Network Working Group D. Levi Request for Comments: 2573 SNMP Research, Inc. Obsoletes: 2273 P. Meyer Category: Standards Track Secure Computing Corporation B. Stewart Cisco Systems April 1999 SNMP Applications Status of this Memo This document specifies an Internet standards track protocol for the Internet community, and requests discussion and suggestions for improvements. Please refer to the current edition of the "Internet Official Protocol Standards" (STD 1) for the standardization state and status of this protocol. Distribution of this memo is unlimited. Copyright Notice Copyright (C) The Internet Society (1999). All Rights Reserved. Abstract This memo describes five types of SNMP applications which make use of an SNMP engine as described in [RFC2571]. The types of application described are Command Generators, Command Responders, Notification Originators, Notification Receivers, and Proxy Forwarders. This memo also defines MIB modules for specifying targets of management operations, for notification filtering, and for proxy forwarding. Table Of Contents 1 Overview ..................................................... 2 1.1 Command Generator Applications ............................. 3 1.2 Command Responder Applications ............................. 3 1.3 Notification Originator Applications ....................... 3 1.4 Notification Receiver Applications ......................... 3 1.5 Proxy Forwarder Applications ............................... 4 2 Management Targets ........................................... 5 3 Elements Of Procedure ........................................ 6 3.1 Command Generator Applications ............................. 6 3.2 Command Responder Applications ............................. 9 3.3 Notification Originator Applications ....................... 14 3.4 Notification Receiver Applications ......................... 17 Levi, et al. Standards Track [Page 1] RFC 2573 SNMP Applications April 1999 3.5 Proxy Forwarder Applications ............................... 19 3.5.1 Request Forwarding ....................................... 20 3.5.1.1 Processing an Incoming Request ......................... 20 3.5.1.2 Processing an Incoming Response ........................ 23 3.5.1.3 Processing an Incoming Internal-Class PDU .............. 24 3.5.2 Notification Forwarding .................................. 25 4 The Structure of the MIB Modules ............................. 28 4.1 The Management Target MIB Module ........................... 28 4.1.1 Tag Lists ................................................ 29 4.1.2 Definitions .............................................. 30 4.2 The Notification MIB Module ................................ 43 4.2.1 Definitions .............................................. 43 4.3 The Proxy MIB Module ....................................... 55 4.3.1 Definitions .............................................. 55 5 Identification of Management Targets in Notification Originators ............................................... 61 6 Notification Filtering ....................................... 62 7 Management Target Translation in Proxy Forwarder Applica- tions ..................................................... 63 7.1 Management Target Translation for Request Forwarding ....... 63 7.2 Management Target Translation for Notification Forwarding ........................................................... 64 8 Intellectual Property ........................................ 65 9 Acknowledgments .............................................. 66 10 Security Considerations ..................................... 67 11 References .................................................. 67 12 Editors' Addresses........................................... 69 A. Trap Configuration Example .................................. 70 B. Full Copyright Statement .................................... 72 1. Overview This document describes five types of SNMP applications: - Applications which initiate SNMP Read-Class, and/or Write-Class requests, called 'command generators.' - Applications which respond to SNMP Read-Class, and/or Write-Class requests, called 'command responders.' - Applications which generate SNMP Notification-Class PDUs, called 'notification originators.' - Applications which receive SNMP Notification-Class PDUs, called 'notification receivers.' - Applications which forward SNMP messages, called 'proxy forwarders.' Levi, et al. Standards Track [Page 2] RFC 2573 SNMP Applications April 1999 Note that there are no restrictions on which types of applications may be associated with a particular SNMP engine. For example, a single SNMP engine may, in fact, be associated with both command generator and command responder applications. The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119]. 1.1. Command Generator Applications A command generator application initiates SNMP Read-Class and/or Write-Class requests, as well as processing the response to a request which it generated. 1.2. Command Responder Applications A command responder application receives SNMP Read-Class and/or Write-Class requests destined for the local system as indicated by the fact that the contextEngineID in the received request is equal to that of the local engine through which the request was received. The command responder application will perform the appropriate protocol operation, using access control, and will generate a response message to be sent to the request's originator. 1.3. Notification Originator Applications A notification originator application conceptually monitors a system for particular events or conditions, and generates Notification-Class messages based on these events or conditions. A notification originator must have a mechanism for determining where to send messages, and what SNMP version and security parameters to use when sending messages. A mechanism and MIB module for this purpose is provided in this document. Note that Notification-Class PDUs generated by a notification originator may be either Confirmed-Class or Unconfirmed-Class PDU types. 1.4. Notification Receiver Applications A notification receiver application listens for notification messages, and generates response messages when a message containing a Confirmed-Class PDU is received. Levi, et al. Standards Track [Page 3] RFC 2573 SNMP Applications April 1999 1.5. Proxy Forwarder Applications A proxy forwarder application forwards SNMP messages. Note that implementation of a proxy forwarder application is optional. The sections describing proxy (4.5, 5.3, and 8) may be skipped for implementations that do not include a proxy forwarder application. The term "proxy" has historically been used very loosely, with multiple different meanings. These different meanings include (among others): (1) the forwarding of SNMP requests to other SNMP entities without regard for what managed object types are being accessed; for example, in order to forward an SNMP request from one transport domain to another, or to translate SNMP requests of one version into SNMP requests of another version; (2) the translation of SNMP requests into operations of some non- SNMP management protocol; and (3) support for aggregated managed objects where the value of one managed object instance depends upon the values of multiple other (remote) items of management information. Each of these scenarios can be advantageous; for example, support for aggregation of management information can significantly reduce the bandwidth requirements of large-scale management activities. However, using a single term to cover multiple different scenarios causes confusion. To avoid such confusion, this document uses the term "proxy" with a much more tightly defined meaning. The term "proxy" is used in this document to refer to a proxy forwarder application which forwards either SNMP messages without regard for what managed objects are contained within those messages. This definition is most closely related to the first definition above. Note, however, that in the SNMP architecture [RFC2571], a proxy forwarder is actually an application, and need not be associated with what is traditionally thought of as an SNMP agent. Specifically, the distinction between a traditional SNMP agent and a proxy forwarder application is simple: Levi, et al. Standards Track [Page 4] RFC 2573 SNMP Applications April 1999 - a proxy forwarder application forwards SNMP messages to other SNMP engines according to the context, and irrespective of the specific managed object types being accessed, and forwards the response to such previously forwarded messages back to the SNMP engine from which the original message was received; - in contrast, the command responder application that is part of what is traditionally thought of as an SNMP agent, and which processes SNMP requests according to the (names of the) individual managed object types and instances being accessed, is NOT a proxy forwarder application from the perspective of this document. Thus, when a proxy forwarder application forwards a request or notification for a particular contextEngineID / contextName pair, not only is the information on how to forward the request specifically associated with that context, but the proxy forwarder application has no need of a detailed definition of a MIB view (since the proxy forwarder application forwards the request irrespective of the managed object types). In contrast, a command responder application must have the detailed definition of the MIB view, and even if it needs to issue requests to other entities, via SNMP or otherwise, that need is dependent on the individual managed object instances being accessed (i.e., not only on the context). Note that it is a design goal of a proxy forwarder application to act as an intermediary between the endpoints of a transaction. In particular, when forwarding Confirmed Notification-Class messages, the associated response is forwarded when it is received from the target to which the Notification-Class message was forwarded, rather than generating a response immediately when the Notification-Class message is received. 2. Management Targets Some types of applications (notification generators and proxy forwarders in particular) require a mechanism for determining where and how to send generated messages. This document provides a mechanism and MIB module for this purpose. The set of information that describes where and how to send a message is called a ' Management Target', and consists of two kinds of information: - Destination information, consisting of a transport domain and a transport address. This is also termed a transport endpoint. Levi, et al. Standards Track [Page 5] RFC 2573 SNMP Applications April 1999 - SNMP parameters, consisting of message processing model, security model, security level, and security name information. The SNMP-TARGET-MIB module described later in this document contains one table for each of these types of information. There can be a many-to-many relationship in the MIB between these two types of information. That is, there may be multiple transport endpoints associated with a particular set of SNMP parameters, or a particular transport endpoint may be associated with several sets of SNMP parameters. 3. Elements Of Procedure The following sections describe the procedures followed by each type of application when generating messages for transmission or when processing received messages. Applications communicate with the Dispatcher using the abstract service interfaces defined in [RFC2571]. 3.1. Command Generator Applications A command generator initiates an SNMP request by calling the Dispatcher using the following abstract service interface: statusInformation = -- sendPduHandle if success -- errorIndication if failure sendPdu( IN transportDomain -- transport domain to be used IN transportAddress -- destination network address IN messageProcessingModel -- typically, SNMP version IN securityModel -- Security Model to use IN securityName -- on behalf of this principal IN securityLevel -- Level of Security requested IN contextEngineID -- data from/at this entity IN contextName -- data from/in this context IN pduVersion -- the version of the PDU IN PDU -- SNMP Protocol Data Unit IN expectResponse -- TRUE or FALSE ) Where: - The transportDomain is that of the destination of the message. - The transportAddress is that of the destination of the message. Levi, et al. Standards Track [Page 6] RFC 2573 SNMP Applications April 1999 - The messageProcessingModel indicates which Message Processing Model the application wishes to use. - The securityModel is the security model that the application wishes to use. - The securityName is the security model independent name for the principal on whose behalf the application wishes the message is to be generated. - The securityLevel is the security level that the application wishes to use. - The contextEngineID is provided by the command generator if it wishes to explicitly specify the location of the management information it is requesting. - The contextName is provided by the command generator if it wishes to explicitly specify the local context name for the management information it is requesting. - The pduVersion indicates the version of the PDU to be sent. - The PDU is a value constructed by the command generator containing the management operation that the command generator wishes to perform. - The expectResponse argument indicates that a response is expected. The result of the sendPdu interface indicates whether the PDU was successfully sent. If it was successfully sent, the returned value will be a sendPduHandle. The command generator should store the sendPduHandle so that it can correlate a response to the original request. The Dispatcher is responsible for delivering the response to a particular request to the correct command generator application. The abstract service interface used is: processResponsePdu( -- process Response PDU IN messageProcessingModel -- typically, SNMP version IN securityModel -- Security Model in use IN securityName -- on behalf of this principal IN securityLevel -- Level of Security IN contextEngineID -- data from/at this SNMP entity IN contextName -- data from/in this context IN pduVersion -- the version of the PDU Levi, et al. Standards Track [Page 7] RFC 2573 SNMP Applications April 1999 IN PDU -- SNMP Protocol Data Unit IN statusInformation -- success or errorIndication IN sendPduHandle -- handle from sendPdu ) Where: - The messageProcessingModel is the value from the received response. - The securityModel is the value from the received response. - The securityName is the value from the received response. - The securityLevel is the value from the received response. - The contextEngineID is the value from the received response. - The contextName is the value from the received response. - The pduVersion indicates the version of the PDU in the received response. - The PDU is the value from the received response. - The statusInformation indicates success or failure in receiving the response. - The sendPduHandle is the value returned by the sendPdu call which generated the original request to which this is a response. The procedure when a command generator receives a message is as follows: (1) If the received values of messageProcessingModel, securityModel, securityName, contextEngineID, contextName, and pduVersion are not all equal to the values used in the original request, the response is discarded. (2) The operation type, request-id, error-status, error-index, and variable-bindings are extracted from the PDU and saved. If the request-id is not equal to the value used in the original request, the response is discarded. (3) At this point, it is up to the application to take an appropriate action. The specific action is implementation dependent. If the statusInformation indicates that the request Levi, et al. Standards Track [Page 8] RFC 2573 SNMP Applications April 1999 failed, an appropriate action might be to attempt to transmit the request again, or to notify the person operating the application that a failure occurred. 3.2. Command Responder Applications Before a command responder application can process messages, it must first associate itself with an SNMP engine. The abstract service interface used for this purpose is: statusInformation = -- success or errorIndication registerContextEngineID( IN contextEngineID -- take responsibility for this one IN pduType -- the pduType(s) to be registered ) Where: - The statusInformation indicates success or failure of the registration attempt. - The contextEngineID is equal to the snmpEngineID of the SNMP engine with which the command responder is registering. - The pduType indicates a Read-Class and/or Write-Class PDU. Note that if another command responder application is already registered with an SNMP engine, any further attempts to register with the same contextEngineID and pduType will be denied. This implies that separate command responder applications could register separately for the various pdu types. However, in practice this is undesirable, and only a single command responder application should be registered with an SNMP engine at any given time. A command responder application can disassociate with an SNMP engine using the following abstract service interface: unregisterContextEngineID( IN contextEngineID -- give up responsibility for this one IN pduType -- the pduType(s) to be unregistered ) Where: - The contextEngineID is equal to the snmpEngineID of the SNMP engine with which the command responder is cancelling the registration. Levi, et al. Standards Track [Page 9] RFC 2573 SNMP Applications April 1999 - The pduType indicates a Read-Class and/or Write-Class PDU. Once the command responder has registered with the SNMP engine, it waits to receive SNMP messages. The abstract service interface used for receiving messages is: processPdu( -- process Request/Notification PDU IN messageProcessingModel -- typically, SNMP version IN securityModel -- Security Model in use IN securityName -- on behalf of this principal IN securityLevel -- Level of Security IN contextEngineID -- data from/at this SNMP entity IN contextName -- data from/in this context IN pduVersion -- the version of the PDU IN PDU -- SNMP Protocol Data Unit IN maxSizeResponseScopedPDU -- maximum size of the Response PDU IN stateReference -- reference to state information ) -- needed when sending a response Where: - The messageProcessingModel indicates which Message Processing Model received and processed the message. - The securityModel is the value from the received message. - The securityName is the value from the received message. - The securityLevel is the value from the received message. - The contextEngineID is the value from the received message. - The contextName is the value from the received message. - The pduVersion indicates the version of the PDU in the received message. - The PDU is the value from the received message. - The maxSizeResponseScopedPDU is the maximum allowable size of a ScopedPDU containing a Response PDU (based on the maximum message size that the originator of the message can accept). - The stateReference is a value which references cached information about each received request message. This value must be returned to the Dispatcher in order to generate a response. Levi, et al. Standards Track [Page 10] RFC 2573 SNMP Applications April 1999 The procedure when a message is received is as follows. (1) The operation type is determined from the ASN.1 tag value associated with the PDU parameter. The operation type should always be one of the types previously registered by the application. (2) The request-id is extracted from the PDU and saved. (3) Any PDU type specific parameters are extracted from the PDU and saved (for example, if the PDU type is an SNMPv2 GetBulk PDU, the non-repeaters and max-repetitions values are extracted). (4) The variable-bindings are extracted from the PDU and saved. (5) The management operation represented by the PDU type is performed with respect to the relevant MIB view within the context named by the contextName (for an SNMPv2 PDU type, the operation is performed according to the procedures set forth in [RFC1905]). The relevant MIB view is determined by the securityLevel, securityModel, contextName, securityName, and the class of the PDU type. To determine whether a particular object instance is within the relevant MIB view, the following abstract service interface is called: statusInformation = -- success or errorIndication isAccessAllowed( IN securityModel -- Security Model in use IN securityName -- principal who wants to access IN securityLevel -- Level of Security IN viewType -- read, write, or notify view IN contextName -- context containing variableName IN variableName -- OID for the managed object ) Where: - The securityModel is the value from the received message. - The securityName is the value from the received message. - The securityLevel is the value from the received message. - The viewType indicates whether the PDU type is a Read-Class or Write-Class operation. - The contextName is the value from the received message. Levi, et al. Standards Track [Page 11] RFC 2573 SNMP Applications April 1999 - The variableName is the object instance of the variable for which access rights are to be checked. Normally, the result of the management operation will be a new PDU value, and processing will continue in step (6) below. However, at any time during the processing of the management operation: - If the isAccessAllowed ASI returns a noSuchView, noAccessEntry, or noGroupName error, processing of the management operation is halted, a PDU value is constructed using the values from the originally received PDU, but replacing the error_status with an authorizationError code, and error_index value of 0, and control is passed to step (6) below. - If the isAccessAllowed ASI returns an otherError, processing of the management operation is halted, a different PDU value is constructed using the values from the originally received PDU, but replacing the error_status with a genError code, and control is passed to step (6) below. - If the isAccessAllowed ASI returns a noSuchContext error, processing of the management operation is halted, no result PDU is generated, the snmpUnknownContexts counter is incremented, and control is passed to step (6) below. - If the context named by the contextName parameter is unavailable, processing of the management operation is halted, no result PDU is generated, the snmpUnavailableContexts counter is incremented, and control is passed to step (6) below. (6) The Dispatcher is called to generate a response or report message. The abstract service interface is: returnResponsePdu( IN messageProcessingModel -- typically, SNMP version IN securityModel -- Security Model in use IN securityName -- on behalf of this principal IN securityLevel -- same as on incoming request IN contextEngineID -- data from/at this SNMP entity IN contextName -- data from/in this context IN pduVersion -- the version of the PDU IN PDU -- SNMP Protocol Data Unit IN maxSizeResponseScopedPDU -- maximum size of the Response PDU IN stateReference -- reference to state information -- as presented with the request IN statusInformation -- success or errorIndication ) -- error counter OID/value if error Levi, et al. Standards Track [Page 12] RFC 2573 SNMP Applications April 1999 Where: - The messageProcessingModel is the value from the processPdu call. - The securityModel is the value from the processPdu call. - The securityName is the value from the processPdu call. - The securityLevel is the value from the processPdu call. - The contextEngineID is the value from the processPdu call. - The contextName is the value from the processPdu call. - The pduVersion indicates the version of the PDU to be returned. If no result PDU was generated, the pduVersion is an undefined value. - The PDU is the result generated in step (5) above. If no result PDU was generated, the PDU is an undefined value. - The maxSizeResponseScopedPDU is a local value indicating the maximum size of a ScopedPDU that the application can accept. - The stateReference is the value from the processPdu call. - The statusInformation either contains an indication that no error occurred and that a response should be generated, or contains an indication that an error occurred along with the OID and counter value of the appropriate error counter object. Note that a command responder application should always call the returnResponsePdu abstract service interface, even in the event of an error such as a resource allocation error. In the event of such an error, the PDU value passed to returnResponsePdu should contain appropriate values for errorStatus and errorIndex. Note that the text above describes situations where the snmpUnknownContexts counter is incremented, and where the snmpUnavailableContexts counter is incremented. The difference between these is that the snmpUnknownContexts counter is incremented when a request is received for a context which unknown to the SNMP entity. The snmpUnavailableContexts counter is incremented when a request is received for a context which is known to the SNMP entity, but is currently unavailable. Determining when a context is Levi, et al. Standards Track [Page 13] RFC 2573 SNMP Applications April 1999 unavailable is implementation specific, and some implementations may never encounter this situation, and so may never increment the snmpUnavailableContexts counter. 3.3. Notification Originator Applications A notification originator application generates SNMP messages containing Notification-Class PDUs (for example, SNMPv2-Trap PDUs or Inform PDUs). There is no requirement as to what specific types of Notification-Class PDUs a particular implementation must be capable of generating. Notification originator applications require a mechanism for identifying the management targets to which notifications should be sent. The particular mechanism used is implementation dependent. However, if an implementation makes the configuration of management targets SNMP manageable, it MUST use the SNMP-TARGET-MIB module described in this document. When a notification originator wishes to generate a notification, it must first determine in which context the information to be conveyed in the notification exists, i.e., it must determine the contextEngineID and contextName. It must then determine the set of management targets to which the notification should be sent. The application must also determine, for each management target, what specific PDU type the notification message should contain, and if it is to contain a Confirmed-Class PDU, the number of retries and retransmission algorithm. The mechanism by which a notification originator determines this information is implementation dependent. Once the application has determined this information, the following procedure is performed for each management target: (1) Any appropriate filtering mechanisms are applied to determine whether the notification should be sent to the management target. If such filtering mechanisms determine that the notification should not be sent, processing continues with the next management target. Otherwise, (2) The appropriate set of variable-bindings is retrieved from local MIB instrumentation within the relevant MIB view. The relevant MIB view is determined by the securityLevel, securityModel, contextName, and securityName of the management target. To determine whether a particular object instance is within the relevant MIB view, the isAccessAllowed abstract service interface is used, in the same manner as described in the Levi, et al. Standards Track [Page 14] RFC 2573 SNMP Applications April 1999 preceding section. If the statusInformation returned by isAccessAllowed does not indicate accessAllowed, the notification is not sent to the management target. (3) The NOTIFICATION-TYPE OBJECT IDENTIFIER of the notification (this is the value of the element of the variable bindings whose name is snmpTrapOID.0, i.e., the second variable binding) is checked using the isAccessAllowed abstract service interface, using the same parameters used in the preceding step. If the statusInformation returned by isAccessAllowed does not indicate accessAllowed, the notification is not sent to the management target. (4) A PDU is constructed using a locally unique request-id value, a PDU type as determined by the implementation, an error-status and error-index value of 0, and the variable-bindings supplied previously in step (2). (5) If the notification contains an Unconfirmed-Class PDU, the Dispatcher is called using the following abstract service interface: statusInformation = -- sendPduHandle if success -- errorIndication if failure sendPdu( IN transportDomain -- transport domain to be used IN transportAddress -- destination network address IN messageProcessingModel -- typically, SNMP version IN securityModel -- Security Model to use IN securityName -- on behalf of this principal IN securityLevel -- Level of Security requested IN contextEngineID -- data from/at this entity IN contextName -- data from/in this context IN pduVersion -- the version of the PDU IN PDU -- SNMP Protocol Data Unit IN expectResponse -- TRUE or FALSE ) Where: - The transportDomain is that of the management target. - The transportAddress is that of the management target. - The messageProcessingModel is that of the management target. - The securityModel is that of the management target. Levi, et al. Standards Track [Page 15] RFC 2573 SNMP Applications April 1999 - The securityName is that of the management target. - The securityLevel is that of the management target. - The contextEngineID is the value originally determined for the notification. - The contextName is the value originally determined for the notification. - The pduVersion is the version of the PDU to be sent. - The PDU is the value constructed in step (3) above. - The expectResponse argument indicates that no response is expected. Otherwise, (6) If the notification contains a Confirmed-Class PDU, then: a) The Dispatcher is called using the sendPdu abstract service interface as described in step (4) above, except that the expectResponse argument indicates that a response is expected. b) The application caches information about the management target. c) If a response is received within an appropriate time interval from the transport endpoint of the management target, the notification is considered acknowledged and the cached information is deleted. Otherwise, d) If a response is not received within an appropriate time period, or if a report indication is received, information about the management target is retrieved from the cache, and steps a) through d) are repeated. The number of times these steps are repeated is equal to the previously determined retry count. If this retry count is exceeded, the acknowledgement of the notification is considered to have failed, and processing of the notification for this management target is halted. Note that some report indications might be considered a failure. Such report indications should be interpreted to mean that the acknowledgement of the notification has failed. Levi, et al. Standards Track [Page 16] RFC 2573 SNMP Applications April 1999 Responses to Confirmed-Class PDU notifications will be received via the processResponsePdu abstract service interface. To summarize, the steps that a notification originator follows when determining where to send a notification are: - Determine the targets to which the notification should be sent. - Apply any required filtering to the list of targets. - Determine which targets are authorized to receive the notification. 3.4. Notification Receiver Applications Notification receiver applications receive SNMP Notification messages from the Dispatcher. Before any messages can be received, the notification receiver must register with the Dispatcher using the registerContextEngineID abstract service interface. The parameters used are: - The contextEngineID is an undefined 'wildcard' value. Notifications are delivered to a registered notification receiver regardless of the contextEngineID contained in the notification message. - The pduType indicates the type of notifications that the application wishes to receive (for example, SNMPv2-Trap PDUs or Inform PDUs). Once the notification receiver has registered with the Dispatcher, messages are received using the processPdu abstract service interface. Parameters are: - The messageProcessingModel indicates which Message Processing Model received and processed the message. - The securityModel is the value from the received message. - The securityName is the value from the received message. - The securityLevel is the value from the received message. - The contextEngineID is the value from the received message. - The contextName is the value from the received message. Levi, et al. Standards Track [Page 17] RFC 2573 SNMP Applications April 1999 - The pduVersion indicates the version of the PDU in the received message. - The PDU is the value from the received message. - The maxSizeResponseScopedPDU is the maximum allowable size of a ScopedPDU containing a Response PDU (based on the maximum message size that the originator of the message can accept). - If the message contains an Unconfirmed-Class PDU, the stateReference is undefined and unused. Otherwise, the stateReference is a value which references cached information about the notification. This value must be returned to the Dispatcher in order to generate a response. When an Unconfirmed-Class PDU is delivered to a notification receiver application, it first extracts the SNMP operation type, request-id, error-status, error-index, and variable-bindings from the PDU. After this, processing depends on the particular implementation. When a Confirmed-Class PDU is received, the notification receiver application follows the following procedure: (1) The PDU type, request-id, error-status, error-index, and variable-bindings are extracted from the PDU. (2) A Response-Class PDU is constructed using the extracted request-id and variable-bindings, and with error-status and error-index both set to 0. (3) The Dispatcher is called to generate a response message using the returnResponsePdu abstract service interface. Parameters are: - The messageProcessingModel is the value from the processPdu call. - The securityModel is the value from the processPdu call. - The securityName is the value from the processPdu call. - The securityLevel is the value from the processPdu call. - The contextEngineID is the value from the processPdu call. - The contextName is the value from the processPdu call. - The pduVersion indicates the version of the PDU to be returned. Levi, et al. Standards Track [Page 18] RFC 2573 SNMP Applications April 1999 - The PDU is the result generated in step (2) above. - The maxSizeResponseScopedPDU is a local value indicating the maximum size of a ScopedPDU that the application can accept. - The stateReference is the value from the processPdu call. - The statusInformation indicates that no error occurred and that a response should be generated. 3.5. Proxy Forwarder Applications A proxy forwarder application deals with forwarding SNMP messages. There are four basic types of messages which a proxy forwarder application may need to forward. These are grouped according to the class of PDU type contained in a message. The four basic types of messages are: - Those containing Read-Class or Write-Class PDU types (for example, Get, GetNext, GetBulk, and Set PDU types). These deal with requesting or modifying information located within a particular context. - Those containing Notification-Class PDU types (for example, SNMPv2-Trap and Inform PDU types). These deal with notifications concerning information located within a particular context. - Those containing a Response-Class PDU type. Forwarding of Response PDUs always occurs as a result of receiving a response to a previously forwarded message. - Those containing Internal-Class PDU types (for example, a Report PDU). Forwarding of Internal-Class PDU types always occurs as a result of receiving an Internal-Class PDU in response to a previously forwarded message. For the first type, the proxy forwarder's role is to deliver a request for management information to an SNMP engine which is "closer" or "downstream in the path" to the SNMP engine which has access to that information, and to deliver the response containing the information back to the SNMP engine from which the request was received. The context information in a request is used to determine which SNMP engine has access to the requested information, and this is used to determine where and how to forward the request. Levi, et al. Standards Track [Page 19] RFC 2573 SNMP Applications April 1999 For the second type, the proxy forwarder's role is to determine which SNMP engines should receive notifications about management information from a particular location. The context information in a notification message determines the location to which the information contained in the notification applies. This is used to determine which SNMP engines should receive notification about this information. For the third type, the proxy forwarder's role is to determine which previously forwarded request or notification (if any) the response matches, and to forward the response back to the initiator of the request or notification. For the fourth type, the proxy forwarder's role is to determine which previously forwarded request or notification (if any) the Internal- Class PDU matches, and to forward the Internal-Class PDU back to the initiator of the request or notification. When forwarding messages, a proxy forwarder application must perform a translation of incoming management target information into outgoing management target information. How this translation is performed is implementation specific. In many cases, this will be driven by a preconfigured translation table. If a proxy forwarder application makes the contents of this table SNMP manageable, it MUST use the SNMP-PROXY-MIB module defined in this document. 3.5.1. Request Forwarding There are two phases for request forwarding. First, the incoming request needs to be passed through the proxy application. Then, the resulting response needs to be passed back. These phases are described in the following two sections. 3.5.1.1. Processing an Incoming Request A proxy forwarder application that wishes to forward request messages must first register with the Dispatcher using the registerContextEngineID abstract service interface. The proxy forwarder must register each contextEngineID for which it wishes to forward messages, as well as for each pduType. Note that as the configuration of a proxy forwarder is changed, the particular contextEngineID values for which it is forwarding may change. The proxy forwarder should call the registerContextEngineID and unregisterContextEngineID abstract service interfaces as needed to reflect its current configuration. Levi, et al. Standards Track [Page 20] RFC 2573 SNMP Applications April 1999 A proxy forwarder application should never attempt to register a value of contextEngineID which is equal to the snmpEngineID of the SNMP engine to which the proxy forwarder is associated. Once the proxy forwarder has registered for the appropriate contextEngineID values, it can start processing messages. The following procedure is used: (1) A message is received using the processPdu abstract service interface. The incoming management target information received from the processPdu interface is translated into outgoing management target information. Note that this translation may vary for different values of contextEngineID and/or contextName. The translation should result in a single management target. (2) If appropriate outgoing management target information cannot be found, the proxy forwarder increments the snmpProxyDrops counter [RFC1907], and then calls the Dispatcher using the returnResponsePdu abstract service interface. Parameters are: - The messageProcessingModel is the value from the processPdu call. - The securityModel is the value from the processPdu call. - The securityName is the value from the processPdu call. - The securityLevel is the value from the processPdu call. - The contextEngineID is the value from the processPdu call. - The contextName is the value from the processPdu call. - The pduVersion is the value from the processPdu call. - The PDU is an undefined value. - The maxSizeResponseScopedPDU is a local value indicating the maximum size of a ScopedPDU that the application can accept. - The stateReference is the value from the processPdu call. - The statusInformation indicates that an error occurred and includes the OID and value of the snmpProxyDrops object. Processing of the message stops at this point. Otherwise, Levi, et al. Standards Track [Page 21] RFC 2573 SNMP Applications April 1999 (3) A new PDU is constructed. A unique value of request-id should be used in the new PDU (this value will enable a subsequent response message to be correlated with this request). The remainder of the new PDU is identical to the received PDU, unless the incoming SNMP version and the outgoing SNMP version support different PDU versions, in which case the proxy forwarder ma