Network Working Group Z. Kielczewski Request for Comments: 1666 Eicon Technology Corporation Obsoletes: 1665 D. Kostick Category: Standards Track Bell Communications Research K. Shih Novell Editors August 1994 Definitions of Managed Objects for SNA NAUs using SMIv2 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. Table of Contents 1. Introduction ................................................ 2 2. The SNMPv2 Network Management Framework ..................... 2 2.1 Object Definitions ......................................... 2 3. Overview .................................................... 3 3.1 Applying MIB II to managing SNA NAUs ....................... 4 3.2 SNANAU MIB Structure ....................................... 4 3.2.1 snaNode group ............................................ 5 3.2.2 snaLu group .............................................. 6 3.2.3 snaMgtTools group ........................................ 7 3.2.4 Conformance statement .................................... 7 3.3 SNANAU MIB special feature ................................. 7 3.3.1 Row Creation mechanism ................................... 8 3.3.2 State Diagrams ........................................... 8 4. Object Definitions .......................................... 9 5. Acknowledgments ............................................. 67 6. References .................................................. 67 7. Security Considerations ..................................... 68 8. Authors' Addresses .......................................... 68 Kielczewski, Kostick & Shih [Page 1] RFC 1666 SNANAU MIB August 1994 1. Introduction This memo defines a portion of the Management Information Base (MIB) for use with network management protocols in the Internet community. In particular, it defines objects for managing the configuration, monitoring and control of Physical Units (PUs) and Logical Units (LUs) in an SNA environment. PUs and LUs are two types of Network Addressable Units (NAUs) in the logical structure of an SNA network. NAUs are the origination or destination points for SNA data streams. This memo identifies managed objects for PU Type 1.0, 2.0 and Type 2.1 and LU Type 0, 1, 2, 3, 4, 7. The generic objects defined here can also be used to manage LU 6.2 and any LU-LU session. The SNA terms and overall architecture are documented in [1]. 2. The SNMPv2 Network Management Framework The SNMPv2 Network Management Framework consists of four major components. They are: o RFC 1442 [2] which defines the SMI, the mechanisms used for describing and naming objects for the purpose of management. o STD 17, RFC 1213 [3] defines MIB-II, the core set of managed objects for the Internet suite of protocols. o RFC 1445 [4] which defines the administrative and other architectural aspects of the framework. o RFC 1448 [5] which defines the protocol used for network access to managed objects. The Framework permits new objects to be defined for the purpose of experimentation and evaluation. 2.1. Object Definitions Managed objects are accessed via a virtual information store, termed the Management Information Base or MIB. Objects in the MIB are defined using the subset of Abstract Syntax Notation One (ASN.1) defined in the SMI (RFC 1442 [2]). In particular, each object type is named by an OBJECT IDENTIFIER, an administratively assigned name. The object type together with an object instance serves to uniquely identify a specific instantiation of the object. For human convenience, we often use a textual string, termed the descriptor, to refer to the object type. Kielczewski, Kostick & Shih [Page 2] RFC 1666 SNANAU MIB August 1994 3. Overview This document identifies the proposed set of objects for managing the configuration, monitoring and control of Physical Units (PUs) and Logical Units (LUs) in an SNA environment. In this document, the name "Node" is used to describe SNA Node Type 1.0, 2.0 and Type 2.1 and the name "LU" is used to describe Logical Unit of Type 0, 1, 2, 3, 4, 7 and 6.2. Note however that only objects common to all PU and LU types are covered here and LU 6.2 specific objects are not included in this MIB module. Highlights of the management functions supported by the SNANAU MIB module include the following: o Creation/deletion of Nodes and LUs via the RowStatus objects in the snaNodeAdminTable and in the snaLuAdminTable. o Creation/deletion of table entries associating Node instances with link instances via the RowStatus object in the snaNodeLinkAdminTable o Activation/Deactivation of Nodes via the AdminState object in the snaNodeAdminTable o Deactivation of sessions via the AdminState object in the snaLuSessnTable o Monitoring and modification of parameters related to Nodes, LUs, and Node/link associations o Monitoring of session operational parameters o PU2.0 operational statistics o Session operational statistics o RTM statistics o Traps for: + Node state change + Node activation failure + LU state change + LU session BIND failure Kielczewski, Kostick & Shih [Page 3] RFC 1666 SNANAU MIB August 1994 This MIB module does not support: o creation of links, o activation or deactivation of LUs, nor o activation of sessions. 3.1. Applying MIB II to managing SNA NAUs This section identifies how MIB II objects, specifically the MIB II system group will be used in SNMP-based management of SNA NAUs. The MIB II system group applies to the SNMP Agent. The following object is from the MIB II system group: sysUpTime: clock in the SNMP Agent/proxy-Agent; expressed in TimeTicks (1/100s of a seconds). This MIB module uses the TimeStamp TEXTUAL-CONVENTION which is defined in the SNMPv2 Textual Conventions (RFC 1443 [6]) as "the value of MIB II's sysUpTime object when a specific occurrence happens." The specific occurrences related to SNA NAU management are defined in this MIB module. 3.2. SNANAU MIB Structure The SNANAU MIB module contains three groups of objects: o snaNode - objects related to Node configuration, monitoring and control. o snaLu - objects related to LU definition, monitoring and control. o snaMgtTools - objects related to specific management tools well known in SNA environment. These groups are described below in more detail. The objects related to PUs and LUs are organized into two types of tables: the Admin and Oper tables. The "Admin" table contains parameters which are used by a Management Station to affect the operation of the SNA service. Some parameters are used to initialize and configure the SNA service at the next startup, while others can take effect immediately. A Management Station can dynamically define SNA resources (PUs, LUs) by creating new entries in the Admin table. It uses a special object, AdminState, Kielczewski, Kostick & Shih [Page 4] RFC 1666 SNANAU MIB August 1994 to control the desired state of a defined PU or LU Session resource. Note that this MIB does not allow the manipulation of an LU's operational state. The "Oper" table is an extension (augment) of the corresponding Admin table. It contains objects which correspond to the values of parameters currently used by the SNA system. 3.2.1. snaNode group The snaNode group consists of the following tables: 1) snaNodeAdminTable - This table contains objects which describe the configuration parameters of an SNA Node. Link-specific configuration objects are contained in a separate MIB module (e.g., the SNA DLC MIB module) corresponding to link type. Entries in this table can be created, modified and deleted by either an Agent or a Management Station. The snaNodeAdminRowStatus object describes the status of an entry and is used to change the status of that entry. The snaNodeAdminState object describes the desired operational state of a Node and is used to change the operational state of a Node. How an Agent or a Management Station obtains the initial value of each object at creation time is an implementation specific issue not addressed in this memo. For each entry in the snaNodeAdminTable, there is a corresponding entry in the snaNodeOperTable. While the objects in this table describe the desired or configured operational values of the SNA Node, the actual runtime values are contained in snaNodeOperTable. 2) snaNodeOperTable - Each row contains runtime and operational state variables for a Node. It is an extension of snaNodeAdminTable and as such uses the same index. The rows in this table are created by an Agent as soon as the entry in the Admin Table become 'active'. The entries in this table cannot be modified by a Management Station. 3) snaPu20StatsTable - Each row contains statistics variables (counters) for a PU 2.0. The entries in this table are indexed by snaNodeAdminIndex. The rows in this table are created by an Agent as soon as the corresponding entry in the snaNodeAdminTable becomes 'active'. Kielczewski, Kostick & Shih [Page 5] RFC 1666 SNANAU MIB August 1994 4) snaNodeLinkAdminTable - This table contains all references to link- specific tables. If a Node is configured with multiple links, then it will have multiple entries in this table. The entries in this table can be generated initially, after startup of SNA service, by the Agent which uses information from Node configuration file. Subsequent modifications of parameters, creation of new Node link entries and deletion of entries is possible. The modifications to this table can be saved in the Node configuration file for the next startup (i.e., restart or next initialization) of SNA service, but the mechanism for this function is not defined in this memo. Each entry contains the configuration information that associates a Node instance to one link instance. The entries are indexed by snaNodeAdminIndex and snaNodeLinkAdminIndex. 5) snaNodeLinkOperTable - This table contains all references to link- specific tables for operational parameters. If the Node is configured for multiple links, then it will have multiple entries in this table. This table augments the snaNodeLinkAdminTable. 6) snaNodeTraps - Two traps are defined for Nodes. The snaNodeStateChangeTrap indicates that the operational state of a Node has changed. The snaNodeActFailTrap indicates the failure of ACTPU received from host. 3.2.2. snaLu group The snaLu group consists of the following tables: 1) snaLuAdminTable - Table containing LU configuration information. The rows in this table can be created and deleted by a Management Station. Only objects which are common to all types of LUs are included in this table. The entries are indexed by Node and LU indices. 2) snaLuOperTable - Table containing dynamic runtime information and control variables relating to LUs. Only objects which are common to all types of LUs are included in this table. This table augments the snaLuAdminTable. 3) snaLuSessnTable - This is a table containing objects which describe the operational state of LU-LU sessions. Only objects which are common to all types of LU-LU sessions are included in this table. When a session's snaLuSessnOperState value changes to entry in the session table is created by the Agent. When the snaLuSessionOperState value changes to will be removed from the session table by the Agent. Entries are indexed by Node, local LU, remote LU and session indices. Kielczewski, Kostick & Shih [Page 6] RFC 1666 SNANAU MIB August 1994 4) snaLuSessnStatsTable - Table containing dynamic statistics information relating to LU-LU sessions. The entries in this table augment the entries in the snaLuSessnTable and cannot be created by a Management Station. 5) snaLuTraps - Two traps are defined for LUs. The snaLuStateChangeTrap indicates that the operational state of an LU has changed. The snaLuSessnBindFailTrap indicates the failure of a BIND request. 3.2.3. snaMgtTools group This is an optional group. The snaMgtTools group consists of the following table: 1) snaLuRtmTable - Each row contains Response Time Monitor (RTM) variables for an LU. The table is indexed by Node and LU indices. Entries correspond to LU 2 entries in the snaLuAdminTable. A Management Station can read collection of RTM statistics for a given LU. 3.2.4. Conformance statement Compliance of the SNMPv2 management entity to the SNANAU MIB is defined in terms of following conformance units called groups. Unconditionally mandatory groups: snaNodeGroup, snaLuGroup, snaSessionGroup. Conditionally mandatory groups: snaPu20Group - mandatory only for those entities which implement PU type 2.0. The snaMgtToolsRtmGroup - mandatory only for those entities which implement LU type 2 and RTM. Refinement of requirements for objects access: an Agent which does not implement row creation for snaNodeAdminTable snaNodeLinkAdminTable and snaLuAdminTable must at least support object modification requests (i.e., read-write access instead of read-create). 3.3. SNANAU MIB special feature This section describes the mechanism used for row creation in the Admin tables and also presents critical state transitions for PUs, LUs and Sessions. Kielczewski, Kostick & Shih [Page 7] RFC 1666 SNANAU MIB August 1994 3.3.1. Row Creation mechanism The row creation mechanism for the Admin tables in this MIB module is based on the use of the RowStatus object. Restriction of some operations for specific tables are described in each table. In particular, before accepting the 'destroy' value for an entry, an Agent has to verify the operational state of the corresponding entry in the Oper table. 3.3.2. State Diagrams The following state diagram models the state transitions for Nodes. When a row is created by a Management Station, an Agent creates the Oper table entry for that Node with the OperState equal to 'inactive'. An Agent cannot accept any operations for that Node until the RowStatus is set to 'active'. OperState -> inactive active waiting stopping --------------I--------------I--------------I--------------I--------- AdminState: I I I I active I active I active I waiting I no I I I I inactive I inactive I stopping I inactive I stopping I or inactive I The following state diagram models state transitions for Sessions. When a session goes to the 'unbound' state [1], the corresponding entry will be removed from the Session table by the Agent. OperState -> unbound pendingBind bound pendingUnbind --------------I--------------I--------------I----------I-------------- AdminState: I I I I bound I no I no I no I no I I I I unbound I unbound I unbound I unbound I unbound Kielczewski, Kostick & Shih [Page 8] RFC 1666 SNANAU MIB August 1994 4. Object Definitions SNA-NAU-MIB DEFINITIONS ::= BEGIN -- This MIB module contains objects necessary -- for management of the following SNA devices: PU types 1.0, 2.0, 2.1 -- and LU types 0, 1, 2, 3, 4, 7. It also contains generic objects -- which can be used to manage LU 6.2. -- Naming conventions in this document: -- The following names are used in object descriptors according to -- SNA conventions. -- The name 'PU' or 'Node' is used to describe Node type 1.0, 2.0 or -- 2.1. -- The name 'LU' is used to describe Logical Unit of type 0,1,2,3, -- 4,7 or 6.2. IMPORTS DisplayString, RowStatus, TimeStamp, InstancePointer FROM SNMPv2-TC Counter32, Gauge32, Integer32, OBJECT-TYPE, MODULE-IDENTITY, NOTIFICATION-TYPE FROM SNMPv2-SMI MODULE-COMPLIANCE, OBJECT-GROUP FROM SNMPv2-CONF; snanauMIB MODULE-IDENTITY LAST-UPDATED "9405120900Z" ORGANIZATION "IETF SNA NAU MIB Working Group" CONTACT-INFO " Zbigniew Kielczewski Eicon Technology Inc. 2196 32nd Avenue Lachine, Que H8T 3H7 Canada Tel: 1 514 631 2592 E-mail: zbig@eicon.qc.ca Deirdre Kostick Bellcore 331 Newman Springs Road Red Bank, NJ 07701 Tel: 1 908 758 2642 Kielczewski, Kostick & Shih [Page 9] RFC 1666 SNANAU MIB August 1994 E-mail: dck2@mail.bellcore.com Kitty Shih (editor) Novell 890 Ross Drive Sunnyvale, CA 94089 Tel: 1 408 747 4305 E-mail: kmshih@novell.com" DESCRIPTION "This is the MIB module for objects used to manage SNA devices." ::= { mib-2 34 } -- The SNANAU MIB module contains an objects part and a conformance part. -- Objects are organized into the following groups: -- (1)snaNode group, -- (2)snaLU group, -- (3)snaMgtTools group. snanauObjects OBJECT IDENTIFIER ::= { snanauMIB 1 } snaNode OBJECT IDENTIFIER ::= { snanauObjects 1 } snaLu OBJECT IDENTIFIER ::= { snanauObjects 2 } snaMgtTools OBJECT IDENTIFIER ::= { snanauObjects 3} -- *************************************************************** -- snaNode group -- -- It contains Managed Objects related to any type of Node and -- some specific objects for Node Type 2.0. -- *************************************************************** -- *************************************************************** -- The following table contains generic Node configuration -- parameters. -- *************************************************************** snaNodeAdminTable OBJECT-TYPE SYNTAX SEQUENCE OF SnaNodeAdminEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table contains objects which describe the configuration parameters for an SNA Node. Link specific configuration objects are contained in a separate MIB module (e.g., SNA DLC MIB) Kielczewski, Kostick & Shih [Page 10] RFC 1666 SNANAU MIB August 1994 corresponding to the link type. The table snaNodeAdminLinkTable contains objects which identify the relationship between node instances and link instances. The entries (i.e., rows) in this table can be created by either an Agent or a Management Station. The Management Station can do this through setting the appropriate value in the snaNodeAdminRowStatus. The snaNodeAdminRowStatus object describes the status of an entry and is used to change the status of an entry. The entry is deleted by an Agent based on the value of the snaNodeAdminRowStatus. The snaNodeAdminState object describes the desired operational state of a Node and is used to change the operational state of a Node. For example, such information may be obtained from a configuration file. How an Agent or a Management Station obtains the initial value of each object at creation time is an implementation specific issue. For each entry in this table, there is a corresponding entry in the snaNodeOperTable. While the objects in this table describe the desired or configured operational values of the SNA Node, the actual runtime values are contained in snaNodeOperTable." ::= { snaNode 1 } snaNodeAdminEntry OBJECT-TYPE SYNTAX SnaNodeAdminEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry contains the configuration parameters for one SNA Node instance. The objects in the entry have read-create access. An entry can be created, modified or deleted. The object snaNodeAdminRowStatus is used (i.e., set) to create or delete a row entry." INDEX { snaNodeAdminIndex } ::= { snaNodeAdminTable 1 } SnaNodeAdminEntry ::= SEQUENCE { snaNodeAdminIndex Kielczewski, Kostick & Shih [Page 11] RFC 1666 SNANAU MIB August 1994 Integer32, snaNodeAdminName DisplayString, snaNodeAdminType INTEGER, snaNodeAdminXidFormat INTEGER, snaNodeAdminBlockNum DisplayString, snaNodeAdminIdNum DisplayString, snaNodeAdminEnablingMethod INTEGER, snaNodeAdminLuTermDefault INTEGER, snaNodeAdminMaxLu Integer32, snaNodeAdminHostDescription DisplayString, snaNodeAdminStopMethod INTEGER, snaNodeAdminState INTEGER, snaNodeAdminRowStatus RowStatus } snaNodeAdminIndex OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS not-accessible STATUS current DESCRIPTION "Index used to uniquely identify each Node instance. If an Agent creates the entry, then it will assign this number otherwise a Management Station generates a random number when it reserves the entry for creation." ::= { snaNodeAdminEntry 1 } snaNodeAdminName OBJECT-TYPE SYNTAX DisplayString (SIZE(0..17)) MAX-ACCESS read-create STATUS current DESCRIPTION "The value indicates the desired name of the Node for use during Node activation. In Type 2.1 networks, this is a fully-qualified name, meaning that the Node name is preceded by the NetId (if Kielczewski, Kostick & Shih [Page 12] RFC 1666 SNANAU MIB August 1994 present) with a period as the delimiter. A write operation to this object will not change the operational value reflected in snaNodeOperName until the Node has been re-activated (e.g., after the next initialization of the SNA services)." ::= { snaNodeAdminEntry 2 } snaNodeAdminType OBJECT-TYPE SYNTAX INTEGER { other(1), pu10(2), pu20(3), t21len(4), endNode(5), networkNode(6) } MAX-ACCESS read-create STATUS current DESCRIPTION "The value indicates the type of SNA Node. A write operation to this object will not change the operational value reflected in snaNodeOperType until the Node has been re-activated (e.g., after the next initialization of the SNA services)." ::= { snaNodeAdminEntry 3 } snaNodeAdminXidFormat OBJECT-TYPE SYNTAX INTEGER { format0(1), format1(2), format3(3) } MAX-ACCESS read-create STATUS current DESCRIPTION "The value indicates the type of XID format used for this Node. Note that there is no format type 2. A write operation to this object will not change the operational value reflected in snaNodeOperAdminXidFormat until the Node has been re-activated (e.g., after the next initialization of the SNA services)." ::= { snaNodeAdminEntry 4 } Kielczewski, Kostick & Shih [Page 13] RFC 1666 SNANAU MIB August 1994 snaNodeAdminBlockNum OBJECT-TYPE SYNTAX DisplayString (SIZE(3)) MAX-ACCESS read-create STATUS current DESCRIPTION "The value indicates the block number for this Node instance. It is the first 3 hexadecimal digits of the SNA Node id. A write operation to this object will not change the operational value reflected in snaNodeOperBlockNum until the Node has been re-activated (e.g., after the next initialization of the SNA services)." ::= { snaNodeAdminEntry 5 } snaNodeAdminIdNum OBJECT-TYPE SYNTAX DisplayString (SIZE(5)) MAX-ACCESS read-create STATUS current DESCRIPTION "The value indicates the ID number for this Node instance. This is the last 5 hexadecimal digits of the SNA Node id. A write operation to this object will not change the operational value reflected in snaNodeOperIdNum until the Node has been re-activated (e.g., after the next initialization of the SNA services)." ::= { snaNodeAdminEntry 6 } snaNodeAdminEnablingMethod OBJECT-TYPE SYNTAX INTEGER { other (1), startup (2), demand (3), onlyMS (4) } MAX-ACCESS read-create STATUS current DESCRIPTION "The value indicates how the Node should be activated for the first time. The values have the following meanings: other (1) - may be used for proprietary methods not listed in this enumeration, Kielczewski, Kostick & Shih [Page 14] RFC 1666 SNANAU MIB August 1994 startup (2) - at SNA services' initialization time (this is the default), demand (3) - only when LU is requested by application, or onlyMS (4) - by a Management Station only. A write operation to this object may immediately change the operational value reflected in snaNodeOperEnablingMethod depending on the Agent implementation. If the Agent implementation accepts immediate changes, then the behavior of the Node changes immediately and not only after the next system startup of the SNA services. An immediate change may only apply when the current value 'demand (3)' is changed to 'onlyMS (4)' and vice versa." ::= { snaNodeAdminEntry 7 } snaNodeAdminLuTermDefault OBJECT-TYPE SYNTAX INTEGER { unbind (1), termself (2), rshutd (3), poweroff(4) } MAX-ACCESS read-create STATUS current DESCRIPTION "The value indicates the desired default method used to deactivate LUs for this Node For LU6.2s, 'unbind(1)' is the only valid value. unbind(1) - terminate the LU-LU session by sending an SNA UNBIND request. termself(2) - terminate the LU-LU session by sending an SNA TERM-SELF (Terminate Self) request on the SSCP-LU session. The SSCP will inform the remote session LU partner to send an UNBIND request to terminate the session. rshutd(3) - terminate the LU-LU session by sending an SNA RSHUTD (Request ShutDown) request to the remote session LU partner. The remote LU will then send an UNBIND request to terminate the session. poweroff(4) - terminate the LU-LU session by sending either an SNA LUSTAT (LU Status) request on the LU-LU session or an SNA NOTIFY request on the SSCP-LU session indicating that the LU has Kielczewski, Kostick & Shih [Page 15] RFC 1666 SNANAU MIB August 1994 been powered off. Sending both is also acceptable. The result should be that the remote session LU partner will send an UNBIND to terminate the session. The default behavior indicated by the value of this object may be overridden for an LU instance. The override is performed by setting the snaLuAdminTerm object instance in the snaLuAdminTable to the desired value. A write operation to this object may immediately change the operational value reflected in snaNodeOperLuTermDefault depending on the Agent implementation." ::= { snaNodeAdminEntry 8 } snaNodeAdminMaxLu OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-create STATUS current DESCRIPTION "The maximum number of LUs that may be activated for this Node. For PU2.1, this object refers to the number of dependent LUs. A write operation to this object will not change the operational value reflected in snaNodeOperMaxLu until the Node has been re-activated (e.g., after the next initialization of the SNA services)." ::= { snaNodeAdminEntry 9 } snaNodeAdminHostDescription OBJECT-TYPE SYNTAX DisplayString (SIZE(0..128)) MAX-ACCESS read-create STATUS current DESCRIPTION "The value identifies the remote host associated with this Node. Since SSCP Id's may not be unique across hosts, the host description is required to uniquely identify the SSCP. This object is only applicable to PU2.0 type Nodes. If the remote host is unknown, then the value is the null string. A write operation to this object may immediately Kielczewski, Kostick & Shih [Page 16] RFC 1666 SNANAU MIB August 1994 change the operational value reflected in snaNodeOperHostDescription depending on the Agent implementation." ::= { snaNodeAdminEntry 10 } snaNodeAdminStopMethod OBJECT-TYPE SYNTAX INTEGER { other (1), normal (2), immed (3), force (4) } MAX-ACCESS read-create STATUS current DESCRIPTION "The value indicates the desired method to be used by the Agent to stop a Node (i.e., change the Node's operational state to inactive(1) ). The values have the following meaning: other (1) - used for proprietary methods not listed in this enumeration. normal(2) - deactivate only when there is no more activity on this Node (i.e., all data flows have been completed and all sessions have been terminated). immed(3) - deactivate immediately regardless of current activities on this Node. Wait for deactivation responses (from remote Node) before changing the Node state to inactive. force(4) - deactivate immediately regardless of current activities on this Node. Do not wait for deactivation responses (from remote Node) before changing the Node state to inactive. A write operation to this object may immediately change the operational value reflected in snaNodeOperStopMethod depending on the Agent implementation." ::= { snaNodeAdminEntry 11 } snaNodeAdminState OBJECT-TYPE SYNTAX INTEGER { inactive (1), active (2) } MAX-ACCESS read-create Kielczewski, Kostick & Shih [Page 17] RFC 1666 SNANAU MIB August 1994 STATUS current DESCRIPTION "The value indicates the desired operational state of the SNA Node. This object is used by the Management Station to activate or deactivate the Node. If the current value in snaNodeOperState is 'active (2)', then setting this object to 'inactive (1)' will initiate the Node shutdown process using the method indicated by snaNodeOperStopMethod. If the current value in snaNodeOperState is 'inactive (1)', then setting this object to 'active (2)' will initiate the Node's activation. A Management Station can always set this object to 'active (2)' irrespective of the value in the snaOperEnablingMethod." ::= { snaNodeAdminEntry 12 } snaNodeAdminRowStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object is used by a Management Station to create or delete the row entry in the snaNodeAdminTable following the RowStatus textual convention. Upon successful creation of the row, an Agent automatically creates a corresponding entry in the snaNodeOperTable with snaNodeOperState equal to 'inactive (1)'. Row deletion can be Management Station or Agent initiated: (a) The Management Station can set the value to 'destroy (6)' only when the value of snaNodeOperState of this Node instance is 'inactive (1)'. The Agent will then delete the rows corresponding to this Node instance from the snaNodeAdminTable and the snaNodeOperTable. (b) The Agent detects that a row is in the 'notReady (3)' state for greater than a Kielczewski, Kostick & Shih [Page 18] RFC 1666 SNANAU MIB August 1994 default period of 5 minutes. (c) All rows with the snaNodeAdminRowStatus object's value of 'notReady (3)' will be removed upon the next initialization of the SNA services." ::= { snaNodeAdminEntry 13 } -- *************************************************************** -- The following object is updated when there is a change to -- the value of any object in the snaNodeAdminTable. -- *************************************************************** snaNodeAdminTableLastChange OBJECT-TYPE SYNTAX TimeStamp MAX-ACCESS read-only STATUS current DESCRIPTION "The value indicates the timestamp (e.g., the Agent's sysUpTime value) of the last change made to any object in the snaNodeAdminTable, including row deletions/additions (e.g., changes to snaNodeAdminRowStatus values). This object can be used to reduce frequent retrievals of the snaNodeAdminTable by a Management Station. It is expected that a Management Station will periodically poll this object and compare its current value with the previous one. A difference indicates that some Node configuration information has been changed. Only then will the Management Station retrieve the entire table." ::= { snaNode 2 } -- *************************************************************** -- The following table contains Node operational parameters. -- *************************************************************** snaNodeOperTable OBJECT-TYPE SYNTAX SEQUENCE OF SnaNodeOperEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table contains the dynamic parameters which have read-only access. These objects reflect the actual status of the Node. The entries in this table cannot be created or modified by a Management Station. Kielczewski, Kostick & Shih [Page 19] RFC 1666 SNANAU MIB August 1994 This table augments the snaNodeAdminTable." ::= { snaNode 3 } snaNodeOperEntry OBJECT-TYPE SYNTAX SnaNodeOperEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "The entry contains parameters which describe the state of one Node. The entries are created by the Agent. They have read-only access." AUGMENTS { snaNodeAdminEntry } ::= { snaNodeOperTable 1 } SnaNodeOperEntry ::= SEQUENCE { snaNodeOperName DisplayString, snaNodeOperType INTEGER, snaNodeOperXidFormat INTEGER, snaNodeOperBlockNum DisplayString, snaNodeOperIdNum DisplayString, snaNodeOperEnablingMethod INTEGER, snaNodeOperLuTermDefault INTEGER, snaNodeOperMaxLu Integer32, snaNodeOperHostDescription DisplayString, snaNodeOperStopMethod INTEGER, snaNodeOperState INTEGER, snaNodeOperHostSscpId OCTET STRING, snaNodeOperStartTime TimeStamp, snaNodeOperLastStateChange TimeStamp, snaNodeOperActFailures Counter32, snaNodeOperActFailureReason INTEGER } Kielczewski, Kostick & Shih [Page 20] RFC 1666 SNANAU MIB August 1994 snaNodeOperName OBJECT-TYPE SYNTAX DisplayString (SIZE(0..17)) MAX-ACCESS read-only STATUS current DESCRIPTION "The value identifies the current name of the Node. In Type 2.1 networks, this is a fully-qualified name, meaning that the Node name is preceded by the NetId (if present) with a period as the delimiter." ::= { snaNodeOperEntry 1 } snaNodeOperType OBJECT-TYPE SYNTAX INTEGER { other(1), pu10(2), pu20(3), t21LEN(4), endNode(5), networkNode(6) } MAX-ACCESS read-only STATUS current DESCRIPTION "The value identifies the current type of the Node." ::= { snaNodeOperEntry 2 } snaNodeOperXidFormat OBJECT-TYPE SYNTAX INTEGER { format0 (1), format1 (2), format3 (3) } MAX-ACCESS read-only STATUS current DESCRIPTION "The value identifies the type of XID format currently used for this Node. Note that there is no format type 2." ::= { snaNodeOperEntry 3 } snaNodeOperBlockNum OBJECT-TYPE SYNTAX DisplayString (SIZE(3)) MAX-ACCESS read-only STATUS current DESCRIPTION "The value identifies the block number for this Node instance. It is the first 3 hexadecimal digits Kielczewski, Kostick & Shih [Page 21] RFC 1666 SNANAU MIB August 1994 of the SNA Node id." ::= { snaNodeOperEntry 4 } snaNodeOperIdNum OBJECT-TYPE SYNTAX DisplayString (SIZE(5)) MAX-ACCESS read-only STATUS current DESCRIPTION "The value identifies the ID number for this Node instance. This is the last 5 hexadecimal digits of the SNA Node id." ::= { snaNodeOperEntry 5 } snaNodeOperEnablingMethod OBJECT-TYPE SYNTAX INTEGER { other (1), startup (2), demand (3), onlyMS (4) } MAX-ACCESS read-only STATUS current DESCRIPTION "The value indicates how the Node is activated for the first time. The values have the following meanings: other (1) - not at boot time, LU activation or by a Management Station; startup (2) - at SNA services' initialization time (this is the default), demand (3) - only when LU is requested by application, onlyMS (4) - by a network Management Station only." ::= { snaNodeOperEntry 6 } snaNodeOperLuTermDefault OBJECT-TYPE SYNTAX INTEGER { unbind (1), termself (2), rshutd (3), poweroff (4) } MAX-ACCESS read-only STATUS current DESCRIPTION "The value identifies the default method used to deactivate LUs for this Node. Kielczewski, Kostick & Shih [Page 22] RFC 1666 SNANAU MIB August 1994 For LU6.2s, 'unbind(1)' is the only valid value. unbind(1) - terminate the LU-LU session by sending an SNA UNBIND request. termself(2) - terminate the LU-LU session by sending an SNA TERM-SELF (Terminate Self) request on the SSCP-LU session. The SSCP will inform the remote session LU partner to send an UNBIND request to terminate the session. rshutd(3) - terminate the LU-LU session by sending an SNA RSHUTD (Request ShutDown) request to the remote session LU partner. The remote LU will then send an UNBIND request to terminate the session. poweroff(4) - terminate the LU-LU session by sending either an SNA LUSTAT (LU Status) request on the LU-LU session or an SNA NOTIFY request on the SSCP-LU session indicating that the LU has been powered off. Sending both is also acceptable. The result should be that the remote session LU partner will send an UNBIND to terminate the session. This object describes the default behavior for this Node; however, it is possible that for a specific LU the behavior indicated by the snaLuOperTerm object is different." ::= { snaNodeOperEntry 7 } snaNodeOperMaxLu OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-only STATUS current DESCRIPTION "This value identifies the current, maximum number of LUs that are activated for this Node. For PU2.1, this object refers to the number of dependent LUs." ::= { snaNodeOperEntry 8 } snaNodeOperHostDescription OBJECT-TYPE SYNTAX DisplayString (SIZE(0..128)) MAX-ACCESS read-only STATUS current DESCRIPTION "This value identifies the remote host currently associated with this Node. Since SSCP Id's may not be unique across hosts, the host description Kielczewski, Kostick & Shih [Page 23] RFC 1666 SNANAU MIB August 1994 is required to uniquely identify the SSCP." ::= { snaNodeOperEntry 9 } snaNodeOperStopMethod OBJECT-TYPE SYNTAX INTEGER { other (1), normal (2), immed (3),