/* -- DO NOT EDIT -- * Generated by smidump version 0.4.8: * smidump -f corba RMON2-MIB * * Derived from RMON2-MIB: * The MIB module for managing remote monitoring * device implementations. This MIB module * extends the architecture introduced in the original * RMON MIB as specified in RFC 2819. * * Copyright (C) The Internet Society (2006). This version of * this MIB module is part of RFC 4502; see the RFC itself for * full legal notices. * * Revision 2006-05-02 00:00: * This version updates the proposed-standard version of the * RMON2 MIB (published as RFC 2021) by adding 2 new * enumerations to the nlMatrixTopNControlRateBase object and * 4 new enumerations to the alMatrixTopNControlRateBase object. * These new enumerations support the creation of high-capacity * topN reports in the High Capacity RMON MIB [RFC3273]. * * Additionally, the following objects have been deprecated, as * they have not had enough independent implementations to * demonstrate interoperability to meet the requirements of a * Draft Standard: * * probeDownloadFile * probeDownloadTFTPServer * probeDownloadAction * probeDownloadStatus * * * * serialMode * serialProtocol * serialTimeout * serialModemInitString * serialModemHangUpString * serialModemConnectResp * serialModemNoConnectResp * serialDialoutTimeout * serialStatus * serialConnectDestIpAddress * serialConnectType * serialConnectDialString * serialConnectSwitchConnectSeq * serialConnectSwitchDisconnectSeq * serialConnectSwitchResetSeq * serialConnectOwner * serialConnectStatus * netConfigIPAddress * netConfigSubnetMask * netConfigStatus * netDefaultGateway * tokenRingMLStats2DroppedFrames * tokenRingMLStats2CreateTime * tokenRingPStats2DroppedFrames * tokenRingPStats2CreateTime * ringStationControl2DroppedFrames * ringStationControl2CreateTime * sourceRoutingStats2DroppedFrames * sourceRoutingStats2CreateTime * trapDestIndex * trapDestCommunity * trapDestProtocol * trapDestAddress * trapDestOwner * trapDestStatus * * In addition, two corrections were made. The LastCreateTime * Textual Convention had been defined with a base type of * another textual convention, which isn't allowed in SMIv2. The * definition has been modified to use TimeTicks as the base * type. * * Further, the SerialConfigEntry SEQUENCE definition included * sub-typing information that is not allowed in SMIv2. This * information has been deleted. Ranges were added to a number of * objects and textual-conventions to constrain their maximum * (and sometimes minimum) sizes. The addition of these ranges * documents existing practice for these objects. These objects * * * * are: * ControlString * protocolDirID * protocolDirParameters * addressMapNetworkAddress * nlHostAddress * nlMatrixSDSourceAddress * nlMatrixSDDestAddress * nlMatrixDSSourceAddress * nlMatrixDSDestAddress * nlMatrixTopNSourceAddress * nlMatrixTopNDestAddress * alHostEntry * alMatrixSDEntry * alMatrixDSEntry * alMatrixTopNSourceAddress * alMatrixTopNDestAddress * * Finally, the TimeFilter TC has been updated to encourage agent * implementations that allow a MIB walk to behave well even when * performed by an application that is not aware of the special * TimeFilter semantics. * * Revision 2002-07-08 00:00: * Added new enumerations to support the High-Capacity RMON * MIB as defined in RFC 3273. Also fixed some typos and * added clarifications. * * Revision 1996-05-27 00:00: * Original version. Published as RFC 2021. * * $Id: RMON2_MIB.idl 8090 2008-04-18 12:56:29Z strauss $ */ #ifndef _RMON2_MIB_IDL_ #define _RMON2_MIB_IDL_ #include #include #include #include #include #include module RMON2_MIB { typedef IF_MIB::InterfaceIndexType InterfaceIndexType; typedef RMON_MIB::OwnerStringType OwnerStringType; typedef SNMPv2_SMI::Counter32Type Counter32Type; typedef SNMPv2_SMI::Gauge32Type Gauge32Type; typedef SNMPv2_SMI::Integer32Type Integer32Type; typedef SNMPv2_SMI::IpAddressType IpAddressType; typedef SNMPv2_TC::RowStatusType RowStatusType; typedef SNMPv2_TC::TimeStampType TimeStampType; const string moduleIdentity = "rmon"; const ASN1_ObjectIdentifier rmon = "::RMON2_MIB::rmon"; /* The MIB module for managing remote monitoring device implementations. This MIB module extends the architecture introduced in the original RMON MIB as specified in RFC 2819. Copyright (C) The Internet Society (2006). This version of this MIB module is part of RFC 4502; see the RFC itself for full legal notices. LAST-UPDATED: 200605020000Z ORGANIZATION: "IETF RMON MIB Working Group" CONTACT-INFO: "Author: Steve Waldbusser Phone: +1-650-948-6500 Fax : +1-650-745-0671 Email: waldbusser@nextbeacon.com Working Group Chair: Andy Bierman E-mail: ietf@andybierman.com Working Group Mailing List: To subscribe send email to: " REVISION: "200605020000Z" REVISION-DESCRIPTION: "This version updates the proposed-standard version of the RMON2 MIB (published as RFC 2021) by adding 2 new enumerations to the nlMatrixTopNControlRateBase object and 4 new enumerations to the alMatrixTopNControlRateBase object. These new enumerations support the creation of high-capacity topN reports in the High Capacity RMON MIB [RFC3273]. Additionally, the following objects have been deprecated, as they have not had enough independent implementations to demonstrate interoperability to meet the requirements of a Draft Standard: probeDownloadFile probeDownloadTFTPServer probeDownloadAction probeDownloadStatus serialMode serialProtocol serialTimeout serialModemInitString serialModemHangUpString serialModemConnectResp serialModemNoConnectResp serialDialoutTimeout serialStatus serialConnectDestIpAddress serialConnectType serialConnectDialString serialConnectSwitchConnectSeq serialConnectSwitchDisconnectSeq serialConnectSwitchResetSeq serialConnectOwner serialConnectStatus netConfigIPAddress netConfigSubnetMask netConfigStatus netDefaultGateway tokenRingMLStats2DroppedFrames tokenRingMLStats2CreateTime tokenRingPStats2DroppedFrames tokenRingPStats2CreateTime ringStationControl2DroppedFrames ringStationControl2CreateTime sourceRoutingStats2DroppedFrames sourceRoutingStats2CreateTime trapDestIndex trapDestCommunity trapDestProtocol trapDestAddress trapDestOwner trapDestStatus In addition, two corrections were made. The LastCreateTime Textual Convention had been defined with a base type of another textual convention, which isn't allowed in SMIv2. The definition has been modified to use TimeTicks as the base type. Further, the SerialConfigEntry SEQUENCE definition included sub-typing information that is not allowed in SMIv2. This information has been deleted. Ranges were added to a number of objects and textual-conventions to constrain their maximum (and sometimes minimum) sizes. The addition of these ranges documents existing practice for these objects. These objects are: ControlString protocolDirID protocolDirParameters addressMapNetworkAddress nlHostAddress nlMatrixSDSourceAddress nlMatrixSDDestAddress nlMatrixDSSourceAddress nlMatrixDSDestAddress nlMatrixTopNSourceAddress nlMatrixTopNDestAddress alHostEntry alMatrixSDEntry alMatrixDSEntry alMatrixTopNSourceAddress alMatrixTopNDestAddress Finally, the TimeFilter TC has been updated to encourage agent implementations that allow a MIB walk to behave well even when performed by an application that is not aware of the special TimeFilter semantics." REVISION: "200207080000Z" REVISION-DESCRIPTION: "Added new enumerations to support the High-Capacity RMON MIB as defined in RFC 3273. Also fixed some typos and added clarifications." REVISION: "199605270000Z" REVISION-DESCRIPTION: "Original version. Published as RFC 2021." */ /* This TC describes an object that counts events with the following semantics: objects of this type will be set to zero(0) on creation and will thereafter count appropriate events, wrapping back to zero(0) when the value 2^32 is reached. Provided that an application discovers the new object within the minimum time to wrap, it can use the initial value as a delta since it last polled the table of which this object is part. It is important for a management station to be aware of this minimum time and the actual time between polls, and to discard data if the actual time is too long or there is no defined minimum time. Typically, this TC is used in tables where the INDEX space is constantly changing and/or the TimeFilter mechanism is in use. */ typedef ASN1_Unsigned ZeroBasedCounter32Type; /* This TC describes an object that stores the value of the sysUpTime object at the last time its entry was created. This can be used for polling applications to determine that an entry has been deleted and re-created between polls, causing an otherwise undetectable discontinuity in the data. If sysUpTime is reset to zero as a result of a re- initialization of the network management (sub)system, then the values of all LastCreateTime objects are also reset. However, after approximately 497 days without a re- initialization, the sysUpTime object will reach 2^^32-1 and then increment to zero; in this case, existing values of TimeStamp objects do not change. This can lead to ambiguities in the value of TimeStamp objects. */ typedef ASN1_Unsigned LastCreateTimeType; /* To be used for the index to a table. Allows an application to download only those rows changed since a particular time. Note that this is not a history mechanism. Only current values of underlying objects are returned; saved instance values associated with particular values of sysUpTime are not. An entry is considered changed if the value of any object in the entry changes, if the row is created, or if any object in the entry is created or deleted. Note that deleted entries cannot be detected or downloaded. A time-filtered conceptual table is created by inserting a single object of SYNTAX TimeFilter as the first INDEX component in a copy of an existing basic conceptual table (i.e., any SEQUENCE without a TimeFilter INDEX component). Thus, for each conceptual entry 'I' in the basic table, there exists N conceptual entries in the time-filtered version, indexed N.I, where 'N' is equal to the value of sysUpTime. When an application retrieves conceptual instances from a time-filtered table, and an INDEX value is provided for the TimeFilter INDEX component 'N', the agent will only consider returning basic conceptual entries (e.g., 'fooColumn.N.I') if any column within the basic conceptual entry has changed since sysUpTime 'N'. If not, the basic conceptual entry will be ignored for the particular retrieval operation. When sysUpTime is equal to zero, this table shall be empty. One conceptual entry exists for each past value of sysUpTime, except that the whole table is purged should sysUpTime wrap. As an entry in a time-filtered table is updated (i.e., one of the columns in the basic conceptual table is changed), new conceptual entries are also created in the time-filtered version (which still shares the now updated object values with all other instances). The number of unique time-filtered instances that are created is determined by the value of sysUpTime at which the basic entry was last updated. One unique instance will exist for each value of sysUpTime at the last update time for the row. However, a new TimeFilter index instance is created for each new sysUpTime value. The TimeFilter index values not associated with entry updates are called duplicate time-filtered instances. After some deployment experience, it has been determined that a time-filtered table is more efficient if the agent stops a MIB walk operation by skipping over rows with a TimeFilter index value higher than the value in the received GetNext/GetBulk request. That is, instead of incrementing a TimeFilter index value, the agent will continue to the next object or table. As a consequence, GetNext or GetBulk operations will provide only one pass through a time-filtered table. It is suggested that an agent implement a time-filtered table in this manner to improve performance and avoid a MIB walk getting stuck in time-filtered tables. It is, however, still acceptable for an agent to implement a time-filtered table in the traditional manner (i.e., every conceptual time-filtered instance is returned in GetNext and GetBulk PDU responses), and management applications must be able to deal with such traditional implementations. See the appendix for further discussion of this textual convention. The following example is provided to demonstrate TimeFilter behavior: Consider the following basic conceptual table, basicFooTable. (Note that the basic version of a time-filtered table may not actually be defined.) basicFooTable: basicFooTable ... INDEX { fooIndex } BasicFooEntry { fooIndex Integer32, fooCounts Counter32 } For this example, the basicFooTable contains two static conceptual entries (fooIndex equals '1' and '2'), created at time zero. It also contains one dynamic conceptual entry (fooIndex equals '3'), which is created at time '3' and deleted at time '7'. The time-filtered version of the basicFooTable could be defined as follows: FooTable: fooTable ... INDEX { fooTimeMark, fooIndex } FooEntry { fooTimeMark TimeFilter, fooIndex Integer32, fooCounts Counter32 } Note that entries exist in the time-filtered conceptual table only if they actually exist in the underlying (basic) table. For this example, the fooTable will have three underlying basic entries (fooIndex == 1, 2, and 3), with the following activity (for sysUpTime equal 0 to 9): - fooEntry.N.1 is created at time '0' and most recently updated at time '6' to the value '5'. - fooEntry.N.2 is created at time '0' and most recently updated at time '8' to the value '9'. - fooEntry.N.3 is created at time '3', updated at time '5' to the value '17', and deleted at time '7'. The following tables show the values that would be returned for MIB walk operations with various TimeFilter values, done at different times. An application issues a retrieval request at time 'T', with a TimeFilter value, 'N' (typically set to a lower value, such as the value of sysUpTime at the last polling cycle). The following values would be returned in a MIB walk of fooCounts.N if T equals '0' and N equals '0': fooCounts.N.I Value ========================== fooCounts.0.1 0 fooCounts.0.2 0 Note that nothing is returned for fooCounts.0.3, since that entry does not exist at sysUpTime equals '0'. The following values would be returned in a full (traditional) MIB walk of fooCounts.N if T equals '3' and N equals '0': fooCounts.N.I Value ======================= fooCounts.0.1 0 fooCounts.0.2 0 fooCounts.0.3 0 fooCounts.1.3 0 fooCounts.2.3 0 fooCounts.3.3 0 Note that there are no instances for T equals 1 or 2 for the first two values of N, as these entries did not change since they were created at time '0'. Note that the current value for 'fooCounts.N.3' is returned here, even for values of N less than '3' (when the entry was created). The agent only considers the current existence of an entry in the TimeFilter algorithm, not the time when the entry was created. Note that the instances 'fooCounts.0.3', 'fooCounts.1.3', and 'fooCounts.2.3' are duplicates and can be suppressed by the agent in a MIB walk. The following values would be returned in a full (traditional) MIB walk of fooCounts.N if T equals '6' and N equals '3': fooCounts.N.I Value ======================= fooCounts.3.1 5 fooCounts.3.3 17 fooCounts.4.1 5 fooCounts.4.3 17 fooCounts.5.1 5 fooCounts.5.3 17 fooCounts.6.1 5 Note that no instances for entry 'fooCounts.N.2' are returned, since it has not changed since time '3'. Note that all instances except 'fooCounts.5.3' and 'fooCounts.6.1' are duplicates and can be suppressed by the agent in a MIB walk. The following values would be returned in a full (traditional) MIB walk of fooCounts.N if T equals '9' and N equals '6': fooCounts.N.I Value ======================= fooCounts.6.1 5 fooCounts.6.2 9 fooCounts.7.2 9 fooCounts.8.2 9 Note that no instances for entry 'fooCounts.N.3' are returned, since it was deleted at time '7'. Note that instances 'fooCounts.6.2' and 'fooCounts.7.2' are duplicates and can be suppressed by the agent in a MIB walk. */ typedef ASN1_Unsigned TimeFilterType; /* Identifies the source of the data that the associated function is configured to analyze. This source can be any interface on this device. In order to identify a particular interface, this object shall identify the instance of the ifIndex object, defined in [RFC2863], for the desired interface. For example, if an entry were to receive data from interface #1, this object would be set to ifIndex.1. */ typedef ASN1_ObjectIdentifier DataSourceType; /* This data type is used to communicate with a modem or a serial data switch. A ControlString contains embedded commands to control how the device will interact with the remote device through the serial interface. Commands are represented as two-character sequences beginning with the '^' character. The following commands are recognized by the device (note that command characters are case sensitive): ^s Send string that follows, which is terminated by the next command or the end of string. ^c Delay for the number of seconds that follows. Toss out any data received rather than store it in a buffer for parsing. ^t Set timeout to the value represented by the decimal digits that follow. The default timeout is 20 seconds. Note that this timeout may be overridden by a smaller serialTimeout configured for the associated serial interface (see serialConfigTable). ^w Wait for the reply string that follows, which is terminated by the next command or the end of string. Partial and case-insensitive matching is applied, i.e., if the reply string (any case combination) is found anywhere in the received string, then the a match is found. If the current timeout elapses without a match, then the remaining control string is ignored. ^! The ^ character. ^d Delay the number of seconds specified by the decimal digits that follow. ^b Send break for the number of milliseconds specified by the decimal digits that follow. If no digits follow, break will be enforced for 250 milliseconds by default. The following ASCII control characters may be inserted into the '^s' send string or the '^w' reply string: ^@ 0x00 ^A 0x01 .. ^M 0x0D .. ^Z 0x1A ^[ 0x1B ^ 0x1C ^] 0x1D ^^ 0x1E ^_ 0x1F Binary data may also be inserted into the data stream. The control sequence for each byte of binary data is ^0x##, where ## is the hexadecimal representation of the data byte. Two ASCII characters (0-9, a-f, A-F) must follow the '^0x' control prefix. For example, '^0x0D^0x0A' is interpreted as a carriage return followed by a line feed. */ typedef ASN1_OctetString ControlStringType; typedef ASN1_Integer FilterProtocolDirDataLocalIndexType; typedef ASN1_Integer FilterProtocolDirLocalIndexType; typedef ASN1_OctetString ProtocolDirIDType; typedef ASN1_OctetString ProtocolDirParametersType; typedef ASN1_Integer ProtocolDirLocalIndexType; typedef ASN1_OctetString ProtocolDirDescrType; typedef ASN1_OctetString ProtocolDirTypeType; typedef ASN1_Integer ProtocolDirAddressMapConfigType; const ProtocolDirAddressMapConfigType ProtocolDirAddressMapConfigType_notSupported = 1; const ProtocolDirAddressMapConfigType ProtocolDirAddressMapConfigType_supportedOff = 2; const ProtocolDirAddressMapConfigType ProtocolDirAddressMapConfigType_supportedOn = 3; const string ProtocolDirAddressMapConfigType_NameNumberList = "notSupported (1) , supportedOff (2) , supportedOn (3)"; typedef ASN1_Integer ProtocolDirHostConfigType; const ProtocolDirHostConfigType ProtocolDirHostConfigType_notSupported = 1; const ProtocolDirHostConfigType ProtocolDirHostConfigType_supportedOff = 2; const ProtocolDirHostConfigType ProtocolDirHostConfigType_supportedOn = 3; const string ProtocolDirHostConfigType_NameNumberList = "notSupported (1) , supportedOff (2) , supportedOn (3)"; typedef ASN1_Integer ProtocolDirMatrixConfigType; const ProtocolDirMatrixConfigType ProtocolDirMatrixConfigType_notSupported = 1; const ProtocolDirMatrixConfigType ProtocolDirMatrixConfigType_supportedOff = 2; const ProtocolDirMatrixConfigType ProtocolDirMatrixConfigType_supportedOn = 3; const string ProtocolDirMatrixConfigType_NameNumberList = "notSupported (1) , supportedOff (2) , supportedOn (3)"; typedef ASN1_Integer ProtocolDistControlIndexType; typedef ASN1_Integer AddressMapMaxDesiredEntriesType; typedef ASN1_Integer AddressMapControlIndexType; typedef ASN1_OctetString AddressMapNetworkAddressType; typedef ASN1_Integer HlHostControlIndexType; typedef ASN1_Integer HlHostControlNlMaxDesiredEntriesType; typedef ASN1_Integer HlHostControlAlMaxDesiredEntriesType; typedef ASN1_OctetString NlHostAddressType; typedef ASN1_Integer HlMatrixControlIndexType; typedef ASN1_Integer HlMatrixControlNlMaxDesiredEntriesType; typedef ASN1_Integer HlMatrixControlAlMaxDesiredEntriesType; typedef ASN1_OctetString NlMatrixSDSourceAddressType; typedef ASN1_OctetString NlMatrixSDDestAddressType; typedef ASN1_OctetString NlMatrixDSSourceAddressType; typedef ASN1_OctetString NlMatrixDSDestAddressType; typedef ASN1_Integer NlMatrixTopNControlIndexType; typedef ASN1_Integer NlMatrixTopNControlMatrixIndexType; typedef ASN1_Integer NlMatrixTopNControlRateBaseType; const NlMatrixTopNControlRateBaseType NlMatrixTopNControlRateBaseType_nlMatrixTopNPkts = 1; const NlMatrixTopNControlRateBaseType NlMatrixTopNControlRateBaseType_nlMatrixTopNOctets = 2; const NlMatrixTopNControlRateBaseType NlMatrixTopNControlRateBaseType_nlMatrixTopNHighCapacityPkts = 3; const NlMatrixTopNControlRateBaseType NlMatrixTopNControlRateBaseType_nlMatrixTopNHighCapacityOctets = 4; const string NlMatrixTopNControlRateBaseType_NameNumberList = "nlMatrixTopNPkts (1) , nlMatrixTopNOctets (2) , nlMatrixTopNHighCapacityPkts (3) , nlMatrixTopNHighCapacityOctets (4)"; typedef ASN1_Integer NlMatrixTopNControlTimeRemainingType; typedef ASN1_Integer NlMatrixTopNControlRequestedSizeType; typedef ASN1_Integer NlMatrixTopNControlGrantedSizeType; typedef ASN1_Integer NlMatrixTopNIndexType; typedef ASN1_Integer NlMatrixTopNProtocolDirLocalIndexType; typedef ASN1_OctetString NlMatrixTopNSourceAddressType; typedef ASN1_OctetString NlMatrixTopNDestAddressType; typedef ASN1_Integer AlMatrixTopNControlIndexType; typedef ASN1_Integer AlMatrixTopNControlMatrixIndexType; typedef ASN1_Integer AlMatrixTopNControlRateBaseType; const AlMatrixTopNControlRateBaseType AlMatrixTopNControlRateBaseType_alMatrixTopNTerminalsPkts = 1; const AlMatrixTopNControlRateBaseType AlMatrixTopNControlRateBaseType_alMatrixTopNTerminalsOctets = 2; const AlMatrixTopNControlRateBaseType AlMatrixTopNControlRateBaseType_alMatrixTopNAllPkts = 3; const AlMatrixTopNControlRateBaseType AlMatrixTopNControlRateBaseType_alMatrixTopNAllOctets = 4; const AlMatrixTopNControlRateBaseType AlMatrixTopNControlRateBaseType_alMatrixTopNTerminalsHighCapacityPkts = 5; const AlMatrixTopNControlRateBaseType AlMatrixTopNControlRateBaseType_alMatrixTopNTerminalsHighCapacityOctets = 6; const AlMatrixTopNControlRateBaseType AlMatrixTopNControlRateBaseType_alMatrixTopNAllHighCapacityPkts = 7; const AlMatrixTopNControlRateBaseType AlMatrixTopNControlRateBaseType_alMatrixTopNAllHighCapacityOctets = 8; const string AlMatrixTopNControlRateBaseType_NameNumberList = "alMatrixTopNTerminalsPkts (1) , alMatrixTopNTerminalsOctets (2) , alMatrixTopNAllPkts (3) , alMatrixTopNAllOctets (4) , alMatrixTopNTerminalsHighCapacityPkts (5) , alMatrixTopNTerminalsHighCapacityOctets (6) , alMatrixTopNAllHighCapacityPkts (7) , alMatrixTopNAllHighCapacityOctets (8)"; typedef ASN1_Integer AlMatrixTopNControlTimeRemainingType; typedef ASN1_Integer AlMatrixTopNControlRequestedSizeType; typedef ASN1_Integer AlMatrixTopNControlGrantedSizeType; typedef ASN1_Integer AlMatrixTopNIndexType; typedef ASN1_Integer AlMatrixTopNProtocolDirLocalIndexType; typedef ASN1_OctetString AlMatrixTopNSourceAddressType; typedef ASN1_OctetString AlMatrixTopNDestAddressType; typedef ASN1_Integer AlMatrixTopNAppProtocolDirLocalIndexType; typedef ASN1_Integer UsrHistoryControlIndexType; typedef ASN1_Integer UsrHistoryControlObjectsType; typedef ASN1_Integer UsrHistoryControlBucketsRequestedType; typedef ASN1_Integer UsrHistoryControlBucketsGrantedType; typedef ASN1_Integer UsrHistoryControlIntervalType; typedef ASN1_Integer UsrHistoryObjectIndexType; typedef ASN1_Integer UsrHistoryObjectSampleTypeType; const UsrHistoryObjectSampleTypeType UsrHistoryObjectSampleTypeType_absoluteValue = 1; const UsrHistoryObjectSampleTypeType UsrHistoryObjectSampleTypeType_deltaValue = 2; const string UsrHistoryObjectSampleTypeType_NameNumberList = "absoluteValue (1) , deltaValue (2)"; typedef ASN1_Integer UsrHistorySampleIndexType; typedef ASN1_Integer UsrHistoryValStatusType; const UsrHistoryValStatusType UsrHistoryValStatusType_valueNotAvailable = 1; const UsrHistoryValStatusType UsrHistoryValStatusType_valuePositive = 2; const UsrHistoryValStatusType UsrHistoryValStatusType_valueNegative = 3; const string UsrHistoryValStatusType_NameNumberList = "valueNotAvailable (1) , valuePositive (2) , valueNegative (3)"; typedef ASN1_OctetString ProbeCapabilitiesType; typedef ASN1_OctetString ProbeSoftwareRevType; typedef ASN1_OctetString ProbeHardwareRevType; typedef ASN1_OctetString ProbeDateTimeType; typedef ASN1_Integer ProbeResetControlType; const ProbeResetControlType ProbeResetControlType_running = 1; const ProbeResetControlType ProbeResetControlType_warmBoot = 2; const ProbeResetControlType ProbeResetControlType_coldBoot = 3; const string ProbeResetControlType_NameNumberList = "running (1) , warmBoot (2) , coldBoot (3)"; /* Contains the RMON-2 augmentations to RMON-1. */ interface etherStats2Entry : RMON_MIB::etherStatsEntry { /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type etherStatsDroppedFrames; /* The value of sysUpTime when this control entry was last activated. This can be used by the management station to ensure that the table has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType etherStatsCreateTime; }; /* Contains the RMON-2 augmentations to RMON-1. */ interface historyControl2Entry : RMON_MIB::historyControlEntry { /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type historyControlDroppedFrames; }; /* Contains the RMON-2 augmentations to RMON-1. */ interface hostControl2Entry : RMON_MIB::hostControlEntry { /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type hostControlDroppedFrames; /* The value of sysUpTime when this control entry was last activated. This can be used by the management station to ensure that the table has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType hostControlCreateTime; }; /* Contains the RMON-2 augmentations to RMON-1. */ interface matrixControl2Entry : RMON_MIB::matrixControlEntry { /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type matrixControlDroppedFrames; /* The value of sysUpTime when this control entry was last activated. This can be used by the management station to ensure that the table has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType matrixControlCreateTime; }; /* Contains the RMON-2 augmentations to RMON-1. */ interface channel2Entry : RMON_MIB::channelEntry { /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type channelDroppedFrames; /* The value of sysUpTime when this control entry was last activated. This can be used by the management station to ensure that the table has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType channelCreateTime; }; /* Provides a variable-length packet filter feature to the RMON-1 filter table. */ interface filter2Entry : RMON_MIB::filterEntry { /* When this object is set to a non-zero value, the filter that it is associated with performs the following operations on every packet: 1) If the packet doesn't match the protocol directory entry identified by this object, discard the packet and exit (i.e., discard the packet if it is not of the identified protocol). 2) If the associated filterProtocolDirLocalIndex is non-zero and the packet doesn't match the protocol directory entry identified by that object, discard the packet and exit. 3) If the packet matches, perform the regular filter algorithm as if the beginning of this named protocol is the beginning of the packet, potentially applying the filterOffset value to move further into the packet. */ attribute FilterProtocolDirDataLocalIndexType filterProtocolDirDataLocalIndex; /* When this object is set to a non-zero value, the filter that it is associated with will discard the packet if the packet doesn't match this protocol directory entry. */ attribute FilterProtocolDirLocalIndexType filterProtocolDirLocalIndex; }; interface protocolDir : SNMPMgmt::SmiEntry { /* The value of sysUpTime at the time the protocol directory was last modified, either through insertions or deletions, or through modifications of the protocolDirAddressMapConfig, protocolDirHostConfig, or protocolDirMatrixConfig. */ readonly attribute TimeStampType protocolDirLastChange; /* This table lists the protocols that this agent has the capability to decode and count. There is one entry in this table for each such protocol. These protocols represent different network-layer, transport-layer, and higher-layer protocols. The agent should boot up with this table preconfigured with those protocols that it knows about and wishes to monitor. Implementations are strongly encouraged to support protocols higher than the network layer (at least for the protocol distribution group), even for implementations that don't support the application-layer groups. */ SNMPMgmt::SmiTableIterator get_protocolDirTable(); }; /* A conceptual row in the protocolDirTable. An example of the indexing of this entry is protocolDirLocalIndex.8.0.0.0.1.0.0.8.0.2.0.0, which is the encoding of a length of 8, followed by 8 subids encoding the protocolDirID of 1.2048, followed by a length of 2 and the 2 subids encoding zero-valued parameters. Note that some combinations of index values may result in an index that exceeds 128 sub-identifiers in length, which exceeds the maximum for the SNMP protocol. Implementations should take care to avoid such combinations. */ interface protocolDirEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "protocolDirID protocolDirParameters"; /* The locally arbitrary but unique identifier associated with this protocolDir entry. The value for each supported protocol must remain constant at least from one re-initialization of the entity's network management system to the next re-initialization, except that if a protocol is deleted and re-created, it must be re-created with a new value that has not been used since the last re-initialization. The specific value is meaningful only within a given SNMP entity. A protocolDirLocalIndex must not be re-used until the next agent restart in the event that the protocol directory entry is deleted. */ readonly attribute ProtocolDirLocalIndexType protocolDirLocalIndex; /* A textual description of the protocol encapsulation. A probe may choose to describe only a subset of the entire encapsulation (e.g., only the highest layer). This object is intended for human consumption only. This object may not be modified if the associated protocolDirStatus object is equal to active(1). */ attribute ProtocolDirDescrType protocolDirDescr; /* This object describes 2 attributes of this protocol directory entry. The presence or absence of the 'extensible' bit describes whether this protocol directory entry can be extended by the user by creating protocol directory entries that are children of this protocol. An example of an entry that will often allow extensibility is 'ip.udp'. The probe may automatically populate some children of this node, such as 'ip.udp.snmp' and 'ip.udp.dns'. A probe administrator or user may also populate additional children via remote SNMP requests that create entries in this table. When a child node is added for a protocol for which the probe has no built-in support extending a parent node (for which the probe does have built-in support), that child node is not extendable. This is termed 'limited extensibility'. When a child node is added through this extensibility mechanism, the values of protocolDirLocalIndex and protocolDirType shall be assigned by the agent. The other objects in the entry will be assigned by the manager who is creating the new entry. This object also describes whether this agent can recognize addresses for this protocol, should it be a network-level protocol. That is, while a probe may be able to recognize packets of a particular network-layer protocol and count them, it takes additional logic to be able to recognize the addresses in this protocol and to populate network-layer or application-layer tables with the addresses in this protocol. If this bit is set, the agent will recognize network-layer addresses for this protocol and populate the network- and application-layer host and matrix tables with these protocols. Note that when an entry is created, the agent will supply values for the bits that match the capabilities of the agent with respect to this protocol. Note that since row creations usually exercise the limited extensibility feature, these bits will usually be set to zero. */ readonly attribute ProtocolDirTypeType protocolDirType; /* This object describes and configures the probe's support for address mapping for this protocol. When the probe creates entries in this table for all protocols that it understands, it will set the entry to notSupported(1) if it doesn't have the capability to perform address mapping for the protocol or if this protocol is not a network-layer protocol. When an entry is created in this table by a management operation as part of the limited extensibility feature, the probe must set this value to notSupported(1), because limited extensibility of the protocolDirTable does not extend to interpreting addresses of the extended protocols. If the value of this object is notSupported(1), the probe will not perform address mapping for this protocol and shall not allow this object to be changed to any other value. If the value of this object is supportedOn(3), the probe supports address mapping for this protocol and is configured to perform address mapping for this protocol for all addressMappingControlEntries and all interfaces. If the value of this object is supportedOff(2), the probe supports address mapping for this protocol but is configured to not perform address mapping for this protocol for any addressMappingControlEntries and all interfaces. Whenever this value changes from supportedOn(3) to supportedOff(2), the probe shall delete all related entries in the addressMappingTable. */ attribute ProtocolDirAddressMapConfigType protocolDirAddressMapConfig; /* This object describes and configures the probe's support for the network-layer and application-layer host tables for this protocol. When the probe creates entries in this table for all protocols that it understands, it will set the entry to notSupported(1) if it doesn't have the capability to track the nlHostTable for this protocol or if the alHostTable is implemented but doesn't have the capability to track this protocol. Note that if the alHostTable is implemented, the probe may only support a protocol if it is supported in both the nlHostTable and the alHostTable. If the associated protocolDirType object has the addressRecognitionCapable bit set, then this is a network- layer protocol for which the probe recognizes addresses, and thus the probe will populate the nlHostTable and alHostTable with addresses it discovers for this protocol. If the value of this object is notSupported(1), the probe will not track the nlHostTable or alHostTable for this protocol and shall not allow this object to be changed to any other value. If the value of this object is supportedOn(3), the probe supports tracking of the nlHostTable and alHostTable for this protocol and is configured to track both tables for this protocol for all control entries and all interfaces. If the value of this object is supportedOff(2), the probe supports tracking of the nlHostTable and alHostTable for this protocol but is configured to not track these tables for any control entries or interfaces. Whenever this value changes from supportedOn(3) to supportedOff(2), the probe shall delete all related entries in the nlHostTable and alHostTable. Note that since each alHostEntry references 2 protocol directory entries, one for the network address and one for the type of the highest protocol recognized, an entry will only be created in that table if this value is supportedOn(3) for both protocols. */ attribute ProtocolDirHostConfigType protocolDirHostConfig; /* This object describes and configures the probe's support for the network-layer and application-layer matrix tables for this protocol. When the probe creates entries in this table for all protocols that it understands, it will set the entry to notSupported(1) if it doesn't have the capability to track the nlMatrixTables for this protocol or if the alMatrixTables are implemented but don't have the capability to track this protocol. Note that if the alMatrix tables are implemented, the probe may only support a protocol if it is supported in both of the nlMatrixTables and both of the alMatrixTables. If the associated protocolDirType object has the addressRecognitionCapable bit set, then this is a network- layer protocol for which the probe recognizes addresses, and thus the probe will populate both of the nlMatrixTables and both of the alMatrixTables with addresses it discovers for this protocol. If the value of this object is notSupported(1), the probe will not track either of the nlMatrixTables or the alMatrixTables for this protocol and shall not allow this object to be changed to any other value. If the value of this object is supportedOn(3), the probe supports tracking of both of the nlMatrixTables and (if implemented) both of the alMatrixTables for this protocol and is configured to track these tables for this protocol for all control entries and all interfaces. If the value of this object is supportedOff(2), the probe supports tracking of both of the nlMatrixTables and (if implemented) both of the alMatrixTables for this protocol but is configured to not track these tables for this protocol for any control entries or interfaces. Whenever this value changes from supportedOn(3) to supportedOff(2), the probe shall delete all related entries in the nlMatrixTables and the alMatrixTables. Note that since each alMatrixEntry references 2 protocol directory entries, one for the network address and one for the type of the highest protocol recognized, an entry will only be created in that table if this value is supportedOn(3) for both protocols. */ attribute ProtocolDirMatrixConfigType protocolDirMatrixConfig; /* The entity that configured this entry and is therefore using the resources assigned to it. */ attribute OwnerStringType protocolDirOwner; /* The status of this protocol directory entry. An entry may not exist in the active state unless all objects in the entry have an appropriate value. If this object is not equal to active(1), all associated entries in the nlHostTable, nlMatrixSDTable, nlMatrixDSTable, alHostTable, alMatrixSDTable, and alMatrixDSTable shall be deleted. */ attribute RowStatusType protocolDirStatus; }; interface protocolDist : SNMPMgmt::SmiEntry { /* Controls the setup of protocol type distribution statistics tables. Implementations are encouraged to add an entry per monitored interface upon initialization so that a default collection of protocol statistics is available. Rationale: This table controls collection of very basic statistics for any or all of the protocols detected on a given interface. An NMS can use this table to quickly determine bandwidth allocation utilized by different protocols. A media-specific statistics collection could also be configured (e.g., etherStats, trPStats) to easily obtain total frame, octet, and droppedEvents for the same interface. */ SNMPMgmt::SmiTableIterator get_protocolDistControlTable(); /* An entry is made in this table for every protocol in the protocolDirTable that has been seen in at least one packet. Counters are updated in this table for every protocol type that is encountered when parsing a packet, but no counters are updated for packets with MAC-layer errors. Note that if a protocolDirEntry is deleted, all associated entries in this table are removed. */ SNMPMgmt::SmiTableIterator get_protocolDistStatsTable(); }; /* A conceptual row in the protocolDistControlTable. An example of the indexing of this entry is protocolDistControlDroppedFrames.7 */ interface protocolDistControlEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "protocolDistControlIndex"; /* The source of data for the this protocol distribution. The statistics in this group reflect all packets on the local network segment attached to the identified interface. This object may not be modified if the associated protocolDistControlStatus object is equal to active(1). */ attribute DataSourceType protocolDistControlDataSource; /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type protocolDistControlDroppedFrames; /* The value of sysUpTime when this control entry was last activated. This can be used by the management station to ensure that the table has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType protocolDistControlCreateTime; /* The entity that configured this entry and is therefore using the resources assigned to it. */ attribute OwnerStringType protocolDistControlOwner; /* The status of this row. An entry may not exist in the active state unless all objects in the entry have an appropriate value. If this object is not equal to active(1), all associated entries in the protocolDistStatsTable shall be deleted. */ attribute RowStatusType protocolDistControlStatus; }; /* A conceptual row in the protocolDistStatsTable. The index is composed of the protocolDistControlIndex of the associated protocolDistControlEntry, followed by the protocolDirLocalIndex of the associated protocol that this entry represents. In other words, the index identifies the protocol distribution an entry is a part of and the particular protocol that it represents. An example of the indexing of this entry is protocolDistStatsPkts.1.18 */ interface protocolDistStatsEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "protocolDistControlIndex protocolDirLocalIndex"; /* The number of packets of this protocol type received without errors. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type protocolDistStatsPkts; /* The number of octets in packets of this protocol type received since it was added to the protocolDistStatsTable (excluding framing bits, but including FCS octets), except for those octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type protocolDistStatsOctets; }; interface addressMap : SNMPMgmt::SmiEntry { /* The number of times an address mapping entry has been inserted into the addressMapTable. If an entry is inserted, then deleted, and then inserted, this counter will be incremented by 2. Note that the table size can be determined by subtracting addressMapDeletes from addressMapInserts. */ readonly attribute Counter32Type addressMapInserts; /* The number of times an address mapping entry has been deleted from the addressMapTable (for any reason). If an entry is deleted, then inserted, and then deleted, this counter will be incremented by 2. Note that the table size can be determined by subtracting addressMapDeletes from addressMapInserts. */ readonly attribute Counter32Type addressMapDeletes; /* The maximum number of entries that are desired in the addressMapTable. The probe will not create more than this number of entries in the table but may choose to create fewer entries in this table for any reason, including the lack of resources. If this object is set to a value less than the current number of entries, enough entries are chosen in an implementation-dependent manner and deleted so that the number of entries in the table equals the value of this object. If this value is set to -1, the probe may create any number of entries in this table. This object may be used to control how resources are allocated on the probe for the various RMON functions. */ attribute AddressMapMaxDesiredEntriesType addressMapMaxDesiredEntries; /* A table to control the collection of mappings from network layer address to physical address to interface. Note that this is not like the typical RMON controlTable and dataTable in which each entry creates its own data table. Each entry in this table enables the discovery of addresses on a new interface and the placement of address mappings into the central addressMapTable. Implementations are encouraged to add an entry per monitored interface upon initialization so that a default collection of address mappings is available. */ SNMPMgmt::SmiTableIterator get_addressMapControlTable(); /* A table of mappings from network layer address to physical address to interface. The probe will add entries to this table based on the source MAC and network addresses seen in packets without MAC-level errors. The probe will populate this table for all protocols in the protocol directory table whose value of protocolDirAddressMapConfig is equal to supportedOn(3), and will delete any entries whose protocolDirEntry is deleted or has a protocolDirAddressMapConfig value of supportedOff(2). */ SNMPMgmt::SmiTableIterator get_addressMapTable(); }; /* A conceptual row in the addressMapControlTable. An example of the indexing of this entry is addressMapControlDroppedFrames.1 */ interface addressMapControlEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "addressMapControlIndex"; /* The source of data for this addressMapControlEntry. */ attribute DataSourceType addressMapControlDataSource; /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type addressMapControlDroppedFrames; /* The entity that configured this entry and is therefore using the resources assigned to it. */ attribute OwnerStringType addressMapControlOwner; /* The status of this addressMap control entry. An entry may not exist in the active state unless all objects in the entry have an appropriate value. If this object is not equal to active(1), all associated entries in the addressMapTable shall be deleted. */ attribute RowStatusType addressMapControlStatus; }; /* A conceptual row in the addressMapTable. The protocolDirLocalIndex in the index identifies the network layer protocol of the addressMapNetworkAddress. An example of the indexing of this entry is addressMapSource.783495.18.4.128.2.6.6.11.1.3.6.1.2.1.2.2.1.1.1. Note that some combinations of index values may result in an index that exceeds 128 sub-identifiers in length, which exceeds the maximum for the SNMP protocol. Implementations should take care to avoid such combinations. */ interface addressMapEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "addressMapTimeMark protocolDirLocalIndex addressMapNetworkAddress addressMapSource"; /* The last source physical address on which the associated network address was seen. If the protocol of the associated network address was encapsulated inside of a network-level or higher protocol, this will be the address of the next-lower protocol with the addressRecognitionCapable bit enabled and will be formatted as specified for that protocol. */ readonly attribute ASN1_OctetString addressMapPhysicalAddress; /* The value of sysUpTime at the time this entry was last created or the values of the physical address changed. This can be used to help detect duplicate address problems, in which case this object will be updated frequently. */ readonly attribute TimeStampType addressMapLastChange; }; interface nlHost : SNMPMgmt::SmiEntry { /* A list of higher-layer (i.e., non-MAC) host table control entries. These entries will enable the collection of the network- and application-level host tables indexed by network addresses. Both the network- and application-level host tables are controlled by this table so that they will both be created and deleted at the same time, further increasing the ease with which they can be implemented as a single datastore. (Note that if an implementation stores application-layer host records in memory, it can derive network-layer host records from them.) Entries in the nlHostTable will be created on behalf of each entry in this table. Additionally, if this probe implements the alHostTable, entries in the alHostTable will be created on behalf of each entry in this table. Implementations are encouraged to add an entry per monitored interface upon initialization so that a default collection of host statistics is available. */ SNMPMgmt::SmiTableIterator get_hlHostControlTable(); /* A collection of statistics for a particular network layer address that has been discovered on an interface of this device. The probe will populate this table for all network layer protocols in the protocol directory table whose value of protocolDirHostConfig is equal to supportedOn(3), and will delete any entries whose protocolDirEntry is deleted or has a protocolDirHostConfig value of supportedOff(2). The probe will add to this table all addresses seen as the source or destination address in all packets with no MAC errors, and will increment octet and packet counts in the table for all packets with no MAC errors. */ SNMPMgmt::SmiTableIterator get_nlHostTable(); }; /* A conceptual row in the hlHostControlTable. An example of the indexing of this entry is hlHostControlNlDroppedFrames.1 */ interface hlHostControlEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "hlHostControlIndex"; /* The source of data for the associated host tables. The statistics in this group reflect all packets on the local network segment attached to the identified interface. This object may not be modified if the associated hlHostControlStatus object is equal to active(1). */ attribute DataSourceType hlHostControlDataSource; /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for the associated nlHost entries for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that if the nlHostTable is inactive because no protocols are enabled in the protocol directory, this value should be 0. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type hlHostControlNlDroppedFrames; /* The number of times an nlHost entry has been inserted into the nlHost table. If an entry is inserted, then deleted, and then inserted, this counter will be incremented by 2. To allow for efficient implementation strategies, agents may delay updating this object for short periods of time. For example, an implementation strategy may allow internal data structures to differ from those visible via SNMP for short periods of time. This counter may reflect the internal data structures for those short periods of time. Note that the table size can be determined by subtracting hlHostControlNlDeletes from hlHostControlNlInserts. */ readonly attribute Counter32Type hlHostControlNlInserts; /* The number of times an nlHost entry has been deleted from the nlHost table (for any reason). If an entry is deleted, then inserted, and then deleted, this counter will be incremented by 2. To allow for efficient implementation strategies, agents may delay updating this object for short periods of time. For example, an implementation strategy may allow internal data structures to differ from those visible via SNMP for short periods of time. This counter may reflect the internal data structures for those short periods of time. Note that the table size can be determined by subtracting hlHostControlNlDeletes from hlHostControlNlInserts. */ readonly attribute Counter32Type hlHostControlNlDeletes; /* The maximum number of entries that are desired in the nlHostTable on behalf of this control entry. The probe will not create more than this number of associated entries in the table but may choose to create fewer entries in this table for any reason, including the lack of resources. If this object is set to a value less than the current number of entries, enough entries are chosen in an implementation-dependent manner and deleted so that the number of entries in the table equals the value of this object. If this value is set to -1, the probe may create any number of entries in this table. If the associated hlHostControlStatus object is equal to 'active', this object may not be modified. This object may be used to control how resources are allocated on the probe for the various RMON functions. */ attribute HlHostControlNlMaxDesiredEntriesType hlHostControlNlMaxDesiredEntries; /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for the associated alHost entries for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that if the alHostTable is not implemented or is inactive because no protocols are enabled in the protocol directory, this value should be 0. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type hlHostControlAlDroppedFrames; /* The number of times an alHost entry has been inserted into the alHost table. If an entry is inserted, then deleted, and then inserted, this counter will be incremented by 2. To allow for efficient implementation strategies, agents may delay updating this object for short periods of time. For example, an implementation strategy may allow internal data structures to differ from those visible via SNMP for short periods of time. This counter may reflect the internal data structures for those short periods of time. Note that the table size can be determined by subtracting hlHostControlAlDeletes from hlHostControlAlInserts. */ readonly attribute Counter32Type hlHostControlAlInserts; /* The number of times an alHost entry has been deleted from the alHost table (for any reason). If an entry is deleted, then inserted, and then deleted, this counter will be incremented by 2. To allow for efficient implementation strategies, agents may delay updating this object for short periods of time. For example, an implementation strategy may allow internal data structures to differ from those visible via SNMP for short periods of time. This counter may reflect the internal data structures for those short periods of time. Note that the table size can be determined by subtracting hlHostControlAlDeletes from hlHostControlAlInserts. */ readonly attribute Counter32Type hlHostControlAlDeletes; /* The maximum number of entries that are desired in the alHost table on behalf of this control entry. The probe will not create more than this number of associated entries in the table but may choose to create fewer entries in this table for any reason, including the lack of resources. If this object is set to a value less than the current number of entries, enough entries are chosen in an implementation-dependent manner and deleted so that the number of entries in the table equals the value of this object. If this value is set to -1, the probe may create any number of entries in this table. If the associated hlHostControlStatus object is equal to 'active', this object may not be modified. This object may be used to control how resources are allocated on the probe for the various RMON functions. */ attribute HlHostControlAlMaxDesiredEntriesType hlHostControlAlMaxDesiredEntries; /* The entity that configured this entry and is therefore using the resources assigned to it. */ attribute OwnerStringType hlHostControlOwner; /* The status of this hlHostControlEntry. An entry may not exist in the active state unless all objects in the entry have an appropriate value. If this object is not equal to active(1), all associated entries in the nlHostTable and alHostTable shall be deleted. */ attribute RowStatusType hlHostControlStatus; }; /* A conceptual row in the nlHostTable. The hlHostControlIndex value in the index identifies the hlHostControlEntry on whose behalf this entry was created. The protocolDirLocalIndex value in the index identifies the network layer protocol of the nlHostAddress. An example of the indexing of this entry is nlHostOutPkts.1.783495.18.4.128.2.6.6. Note that some combinations of index values may result in an index that exceeds 128 sub-identifiers in length, which exceeds the maximum for the SNMP protocol. Implementations should take care to avoid such combinations. */ interface nlHostEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "hlHostControlIndex nlHostTimeMark protocolDirLocalIndex nlHostAddress"; /* The number of packets without errors transmitted to this address since it was added to the nlHostTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type nlHostInPkts; /* The number of packets without errors transmitted by this address since it was added to the nlHostTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type nlHostOutPkts; /* The number of octets transmitted to this address since it was added to the nlHostTable (excluding framing bits, but including FCS octets), excluding octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type nlHostInOctets; /* The number of octets transmitted by this address since it was added to the nlHostTable (excluding framing bits, but including FCS octets), excluding octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type nlHostOutOctets; /* The number of packets without errors transmitted by this address that were directed to any MAC broadcast addresses or to any MAC multicast addresses since this host was added to the nlHostTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type nlHostOutMacNonUnicastPkts; /* The value of sysUpTime when this entry was last activated. This can be used by the management station to ensure that the entry has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType nlHostCreateTime; }; interface nlMatrix : SNMPMgmt::SmiEntry { /* A list of higher-layer (i.e., non-MAC) matrix control entries. These entries will enable the collection of the network- and application-level matrix tables containing conversation statistics indexed by pairs of network addresses. Both the network- and application-level matrix tables are controlled by this table so that they will both be created and deleted at the same time, further increasing the ease with which they can be implemented as a single datastore. (Note that if an implementation stores application-layer matrix records in memory, it can derive network-layer matrix records from them.) Entries in the nlMatrixSDTable and nlMatrixDSTable will be created on behalf of each entry in this table. Additionally, if this probe implements the alMatrix tables, entries in the alMatrix tables will be created on behalf of each entry in this table. */ SNMPMgmt::SmiTableIterator get_hlMatrixControlTable(); /* A list of traffic matrix entries that collect statistics for conversations between two network-level addresses. This table is indexed first by the source address and then by the destination address to make it convenient to collect all conversations from a particular address. The probe will populate this table for all network layer protocols in the protocol directory table whose value of protocolDirMatrixConfig is equal to supportedOn(3), and will delete any entries whose protocolDirEntry is deleted or has a protocolDirMatrixConfig value of supportedOff(2). The probe will add to this table all pairs of addresses seen in all packets with no MAC errors and will increment octet and packet counts in the table for all packets with no MAC errors. Further, this table will only contain entries that have a corresponding entry in the nlMatrixDSTable with the same source address and destination address. */ SNMPMgmt::SmiTableIterator get_nlMatrixSDTable(); /* A list of traffic matrix entries that collect statistics for conversations between two network-level addresses. This table is indexed first by the destination address and then by the source address to make it convenient to collect all conversations to a particular address. The probe will populate this table for all network layer protocols in the protocol directory table whose value of protocolDirMatrixConfig is equal to supportedOn(3), and will delete any entries whose protocolDirEntry is deleted or has a protocolDirMatrixConfig value of supportedOff(2). The probe will add to this table all pairs of addresses seen in all packets with no MAC errors and will increment octet and packet counts in the table for all packets with no MAC errors. Further, this table will only contain entries that have a corresponding entry in the nlMatrixSDTable with the same source address and destination address. */ SNMPMgmt::SmiTableIterator get_nlMatrixDSTable(); /* A set of parameters that control the creation of a report of the top N matrix entries according to a selected metric. */ SNMPMgmt::SmiTableIterator get_nlMatrixTopNControlTable(); /* A set of statistics for those network-layer matrix entries that have counted the highest number of octets or packets. */ SNMPMgmt::SmiTableIterator get_nlMatrixTopNTable(); }; /* A conceptual row in the hlMatrixControlTable. An example of indexing of this entry is hlMatrixControlNlDroppedFrames.1 */ interface hlMatrixControlEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "hlMatrixControlIndex"; /* The source of the data for the associated matrix tables. The statistics in this group reflect all packets on the local network segment attached to the identified interface. This object may not be modified if the associated hlMatrixControlStatus object is equal to active(1). */ attribute DataSourceType hlMatrixControlDataSource; /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that if the nlMatrixTables are inactive because no protocols are enabled in the protocol directory, this value should be 0. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type hlMatrixControlNlDroppedFrames; /* The number of times an nlMatrix entry has been inserted into the nlMatrix tables. If an entry is inserted, then deleted, and then inserted, this counter will be incremented by 2. The addition of a conversation into both the nlMatrixSDTable and nlMatrixDSTable shall be counted as two insertions (even though every addition into one table must be accompanied by an insertion into the other). To allow for efficient implementation strategies, agents may delay updating this object for short periods of time. For example, an implementation strategy may allow internal data structures to differ from those visible via SNMP for short periods of time. This counter may reflect the internal data structures for those short periods of time. Note that the sum of then nlMatrixSDTable and nlMatrixDSTable sizes can be determined by subtracting hlMatrixControlNlDeletes from hlMatrixControlNlInserts. */ readonly attribute Counter32Type hlMatrixControlNlInserts; /* The number of times an nlMatrix entry has been deleted from the nlMatrix tables (for any reason). If an entry is deleted, then inserted, and then deleted, this counter will be incremented by 2. The deletion of a conversation from both the nlMatrixSDTable and nlMatrixDSTable shall be counted as two deletions (even though every deletion from one table must be accompanied by a deletion from the other). To allow for efficient implementation strategies, agents may delay updating this object for short periods of time. For example, an implementation strategy may allow internal data structures to differ from those visible via SNMP for short periods of time. This counter may reflect the internal data structures for those short periods of time. Note that the table size can be determined by subtracting hlMatrixControlNlDeletes from hlMatrixControlNlInserts. */ readonly attribute Counter32Type hlMatrixControlNlDeletes; /* The maximum number of entries that are desired in the nlMatrix tables on behalf of this control entry. The probe will not create more than this number of associated entries in the table but may choose to create fewer entries in this table for any reason, including the lack of resources. If this object is set to a value less than the current number of entries, enough entries are chosen in an implementation-dependent manner and deleted so that the number of entries in the table equals the value of this object. If this value is set to -1, the probe may create any number of entries in this table. If the associated hlMatrixControlStatus object is equal to 'active', this object may not be modified. This object may be used to control how resources are allocated on the probe for the various RMON functions. */ attribute HlMatrixControlNlMaxDesiredEntriesType hlMatrixControlNlMaxDesiredEntries; /* The total number of frames that were received by the probe and therefore not accounted for in the *StatsDropEvents, but that the probe chose not to count for this entry for whatever reason. Most often, this event occurs when the probe is out of some resources and decides to shed load from this collection. This count does not include packets that were not counted because they had MAC-layer errors. Note that if the alMatrixTables are not implemented or are inactive because no protocols are enabled in the protocol directory, this value should be 0. Note that, unlike the dropEvents counter, this number is the exact number of frames dropped. */ readonly attribute Counter32Type hlMatrixControlAlDroppedFrames; /* The number of times an alMatrix entry has been inserted into the alMatrix tables. If an entry is inserted, then deleted, and then inserted, this counter will be incremented by 2. The addition of a conversation into both the alMatrixSDTable and alMatrixDSTable shall be counted as two insertions (even though every addition into one table must be accompanied by an insertion into the other). To allow for efficient implementation strategies, agents may delay updating this object for short periods of time. For example, an implementation strategy may allow internal data structures to differ from those visible via SNMP for short periods of time. This counter may reflect the internal data structures for those short periods of time. Note that the table size can be determined by subtracting hlMatrixControlAlDeletes from hlMatrixControlAlInserts. */ readonly attribute Counter32Type hlMatrixControlAlInserts; /* The number of times an alMatrix entry has been deleted from the alMatrix tables. If an entry is deleted, then inserted, and then deleted, this counter will be incremented by 2. The deletion of a conversation from both the alMatrixSDTable and alMatrixDSTable shall be counted as two deletions (even though every deletion from one table must be accompanied by a deletion from the other). To allow for efficient implementation strategies, agents may delay updating this object for short periods of time. For example, an implementation strategy may allow internal data structures to differ from those visible via SNMP for short periods of time. This counter may reflect the internal data structures for those short periods of time. Note that the table size can be determined by subtracting hlMatrixControlAlDeletes from hlMatrixControlAlInserts. */ readonly attribute Counter32Type hlMatrixControlAlDeletes; /* The maximum number of entries that are desired in the alMatrix tables on behalf of this control entry. The probe will not create more than this number of associated entries in the table but may choose to create fewer entries in this table for any reason, including the lack of resources. If this object is set to a value less than the current number of entries, enough entries are chosen in an implementation-dependent manner and deleted so that the number of entries in the table equals the value of this object. If this value is set to -1, the probe may create any number of entries in this table. If the associated hlMatrixControlStatus object is equal to 'active', this object may not be modified. This object may be used to control how resources are allocated on the probe for the various RMON functions. */ attribute HlMatrixControlAlMaxDesiredEntriesType hlMatrixControlAlMaxDesiredEntries; /* The entity that configured this entry and is therefore using the resources assigned to it. */ attribute OwnerStringType hlMatrixControlOwner; /* The status of this hlMatrixControlEntry. An entry may not exist in the active state unless all objects in the entry have an appropriate value. If this object is not equal to active(1), all associated entries in the nlMatrixSDTable, nlMatrixDSTable, alMatrixSDTable, and alMatrixDSTable shall be deleted by the agent. */ attribute RowStatusType hlMatrixControlStatus; }; /* A conceptual row in the nlMatrixSDTable. The hlMatrixControlIndex value in the index identifies the hlMatrixControlEntry on whose behalf this entry was created. The protocolDirLocalIndex value in the index identifies the network-layer protocol of the nlMatrixSDSourceAddress and nlMatrixSDDestAddress. An example of the indexing of this table is nlMatrixSDPkts.1.783495.18.4.128.2.6.6.4.128.2.6.7. Note that some combinations of index values may result in an index that exceeds 128 sub-identifiers in length, which exceeds the maximum for the SNMP protocol. Implementations should take care to avoid such combinations. */ interface nlMatrixSDEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "hlMatrixControlIndex nlMatrixSDTimeMark protocolDirLocalIndex nlMatrixSDSourceAddress nlMatrixSDDestAddress"; /* The number of packets without errors transmitted from the source address to the destination address since this entry was added to the nlMatrixSDTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type nlMatrixSDPkts; /* The number of octets transmitted from the source address to the destination address since this entry was added to the nlMatrixSDTable (excluding framing bits, but including FCS octets), excluding octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type nlMatrixSDOctets; /* The value of sysUpTime when this entry was last activated. This can be used by the management station to ensure that the entry has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType nlMatrixSDCreateTime; }; /* A conceptual row in the nlMatrixDSTable. The hlMatrixControlIndex value in the index identifies the hlMatrixControlEntry on whose behalf this entry was created. The protocolDirLocalIndex value in the index identifies the network-layer protocol of the nlMatrixDSSourceAddress and nlMatrixDSDestAddress. An example of the indexing of this table is nlMatrixDSPkts.1.783495.18.4.128.2.6.7.4.128.2.6.6. Note that some combinations of index values may result in an index that exceeds 128 sub-identifiers in length, which exceeds the maximum for the SNMP protocol. Implementations should take care to avoid such combinations. */ interface nlMatrixDSEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "hlMatrixControlIndex nlMatrixDSTimeMark protocolDirLocalIndex nlMatrixDSDestAddress nlMatrixDSSourceAddress"; /* The number of packets without errors transmitted from the source address to the destination address since this entry was added to the nlMatrixDSTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type nlMatrixDSPkts; /* The number of octets transmitted from the source address to the destination address since this entry was added to the nlMatrixDSTable (excluding framing bits, but including FCS octets), excluding octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type nlMatrixDSOctets; /* The value of sysUpTime when this entry was last activated. This can be used by the management station to ensure that the entry has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType nlMatrixDSCreateTime; }; /* A conceptual row in the nlMatrixTopNControlTable. An example of the indexing of this table is nlMatrixTopNControlDuration.3 */ interface nlMatrixTopNControlEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "nlMatrixTopNControlIndex"; /* The nlMatrix[SD/DS] table for which a topN report will be prepared on behalf of this entry. The nlMatrix[SD/DS] table is identified by the value of the hlMatrixControlIndex for that table - that value is used here to identify the particular table. This object may not be modified if the associated nlMatrixTopNControlStatus object is equal to active(1). */ attribute NlMatrixTopNControlMatrixIndexType nlMatrixTopNControlMatrixIndex; /* The variable for each nlMatrix[SD/DS] entry that the nlMatrixTopNEntries are sorted by, as well as a control for the table that the results will be reported in. This object may not be modified if the associated nlMatrixTopNControlStatus object is equal to active(1). If this value is less than or equal to 2, when the report is prepared, entries are created in the nlMatrixTopNTable associated with this object. If this value is greater than or equal to 3, when the report is prepared, entries are created in the nlMatrixTopNHighCapacityTable associated with this object. */ attribute NlMatrixTopNControlRateBaseType nlMatrixTopNControlRateBase; /* The number of seconds left in the report currently being collected. When this object is modified by the management station, a new collection is started, possibly aborting a currently running report. The new value is used as the requested duration of this report and is immediately loaded into the associated nlMatrixTopNControlDuration object. When the report finishes, the probe will automatically start another collection with the same initial value of nlMatrixTopNControlTimeRemaining. Thus, the management station may simply read the resulting reports repeatedly, checking the startTime and duration each time to ensure that a report was not missed or that the report parameters were not changed. While the value of this object is non-zero, it decrements by one per second until it reaches zero. At the time that this object decrements to zero, the report is made accessible in the nlMatrixTopNTable, overwriting any report that may be there. When this object is modified by the management station, any associated entries in the nlMatrixTopNTable shall be deleted. (Note that this is a different algorithm than the one used in the hostTopNTable). */ attribute NlMatrixTopNControlTimeRemainingType nlMatrixTopNControlTimeRemaining; /* The number of reports that have been generated by this entry. */ readonly attribute Counter32Type nlMatrixTopNControlGeneratedReports; /* The number of seconds that this report has collected during the last sampling interval. When the associated nlMatrixTopNControlTimeRemaining object is set, this object shall be set by the probe to the same value and shall not be modified until the next time the nlMatrixTopNControlTimeRemaining is set. This value shall be zero if no reports have been requested for this nlMatrixTopNControlEntry. */ readonly attribute ASN1_Integer nlMatrixTopNControlDuration; /* The maximum number of matrix entries requested for this report. When this object is created or modified, the probe should set nlMatrixTopNControlGrantedSize as closely to this object as possible for the particular probe implementation and available resources. */ attribute NlMatrixTopNControlRequestedSizeType nlMatrixTopNControlRequestedSize; /* The maximum number of matrix entries in this report. When the associated nlMatrixTopNControlRequestedSize object is created or modified, the probe should set this object as closely to the requested value as possible for the particular implementation and available resources. The probe must not lower this value except as a side-effect of a set to the associated nlMatrixTopNControlRequestedSize object. If the value of nlMatrixTopNControlRateBase is equal to nlMatrixTopNPkts, when the next topN report is generated, matrix entries with the highest value of nlMatrixTopNPktRate shall be placed in this table in decreasing order of this rate until there is no more room or until there are no more matrix entries. If the value of nlMatrixTopNControlRateBase is equal to nlMatrixTopNOctets, when the next topN report is generated, matrix entries with the highest value of nlMatrixTopNOctetRate shall be placed in this table in decreasing order of this rate until there is no more room or until there are no more matrix entries. It is an implementation-specific matter how entries with the same value of nlMatrixTopNPktRate or nlMatrixTopNOctetRate are sorted. It is also an implementation-specific matter as to whether zero-valued entries are available. */ readonly attribute NlMatrixTopNControlGrantedSizeType nlMatrixTopNControlGrantedSize; /* The value of sysUpTime when this topN report was last started. In other words, this is the time that the associated nlMatrixTopNControlTimeRemaining object was modified to start the requested report or the time the report was last automatically (re)started. This object may be used by the management station to determine whether a report was missed. */ readonly attribute TimeStampType nlMatrixTopNControlStartTime; /* The entity that configured this entry and is therefore using the resources assigned to it. */ attribute OwnerStringType nlMatrixTopNControlOwner; /* The status of this nlMatrixTopNControlEntry. An entry may not exist in the active state unless all objects in the entry have an appropriate value. If this object is not equal to active(1), all associated entries in the nlMatrixTopNTable shall be deleted by the agent. */ attribute RowStatusType nlMatrixTopNControlStatus; }; /* A conceptual row in the nlMatrixTopNTable. The nlMatrixTopNControlIndex value in the index identifies the nlMatrixTopNControlEntry on whose behalf this entry was created. An example of the indexing of this table is nlMatrixTopNPktRate.3.10 */ interface nlMatrixTopNEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "nlMatrixTopNControlIndex nlMatrixTopNIndex"; /* The protocolDirLocalIndex of the network-layer protocol of this entry's network address. */ readonly attribute NlMatrixTopNProtocolDirLocalIndexType nlMatrixTopNProtocolDirLocalIndex; /* The network-layer address of the source host in this conversation. This is represented as an octet string with specific semantics and length as identified by the associated nlMatrixTopNProtocolDirLocalIndex. For example, if the protocolDirLocalIndex indicates an encapsulation of IP, this object is encoded as a length octet of 4, followed by the 4 octets of the IP address, in network byte order. */ readonly attribute NlMatrixTopNSourceAddressType nlMatrixTopNSourceAddress; /* The network-layer address of the destination host in this conversation. This is represented as an octet string with specific semantics and length as identified by the associated nlMatrixTopNProtocolDirLocalIndex. For example, if the nlMatrixTopNProtocolDirLocalIndex indicates an encapsulation of IP, this object is encoded as a length octet of 4, followed by the 4 octets of the IP address, in network byte order. */ readonly attribute NlMatrixTopNDestAddressType nlMatrixTopNDestAddress; /* The number of packets seen from the source host to the destination host during this sampling interval, counted using the rules for counting the nlMatrixSDPkts object. If the value of nlMatrixTopNControlRateBase is nlMatrixTopNPkts, this variable will be used to sort this report. */ readonly attribute Gauge32Type nlMatrixTopNPktRate; /* The number of packets seen from the destination host to the source host during this sampling interval, counted using the rules for counting the nlMatrixSDPkts object. (Note that the corresponding nlMatrixSDPkts object selected is the one whose source address is equal to nlMatrixTopNDestAddress and whose destination address is equal to nlMatrixTopNSourceAddress.) Note that if the value of nlMatrixTopNControlRateBase is equal to nlMatrixTopNPkts, the sort of topN entries is based entirely on nlMatrixTopNPktRate, and not on the value of this object. */ readonly attribute Gauge32Type nlMatrixTopNReversePktRate; /* The number of octets seen from the source host to the destination host during this sampling interval, counted using the rules for counting the nlMatrixSDOctets object. If the value of nlMatrixTopNControlRateBase is nlMatrixTopNOctets, this variable will be used to sort this report. */ readonly attribute Gauge32Type nlMatrixTopNOctetRate; /* The number of octets seen from the destination host to the source host during this sampling interval, counted using the rules for counting the nlMatrixDSOctets object. (Note that the corresponding nlMatrixSDOctets object selected is the one whose source address is equal to nlMatrixTopNDestAddress and whose destination address is equal to nlMatrixTopNSourceAddress.) Note that if the value of nlMatrixTopNControlRateBase is equal to nlMatrixTopNOctets, the sort of topN entries is based entirely on nlMatrixTopNOctetRate, and not on the value of this object. */ readonly attribute Gauge32Type nlMatrixTopNReverseOctetRate; }; interface alHost : SNMPMgmt::SmiEntry { /* A collection of statistics for a particular protocol from a particular network address that has been discovered on an interface of this device. The probe will populate this table for all protocols in the protocol directory table whose value of protocolDirHostConfig is equal to supportedOn(3), and will delete any entries whose protocolDirEntry is deleted or has a protocolDirHostConfig value of supportedOff(2). The probe will add to this table all addresses seen as the source or destination address in all packets with no MAC errors and will increment octet and packet counts in the table for all packets with no MAC errors. Further, entries will only be added to this table if their address exists in the nlHostTable and will be deleted from this table if their address is deleted from the nlHostTable. */ SNMPMgmt::SmiTableIterator get_alHostTable(); }; /* A conceptual row in the alHostTable. The hlHostControlIndex value in the index identifies the hlHostControlEntry on whose behalf this entry was created. The first protocolDirLocalIndex value in the index identifies the network-layer protocol of the address. The nlHostAddress value in the index identifies the network- layer address of this entry. The second protocolDirLocalIndex value in the index identifies the protocol that is counted by this entry. An example of the indexing in this entry is alHostOutPkts.1.783495.18.4.128.2.6.6.34. Note that some combinations of index values may result in an index that exceeds 128 sub-identifiers in length, which exceeds the maximum for the SNMP protocol. Implementations should take care to avoid such combinations. */ interface alHostEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "hlHostControlIndex alHostTimeMark protocolDirLocalIndex nlHostAddress protocolDirLocalIndex"; /* The number of packets of this protocol type without errors transmitted to this address since it was added to the alHostTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type alHostInPkts; /* The number of packets of this protocol type without errors transmitted by this address since it was added to the alHostTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type alHostOutPkts; /* The number of octets transmitted to this address of this protocol type since it was added to the alHostTable (excluding framing bits, but including FCS octets), excluding octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type alHostInOctets; /* The number of octets transmitted by this address of this protocol type since it was added to the alHostTable (excluding framing bits, but including FCS octets), excluding octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type alHostOutOctets; /* The value of sysUpTime when this entry was last activated. This can be used by the management station to ensure that the entry has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType alHostCreateTime; }; interface alMatrix : SNMPMgmt::SmiEntry { /* A list of application traffic matrix entries that collect statistics for conversations of a particular protocol between two network-level addresses. This table is indexed first by the source address and then by the destination address to make it convenient to collect all statistics from a particular address. The probe will populate this table for all protocols in the protocol directory table whose value of protocolDirMatrixConfig is equal to supportedOn(3), and will delete any entries whose protocolDirEntry is deleted or has a protocolDirMatrixConfig value of supportedOff(2). The probe will add to this table all pairs of addresses for all protocols seen in all packets with no MAC errors and will increment octet and packet counts in the table for all packets with no MAC errors. Further, entries will only be added to this table if their address pair exists in the nlMatrixSDTable and will be deleted from this table if the address pair is deleted from the nlMatrixSDTable. */ SNMPMgmt::SmiTableIterator get_alMatrixSDTable(); /* A list of application traffic matrix entries that collect statistics for conversations of a particular protocol between two network-level addresses. This table is indexed first by the destination address and then by the source address to make it convenient to collect all statistics to a particular address. The probe will populate this table for all protocols in the protocol directory table whose value of protocolDirMatrixConfig is equal to supportedOn(3), and will delete any entries whose protocolDirEntry is deleted or has a protocolDirMatrixConfig value of supportedOff(2). The probe will add to this table all pairs of addresses for all protocols seen in all packets with no MAC errors and will increment octet and packet counts in the table for all packets with no MAC errors. Further, entries will only be added to this table if their address pair exists in the nlMatrixDSTable and will be deleted from this table if the address pair is deleted from the nlMatrixDSTable. */ SNMPMgmt::SmiTableIterator get_alMatrixDSTable(); /* A set of parameters that control the creation of a report of the top N matrix entries according to a selected metric. */ SNMPMgmt::SmiTableIterator get_alMatrixTopNControlTable(); /* A set of statistics for those application-layer matrix entries that have counted the highest number of octets or packets. */ SNMPMgmt::SmiTableIterator get_alMatrixTopNTable(); }; /* A conceptual row in the alMatrixSDTable. The hlMatrixControlIndex value in the index identifies the hlMatrixControlEntry on whose behalf this entry was created. The first protocolDirLocalIndex value in the index identifies the network-layer protocol of the nlMatrixSDSourceAddress and nlMatrixSDDestAddress. The nlMatrixSDSourceAddress value in the index identifies the network-layer address of the source host in this conversation. The nlMatrixSDDestAddress value in the index identifies the network-layer address of the destination host in this conversation. The second protocolDirLocalIndex value in the index identifies the protocol that is counted by this entry. An example of the indexing of this entry is alMatrixSDPkts.1.783495.18.4.128.2.6.6.4.128.2.6.7.34. Note that some combinations of index values may result in an index that exceeds 128 sub-identifiers in length, which exceeds the maximum for the SNMP protocol. Implementations should take care to avoid such combinations. */ interface alMatrixSDEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "hlMatrixControlIndex alMatrixSDTimeMark protocolDirLocalIndex nlMatrixSDSourceAddress nlMatrixSDDestAddress protocolDirLocalIndex"; /* The number of packets of this protocol type without errors transmitted from the source address to the destination address since this entry was added to the alMatrixSDTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type alMatrixSDPkts; /* The number of octets in packets of this protocol type transmitted from the source address to the destination address since this entry was added to the alMatrixSDTable (excluding framing bits, but including FCS octets), excluding octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type alMatrixSDOctets; /* The value of sysUpTime when this entry was last activated. This can be used by the management station to ensure that the entry has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType alMatrixSDCreateTime; }; /* A conceptual row in the alMatrixDSTable. The hlMatrixControlIndex value in the index identifies the hlMatrixControlEntry on whose behalf this entry was created. The first protocolDirLocalIndex value in the index identifies the network-layer protocol of the alMatrixDSSourceAddress and alMatrixDSDestAddress. The nlMatrixDSDestAddress value in the index identifies the network-layer address of the destination host in this conversation. The nlMatrixDSSourceAddress value in the index identifies the network-layer address of the source host in this conversation. The second protocolDirLocalIndex value in the index identifies the protocol that is counted by this entry. An example of the indexing of this entry is alMatrixDSPkts.1.783495.18.4.128.2.6.7.4.128.2.6.6.34. Note that some combinations of index values may result in an index that exceeds 128 sub-identifiers in length, which exceeds the maximum for the SNMP protocol. Implementations should take care to avoid such combinations. */ interface alMatrixDSEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "hlMatrixControlIndex alMatrixDSTimeMark protocolDirLocalIndex nlMatrixDSDestAddress nlMatrixDSSourceAddress protocolDirLocalIndex"; /* The number of packets of this protocol type without errors transmitted from the source address to the destination address since this entry was added to the alMatrixDSTable. Note that this is the number of link-layer packets, so if a single network-layer packet is fragmented into several link-layer frames, this counter is incremented several times. */ readonly attribute ZeroBasedCounter32Type alMatrixDSPkts; /* The number of octets in packets of this protocol type transmitted from the source address to the destination address since this entry was added to the alMatrixDSTable (excluding framing bits, but including FCS octets), excluding octets in packets that contained errors. Note that this doesn't count just those octets in the particular protocol frames but includes the entire packet that contained the protocol. */ readonly attribute ZeroBasedCounter32Type alMatrixDSOctets; /* The value of sysUpTime when this entry was last activated. This can be used by the management station to ensure that the entry has not been deleted and recreated between polls. */ readonly attribute LastCreateTimeType alMatrixDSCreateTime; }; /* A conceptual row in the alMatrixTopNControlTable. An example of the indexing of this table is alMatrixTopNControlDuration.3 */ interface alMatrixTopNControlEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "alMatrixTopNControlIndex"; /* The alMatrix[SD/DS] table for which a topN report will be prepared on behalf of this entry. The alMatrix[SD/DS] table is identified by the value of the hlMatrixControlIndex for that table - that value is used here to identify the particular table. This object may not be modified if the associated alMatrixTopNControlStatus object is equal to active(1). */ attribute AlMatrixTopNControlMatrixIndexType alMatrixTopNControlMatrixIndex; /* This object controls which alMatrix[SD/DS] entry that the alMatrixTopNEntries are sorted by, which view of the matrix table that will be used, as well as which table the results will be reported in. The values alMatrixTopNTerminalsPkts, alMatrixTopNTerminalsOctets, alMatrixTopNTerminalsHighCapacityPkts, and alMatrixTopNTerminalsHighCapacityOctets cause collection only from protocols that have no child protocols that are counted. The values alMatrixTopNAllPkts, alMatrixTopNAllOctets, alMatrixTopNAllHighCapacityPkts, and alMatrixTopNAllHighCapacityOctets cause collection from all alMatrix entries. This object may not be modified if the associated alMatrixTopNControlStatus object is equal to active(1). */ attribute AlMatrixTopNControlRateBaseType alMatrixTopNControlRateBase; /* The number of seconds left in the report currently being collected. When this object is modified by the management station, a new collection is started, possibly aborting a currently running report. The new value is used as the requested duration of this report and is immediately loaded into the associated alMatrixTopNControlDuration object. When the report finishes, the probe will automatically start another collection with the same initial value of alMatrixTopNControlTimeRemaining. Thus, the management station may simply read the resulting reports repeatedly, checking the startTime and duration each time to ensure that a report was not missed or that the report parameters were not changed. While the value of this object is non-zero, it decrements by one per second until it reaches zero. At the time that this object decrements to zero, the report is made accessible in the alMatrixTopNTable, overwriting any report that may be there. When this object is modified by the management station, any associated entries in the alMatrixTopNTable shall be deleted. (Note that this is a different algorithm than the one used in the hostTopNTable). */ attribute AlMatrixTopNControlTimeRemainingType alMatrixTopNControlTimeRemaining; /* The number of reports that have been generated by this entry. */ readonly attribute Counter32Type alMatrixTopNControlGeneratedReports; /* The number of seconds that this report has collected during the last sampling interval. When the associated alMatrixTopNControlTimeRemaining object is set, this object shall be set by the probe to the same value and shall not be modified until the next time the alMatrixTopNControlTimeRemaining is set. This value shall be zero if no reports have been requested for this alMatrixTopNControlEntry. */ readonly attribute ASN1_Integer alMatrixTopNControlDuration; /* The maximum number of matrix entries requested for this report. When this object is created or modified, the probe should set alMatrixTopNControlGrantedSize as closely to this object as possible for the particular probe implementation and available resources. */ attribute AlMatrixTopNControlRequestedSizeType alMatrixTopNControlRequestedSize; /* The maximum number of matrix entries in this report. When the associated alMatrixTopNControlRequestedSize object is created or modified, the probe should set this object as closely to the requested value as possible for the particular implementation and available resources. The probe must not lower this value except as a side-effect of a set to the associated alMatrixTopNControlRequestedSize object. If the value of alMatrixTopNControlRateBase is equal to alMatrixTopNTerminalsPkts or alMatrixTopNAllPkts, when the next topN report is generated, matrix entries with the highest value of alMatrixTopNPktRate shall be placed in this table in decreasing order of this rate until there is no more room or until there are no more matrix entries. If the value of alMatrixTopNControlRateBase is equal to alMatrixTopNTerminalsOctets or alMatrixTopNAllOctets, when the next topN report is generated, matrix entries with the highest value of alMatrixTopNOctetRate shall be placed in this table in decreasing order of this rate until there is no more room or until there are no more matrix entries. It is an implementation-specific matter how entries with the same value of alMatrixTopNPktRate or alMatrixTopNOctetRate are sorted. It is also an implementation-specific matter as to whether zero-valued entries are available. */ readonly attribute AlMatrixTopNControlGrantedSizeType alMatrixTopNControlGrantedSize; /* The value of sysUpTime when this topN report was last started. In other words, this is the time that the associated alMatrixTopNControlTimeRemaining object was modified to start the requested report or the time the report was last automatically (re)started. This object may be used by the management station to determine whether a report was missed. */ readonly attribute TimeStampType alMatrixTopNControlStartTime; /* The entity that configured this entry and is therefore using the resources assigned to it. */ attribute OwnerStringType alMatrixTopNControlOwner; /* The status of this alMatrixTopNControlEntry. An entry may not exist in the active state unless all objects in the entry have an appropriate value. If this object is not equal to active(1), all associated entries in the alMatrixTopNTable shall be deleted by the agent. */ attribute RowStatusType alMatrixTopNControlStatus; }; /* A conceptual row in the alMatrixTopNTable. The alMatrixTopNControlIndex value in the index identifies the alMatrixTopNControlEntry on whose behalf this entry was created. An example of the indexing of this table is alMatrixTopNPktRate.3.10 */ interface alMatrixTopNEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "alMatrixTopNControlIndex alMatrixTopNIndex"; /* The protocolDirLocalIndex of the network-layer protocol of this entry's network address. */ readonly attribute AlMatrixTopNProtocolDirLocalIndexType alMatrixTopNProtocolDirLocalIndex; /* The network-layer address of the source host in this conversation. This is represented as an octet string with specific semantics and length as identified by the associated alMatrixTopNProtocolDirLocalIndex. For example, if the alMatrixTopNProtocolDirLocalIndex indicates an encapsulation of IP, this object is encoded as a length octet of 4, followed by the 4 octets of the IP address, in network byte order. */ readonly attribute AlMatrixTopNSourceAddressType alMatrixTopNSourceAddress; /* The network-layer address of the destination host in this conversation. This is represented as an octet string with specific semantics and length as identified by the associated alMatrixTopNProtocolDirLocalIndex. For example, if the alMatrixTopNProtocolDirLocalIndex indicates an encapsulation of IP, this object is encoded as a length octet of 4, followed by the 4 octets of the IP address, in network byte order. */ readonly attribute AlMatrixTopNDestAddressType alMatrixTopNDestAddress; /* The type of the protocol counted by this matrix entry. */ readonly attribute AlMatrixTopNAppProtocolDirLocalIndexType alMatrixTopNAppProtocolDirLocalIndex; /* The number of packets seen of this protocol from the source host to the destination host during this sampling interval, counted using the rules for counting the alMatrixSDPkts object. If the value of alMatrixTopNControlRateBase is alMatrixTopNTerminalsPkts or alMatrixTopNAllPkts, this variable will be used to sort this report. */ readonly attribute Gauge32Type alMatrixTopNPktRate; /* The number of packets seen of this protocol from the destination host to the source host during this sampling interval, counted using the rules for counting the alMatrixDSPkts object. (Note that the corresponding alMatrixSDPkts object selected is the one whose source address is equal to alMatrixTopNDestAddress and whose destination address is equal to alMatrixTopNSourceAddress.) Note that if the value of alMatrixTopNControlRateBase is equal to alMatrixTopNTerminalsPkts or alMatrixTopNAllPkts, the sort of topN entries is based entirely on alMatrixTopNPktRate, and not on the value of this object. */ readonly attribute Gauge32Type alMatrixTopNReversePktRate; /* The number of octets seen of this protocol from the source host to the destination host during this sampling interval, counted using the rules for counting the alMatrixSDOctets object. If the value of alMatrixTopNControlRateBase is alMatrixTopNTerminalsOctets or alMatrixTopNAllOctets, this variable will be used to sort this report. */ readonly attribute Gauge32Type alMatrixTopNOctetRate; /* The number of octets seen of this protocol from the destination host to the source host during this sampling interval, counted using the rules for counting the alMatrixDSOctets object. (Note that the corresponding alMatrixSDOctets object selected is the one whose source address is equal to alMatrixTopNDestAddress and whose destination address is equal to alMatrixTopNSourceAddress.) Note that if the value of alMatrixTopNControlRateBase is equal to alMatrixTopNTerminalsOctets or alMatrixTopNAllOctets, the sort of topN entries is based entirely on alMatrixTopNOctetRate, and not on the value of this object. */ readonly attribute Gauge32Type alMatrixTopNReverseOctetRate; }; interface usrHistory : SNMPMgmt::SmiEntry { /* A list of data-collection configuration entries. */ SNMPMgmt::SmiTableIterator get_usrHistoryControlTable(); /* A list of data-collection configuration entries. */ SNMPMgmt::SmiTableIterator get_usrHistoryObjectTable(); /* A list of user-defined history entries. */ SNMPMgmt::SmiTableIterator get_usrHistoryTable(); }; /* A list of parameters that set up a group of user-defined MIB objects to be sampled periodically (called a bucket-group). For example, an instance of usrHistoryControlInterval might be named usrHistoryControlInterval.1 */ interface usrHistoryControlEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "usrHistoryControlIndex"; /* The number of MIB objects to be collected in the portion of usrHistoryTable associated with this usrHistoryControlEntry. This object may not be modified if the associated instance of usrHistoryControlStatus is equal to active(1). */ attribute UsrHistoryControlObjectsType usrHistoryControlObjects; /* The requested number of discrete time intervals over which data is to be saved in the part of the usrHistoryTable associated with this usrHistoryControlEntry. When this object is created or modified, the probe should set usrHistoryControlBucketsGranted as closely to this object as possible for the particular probe implementation and available resources. */ attribute UsrHistoryControlBucketsRequestedType usrHistoryControlBucketsRequested; /* The number of discrete sampling intervals over which data shall be saved in the part of the usrHistoryTable associated with this usrHistoryControlEntry. When the associated usrHistoryControlBucketsRequested object is created or modified, the probe should set this object as closely to the requested value as possible for the particular probe implementation and available resources. The probe must not lower this value except as a result of a modification to the associated usrHistoryControlBucketsRequested object. The associated usrHistoryControlBucketsRequested object should be set before or at the same time as this object to allow the probe to accurately estimate the resources required for this usrHistoryControlEntry. There will be times when the actual number of buckets associated with this entry is less than the value of this object. In this case, at the end of each sampling interval, a new bucket will be added to the usrHistoryTable. When the number of buckets reaches the value of this object and a new bucket is to be added to the usrHistoryTable, the oldest bucket associated with this usrHistoryControlEntry shall be deleted by the agent so that the new bucket can be added. When the value of this object changes to a value less than the current value, entries are deleted from the usrHistoryTable associated with this usrHistoryControlEntry. Enough of the oldest of these entries shall be deleted by the agent so that their number remains less than or equal to the new value of this object. When the value of this object changes to a value greater than the current value, the number of associated usrHistory entries may be allowed to grow. */ readonly attribute UsrHistoryControlBucketsGrantedType usrHistoryControlBucketsGranted; /* The interval in seconds over which the data is sampled for each bucket in the part of the usrHistory table associated with this usrHistoryControlEntry. Because the counters in a bucket may overflow at their maximum value with no indication, a prudent manager will take into account the possibility of overflow in any of the associated counters. It is important to consider the minimum time in which any counter could overflow on a particular media type and to set the usrHistoryControlInterval object to a value less than this interval. This object may not be modified if the associated usrHistoryControlStatus object is equal to active(1). */ attribute UsrHistoryControlIntervalType usrHistoryControlInterval; /* The entity that configured this entry and is therefore using the resources assigned to it. */ attribute OwnerStringType usrHistoryControlOwner; /* The status of this variable history control entry. An entry may not exist in the active state unless all objects in the entry have an appropriate value. If this object is not equal to active(1), all associated entries in the usrHistoryTable shall be deleted. */ attribute RowStatusType usrHistoryControlStatus; }; /* A list of MIB instances to be sampled periodically. Entries in this table are created when an associated usrHistoryControlObjects object is created. The usrHistoryControlIndex value in the index is that of the associated usrHistoryControlEntry. For example, an instance of usrHistoryObjectVariable might be usrHistoryObjectVariable.1.3 */ interface usrHistoryObjectEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "usrHistoryControlIndex usrHistoryObjectIndex"; /* The object identifier of the particular variable to be sampled. Only variables that resolve to an ASN.1 primitive type of Integer32 (Integer32, Counter, Gauge, or TimeTicks) may be sampled. Because SNMP access control is articulated entirely in terms of the contents of MIB views, no access control mechanism exists that can restrict the value of this object to identify only those objects that exist in a particular MIB view. Because there is thus no acceptable means of restricting the read access that could be obtained through the user history mechanism, the probe must only grant write access to this object in those views that have read access to all objects on the probe. See USM [RFC3414] and VACM [RFC3415] for more information. During a set operation, if the supplied variable name is not available in the selected MIB view, a badValue error must be returned. This object may not be modified if the associated usrHistoryControlStatus object is equal to active(1). */ attribute ASN1_ObjectIdentifier usrHistoryObjectVariable; /* The method of sampling the selected variable for storage in the usrHistoryTable. If the value of this object is absoluteValue(1), the value of the selected variable will be copied directly into the history bucket. If the value of this object is deltaValue(2), the value of the selected variable at the last sample will be subtracted from the current value, and the difference will be stored in the history bucket. If the associated usrHistoryObjectVariable instance could not be obtained at the previous sample interval, then a delta sample is not possible, and the value of the associated usrHistoryValStatus object for this interval will be valueNotAvailable(1). This object may not be modified if the associated usrHistoryControlStatus object is equal to active(1). */ attribute UsrHistoryObjectSampleTypeType usrHistoryObjectSampleType; }; /* A historical sample of user-defined variables. This sample is associated with the usrHistoryControlEntry that set up the parameters for a regular collection of these samples. The usrHistoryControlIndex value in the index identifies the usrHistoryControlEntry on whose behalf this entry was created. The usrHistoryObjectIndex value in the index identifies the usrHistoryObjectEntry on whose behalf this entry was created. For example, an instance of usrHistoryAbsValue, which represents the 14th sample of a variable collected as specified by usrHistoryControlEntry.1 and usrHistoryObjectEntry.1.5, would be named usrHistoryAbsValue.1.14.5 */ interface usrHistoryEntry : SNMPMgmt::SmiEntry { const string IndexVarList = "usrHistoryControlIndex usrHistorySampleIndex usrHistoryObjectIndex"; /* The value of sysUpTime at the start of the interval over which this sample was measured. If the probe keeps track of the time of day, it should start the first sample of the history at a time such that when the next hour of the day begins, a sample is started at that instant. Note that following this rule may require that the probe delay collecting the first sample of the history, as each sample must be of the same interval. Also note that the sample that is currently being collected is not accessible in this table until the end of its interval. */ readonly attribute TimeStampType usrHistoryIntervalStart; /* The value of sysUpTime at the end of the interval over which this sample was measured. */ readonly attribute TimeStampType usrHistoryIntervalEnd; /* The absolute value (i.e., unsigned value) of the user-specified statistic during the last sampling period. The value during the current sampling period is not made available until the period is completed. To obtain the true value for this sampling interval, the associated instance of usrHistoryValStatus must be checked, and usrHistoryAbsValue adjusted as necessary. If the MIB instance could not be accessed during the sampling interval, then this object will have a value of zero, and the associated instance of usrHistoryValStatus will be set to 'valueNotAvailable(1)'. The access control check prescribed in the definition of usrHistoryObjectVariable SHOULD be checked for each sampling interval. If this check determines that access should not be allowed, then this object will have a value of zero, and the associated instance of usrHistoryValStatus will be set to 'valueNotAvailable(1)'. */ readonly attribute Gauge32Type usrHistoryAbsValue; /* This object indicates the validity and sign of the data in the associated instance of usrHistoryAbsValue. If the MIB instance could not be accessed during the sampling interval, then 'valueNotAvailable(1)' will be returned. If the sample is valid and the actual value of the sample is greater than or equal to zero, then 'valuePositive(2)' is returned. If the sample is valid and the actual value of the sample is less than zero, 'valueNegative(3)' will be returned. The associated instance of usrHistoryAbsValue should be multiplied by -1 to obtain the true sample value. */ readonly attribute UsrHistoryValStatusType usrHistoryValStatus; }; interface probeConfig : SNMPMgmt::SmiEntry { /* An indication of the RMON MIB groups supported on at least one interface by this probe. */ readonly attribute ProbeCapabilitiesType probeCapabilities; /* The software revision of this device. This string will have a zero length if the revision is unknown. */ readonly attribute ProbeSoftwareRevType probeSoftwareRev; /* The hardware revision of this device. This string will have a zero length if the revision is unknown. */ readonly attribute ProbeHardwareRevType probeHardwareRev; /* Probe's current date and time. field octets contents range ----- ------ -------- ----- 1 1-2 year 0..65536 2 3 month 1..12 3 4 day 1..31 4 5 hour 0..23 5 6 minutes 0..59 6 7 seconds 0..60 (use 60 for leap-second) 7 8 deci-seconds 0..9 8 9 direction from UTC '+' / '-' 9 10 hours from UTC 0..11 10 11 minutes from UTC 0..59 For example, Tuesday May 26, 1992 at 1:30:15 PM EDT would be displayed as: 1992-5-26,13:30:15.0,-4:0 Note that if only local time is known, then time zone information (fields 8-10) is not present, and that if no time information is known, the null string is returned. */ attribute ProbeDateTimeType probeDateTime; /* Setting this object to warmBoot(2) causes the device to restart the application software with current configuration parameters saved in non-volatile memory. Setting this object to coldBoot(3) causes the device to reinitialize configuration parameters in non-volatile memory to default values and to restart the application software. When the device is running normally, this variable has a value of running(1). */ attribute ProbeResetControlType probeResetControl; }; interface SmiEntryFactory : SNMPMgmt::GenericFactory { filter2Entry create_filter2Entry ( in FilterProtocolDirDataLocalIndexType filterProtocolDirDataLocalIndex, in FilterProtocolDirLocalIndexType filterProtocolDirLocalIndex ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); protocolDirEntry create_protocolDirEntry ( in ProtocolDirIDType protocolDirID, in ProtocolDirParametersType protocolDirParameters, in ProtocolDirDescrType protocolDirDescr, in ProtocolDirAddressMapConfigType protocolDirAddressMapConfig, in ProtocolDirHostConfigType protocolDirHostConfig, in ProtocolDirMatrixConfigType protocolDirMatrixConfig, in OwnerStringType protocolDirOwner, in RowStatusType protocolDirStatus ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); protocolDistControlEntry create_protocolDistControlEntry ( in ProtocolDistControlIndexType protocolDistControlIndex, in DataSourceType protocolDistControlDataSource, in OwnerStringType protocolDistControlOwner, in RowStatusType protocolDistControlStatus ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); addressMap create_addressMap ( in AddressMapMaxDesiredEntriesType addressMapMaxDesiredEntries ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); addressMapControlEntry create_addressMapControlEntry ( in AddressMapControlIndexType addressMapControlIndex, in DataSourceType addressMapControlDataSource, in OwnerStringType addressMapControlOwner, in RowStatusType addressMapControlStatus ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); hlHostControlEntry create_hlHostControlEntry ( in HlHostControlIndexType hlHostControlIndex, in DataSourceType hlHostControlDataSource, in HlHostControlNlMaxDesiredEntriesType hlHostControlNlMaxDesiredEntries, in HlHostControlAlMaxDesiredEntriesType hlHostControlAlMaxDesiredEntries, in OwnerStringType hlHostControlOwner, in RowStatusType hlHostControlStatus ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); hlMatrixControlEntry create_hlMatrixControlEntry ( in HlMatrixControlIndexType hlMatrixControlIndex, in DataSourceType hlMatrixControlDataSource, in HlMatrixControlNlMaxDesiredEntriesType hlMatrixControlNlMaxDesiredEntries, in HlMatrixControlAlMaxDesiredEntriesType hlMatrixControlAlMaxDesiredEntries, in OwnerStringType hlMatrixControlOwner, in RowStatusType hlMatrixControlStatus ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); nlMatrixTopNControlEntry create_nlMatrixTopNControlEntry ( in NlMatrixTopNControlIndexType nlMatrixTopNControlIndex, in NlMatrixTopNControlMatrixIndexType nlMatrixTopNControlMatrixIndex, in NlMatrixTopNControlRateBaseType nlMatrixTopNControlRateBase, in NlMatrixTopNControlTimeRemainingType nlMatrixTopNControlTimeRemaining, in NlMatrixTopNControlRequestedSizeType nlMatrixTopNControlRequestedSize, in OwnerStringType nlMatrixTopNControlOwner, in RowStatusType nlMatrixTopNControlStatus ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); alMatrixTopNControlEntry create_alMatrixTopNControlEntry ( in AlMatrixTopNControlIndexType alMatrixTopNControlIndex, in AlMatrixTopNControlMatrixIndexType alMatrixTopNControlMatrixIndex, in AlMatrixTopNControlRateBaseType alMatrixTopNControlRateBase, in AlMatrixTopNControlTimeRemainingType alMatrixTopNControlTimeRemaining, in AlMatrixTopNControlRequestedSizeType alMatrixTopNControlRequestedSize, in OwnerStringType alMatrixTopNControlOwner, in RowStatusType alMatrixTopNControlStatus ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); usrHistoryControlEntry create_usrHistoryControlEntry ( in UsrHistoryControlIndexType usrHistoryControlIndex, in UsrHistoryControlObjectsType usrHistoryControlObjects, in UsrHistoryControlBucketsRequestedType usrHistoryControlBucketsRequested, in UsrHistoryControlIntervalType usrHistoryControlInterval, in OwnerStringType usrHistoryControlOwner, in RowStatusType usrHistoryControlStatus ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); usrHistoryObjectEntry create_usrHistoryObjectEntry ( in UsrHistoryControlIndexType usrHistoryControlIndex, in UsrHistoryObjectIndexType usrHistoryObjectIndex, in ASN1_ObjectIdentifier usrHistoryObjectVariable, in UsrHistoryObjectSampleTypeType usrHistoryObjectSampleType ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); probeConfig create_probeConfig ( in ProbeDateTimeType probeDateTime, in ProbeResetControlType probeResetControl ) raises ( SNMPMgmt::AlreadyExists, CosLifeCycle::InvalidCriteria, CosLifeCycle::CannotMeetCriteria ); }; /* pseudo */ interface DefaultValues { /* DEFVAL: 0 */ FilterProtocolDirDataLocalIndexType filterProtocolDirDataLocalIndex(); /* DEFVAL: 0 */ FilterProtocolDirLocalIndexType filterProtocolDirLocalIndex(); /* DEFVAL: 1800 */ NlMatrixTopNControlTimeRemainingType nlMatrixTopNControlTimeRemaining(); /* DEFVAL: 150 */ NlMatrixTopNControlRequestedSizeType nlMatrixTopNControlRequestedSize(); /* DEFVAL: 1800 */ AlMatrixTopNControlTimeRemainingType alMatrixTopNControlTimeRemaining(); /* DEFVAL: 150 */ AlMatrixTopNControlRequestedSizeType alMatrixTopNControlRequestedSize(); /* DEFVAL: 50 */ UsrHistoryControlBucketsRequestedType usrHistoryControlBucketsRequested(); /* DEFVAL: 1800 */ UsrHistoryControlIntervalType usrHistoryControlInterval(); /* DEFVAL: direct */ SerialModeType serialMode(); /* DEFVAL: slip */ SerialProtocolType serialProtocol(); /* DEFVAL: 300 */ SerialTimeoutType serialTimeout(); /* DEFVAL: 20 */ SerialDialoutTimeoutType serialDialoutTimeout(); /* DEFVAL: direct */ SerialConnectTypeType serialConnectType(); }; }; #endif /* !_RMON2_MIB_IDL_ */