RFC3413 - Simple Network Management Protocol (SNMP) Applications

Network Working Group D. Levi

Request for Comments: 3413 Nortel Networks

STD: 62 P. Meyer

Obsoletes: 2573 Secure Computing Corporation

Category: Standards Track B. Stewart

Retired

December 2002

Simple Network Management Protocol (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.

Abstract

This document describes five types of Simple Network Management

Protocol (SNMP) applications which make use of an SNMP engine as

described in STD 62, RFC3411. The types of application described

are Command Generators, Command Responders, Notification Originators,

Notification Receivers, and Proxy Forwarders.

This document also defines Management Information Base (MIB) modules

for specifying targets of management operations, for notification

filtering, and for proxy forwarding. This document obsoletes RFC

2573.

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

3.5 Proxy Forwarder Applications ........................... 19

3.5.1 Request Forwarding ..................................... 21

3.5.1.1 Processing an Incoming Request ......................... 21

3.5.1.2 Processing an Incoming Response ........................ 24

3.5.1.3 Processing an Incoming Internal-Class PDU .............. 25

3.5.2 Notification Forwarding ................................ 26

4 The StrUCture of the MIB Modules ....................... 29

4.1 The Management Target MIB Module ....................... 29

4.1.1 Tag Lists .....................,........................ 29

4.1.2 Definitions ..................,......................... 30

4.2 The Notification MIB Module ............................ 44

4.2.1 Definitions ............................................ 44

4.3 The Proxy MIB Module ................................... 56

4.3.1 Definitions ............................................ 57

5 Identification of Management Targets in

Notification Originators ............................... 63

6 Notification Filtering ................................. 64

7 Management Target Translation in

Proxy Forwarder Applications ........................... 65

7.1 Management Target Translation for

Request Forwarding ..................................... 65

7.2 Management Target Translation for

Notification Forwarding ................................ 66

8 Intellectual Property .................................. 67

9 Acknowledgments ........................................ 67

10 Security Considerations ................................ 69

11 References ............................................. 69

A. Trap Configuration Example ............................. 71

Editors' Addresses ..................................... 73

Full Copyright Statement ............................... 74

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.'

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, and processes responses to requests 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.

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 (3.5, 4.3, and 7) 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 [RFC3411], 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:

- 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.

- 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

[RFC3411].

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.

- 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 to be

generated.

- The securityLevel is the security level that the application wishes

to use.

- The contextEngineID specifies the location of the management

information it is requesting. Note that unless the request is

being sent to a proxy, this value will usually be equal to the

snmpEngineID value of the engine to which the request is being

sent.

- The contextName specifies 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

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 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.

- 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.

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.

- 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 the

error-index with the index of the failed variable binding, 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 for generation of a

report message.

- 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 for

generation of a report message.

(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

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 is 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

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 preceding

section, except that the viewType indicates a Notification-Class

operation. 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.

- 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 (4) 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 (5) 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,

and that steps a) through d) need not be repeated.

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.

- 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.

- 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.

(4) After this, processing depends on the particular implementation.

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-Class 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.

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.

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,

(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 may need to perform a

translation on the PDU. (A method for performing such a

translation is described in [RFC2576].)

(4) The proxy forwarder calls the Dispatcher to generate the

forwarded message, using the sendPdu abstract service interface.

The parameters are:

- The transportDomain is that of the outgoing management target.

- The transportAddress is that of the outgoing management target.

- The messageProcessingModel is that of the outgoing management

target.

- The securityModel is that of the outgoing management target.

- The securityName is that of the outgoing management target.

- The securityLevel is that of the outgoing management target.

- The contextEngineID is the value from the processPdu call.

- The contextName is the value from the processPdu call.

- 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 a response is

expected. If the sendPdu call is unsuccessful, the proxy

forwarder performs the steps described in (2) above.

Otherwise:

(5) The proxy forwarder caches the following information in order to

match an incoming response to the forwarded request:

- The sendPduHandle returned from the call to sendPdu,

- The request-id from the received PDU.

- The contextEngineID,

- The contextName,

- The stateReference,

- The incoming management target information,

- The outgoing management information,

- Any other information needed to match an incoming response to

the forwarded request.

If this information cannot be cached (possibly due to a lack of

resources), the proxy forwarder performs the steps described in

(2) above. Otherwise:

(6) Processing of the request stops until a response to the forwarded

request is received, or until an appropriate time interval has

expired. If this time interval expires before a response has

been received, the cached information about this request is

removed.

3.5.1.2. Processing an Incoming Response

A proxy forwarder follows the following procedure when an

incoming response is received:

(1) The incoming response is received using the processResponsePdu

interface. The proxy forwarder uses the received parameters to

locate an entry in its cache of pending forwarded requests. This

is done by matching the received parameters with the cached

values of sendPduHandle, contextEngineID, contextName, outgoing

management target information, and the request-id contained in

the received PDU (the proxy forwarder must extract the request-id

for this purpose). If an appropriate cache entry cannot be

found, processing of the response is halted. Otherwise:

(2) The cache information is extracted, and removed from the cache.

(3) A new Response-Class PDU is constructed, using the request-id

value from the original forwarded request (as extracted from the

cache). All other values are identical to those in the received

Response-Class PDU, unless the incoming SNMP version and the

outgoing SNMP version support different PDU versions, in which

case the proxy forwarder may need to perform a translation on the

PDU. (A method for performing such a translation is described in

[RFC2576].)

(4) The proxy forwarder calls the Dispatcher using the

returnResponsePdu abstract service interface. Parameters are:

- The messageProcessingModel indicates the Message Processing

Model by which the original incoming message was processed.

- The securityModel is that of the original incoming management

target extracted from the cache.

- The securityName is that of the original incoming management

target extracted from the cache.

- The securityLevel is that of the original incoming management

target extracted from the cache.

- The contextEngineID is the value extracted from the cache.

- The contextName is the value extracted from the cache.

- The pduVersion indicates the version of the PDU to be returned.

- The PDU is the (possibly translated) Response PDU.

- The maxSizeResponseScopedPDU is a local value indicating the

maximum size of a ScopedPDU that the application can accept.

- The stateReference is the value extracted from the cache.

- The statusInformation indicates that no error occurred and that

a Response PDU message should be generated.

3.5.1.3. Processing an Incoming Internal-Class PDU

A proxy forwarder follows the following procedure when an incoming

Internal-Class PDU is received:

(1) The incoming Internal-Class PDU is received using the

processResponsePdu interface. The proxy forwarder uses the

received parameters to locate an entry in its cache of pending

forwarded requests. This is done by matching the received

parameters with the cached values of sendPduHandle. If an

appropriate cache entry cannot be found, processing of the

Internal-Class PDU is halted. Otherwise:

(2) The cache information is extracted, and removed from the cache.

(3) If the original incoming management target information indicates

an SNMP version which does not support Report PDUs, processing of

the Internal-Class PDU is halted.

(4) The proxy forwarder calls the Dispatcher using the

returnResponsePdu abstract service interface. Parameters are:

- The messageProcessingModel indicates the Message Processing

Model by which the original incoming message was processed.

- The securityModel is that of the original incoming management

target extracted from the cache.

- The securityName is that of the original incoming management

target extracted from the cache.

- The securityLevel is that of the original incoming management

target extracted from the cache.

- The contextEngineID is the value extracted from the cache.

- The contextName is the value extracted from the cache.

- The pduVersion indicates the version of the PDU to be returned.

- The PDU is unused.

- The maxSizeResponseScopedPDU is a local value indicating the

maximum size of a ScopedPDU that the application can accept.

- The stateReference is the value extracted from the cache.

- The statusInformation contains values specific to the

Internal-Class PDU type (for example, for a Report PDU, the

statusInformation contains the contextEngineID, contextName,

counter OID, and counter value received in the incoming Report

PDU).

3.5.2. Notification Forwarding

A proxy forwarder receives notifications in the same manner as a

notification receiver application, using the processPdu abstract

service interface. The following procedure is used when a

notification is received:

(1) 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 may result in multiple management targets.

(2) If appropriate outgoing management target information cannot be

found and the notification was an Unconfirmed-Class PDU,

processing of the notification is halted. If appropriate

outgoing management target information cannot be found and the

notification was a Confirmed-Class PDU, the proxy forwarder

increments the snmpProxyDrops object, and calls the Dispatcher

using the returnResponsePdu abstract service interface. The

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 and unused 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 that

a Report message should be generated.

Processing of the message stops at this point. Otherwise,

(3) The proxy forwarder generates a notification using the procedures

described in the preceding section on Notification Originators,

with the following exceptions:

- The contextEngineID and contextName values from the original

received notification are used.

- The outgoing management targets previously determined are used.

- No filtering mechanisms are applied.

- The variable-bindings from the original received notification

are used, rather than retrieving variable-bindings from local

MIB instrumentation. In particular, no access-control is

applied to these variable-bindings, nor to the value of the

variable-binding containing snmpTrapOID.0.

- If the original notification contains a Confirmed-Class PDU,

then any outgoing management targets for which the outgoing

SNMP version does not support any PDU types that are both

Notification-Class and Confirmed-Class PDUs will not be used

when generating the forwarded notifications.

- If, for any of the outgoing management targets, the incoming

SNMP version and the outgoing SNMP version support different

PDU versions, the proxy forwarder may need to perform a

translation on the PDU. (A method for performing such a

translation is described in [RFC2576].)

(4) If the original received notification contains an

Unconfirmed-Class PDU, processing of the notification is now

completed. Otherwise, the original received notification must

contain Confirmed-Class PDU, and processing continues.

(5) If the forwarded notifications included any Confirmed-Class PDUs,

processing continues when the procedures described in the section

for Notification Originators determine that either:

- None of the generated notifications containing Confirmed-Class

PDUs have been successfully acknowledged within the longest of

the time intervals, in which case processing of the original

notification is halted, or,

- At least one of the generated notifications containing

Confirmed-Class PDUs is successfully acknowledged, in which

case a response to the original received notification

containing an Confirmed-Class PDU is generated as described in

the following steps.

(6) A Response-Class PDU is constructed, using the values of

request-id and variable-bindings from the original received

Notification-Class PDU, and error-status and error-index values

of 0.

(7) The Dispatcher is called 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 constructed in

step (6) above.

- The PDU is the value constructed in step (6) 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-Class PDU message should be generated.

4. The Structure of the MIB Modules

There are three separate MIB modules described in this document, the

management target MIB, the notification MIB, and the proxy MIB. The

following sections describe the structure of these three MIB modules.

The use of these MIBs by particular types of applications is

described later in this document:

- The use of the management target MIB and the notification MIB in

notification originator applications is described in section 5.

- The use of the notification MIB for filtering notifications in

notification originator applications is described in section 6.

- The use of the management target MIB and the proxy MIB in proxy

forwarding applications is described in section 7.

4.1. The Management Target MIB Module

The SNMP-TARGET-MIB module contains objects for defining management

targets. It consists of two tables and conformance/compliance

statements.

The first table, the snmpTargetAddrTable, contains information about

transport domains and addresses. It also contains an object,

snmpTargetAddrTagList, which provides a mechanism for grouping

entries.

The second table, the snmpTargetParamsTable, contains information

about SNMP version and security information to be used when sending

messages to particular transport domains and addresses.

The Management Target MIB is intended to provide a general-purpose

mechanism for specifying transport address, and for specifying

parameters of SNMP messages generated by an SNMP entity. It is used

within this document for generation of notifications and for proxy

forwarding. However, it may be used for other purposes. If another

document makes use of this MIB, that document is responsible for

specifying how it is used. For example, [RFC2576] uses this MIB for

source address validation of SNMPv1 messages.

4.1.1. Tag Lists

The snmpTargetAddrTagList object is used for grouping entries in the

snmpTargetAddrTable. The value of this object contains a list of tag

values which are used to select target addresses to be used for a

particular operation.

A tag value, which may also be used in MIB objects other than

snmpTargetAddrTagList, is an arbitrary string of octets, but may not

contain a delimiter character. Delimiter characters are defined to

be one of the following characters:

- An ASCII space character (0x20).

- An ASCII TAB character (0x09).

- An ASCII carriage return (CR) character (0x0D).

- An ASCII line feed (LF) character (0x0A).

In addition, a tag value within a tag list may not have a zero

length. Generally, a particular MIB object may contain either

- a zero-length octet string representing an empty list, or

- a single tag value, in which case the value of the MIB object may

not contain a delimiter character, or

- a list of tag values, separated by single delimiter characters.

For a list of tag values, these constraints imply certain

restrictions on the value of a MIB object:

- There cannot be a leading or trailing delimiter character.

- There cannot be multiple adjacent delimiter characters.

4.1.2. Definitions

SNMP-TARGET-MIB DEFINITIONS ::= BEGIN

IMPORTS

MODULE-IDENTITY,

OBJECT-TYPE,

snmpModules,

Counter32,

Integer32

FROM SNMPv2-SMI

TEXTUAL-CONVENTION,

TDomain,

TAddress,

TimeInterval,

RowStatus,

StorageType,

TestAndIncr

FROM SNMPv2-TC

SnmpSecurityModel,

SnmpMessageProcessingModel,

SnmpSecurityLevel,

SnmpAdminString

FROM SNMP-FRAMEWORK-MIB

MODULE-COMPLIANCE,

OBJECT-GROUP

FROM SNMPv2-CONF;

snmpTargetMIB MODULE-IDENTITY

LAST-UPDATED "200210140000Z"

ORGANIZATION "IETF SNMPv3 Working Group"

CONTACT-INFO

"WG-email: snmpv3@lists.tislabs.com

Subscribe: majordomo@lists.tislabs.com

In message body: subscribe snmpv3

Co-Chair: Russ Mundy

Network Associates Laboratories

Postal: 15204 Omega Drive, Suite 300

Rockville, MD 20850-4601

USA

EMail: mundy@tislabs.com

Phone: +1 301-947-7107

Co-Chair: David Harrington

Enterasys Networks

Postal: 35 Industrial Way

P. O. Box 5004

Rochester, New Hampshire 03866-5005

USA

EMail: dbh@enterasys.com

Phone: +1 603-337-2614

Co-editor: David B. Levi

Nortel Networks

Postal: 3505 Kesterwood Drive

Knoxville, Tennessee 37918

EMail: dlevi@nortelnetworks.com

Phone: +1 865 686 0432

Co-editor: Paul Meyer

Secure Computing Corporation

Postal: 2675 Long Lake Road

Roseville, Minnesota 55113

EMail: paul_meyer@securecomputing.com

Phone: +1 651 628 1592

Co-editor: Bob Stewart

Retired"

DESCRIPTION

"This MIB module defines MIB objects which provide

mechanisms to remotely configure the parameters used

by an SNMP entity for the generation of SNMP messages.

Copyright (C) The Internet Society (2002). This

version of this MIB module is part of RFC3413;

see the RFCitself for full legal notices.

"

REVISION "200210140000Z" -- 14 October 2002

DESCRIPTION "Fixed DISPLAY-HINTS for UTF-8 strings, fixed hex

value of LF characters, clarified meaning of zero

length tag values, improved tag list examples.

Published as RFC3413."

REVISION "199808040000Z" -- 4 August 1998

DESCRIPTION "Clarifications, published as

RFC2573."

REVISION "199707140000Z" -- 14 July 1997

DESCRIPTION "The initial revision, published as RFC2273."

::= { snmpModules 12 }

snmpTargetObjects OBJECT IDENTIFIER ::= { snmpTargetMIB 1 }

snmpTargetConformance OBJECT IDENTIFIER ::= { snmpTargetMIB 3 }

SnmpTagValue ::= TEXTUAL-CONVENTION

DISPLAY-HINT "255t"

STATUS current

DESCRIPTION

"An octet string containing a tag value.

Tag values are preferably in human-readable form.

To facilitate internationalization, this information

is represented using the ISO/IEC IS 10646-1 character

set, encoded as an octet string using the UTF-8

character encoding scheme described in RFC2279.

Since additional code points are added by amendments

to the 10646 standard from time to time,

implementations must be prepared to encounter any code

point from 0x00000000 to 0x7fffffff.

The use of control codes should be avoided, and certain

control codes are not allowed as described below.

For code points not directly supported by user

interface hardware or software, an alternative means

of entry and display, such as hexadecimal, may be

provided.

For information encoded in 7-bit US-ASCII, the UTF-8

representation is identical to the US-ASCII encoding.

Note that when this TC is used for an object that

is used or envisioned to be used as an index, then a

SIZE restriction must be specified so that the number

of sub-identifiers for any object instance does not

exceed the limit of 128, as defined by [RFC1905].

An object of this type contains a single tag value

which is used to select a set of entries in a table.

A tag value is an arbitrary string of octets, but

may not contain a delimiter character. Delimiter

characters are defined to be one of the following:

- An ASCII space character (0x20).

- An ASCII TAB character (0x09).

- An ASCII carriage return (CR) character (0x0D).

- An ASCII line feed (LF) character (0x0A).

Delimiter characters are used to separate tag values

in a tag list. An object of this type may only

contain a single tag value, and so delimiter

characters are not allowed in a value of this type.

Note that a tag value of 0 length means that no tag is

defined. In other words, a tag value of 0 length would

never match anything in a tag list, and would never

select any table entries.

Some examples of valid tag values are:

- 'acme'

- 'router'

- 'host'

The use of a tag value to select table entries is

application and MIB specific."

SYNTAX OCTET STRING (SIZE (0..255))

SnmpTagList ::= TEXTUAL-CONVENTION

DISPLAY-HINT "255t"

STATUS current

DESCRIPTION

"An octet string containing a list of tag values.

Tag values are preferably in human-readable form.

To facilitate internationalization, this information

is represented using the ISO/IEC IS 10646-1 character

set, encoded as an octet string using the UTF-8

character encoding scheme described in RFC2279.

Since additional code points are added by amendments

to the 10646 standard from time to time,

implementations must be prepared to encounter any code

point from 0x00000000 to 0x7fffffff.

The use of control codes should be avoided, except as

described below.

For code points not directly supported by user

interface hardware or software, an alternative means

of entry and display, such as hexadecimal, may be

provided.

For information encoded in 7-bit US-ASCII, the UTF-8

representation is identical to the US-ASCII encoding.

An object of this type contains a list of tag values

which are used to select a set of entries in a table.

A tag value is an arbitrary string of octets, but

may not contain a delimiter character. Delimiter

characters are defined to be one of the following:

- An ASCII space character (0x20).

- An ASCII TAB character (0x09).

- An ASCII carriage return (CR) character (0x0D).

- An ASCII line feed (LF) character (0x0A).

Delimiter characters are used to separate tag values

in a tag list. Only a single delimiter character may

occur between two tag values. A tag value may not

have a zero length. These constraints imply certain

restrictions on the contents of this object:

- There cannot be a leading or trailing delimiter

character.

- There cannot be multiple adjacent delimiter

characters.

Some examples of valid tag lists are:

- '' -- an empty list

- 'acme' -- list of one tag

- 'host router bridge' -- list of several tags

Note that although a tag value may not have a length of

zero, an empty string is still valid. This indicates

an empty list (i.e. there are no tag values in the list).

The use of the tag list to select table entries is

application and MIB specific. Typically, an application

will provide one or more tag values, and any entry

which contains some combination of these tag values

will be selected."

SYNTAX OCTET STRING (SIZE (0..255))

--

--

-- The snmpTargetObjects group

--

--

snmpTargetSpinLock OBJECT-TYPE

SYNTAX TestAndIncr

MAX-ACCESS read-write

STATUS current

DESCRIPTION

"This object is used to facilitate modification of table

entries in the SNMP-TARGET-MIB module by multiple

managers. In particular, it is useful when modifying

the value of the snmpTargetAddrTagList object.

The procedure for modifying the snmpTargetAddrTagList

object is as follows:

1. Retrieve the value of snmpTargetSpinLock and

of snmpTargetAddrTagList.

2. Generate a new value for snmpTargetAddrTagList.

3. Set the value of snmpTargetSpinLock to the

retrieved value, and the value of

snmpTargetAddrTagList to the new value. If

the set fails for the snmpTargetSpinLock

object, go back to step 1."

::= { snmpTargetObjects 1 }

snmpTargetAddrTable OBJECT-TYPE

SYNTAX SEQUENCE OF SnmpTargetAddrEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"A table of transport addresses to be used in the generation

of SNMP messages."

::= { snmpTargetObjects 2 }

snmpTargetAddrEntry OBJECT-TYPE

SYNTAX SnmpTargetAddrEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"A transport address to be used in the generation

of SNMP operations.

Entries in the snmpTargetAddrTable are created and

deleted using the snmpTargetAddrRowStatus object."

INDEX { IMPLIED snmpTargetAddrName }

::= { snmpTargetAddrTable 1 }

SnmpTargetAddrEntry ::= SEQUENCE {

snmpTargetAddrName SnmpAdminString,

snmpTargetAddrTDomain TDomain,

snmpTargetAddrTAddress TAddress,

snmpTargetAddrTimeout TimeInterval,

snmpTargetAddrRetryCount Integer32,

snmpTargetAddrTagList SnmpTagList,

snmpTargetAddrParams SnmpAdminString,

snmpTargetAddrStorageType StorageType,

snmpTargetAddrRowStatus RowStatus

}

snmpTargetAddrName OBJECT-TYPE

SYNTAX SnmpAdminString (SIZE(1..32))

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"The locally arbitrary, but unique identifier associated

with this snmpTargetAddrEntry."

::= { snmpTargetAddrEntry 1 }

snmpTargetAddrTDomain OBJECT-TYPE

SYNTAX TDomain

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object indicates the transport type of the address

contained in the snmpTargetAddrTAddress object."

::= { snmpTargetAddrEntry 2 }

snmpTargetAddrTAddress OBJECT-TYPE

SYNTAX TAddress

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object contains a transport address. The format of

this address depends on the value of the

snmpTargetAddrTDomain object."

::= { snmpTargetAddrEntry 3 }

snmpTargetAddrTimeout OBJECT-TYPE

SYNTAX TimeInterval

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object should reflect the expected maximum round

trip time for communicating with the transport address

defined by this row. When a message is sent to this

address, and a response (if one is expected) is not

received within this time period, an implementation

may assume that the response will not be delivered.

Note that the time interval that an application waits

for a response may actually be derived from the value

of this object. The method for deriving the actual time

interval is implementation dependent. One such method

is to derive the expected round trip time based on a

particular retransmission algorithm and on the number

of timeouts which have occurred. The type of message may

also be considered when deriving expected round trip

times for retransmissions. For example, if a message is

being sent with a securityLevel that indicates both

authentication and privacy, the derived value may be

increased to compensate for extra processing time spent

during authentication and encryption processing."

DEFVAL { 1500 }

::= { snmpTargetAddrEntry 4 }

snmpTargetAddrRetryCount OBJECT-TYPE

SYNTAX Integer32 (0..255)

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object specifies a default number of retries to be

attempted when a response is not received for a generated

message. An application may provide its own retry count,

in which case the value of this object is ignored."

DEFVAL { 3 }

::= { snmpTargetAddrEntry 5 }

snmpTargetAddrTagList OBJECT-TYPE

SYNTAX SnmpTagList

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object contains a list of tag values which are

used to select target addresses for a particular

operation."

DEFVAL { "" }

::= { snmpTargetAddrEntry 6 }

snmpTargetAddrParams OBJECT-TYPE

SYNTAX SnmpAdminString (SIZE(1..32))

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The value of this object identifies an entry in the

snmpTargetParamsTable. The identified entry

contains SNMP parameters to be used when generating

messages to be sent to this transport address."

::= { snmpTargetAddrEntry 7 }

snmpTargetAddrStorageType OBJECT-TYPE

SYNTAX StorageType

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The storage type for this conceptual row.

Conceptual rows having the value 'permanent' need not

allow write-access to any columnar objects in the row."

DEFVAL { nonVolatile }

::= { snmpTargetAddrEntry 8 }

snmpTargetAddrRowStatus OBJECT-TYPE

SYNTAX RowStatus

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The status of this conceptual row.

To create a row in this table, a manager must

set this object to either createAndGo(4) or

createAndWait(5).

Until instances of all corresponding columns are

appropriately configured, the value of the

corresponding instance of the snmpTargetAddrRowStatus

column is 'notReady'.

In particular, a newly created row cannot be made

active until the corresponding instances of

snmpTargetAddrTDomain, snmpTargetAddrTAddress, and

snmpTargetAddrParams have all been set.

The following objects may not be modified while the

value of this object is active(1):

- snmpTargetAddrTDomain

- snmpTargetAddrTAddress

An attempt to set these objects while the value of

snmpTargetAddrRowStatus is active(1) will result in

an inconsistentValue error."

::= { snmpTargetAddrEntry 9 }

snmpTargetParamsTable OBJECT-TYPE

SYNTAX SEQUENCE OF SnmpTargetParamsEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"A table of SNMP target information to be used

in the generation of SNMP messages."

::= { snmpTargetObjects 3 }

snmpTargetParamsEntry OBJECT-TYPE

SYNTAX SnmpTargetParamsEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"A set of SNMP target information.

Entries in the snmpTargetParamsTable are created and

deleted using the snmpTargetParamsRowStatus object."

INDEX { IMPLIED snmpTargetParaMSName }

::= { snmpTargetParamsTable 1 }

SnmpTargetParamsEntry ::= SEQUENCE {

snmpTargetParamsName SnmpAdminString,

snmpTargetParamsMPModel SnmpMessageProcessingModel,

snmpTargetParamsSecurityModel SnmpSecurityModel,

snmpTargetParamsSecurityName SnmpAdminString,

snmpTargetParamsSecurityLevel SnmpSecurityLevel,

snmpTargetParamsStorageType StorageType,

snmpTargetParamsRowStatus RowStatus

}

snmpTargetParamsName OBJECT-TYPE

SYNTAX SnmpAdminString (SIZE(1..32))

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"The locally arbitrary, but unique identifier associated

with this snmpTargetParamsEntry."

::= { snmpTargetParamsEntry 1 }

snmpTargetParamsMPModel OBJECT-TYPE

SYNTAX SnmpMessageProcessingModel

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The Message Processing Model to be used when generating

SNMP messages using this entry."

::= { snmpTargetParamsEntry 2 }

snmpTargetParamsSecurityModel OBJECT-TYPE

SYNTAX SnmpSecurityModel (1..2147483647)

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The Security Model to be used when generating SNMP

messages using this entry. An implementation may

choose to return an inconsistentValue error if an

attempt is made to set this variable to a value

for a security model which the implementation does

not support."

::= { snmpTargetParamsEntry 3 }

snmpTargetParamsSecurityName OBJECT-TYPE

SYNTAX SnmpAdminString

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The securityName which identifies the Principal on

whose behalf SNMP messages will be generated using

this entry."

::= { snmpTargetParamsEntry 4 }

snmpTargetParamsSecurityLevel OBJECT-TYPE

SYNTAX SnmpSecurityLevel

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The Level of Security to be used when generating

SNMP messages using this entry."

::= { snmpTargetParamsEntry 5 }

snmpTargetParamsStorageType OBJECT-TYPE

SYNTAX StorageType

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The storage type for this conceptual row.

Conceptual rows having the value 'permanent' need not

allow write-access to any columnar objects in the row."

DEFVAL { nonVolatile }

::= { snmpTargetParamsEntry 6 }

snmpTargetParamsRowStatus OBJECT-TYPE

SYNTAX RowStatus

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The status of this conceptual row.

To create a row in this table, a manager must

set this object to either createAndGo(4) or

createAndWait(5).

Until instances of all corresponding columns are

appropriately configured, the value of the

corresponding instance of the snmpTargetParamsRowStatus

column is 'notReady'.

In particular, a newly created row cannot be made

active until the corresponding

snmpTargetParamsMPModel,

snmpTargetParamsSecurityModel,

snmpTargetParamsSecurityName,

and snmpTargetParamsSecurityLevel have all been set.

The following objects may not be modified while the

value of this object is active(1):

- snmpTargetParamsMPModel

- snmpTargetParamsSecurityModel

- snmpTargetParamsSecurityName

- snmpTargetParamsSecurityLevel

An attempt to set these objects while the value of

snmpTargetParamsRowStatus is active(1) will result in

an inconsistentValue error."

::= { snmpTargetParamsEntry 7 }

snmpUnavailableContexts 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 context

contained in the message was unavailable."

::= { snmpTargetObjects 4 }

snmpUnknownContexts 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 context

contained in the message was unknown."

::= { snmpTargetObjects 5 }

--

--

-- Conformance information

--

--

snmpTargetCompliances OBJECT IDENTIFIER ::=

{ snmpTargetConformance 1 }

snmpTargetGroups OBJECT IDENTIFIER ::=

{ snmpTargetConformance 2 }

--

--

-- Compliance statements

--

--

snmpTargetCommandResponderCompliance MODULE-COMPLIANCE

STATUS current

DESCRIPTION

"The compliance statement for SNMP entities which include

a command responder application."

MODULE -- This Module

MANDATORY-GROUPS { snmpTargetCommandResponderGroup }

::= { snmpTargetCompliances 1 }

snmpTargetBasicGroup OBJECT-GROUP

OBJECTS {

snmpTargetSpinLock,

snmpTargetAddrTDomain,

snmpTargetAddrTAddress,

snmpTargetAddrTagList,

snmpTargetAddrParams,

snmpTargetAddrStorageType,

snmpTargetAddrRowStatus,

snmpTargetParamsMPModel,

snmpTargetParamsSecurityModel,

snmpTargetParamsSecurityName,

snmpTargetParamsSecurityLevel,

snmpTargetParamsStorageType,

snmpTargetParamsRowStatus

}

STATUS current

DESCRIPTION

"A collection of objects providing basic remote

configuration of management targets."

::= { snmpTargetGroups 1 }

snmpTargetResponseGroup OBJECT-GROUP

OBJECTS {

snmpTargetAddrTimeout,

snmpTargetAddrRetryCount

}

STATUS current

DESCRIPTION

"A collection of objects providing remote configuration

of management targets for applications which generate

SNMP messages for which a response message would be

expected."

::= { snmpTargetGroups 2 }

snmpTargetCommandResponderGroup OBJECT-GROUP

OBJECTS {

snmpUnavailableContexts,

snmpUnknownContexts

}

STATUS current

DESCRIPTION

"A collection of objects required for command responder

applications, used for counting error conditions."

::= { snmpTargetGroups 3 }

END

4.2. The Notification MIB Module

The SNMP-NOTIFICATION-MIB module contains objects for the remote

configuration of the parameters used by an SNMP entity for the

generation of notifications. It consists of three tables and

conformance/compliance statements. The first table, the

snmpNotifyTable, contains entries which select which entries in the

snmpTargetAddrTable should be used for generating notifications, and

the type of notifications to be generated.

The second table, the snmpNotifyFilterProfileTable, sparsely augments

the snmpTargetParamsTable with an object which is used to associate a

set of filters with a particular management target.

The third table, the snmpNotifyFilterTable, defines filters which are

used to limit the number of notifications which are generated using

particular management targets.

4.2.1. Definitions

SNMP-NOTIFICATION-MIB DEFINITIONS ::= BEGIN

IMPORTS

MODULE-IDENTITY,

OBJECT-TYPE,

snmpModules

FROM SNMPv2-SMI

RowStatus,

StorageType

FROM SNMPv2-TC

SnmpAdminString

FROM SNMP-FRAMEWORK-MIB

SnmpTagValue,

snmpTargetParamsName

FROM SNMP-TARGET-MIB

MODULE-COMPLIANCE,

OBJECT-GROUP

FROM SNMPv2-CONF;

snmpNotificationMIB MODULE-IDENTITY

LAST-UPDATED "200210140000Z"

ORGANIZATION "IETF SNMPv3 Working Group"

CONTACT-INFO

"WG-email: snmpv3@lists.tislabs.com

Subscribe: majordomo@lists.tislabs.com

In message body: subscribe snmpv3

Co-Chair: Russ Mundy

Network Associates Laboratories

Postal: 15204 Omega Drive, Suite 300

Rockville, MD 20850-4601

USA

EMail: mundy@tislabs.com

Phone: +1 301-947-7107

Co-Chair: David Harrington

Enterasys Networks

Postal: 35 Industrial Way

P. O. Box 5004

Rochester, New Hampshire 03866-5005

USA

EMail: dbh@enterasys.com

Phone: +1 603-337-2614

Co-editor: David B. Levi

Nortel Networks

Postal: 3505 Kesterwood Drive

Knoxville, Tennessee 37918

EMail: dlevi@nortelnetworks.com

Phone: +1 865 686 0432

Co-editor: Paul Meyer

Secure Computing Corporation

Postal: 2675 Long Lake Road

Roseville, Minnesota 55113

EMail: paul_meyer@securecomputing.com

Phone: +1 651 628 1592

Co-editor: Bob Stewart

Retired"

DESCRIPTION

"This MIB module defines MIB objects which provide

mechanisms to remotely configure the parameters

used by an SNMP entity for the generation of

notifications.

Copyright (C) The Internet Society (2002). This

version of this MIB module is part of RFC3413;

see the RFCitself for full legal notices.

"

REVISION "200210140000Z" -- 14 October 2002

DESCRIPTION "Clarifications, published as

RFC3413."

REVISION "199808040000Z" -- 4 August 1998

DESCRIPTION "Clarifications, published as

RFC2573."

REVISION "199707140000Z" -- 14 July 1997

DESCRIPTION "The initial revision, published as RFC2273."

::= { snmpModules 13 }

snmpNotifyObjects OBJECT IDENTIFIER ::=

{ snmpNotificationMIB 1 }

snmpNotifyConformance OBJECT IDENTIFIER ::=

{ snmpNotificationMIB 3 }

--

--

-- The snmpNotifyObjects group

--

--

snmpNotifyTable OBJECT-TYPE

SYNTAX SEQUENCE OF SnmpNotifyEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"This table is used to select management targets which should

receive notifications, as well as the type of notification

which should be sent to each selected management target."

::= { snmpNotifyObjects 1 }

snmpNotifyEntry OBJECT-TYPE

SYNTAX SnmpNotifyEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"An entry in this table selects a set of management targets

which should receive notifications, as well as the type of

notification which should be sent to each selected

management target.

Entries in the snmpNotifyTable are created and

deleted using the snmpNotifyRowStatus object."

INDEX { IMPLIED snmpNotifyName }

::= { snmpNotifyTable 1 }

SnmpNotifyEntry ::= SEQUENCE {

snmpNotifyName SnmpAdminString,

snmpNotifyTag SnmpTagValue,

snmpNotifyType INTEGER,

snmpNotifyStorageType StorageType,

snmpNotifyRowStatus RowStatus

}

snmpNotifyName OBJECT-TYPE

SYNTAX SnmpAdminString (SIZE(1..32))

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"The locally arbitrary, but unique identifier associated

with this snmpNotifyEntry."

::= { snmpNotifyEntry 1 }

snmpNotifyTag OBJECT-TYPE

SYNTAX SnmpTagValue

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object contains a single tag value which is used

to select entries in the snmpTargetAddrTable. Any entry

in the snmpTargetAddrTable which contains a tag value

which is equal to the value of an instance of this

object is selected. If this object contains a value

of zero length, no entries are selected."

DEFVAL { "" }

::= { snmpNotifyEntry 2 }

snmpNotifyType OBJECT-TYPE

SYNTAX INTEGER {

trap(1),

inform(2)

}

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object determines the type of notification to

be generated for entries in the snmpTargetAddrTable

selected by the corresponding instance of

snmpNotifyTag. This value is only used when

generating notifications, and is ignored when

using the snmpTargetAddrTable for other purposes.

If the value of this object is trap(1), then any

messages generated for selected rows will contain

Unconfirmed-Class PDUs.

If the value of this object is inform(2), then any

messages generated for selected rows will contain

Confirmed-Class PDUs.

Note that if an SNMP entity only supports

generation of Unconfirmed-Class PDUs (and not

Confirmed-Class PDUs), then this object may be

read-only."

DEFVAL { trap }

::= { snmpNotifyEntry 3 }

snmpNotifyStorageType OBJECT-TYPE

SYNTAX StorageType

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The storage type for this conceptual row.

Conceptual rows having the value 'permanent' need not

allow write-access to any columnar objects in the row."

DEFVAL { nonVolatile }

::= { snmpNotifyEntry 4 }

snmpNotifyRowStatus OBJECT-TYPE

SYNTAX RowStatus

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The status of this conceptual row.

To create a row in this table, a manager must

set this object to either createAndGo(4) or

createAndWait(5)."

::= { snmpNotifyEntry 5 }

snmpNotifyFilterProfileTable OBJECT-TYPE

SYNTAX SEQUENCE OF SnmpNotifyFilterProfileEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"This table is used to associate a notification filter

profile with a particular set of target parameters."

::= { snmpNotifyObjects 2 }

snmpNotifyFilterProfileEntry OBJECT-TYPE

SYNTAX SnmpNotifyFilterProfileEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"An entry in this table indicates the name of the filter

profile to be used when generating notifications using

the corresponding entry in the snmpTargetParamsTable.

Entries in the snmpNotifyFilterProfileTable are created

and deleted using the snmpNotifyFilterProfileRowStatus

object."

INDEX { IMPLIED snmpTargetParamsName }

::= { snmpNotifyFilterProfileTable 1 }

SnmpNotifyFilterProfileEntry ::= SEQUENCE {

snmpNotifyFilterProfileName SnmpAdminString,

snmpNotifyFilterProfileStorType StorageType,

snmpNotifyFilterProfileRowStatus RowStatus

}

snmpNotifyFilterProfileName OBJECT-TYPE

SYNTAX SnmpAdminString (SIZE(1..32))

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The name of the filter profile to be used when generating

notifications using the corresponding entry in the

snmpTargetAddrTable."

::= { snmpNotifyFilterProfileEntry 1 }

snmpNotifyFilterProfileStorType OBJECT-TYPE

SYNTAX StorageType

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The storage type for this conceptual row.

Conceptual rows having the value 'permanent' need not

allow write-access to any columnar objects in the row."

DEFVAL { nonVolatile }

::= { snmpNotifyFilterProfileEntry 2 }

snmpNotifyFilterProfileRowStatus OBJECT-TYPE

SYNTAX RowStatus

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The status of this conceptual row.

To create a row in this table, a manager must

set this object to either createAndGo(4) or

createAndWait(5).

Until instances of all corresponding columns are

appropriately configured, the value of the

corresponding instance of the

snmpNotifyFilterProfileRowStatus column is 'notReady'.

In particular, a newly created row cannot be made

active until the corresponding instance of

snmpNotifyFilterProfileName has been set."

::= { snmpNotifyFilterProfileEntry 3 }

snmpNotifyFilterTable OBJECT-TYPE

SYNTAX SEQUENCE OF SnmpNotifyFilterEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"The table of filter profiles. Filter profiles are used

to determine whether particular management targets should

receive particular notifications.

When a notification is generated, it must be compared

with the filters associated with each management target

which is configured to receive notifications, in order to

determine whether it may be sent to each such management

target.

A more complete discussion of notification filtering

can be found in section 6. of [SNMP-APPL]."

::= { snmpNotifyObjects 3 }

snmpNotifyFilterEntry OBJECT-TYPE

SYNTAX SnmpNotifyFilterEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"An element of a filter profile.

Entries in the snmpNotifyFilterTable are created and

deleted using the snmpNotifyFilterRowStatus object."

INDEX { snmpNotifyFilterProfileName,

IMPLIED snmpNotifyFilterSuBTree }

::= { snmpNotifyFilterTable 1 }

SnmpNotifyFilterEntry ::= SEQUENCE {

snmpNotifyFilterSubtree OBJECT IDENTIFIER,

snmpNotifyFilterMask OCTET STRING,

snmpNotifyFilterType INTEGER,

snmpNotifyFilterStorageType StorageType,

snmpNotifyFilterRowStatus RowStatus

}

snmpNotifyFilterSubtree OBJECT-TYPE

SYNTAX OBJECT IDENTIFIER

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"The MIB subtree which, when combined with the corresponding

instance of snmpNotifyFilterMask, defines a family of

subtrees which are included in or excluded from the

filter profile."

::= { snmpNotifyFilterEntry 1 }

snmpNotifyFilterMask OBJECT-TYPE

SYNTAX OCTET STRING (SIZE(0..16))

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The bit mask which, in combination with the corresponding

instance of snmpNotifyFilterSubtree, defines a family of

subtrees which are included in or excluded from the

filter profile.

Each bit of this bit mask corresponds to a

sub-identifier of snmpNotifyFilterSubtree, with the

most significant bit of the i-th octet of this octet

string value (extended if necessary, see below)

corresponding to the (8*i - 7)-th sub-identifier, and

the least significant bit of the i-th octet of this

octet string corresponding to the (8*i)-th

sub-identifier, where i is in the range 1 through 16.

Each bit of this bit mask specifies whether or not

the corresponding sub-identifiers must match when

determining if an OBJECT IDENTIFIER matches this

family of filter subtrees; a '1' indicates that an

exact match must occur; a '0' indicates 'wild card',

i.e., any sub-identifier value matches.

Thus, the OBJECT IDENTIFIER X of an object instance

is contained in a family of filter subtrees if, for

each sub-identifier of the value of

snmpNotifyFilterSubtree, either:

the i-th bit of snmpNotifyFilterMask is 0, or

the i-th sub-identifier of X is equal to the i-th

sub-identifier of the value of

snmpNotifyFilterSubtree.

If the value of this bit mask is M bits long and

there are more than M sub-identifiers in the

corresponding instance of snmpNotifyFilterSubtree,

then the bit mask is extended with 1's to be the

required length.

Note that when the value of this object is the

zero-length string, this extension rule results in

a mask of all-1's being used (i.e., no 'wild card'),

and the family of filter subtrees is the one

subtree uniquely identified by the corresponding

instance of snmpNotifyFilterSubtree."

DEFVAL { ''H }

::= { snmpNotifyFilterEntry 2 }

snmpNotifyFilterType OBJECT-TYPE

SYNTAX INTEGER {

included(1),

excluded(2)

}

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object indicates whether the family of filter subtrees

defined by this entry are included in or excluded from a

filter. A more detailed discussion of the use of this

object can be found in section 6. of [SNMP-APPL]."

DEFVAL { included }

::= { snmpNotifyFilterEntry 3 }

snmpNotifyFilterStorageType OBJECT-TYPE

SYNTAX StorageType

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The storage type for this conceptual row.

Conceptual rows having the value 'permanent' need not

allow write-access to any columnar objects in the row."

DEFVAL { nonVolatile }

::= { snmpNotifyFilterEntry 4 }

snmpNotifyFilterRowStatus OBJECT-TYPE

SYNTAX RowStatus

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The status of this conceptual row.

To create a row in this table, a manager must

set this object to either createAndGo(4) or

createAndWait(5)."

::= { snmpNotifyFilterEntry 5 }

--

--

-- Conformance information

--

--

snmpNotifyCompliances OBJECT IDENTIFIER ::=

{ snmpNotifyConformance 1 }

snmpNotifyGroups OBJECT IDENTIFIER ::=

{ snmpNotifyConformance 2 }

--

--

-- Compliance statements

--

--

snmpNotifyBasicCompliance MODULE-COMPLIANCE

STATUS current

DESCRIPTION

"The compliance statement for minimal SNMP entities which

implement only SNMP Unconfirmed-Class notifications and

read-create operations on only the snmpTargetAddrTable."

MODULE SNMP-TARGET-MIB

MANDATORY-GROUPS { snmpTargetBasicGroup }

OBJECT snmpTargetParamsMPModel

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access is not required."

OBJECT snmpTargetParamsSecurityModel

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access is not required."

OBJECT snmpTargetParamsSecurityName

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access is not required."

OBJECT snmpTargetParamsSecurityLevel

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access is not required."

OBJECT snmpTargetParamsStorageType

SYNTAX INTEGER {

readOnly(5)

}

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access is not required.

Support of the values other(1), volatile(2),

nonVolatile(3), and permanent(4) is not required."

OBJECT snmpTargetParamsRowStatus

SYNTAX INTEGER {

active(1)

}

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access to the

snmpTargetParamsTable is not required.

Support of the values notInService(2), notReady(3),

createAndGo(4), createAndWait(5), and destroy(6) is

not required."

MODULE -- This Module

MANDATORY-GROUPS { snmpNotifyGroup }

OBJECT snmpNotifyTag

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access is not required."

OBJECT snmpNotifyType

SYNTAX INTEGER {

trap(1)

}

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access is not required.

Support of the value notify(2) is not required."

OBJECT snmpNotifyStorageType

SYNTAX INTEGER {

readOnly(5)

}

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access is not required.

Support of the values other(1), volatile(2),

nonVolatile(3), and permanent(4) is not required."

OBJECT snmpNotifyRowStatus

SYNTAX INTEGER {

active(1)

}

MIN-ACCESS read-only

DESCRIPTION

"Create/delete/modify access to the

snmpNotifyTable is not required.

Support of the values notInService(2), notReady(3),

createAndGo(4), createAndWait(5), and destroy(6) is

not required."

::= { snmpNotifyCompliances 1 }

snmpNotifyBasicFiltersCompliance MODULE-COMPLIANCE

STATUS current

DESCRIPTION

"The compliance statement for SNMP entities which implement

SNMP Unconfirmed-Class notifications with filtering, and

read-create operations on all related tables."

MODULE SNMP-TARGET-MIB

MANDATORY-GROUPS { snmpTargetBasicGroup }

MODULE -- This Module

MANDATORY-GROUPS { snmpNotifyGroup,

snmpNotifyFilterGroup }

::= { snmpNotifyCompliances 2 }

snmpNotifyFullCompliance MODULE-COMPLIANCE

STATUS current

DESCRIPTION

"The compliance statement for SNMP entities which either

implement only SNMP Confirmed-Class notifications, or both

SNMP Unconfirmed-Class and Confirmed-Class notifications,

plus filtering and read-create operations on all related

tables."

MODULE SNMP-TARGET-MIB

MANDATORY-GROUPS { snmpTargetBasicGroup,

snmpTargetResponseGroup }

MODULE -- This Module

MANDATORY-GROUPS { snmpNotifyGroup,

snmpNotifyFilterGroup }

::= { snmpNotifyCompliances 3 }

snmpNotifyGroup OBJECT-GROUP

OBJECTS {

snmpNotifyTag,

snmpNotifyType,

snmpNotifyStorageType,

snmpNotifyRowStatus

}

STATUS current

DESCRIPTION

"A collection of objects for selecting which management

targets are used for generating notifications, and the

type of notification to be generated for each selected

management target."

::= { snmpNotifyGroups 1 }

snmpNotifyFilterGroup OBJECT-GROUP

OBJECTS {

snmpNotifyFilterProfileName,

snmpNotifyFilterProfileStorType,

snmpNotifyFilterProfileRowStatus,

snmpNotifyFilterMask,

snmpNotifyFilterType,

snmpNotifyFilterStorageType,

snmpNotifyFilterRowStatus

}

STATUS current

DESCRIPTION

"A collection of objects providing remote configuration

of notification filters."

::= { snmpNotifyGroups 2 }

END

4.3. The Proxy MIB Module

The SNMP-PROXY-MIB module, which defines MIB objects that provide

mechanisms to remotely configure the parameters used by an SNMP

entity for proxy forwarding operations, contains a single table.

This table, snmpProxyTable, is used to define translations between

management targets for use when forwarding messages.

4.3.1. Definitions

SNMP-PROXY-MIB DEFINITIONS ::= BEGIN

IMPORTS

MODULE-IDENTITY,

OBJECT-TYPE,

snmpModules

FROM SNMPv2-SMI

RowStatus,

StorageType

FROM SNMPv2-TC

SnmpEngineID,

SnmpAdminString

FROM SNMP-FRAMEWORK-MIB

SnmpTagValue

FROM SNMP-TARGET-MIB

MODULE-COMPLIANCE,

OBJECT-GROUP

FROM SNMPv2-CONF;

snmpProxyMIB MODULE-IDENTITY

LAST-UPDATED "200210140000Z"

ORGANIZATION "IETF SNMPv3 Working Group"

CONTACT-INFO

"WG-email: snmpv3@lists.tislabs.com

Subscribe: majordomo@lists.tislabs.com

In message body: subscribe snmpv3

Co-Chair: Russ Mundy

Network Associates Laboratories

Postal: 15204 Omega Drive, Suite 300

Rockville, MD 20850-4601

USA

EMail: mundy@tislabs.com

Phone: +1 301-947-7107

Co-Chair: David Harrington

Enterasys Networks

Postal: 35 Industrial Way

P. O. Box 5004

Rochester, New Hampshire 03866-5005

USA

EMail: dbh@enterasys.com

Phone: +1 603-337-2614

Co-editor: David B. Levi

Nortel Networks

Postal: 3505 Kesterwood Drive

Knoxville, Tennessee 37918

EMail: dlevi@nortelnetworks.com

Phone: +1 865 686 0432

Co-editor: Paul Meyer

Secure Computing Corporation

Postal: 2675 Long Lake Road

Roseville, Minnesota 55113

EMail: paul_meyer@securecomputing.com

Phone: +1 651 628 1592

Co-editor: Bob Stewart

Retired"

DESCRIPTION

"This MIB module defines MIB objects which provide

mechanisms to remotely configure the parameters

used by a proxy forwarding application.

Copyright (C) The Internet Society (2002). This

version of this MIB module is part of RFC3413;

see the RFCitself for full legal notices.

"

REVISION "200210140000Z" -- 14 October 2002

DESCRIPTION "Clarifications, published as

RFC3413."

REVISION "199808040000Z" -- 4 August 1998

DESCRIPTION "Clarifications, published as

RFC2573."

REVISION "199707140000Z" -- 14 July 1997

DESCRIPTION "The initial revision, published as RFC2273."

::= { snmpModules 14 }

snmpProxyObjects OBJECT IDENTIFIER ::= { snmpProxyMIB 1 }

snmpProxyConformance OBJECT IDENTIFIER ::= { snmpProxyMIB 3 }

--

--

-- The snmpProxyObjects group

--

--

snmpProxyTable OBJECT-TYPE

SYNTAX SEQUENCE OF SnmpProxyEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"The table of translation parameters used by proxy forwarder

applications for forwarding SNMP messages."

::= { snmpProxyObjects 2 }

snmpProxyEntry OBJECT-TYPE

SYNTAX SnmpProxyEntry

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"A set of translation parameters used by a proxy forwarder

application for forwarding SNMP messages.

Entries in the snmpProxyTable are created and deleted

using the snmpProxyRowStatus object."

INDEX { IMPLIED snmpProxyName }

::= { snmpProxyTable 1 }

SnmpProxyEntry ::= SEQUENCE {

snmpProxyName SnmpAdminString,

snmpProxyType INTEGER,

snmpProxyContextEngineID SnmpEngineID,

snmpProxyContextName SnmpAdminString,

snmpProxyTargetParamsIn SnmpAdminString,

snmpProxySingleTargetOut SnmpAdminString,

snmpProxyMultipleTargetOut SnmpTagValue,

snmpProxyStorageType StorageType,

snmpProxyRowStatus RowStatus

}

snmpProxyName OBJECT-TYPE

SYNTAX SnmpAdminString (SIZE(1..32))

MAX-ACCESS not-accessible

STATUS current

DESCRIPTION

"The locally arbitrary, but unique identifier associated

with this snmpProxyEntry."

::= { snmpProxyEntry 1 }

snmpProxyType OBJECT-TYPE

SYNTAX INTEGER {

read(1),

write(2),

trap(3),

inform(4)

}

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The type of message that may be forwarded using

the translation parameters defined by this entry."

::= { snmpProxyEntry 2 }

snmpProxyContextEngineID OBJECT-TYPE

SYNTAX SnmpEngineID

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The contextEngineID contained in messages that

may be forwarded using the translation parameters

defined by this entry."

::= { snmpProxyEntry 3 }

snmpProxyContextName OBJECT-TYPE

SYNTAX SnmpAdminString

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The contextName contained in messages that may be

forwarded using the translation parameters defined

by this entry.

This object is optional, and if not supported, the

contextName contained in a message is ignored when

selecting an entry in the snmpProxyTable."

::= { snmpProxyEntry 4 }

snmpProxyTargetParamsIn OBJECT-TYPE

SYNTAX SnmpAdminString

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object selects an entry in the snmpTargetParamsTable.

The selected entry is used to determine which row of the

snmpProxyTable to use for forwarding received messages."

::= { snmpProxyEntry 5 }

snmpProxySingleTargetOut OBJECT-TYPE

SYNTAX SnmpAdminString

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object selects a management target defined in the

snmpTargetAddrTable (in the SNMP-TARGET-MIB). The

selected target is defined by an entry in the

snmpTargetAddrTable whose index value (snmpTargetAddrName)

is equal to this object.

This object is only used when selection of a single

target is required (i.e. when forwarding an incoming

read or write request)."

::= { snmpProxyEntry 6 }

snmpProxyMultipleTargetOut OBJECT-TYPE

SYNTAX SnmpTagValue

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"This object selects a set of management targets defined

in the snmpTargetAddrTable (in the SNMP-TARGET-MIB).

This object is only used when selection of multiple

targets is required (i.e. when forwarding an incoming

notification)."

::= { snmpProxyEntry 7 }

snmpProxyStorageType OBJECT-TYPE

SYNTAX StorageType

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The storage type of this conceptual row.

Conceptual rows having the value 'permanent' need not

allow write-access to any columnar objects in the row."

DEFVAL { nonVolatile }

::= { snmpProxyEntry 8 }

snmpProxyRowStatus OBJECT-TYPE

SYNTAX RowStatus

MAX-ACCESS read-create

STATUS current

DESCRIPTION

"The status of this conceptual row.

To create a row in this table, a manager must

set this object to either createAndGo(4) or

createAndWait(5).

The following objects may not be modified while the

value of this object is active(1):

- snmpProxyType

- snmpProxyContextEngineID

- snmpProxyContextName

- snmpProxyTargetParamsIn

- snmpProxySingleTargetOut

- snmpProxyMultipleTargetOut"

::= { snmpProxyEntry 9 }

--

--

-- Conformance information

--

--

snmpProxyCompliances OBJECT IDENTIFIER ::=

{ snmpProxyConformance 1 }

snmpProxyGroups OBJECT IDENTIFIER ::=

{ snmpProxyConformance 2 }

--

--

-- Compliance statements

--

--

snmpProxyCompliance MODULE-COMPLIANCE

STATUS current

DESCRIPTION

"The compliance statement for SNMP entities which include

a proxy forwarding application."

MODULE SNMP-TARGET-MIB

MANDATORY-GROUPS { snmpTargetBasicGroup,

snmpTargetResponseGroup }

MODULE -- This Module

MANDATORY-GROUPS { snmpProxyGroup }

::= { snmpProxyCompliances 1 }

snmpProxyGroup OBJECT-GROUP

OBJECTS {

snmpProxyType,

snmpProxyContextEngineID,

snmpProxyContextName,

snmpProxyTargetParamsIn,

snmpProxySingleTargetOut,

snmpProxyMultipleTargetOut,

snmpProxyStorageType,

snmpProxyRowStatus

}

STATUS current

DESCRIPTION

"A collection of objects providing remote configuration of

management target translation parameters for use by

proxy forwarder applications."

::= { snmpProxyGroups 3 }

END

5. Identification of Management Targets in Notification Originators

This section describes the mechanisms used by a notification

originator application when using the MIB module described in this

document to determine the set of management targets to be used when

generating a notification.

A notification originator uses all active entries in the

snmpNotifyTable to find the management targets to be used for

generating notifications. Each active entry in this table selects

zero or more entries in the snmpTargetAddrTable. When a notification

is generated, it is sent to all of the targets specified by the

selected snmpTargetAddrTable entries (subject to the application of

access control and notification filtering).

Any entry in the snmpTargetAddrTable whose snmpTargetAddrTagList

object contains a tag value which is equal to a value of

snmpNotifyTag is selected by the snmpNotifyEntry which contains that

instance of snmpNotifyTag. Note that a particular

snmpTargetAddrEntry may be selected by multiple entries in the

snmpNotifyTable, resulting in multiple notifications being generated

using that snmpTargetAddrEntry (this allows, for example, both traps

and informs to be sent to the same target).

Each snmpTargetAddrEntry contains a pointer to the

snmpTargetParamsTable (snmpTargetAddrParams). This pointer selects a

set of SNMP parameters to be used for generating notifications. If

the selected entry in the snmpTargetParamsTable does not exist, the

management target is not used to generate notifications.

The decision as to whether a notification should contain an

Unconfirmed-Class or a Confirmed-Class PDU is determined by the value

of the snmpNotifyType object. If the value of this object is

trap(1), the notification should contain an Unconfirmed-Class PDU.

If the value of this object is inform(2), then the notification

should contain a Confirmed-Class PDU, and the timeout time and number

of retries for the notification are the value of

snmpTargetAddrTimeout and snmpTargetAddrRetryCount. Note that the

exception to these rules is when the snmpTargetParamsMPModel object

indicates an SNMP version which supports a different PDU version. In

this case, the notification may be sent using a different PDU type

([RFC2576] defines the PDU type in the case where the outgoing SNMP

version is SNMPv1).

6. Notification Filtering

This section describes the mechanisms used by a notification

originator application when using the MIB module described in this

document to filter generation of notifications.

A notification originator uses the snmpNotifyFilterTable to filter

notifications. A notification filter profile may be associated with

a particular entry in the snmpTargetParamsTable. The associated

filter profile is identified by an entry in the

snmpNotifyFilterProfileTable whose index is equal to the index of the

entry in the snmpTargetParamsTable. If no such entry exists in the

snmpNotifyFilterProfileTable, no filtering is performed for that

management target.

If such an entry does exist, the value of snmpNotifyFilterProfileName

of the entry is compared with the corresponding portion of the index

of all active entries in the snmpNotifyFilterTable. All such entries

for which this comparison results in an exact match are used for

filtering a notification generated using the associated

snmpTargetParamsEntry. If no such entries exist, no filtering is

performed, and a notification may be sent to the management target.

Otherwise, if matching entries do exist, a notification may be sent

if 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 specifically

included, and none of the object instances to be included in the

variable-bindings of the notification are specifically excluded by

the matching entries.

Each set of snmpNotifyFilterTable entries is divided into two

collections of filter subtrees: the included filter subtrees, and

the excluded filter subtrees. The snmpNotifyFilterType object

defines the collection to which each matching entry belongs.

To determine whether a particular notification name or object

instance is excluded by the set of matching entries, compare the

notification name's or object instance's OBJECT IDENTIFIER with each

of the matching entries. For a notification name, if none match,

then the notification name is considered excluded, and the

notification should not be sent to this management target. For an

object instance, if none match, the object instance is considered

included, and the notification may be sent to this management target.

If one or more match, then the notification name or object instance

is included or excluded, according to the value of

snmpNotifyFilterType in the entry whose value of

snmpNotifyFilterSubtree has the most sub-identifiers. If multiple

entries match and have the same number of sub-identifiers, then the

value of snmpNotifyFilterType, in the entry among those which match,

and whose instance is lexicographically the largest, determines the

inclusion or exclusion.

A notification name or object instance's OBJECT IDENTIFIER X matches

an entry in the snmpNotifyFilterTable when the number of sub-

identifiers in X is at least as many as in the value of

snmpNotifyFilterSubtree for the entry, and each sub-identifier in the

value of snmpNotifyFilterSubtree matches its corresponding sub-

identifier in X. Two sub-identifiers match either if the

corresponding bit of snmpNotifyFilterMask is zero (the 'wild card'

value), or if the two sub-identifiers are equal.

7. Management Target Translation in Proxy Forwarder Applications

This section describes the mechanisms used by a proxy forwarder

application when using the MIB module described in this document to

translate incoming management target information into outgoing

management target information for the purpose of forwarding messages.

There are actually two mechanisms a proxy forwarder may use, one for

forwarding request messages, and one for forwarding notification

messages.

7.1. Management Target Translation for Request Forwarding

When forwarding request messages, the proxy forwarder will select a

single entry in the snmpProxyTable. To select this entry, it will

perform the following comparisons:

- The snmpProxyType must be read(1) if the request is a Read-Class

PDU. The snmpProxyType must be write(2) if the request is a

Write-Class PDU.

- The contextEngineID must equal the snmpProxyContextEngineID object.

- If the snmpProxyContextName object is supported, it must equal the

contextName.

- The snmpProxyTargetParamsIn object identifies an entry in the

snmpTargetParamsTable. The messageProcessingModel, security model,

securityName, and securityLevel must match the values of

snmpTargetParamsMPModel, snmpTargetParamsSecurityModel,

snmpTargetParamsSecurityName, and snmpTargetParamsSecurityLevel of

the identified entry in the snmpTargetParamsTable.

There may be multiple entries in the snmpProxyTable for which these

comparisons succeed. The entry whose snmpProxyName has the

lexicographically smallest value and for which the comparisons

succeed will be selected by the proxy forwarder.

The outgoing management target information is identified by the value

of the snmpProxySingleTargetOut object of the selected entry. This

object identifies an entry in the snmpTargetAddrTable. The

identified entry in the snmpTargetAddrTable also contains a reference

to the snmpTargetParamsTable (snmpTargetAddrParams). If either the

identified entry in the snmpTargetAddrTable does not exist, or the

identified entry in the snmpTargetParamsTable does not exist, then

this snmpProxyEntry does not identify valid forwarding information,

and the proxy forwarder should attempt to identify another row.

If there is no entry in the snmpProxyTable for which all of the

conditions above may be met, then there is no appropriate forwarding

information, and the proxy forwarder should take appropriate actions.

Otherwise, The snmpTargetAddrTDomain, snmpTargetAddrTAddress,

snmpTargetAddrTimeout, and snmpTargetRetryCount of the identified

snmpTargetAddrEntry, and the snmpTargetParamsMPModel,

snmpTargetParamsSecurityModel, snmpTargetParamsSecurityName, and

snmpTargetParamsSecurityLevel of the identified snmpTargetParamsEntry

are used as the destination management target.

7.2. Management Target Translation for Notification Forwarding

When forwarding notification messages, the proxy forwarder will

select multiple entries in the snmpProxyTable. To select these

entries, it will perform the following comparisons:

- The snmpProxyType must be trap(3) if the notification is an

Unconfirmed-Class PDU. The snmpProxyType must be inform(4) if the

request is a Confirmed-Class PDU.

- The contextEngineID must equal the snmpProxyContextEngineID object.

- If the snmpProxyContextName object is supported, it must equal the

contextName.

- The snmpProxyTargetParamsIn object identifies an entry in the

snmpTargetParamsTable. The messageProcessingModel, security model,

securityName, and securityLevel must match the values of

snmpTargetParamsMPModel, snmpTargetParamsSecurityModel,

snmpTargetParamsSecurityName, and snmpTargetParamsSecurityLevel of

the identified entry in the snmpTargetParamsTable.

All entries for which these conditions are met are selected. The

snmpProxyMultipleTargetOut object of each such entry is used to

select a set of entries in the snmpTargetAddrTable. Any

snmpTargetAddrEntry whose snmpTargetAddrTagList object contains a tag

value equal to the value of snmpProxyMultipleTargetOut, and whose

snmpTargetAddrParams object references an existing entry in the

snmpTargetParamsTable, is selected as a destination for the forwarded

notification.

8. 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.

9. Acknowledgments

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 (Enterasys Networks)

Lauren Heintz (BMC Software, Inc.)

N.C. Hien (IBM T.J. Watson Research Center)

Michael Kirkham (InterWorking Labs, Inc.)

Dave Levi (Nortel Networks)

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 (Lucent Technologies)

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 (Enterasys Networks)

Jeff Johnson (Cisco Systems)

David Levi (Nortel Networks)

John Linn (Openvision)

Russ Mundy (Trusted Information Systems) chair

Shawn Routhier (Epilogue)

Glenn Waters (Nortel)

Bert Wijnen (Lucent Technologies)

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 (Enterasys Networks)

David Levi (Nortel Networks)

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 SNMP applications described in this document typically have

direct access to MIB instrumentation. Thus, it is very important

that these applications be strict in their application of access

control as described in this document.

In addition, there may be some types of notification generator

applications which, rather than accessing MIB instrumentation using

access control, will obtain MIB information through other means (such

as from a command line). The implementors and users of such

applications must be responsible for not divulging MIB information

that normally would be inaccessible due to access control.

Finally, the MIBs described in this document contain potentially

sensitive information. A security administrator may wish to limit

access to these MIBs.

11. References

11.1 Normative References

[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate

Requirement Levels", BCP 14, RFC2119, 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, RFC2578, April

1999.

[RFC2579] McCloghrie, K., Perkins, D., Schoenwaelder, J., Case, J.,

Rose, M. and S. Waldbusser, "Textual Conventions for

SMIv2", STD 58, RFC2579, April 1999.

[RFC2580] McCloghrie, K., Perkins, D., Schoenwaelder, J., Case, J.,

Rose, M. and S. Waldbusser, "Conformance Statements for

SMIv2", STD 58, RFC2580, April 1999.

[RFC3411] Harrington, D., Presuhn, R. and B. Wijnen, "An

Architecture for describing Simple Network Management

Protocol (SNMP) Management Frameworks", STD 62, RFC3411,

December 2002.

[RFC3412] Case, J., Harrington, D., Presuhn, R. and B. Wijnen,

"Message Processing and Dispatching for the Simple

Network Management Protocol (SNMP)", STD 62, RFC3412,

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, RFC3415, December

2002.

[RFC3416] Presuhn, R., Case, J., McCloghrie, K., Rose, M. and S.

Waldbusser, "Protocol Operations for the Simple Network

Management Protocol (SNMP)", STD 62, RFC3416, 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

[RFC1157] Case, J., Fedor, M., Schoffstall, M. and J. Davin,

"Simple Network Management Protocol", STD 15, RFC1157,

May 1990.

[RFC1213] McCloghrie, K. and M. Rose, Editors, "Management

Information Base for Network Management of TCP/IP-based

internets: MIB-II", STD 17, RFC1213, March 1991.

[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",

RFC2576, February 1999.

Appendix A - Trap Configuration Example

This section describes an example configuration for a Notification

Generator application which implements the snmpNotifyBasicCompliance

level. The example configuration specifies that the Notification

Generator should send notifications to 3 separate managers, using

authentication and no privacy for the first 2 managers, and using

both authentication and privacy for the third manager.

The configuration consists of three rows in the snmpTargetAddrTable,

two rows in the snmpTargetTable, and two rows in the snmpNotifyTable.

* snmpTargetAddrName = "addr1"

snmpTargetAddrTDomain = snmpUDPDomain

snmpTargetAddrTAddress = 128.1.2.3/162

snmpTargetAddrTagList = "group1"

snmpTargetAddrParams = "AuthNoPriv-joe"

snmpTargetAddrStorageType = readOnly(5)

snmpTargetAddrRowStatus = active(1)

* snmpTargetAddrName = "addr2"

snmpTargetAddrTDomain = snmpUDPDomain

snmpTargetAddrTAddress = 128.2.4.6/162

snmpTargetAddrTagList = "group1"

snmpTargetAddrParams = "AuthNoPriv-joe"

snmpTargetAddrStorageType = readOnly(5)

snmpTargetAddrRowStatus = active(1)

* snmpTargetAddrName = "addr3"

snmpTargetAddrTDomain = snmpUDPDomain

snmpTargetAddrTAddress = 128.1.5.9/162

snmpTargetAddrTagList = "group2"

snmpTargetAddrParams = "AuthPriv-bob"

snmpTargetAddrStorageType = readOnly(5)

snmpTargetAddrRowStatus = active(1)

* snmpTargetParamsName = "AuthNoPriv-joe"

snmpTargetParamsMPModel = 3

snmpTargetParamsSecurityModel = 3 (USM)

snmpTargetParamsSecurityName = "joe"

snmpTargetParamsSecurityLevel = authNoPriv(2)

snmpTargetParamsStorageType = readOnly(5)

snmpTargetParamsRowStatus = active(1)

* snmpTargetParamsName = "AuthPriv-bob"

snmpTargetParamsMPModel = 3

snmpTargetParamsSecurityModel = 3 (USM)

snmpTargetParamsSecurityName = "bob"

snmpTargetParamsSecurityLevel = authPriv(3)

snmpTargetParamsStorageType = readOnly(5)

snmpTargetParamsRowStatus = active(1)

* snmpNotifyName = "group1"

snmpNotifyTag = "group1"

snmpNotifyType = trap(1)

snmpNotifyStorageType = readOnly(5)

snmpNotifyRowStatus = active(1)

* snmpNotifyName = "group2"

snmpNotifyTag = "group2"

snmpNotifyType = trap(1)

snmpNotifyStorageType = readOnly(5)

snmpNotifyRowStatus = active(1)

These entries define two groups of management targets. The first

group contains two management targets:

first target second target

------------ -------------

messageProcessingModel SNMPv3 SNMPv3

securityModel 3 (USM) 3 (USM)

securityName "joe" "joe"

securityLevel authNoPriv(2) authNoPriv(2)

transportDomain snmpUDPDomain snmpUDPDomain

transportAddress 128.1.2.3/162 128.2.4.6/162

And the second group contains a single management target:

messageProcessingModel SNMPv3

securityLevel authPriv(3)

securityModel 3 (USM)

securityName "bob"

transportDomain snmpUDPDomain

transportAddress 128.1.5.9/162

Editors' Addresses

David B. Levi

Nortel Networks

3505 Kesterwood Drive

Knoxville, TN 37918

U.S.A.

Phone: +1 865 686 0432

EMail: dlevi@nortelnetworks.com

Paul Meyer

Secure Computing Corporation

2675 Long Lake Road

Roseville, MN 55113

U.S.A.

Phone: +1 651 628 1592

EMail: paul_meyer@securecomputing.com

Bob Stewart

Retired

Full Copyright Statement

Copyright (C) The Internet Society (2002). All Rights Reserved.

This document and translations of it may be copied and furnished to

others, and derivative works that comment on or otherwise explain it

or assist in its implementation may be prepared, copied, published

and distributed, in whole or in part, without restriction of any

kind, provided that the above copyright notice and this paragraph are

included on all such copies and derivative works. However, this

document itself may not be modified in any way, such as by removing

the copyright notice or references to the Internet Society or other

Internet organizations, except as needed for the purpose of

developing Internet standards in which case the procedures for

copyrights defined in the Internet Standards process must be

followed, or as required to translate it into languages other than

English.

The limited permissions granted above are perpetual and will not be

revoked by the Internet Society or its successors or assigns.

This document and the information contained herein is provided on an

"AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING

TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING

BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION

HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF

MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.

Acknowledgement

Funding for the RFCEditor function is currently provided by the

Internet Society.

• ·RFC3391 - The MIME Appl
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• ·RFC3394 - Advanced Encr
• ·RFC3392 - Capabilities
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• ·RFC3419 - Textual Conve
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