RFC3412
Network Working Group J. Case Request for Comments: 3412 SNMP Research, Inc. STD: 62 D. Harrington Obsoletes: 2572 Enterasys Networks Category: Standards Track R. Presuhn
BMC Software, Inc.
B. Wijnen
Lucent Technologies
December 2002
Message Processing and Dispatching for the
Simple Network Management Protocol (SNMP)
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 (2002). All Rights Reserved.
Abstract
This document describes the Message Processing and Dispatching for Simple Network Management Protocol (SNMP) messages within the SNMP architecture. It defines the procedures for dispatching potentially multiple versions of SNMP messages to the proper SNMP Message Processing Models, and for dispatching PDUs to SNMP applications. This document also describes one Message Processing Model - the SNMPv3 Message Processing Model. This document obsoletes RFC 2572.
5.1. Definitions for SNMP Message Processing and Dispatching ... 16
Contents
- 1 Introduction
- 2 Overview
- 3 Elements of Message Processing and Dispatching
- 4 Dispatcher Elements of Procedure
- 5 Definitions
- 6 The SNMPv3 Message Format
- 7 Elements of Procedure for v3MP
- 8 Intellectual Property
- 9 Acknowledgements
Introduction
The Architecture for describing Internet Management Frameworks RFC3411 describes that an SNMP engine is composed of:
1) a Dispatcher 2) a Message Processing Subsystem, 3) a Security Subsystem, and 4) an Access Control Subsystem.
Applications make use of the services of these subsystems.
It is important to understand the SNMP architecture and its terminology to understand where the Message Processing Subsystem and Dispatcher described in this document fit into the architecture and interact with other subsystems within the architecture. The reader is expected to have read and understood the description of the SNMP architecture, defined in RFC3411.
The Dispatcher in the SNMP engine sends and receives SNMP messages. It also dispatches SNMP PDUs to SNMP applications. When an SNMP message needs to be prepared or when data needs to be extracted from an SNMP message, the Dispatcher delegates these tasks to a message version-specific Message Processing Model within the Message Processing Subsystem.
A Message Processing Model is responsible for processing an SNMP version-specific message and for coordinating the interaction with the Security Subsystem to ensure proper security is applied to the SNMP message being handled.
Interactions between the Dispatcher, the Message Processing Subsystem, and applications are modeled using abstract data elements and abstract service interface primitives defined by the SNMP architecture.
Similarly, interactions between the Message Processing Subsystem and the Security Subsystem are modeled using abstract data elements and abstract service interface primitives as defined by the SNMP architecture.
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 BCP 14, RFC 2119.
Overview
The following illustration depicts the Message Processing in relation to SNMP applications, the Security Subsystem and Transport Mappings.
+-------------------------------------------------------------------+ | SNMP Entity | | | | +---------------------------------------------------------------+ | | | Applications | | | | +-----------+ +--------------+ | | | | | Command | | Notification | | | | | | Generator | | Originator | +-----------+ +--------------+| | | | +-----------+ +--------------+ | Proxy | | Other || | | | +-----------+ +--------------+ | Forwarder | |Application(s)|| | | | | Command | | Notification | +-----------+ +--------------+| | | | | Responder | | Receiver | | | | | +-----------+ +--------------+ | | | +---------------------------------------------------------------+ | | ^ ^ ^ ^ | | | | | | | | v v v v | | +--------+-------+---------------+-----------+ | | ^ | | | +---------------------+ +-----------------+ | | | | Message Processing | | Security | | | Dispatcher v | Subsystem | | Subsystem | | | +------------------+ | +------------+ | | | | | | PDU Dispatcher | | +->| v1MP * |<--->| +-------------+ | | | | | | | +------------+ | | | Other | | | | | | | | +------------+ | | | Security | | | | | | | +->| v2cMP * |<--->| | Model | | | | | Message | | | +------------+ | | +-------------+ | | | | Dispatcher <-------->+ | | | | | | | | | +------------+ | | +-------------+ | | | | | | +->| v3MP * |<--->| | User-based | | | | | Transport | | | +------------+ | | | Security | | | | | Mapping | | | +------------+ | | | Model | | | | | (e.g., RFC 3417) | | +->| otherMP * |<--->| +-------------+ | | | +------------------+ | +------------+ | | | | | ^ +---------------------+ +-----------------+ | | | | +----------|--------------------------------------------------------+
v +------------------+ | Network | * One or more models may be present. +------------------+
The Dispatcher
The Dispatcher is a key piece of an SNMP engine. There is only one in an SNMP engine, and its job is to dispatch tasks to the multiple version-specific Message Processing Models, and to dispatch PDUs to various applications.
For outgoing messages, an application provides a PDU to be sent, plus the data needed to prepare and send the message, and the application specifies which version-specific Message Processing Model will be used to prepare the message with the desired security processing. Once the message is prepared, the Dispatcher sends the message.
For incoming messages, the Dispatcher determines the SNMP version of the incoming message and passes the message to the version-specific Message Processing Model to extract the components of the message and to coordinate the processing of security services for the message. After version-specific processing, the PDU Dispatcher determines which application, if any, should receive the PDU for processing and forwards it accordingly.
The Dispatcher, while sending and receiving SNMP messages, collects statistics about SNMP messages and the behavior of the SNMP engine in managed objects to make them accessible to remote SNMP entities. This document defines these managed objects, the MIB module which contains them, and how these managed objects might be used to provide useful management.
Message Processing Subsystem
The SNMP Message Processing Subsystem is the part of an SNMP engine which interacts with the Dispatcher to handle the version-specific SNMP messages. It contains one or more Message Processing Models.
This document describes one Message Processing Model, the SNMPv3 Message Processing Model, in Section 6. The SNMPv3 Message Processing Model is defined in a separate section to show that multiple (independent) Message Processing Models can exist at the same time and that such Models can be described in different documents. The SNMPv3 Message Processing Model can be replaced or supplemented with other Message Processing Models in the future. Two Message Processing Models which are expected to be developed in the future are the SNMPv1 message format RFC1157 and the SNMPv2c message format RFC1901. Others may be developed as needed.
Elements of Message Processing and Dispatching
See RFC3411 for the definitions of:
contextEngineID contextName scopedPDU maxSizeResponseScopedPDU securityModel securityName securityLevel messageProcessingModel
For incoming messages, a version-specific message processing module provides these values to the Dispatcher. For outgoing messages, an application provides these values to the Dispatcher.
For some version-specific processing, the values may be extracted from received messages; for other versions, the values may be determined by algorithm, or by an implementation-defined mechanism. The mechanism by which the value is determined is irrelevant to the Dispatcher.
The following additional or expanded definitions are for use within the Dispatcher.
messageProcessingModel
The value of messageProcessingModel identifies a Message Processing Model. A Message Processing Model describes the version-specific procedures for extracting data from messages, generating messages, calling upon a securityModel to apply its security services to messages, for converting data from a version-specific message format into a generic format usable by the Dispatcher, and for converting data from Dispatcher format into a version-specific message format.
pduVersion
The value of pduVersion represents a specific version of protocol operation and its associated PDU formats, such as SNMPv1 or SNMPv2 RFC3416. The values of pduVersion are specific to the version of the PDU contained in a message, and the PDUs processed by applications. The Dispatcher does not use the value of pduVersion directly.
An application specifies the pduVersion when it requests the PDU Dispatcher to send a PDU to another SNMP engine. The Dispatcher passes the pduVersion to a Message Processing Model, so it knows how to handle the PDU properly.
For incoming messages, the pduVersion is provided to the Dispatcher by a version-specific Message Processing module. The PDU Dispatcher passes the pduVersion to the application so it knows how to handle the PDU properly. For example, a command responder application needs to know whether to use RFC3416 elements of procedure and syntax instead of those specified for SNMPv1.
pduType
A value of the pduType represents a specific type of protocol operation. The values of the pduType are specific to the version of the PDU contained in a message.
Applications register to support particular pduTypes for particular contextEngineIDs.
For incoming messages, pduType is provided to the Dispatcher by a version-specific Message Processing module. It is subsequently used to dispatch the PDU to the application which registered for the pduType for the contextEngineID of the associated scopedPDU.
sendPduHandle
This handle is generated for coordinating the processing of requests and responses between the SNMP engine and an application. The handle must be unique across all version-specific Message Processing Models, and is of local significance only.
Dispatcher Elements of Procedure
This section describes the procedures followed by the Dispatcher when generating and processing SNMP messages.
Sending an SNMP Message to the Network
This section describes the procedure followed by an SNMP engine whenever it sends an SNMP message.
Sending a Request or Notification
The following procedures are followed by the Dispatcher when an application wants to send an SNMP PDU to another (remote) application, i.e., to initiate a communication by originating a message, such as one containing a request or a notification.
1) The application requests this using the abstract service
primitive:
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
)
2) If the messageProcessingModel value does not represent a Message
Processing Model known to the Dispatcher, then an errorIndication (implementation-dependent) is returned to the calling application. No further processing is performed.
3) The Dispatcher generates a sendPduHandle to coordinate subsequent
processing.
4) The Message Dispatcher sends the request to the version-specific
Message Processing module identified by messageProcessingModel using the abstract service primitive:
statusInformation = -- success or error indication
prepareOutgoingMessage(
IN transportDomain -- as specified by application
IN transportAddress -- as specified by application
IN messageProcessingModel -- as specified by application
IN securityModel -- as specified by application
IN securityName -- as specified by application
IN securityLevel -- as specified by application
IN contextEngineID -- as specified by application
IN contextName -- as specified by application
IN pduVersion -- as specified by application
IN PDU -- as specified by application
IN expectResponse -- as specified by application
IN sendPduHandle -- as determined in step 3.
OUT destTransportDomain -- destination transport domain
OUT destTransportAddress -- destination transport address
OUT outgoingMessage -- the message to send
OUT outgoingMessageLength -- the message length
)
5) If the statusInformation indicates an error, the errorIndication
is returned to the calling application. No further processing is performed.
6) If the statusInformation indicates success, the sendPduHandle is
returned to the application, and the outgoingMessage is sent. The transport used to send the outgoingMessage is returned via destTransportDomain, and the address to which it was sent is returned via destTransportAddress.
Outgoing Message Processing is complete.
Sending a Response to the Network
The following procedure is followed when an application wants to return a response back to the originator of an SNMP Request.
1) An application can request this using the abstract service
primitive:
result =
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 Response PDU
IN stateReference -- reference to state information
-- as presented with the request
IN statusInformation -- success or errorIndication
) -- (error counter OID and value
-- when errorIndication)
2) The Message Dispatcher sends the request to the appropriate
Message Processing Model indicated by the received value of messageProcessingModel using the abstract service primitive:
result = -- SUCCESS or errorIndication
prepareResponseMessage(
IN messageProcessingModel -- specified by application
IN securityModel -- specified by application
IN securityName -- specified by application
IN securityLevel -- specified by application
IN contextEngineID -- specified by application
IN contextName -- specified by application
IN pduVersion -- specified by application
IN PDU -- specified by application
IN maxSizeResponseScopedPDU -- specified by application
IN stateReference -- specified by application
IN statusInformation -- specified by application
OUT destTransportDomain -- destination transport domain
OUT destTransportAddress -- destination transport address
OUT outgoingMessage -- the message to send
OUT outgoingMessageLength -- the message length
)
3) If the result is an errorIndication, the errorIndication is
returned to the calling application. No further processing is performed.
4) If the result is success, the outgoingMessage is sent. The
transport used to send the outgoingMessage is returned via destTransportDomain, and the address to which it was sent is returned via destTransportAddress.
Message Processing is complete.
Receiving an SNMP Message from the Network
This section describes the procedure followed by an SNMP engine whenever it receives an SNMP message.
Please note, that for the sake of clarity and to prevent the text from being even longer and more complicated, some details were omitted from the steps below. In particular, the elements of procedure do not always explicitly indicate when state information needs to be released. The general rule is that if state information is available when a message is to be "discarded without further processing", then the state information must also be released at that same time.
Message Dispatching of received SNMP Messages
1) The snmpInPkts counter RFC3418 is incremented.
2) The version of the SNMP message is determined in an
implementation-dependent manner. If the packet cannot be sufficiently parsed to determine the version of the SNMP message, then the snmpInASNParseErrs RFC3418 counter is incremented, and the message is discarded without further processing. If the version is not supported, then the snmpInBadVersions RFC3418 counter is incremented, and the message is discarded without further processing.
3) The origin transportDomain and origin transportAddress are
determined.
4) The message is passed to the version-specific Message Processing
Model which returns the abstract data elements required by the Dispatcher. This is performed using the abstract service primitive:
result = -- SUCCESS or errorIndication
prepareDataElements(
IN transportDomain -- origin as determined in step 3.
IN transportAddress -- origin as determined in step 3.
IN wholeMsg -- as received from the network
IN wholeMsgLength -- as received from the network
OUT messageProcessingModel -- typically, SNMP version
OUT securityModel -- Security Model specified
OUT securityName -- on behalf of this principal
OUT securityLevel -- Level of Security specified
OUT contextEngineID -- data from/at this entity
OUT contextName -- data from/in this context
OUT pduVersion -- the version of the PDU
OUT PDU -- SNMP Protocol Data Unit
OUT pduType -- SNMP PDU type
OUT sendPduHandle -- handle for a matched request
OUT maxSizeResponseScopedPDU -- maximum size of Response PDU
OUT statusInformation -- success or errorIndication
-- (error counter OID and value
-- when errorIndication)
OUT stateReference -- reference to state information
-- to be used for a possible
) -- Response
5) If the result is a FAILURE errorIndication, the message is
discarded without further processing.
6) At this point, the abstract data elements have been prepared and
processing continues as described in Section 4.2.2, PDU Dispatching for Incoming Messages.
PDU Dispatching for Incoming Messages
The elements of procedure for the dispatching of PDUs depends on the value of sendPduHandle. If the value of sendPduHandle is <none>, then this is a request or notification and the procedures specified in Section 4.2.2.1 apply. If the value of snmpPduHandle is not <none>, then this is a response and the procedures specified in Section 4.2.2.2 apply.
Incoming Requests and Notifications
The following procedures are followed for the dispatching of PDUs when the value of sendPduHandle is <none>, indicating this is a request or notification.
1) The combination of contextEngineID and pduType is used to
determine which application has registered for this request or notification.
2) If no application has registered for the combination, then:
a) The snmpUnknownPDUHandlers counter is incremented.
b) A Response message is generated using the abstract service
primitive:
result = -- SUCCESS or FAILURE
prepareResponseMessage(
IN messageProcessingModel -- as provided by MP module
IN securityModel -- as provided by MP module
IN securityName -- as provided by MP module
IN securityLevel -- as provided by MP module
IN contextEngineID -- as provided by MP module
IN contextName -- as provided by MP module
IN pduVersion -- as provided by MP module
IN PDU -- as provided by MP module
IN maxSizeResponseScopedPDU -- as provided by MP module
IN stateReference -- as provided by MP module
IN statusInformation -- errorIndication plus
-- snmpUnknownPDUHandlers OID
-- value pair.
OUT destTransportDomain -- destination transportDomain
OUT destTransportAddress -- destination transportAddress
OUT outgoingMessage -- the message to send
OUT outgoingMessageLength -- its length
)
c) If the result is SUCCESS, then the prepared message is sent to
the originator of the request as identified by the
transportDomain and transportAddress. The transport used to
send the outgoingMessage is returned via destTransportDomain,
and the address to which it was sent is returned via
destTransportAddress.
d) The incoming message is discarded without further processing.
Message Processing for this message is complete.
3) The PDU is dispatched to the application, using the abstract
service primitive:
processPdu( -- process Request/Notification
IN messageProcessingModel -- as provided by MP module
IN securityModel -- as provided by MP module
IN securityName -- as provided by MP module
IN securityLevel -- as provided by MP module
IN contextEngineID -- as provided by MP module
IN contextName -- as provided by MP module
IN pduVersion -- as provided by MP module
IN PDU -- as provided by MP module
IN maxSizeResponseScopedPDU -- as provided by MP module
IN stateReference -- as provided by MP module
-- needed when sending response
)
Message processing for this message is complete.
Incoming Responses
The following procedures are followed for the dispatching of PDUs when the value of sendPduHandle is not <none>, indicating this is a response.
1) The value of sendPduHandle is used to determine, in an
implementation-defined manner, which application is waiting for a response associated with this sendPduHandle.
2) If no waiting application is found, the message is discarded
without further processing, and the stateReference is released. The snmpUnknownPDUHandlers counter is incremented. Message Processing is complete for this message.
3) Any cached information, including stateReference, about the
message is discarded.
4) The response is dispatched to the application using the abstract
service primitive:
processResponsePdu( -- process Response PDU
IN messageProcessingModel -- provided by the MP module
IN securityModel -- provided by the MP module
IN securityName -- provided by the MP module
IN securityLevel -- provided by the MP module
IN contextEngineID -- provided by the MP module
IN contextName -- provided by the MP module
IN pduVersion -- provided by the MP module
IN PDU -- provided by the MP module
IN statusInformation -- provided by the MP module
IN sendPduHandle -- provided by the MP module
)
Message Processing is complete for this message.
Application Registration for Handling PDU types
Applications that want to process certain PDUs must register with the PDU Dispatcher. Applications specify the combination of contextEngineID and pduType(s) for which they want to take responsibility.
1) An application registers according to the abstract interface
primitive:
statusInformation = -- success or errorIndication
registerContextEngineID(
IN contextEngineID -- take responsibility for this one
IN pduType -- the pduType(s) to be registered
)
Note: Implementations may provide a means of requesting registration for simultaneous multiple contextEngineID values, e.g., all contextEngineID values, and may also provide a means for requesting simultaneous registration for multiple values of the pduType.
2) The parameters may be checked for validity; if they are not, then
an errorIndication (invalidParameter) is returned to the application.
3) Each combination of contextEngineID and pduType can be registered
only once. If another application has already registered for the specified combination, then an errorIndication (alreadyRegistered) is returned to the application.
4) Otherwise, the registration is saved so that SNMP PDUs can be
dispatched to this application.
Application Unregistration for Handling PDU Types
Applications that no longer want to process certain PDUs must unregister with the PDU Dispatcher.
1) An application unregisters using the abstract service primitive:
unregisterContextEngineID(
IN contextEngineID -- give up responsibility for this
IN pduType -- the pduType(s) to be unregistered
)
Note: Implementations may provide a means for requesting the unregistration for simultaneous multiple contextEngineID values, e.g., all contextEngineID values, and may also provide a means for requesting simultaneous unregistration for multiple values of pduType.
2) If the contextEngineID and pduType combination has been
registered, then the registration is deleted.
If no such registration exists, then the request is ignored.
Definitions
Definitions for SNMP Message Processing and Dispatching
SNMP-MPD-MIB DEFINITIONS ::= BEGIN
IMPORTS
MODULE-COMPLIANCE, OBJECT-GROUP FROM SNMPv2-CONF MODULE-IDENTITY, OBJECT-TYPE, snmpModules, Counter32 FROM SNMPv2-SMI;
snmpMPDMIB MODULE-IDENTITY
LAST-UPDATED "200210140000Z" ORGANIZATION "SNMPv3 Working Group" CONTACT-INFO "WG-EMail: [email protected] Subscribe: [email protected]
Co-Chair: Russ Mundy
Network Associates Laboratories
postal: 15204 Omega Drive, Suite 300
Rockville, MD 20850-4601
USA
EMail: [email protected] phone: +1 301-947-7107
Co-Chair &
Co-editor: David Harrington
Enterasys Networks
postal: 35 Industrial Way
P. O. Box 5005
Rochester NH 03866-5005
USA
EMail: [email protected]
phone: +1 603-337-2614
Co-editor: Jeffrey Case
SNMP Research, Inc.
postal: 3001 Kimberlin Heights Road
Knoxville, TN 37920-9716
USA
EMail: [email protected]
phone: +1 423-573-1434
Co-editor: Randy Presuhn
BMC Software, Inc.
postal: 2141 North First Street
San Jose, CA 95131
USA
EMail: [email protected]
phone: +1 408-546-1006
Co-editor: Bert Wijnen
Lucent Technologies
postal: Schagen 33
3461 GL Linschoten
Netherlands
EMail: [email protected]
phone: +31 348-680-485
"
DESCRIPTION "The MIB for Message Processing and Dispatching
Copyright (C) The Internet Society (2002). This
version of this MIB module is part of RFC 3412;
see the RFC itself for full legal notices.
"
REVISION "200210140000Z" -- 14 October 2002
DESCRIPTION "Updated addresses, published as RFC 3412."
REVISION "199905041636Z" -- 4 May 1999
DESCRIPTION "Updated addresses, published as RFC 2572."
REVISION "199709300000Z" -- 30 September 1997 DESCRIPTION "Original version, published as RFC 2272." ::= { snmpModules 11 }
-- Administrative assignments ***************************************
snmpMPDAdmin OBJECT IDENTIFIER ::= { snmpMPDMIB 1 } snmpMPDMIBObjects OBJECT IDENTIFIER ::= { snmpMPDMIB 2 } snmpMPDMIBConformance OBJECT IDENTIFIER ::= { snmpMPDMIB 3 }
-- Statistics for SNMP Messages *************************************
snmpMPDStats OBJECT IDENTIFIER ::= { snmpMPDMIBObjects 1 }
snmpUnknownSecurityModels OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION "The total number of packets received by the SNMP
engine which were dropped because they referenced a
securityModel that was not known to or supported by
the SNMP engine.
"
::= { snmpMPDStats 1 }
snmpInvalidMsgs OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION "The total number of packets received by the SNMP
engine which were dropped because there were invalid
or inconsistent components in the SNMP message.
"
::= { snmpMPDStats 2 }
snmpUnknownPDUHandlers OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION "The total number of packets received by the SNMP
engine which were dropped because the PDU contained
in the packet could not be passed to an application
responsible for handling the pduType, e.g. no SNMP
application had registered for the proper
combination of the contextEngineID and the pduType.
"
::= { snmpMPDStats 3 }
-- Conformance information ******************************************
snmpMPDMIBCompliances OBJECT IDENTIFIER ::= {snmpMPDMIBConformance 1} snmpMPDMIBGroups OBJECT IDENTIFIER ::= {snmpMPDMIBConformance 2}
-- Compliance statements
snmpMPDCompliance MODULE-COMPLIANCE
STATUS current
DESCRIPTION "The compliance statement for SNMP entities which
implement the SNMP-MPD-MIB.
"
MODULE -- this module
MANDATORY-GROUPS { snmpMPDGroup }
::= { snmpMPDMIBCompliances 1 }
snmpMPDGroup OBJECT-GROUP
OBJECTS {
snmpUnknownSecurityModels,
snmpInvalidMsgs,
snmpUnknownPDUHandlers
}
STATUS current
DESCRIPTION "A collection of objects providing for remote
monitoring of the SNMP Message Processing and
Dispatching process.
"
::= { snmpMPDMIBGroups 1 }
END
The SNMPv3 Message Format
This section defines the SNMPv3 message format and the corresponding SNMP version 3 Message Processing Model (v3MP).
SNMPv3MessageSyntax DEFINITIONS IMPLICIT TAGS ::= BEGIN
SNMPv3Message ::= SEQUENCE {
-- identify the layout of the SNMPv3Message
-- this element is in same position as in SNMPv1
-- and SNMPv2c, allowing recognition
-- the value 3 is used for snmpv3
msgVersion INTEGER ( 0 .. 2147483647 ),
-- administrative parameters
msgGlobalData HeaderData,
-- security model-specific parameters
-- format defined by Security Model
msgSecurityParameters OCTET STRING,
msgData ScopedPduData
}
HeaderData ::= SEQUENCE {
msgID INTEGER (0..2147483647),
msgMaxSize INTEGER (484..2147483647),
msgFlags OCTET STRING (SIZE(1)),
-- Please observe:
msgSecurityModel INTEGER (1..2147483647) }
ScopedPduData ::= CHOICE {
plaintext ScopedPDU,
encryptedPDU OCTET STRING -- encrypted scopedPDU value
}
ScopedPDU ::= SEQUENCE {
contextEngineID OCTET STRING,
contextName OCTET STRING,
data ANY -- e.g., PDUs as defined in RFC3416
}
END
msgVersion
The msgVersion field is set to snmpv3(3) and identifies the message as an SNMP version 3 Message.
msgID
The msgID is used between two SNMP entities to coordinate request messages and responses, and by the v3MP to coordinate the processing of the message by different subsystem models within the architecture.
Values for msgID SHOULD be generated in a manner that avoids re-use of any outstanding values. Doing so provides protection against some replay attacks. One possible implementation strategy would be to use the low-order bits of snmpEngineBoots RFC3411 as the high-order
portion of the msgID value and a monotonically increasing integer for the low-order portion of msgID.
Note that the request-id in a PDU may be used by SNMP applications to identify the PDU; the msgID is used by the engine to identify the message which carries a PDU. The engine needs to identify the message even if decryption of the PDU (and request-id) fails. No assumption should be made that the value of the msgID and the value of the request-id are equivalent.
The value of the msgID field for a response takes the value of the msgID field from the message to which it is a response. By use of the msgID value, an engine can distinguish the (potentially multiple) outstanding requests, and thereby correlate incoming responses with outstanding requests. In cases where an unreliable datagram service is used, the msgID also provides a simple means of identifying messages duplicated by the network. If a request is retransmitted, a new msgID value SHOULD be used for each retransmission.
msgMaxSize
The msgMaxSize field of the message conveys the maximum message size supported by the sender of the message, i.e., the maximum message size that the sender can accept when another SNMP engine sends an SNMP message (be it a response or any other message) to the sender of this message on the transport in use for this message.
When an SNMP message is being generated, the msgMaxSize is provided by the SNMP engine which generates the message. At the receiving SNMP engine, the msgMaxSize is used to determine the maximum message size the sender can accommodate.
msgFlags
The msgFlags field of the message contains several bit fields which control processing of the message.
The reportableFlag is a secondary aid in determining whether a Report PDU MUST be sent. It is only used in cases where the PDU portion of a message cannot be decoded, due to, for example, an incorrect encryption key. If the PDU can be decoded, the PDU type forms the basis for decisions on sending Report PDUs.
When the reportableFlag is used, if its value is one, a Report PDU MUST be returned to the sender under those conditions which can cause the generation of Report PDUs. Similarly, when the reportableFlag is used and its value is zero, then a Report PDU MUST NOT be sent. The reportableFlag MUST always be zero when the message contains a PDU
from the Unconfirmed Class, such as a Report PDU, a response-type PDU (such as a Response PDU), or an unacknowledged notification-type PDU (such as an SNMPv2-trap PDU). The reportableFlag MUST always be one for a PDU from the Confirmed Class, including request-type PDUs (such as a Get PDU) and acknowledged notification-type PDUs (such as an Inform PDU).
If the reportableFlag is set to one for a message containing a PDU from the Unconfirmed Class, such as a Report PDU, a response-type PDU (such as a Response PDU), or an unacknowledged notification-type PDU (such as an SNMPv2-trap PDU), then the receiver of that message MUST process it as though the reportableFlag had been set to zero.
If the reportableFlag is set to zero for a message containing a request-type PDU (such as a Get PDU) or an acknowledged notification-type PDU (such as an Inform PDU), then the receiver of that message MUST process it as though the reportableFlag had been set to one.
Report PDUs are generated directly by the SNMPv3 Message Processing Model, and support engine-to-engine communications, but may be passed to applications for processing.
An SNMP engine that receives a reportPDU may use it to determine what kind of problem was detected by the remote SNMP engine. It can do so based on the error counter included as the first (and only) varBind of the reportPDU. Based on the detected error, the SNMP engine may try to send a corrected SNMP message. If that is not possible, it may pass an indication of the error to the application on whose behalf the failed SNMP request was issued.
The authFlag and privFlag portions of the msgFlags field are set by the sender to indicate the securityLevel that was applied to the message before it was sent on the wire. The receiver of the message MUST apply the same securityLevel when the message is received and the contents are being processed.
There are three securityLevels, namely noAuthNoPriv, which is less than authNoPriv, which is in turn less than authPriv. See the SNMP architecture document RFC3411 for details about the securityLevel.
a) authFlag
If the authFlag is set to one, then the securityModel used by the SNMP engine which sent the message MUST identify the securityName on whose behalf the SNMP message was generated and MUST provide, in a securityModel-specific manner, sufficient data for the receiver of the message to be able to authenticate that
identification. In general, this authentication will allow the receiver to determine with reasonable certainty that the message was:
- sent on behalf of the principal associated with the
securityName,
- was not redirected,
- was not modified in transit, and
- was not replayed.
If the authFlag is zero, then the securityModel used by the SNMP engine which sent the message MUST identify the securityName on whose behalf the SNMP message was generated but it does not need to provide sufficient data for the receiver of the message to authenticate the identification, as there is no need to authenticate the message in this case.
b) privFlag
If the privFlag is set, then the securityModel used by the SNMP engine which sent the message MUST also protect the scopedPDU in an SNMP message from disclosure, i.e., it MUST encrypt/decrypt the scopedPDU. If the privFlag is zero, then the securityModel in use does not need to protect the data from disclosure.
It is an explicit requirement of the SNMP architecture that if privacy is selected, then authentication is also required. That means that if the privFlag is set, then the authFlag MUST also be set to one.
The combination of the authFlag and the privFlag comprises a Level of Security as follows:
authFlag zero, privFlag zero -> securityLevel is noAuthNoPriv
authFlag zero, privFlag one -> invalid combination, see below
authFlag one, privFlag zero -> securityLevel is authNoPriv
authFlag one, privFlag one -> securityLevel is authPriv
The elements of procedure (see below) describe the action to be taken when the invalid combination of authFlag equal to zero and privFlag equal to one is encountered.
The remaining bits in msgFlags are reserved, and MUST be set to zero when sending a message and SHOULD be ignored when receiving a message.
msgSecurityModel
The v3MP supports the concurrent existence of multiple Security Models to provide security services for SNMPv3 messages. The msgSecurityModel field in an SNMPv3 Message identifies which Security Model was used by the sender to generate the message and therefore which securityModel MUST be used by the receiver to perform security processing for the message. The mapping to the appropriate securityModel implementation within an SNMP engine is accomplished in an implementation-dependent manner.
msgSecurityParameters
The msgSecurityParameters field of the SNMPv3 Message is used for communication between the Security Model modules in the sending and receiving SNMP engines. The data in the msgSecurityParameters field is used exclusively by the Security Model, and the contents and format of the data is defined by the Security Model. This OCTET STRING is not interpreted by the v3MP, but is passed to the local implementation of the Security Model indicated by the msgSecurityModel field in the message.
scopedPduData
The scopedPduData field represents either the plain text scopedPDU if the privFlag in the msgFlags is zero, or it represents an encryptedPDU (encoded as an OCTET STRING) which MUST be decrypted by the securityModel in use to produce a plaintext scopedPDU.
scopedPDU
The scopedPDU contains information to identify an administratively unique context and a PDU. The object identifiers in the PDU refer to managed objects which are (expected to be) accessible within the specified context.
contextEngineID
The contextEngineID in the SNMPv3 message uniquely identifies, within an administrative domain, an SNMP entity that may realize an instance of a context with a particular contextName.
For incoming messages, the contextEngineID is used in conjunction with the pduType to determine to which application the scopedPDU will be sent for processing.
For outgoing messages, the v3MP sets the contextEngineID to the value provided by the application in the request for a message to be sent.
contextName
The contextName field in an SNMPv3 message, in conjunction with the contextEngineID field, identifies the particular context associated with the management information contained in the PDU portion of the message. The contextName is unique within the SNMP entity specified by the contextEngineID, which may realize the managed objects referenced within the PDU. An application which originates a message provides the value for the contextName field and this value may be used during processing by an application at the receiving SNMP Engine.
data
The data field of the SNMPv3 Message contains the PDU. Among other things, the PDU contains the PDU type that is used by the v3MP to determine the type of the incoming SNMP message. The v3MP specifies that the PDU MUST be one of those specified in RFC3416.
Elements of Procedure for v3MP
This section describes the procedures followed by an SNMP engine when generating and processing SNMP messages according to the SNMPv3 Message Processing Model.
Please note, that for the sake of clarity and to prevent the text from being even longer and more complicated, some details were omitted from the steps below.
a) Some steps specify that when some error conditions are
encountered when processing a received message, a message
containing a Report PDU is generated and the received message
is discarded without further processing. However, a Report-PDU
MUST NOT be generated unless the PDU causing generation of the
Report PDU can be determined to be a member of the Confirmed
Class, or the reportableFlag is set to one and the PDU class
cannot be determined.
b) The elements of procedure do not always explicitly indicate
when state information needs to be released. The general rule
is that if state information is available when a message is to
be "discarded without further processing", then the state
information should also be released at that same time.
Prepare an Outgoing SNMP Message
This section describes the procedure followed to prepare an SNMPv3 message from the data elements passed by the Message Dispatcher.
1) The Message Dispatcher may request that an SNMPv3 message
containing a Read Class, Write Class, or Notification Class PDU be prepared for sending.
a) It makes such a request according to the abstract service
primitive:
statusInformation = -- success or errorIndication
prepareOutgoingMessage(
IN transportDomain -- requested transport domain
IN transportAddress -- requested destination 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 -- version of the PDU *
IN PDU -- SNMP Protocol Data Unit
IN expectResponse -- TRUE or FALSE *
IN sendPduHandle -- the handle for matching
-- incoming responses
OUT destTransportDomain -- destination transport domain
OUT destTransportAddress -- destination transport address
OUT outgoingMessage -- the message to send
OUT outgoingMessageLength -- the length of the message
)
* The SNMPv3 Message Processing Model does not use the values of
expectResponse or pduVersion.
b) A unique msgID is generated. The number used for msgID should
not have been used recently, and MUST NOT be the same as was
used for any outstanding request.
2) The Message Dispatcher may request that an SNMPv3 message
containing a Response Class or Internal Class PDU be prepared for sending.
a) It makes such a request according to the abstract service
primitive:
result = -- SUCCESS or FAILURE
prepareResponseMessage(
IN messageProcessingModel -- typically, SNMP version
IN securityModel -- same as on incoming request
IN securityName -- same as on incoming request
IN securityLevel -- same as on incoming request
IN contextEngineID -- data from/at this SNMP entity
IN contextName -- data from/in this context
IN pduVersion -- version of the PDU
IN PDU -- SNMP Protocol Data Unit
IN maxSizeResponseScopedPDU -- maximum size sender can
-- accept
IN stateReference -- reference to state
-- information presented with
-- the request
IN statusInformation -- success or errorIndication
-- error counter OID and value
-- when errorIndication
OUT destTransportDomain -- destination transport domain
OUT destTransportAddress -- destination transport address
OUT outgoingMessage -- the message to send
OUT outgoingMessageLength -- the length of the message
)
b) The cached information for the original request is retrieved
via the stateReference, including:
- msgID,
- contextEngineID,
- contextName,
- securityModel,
- securityName,
- securityLevel,
- securityStateReference,
- reportableFlag,
- transportDomain, and
- transportAddress.
The SNMPv3 Message Processing Model does not allow cached data
to be overridden, except by error indications as detailed in
(3) below.
3) If statusInformation contains values for an OID/value combination
(potentially also containing a securityLevel value, contextEngineID value, or contextName value), then:
a) If a PDU is provided, it is the PDU from the original request.
If possible, extract the request-id and pduType.
b) If the pduType is determined to not be a member of the
Confirmed Class, or if the reportableFlag is zero and the
pduType cannot be determined, then the original message is
discarded, and no further processing is done. A result of
FAILURE is returned. SNMPv3 Message Processing is complete.
c) A Report PDU is prepared:
1) the varBindList is set to contain the OID and value from the
statusInformation.
2) error-status is set to 0.
3) error-index is set to 0.
4) request-id is set to the value extracted in step b).
Otherwise, request-id is set to 0.
d) The errorIndication in statusInformation may be accompanied by
a securityLevel value, a contextEngineID value, or a
contextName value.
1) If statusInformation contains a value for securityLevel,
then securityLevel is set to that value, otherwise it is set
to noAuthNoPriv.
2) If statusInformation contains a value for contextEngineID,
then contextEngineID is set to that value, otherwise it is
set to the value of this entity's snmpEngineID.
3) If statusInformation contains a value for contextName, then
contextName is set to that value, otherwise it is set to the
default context of "" (zero-length string).
e) PDU is set to refer to the new Report-PDU. The old PDU is
discarded.
f) Processing continues with step 6) below.
4) If the contextEngineID is not yet determined, then the
contextEngineID is determined, in an implementation-dependent manner, possibly using the transportDomain and transportAddress.
5) If the contextName is not yet determined, the contextName is set
to the default context.
6) A scopedPDU is prepared from the contextEngineID, contextName, and
PDU.
7) msgGlobalData is constructed as follows:
a) The msgVersion field is set to snmpv3(3).
b) msgID is set as determined in step 1 or 2 above.
c) msgMaxSize is set to an implementation-dependent value.
d) msgFlags are set as follows:
- If securityLevel specifies noAuthNoPriv, then authFlag and
privFlag are both set to zero.
- If securityLevel specifies authNoPriv, then authFlag is set
to one and privFlag is set to zero.
- If securityLevel specifies authPriv, then authFlag is set to
one and privFlag is set to one.
- If the PDU is from the Unconfirmed Class, then the
reportableFlag is set to zero.
- If the PDU is from the Confirmed Class then the
reportableFlag is set to one.
- All other msgFlags bits are set to zero.
e) msgSecurityModel is set to the value of securityModel.
8) If the PDU is from the Response Class or the Internal Class, then:
a) The specified Security Model is called to generate the message
according to the primitive:
statusInformation =
generateResponseMsg(
IN messageProcessingModel -- SNMPv3 Message Processing
-- Model
IN globalData -- msgGlobalData from step 7
IN maxMessageSize -- from msgMaxSize (step 7c)
IN securityModel -- as determined in step 7e
IN securityEngineID -- the value of snmpEngineID
IN securityName -- on behalf of this principal
IN securityLevel -- for the outgoing message
IN scopedPDU -- as prepared in step 6)
IN securityStateReference -- as determined in step 2
OUT securityParameters -- filled in by Security Module
OUT wholeMsg -- complete generated message
OUT wholeMsgLength -- length of generated message
)
If, upon return from the Security Model, the statusInformation
includes an errorIndication, then any cached information about
the outstanding request message is discarded, and an
errorIndication is returned, so it can be returned to the
calling application. SNMPv3 Message Processing is complete.
b) A SUCCESS result is returned. SNMPv3 Message Processing is
complete.
9) If the PDU is from the Confirmed Class or the Notification Class,
then:
a) If the PDU is from the Unconfirmed Class, then securityEngineID
is set to the value of this entity's snmpEngineID.
Otherwise, the snmpEngineID of the target entity is determined,
in an implementation-dependent manner, possibly using
transportDomain and transportAddress. The value of the
securityEngineID is set to the value of the target entity's
snmpEngineID.
b) The specified Security Model is called to generate the message
according to the primitive:
statusInformation =
generateRequestMsg(
IN messageProcessingModel -- SNMPv3 Message Processing Model
IN globalData -- msgGlobalData, from step 7
IN maxMessageSize -- from msgMaxSize in step 7 c)
IN securityModel -- as provided by caller
IN securityEngineID -- authoritative SNMP entity
-- from step 9 a)
IN securityName -- as provided by caller
IN securityLevel -- as provided by caller
IN scopedPDU -- as prepared in step 6
OUT securityParameters -- filled in by Security Module
OUT wholeMsg -- complete generated message
OUT wholeMsgLength -- length of the generated message
)
If, upon return from the Security Model, the statusInformation
includes an errorIndication, then the message is discarded, and
the errorIndication is returned, so it can be returned to the
calling application, and no further processing is done. SNMPv3
Message Processing is complete.
c) If the PDU is from the Confirmed Class, information about the
outgoing message is cached, and an implementation-specific
stateReference is created. Information to be cached includes
the values of:
- sendPduHandle
- msgID
- snmpEngineID
- securityModel
- securityName
- securityLevel
- contextEngineID
- contextName
d) A SUCCESS result is returned. SNMPv3 Message Processing is
complete.
Prepare Data Elements from an Incoming SNMP Message
This section describes the procedure followed to extract data from an SNMPv3 message, and to prepare the data elements required for further processing of the message by the Message Dispatcher.
1) The message is passed in from the Message Dispatcher according to
the abstract service primitive:
result = -- SUCCESS or errorIndication
prepareDataElements(
IN transportDomain -- origin transport domain
IN transportAddress -- origin transport address
IN wholeMsg -- as received from the network
IN wholeMsgLength -- as received from the network
OUT messageProcessingModel -- typically, SNMP version
OUT securityModel -- Security Model to use
OUT securityName -- on behalf of this principal
OUT securityLevel -- Level of Security requested
OUT contextEngineID -- data from/at this entity
OUT contextName -- data from/in this context
OUT pduVersion -- version of the PDU
OUT PDU -- SNMP Protocol Data Unit
OUT pduType -- SNMP PDU type
OUT sendPduHandle -- handle for matched request
OUT maxSizeResponseScopedPDU -- maximum size sender can accept
OUT statusInformation -- success or errorIndication
-- error counter OID and value
-- when errorIndication
OUT stateReference -- reference to state information
-- to be used for a possible
) -- Response
2) If the received message is not the serialization (according to
the conventions of RFC3417) of an SNMPv3Message value, then the snmpInASNParseErrs counter RFC3418 is incremented, the message is discarded without further processing, and a FAILURE result is returned. SNMPv3 Message Processing is complete.
3) The values for msgVersion, msgID, msgMaxSize, msgFlags,
msgSecurityModel, msgSecurityParameters, and msgData are extracted from the message.
4) If the value of the msgSecurityModel component does not match a
supported securityModel, then the snmpUnknownSecurityModels counter is incremented, the message is discarded without further processing, and a FAILURE result is returned. SNMPv3 Message Processing is complete.
5) The securityLevel is determined from the authFlag and the
privFlag bits of the msgFlags component as follows:
a) If the authFlag is not set and the privFlag is not set, then
securityLevel is set to noAuthNoPriv.
b) If the authFlag is set and the privFlag is not set, then
securityLevel is set to authNoPriv.
c) If the authFlag is set and the privFlag is set, then
securityLevel is set to authPriv.
d) If the authFlag is not set and privFlag is set, then the
snmpInvalidMsgs counter is incremented, the message is
discarded without further processing, and a FAILURE result is
returned. SNMPv3 Message Processing is complete.
e) Any other bits in the msgFlags are ignored.
6) The security module implementing the Security Model as specified
by the securityModel component is called for authentication and privacy services. This is done according to the abstract service primitive:
statusInformation = -- errorIndication or success
-- error counter OID and
-- value if error
processIncomingMsg(
IN messageProcessingModel -- SNMPv3 Message Processing Model
IN maxMessageSize -- of the sending SNMP entity
IN securityParameters -- for the received message
IN securityModel -- for the received message
IN securityLevel -- Level of Security
IN wholeMsg -- as received on the wire
IN wholeMsgLength -- length as received on the wire
OUT securityEngineID -- authoritative SNMP entity
OUT securityName -- identification of the principal
OUT scopedPDU, -- message (plaintext) payload
OUT maxSizeResponseScopedPDU -- maximum size sender can accept
OUT securityStateReference -- reference to security state
) -- information, needed for
-- response
If an errorIndication is returned by the security module, then:
a) If statusInformation contains values for an OID/value pair,
then generation of a Report PDU is attempted (see step 3 in
section 7.1).
1) If the scopedPDU has been returned from processIncomingMsg,
then determine contextEngineID, contextName, and PDU.
2) Information about the message is cached and a
stateReference is created (implementation-specific).
Information to be cached includes the values of:
msgVersion,
msgID,
securityLevel,
msgFlags,
msgMaxSize,
securityModel,
maxSizeResponseScopedPDU,
securityStateReference
3) Request that a Report-PDU be prepared and sent, according
to the abstract service primitive:
result = -- SUCCESS or FAILURE
returnResponsePdu(
IN messageProcessingModel -- SNMPv3(3)
IN securityModel -- same as on incoming request
IN securityName -- from processIncomingMsg
IN securityLevel -- same as on incoming request
IN contextEngineID -- from step 6 a) 1)
IN contextName -- from step 6 a) 1)
IN pduVersion -- SNMPv2-PDU
IN PDU -- from step 6 a) 1)
IN maxSizeResponseScopedPDU -- from processIncomingMsg
IN stateReference -- from step 6 a) 2)
IN statusInformation -- from processIncomingMsg
)
b) The incoming message is discarded without further processing,
and a FAILURE result is returned. SNMPv3 Message Processing
is complete.
7) The scopedPDU is parsed to extract the contextEngineID, the
contextName and the PDU. If any parse error occurs, then the snmpInASNParseErrs counter RFC3418 is incremented, the security state information is discarded, the message is discarded without further processing, and a FAILURE result is returned. SNMPv3 Message Processing is complete. Treating an unknown PDU type is treated as a parse error is an implementation option.
8) The pduVersion is determined in an implementation-dependent
manner. For SNMPv3, the pduVersion would be an SNMPv2-PDU.
9) The pduType is determined, in an implementation-dependent manner.
For RFC3416, the pduTypes include:
- GetRequest-PDU,
- GetNextRequest-PDU,
- GetBulkRequest-PDU,
- SetRequest-PDU,
- InformRequest-PDU,
- SNMPv2-Trap-PDU,
- Response-PDU,
- Report-PDU.
10) If the pduType is from the Response Class or the Internal Class,
then:
a) The value of the msgID component is used to find the cached
information for a corresponding outstanding Request message.
If no such outstanding Request message is found, then the
security state information is discarded, the message is
discarded without further processing, and a FAILURE result is
returned. SNMPv3 Message Processing is complete.
b) sendPduHandle is retrieved from the cached information.
Otherwise, sendPduHandle is set to <none>, an implementation defined value.
11) If the pduType is from the Internal Class, then:
a) statusInformation is created using the contents of the
Report-PDU, in an implementation-dependent manner. This
statusInformation will be forwarded to the application
associated with the sendPduHandle.
b) The cached data for the outstanding message, referred to by
stateReference, is retrieved. If the securityModel or
securityLevel values differ from the cached ones, it is
important to recognize that Internal Class PDUs delivered at
the security level of noAuthNoPriv open a window of
opportunity for spoofing or replay attacks. If the receiver
of such messages is aware of these risks, the use of such
unauthenticated messages is acceptable and may provide a
useful function for discovering engine IDs or for detecting
misconfiguration at remote nodes.
When the securityModel or securityLevel values differ from the
cached ones, an implementation may retain the cached
information about the outstanding Request message, in
anticipation of the possibility that the Internal Class PDU
received might be illegitimate. Otherwise, any cached
information about the outstanding Request message is
discarded.
c) The security state information for this incoming message is
discarded.
d) stateReference is set to <none>.
e) A SUCCESS result is returned. SNMPv3 Message Processing is
complete.
12) If the pduType is from the Response Class, then:
a) The cached data for the outstanding request, referred to by
stateReference, is retrieved, including:
- snmpEngineID
- securityModel
- securityName
- securityLevel
- contextEngineID
- contextName
b) If the values extracted from the incoming message differ from
the cached data, then any cached information about the
outstanding Request message is discarded, the incoming message
is discarded without further processing, and a FAILURE result
is returned. SNMPv3 Message Processing is complete.
When the securityModel or securityLevel values differ from the
cached ones, an implementation may retain the cached
information about the outstanding Request message, in
anticipation of the possibility that the Response Class PDU
received might be illegitimate.
c) Otherwise, any cached information about the outstanding
Request message is discarded, and the stateReference is set to
<none>.
d) A SUCCESS result is returned. SNMPv3 Message Processing is
complete.
13) If the pduType is from the Confirmed Class, then:
a) If the value of securityEngineID is not equal to the value of
snmpEngineID, then the security state information is
discarded, any cached information about this message is
discarded, the incoming message is discarded without further
processing, and a FAILURE result is returned. SNMPv3 Message
Processing is complete.
b) Information about the message is cached and a stateReference
is created (implementation-specific). Information to be
cached includes the values of:
msgVersion,
msgID,
securityLevel,
msgFlags,
msgMaxSize,
securityModel,
maxSizeResponseScopedPDU,
securityStateReference
c) A SUCCESS result is returned. SNMPv3 Message Processing is
complete.
14) If the pduType is from the Unconfirmed Class, then a SUCCESS
result is returned. SNMPv3 Message Processing is complete.
Intellectual Property
The IETF takes no position regarding the validity or scope of any intellectual property or other rights that might be claimed to pertain to the implementation or use of the technology described in this document or the extent to which any license under such rights might or might not be available; neither does it represent that it has made any effort to identify any such rights. Information on the IETF's procedures with respect to rights in standards-track and standards-related documentation can be found in BCP-11. Copies of claims of rights made available for publication and any assurances of licenses to be made available, or the result of an attempt made to obtain a general license or permission for the use of such proprietary rights by implementors or users of this specification can be obtained from the IETF Secretariat.
The IETF invites any interested party to bring to its attention any copyrights, patents or patent applications, or other proprietary rights which may cover technology that may be required to practice this standard. Please address the information to the IETF Executive Director.
Acknowledgements
This document is the result of the efforts of the SNMPv3 Working Group. Some special thanks are in order to the following SNMPv3 WG members:
Harald Tveit Alvestrand (Maxware) Dave Battle (SNMP Research, Inc.) Alan Beard (Disney Worldwide Services) Paul Berrevoets (SWI Systemware/Halcyon Inc.) Martin Bjorklund (Ericsson) Uri Blumenthal (IBM T. J. Watson Research Center) Jeff Case (SNMP Research, Inc.) John Curran (BBN) Mike Daniele (Compaq Computer Corporation) T. Max Devlin (Eltrax Systems) John Flick (Hewlett Packard) Rob Frye (MCI) Wes Hardaker (U.C.Davis, Information Technology - D.C.A.S.) David Harrington (Cabletron Systems Inc.) Lauren Heintz (BMC Software, Inc.) N.C. Hien (IBM T. J. Watson Research Center) Michael Kirkham (InterWorking Labs, Inc.) Dave Levi (SNMP Research, Inc.) Louis A Mamakos (UUNET Technologies Inc.) Joe Marzot (Nortel Networks) Paul Meyer (Secure Computing Corporation) Keith McCloghrie (Cisco Systems) Bob Moore (IBM) Russ Mundy (TIS Labs at Network Associates) Bob Natale (ACE*COMM Corporation) Mike O'Dell (UUNET Technologies Inc.) Dave Perkins (DeskTalk) Peter Polkinghorne (Brunel University) Randy Presuhn (BMC Software, Inc.) David Reeder (TIS Labs at Network Associates) David Reid (SNMP Research, Inc.) Aleksey Romanov (Quality Quorum) Shawn Routhier (Epilogue) Juergen Schoenwaelder (TU Braunschweig) Bob Stewart (Cisco Systems) Mike Thatcher (Independent Consultant) Bert Wijnen (IBM T. J. Watson Research Center)
The document is based on recommendations of the IETF Security and Administrative Framework Evolution for SNMP Advisory Team. Members of that Advisory Team were:
David Harrington (Cabletron Systems Inc.) Jeff Johnson (Cisco Systems) David Levi (SNMP Research Inc.) John Linn (Openvision) Russ Mundy (Trusted Information Systems) chair Shawn Routhier (Epilogue) Glenn Waters (Nortel) Bert Wijnen (IBM T. J. Watson Research Center)
As recommended by the Advisory Team and the SNMPv3 Working Group Charter, the design incorporates as much as practical from previous RFCs and drafts. As a result, special thanks are due to the authors of previous designs known as SNMPv2u and SNMPv2*:
Jeff Case (SNMP Research, Inc.) David Harrington (Cabletron Systems Inc.) David Levi (SNMP Research, Inc.) Keith McCloghrie (Cisco Systems) Brian O'Keefe (Hewlett Packard) Marshall T. Rose (Dover Beach Consulting) Jon Saperia (BGS Systems Inc.) Steve Waldbusser (International Network Services) Glenn W. Waters (Bell-Northern Research Ltd.)
10. Security Considerations
The Dispatcher coordinates the processing of messages to provide a level of security for management messages and to direct the SNMP PDUs to the proper SNMP application(s).
A Message Processing Model, and in particular the v3MP defined in this document, interacts as part of the Message Processing with Security Models in the Security Subsystem via the abstract service interface primitives defined in RFC3411 and elaborated above.
The level of security actually provided is primarily determined by the specific Security Model implementation(s) and the specific SNMP application implementation(s) incorporated into this framework. Applications have access to data which is not secured. Applications should take reasonable steps to protect the data from disclosure, and when they send data across the network, they should obey the securityLevel and call upon the services of an Access Control Model as they apply access control.
The values for the msgID element used in communication between SNMP entities MUST be chosen to avoid replay attacks. The values do not need to be unpredictable; it is sufficient that they not repeat.
When exchanges are carried out over an insecure network, there is an open opportunity for a third party to spoof or replay messages when any message of an exchange is given at the security level of noAuthNoPriv. For most exchanges, all messages exist at the same security level. In the case where the final message is an Internal Class PDU, this message may be delivered at a level of noAuthNoPriv or authNoPriv, independent of the security level of the preceding messages. Internal Class PDUs delivered at the level of authNoPriv are not considered to pose a security hazard. Internal Class PDUs delivered at the security level of noAuthNoPriv open a window of opportunity for spoofing or replay attacks. If the receiver of such messages is aware of these risks, the use of such unauthenticated messages is acceptable and may provide a useful function for discovering engine IDs or for detecting misconfiguration at remote nodes.
This document also contains a MIB definition module. None of the objects defined is writable, and the information they represent is not deemed to be particularly sensitive. However, if they are deemed sensitive in a particular environment, access to them should be restricted through the use of appropriately configured Security and Access Control models.
11. References
11.1. Normative References
RFC2119 Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
RFC2578 McCloghrie, K., Perkins, D., Schoenwaelder, J., Case, J.,
Rose, M. and S. Waldbusser, "Structure of Management
Information Version 2 (SMIv2)", STD 58, RFC 2578, April
1999.
RFC2580 McCloghrie, K., Perkins, D., Schoenwaelder, J., Case, J.,
Rose, M. and S. Waldbusser, "Conformance Statements for
SMIv2", STD 58, RFC 2580, April 1999.
RFC3411 Harrington, D., Presuhn, R. and B. Wijnen, "An
Architecture for Describing Simple Network Management
Protocol (SNMP) Management Frameworks", STD 62, RFC 3411,
December 2002.
RFC3413 Levi, D., Meyer, P. and B. Stewart, "Simple Network
Management Protocol (SNMP) Applications", STD 62, RFC 3413, December 2002.
RFC3414 Blumenthal, U. and B. Wijnen, "The User-Based Security
Model (USM) for Version 3 of the Simple Network
Management Protocol (SNMPv3)", STD 62, RFC 3414, December
2002.
RFC3415 Wijnen, B., Presuhn, R. and K. McCloghrie, "View-based
Access Control Model (VACM) for the Simple Network
Management Protocol (SNMP)", STD 62, RFC 3415, December
2002.
RFC3416 Presuhn, R., Case, J., McCloghrie, K., Rose, M. and S.
Waldbusser, "Version 2 of the Protocol Operations for the
Simple Network Management Protocol (SNMP)", STD 62, RFC
3416, December 2002.
RFC3417 Presuhn, R., Case, J., McCloghrie, K., Rose, M. and S.
Waldbusser, "Transport Mappings for the Simple Network
Management Protocol (SNMP)", STD 62, RFC 3417, December
2002.
RFC3418 Presuhn, R., Case, J., McCloghrie, K., Rose, M. and S.
Waldbusser, "Management Information Base (MIB) for the
Simple Network Management Protocol (SNMP)", STD 62, RFC
3418, December 2002.
11.2. Informative References
RFC1901 Case, J., McCloghrie, K., Rose, M. and S. Waldbusser,
"Introduction to Community-based SNMPv2", RFC 1901, January 1996.
RFC2028 Hovey, R. and S. Bradner, "The Organizations Involved in
the IETF Standards Process", BCP 11, RFC 2028, October 1996.
RFC2576 Frye, R., Levi, D., Routhier, S. and B. Wijnen,
"Coexistence between Version 1, Version 2, and Version 3
of the Internet-Standard Network Management Framework",
RFC 2576, March 2000.
RFC3410 Case, J., Mundy, R., Partain, D. and B. Stewart,
"Introduction and Applicability Statements for Internet-
Standard Management Framework", RFC 3410, December 2002.
12. Editors' Addresses
Jeffrey Case SNMP Research, Inc. 3001 Kimberlin Heights Road Knoxville, TN 37920-9716 USA
Phone: +1 423-573-1434 EMail: [email protected]
David Harrington Enterasys Networks 35 Industrial Way Post Office Box 5005 Rochester, NH 03866-5005 USA
Phone: +1 603-337-2614 EMail: [email protected]
Randy Presuhn BMC Software, Inc. 2141 North First Street San Jose, CA 95131 USA
Phone: +1 408-546-1006 EMail: [email protected]
Bert Wijnen Lucent Technologies Schagen 33 3461 GL Linschoten Netherlands
Phone: +31 348-680-485 EMail: [email protected]
13. Full Copyright Statement
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Acknowledgement
Funding for the RFC Editor function is currently provided by the Internet Society.
