of the card." ::= { slotEntry 5 } -- The hostSlotTable is used to store information about modules -- which are hosted in the GIGAswitch/FDDI. hostSlotTable OBJECT-TYPE SYNTAX SEQUENCE OF HostSlotEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Describes the current IP address and community string of any modules which are hosted in the switch (eg GS2000)." ::= { slot 4 } hostSlotEntry OBJECT-TYPE SYNTAX HostSlotEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The IP and community of the module hosted in the slot corresponding to the index." INDEX { hostSlotIndex } ::= { hostSlotTable 1 } HostSlotEntry ::= SEQUENCE { hostSlotIndex INTEGER, hostIP IpAddress } hostSlotIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The slot number. Varies from 1 to slotNumber." ::= { hostSlotEntry 1 } hostIP OBJECT-TYPE SYNTAX IpAddress ACCESS read-write STATUS mandatory DESCRIPTION "The IP address of the hosted module." ::= { hostSlotEntry 2 } -- The fan subgroup fanSpeed OBJECT-TYPE SYNTAX INTEGER { maximum(1), normal(2) } ACCESS read-write STATUS mandatory DESCRIPTION " 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." ::= { fan 1 } rightFanStatus OBJECT-TYPE SYNTAX INTEGER { notPresent(1), okay(2), fault(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The status of the right fan tray." ::= { fan 2 } leftFanStatus OBJECT-TYPE SYNTAX INTEGER { notPresent(1), okay(2), fault(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The status of the left fan tray." ::= { fan 3 } -- The battery subgroup -- There is no battery at FRS, so this object will read notPresent(1). batteryStatus OBJECT-TYPE SYNTAX INTEGER { notPresent(1), okay(2), fault(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The status of the backup battery." ::= { battery 1 } -- There is no battery at FRS, so this object is read-only and -- will read externalPower(1). -- When the battery is available, and this is made read-write, -- the same delicacies as batteryTest would apply. -- Write this object to force the GIGAswitch to -- use power from the external power supplies, -- or from the backup battery. batteryUsing OBJECT-TYPE SYNTAX INTEGER { batteryPower(1), externalPower(2) } ACCESS read-only STATUS mandatory DESCRIPTION "The source of power being used for the box. The value batteryPower(2) indicates that the backup battery unit is being used to power the GIGAswitch. The external power line can be either AC or a 48 volt DC telecommunications power line. " ::= { battery 2 } batteryCharge OBJECT-TYPE SYNTAX INTEGER { fullyCharged(1), okay(2), low(3) } ACCESS read-only STATUS mandatory DESCRIPTION "The charge-level of the backup battery. Meaningful only if the battery is present." ::= { battery 3 } -- There is no battery at FRS, so this object is read-only. batteryTest OBJECT-TYPE SYNTAX INTEGER { pass(1), fail(2), test(3) } ACCESS read-only STATUS mandatory DESCRIPTION "Only the value test(3) can be written. Writes of other values are erroneous. This shows the result of the last battery test performed. Testing the battery is risky, since the GIGAswitch is temporarily switched to run off the battery, and if the battery-backup system is not working properly, the GIGAswitch fails and restarts. Meaningful only if the battery is present. " ::= { battery 4 } -- The fppn subgroup -- Make the table read-write if ever introduce card types with more -- datalinks than switch ports, to allow new cards to be added while -- preserving utility of management memory contents. fppnTable OBJECT-TYPE SYNTAX SEQUENCE OF FppnEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A list of front panel port number to MIB-II interface number mappings." ::= { fppn 1 } fppnEntry OBJECT-TYPE SYNTAX FppnEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Assigns the MIB-II interface ifIndex for a physical datalink (cable) connection to the box." INDEX { fppnSlotNumber, fppnPortOfThatSlot } ::= { fppnTable 1 } FppnEntry ::= SEQUENCE { fppnSlotNumber INTEGER, fppnPortOfThatSlot INTEGER, fppnIfIndex INTEGER, fppnBridgePortNumber INTEGER } fppnSlotNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The 1-based slot number of the module." ::= { fppnEntry 1 } fppnPortOfThatSlot OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The 1-based media connection to the module." ::= { fppnEntry 2 } fppnIfIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The assigned MIB-II ifIndex." ::= { fppnEntry 3 } -- Save searching through the dot1dBasePortTable to find the -- dot1dBasePort for a dot1dBasePortIfIndex when plug a cable -- into the box and want to set a filter. fppnBridgePortNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The assigned Bridge MIB dot1dBasePort." ::= { fppnEntry 4 } -- The lineCard subgroup mPortTable OBJECT-TYPE SYNTAX SEQUENCE OF MPortEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A list of mPort entries." ::= { lineCard 1 } mPortEntry OBJECT-TYPE SYNTAX MPortEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A collection of objects containing information for a given mPort MAC entity" INDEX { mPortSMTIndex, mPortMACIndex } ::= { mPortTable 1 } MPortEntry ::= SEQUENCE { mPortSMTIndex INTEGER, mPortMACIndex INTEGER, mPortEnable INTEGER } mPortSMTIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The value of the SMT index associated with this mPort MAC." ::= { mPortEntry 1 } mPortMACIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The value of the MAC index associated with this mPort MAC." ::= { mPortEntry 2 } mPortEnable OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION "When true, this link will be enabled to operate in concentrator mode, i.e. mport." ::= { mPortEntry 3 } -- The led subgroup ledTable OBJECT-TYPE SYNTAX SEQUENCE OF LedTableEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A list of LED entries, one for each module." ::= { led 1 } ledTableEntry OBJECT-TYPE SYNTAX LedTableEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Each entry describes the state of one module." INDEX { ledTableIndex } ::= { ledTable 1 } LedTableEntry ::= SEQUENCE { ledTableIndex INTEGER, ledCount INTEGER } ledTableIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The module index into the table. " ::= { ledTableEntry 1 } ledCount OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The number of LEDs on this module." ::= { ledTableEntry 2 } ledSlotTable OBJECT-TYPE SYNTAX SEQUENCE OF LedEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "A list of LED entries, one for each module LED." ::= { led 2 } ledEntry OBJECT-TYPE SYNTAX LedEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Each entry describes the state of one module LED." INDEX { ledSlotIndex, ledLedIndex } ::= { ledSlotTable 1 } LedEntry ::= SEQUENCE { ledSlotIndex INTEGER, ledLedIndex INTEGER, ledDescr DisplayString, ledProgram OCTET STRING } ledSlotIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The slot index into the table. " ::= { ledEntry 1 } ledLedIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The led index within the slot given by slotIndex." ::= { ledEntry 2 } ledDescr OBJECT-TYPE SYNTAX DisplayString (SIZE(0..80)) ACCESS read-only STATUS mandatory DESCRIPTION "A textual description of the information which the LED is meant to convey. i.e.: +5 Volt Power, DC Okay ATM port activity. Diagnostic status." ::= { ledEntry 3 } ledProgram OBJECT-TYPE SYNTAX OCTET STRING (SIZE(0..48)) ACCESS read-only STATUS mandatory DESCRIPTION "The ledProgram string is a sequence of instructions for the LED state. The LED constantly repeats the program. Each LED state is represented by a two octet sequence where the value of the first octet of the pair indicates the color of the LED, and the value of the second octet of the pair indicates the duration in which that color will be present. +----------+----------+ --/ /-- +----------+----------+ | Color | Duration | | Color | Duration | +----------+----------+ --/ /-- +----------+----------+ The 'color' octet may have one of the following values: 0 - off 1 - other 2 - red 3 - yellow 4 - green 5 - blue 6 - red-blinking 7 - yellow-blinking 8 - blue-blinking 9 - green-blinking The value 'off' indicates that the LED is off. The value 'other' indicates a color not covered by any others in the list. The value of the second octet in each pair indicates the duration in which that color will be present. A value of zero indicates that the LED is off. A value of 0xff indicates that the LED is always on. Values in between 0 and 0xff indicate the duration in 10 ms ticks. A zero length string may be returned if the LED is 'not present'. This indicates that the LED is currently not visible. Activity LEDs are a special case. Activity LEDs are defined as LEDs which blink whenever data is received on the line. They are typically on solid under heavy activity. Since these LEDs can change rapidly, the following rules apply: o The initial state of activity LEDs is off. o If the line shows activity any time in a 10 second period, then the LED is shown as on. o If the line shown inactivity any time in a 10 second period, then the LED is shown as off. See the 'pcomLedProgram' object in the DECHUB900-COMMON MIB for examples." ::= { ledEntry 4 } -- the gigaBridge group flooding OBJECT IDENTIFIER ::= { gigaBridge 6 } floodUnknownUnicastRate OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The maximum bytes-per-second bandwidth of packets multicast because the destination address was not yet learned by the bridge. The resolution of this value is 100 bytes-per-second. The 2 LS digits are rounded down to zero, i.e. 1-99 => 0." ::= { flooding 1 } floodMulticastRate OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The maximum bytes-per-second bandwidth of packets multicast because the destination address is a multicast address.The resolution of this value is 100 bytes-per-second. The 2 LS digits are rounded down to zero, i.e. 1-99 => 0." ::= { flooding 2 } floodTable OBJECT-TYPE SYNTAX SEQUENCE OF FloodEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Detailed view of the bridge flooding process." ::= { flooding 3 } floodEntry OBJECT-TYPE SYNTAX FloodEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Flooding state for a packet class and source." INDEX { floodQuotaQualifier, floodQuotaClass } ::= { floodTable 1 } FloodEntry ::= SEQUENCE { floodQuotaQualifier INTEGER, floodQuotaClass INTEGER, floodBytesSent Counter, floodPacketsSent Counter, floodGeezers Counter, floodLosers Counter, floodHogs Counter, floodSinglePathDiscards Counter, floodPacketsFiltered Counter, floodPacketsPurged Counter, floodBytesPurged Counter, floodLocalCopyPacketsDelivered Counter, floodLocalCopyPacketsDiscarded Counter } floodQuotaQualifier OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The quota qualifier describes an incoming or outgoing port. It is a linear index to the port starting from 1. If n is the quota qualifier for the first port of 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." ::= { floodEntry 1 } floodQuotaClass OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The quota class describes the type of packet. Four packet types are classified as follows: 1 - Unknown Destination Packets, 2 - Multicast Packets, 3 - IS-IS Packets, 4 - Bursty Control Packets" ::= { floodEntry 2 } floodBytesSent OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the count of bytes in flooded packets. It does not include filtered packets or packets discarded due to buffer limitations. Each packet is counted once, regardless of the number of outbound links to which it was flooded. " ::= { floodEntry 3 } floodPacketsSent OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION "This object is the count of flooded packets. It does not include filtered packets or packets discarded due to buffer limitations. Each packet is counted once, regardless of the number of outbound links to which it was flooded. " ::= { floodEntry 4 } floodGeezers OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " 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. " ::= { floodEntry 5 } floodLosers OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the count of packets discarded by the SCP flooding software (at the interrupt level) due to insufficient buffering. " ::= { floodEntry 6 } floodHogs OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the count of packets for which buffer quota conversion to flooding software optimistic quotas failed. This includes packets that were discarded as well as packets that were successfully flooded. " ::= { floodEntry 7 } floodSinglePathDiscards OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the count of packets discarded to prevent packet misordering. Certain protocol types are considered single-path and may not be delivered out of order. If the Destination Address for a packet having a single-path protocol type is learned while the packet is buffered by the flooding software, 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). " ::= { floodEntry 8 } floodPacketsFiltered OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the count of packets discarded by the flooding software because user-configured filtering resulted in no allowed outbound transmit ports. " ::= { floodEntry 9 } floodPacketsPurged OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the count of packets discarded due to the incoming link leaving FORWARDING state while they were buffered by flooding software. " ::= { floodEntry 10 } floodBytesPurged OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the byte count in packets discarded due to the incoming link leaving FORWARDING state while they were buffered by flooding software. " ::= { floodEntry 11 } floodLocalCopyPacketsDelivered OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the count of multicast packets addressed to software modules in the SCP that have been successfully delivered to those modules. " ::= { floodEntry 12 } floodLocalCopyPacketsDiscarded OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " This object is the count of multicast packets addressed to software modules in the SCP that, because of buffer limitations, could not be delivered to those modules. " ::= { floodEntry 13 } -- gigaSnmpDebug group commitFails OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "Exercise abort undo code in SNMP commit processing" ::= { gigaSnmpDebug 1 } -- gigaUpgradeSoftware group -- Upgrading software is a two-step process. First the file is -- transfered, then it is copied to each destination. This way, -- all the (FDDI) line cards can be updated with a single TFTP -- or MOP transfer. doTransfer OBJECT IDENTIFIER ::= { gigaUpgradeSoftware 1 } useTransfer OBJECT IDENTIFIER ::= { gigaUpgradeSoftware 2 } tftpDestination OBJECT-TYPE SYNTAX IpAddress ACCESS read-write STATUS mandatory DESCRIPTION "This object is the IP address of the host storing the file containing the software image. The object may not be set until the last requested transfer succeeds or fails. So, before setting this object the user should verify that transferStatus does not have the value 'requested' or 'inProgress'." ::= { doTransfer 1 } mopDestination OBJECT-TYPE SYNTAX OCTET STRING (SIZE(6)) ACCESS read-write STATUS mandatory DESCRIPTION "This object is the 802 48-bit address of the host storing the file containing the software image. The object may not be set until the last requested transfer succeeds or fails. So, before setting this object, the user should verify that transferStatus does not have the value 'requested' or 'inProgress'. Both version 3 and version 4 of MOP are supported. If a unicast address is specified, the transfer will be from that host. If the MOP multicast address ab-00-00-01-00-00 is used, the transfer will be from the first MOP server to respond, as usual." ::= { doTransfer 2 } transferFileName OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION "This object is the name of the file containing the software image. The object may not be set until the last requested transfer succeeds or fails. Before setting this object, the user should verify that transferStatus does not have the value 'requested' or 'inProgress'. Further, this object may not be set until the last requested copy succeeds or fails. Before setting this object, the user should verify that copyStatus does not have the value 'requested' or 'inProgress'." ::= { doTransfer 3 } -- UDP is unreliable and SNMP may therefore retransmit at the -- management station. We do not distinguish retransmitted -- requests from errant requests to start a new transfer in the -- middle of an ongoing transfer. transferAction OBJECT-TYPE SYNTAX INTEGER { none(1), doMOP(2), doTFTP(3) } ACCESS read-write STATUS mandatory DESCRIPTION "To initiate a transfer of a file from a server to the SCP, set this object. If transferFileName is non-empty, and mopDestination is non-zero, setting this object to doMOP(2) will cause a MOP 'load' to be attempted. If transferFileName is non-empty, and tftpDestination is non-zero, setting this object to doTFTP(3) will cause a TFTP 'Get' to be attempted. This object may not be set until the last requested transfer succeeds or fails, and the last requested copy succeeds or fails. So, before setting this object the user should verify that transferStatus does not have the values 'requested' or 'inProgress', and that copyStatus does not have the values 'requested' or 'inProgress'. " ::= { doTransfer 4 } transferStatus OBJECT-TYPE SYNTAX INTEGER { none(1), requested(2), inProgress(3), failed(4), success(5), failedDueToCheckSum(6) } ACCESS read-only STATUS mandatory DESCRIPTION "This variable can be polled to determine when the transfer has completed. Polling for completion allows other SNMP requests to be processed while the transfer is in progress (the SNMP is single-threaded)." ::= { doTransfer 5 } transferSize OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Size in bytes of the transfered file. This object can be polled along with the transferStatus object to monitor the progress of the transfer." ::= { doTransfer 6 } copyToSlot OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The slot number of the card which is to be upgraded. The object may not be set until the last requested copy succeeds or fails." ::= { useTransfer 1 } copyType OBJECT-TYPE SYNTAX INTEGER { none(1), scp(2), fgl2(3), clock(4), powerSystemController(5), agl-2(6), fgl4(7), agl-2-plus(8) } ACCESS read-only STATUS mandatory DESCRIPTION "The type of the image. The object is set after a transfer succeeds or fails." ::= { useTransfer 2 } -- UDP is unreliabile and SNMP may therefore retransmit at the -- management station. We do not distinguish retransmitted -- requests from errant requests to start a new copy in the -- middle of an ongoing copy. copyAction OBJECT-TYPE SYNTAX INTEGER { none(1), doUpgrade(2) } ACCESS read-write STATUS mandatory DESCRIPTION "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 value 'success', a software upgrade of the card is attempted. The handler double-checks that the slot requires software of the expected type, and provides demultiplexing when multiple images may be sent to the same slot. The power system controller is updated by sending its image to the clock card slot. The object may not be set until the last requested transfer succeeds, and the last requested copy succeeds or fails. Reading this object always returns the value none(1)." ::= { useTransfer 3 } copyStatus OBJECT-TYPE SYNTAX INTEGER { none(1), requested(2), inProgress(3), failed(4), success(5), failedDueToCardType(6), failedDueToHwRev(7), failedDueToFwRev(8), failedDueToBadImage(9) } ACCESS read-only STATUS mandatory DESCRIPTION "This variable can be polled to determine when the card upgrade has completed. Polling for completion allows other SNMP requests to be processed while the copy is in progress (the SNMP is single-threaded)." ::= { useTransfer 4 } deleteTransfer OBJECT-TYPE SYNTAX INTEGER { exists(1), notExist(2) } ACCESS read-write STATUS mandatory DESCRIPTION "When read, this object indicates whether the result of a file transfer is still present. The value exists indicates that the transferred file is present; the value notExist indicates that no file has been transferred or that it has been deleted. Writing the value exists is an error. Writing the value notExist deletes the transferred file. The object may not be set until the last requested transfer succeeds or fails. It may not be set while a copy is in progress, either." ::= { gigaUpgradeSoftware 3 } arpTimingMechanism OBJECT IDENTIFIER ::= { gigaIP 1 } arpTimeoutInSeconds OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The maximum amount of time an IP to LAN address translation will be used if it cannot be re-verified." ::= { arpTimingMechanism 1 } arpPeriodBetweenRequests OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The time, in seconds, between ARP requests that are used to verify or to discover an IP to LAN address translation." ::= { arpTimingMechanism 2 } arpRequestRetries OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "The number of times ARP requests are used to verify or to discover an IP to LAN address translation." ::= { arpTimingMechanism 3 } arpControlParams OBJECT IDENTIFIER ::= { gigaIP 3 } arpAgent OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " When true, the GIGAswitch will service broadcast ARP requests from its ARP cache. When false, Broadcast ARP frames are flooded. " ::= { arpControlParams 1 } arpStatisticalCounters OBJECT IDENTIFIER ::= { gigaIP 4 } arpStatisticalTable OBJECT-TYPE SYNTAX SEQUENCE OF ArpStatisticalEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table stores ARP counters. " ::= { arpStatisticalCounters 1 } arpStatisticalEntry OBJECT-TYPE SYNTAX ArpStatisticalEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " Information about the ARP statistical table is stored. " INDEX { arpStatisticalIfIndex } ::= { arpStatisticalTable 1 } ArpStatisticalEntry ::= SEQUENCE { arpStatisticalIfIndex INTEGER, arpUnicastReceived Counter, arpBroadcastReceived Counter, arpRepliesTransmitted Counter, arpFramesFlooded Counter, arpFramesDiscarded Counter } arpStatisticalIfIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " Identifies the Interface. The value of this object is the same as the ifIndex, defined in MIB-II, for this interface. " ::= { arpStatisticalEntry 1 } arpUnicastReceived OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " Unicast ARP requests received on this port. " ::= { arpStatisticalEntry 2 } arpBroadcastReceived OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " Broadcast ARP requests received on this port. " ::= { arpStatisticalEntry 3 } arpRepliesTransmitted OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " ARP replies transmitted on this port. " ::= { arpStatisticalEntry 4 } arpFramesFlooded OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " ARP frames received on this port that required flooding while acting as an ARP agent. " ::= { arpStatisticalEntry 5 } arpFramesDiscarded OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION " ARP frames received on this port that were discarded due to protocol errors. " ::= { arpStatisticalEntry 6 } snmpParameters OBJECT IDENTIFIER ::= { gigaIP 2 } snmpDuplicateDiscardInterval OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION " If duplicated snmp messages arrive within this interval, all but the first one will be discarded. The unit is a hundredth of second. " ::= { snmpParameters 1 } gigaStp OBJECT IDENTIFIER ::= { gigaBridge 8 } -- The gigaStp subgroup gigaStpPortTable OBJECT-TYPE SYNTAX SEQUENCE OF GigaStpPortEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " A list of gigaStp entries " ::= { gigaStp 1 } gigaStpPortEntry OBJECT-TYPE SYNTAX GigaStpPortEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " A collection of objects containing information for a given StpPort " INDEX { gigaStpPortIfIndex } ::= { gigaStpPortTable 1 } GigaStpPortEntry ::= SEQUENCE { gigaStpPortIfIndex INTEGER, gigaStpPortSpanningTreeEnable INTEGER } gigaStpPortIfIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The value of the interface associated with this spanning tree port." ::= { gigaStpPortEntry 1 } gigaStpPortSpanningTreeEnable OBJECT-TYPE SYNTAX INTEGER { true(1), false(2), trueNoDelay(3) } ACCESS read-write STATUS mandatory DESCRIPTION "When true, this interface will be enabled to operate as part of the spanning tree. When trueNoDelay, this interface will be enabled to operate as part of the spanning tree but will have a pre-forwarding delay of zero." ::= { gigaStpPortEntry 2 } gigaStpDemandLearningEnable OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " If true, then when a source address is learned, the address is only written to the Translation Table in the bridge port on which it was learned. If the address later occurs as a destination address in a packet received on some other bridge port, the packet is flooded if possible and the address is written to the Translation table of the other bridge port at that time. Thus, a bridge port that receives no packets for a certain address will not have that address in its database unless the address had been learned on that bridge port. If false, then when a source address is learned, the address is promptly written to the Translation Table of every bridge port in the GIGASwitch. This variable should be set to yes if the total number of learned addresses is expected to be greater than the number supported by the linecards and if there is sufficient locality of traffic that the behavior described above will not result in more than that number of addresses being learned on any one bridge port. It should be set to no if the total number of learned addresses is not greater than the number supported by the linecards and if it is desired to avoid flooding of packets to already-learned addresses. " ::= { gigaStp 2 } translationTableParams OBJECT IDENTIFIER ::= { gigaBridge 9 } ttSize OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The number of entries in the tables used to store learned network addresses. " ::= { translationTableParams 1 } xacInDiscardCounters OBJECT IDENTIFIER ::= { gigaBridge 10 } xacInDiscardUnknownDAUCast OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION "This object shows the number of unknown DA unicast packets which are transmitted from linecards to the SCP for multicasting, but discarded due to the lack of buffer space in the XAC chip. Packets counted here are not included in other, per-port, discard counters because this counter is shared by all the incoming ports. " ::= { xacInDiscardCounters 1 } xacInDiscardMulticast OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION "This object shows the number of multicast packets which are transmitted from linecards to the SCP for processing, but discarded due to the lack of buffer space in the XAC chip. Packets counted here are not included in other, per-port, discard counters because this counter is shared by all the incoming ports. " ::= { xacInDiscardCounters 2 } xacInDiscardIPForwarding OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION "This object shows the number of IP packets which are transmitted from linecards to the SCP for forwarding, but discarded due to the lack of buffer space in the XAC chip. Packets counted here are not included in other, per-port, discard counters because this counter is shared by all the incoming ports. " ::= { xacInDiscardCounters 3 } communityString OBJECT IDENTIFIER ::= { gigaBridge 11 } communityStringDelimiter OBJECT-TYPE SYNTAX OCTET STRING (SIZE(1)) ACCESS read-write STATUS mandatory DESCRIPTION " The communityStringDelimiter object is used to delimit community string suffixes. Community string suffixes give the SNMP agent additional information to process certain objects. If the objects do not need the suffix then the suffix is ignored. If the object uses the suffix and none is supplied, then a default is used. There are two valid suffixes available for the Gigaswitch/Fddi, LDx and LBDx. LDx references learning domains, LD1-LD8. LBDx references logical bridge domains, LBD1- LBD8. Both uppercase and lowercase are valid. The default communityStringDelimiter is the ':'. ex. public:LD3, use learning domain 4 if required public:LBD4, use logical bridge domain 4 if required public, use default if required. The set of Valid communityStringDelimiter is the set of all printable characters minus all the alphas and all the digits. If a LDx suffix is used where an LBDx is required, then the LBD that contains the LDx will be used. If a LBDx suffix is used where an LDx is required, then the lowest numbered LD in that LBD is used. In both cases if there are no members in the LD/LBD then the default is used. The default LD is LD1 and the default LBD is LBD1. " ::= { communityString 1 } -- The switched IP filtering subgroup ipSwitching OBJECT IDENTIFIER ::= { gigaIP 5 } ipSwitchEnable OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " If true then switched IP filtering is enabled. If false switched IP filtering is disabled. " ::= { ipSwitching 1 } ipSwitchPortsTable OBJECT-TYPE SYNTAX SEQUENCE OF IpSwitchPortsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table allows the user to assign an address range to logical bridge ports so that all traffic destined to addresses within that range will go out those ports. " ::= { ipSwitching 2 } ipSwitchPortsEntry OBJECT-TYPE SYNTAX IpSwitchPortsEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " An entry that stores information about a switched IP filtering range. " INDEX { ipRangeStartAddr , ipRangeEndAddr } ::= { ipSwitchPortsTable 1 } IpSwitchPortsEntry ::= SEQUENCE { ipRangeStartAddr IpAddress, ipRangeEndAddr IpAddress, ipIPAddr IpAddress, ipStaticPorts DisplayString, ipDynamicPorts DisplayString } ipRangeStartAddr OBJECT-TYPE SYNTAX IpAddress ACCESS read-only STATUS mandatory DESCRIPTION " An index for the ipSwitchPortsTable. This is the start address of the range of addresses for which the the ipStaticPorts and ipDynamicPorts are valid. " ::= { ipSwitchPortsEntry 1 } ipRangeEndAddr OBJECT-TYPE SYNTAX IpAddress ACCESS read-only STATUS mandatory DESCRIPTION " An index for the ipSwitchPortsTable. This is the end address of the range of addresses for which the the ipStaticPorts and ipDynamicPorts are valid. " ::= { ipSwitchPortsEntry 2 } ipIPAddr OBJECT-TYPE SYNTAX IpAddress ACCESS read-only STATUS mandatory DESCRIPTION " The IP address associated with the range, ipRangeStartAddr and ipRangeEndAddr. " ::= { ipSwitchPortsEntry 3 } ipStaticPorts OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " ipStaticPorts is the set of logical ports that packets will exit the Gigaswitch when the destination address is within the range specified by ipRangeStartAddr and ipRangeEndAddr. ipStaticPorts is expressed using a shorthand that specifies which logical ports are assigned to the address range. An example of a specification would be (1,6-9,21), where commas separate logical ports and hyphens are short-hand for specifying a range of numbers. This example would assign logical ports 1,6,7,8,9, and 21 to the specified address/mask. Logical port numbers are specified in decimal. The ipStaticPorts will read back in a form equivalent to the form written. It may not read back exactly as written. " ::= { ipSwitchPortsEntry 4 } ipDynamicPorts OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION " ipDynamicPorts is the set of logical ports, learned dynamically, that packets will exit the Gigaswitch when the destination address is within the range specified by ipRangeStartAddr and ipRangeEndAddr. " ::= { ipSwitchPortsEntry 5 } ipPrimaryPorts OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " ipPrimaryPorts is the set of all logical ports, set by management, that packets will exit the Gigaswitch regardless of the range to which they are addressed to. The ipPrimaryPorts is expressed using a shorthand that specifies the logical ports. An example of a specification would be (1,6-9,21) where commas separate logical ports and hyphens are short-hand for specifying a range of numbers. This example would assign logical ports 1,6,7,8,9, and 21 to the specified address/mask. Logical port numbers are specified in decimal. The ipPrimaryPorts will read back in a form equivalent to the form written. It may not read back exactly as written. " ::= { ipSwitching 3 } ipDynamicPrimaryPorts OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION " ipPrimaryPorts is the set of all logical ports, learned dynamically, that packets will exit the Gigaswitch regardless of the range to which they are addressed to. " ::= { ipSwitching 4 } ipDynamicEnabledPorts OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " ipSwitchDynamicEnabledPorts is the set of bridge ports over which the GIGAswitch sends and receives information about configured IP address ranges. The syntax used to specify it is the same as for ipPrimaryPorts. " ::= { ipSwitching 5 } -- ipSwitchAddrQueryTable OBJECT-TYPE -- SYNTAX SEQUENCE OF IpSwitchAddrQueryEntry -- ACCESS not-accessible -- STATUS mandatory -- DESCRIPTION -- " -- This table allows the user to determine the port(s) that -- a packet destined to an IP address will exit the -- Gigaswitch through. -- " -- ::= { ipSwitching 3 } -- -- ipSwitchAddrQueryEntry OBJECT-TYPE -- SYNTAX IpSwitchAddrQueryEntry -- ACCESS not-accessible -- STATUS mandatory -- DESCRIPTION -- " -- An entry that stores information about a switched -- IP filetring range. -- " -- INDEX { ipSwitchAddrQueryAddr } -- ::= { ipSwitchAddrQueryTable 1 } -- -- IpSwitchAddrQueryEntry ::= -- SEQUENCE { -- ipSwitchAddrQueryAddr IpAddress, -- ipSwitchAddrQueryPorts DisplayString -- } -- -- ipSwitchAddrQueryAddr OBJECT-TYPE -- SYNTAX IpAddress -- ACCESS read-only -- STATUS mandatory -- DESCRIPTION -- " -- An index for ipSwitchAddrQueryTable. This is the -- IP address that the user would like to determine -- the output ports for. -- " -- ::= { ipSwitchAddrQueryEntry 1 } -- -- ipSwitchAddrQueryPorts OBJECT-TYPE -- SYNTAX DisplayString -- ACCESS read-only -- STATUS mandatory -- DESCRIPTION -- " -- The set of ports that a packet destined to an address, -- given by ipSwitchAddrQueryAddr, will exit the Gigaswitch. -- " -- ::= { ipSwitchAddrQueryEntry 3 } -- lineCardFailureTrap TRAP-TYPE -- ENTERPRISE gigaswitch -- VARIABLES { slotIndex } -- DESCRIPTION -- " -- A lineCardFailureTrap trap signifies that the box -- recognizes a failure in one of the communications -- slot represented in the agent's configuration. -- " -- ::= 3 -- -- This MIB defines the AGL specific objects required -- for module operation within the Gigaswitch -- agl OBJECT IDENTIFIER ::= { gigaswitch 4 } -- groups in the AGL2 MIB module aglConfig OBJECT IDENTIFIER ::= { agl 1 } aglSonet OBJECT IDENTIFIER ::= { agl 2 } aglDS3E3 OBJECT IDENTIFIER ::= { agl 3 } aglAtm OBJECT IDENTIFIER ::= { agl 4 } -- aglSNP OBJECT IDENTIFIER ::= { agl 5 } -- -- The AGL Configuration Group -- -- Implementation of this group is mandatory -- aglInterfaceConfTable OBJECT-TYPE SYNTAX SEQUENCE OF AglInterfaceConfEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table contains the AGL specific interface configuration parameters, one entry per ATM interface port. " ::= { aglConfig 1 } aglInterfaceConfEntry OBJECT-TYPE SYNTAX AglInterfaceConfEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This list contains ATM interface configuration parameters and state variables. " INDEX { aglInterfaceIndex } ::= { aglInterfaceConfTable 1 } AglInterfaceConfEntry ::= SEQUENCE { aglInterfaceIndex INTEGER, aglInterfacePhyType INTEGER, aglInterfaceTrafficRateGranularity INTEGER } aglInterfaceIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The value of this object identifies the AGL port interface for which this entry contains management information. " ::= { aglInterfaceConfEntry 1 } aglInterfacePhyType OBJECT-TYPE SYNTAX INTEGER { sts3cStm1(1), ds3e3(2), unKnown(3) } ACCESS read-only STATUS mandatory DESCRIPTION " Indicates the type of physical interface used on the ATM port. Two physical layer types are supported: 1. STS3c/STM1 2. DS3/E3 The type is unknown if the port is not present or its physical layer type is not known. " ::= { aglInterfaceConfEntry 2} aglInterfaceTrafficRateGranularity OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " Indicates the granularity in cell/s for assigning peak, average and minimum guaranteed rates for traffic shaped circuits on the AGL port. This value also represents the minimum rate in cells/s that can be assigned to a circuit. The rates subscribed to in the aglVCConnectionTable will be set to a multiple of this rate. " ::= { aglInterfaceConfEntry 3} -- -- The AGL Sonet Group -- -- Implementation of this group is mandatory -- aglInterfaceSonetTable OBJECT-TYPE SYNTAX SEQUENCE OF AglInterfaceSonetEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table contains the AGL specific interface configuration parameters for the SONET/SDH physical layer. " ::= { aglSonet 1 } aglInterfaceSonetEntry OBJECT-TYPE SYNTAX AglInterfaceSonetEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This list contains SONET/SDH interface configuration parameters and state variables. " INDEX { aglInterfaceSonetIndex } ::= { aglInterfaceSonetTable 1 } AglInterfaceSonetEntry ::= SEQUENCE { aglInterfaceSonetIndex INTEGER, aglInterfaceSonetMode INTEGER, aglInterfaceSonetTiming INTEGER } aglInterfaceSonetIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The value of this object identifies the AGL port interface for which this entry contains management information and is the same as aglInterfaceIndex. " ::= { aglInterfaceSonetEntry 1 } aglInterfaceSonetMode OBJECT-TYPE SYNTAX INTEGER { sonetSTS3c(1), sdhSTM1(2) } ACCESS read-write STATUS mandatory DESCRIPTION " Specifies whether the PHY operates in SONET STS-3c or SDH STM-1 mode. The following code points are used: 1 SONET STS-3c 2 SDH STM-1 " ::= { aglInterfaceSonetEntry 2} aglInterfaceSonetTiming OBJECT-TYPE SYNTAX INTEGER { loopTiming(1), localTiming(2) } ACCESS read-write STATUS mandatory DESCRIPTION " Specifies whether the PHY operates in loop-timing or local-timing mode. In loop-timing, the recovered clock from the receive signal is used directly to time transmit data. Hence, the PHY is synchronized to the far-end transmitter. In local timing, transmit data is timed from a local oscillator of frequency 155.52 MHz (20ppm). The following code points are used: 1 loop-timing 2 local-timing " ::= { aglInterfaceSonetEntry 3} -- -- The AGL DS3/E3 Group -- -- Implementation of this group is mandatory -- aglInterfaceDS3E3Table OBJECT-TYPE SYNTAX SEQUENCE OF AglInterfaceDS3E3Entry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table contains the AGL specific interface configuration parameters for the DS3/E3 physical layer. " ::= { aglDS3E3 1 } aglInterfaceDS3E3Entry OBJECT-TYPE SYNTAX AglInterfaceDS3E3Entry ACCESS not-accessible STATUS mandatory DESCRIPTION " This list contains DS3/E3 interface configuration parameters and state variables. " INDEX { aglInterfaceDS3E3Index } ::= { aglInterfaceDS3E3Table 1 } AglInterfaceDS3E3Entry ::= SEQUENCE { aglInterfaceDS3E3Index INTEGER, aglInterfaceDS3E3Mode INTEGER, aglInterfaceDS3E3Plcp INTEGER } aglInterfaceDS3E3Index OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The value of this object identifies the AGL port interface for which this entry contains management information and is the same as aglInterfaceIndex. " ::= { aglInterfaceDS3E3Entry 1 } aglInterfaceDS3E3Mode OBJECT-TYPE SYNTAX INTEGER { low-power(1), high-power(2) } ACCESS read-write STATUS mandatory DESCRIPTION " Specifies whether the DS3/E3 PHY operates in low power mode for short distances or high power mode for longer distances. The following code points are used: 1 low-power 2 high-power " ::= { aglInterfaceDS3E3Entry 2} aglInterfaceDS3E3Plcp OBJECT-TYPE SYNTAX INTEGER { enable(1), disable(2) } ACCESS read-write STATUS mandatory DESCRIPTION " Specifies whether ATM cells may be mapped into the DS3 PLCP. In the enabled mode, PLCP framing and timing is applied to each ATM cell. " ::= { aglInterfaceDS3E3Entry 3} -- -- The AGL ATM Group -- -- Implementation of this group is mandatory -- -- The AglVCConnectionTable allows a network manager to setup -- single-port bidirectional circuits or dual-port bidirectional -- circuits. A single-port circuit terminates at that port, -- whereas a dual-port circuit establishes a connection through -- the GIGAswitch between the two ports (A and B). If a single-port -- connection is to be established, the user simply enters zero -- values for port B parameters below. -- -- GIGAswitch -- -------------- -- | | -- Rx --------->| PortA | -- Tx <---------| | -- | | -- | | -- | PortB |--------> Tx -- | |<-------- Rx -- | | -- -------------- -- aglVCConnectionTable OBJECT-TYPE SYNTAX SEQUENCE OF AglVCConnectionTableEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table contains AGL ATM VCC configuration and performance parameters and state variables. Each entry represents a bidirectional traffic flow. " ::= { aglAtm 1 } aglVCConnectionTableEntry OBJECT-TYPE SYNTAX AglVCConnectionTableEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " A bidirectional circuit. " INDEX { aglVCConnectionPortA, aglVCConnectionPortAVpi, aglVCConnectionPortAVci, aglVCConnectionPortB, aglVCConnectionPortBVpi, aglVCConnectionPortBVci} ::= { aglVCConnectionTable 1} AglVCConnectionTableEntry ::= SEQUENCE { aglVCConnectionPortA INTEGER, aglVCConnectionPortAVpi INTEGER, aglVCConnectionPortAVci INTEGER, aglVCConnectionPortB INTEGER, aglVCConnectionPortBVpi INTEGER, aglVCConnectionPortBVci INTEGER, aglVCConnectionTableEntryStatus INTEGER, aglVCConnectionTrafficType INTEGER, aglVCConnectionAALType INTEGER, aglVCConnectionOperStatus INTEGER, aglVCConnectionAdminStatus INTEGER, aglVCConnectionTrafficShaperPeakRate INTEGER, aglVCConnectionTrafficShaperAvgRate INTEGER, aglVCConnectionTrafficShaperMinGuaranteedRate INTEGER, aglVCConnectionTrafficShaperPriority INTEGER } aglVCConnectionPortA OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The value of this object identifies the AGL ATM port A of the VCC segment for FDDI-bridged and ATM-to-ATM circuit types. " ::= { aglVCConnectionTableEntry 1 } aglVCConnectionPortAVpi OBJECT-TYPE SYNTAX INTEGER (0..255) ACCESS read-only STATUS mandatory DESCRIPTION " The VPI value at port A for the bidirectional circuit. The maximum VPI value cannot exceed the number supported by the atmInterfaceMaxVpiBits at AGL ATM port A. This value is used for both transmit and receive VPIs " ::= { aglVCConnectionTableEntry 2 } aglVCConnectionPortAVci OBJECT-TYPE SYNTAX INTEGER (32..65535) ACCESS read-only STATUS mandatory DESCRIPTION " The VCI value at the port A for the bidirectional circuit. The VCI values from 0 to 31 are reserved. The maximum VCI value cannot exceed the number supported by the atmInterfaceMaxVciBits specified for the AGL ATM port A. This value is used for both transmit and receive VCIs " ::= { aglVCConnectionTableEntry 3 } aglVCConnectionPortB OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The value of this object identifies the AGL ATM port B of the VCC segment for ATM-to-ATM circuit types. For FDDI-bridged circuit types this value should be zero. " ::= { aglVCConnectionTableEntry 4 } aglVCConnectionPortBVpi OBJECT-TYPE SYNTAX INTEGER (0..255) ACCESS read-only STATUS mandatory DESCRIPTION " 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. This value is used for both transmit and receive VPIs. For other circuit types this value should be zero. " ::= { aglVCConnectionTableEntry 5 } aglVCConnectionPortBVci OBJECT-TYPE SYNTAX INTEGER (32..65535) ACCESS read-only STATUS mandatory DESCRIPTION " The VCI value at the port B for the bidirectional ATM-to-ATM circuit. The VCI values from 0 to 31 are reserved. The maximum VCI value cannot exceed the number supported by the atmInterfaceMaxVciBits specified for the AGL ATM port B. This value is used for both transmit and receive VCIs. For other circuit types this value should be zero. " ::= { aglVCConnectionTableEntry 6 } aglVCConnectionTableEntryStatus OBJECT-TYPE SYNTAX INTEGER { create(1), delete(2) } ACCESS read-write STATUS mandatory DESCRIPTION " The status column used for creating, and deleting bidirectional circuit entries in the agl virtual channel connection table. " ::= { aglVCConnectionTableEntry 7 } aglVCConnectionTrafficType OBJECT-TYPE SYNTAX INTEGER { FDDI-bridged(1), ATM-to-ATM(2) } ACCESS read-write STATUS mandatory DESCRIPTION " The value of this object identifies the circuit type and characteristics of a particular circuit. There are two types of connections supported: 1. FDDI-bridged 2. ATM-to-ATM An FDDI-bridged circuit carries all bridged FDDI traffic on AGL ATM port A. No information is required to be entered for Port B. Only one bridged FDDI circuit per AGL ATM port is supported. The packet format on this circuit is VC based multiplexed bridged FDDI as per RFC 1483. An ATM-to-ATM circuit carries arbitrary packet types between circuits specified on Port A and Port B of the GIGAswitch. Multiple ATM-to-ATM circuits are supported per AGL ATM port. " ::= { aglVCConnectionTableEntry 8 } aglVCConnectionAALType OBJECT-TYPE SYNTAX INTEGER { aal34(1), aal5(2) } ACCESS read-write STATUS mandatory DESCRIPTION " The value of this object identifies the AAL type that should be used on a particular circuit. " ::= { aglVCConnectionTableEntry 9 } aglVCConnectionOperStatus OBJECT-TYPE SYNTAX INTEGER { up(1), down(2), unknown(3) } ACCESS read-only STATUS mandatory DESCRIPTION " 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. The status is unknown if the OAM is disabled. " ::= { aglVCConnectionTableEntry 10 } aglVCConnectionAdminStatus OBJECT-TYPE SYNTAX INTEGER { enable(1), disable(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object indicates the desired status of the VCC, i.e., whether the managed VCC segment is enabled or disabled. In the disabled state, no cells can be passed across this VCC segment. " ::= { aglVCConnectionTableEntry 11 } aglVCConnectionTrafficShaperPeakRate OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION " The value of this object specifies the peak rate in cells/s that should be used on a particular circuit. The peak rate will be set to a multiple of the aglInterfaceTrafficRateGranularity close to the user specified input. " ::= { aglVCConnectionTableEntry 12} aglVCConnectionTrafficShaperAvgRate OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION " The value of this object specifies the average (sustained) rate in cells/s that should be used on a particular circuit. The average rate must be less than or equal to the peak rate and it will be set to a multiple of the aglInterfaceTrafficRate- Granularity close to the user specified input. " ::= { aglVCConnectionTableEntry 13} aglVCConnectionTrafficShaperMinGuaranteedRate OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION " The value of this object specifies the minimum guaranteed rate in cells/s that should be used on a particular circuit. For VBR traffic AGL allows the possibility of overbooking link bandwidth (up to 1200%) to achive statistical multiplexing. This parameter specifies the minimum peak bandwidth that you want to guarantee to the circuit. The minimum guaranteed rate must be less than or equal to the peak rate and it will be set to a multiple of the aglInterfaceTrafficRateGranularity close to the user specified input. " ::= { aglVCConnectionTableEntry 14} aglVCConnectionTrafficShaperPriority OBJECT-TYPE SYNTAX INTEGER (1..12) ACCESS read-write STATUS mandatory DESCRIPTION " The value of this object specifies the priority which should be given to this circuit in assigning opportunistic bandwidth that arises from AGL's bandwidth overbooking policy. " ::= { aglVCConnectionTableEntry 15} -- -- The AGL specific ATM Group -- Implementation of this group is mandatory -- aglInterfaceATMTable OBJECT-TYPE SYNTAX SEQUENCE OF AglInterfaceATMTableEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table contains AGL ATM interface specific settable parameters. " ::= { aglAtm 2 } aglInterfaceATMTableEntry OBJECT-TYPE SYNTAX AglInterfaceATMTableEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " The list of settable parameters. " INDEX { aglInterfaceATMIndex } ::= { aglInterfaceATMTable 1} AglInterfaceATMTableEntry ::= SEQUENCE { aglInterfaceATMIndex INTEGER, aglInterfaceATMScrambeStatus INTEGER, aglInterfaceATMOAMStatus INTEGER } aglInterfaceATMIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION " The value of this object identifies the AGL port interface for which this entry contains management information and is the same as aglInterfaceIndex. " ::= { aglInterfaceATMTableEntry 1 } aglInterfaceATMScrambeStatus OBJECT-TYPE SYNTAX INTEGER { enable(1), disable(2) } ACCESS read-write STATUS mandatory DESCRIPTION " This object indicates the desired status of the cell scramble module. In the enabled state, outgoing cells are scrambed and input cells are descrambled. " ::= { aglInterfaceATMTableEntry 2 } aglInterfaceATMOAMStatus OBJECT-TYPE SYNTAX INTEGER { enable(1), disable(2) } ACCESS read-write STATUS mandatory DESCRIPTION " 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. " ::= { aglInterfaceATMTableEntry 3 } -- -- aglSNP branch snapshots the objects that are expected to be evolved and currently -- located under the experimental subtree. Some objects were taken out from the -- experimental ATM and SONET MIBs and prefixed with agl. The objects under this -- branch may be deprecated once the standard committee finalize the objects. -- -- aglatmMIB OBJECT IDENTIFIER ::= { aglSNP 1 } aglatmMIB OBJECT IDENTIFIER ::= { gigaswitch 5 } aglatmMIBObjects OBJECT IDENTIFIER ::= { aglatmMIB 1 } aglatmInterfaceTrafficEnforcementTypes OBJECT IDENTIFIER ::= { aglatmMIBObjects 1 } aglatmInterfaceNoTrafficEnforcement OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This identifies the no ATM traffic enforcement type." ::= { aglatmInterfaceTrafficEnforcementTypes 1 } aglatmInterfaceTrafficEnforcementType1 OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This identifies the ATM traffic enforcement type is 1. For type 1 traffic enforcement, parameter 1 specifies CLP=0+1 peak traffic. Parameters 2, 3, 4 and 5 are not used. The peak rate is measured in cells per second." ::= { aglatmInterfaceTrafficEnforcementTypes 2 } aglatmInterfaceTrafficEnforcementType2 OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This identifies the ATM traffic enforcement type is 2. For type 2 traffic enforcement, parameter 1 specifies CLP=0 peak traffic and parameter 2 specifies CLP=0+1 peak traffic. Parameters 3, 4, and 5 are not used. The peak rate is measured in cells per second." ::= { aglatmInterfaceTrafficEnforcementTypes 3 } aglatmInterfaceTrafficEnforcementType3 OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This identifies the ATM traffic enforcement type is 3. For type 3 traffic enforcement, parameter 1 specifies CLP=0+1 peak traffic, parameter 2 specifies CLP=0 sustained rate, and parameter 3 specifies CLP=0 maximum burst size. Parameters 4 and 5 are not used. The peak rate is measured in cells per second. The sustained rate is measured in cells per second and burst size is measured in cells." ::= { aglatmInterfaceTrafficEnforcementTypes 4 } aglatmInterfaceTrafficEnforcementType4 OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This identifies the ATM traffic enforcement type is 4. For type 4 traffic enforcement, parameter 1 specifies CLP=0 peak traffic, parameter 2 specifies CLP=0+1 peak traffic, and parameter 3 specifies tagging (e.g., a value 1 may be used to indicate tagging). Parameters 4 and 5 are not used. The peak rate is measured in cells per second." ::= { aglatmInterfaceTrafficEnforcementTypes 5 } aglatmInterfaceTrafficEnforcementType5 OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This identifies the ATM traffic enforcement type is 5. For type 5 traffic enforcement, parameter 1 specifies CLP=0+1 peak traffic, parameter 2 specifies CLP=0 sustained rate, parameter 3 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." ::= { aglatmInterfaceTrafficEnforcementTypes 6 } aglatmInterfaceTrafficEnforcementType6 OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This identifies the ATM traffic enforcement type is 6. For type 6 traffic enforcement, parameter 1 specifies CLP=0+1 peak traffic, parameter 2 specifies CLP=0+1 sustained rate, and parameter 3 specifies CLP=0+1 maximum burst size. Parameters 4 and 5 are not used." ::= { aglatmInterfaceTrafficEnforcementTypes 7 } aglatmInterfaceTrafficEnforcementType7 OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This identifies the ATM traffic enforcement type is 7. For type 7 traffic enforcement, parameter 1 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." ::= { aglatmInterfaceTrafficEnforcementTypes 8 } aglatmInterfaceConfTable OBJECT-TYPE SYNTAX SEQUENCE OF AglAtmInterfaceConfEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table contains ATM local interface configuration parameters and state variables, one entry per ATM interface port." ::= { aglatmMIBObjects 2 } aglatmInterfaceConfEntry OBJECT-TYPE SYNTAX AglAtmInterfaceConfEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This list contains ATM interface configuration parameters and state variables." INDEX { aglatmInterfaceIndex } ::= { aglatmInterfaceConfTable 1 } AglAtmInterfaceConfEntry ::= SEQUENCE { aglatmInterfaceIndex INTEGER, aglatmInterfaceMaxVpcs INTEGER, aglatmInterfaceMaxVccs INTEGER, aglatmInterfaceConfVpcs INTEGER, aglatmInterfaceConfVccs INTEGER, aglatmInterfaceMaxActiveVpiBits INTEGER, aglatmInterfaceMaxActiveVciBits INTEGER, aglatmInterfaceIlmiVpiVci INTEGER, aglatmInterfaceSpecific OBJECT IDENTIFIER } aglatmInterfaceIndex OBJECT-TYPE SYNTAX INTEGER ACCESS not-accessible STATUS mandatory DESCRIPTION "The value of this object identifies the ATM port interface for which this entry contains management information." ::= { aglatmInterfaceConfEntry 1 } aglatmInterfaceMaxVpcs OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The maximum number of VPCs supported at this ATM interface." ::= { aglatmInterfaceConfEntry 2 } aglatmInterfaceMaxVccs OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The maximum number of VCCs supported at the ATM interface." ::= { aglatmInterfaceConfEntry 3 } aglatmInterfaceConfVpcs OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The number of VPCs configured for use at this ATM interface." ::= { aglatmInterfaceConfEntry 4 } aglatmInterfaceConfVccs OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The number of VCCs configured for use at the ATM interface." ::= { aglatmInterfaceConfEntry 5 } aglatmInterfaceMaxActiveVpiBits OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The maximum number of active VPI bits configured for use at the ATM interface." ::= { aglatmInterfaceConfEntry 6 } aglatmInterfaceMaxActiveVciBits OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The maximum number of active VCI bits configured for use at this ATM interface." ::= { aglatmInterfaceConfEntry 7 } aglatmInterfaceIlmiVpiVci OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "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 greater 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." ::= { aglatmInterfaceConfEntry 8 } aglatmInterfaceSpecific OBJECT-TYPE SYNTAX OBJECT IDENTIFIER ACCESS read-only STATUS mandatory DESCRIPTION "This object points to the additional information specific to ATM interfaces. For example, if 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}." ::= { aglatmInterfaceConfEntry 9 } aglatmInterfaceDs3PlcpTable OBJECT-TYPE SYNTAX SEQUENCE OF AglAtmInterfaceDs3PlcpEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table contains ATM interface DS3 PLCP parameters and state variables, one entry per ATM interface port." ::= { aglatmMIBObjects 3 } aglatmInterfaceDs3PlcpEntry OBJECT-TYPE SYNTAX AglAtmInterfaceDs3PlcpEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This list contains DS3 PLCP parameters and state variables at the ATM interface." INDEX { aglatmInterfaceDs3PlcpIndex } ::= { aglatmInterfaceDs3PlcpTable 1 } AglAtmInterfaceDs3PlcpEntry ::= SEQUENCE { aglatmInterfaceDs3PlcpIndex INTEGER, aglatmInterfaceDs3PlcpSEFSs Counter, aglatmInterfaceDs3PlcpAlarmState INTEGER, aglatmInterfaceDs3PlcpUASs Counter } aglatmInterfaceDs3PlcpIndex OBJECT-TYPE SYNTAX INTEGER ACCESS not-accessible STATUS mandatory DESCRIPTION "The value of this object identifies the ATM interface port for which this entry contains management information and is the same as the atmInterfaceIndex." ::= { aglatmInterfaceDs3PlcpEntry 1 } aglatmInterfaceDs3PlcpSEFSs OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION "A DS3 Severely Errored Framing Second (SEFS) is a count of one-second intervals containing one or more SEF event." ::= { aglatmInterfaceDs3PlcpEntry 2 } aglatmInterfaceDs3PlcpAlarmState OBJECT-TYPE SYNTAX INTEGER { noAlarm(1), receivedFarEndAlarm(2), incomingLOF(3) } ACCESS read-only STATUS mandatory DESCRIPTION "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 that the DS3 PLCP has declared a loss of frame (LOF) failure condition, and the value noAlarm means that there are no alarms present." ::= { aglatmInterfaceDs3PlcpEntry 3 } aglatmInterfaceDs3PlcpUASs OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Unavailable Seconds encountered by the PLCP." ::= { aglatmInterfaceDs3PlcpEntry 4 } aglatmInterfaceSonetTCTable OBJECT-TYPE SYNTAX SEQUENCE OF AglAtmInterfaceSonetTCEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table contains ATM interface SONET TC Sublayer parameters and state variables, one entry per ATM interface port." ::= { aglatmMIBObjects 4 } aglatmInterfaceSonetTCEntry OBJECT-TYPE SYNTAX AglAtmInterfaceSonetTCEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This list contains SONET TC Sublayer parameters and state variables at the ATM interface." INDEX { aglatmInterfaceSonetTCIndex } ::= { aglatmInterfaceSonetTCTable 1 } AglAtmInterfaceSonetTCEntry ::= SEQUENCE { aglatmInterfaceSonetTCIndex INTEGER, aglatmInterfaceSonetTCOCDEvents Counter, aglatmInterfaceSonetTCAlarmState INTEGER } aglatmInterfaceSonetTCIndex OBJECT-TYPE SYNTAX INTEGER ACCESS not-accessible STATUS mandatory DESCRIPTION "The value of this object identifies the ATM interface port for which this entry contains management information and is the same as the atmInterfaceIndex." ::= { aglatmInterfaceSonetTCEntry 1 } aglatmInterfaceSonetTCOCDEvents OBJECT-TYPE SYNTAX Counter ACCESS read-only STATUS mandatory DESCRIPTION "The number of times the Out of Cell Delineation (OCD) events occur. If seven consecutive ATM cells have Header Error Control (HEC) violations, an OCD event occurs. A high number of OCD events may indicate a problem with the SONET TC Sublayer." ::= { aglatmInterfaceSonetTCEntry 2 } aglatmInterfaceSonetTCAlarmState OBJECT-TYPE SYNTAX INTEGER { noAlarm(1), lcdFailure(2) } ACCESS read-only STATUS mandatory DESCRIPTION "This variable indicates if there is an alarm present for the SONET TC Sublayer. The value lcdFailure indicates that a Loss of Cell Delineation (LCD) failure state has been declared for the SONET TC Sublayer." ::= { aglatmInterfaceSonetTCEntry 3 } -- aglsonetMIB OBJECT IDENTIFIER ::= { aglSNP 2 } aglsonetMIB OBJECT IDENTIFIER ::= { gigaswitch 6 } aglsonetObjects OBJECT IDENTIFIER ::= { aglsonetMIB 1 } aglsonetObjectsPath OBJECT IDENTIFIER ::= { aglsonetMIB 2 } aglsonetMedium OBJECT IDENTIFIER ::= { aglsonetObjects 1 } aglsonetSection OBJECT IDENTIFIER ::= { aglsonetObjects 2 } aglsonetLine OBJECT IDENTIFIER ::= { aglsonetObjects 3 } aglsonetPath OBJECT IDENTIFIER ::= { aglsonetObjectsPath 1 } aglsonetMediumTable OBJECT-TYPE SYNTAX SEQUENCE OF AglSonetMediumEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The SONET/SDH Medium table." ::= { aglsonetMedium 1 } aglsonetMediumEntry OBJECT-TYPE SYNTAX AglSonetMediumEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "An entry in the SONET/SDH Medium table." INDEX { aglsonetMediumIfIndex } ::= { aglsonetMediumTable 1 } AglSonetMediumEntry ::= SEQUENCE { aglsonetMediumIfIndex INTEGER, aglsonetMediumType INTEGER, aglsonetMediumTimeElapsed INTEGER (-2147483648..2147483647), aglsonetMediumValidIntervals INTEGER (-2147483648..2147483647), aglsonetMediumLineCoding INTEGER, aglsonetMediumLineType INTEGER, aglsonetMediumCircuitIdentifier DisplayString } aglsonetMediumIfIndex OBJECT-TYPE SYNTAX INTEGER ACCESS not-accessible STATUS mandatory DESCRIPTION "An index value that uniquely identifies a SONET/SDH Medium/Section/Line Interface." ::= { aglsonetMediumEntry 1 } aglsonetMediumType OBJECT-TYPE SYNTAX INTEGER { sonet(1), sdh(2) } ACCESS read-only STATUS mandatory DESCRIPTION "This variable identifies whether a SONET or a SDH signal is used across this interface." ::= { aglsonetMediumEntry 2 } aglsonetMediumTimeElapsed OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The number of seconds, including partial seconds, that have elapsed since the beginning of the current error-measurement period." ::= { aglsonetMediumEntry 3 } aglsonetMediumValidIntervals OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The number of previous intervals for which valid 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 unless the device was brought online within the last (nx15) minutes, in which case the value will be the number of complete 15 minute intervals the device has been online." ::= { aglsonetMediumEntry 4 } aglsonetMediumLineCoding OBJECT-TYPE SYNTAX INTEGER { sonetMediumOther(1), sonetMediumB3ZS(2), sonetMediumCMI(3), sonetMediumNRZ(4), sonetMediumRZ(5) } ACCESS read-only STATUS mandatory DESCRIPTION "This variable describes the line coding for this interface. The B3ZS and CMI are used for electrical SONET/SDH signals (STS-1 and STS-3). The Non-Return to Zero (NRZ) and the Return to Zero are used for optical SONET/SDH signals." ::= { aglsonetMediumEntry 5 } aglsonetMediumLineType OBJECT-TYPE SYNTAX INTEGER { sonetOther(1), sonetShortSingleMode(2), sonetLongSingleMode(3), sonetMultiMode(4), sonetCoax(5), sonetUTP(6) } ACCESS read-only STATUS mandatory DESCRIPTION "This variable describes the line type for this interface. The line types are Short and Long Range Single Mode fiber or Multi-Mode fiber interfaces, and coax and UTP for electrical interfaces. The value sonetOther should be used when the Line Type is not one of the listed values." ::= { aglsonetMediumEntry 6 } aglsonetMediumCircuitIdentifier OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION "This variable contains the transmission vendor's circuit identifier, for the purpose of facilitating troubleshooting." ::= { aglsonetMediumEntry 7 } aglsonetSectionCurrentTable OBJECT-TYPE SYNTAX SEQUENCE OF AglSonetSectionCurrentEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The SONET/SDH Section Current table." ::= { aglsonetSection 1 } aglsonetSectionCurrentEntry OBJECT-TYPE SYNTAX AglSonetSectionCurrentEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "An entry in the SONET/SDH Section Current table." INDEX { aglsonetSectionCurrentIfIndex } ::= { aglsonetSectionCurrentTable 1 } AglSonetSectionCurrentEntry ::= SEQUENCE { aglsonetSectionCurrentIfIndex INTEGER, aglsonetSectionCurrentStatus INTEGER (-2147483648..2147483647), aglsonetSectionCurrentESs Gauge, aglsonetSectionCurrentSESs Gauge, aglsonetSectionCurrentSEFSs Gauge, aglsonetSectionCurrentCVs Gauge } aglsonetSectionCurrentIfIndex OBJECT-TYPE SYNTAX INTEGER ACCESS not-accessible STATUS mandatory DESCRIPTION "The index value which uniquely identifies the SONET/SDH Medium/Section/Line Interface." ::= { aglsonetSectionCurrentEntry 1 } aglsonetSectionCurrentStatus OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "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 sonetSectionLOF" ::= { aglsonetSectionCurrentEntry 2 } aglsonetSectionCurrentESs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Errored Seconds encountered by a SONET/SDH Section in the current 15 minute interval." ::= { aglsonetSectionCurrentEntry 3 } aglsonetSectionCurrentSESs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Severely Errored Seconds encountered by a SONET/SDH Section in the current 15 minute interval." ::= { aglsonetSectionCurrentEntry 4 } aglsonetSectionCurrentSEFSs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Severely Errored Framing Seconds encountered by a SONET/SDH Section in the current 15 minute interval." ::= { aglsonetSectionCurrentEntry 5 } aglsonetSectionCurrentCVs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Coding Violations encountered by a SONET/SDH Section in the current 15 minute interval." ::= { aglsonetSectionCurrentEntry 6 } aglsonetLineCurrentTable OBJECT-TYPE SYNTAX SEQUENCE OF AglSonetLineCurrentEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The SONET/SDH Line Current table." ::= { aglsonetLine 1 } aglsonetLineCurrentEntry OBJECT-TYPE SYNTAX AglSonetLineCurrentEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "An entry in the SONET/SDH Line Current table." INDEX { aglsonetLineCurrentIfIndex } ::= { aglsonetLineCurrentTable 1 } AglSonetLineCurrentEntry ::= SEQUENCE { aglsonetLineCurrentIfIndex INTEGER, aglsonetLineCurrentStatus INTEGER (-2147483648..2147483647), aglsonetLineCurrentESs Gauge, aglsonetLineCurrentSESs Gauge, aglsonetLineCurrentCVs Gauge, aglsonetLineCurrentUASs Gauge } aglsonetLineCurrentIfIndex OBJECT-TYPE SYNTAX INTEGER ACCESS not-accessible STATUS mandatory DESCRIPTION "The index value which uniquely identifies the SONET/SDH Medium/Line Interface." ::= { aglsonetLineCurrentEntry 1 } aglsonetLineCurrentStatus OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "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 sonetLineRDI" ::= { aglsonetLineCurrentEntry 2 } aglsonetLineCurrentESs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Errored Seconds encountered by a SONET/SDH Line in the current 15 minute interval." ::= { aglsonetLineCurrentEntry 3 } aglsonetLineCurrentSESs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Severely Errored Seconds encountered by a SONET/SDH Line in the current 15 minute interval." ::= { aglsonetLineCurrentEntry 4 } aglsonetLineCurrentCVs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Coding Violations encountered by a SONET/SDH Line in the current 15 minute interval." ::= { aglsonetLineCurrentEntry 5 } aglsonetLineCurrentUASs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Unavailable Seconds encountered by a SONET/SDH Line in the current 15 minute interval." ::= { aglsonetLineCurrentEntry 6 } aglsonetPathCurrentTable OBJECT-TYPE SYNTAX SEQUENCE OF AglSonetPathCurrentEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The SONET/SDH Path Current table." ::= { aglsonetPath 1 } aglsonetPathCurrentEntry OBJECT-TYPE SYNTAX AglSonetPathCurrentEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "An entry in the SONET/SDH Path Current table." INDEX { aglsonetPathCurrentIfIndex } ::= { aglsonetPathCurrentTable 1 } AglSonetPathCurrentEntry ::= SEQUENCE { aglsonetPathCurrentIfIndex INTEGER, aglsonetPathCurrentWidth INTEGER, aglsonetPathCurrentStatus INTEGER (-2147483648..2147483647), aglsonetPathCurrentESs Gauge, aglsonetPathCurrentSESs Gauge, aglsonetPathCurrentCVs Gauge, aglsonetPathCurrentUASs Gauge } aglsonetPathCurrentIfIndex OBJECT-TYPE SYNTAX INTEGER ACCESS not-accessible STATUS mandatory DESCRIPTION "An index value that uniquely identifies a SONET/SDH Path Interface." ::= { aglsonetPathCurrentEntry 1 } aglsonetPathCurrentWidth OBJECT-TYPE SYNTAX INTEGER { sts1(1), sts3cSTM1(2), sts12cSTM4(3), sts24c(4), sts48cSTM16(5) } ACCESS read-write STATUS mandatory DESCRIPTION "A value that indicates the type of the SONET/SDH Path. For SONET, the assigned types are the STS-Nc SPEs, where N = 1, 3, 12, 24, and 48. STS-1 is equal to 51.84 Mbps. For SDH, the assigned types are the STM-Nc VCs, where N = 1, 4, and 16." ::= { aglsonetPathCurrentEntry 2 } aglsonetPathCurrentStatus OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "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 sonetPathSignalLabelMismatch" ::= { aglsonetPathCurrentEntry 3 } aglsonetPathCurrentESs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Errored Seconds encountered by a SONET/SDH Path in the current 15 minute interval." ::= { aglsonetPathCurrentEntry 4 } aglsonetPathCurrentSESs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Severely Errored Seconds encountered by a SONET/SDH Path in the current 15 minute interval." ::= { aglsonetPathCurrentEntry 5 } aglsonetPathCurrentCVs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Coding Violations encountered by a SONET/SDH Path in the current 15 minute interval." ::= { aglsonetPathCurrentEntry 6 } aglsonetPathCurrentUASs OBJECT-TYPE SYNTAX Gauge ACCESS read-only STATUS mandatory DESCRIPTION "The counter associated with the number of Unavailable Seconds encountered by a Path in the current 15 minute, interval." ::= { aglsonetPathCurrentEntry 7 } portGroupMembershipTable OBJECT-TYPE SYNTAX SEQUENCE OF PortGroupMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The table for storing the port group membership." ::= { gigaSets 1 } portGroupMembershipEntry OBJECT-TYPE SYNTAX PortGroupMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "An entry stores information about a single port group." INDEX { portGroupBridgePort } ::= { portGroupMembershipTable 1 } PortGroupMembershipEntry ::= SEQUENCE { portGroupBridgePort INTEGER, portGroupMembership DisplayString, portGroupMembershipWorkBuf DisplayString, portGroupPortType INTEGER, portGroupPortTypeWorkBuf INTEGER, portGroupPortOperStatus INTEGER } portGroupBridgePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The port group port number. It is unique within this table and must be between 37 and 64. Without management settings, the port group has no members in it. " ::= { portGroupMembershipEntry 1 } portGroupMembership OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION " This object displays the current state of the port group membership. Managers specify a new port group membership using portGroupMembershipWorkBuf. The new membership becomes effective and remains unchanged after a system crash when portGroupAction is set to doUpdate and the updating process succeeds. " ::= { portGroupMembershipEntry 2 } portGroupMembershipWorkBuf OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " Managers can update a new port group membership as many times as they want using this object. Setting this object to a new value does not change the current membership and the value will be resetted after a system crash. The new value is copied to portGroupMembership when portGroupAction is set to doUpdate and the updating process successfully changes the port member. A port group is expressed using a shorthand that says what bridge ports are members of the group. An examples of a specification is: (1,3,5) (32-36) (6,12-24,36) () A list of bridge ports between 1 and 36 are used to represent the members of the port group. A bridge port becoming a member of a port group ceases to operate as a normal bridge port, therefore filters on the port have no effect. If a port group is specified as an empty set, the members in the group will operate as normal bridge ports and take their original brige port numbers. Their original filters will also become effective. Commas separate items in a list of bridge ports. Hyphens are short-hand for specifying a range of numbers. Bridge port numbers are specified in decimal. A port group will read back in a form equivalent to the form written. It may not read back exactly as written. If the manager specifies a member that is overlapped with a member of a preexisting port group in the same object, setting portGroupAction to doUpdate will fail. " ::= { portGroupMembershipEntry 3 } portGroupPortType OBJECT-TYPE SYNTAX INTEGER { huntGroup(1), reliabilityGroup(2) } ACCESS read-only STATUS mandatory DESCRIPTION " This object displays the current state of the port group port type. Managers specify a new port group port type using portGroupPortTypeWorkBuf. The new port type becomes effective and remains unchanged after a system crash when portGroupAction is set to doUpdate and the updating process succeeds. " ::= { portGroupMembershipEntry 4 } portGroupPortTypeWorkBuf OBJECT-TYPE SYNTAX INTEGER { huntGroup(1), reliabilityGroup(2) } ACCESS read-write STATUS mandatory DESCRIPTION " Managers can update a new port group port type as many times as they want using this object. Setting this object to a new value does not change the current port type and the value will be resetted after a system crash. The new value is copied to portGroupPortType when portGroupAction is set to doUpdate and the updating process successfully changes the port type. Two port group types are supported: 1) the hunt group and 2) the reliability group. All members in the hunt group port work like a single bridge port as far as the bridge functions are concerned and yet provides higher bandwidth due to multiple parallel FDDI links. A state of a port in a reliability group is either operational or backup. Only a single port in the group may be operational, while the other ports in the group are backup. When the operational port fails, one backup mode port will be selected, and quickly become operational. " ::= { portGroupMembershipEntry 5 } portGroupPortOperStatus OBJECT-TYPE SYNTAX INTEGER { uninitializedPort(1), preBridging(2), bridging(3) } ACCESS read-only STATUS mandatory DESCRIPTION " This object indicates the operational status of the port group. The status represents the aggregated effect of each member's status. uninitializedPort(1) state indicates one of the followings: 1) the port group has no member in it, 2) no port in the port group is powered on, 3) no port in the port group has successfully completed startup diagnostics. State preBridging(2) means that some ports in the port group have been initialized with the bridge functions, but no port is not yet functioning as part of a bridge port. This is always the case if the datalink is not up. A hunt group member remains in this state if the remote end of the link is not properly configured as part of the hunt group. An inactive member of a reliability group is also in this state if it is up and initialized. State bridging(3) means that at least one port in the port group is functioning as part of a bridge port. The port group must be in this state to carry user data. " ::= { portGroupMembershipEntry 6 } portGroupFppnMembershipTable OBJECT-TYPE SYNTAX SEQUENCE OF PortGroupFppnMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The table for storing the port group membership specified by FPPN numbers." ::= { gigaSets 2 } portGroupFppnMembershipEntry OBJECT-TYPE SYNTAX PortGroupFppnMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "An entry stores information about a single port group." INDEX { portGroupFppnPort } ::= { portGroupFppnMembershipTable 1 } PortGroupFppnMembershipEntry ::= SEQUENCE { portGroupFppnPort DisplayString, portGroupFppnMembership DisplayString, portGroupFppnMembershipWorkBuf DisplayString, portGroupFppnPortType INTEGER, portGroupFppnPortTypeWorkBuf INTEGER, portGroupFppnPortOperStatus INTEGER } portGroupFppnPort OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION "The port group port number. It is unique within this table and must be between 99.37 and 99.64. Without management settings, the port group has no members in it. " ::= { portGroupFppnMembershipEntry 1 } portGroupFppnMembership OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION " This object displays the current state of the port group membership. Managers specify a new port group membership using portGroupFppnMembershipWorkBuf. The new membership becomes effective and remains unchanged after a system crash when portGroupAction is set to doUpdate and the updating process succeeds. " ::= { portGroupFppnMembershipEntry 2 } portGroupFppnMembershipWorkBuf OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " Managers can update a new port group membership as many times as they want using this object. Setting this object to a new value does not change the current membership and the value will be resetted after a system crash. The new value is copied to portGroupFppnMembership when portGroupAction is set to doUpdate and the updating process successfully changes the port member. A port group is expressed using a shorthand that says what FPPN ports are members of the group. An examples of a specification is: (1.1,3.2,5.1) (13.1-14.2) (4.1,11.1-13.2,14.2) () A list of FPPN ports between 1.1 and 14.2 are used to represent the members of the port group. A port becoming a member of a port group ceases to operate as a normal bridge port, therefore filters on the port have no effect. If a port group is specified as an empty set, the members in the group will operate as normal bridge ports and take their original FPPN port numbers. Their original filters will also become effective. Commas separate items in a list of FPPN ports. Hyphens are short-hand for specifying a range of numbers. FPPN port numbers are of the form (slot.port) where slot is the slot number and port is the port number in the slot. A port group will read back in a form equivalent to the form written. It may not read back exactly as written. If the manager specifies a member that is overlapped with a member of a preexisting port group in the same object, setting portGroupAction to doUpdate will fail. " ::= { portGroupFppnMembershipEntry 3 } portGroupFppnPortType OBJECT-TYPE SYNTAX INTEGER { huntGroup(1), reliabilityGroup(2) } ACCESS read-only STATUS mandatory DESCRIPTION " This object displays the current state of the port group port type. Managers specify a new port group port type using portGroupPortTypeWorkBuf. The new port type becomes effective and remains unchanged after a system crash when portGroupAction is set to doUpdate and the updating process succeeds. " ::= { portGroupFppnMembershipEntry 4 } portGroupFppnPortTypeWorkBuf OBJECT-TYPE SYNTAX INTEGER { huntGroup(1), reliabilityGroup(2) } ACCESS read-write STATUS mandatory DESCRIPTION " Managers can update a new port group port type as many times as they want using this object. Setting this object to a new value does not change the current port type and the value will be resetted after a system crash. The new value is copied to portGroupPortType when portGroupAction is set to doUpdate and the updating process successfully changes the port type. Two port group types are supported: 1) the hunt group and 2) the reliability group. All members in the hunt group port work like a single bridge port as far as the bridge functions are concerned and yet provides higher bandwidth due to multiple parallel FDDI links. A state of a port in a reliability group is either operational or backup. Only a single port in the group may be operational, while the other ports in the group are backup. When the operational port fails, one backup mode port will be selected, and quickly become operational. " ::= { portGroupFppnMembershipEntry 5 } portGroupFppnPortOperStatus OBJECT-TYPE SYNTAX INTEGER { uninitializedPort(1), preBridging(2), bridging(3) } ACCESS read-only STATUS mandatory DESCRIPTION " This object indicates the operational status of the port group. The status represents the aggregated effect of each member's status. uninitializedPort(1) state indicates one of the followings: 1) the port group has no member in it, 2) no port in the port group is powered on, 3) no port in the port group has successfully completed startup diagnostics. State preBridging(2) means that some ports in the port group have been initialized with the bridge functions, but no port is not yet functioning as part of a bridge port. This is always the case if the datalink is not up. A hunt group member remains in this state if the remote end of the link is not properly configured as part of the hunt group. An inactive member of a reliability group is also in this state if it is up and initialized. State bridging(3) means that at least one port in the port group is functioning as part of a bridge port. The port group must be in this state to carry user data. " ::= { portGroupFppnMembershipEntry 6 } portGroupStatusTable OBJECT-TYPE SYNTAX SEQUENCE OF PortGroupStatusEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "The table for storing the port status." ::= { gigaSets 3 } portGroupStatusEntry OBJECT-TYPE SYNTAX PortGroupStatusEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "An entry stores the port status." INDEX { portGroupStatusBridgePort } ::= { portGroupStatusTable 1 } PortGroupStatusEntry ::= SEQUENCE { portGroupStatusBridgePort INTEGER, portGroupStatusPortNumber INTEGER, portGroupStatusPortType INTEGER, portGroupStatusOperStatus INTEGER } portGroupStatusBridgePort OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "The bridge port number runs from 1 to _LASTPHYSPORT_. " ::= { portGroupStatusEntry 1 } portGroupStatusPortNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "If the indexed port is a member of a port group, the port group number is returned. Otherwise, the index itself is returned. " ::= { portGroupStatusEntry 2 } portGroupStatusPortType OBJECT-TYPE SYNTAX INTEGER { singleton(1), huntGroupMember(2), reliabilityGroupMember(3) } ACCESS read-only STATUS mandatory DESCRIPTION " This object represents the port type. " ::= { portGroupStatusEntry 3 } portGroupStatusOperStatus OBJECT-TYPE SYNTAX INTEGER { uninitializedPort(1), portInitializing(2), preBridging(3), bridging(4) } ACCESS read-only STATUS mandatory DESCRIPTION " This object indicates the operational status of the indexed port. uninitializedPort(1) state indicates one of the followings: 1) the port is nonexistent, 2) the port is in a slot that is not powered on, 3) the port has not successfully completed startup diagnostics. Ports in portInitializing(2) state are in the process of being initialized. It is a temporary state. State preBridging(3) means that the port has been initialized with the bridge functions, but is not functioning as part of a bridge port. This is always the case if the datalink is not up. A hunt group member remains in this state if the remote end of the link is not properly configured as part of the hunt group. An inactive member of a reliability group is also in this state if it is up and initialized. State bridging(4) means that the port is functioning as part of a bridge port. Ports must be in this state to carry user data. " ::= { portGroupStatusEntry 4 } learningDomainMembershipTable OBJECT-TYPE SYNTAX SEQUENCE OF LearningDomainMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table allows learning domains to be created, modified, and deleted. There can be from 1 to 8 learning domains. A learning domain is a collection of port groups (or bridge ports) which share a learning database. Every bridge port is a member of precisely one learning domain. A MAC address that is seen on one port of the learning domain will be taught to the other ports in the learning domain, but not to ports in other learning domains, unless a target learning domain has been set up. Among other things, this allows for the possbility that a single MAC address may be learned on several different ports - as long as they are in separate learning domains. There are a maximum of 8 learning domains, including the default learning domain. The default learning domain is the set of all bridge ports that do not belong to a management defined learning domain. " ::= { gigaSets 4 } learningDomainMembershipEntry OBJECT-TYPE SYNTAX LearningDomainMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " A group of objects, indexed by learningDomainNumber, that specify learning domain attributes. " INDEX { learningDomainNumber } ::= { learningDomainMembershipTable 1 } LearningDomainMembershipEntry ::= SEQUENCE { learningDomainNumber INTEGER, learningDomainMembership DisplayString, learningDomainMembershipWorkBuf DisplayString } learningDomainNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The index for a learning domain is an integer with range, 1-8, where 1 is the default learning domain. " ::= { learningDomainMembershipEntry 1 } learningDomainMembership OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION " This object displays the current state of the learning domain membership. Managers specify a new learning domain membership using learningDomainMembershipWorkBuf. The new membership becomes effective and remains unchanged, across system reboots, when portGroupAction is set to doUpdate and the updating process succeeds. " ::= { learningDomainMembershipEntry 2 } learningDomainMembershipWorkBuf OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " The learningDomainMembershipWorkBuf object is used to create,modify, and delete learning domains. Managers can update a learning domain membership as many times as they want using this object. Setting this object to a new value does not change the current membership nor the values stored in non-volatile memory until the object portGroupAction is written with doUpdate. At that time the new values will be written to learningDomainMembership and non-volatile memory and the learning domain changes will take effect. The addition/removal of bridge ports to/from a learning domain is an atomic operation. Because a bridge port can only belong to one learning domain, the last assignment of a bridge port to a learning domain will determine the learning domain in which the bridge port resides. There is a default learning domain, designated by learningDomainNumber 1, which all bridge ports belong to until management changes the assignments of bridge ports to learning domains. If a bridge port is removed from a learning domain, it is placed back into the default learning domain. The default learning domain can not be modified directly. It changes when new learning domains are created or modified. Every learning domain is a member of precisely one logical bridge. The learningDomainMembership is expressed using a shorthand that specifies which bridge ports belong in the learning domain. An example of a specification would be : (1,6-9,21) where commas separate bridge ports and hyphens are short-hand for specifying a range of numbers. This example would assign bridge ports 1,6,7,8,9, and 21 to the specified learning domain. Bridge port numbers are specified in decimal. A learning domain will read back in a form equivalent to the form written. It may not read back exactly as written. " ::= { learningDomainMembershipEntry 3 } learningQuotaTable OBJECT-TYPE SYNTAX SEQUENCE OF LearningQuotaEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " Each logical bridge domain (LBD) has a learning quota. This table allows the setting of theses quotas. " ::= { gigaSets 11 } learningQuotaEntry OBJECT-TYPE SYNTAX LearningQuotaEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " A group of objects, indexed by learningQuotaNumber, that specify learning quotas. " INDEX { learningQuotaNumber } ::= { learningQuotaTable 1 } LearningQuotaEntry ::= SEQUENCE { learningQuotaNumber INTEGER, learningQuota INTEGER } learningQuotaNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The index for a learning quota is a learning domain with range, 1 - 8. " ::= { learningQuotaEntry 1 } learningQuota OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION " Each learning domain has a learning quota. The ports in the domain are guaranteed the ability to use approximately this number of address entries in the Translation Table, so that an excessive number of learned addresses in one domain cannot interfere significantly with learning in another domain. The GIGAswitch keeps track of the count of addresses learned in each domain and deletes addresses from the domains that have most exceeded their learning quotas to make room for addresses learned in other domains. If these quotas are configured so that they add up to less than the size of the SCP Translation Table, there are almost always SCP Translation Table entries available to accommodate new learned addresses. Further, these addresses will not be deleted to make room for others unless the domain's quota is reached or is close to being reached. If the SCP Translation Table is not full, the quotas are allowed to be exceeded. Under such circumstances, the count of learned addresses in a logical bridge may grow until it is close to the number of unused entries in the Translation Table plus the applicable learning quota. The learning quotas are not exact, and addresses may start to be deleted when this limit is within a small number of addresses (initially 100) of being reached. It should be remembered that there are factors other than the learning quotas that may restrict the number of addresses that can be learned, so that a high learning quota does not guarantee that number of addresses may be learned. In particular: 1) If the capacity of the linecard Translation Tables is exceeded, no more addresses may be learned on that linecard. 2) If the sum of the configured learning quotas is greater than the SCP Translation Table size, then no more addresses may be learned once the SCP Translation Table is full, even though no quota may have been exceeded. When either of these situations occur, an attempt is made to solve the problem by deleting addresses in the same manner as when dealing with the learning quota limits. The default value for each learning quota is 32768, the same as the capacity of the SCP Translation Table. This large value means that the quotas have no effect. To see the full benefit of learning quotas, they should be set so that the sum of the quotas over all active domains is less than 32500. " ::= { learningQuotaEntry 2 } portTargetDomainListMembershipTable OBJECT-TYPE SYNTAX SEQUENCE OF PortTargetDomainListMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table allows port target domains lists to be created, modified, and deleted. The port target domain list is the set of all mgmt defined learning domains to which a bridge port, as specified by the index, will learn addresses from. A MAC address that is seen in one of the learning domains in the port target domain list will be learned by the indexed bridge port. Every port target domain is a member of precisely one logical bridge. " ::= { gigaSets 5 } portTargetDomainListMembershipEntry OBJECT-TYPE SYNTAX PortTargetDomainListMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " A group of objects, indexed by portTargetDomainListIndex, that specify port target domain attributes. " INDEX { portTargetDomainListIndex } ::= { portTargetDomainListMembershipTable 1 } PortTargetDomainListMembershipEntry ::= SEQUENCE { portTargetDomainListIndex INTEGER, portTargetDomainListMembership DisplayString, portTargetDomainListMembershipWorkBuf DisplayString } portTargetDomainListIndex OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " A bridge port number from 1 - 64 . " ::= { portTargetDomainListMembershipEntry 1 } portTargetDomainListMembership OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION " The portTargetDomainListMembership specifies a set of mgmt specified learning domains. This object displays the current state of the port target domain list membership. Managers specify a new port target domain membership, or modify an existing one using portTargetDomainListMembershipWorkBuf. The new membership becomes effective and remains unchanged, across system reboots, when portGroupAction is set to doUpdate and the updating process succeeds. " ::= { portTargetDomainListMembershipEntry 2 } portTargetDomainListMembershipWorkBuf OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " The portTargetDomainListMembership object is used to create, modify, and delete port target domain lists. Managers can update a port target domain membership list as many times as they want using this object. Setting this object to a new value does not change the current membership nor the values stored in mgmt memory until the object portGroupAction is written with doUpdate. At that time the new values will be written to portTargetDomainListMembership and mgmt memory and the target domain changes will take effect. The portTargetDomainListMembership specifies the target domains that a learning domain belongs to. This set of learning domains is called the port target domain list. The portTargetDomainListMembership is expressed using a shorthand that specifies which learning domains belong in the port target domain list. An example of a specification would be : (2-4,6,8) where commas separate learning domains and hyphens are short-hand for specifying a range of numbers.. This example would map the learning domain to the port target domain list consisting of learning_domains 2, 3, 4, 6, and 8. Valid values for learning domains are 1-8. A port target domain list will read back in a form equivalent to the form written. It may not read back exactly as written. " ::= { portTargetDomainListMembershipEntry 3 } lBDomainMembershipTable OBJECT-TYPE SYNTAX SEQUENCE OF LBDomainMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " The table for storing the logical bridge domain membership. " ::= { gigaSets 6 } lBDomainMembershipEntry OBJECT-TYPE SYNTAX LBDomainMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " An entry stores information about a logical bridge domain. " INDEX { lBDomainNumber } ::= { lBDomainMembershipTable 1 } LBDomainMembershipEntry ::= SEQUENCE { lBDomainNumber INTEGER, lBDomainMembership DisplayString, lBDomainMembershipWorkBuf DisplayString } lBDomainNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The logical bridge domain number. It is unique within this table and must be between 1 and 8. " ::= { lBDomainMembershipEntry 1 } lBDomainMembership OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION " This object displays the learning domain numbers which are members of the indexed logical bridge domain in the current box configuration. " ::= { lBDomainMembershipEntry 2 } lBDomainMembershipWorkBuf OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " Managers can specify logical bridge domains as many times as needed without effecting the current box configuration using this object. Setting this object to a new value is stored in a local buffer and the changes are not recorded in the nonvolatile memory. The new value is copied into lBDomainMembership and becomes effective when portGroupAction is set to doUpdate and the updating process successfully upgrades the logical bridge domains. A logical bridge domain is expressed using a shorthand that says what learning domains are members of it. An examples of a specification is: (1,3,5) (2-4) Commas separate items in a list of learning domains. Hyphens are short-hand for specifying a range of numbers. Learning domain numbers are specified in decimal. A logical bridge domain will read back in a form equivalent to the form written. It may not read back exactly as written. Without a management set, the default logical bridge domain (i.e., domain number 1) contains all learning domains. The other logical bridge domains are empty sets. A logical bridge domain is created by specifying what learning domains are members of it. Specified learning domains are deleted from the old logical bridge domain and added to the new logical bridge domain. Deletion and addition of the learning domains are atomic across the SNMP messages. Learning domains left out in the specification will automatically join the default logical bridge domain. Reconfiguring logical bridge domains is an expensive operation. Therefore the manager should not change the configuration very often. " ::= { lBDomainMembershipEntry 3 } portGroupAction OBJECT-TYPE SYNTAX INTEGER { none(1), doUpdate(2) } ACCESS read-write STATUS mandatory DESCRIPTION " To initiate a configuration upgrade of a box, set this object. The tables updated with this set operation are: portGroupMembershipTable, learningDomainMembershipTable, portTargetDomainListMembershipTable, lBDomainMembershipTable The handler checks the consistency of the manager's configuraton of the box specified in the tables' working buffer. If no configuraton error is detected, the box starts the reconfiguration process and the working buffers are copied into their corresponding variables. The changes will survive after a system crash. Reading this object always returns the value none(1). " ::= { gigaSets 7 } portGroupActionStatus OBJECT-TYPE SYNTAX INTEGER { success(1), failedDueToOthers(2), failedDueToPGSpec(3), failedDueToLDSpec(4), failedDueToTLDSpec(5), failedDueToLBDSpec(6) } ACCESS read-only STATUS mandatory DESCRIPTION " This object shows the result of the most recent setting of portGroupAction to doUpdate(2). " ::= { gigaSets 8 } trafficGroupMembershipTable OBJECT-TYPE SYNTAX SEQUENCE OF TrafficGroupMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table allows the user to add and delete physical ports to traffic groups. There can be from 1 to 16 traffic groups. A traffic group is a collection of physical ports that is used to allow single path traffic coming in on physical ports to be transmitted out a single management assigned member port of a hunt group. This is used to restrict single path traffic from being multipathed in a hunt group. Every physical port must belong to one of 16 traffic groups. Traffic group 1 is the default traffic group. All ports that do not belong to traffic groups 2-16 belong to the default traffic group. " ::= { gigaSets 9 } trafficGroupMembershipEntry OBJECT-TYPE SYNTAX TrafficGroupMembershipEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " An entry that stores information about a traffic group. " INDEX { trafficGroupNumber } ::= { trafficGroupMembershipTable 1 } TrafficGroupMembershipEntry ::= SEQUENCE { trafficGroupNumber INTEGER, trafficGroupMembership DisplayString } trafficGroupNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " The index for the traffic group membership is a traffic group number. Traffic group numbers are in the range 1-16. Traffic group 1 is the default traffic group. " ::= { trafficGroupMembershipEntry 1 } trafficGroupMembership OBJECT-TYPE SYNTAX DisplayString ACCESS read-write STATUS mandatory DESCRIPTION " The trafficGroupMembership object allows the user to add and delete physical ports from traffic groups. Because a physical port can only belong to one traffic group, the last assignment of a physical port to a traffic group will determine the traffic group in which the physical port is a member. There is a default traffic group which physical ports belong to until management changes the assignments of physical ports to traffic groups. If a physical port is removed from a traffic group, it is placed back into the default traffic group. The default traffic group can not be modified directly. It changes when new traffic groups are added or removed from other traffic groups. The default traffic group is traffic group 1. The trafficGroupMembership is expressed using a shorthand that specifies which physical ports belong in the traffic group. An example of a specification would be : (1,6-9,21) where commas separate physical ports and hyphens are short- hand for specifying a range of numbers. This example would assign physical ports 1,6,7,8,9, and 21 to the specified traffic group. Physical port numbers are specified in decimal. A traffic group will read back in a form equivalent to the form written. It may not read back exactly as written. " ::= { trafficGroupMembershipEntry 2 } trafficGroupAttributeTable OBJECT-TYPE SYNTAX SEQUENCE OF TrafficGroupAttributeEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " This table allows traffic group attributes to be set. " ::= { gigaSets 10 } trafficGroupAttributeEntry OBJECT-TYPE SYNTAX TrafficGroupAttributeEntry ACCESS not-accessible STATUS mandatory DESCRIPTION " An entry that stores traffic group attributes. " INDEX { trafficGroupNum, trafficGroupHgNumber } ::= { trafficGroupAttributeTable 1 } TrafficGroupAttributeEntry ::= SEQUENCE { trafficGroupNum INTEGER, trafficGroupHgNumber INTEGER, trafficGroupHgMember INTEGER, trafficGroupCategory INTEGER } trafficGroupNum OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " One of two indexes into the trafficGroupAttributeTable. It is within the range 1-16. " ::= { trafficGroupAttributeEntry 1 } trafficGroupHgNumber OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION " Second of two indexes into the trafficGroupAttributeTable. This is the hunt group that all ports in the traffic group are assigned to and is in the range 37-64. " ::= { trafficGroupAttributeEntry 2 } trafficGroupHgMember OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION " The trafficGroupHgMember is a number in the range 1-16 that maps to a member of the hunt group specified by trafficGroupHgNumber. trafficGroupHgMember 1 maps to the lowest numbered member of the hunt group, trafficGroupHgMember 2 maps to the second lowest numbered member of the hunt group, etc. If the trafficGroupHgMember is greater then the number of members in the hunt group, then it wraps. For example : Given that traffic groups 1,2,3,4,5 all have physical ports. hunt group 37 = {3,6,8} For hunt group 37 : traffic group 1 set to member number 1 traffic group 2 set to member number 2 traffic group 3 set to member number 3 traffic group 4 set to member number 4 traffic group 5 set to member number 5 then trafficGroupHgMember 1 maps to port 3 trafficGroupHgMember 2 maps to port 6 trafficGroupHgMember 3 maps to port 8 trafficGroupHgMember 4 maps to port 3 trafficGroupHgMember 5 maps to port 6 " ::= { trafficGroupAttributeEntry 3 } trafficGroupCategory OBJECT-TYPE SYNTAX INTEGER { fixed (1), reconfig (2) } ACCESS read-write STATUS mandatory DESCRIPTION " The trafficGroupCatagory is defined as follows : fixed ----- fixed means that traffic is to stay on the same port until the port fails. For this value, the member number is ignored completely. The first physical port that comes up in the hunt group will be assigned the traffic. If the port fails the lowest numbered remaining member of the hunt group will be assigned the traffic. If the traffic category is fixed, sequential delivery of packets is almost guaranteed. reconfig -------- reconfig means that the traffic group may be moved from one hunt group member to another whenever any port joins or leaves the hunt group. If possible, the traffic group must use the hunt group member whose trafficGroupHgMember is configured. If the traffic category is reconfig, sequential delivery of packets is guaranteed, except when members enter or leave the hunt group. " ::= { trafficGroupAttributeEntry 4 } -- -- Objects for configuring the ports on one of the Fast Ethernet line -- cards available for the GIGAswitch/FDDI. -- xglTable OBJECT-TYPE SYNTAX SEQUENCE OF XglEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table contains miscellaneous objects for configuring Fast Ethernet interfaces." ::= { gigaXglEthernetGroup 1 } xglEntry OBJECT-TYPE SYNTAX XglEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Data for a particular Fast Ethernet interface. This table may be optionally implemented in such a way as to allow pre-configuration of hardware which has not yet been installed." INDEX { ifIndex } ::= { xglTable 1 } XglEntry ::= SEQUENCE { xglCompliantMtu INTEGER, xglDisableIcmpErrors INTEGER, xglTxErrorsToIcmpFifo INTEGER, xglRxErrorsToIcmpFifo INTEGER, xglEnableAppletalkArpII INTEGER, xglEnableRawIPX INTEGER } xglCompliantMtu OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " When true, packets with a data unit of size <= 1500 bytes are sent and received. When false, packets with a data unit of size <= 1535 bytes are sent and received. " ::= { xglEntry 1 } xglDisableIcmpErrors OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " When true(1), ICMP redirect message processing is disabled for the specified port. " ::= { xglEntry 2 } xglTxErrorsToIcmpFifo OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " When true(1), transmit errors are sent to the ICMP FIFO. " ::= { xglEntry 3 } xglRxErrorsToIcmpFifo OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " When true(1), receive errors are sent to the ICMP FIFO. " ::= { xglEntry 4 } xglEnableAppletalkArpII OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " When true(1), enables Appletalk ARP II support. " ::= { xglEntry 5 } xglEnableRawIPX OBJECT-TYPE SYNTAX INTEGER { true(1), false(2) } ACCESS read-write STATUS mandatory DESCRIPTION " When true(1), enables raw IPX support. " ::= { xglEntry 6 } END