RFC1286 - Definitions of Managed Objects for Bridges

Network Working Group E. Decker

Request for Comments: 1286 cisco Systems, Inc.

P. Langille

Digital Equipment Corporation

A. Rijsinghani

Digital Equipment Corporation

K. McCloghrie

Hughes LAN Systems, Inc.

December 1991

Definitions of Managed Objects for Bridges

Status of this Memo

This memo is an extension to the SNMP MIB. This RFCspecifies an IAB

standards track protocol for the Internet community, and requests

discussion and suggestions for improvements. Please refer to the

current edition of the "IAB Official Protocol Standards" for the

standardization state and status of this protocol. Distribution of

this memo is unlimited.

Table of Contents

1. Abstract ............................................. 2

2. The Network Management Framework...................... 2

3. Objects .............................................. 2

3.1 Format of Definitions ............................... 3

4. Overview ............................................. 3

4.1 StrUCture of MIB .................................... 4

4.1.1 The dot1dBase Group ............................... 7

4.1.2 The dot1dStp Group ................................ 7

4.1.3 The dot1dSr Group ................................. 7

4.1.4 The dot1dTp Group ................................. 7

4.1.5 The dot1dStatic Group ............................. 7

4.2 Relationship to Other MIBs .......................... 7

4.2.1 Relationship to the 'system' group ................ 8

4.2.2 Relationship to the 'interfaces' group ............ 8

4.3 Textual Conventions ................................. 9

5. Definitions .......................................... 9

5.1 Groups in the Bridge MIB ............................ 11

5.2 The dot1dBase Group Definitions ..................... 11

5.3 The dot1dStp Group Definitions ...................... 14

5.4 The dot1dSr Group Definitions ....................... 22

5.5 The dot1dTp Group Definitions ....................... 28

5.6 The dot1dStatic Group Definitions ................... 34

5.8 Traps for use by Bridges ............................ 36

6. Acknowledgments ...................................... 37

7. References ........................................... 38

8. Security Considerations............................... 39

9. Authors' Addresses.................................... 40

1. Abstract

This memo defines a portion of the Management Information Base (MIB)

for use with network management protocols in TCP/IP based internets.

In particular it defines objects for managing bridges based on the

IEEE 802.1d draft standard between Local Area Network (LAN) segments.

Provisions are made for support of transparent and source route

bridging. Provisions are also made so that these objects apply to

bridges connected by subnetworks other than LAN segments.

2. The Network Management Framework

The Internet-standard Network Management Framework consists of three

components. They are:

RFC1155 which defines the SMI, the mechanisms used for describing

and naming objects for the purpose of management. RFC1212

defines a more concise description mechanism, which is wholly

consistent with the SMI.

RFC1156 which defines MIB-I, the core set of managed objects for

the Internet suite of protocols. RFC1213, defines MIB-II, an

evolution of MIB-I based on implementation eXPerience and new

operational requirements.

RFC1157 which defines the SNMP, the protocol used for network

Access to managed objects.

The Framework permits new objects to be defined for the purpose of

experimentation and evaluation.

3. Objects

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) [7]

defined in the SMI. In particular, each object has a name, a syntax,

and an encoding. The name is an object identifier, an

administratively assigned name, which specifies an object type. 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 OBJECT

DESCRIPTOR, to also refer to the object type.

The syntax of an object type defines the abstract data structure

corresponding to that object type. The ASN.1 language is used for

this purpose. However, the SMI [3] purposely restricts the ASN.1

constructs which may be used. These restrictions are explicitly made

for simplicity.

The encoding of an object type is simply how that object type is

represented using the object type's syntax. Implicitly tied to the

notion of an object type's syntax and encoding is how the object type

is represented when being transmitted on the network.

The SMI specifies the use of the basic encoding rules of ASN.1 [8],

subject to the additional requirements imposed by the SNMP.

3.1. Format of Definitions

Section 5 contains the specification of all object types contained in

this MIB module. The object types are defined using the conventions

defined in the SMI, as amended by the extensions specified in [9,10].

4. Overview

A common device present in many networks is the Bridge. This device

is used to connect Local Area Network segments below the network

layer. There are two major modes defined for this bridging;

transparent and source route. The transparent method of bridging is

defined in the draft IEEE 802.1d specification [11]. Source route

bridging has been defined by I.B.M. and is described in the Token

Ring Architecture Reference [12]. IEEE 802.1d is currently working

on combining the source route and transparent techniques in a

compatible fashion. This memo defines those objects needed for the

management of a bridging entity operating in one of these modes.

To be consistent with IAB directives and good engineering practice,

an explicit attempt was made to keep this MIB as simple as possible.

This was accomplished by applying the following criteria to objects

proposed for inclusion:

(1) Start with a small set of essential objects and add only

as further objects are needed.

(2) Require objects be essential for either fault or

configuration management.

(3) Consider evidence of current use and/or utility.

(4) Limit the total of objects.

(5) Exclude objects which are simply derivable from others in

this or other MIBs.

(6) Avoid causing critical sections to be heavily

instrumented. The guideline that was followed is one

counter per critical section per layer.

4.1. Structure of MIB

Objects in this MIB are arranged into groups. Each group is

organized as a set of related objects. The overall structure and

assignment of objects to their groups is shown below. Where

appropriate the corresponding IEEE 802.1d [11] management object name

is also included.

Bridge MIB Name IEEE 802.1d Name

dot1dBridge

dot1dBase

BridgeAddress Bridge.BridgeAddress

NumPorts Bridge.NumberOfPorts

Type

PortTable

Port BridgePort.PortNumber

IfIndex

Circuit

DelayExceededDiscards .DiscardTransitDelay

MtuExceededDiscards .DiscardOnError

dot1dStp

ProtocolSpecification

Priority SpanningTreeProtocol

.BridgePriority

TimeSinceTopologyChange .TimeSinceTopologyChange

TopChanges .TopologyChangeCount

DesignatedRoot .DesignatedRoot

RootCost .RootCost

RootPort .RootPort

MaxAge .MaxAge

HelloTime .HelloTime

HoldTime .HoldTime

ForwardDelay .ForwardDelay

BridgeMaxAge .BridgeMaxAge

BridgeHelloTime .BridgeHelloTime

BridgeForwardDelay .BridgeForwardDelay

PortTable

Port SpanningTreeProtocolPort

.PortNumber

Priority .PortPriority

State .SpanningTreeState

Enable

PathCost .PortPathCost

DesignatedRoot .DesignatedRoot

DesignatedCost .DesignatedCost

DesignatedBridge .DesignatedBridge

DesignatedPort .DesignatedPort

ForwardTransitions

dot1dSr

PortTable

Port

HopCount SourceRoutingPort

.PortHopCount

LocalSegment .SegmentNumber

BridgeNum .BridgeNumber

TargetSegment

LargestFrame .LargestFrameSize

STESpanMode .LimitedBroadcastMode

SpecInFrames BridgePort

.ValidSRFramesReceived

SpecOutFrames .ValidSRForwardedOutbound

ApeInFrames

ApeOutFrames .BroadcastFramesForwarded

SteInFrames

SteOutFrames .BroadcastFramesForwarded

SegmentMismatchDiscards .DiscardInvalidRI

DuplicateSegmentDiscards .LanIdMismatch

HopCountExceededDiscards .FramesDiscardedHopCountExceeded

dot1dTp

LearnedEntryDiscards BridgeFilter.DatabaseSize

.NumDynamic,NumStatic

AgingTime BridgeFilter.AgingTime

FdBTable

Address

Status

Port

PortTable

Port

MaxInfo

InFrames BridgePort.FramesReceived

OutFrames .ForwardOutbound

InDiscards .DiscardInbound

dot1dStatic

StaticTable

Address

ReceivePort

AllowedToGoTo

Status

The following IEEE 802.1d management objects have not been included

in the Bridge MIB for the indicated reasons.

IEEE 802.1d Object Disposition

Bridge.BridgeName Same as sysDescr (MIB II)

Bridge.BridgeUpTime Same as sysUpTime (MIB II)

Bridge.PortAddresses Same as ifPhysAddress (MIB II)

BridgePort.PortName Same as ifDescr (MIB II)

BridgePort.PortType Same as ifType (MIB II)

BridgePort.RoutingType Derivable from the implemented

groups

SpanningTreeProtocol

.BridgeIdentifier Combination of dot1dStpPriority

and dot1dBaseBridgeAddress

.TopologyChange Since this is transitory, it

is not considered useful.

SpanningTreeProtocolPort

.Uptime Same as ifLastChange (MIB II)

.PortIdentifier Combination of dot1dStpPortNum

and dot1dStpPortPriority

.TopologyChangeAcknowledged Since this is transitory, it

is not considered useful.

.DiscardLacKOFBuffers Redundant

Transmission Priority These objects are not required

as per the Pics Proforma and

not considered useful.

.TransmissionPriorityName

.OutboundUserPriority

.OutboundAccessPriority

SourceRoutingPort The Source Routing Supplement,

at the time of this writing,

is not stable. The following

objects were NOT included in

this MIB because they are

redundant or not considered

useful.

.LimitedBroadcastEnable

BridgePort.DupLanIdOrTreeError

.DiscardLackOfBuffers

.DiscardErrorDetails

.DiscardTargetLANInoperable

.ValidSRDiscardedInbound

.BroadcastBytesForwarded

.NonBroadcastBytesForwarded

.FramesNotReceivedDueToCongestion

.FramesDiscardedDueToInternalError

4.1.1. The dot1dBase Group

This mandatory group contains the objects which are applicable to all

types of bridges.

4.1.2. The dot1dStp Group

This group contains the objects that denote the bridge's state with

respect to the Spanning Tree Protocol. If a node does not

implemented the Spanning Tree Protocol, this group will not be

implemented. This group is applicable to any transparent only,

source route, or SRT bridge which implements the Spanning Tree

Protocol.

4.1.3. The dot1dSr Group

This group contains the objects that describe the entity's state with

respect to source route bridging. If source routing is not supported

this group will not be implemented. This group is applicable to

source route only, and SRT bridges.

4.1.4. The dot1dTp Group

This group contains objects that describe the entity's state with

respect to transparent bridging. If transparent bridging is not

supported this group will not be implemented. This group is

applicable to transparent only and SRT bridges.

4.1.5. The dot1dStatic Group

This group contains objects that describe the entity's state with

respect to destination-address filtering. If destination-address

filtering is not supported this group will not be implemented. This

group is applicable to any type of bridge which performs

destination-address filtering.

4.2. Relationship to Other MIBs

As described above, some IEEE 802.1d management objects have not been

included in this MIB because they overlap with objects in other MIBs

applicable to a bridge implementing this MIB. In particular, it is

assumed that a bridge implementing this MIB will also implement (at

least) the 'system' group and the 'interfaces' group defined in MIB-

II [6].

4.2.1. Relationship to the 'system' group

In MIB-II, the 'system' group is defined as being mandatory for all

systems such that each managed entity contains one instance of each

object in the 'system' group. Thus, those objects apply to the

entity as a whole irrespective of whether the entity's sole

functionality is bridging, or whether bridging is only a subset of

the entity's functionality.

4.2.2. Relationship to the 'interfaces' group

In MIB-II, the 'interfaces' group is defined as being mandatory for

all systems and contains information on an entity's interfaces, where

each interface is thought of as being attached to a `subnetwork'.

(Note that this term is not to be confused with `subnet' which refers

to an addressing partitioning scheme used in the Internet suite of

protocols.) The term 'segment' is used in this memo to refer to such

a subnetwork, whether it be an Ethernet segment, a 'ring', a WAN

link, or even an X.25 virtual circuit.

Implicit in this Bridge MIB is the notion of ports on a bridge. Each

of these ports is associated with one interface of the 'interfaces'

group, and in most situations, each port is associated with a

different interface. However, there are situations in which multiple

ports are associated with the same interface. An example of such a

situation would be several ports each corresponding one-to-one with

several X.25 virtual circuits but all on the same interface.

Each port is uniquely identified by a port number. A port number has

no mandatory relationship to an interface number, but in the simple

case a port number will have the same value as the corresponding

interface's interface number. Port numbers are in the range

(1..dot1dBaseNumPorts).

Some entities perform other functionality as well as bridging through

the sending and receiving of data on their interfaces. In such

situations, only a subset of the data sent/received on an interface

is within the domain of the entity's bridging functionality. This

subset is considered to be delineated according to a set of

protocols, with some protocols being bridged, and other protocols not

being bridged. For example, in an entity which exclusively performed

bridging, all protocols would be considered as being bridged, whereas

in an entity which performed IP routing on IP datagrams and only

bridged other protocols, only the non-IP data would be considered as

being bridged.

Thus, this Bridge MIB (and in particular, its counters) are

applicable only to that subset of the data on an entity's interfaces

which is sent/received for a protocol being bridged. All such data

is sent/received via the ports of the bridge.

4.3. Textual Conventions

The datatypes, MacAddress, BridgeId and Timeout, are used as textual

conventions in this document. These textual conventions have NO

effect on either the syntax nor the semantics of any managed object.

Objects defined using these conventions are always encoded by means

of the rules that define their primitive type. Hence, no changes to

the SMI or the SNMP are necessary to accommodate these textual

conventions which are adopted merely for the convenience of readers.

5. Definitions

RFC1286-MIB DEFINITIONS ::= BEGIN

IMPORTS

Counter, Gauge, TimeTicks

FROM RFC1155-SMI

mib-2

FROM RFC1213-MIB

OBJECT-TYPE

FROM RFC-1212

TRAP-TYPE

FROM RFC-1215;

-- All representations of MAC addresses in this MIB Module use,

-- as a textual convention (i.e. this convention does not affect

-- their encoding), the data type:

MacAddress ::= OCTET STRING (SIZE (6)) -- a 6 octet address in

-- the "canonical" order

-- defined by IEEE 802.1a, i.e., as if it were transmitted least

-- significant bit first, even though 802.5 (in contrast to other

-- 802.x protocols) requires MAC addresses to be transmitted most

-- significant bit first.

-- 16-bit addresses, if needed, are represented by setting their

-- upper 4 octets to all 0's, i.e., AAFF would be represented

-- as 00000000AAFF.

-- Similarly, all representations of Bridge-Id in this MIB Module

-- use, as a textual convention (i.e. this convention does not affect

-- their encoding), the data type:

BridgeId ::= OCTET STRING (SIZE (8)) -- the Bridge-Identifier as

-- used in the Spanning Tree

-- Protocol to uniquely identify a bridge. Its first two octets

-- (in network byte order) contain a priority value and its last

-- 6 octets contain the MAC address used to refer to a bridge in a

-- unique fashion (typically, the numerically smallest MAC address

-- of all ports on the bridge).

-- Several objects in this MIB module represent values of timers

-- used by the Spanning Tree Protocol. In this MIB, these timers

-- have values in units of hundreths of a second (i.e. 1/100 secs).

-- These timers, when stored in a Spanning Tree Protocol's BPDU,

-- are in units of 1/256 seconds. Note, however, that 802.1d/D9

-- specifies a settable granularity of no more than 1 second for

-- these timers. To avoid ambiguity, a data type is defined here

-- as a textual convention and all representation of these timers

-- in this MIB module are defined using this data type. An algorithm

-- is also defined for converting between the different units, to

-- ensure a timer's value is not distorted by multiple conversions.

-- The data type is:

Timeout ::= INTEGER -- a STP timer in units of 1/100 seconds

-- To convert a Timeout value into a value in units of

-- 1/256 seconds, the following algorithm should be used:

-- b = floor( (n * 256) / 100)

-- where:

-- floor = quotient [ignore remainder]

-- n is the value in 1/100 second units

-- b is the value in 1/256 second units

-- To convert the value from 1/256 second units back to

-- 1/100 seconds, the following algorithm should be used:

-- n = ceiling( (b * 100) / 256)

-- where:

-- ceiling = quotient [if remainder is 0], or

-- quotient + 1 [if remainder is non-zero]

-- n is the value in 1/100 second units

-- b is the value in 1/256 second units

-- Note: it is important that the arithmetic operations are done

-- in the order specified (i.e., multiply first, divide second).

dot1dBridge OBJECT IDENTIFIER ::= { mib-2 17 }

-- groups in the Bridge MIB

dot1dBase OBJECT IDENTIFIER ::= { dot1dBridge 1 }

dot1dStp OBJECT IDENTIFIER ::= { dot1dBridge 2 }

dot1dSr OBJECT IDENTIFIER ::= { dot1dBridge 3 }

dot1dTp OBJECT IDENTIFIER ::= { dot1dBridge 4 }

dot1dStatic OBJECT IDENTIFIER ::= { dot1dBridge 5 }

-- the dot1dBase group

-- Implementation of the dot1dBase group is mandatory for all

-- bridges.

dot1dBaseBridgeAddress OBJECT-TYPE

SYNTAX MacAddress

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The MAC address used by this bridge when it must

be referred to in a unique fashion. It is

recommended that this be the numerically smallest

MAC address of all ports that belong to this

bridge. However it is only required to be unique.

When concatenated with dot1dStpPriority a unique

BridgeIdentifier is formed which is used in the

Spanning Tree Protocol."

REFERENCE

"P802.1d/D9, July 14, 1989: Sections 6.4.1.1.3 and 3.12.5"

::= { dot1dBase 1 }

dot1dBaseNumPorts OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of ports controlled by this bridging

entity."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.4.1.1.3"

::= { dot1dBase 2 }

dot1dBaseType OBJECT-TYPE

SYNTAX INTEGER {

unknown(1),

transparent-only(2),

sourceroute-only(3),

srt(4)

}

ACCESS read-only

STATUS mandatory

DESCRIPTION

"Indicates what type of bridging this bridge can

perform. If a bridge is actually performing a

certain type of bridging this will be indicated by

entries in the port table for the given type."

::= { dot1dBase 3 }

-- The Generic Bridge Port Table

dot1dBasePortTable OBJECT-TYPE

SYNTAX SEQUENCE OF Dot1dBasePortEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A table that contains generic information about

every port that is associated with this bridge.

Transparent, source-route, and srt ports are

included."

::= { dot1dBase 4 }

dot1dBasePortEntry OBJECT-TYPE

SYNTAX Dot1dBasePortEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A list of information for each port of the

bridge."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.4.2, 6.6.1"

INDEX { dot1dBasePort }

::= { dot1dBasePortTable 1 }

Dot1dBasePortEntry ::=

SEQUENCE {

dot1dBasePort

INTEGER,

dot1dBasePortIfIndex

INTEGER,

dot1dBasePortCircuit

OBJECT IDENTIFIER,

dot1dBasePortDelayExceededDiscards

Counter,

dot1dBasePortMtuExceededDiscards

Counter

}

dot1dBasePort OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The port number of the port for which this entry

contains bridge management information."

::= { dot1dBasePortEntry 1 }

dot1dBasePortIfIndex OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The value of the instance of the ifIndex object,

defined in [4,6], for the interface corresponding

to this port."

::= { dot1dBasePortEntry 2 }

dot1dBasePortCircuit OBJECT-TYPE

SYNTAX OBJECT IDENTIFIER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"For a port which (potentially) has the same value

of dot1dBasePortIfIndex as another port on the

same bridge, this object contains the name of an

object instance unique to this port. For example,

in the case where multiple ports correspond one-

to-one with multiple X.25 virtual circuits, this

value might identify an (e.g., the first) object

instance associated with the X.25 virtual circuit

corresponding to this port.

For a port which has a unique value of

dot1dBasePortIfIndex, this object can have the

value { 0 0 }."

::= { dot1dBasePortEntry 3 }

dot1dBasePortDelayExceededDiscards OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of frames discarded by this port due

to excessive transit delay through the bridge. It

is incremented by both transparent and source

route bridges."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.6.1.1.3"

::= { dot1dBasePortEntry 4 }

dot1dBasePortMtuExceededDiscards OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of frames discarded by this port due

to an excessive size. It is incremented by both

transparent and source route bridges."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.6.1.1.3"

::= { dot1dBasePortEntry 5 }

-- the dot1dStp group

-- Implementation of the dot1dStp group is optional. It is

-- implemented by those bridges that support the Spanning Tree

-- Protocol. Transparent, Source Route, and SRT bridges will

-- implement this group only if they support the Spanning Tree

-- Protocol.

dot1dStpProtocolSpecification OBJECT-TYPE

SYNTAX INTEGER {

unknown(1),

decLb100(2),

ieee8021d(3)

}

ACCESS read-only

STATUS mandatory

DESCRIPTION

"An indication of what version of the Spanning

Tree Protocol is being run. The value

'decLb100(2)' indicates the DEC LANbridge 100

Spanning Tree protocol. IEEE 802.1d

implementations will return 'ieee8021d(3)'. If

future versions of the IEEE Spanning Tree Protocol

are released that are incompatible with the

current version a new value will be defined."

::= { dot1dStp 1 }

dot1dStpPriority OBJECT-TYPE

SYNTAX INTEGER (0..65535)

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The value of the write-able portion of the Bridge

ID, i.e., the first two octets of the (8 octet

long) Bridge ID. The other (last) 6 octets of the

Bridge ID are given by the value of

dot1dBaseBridgeAddress."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.7"

::= { dot1dStp 2 }

dot1dStpTimeSinceTopologyChange OBJECT-TYPE

SYNTAX TimeTicks

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The time (in hundredths of a second) since the

last time a topology change was detected by the

bridge entity."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.8.1.1.3"

::= { dot1dStp 3 }

dot1dStpTopChanges OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The total number of topology changes detected by

this bridge since the management entity was last

reset or initialized."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.8.1.1.3"

::= { dot1dStp 4 }

dot1dStpDesignatedRoot OBJECT-TYPE

SYNTAX BridgeId

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The bridge identifier of the root of the spanning

tree as determined by the Spanning Tree Protocol

as executed by this node. This value is used as

the Root Identifier parameter in all Configuration

Bridge PDUs originated by this node."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.1"

::= { dot1dStp 5 }

dot1dStpRootCost OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The cost of the path to the root as seen from

this bridge."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.2"

::= { dot1dStp 6 }

dot1dStpRootPort OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The port number of the port which offers the

lowest cost path from this bridge to the root

bridge."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.3"

::= { dot1dStp 7 }

dot1dStpMaxAge OBJECT-TYPE

SYNTAX Timeout

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The maximum age of Spanning Tree Protocol

information learned from the network on any port

before it is discarded, in units of hundredths of

a second. This is the actual value that this

bridge is currently using."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.4"

::= { dot1dStp 8 }

dot1dStpHelloTime OBJECT-TYPE

SYNTAX Timeout

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The amount of time between the transmission of

Configuration bridge PDUs by this node on any port

when it is the root of the spanning tree or trying

to become so, in units of hundredths of a second.

This is the actual value that this bridge is

currently using."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.5"

::= { dot1dStp 9 }

dot1dStpHoldTime OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"This time value determines the interval length

during which no more than two Configuration bridge

PDUs shall be transmitted by this node, in units

of hundredths of a second."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.14"

::= { dot1dStp 10 }

dot1dStpForwardDelay OBJECT-TYPE

SYNTAX Timeout

ACCESS read-only

STATUS mandatory

DESCRIPTION

"This time value, measured in units of hundredths

of a second, controls how fast a port changes its

spanning state when moving towards the Forwarding

state. The value determines how long the port

stays in a particular state before moving to the

next state. For example, how long a port stays in

the Listening state when moving from Blocking to

Learning. This value is also used, when a

topology change has been detected and is underway,

to age all dynamic entries in the Forwarding

Database. [Note that this value is the one that

this bridge is currently using, in contrast to

dot1dStpBridgeForwardDelay which is the value that

this bridge and all others would start using

if/when this bridge were to become the root.]"

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.6"

::= { dot1dStp 11 }

dot1dStpBridgeMaxAge OBJECT-TYPE

SYNTAX Timeout (600..4000)

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The value that all bridges use for MaxAge when

this bridge is acting as the root. Note that

802.1d/D9 specifies that the range for this

parameter is related to the value of

dot1dStpBridgeHelloTime. The granularity of this

timer is specified by 802.1d/D9 to be 1 second.

An agent may return a badValue error if a set is

attempted to a value which is not a whole number

of seconds."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.8"

::= { dot1dStp 12 }

dot1dStpBridgeHelloTime OBJECT-TYPE

SYNTAX Timeout (100..1000)

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The value that all bridges use for HelloTime when

this bridge is acting as the root. The

granularity of this timer is specified by

802.1d/D9 to be 1 second. An agent may return a

badValue error if a set is attempted to a value

which is not a whole number of seconds."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.9"

::= { dot1dStp 13 }

dot1dStpBridgeForwardDelay OBJECT-TYPE

SYNTAX Timeout (400..3000)

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The value that all bridges use for ForwardDelay

when this bridge is acting as the root. Note that

802.1d/D9 specifies that the range for this

parameter is related to the value of

dot1dStpBridgeMaxAge. The granularity of this

timer is specified by 802.1d/D9 to be 1 second.

An agent may return a badValue error if a set is

attempted to a value which is not a whole number

of seconds."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.3.10"

::= { dot1dStp 14 }

-- The Spanning Tree Port Table

dot1dStpPortTable OBJECT-TYPE

SYNTAX SEQUENCE OF Dot1dStpPortEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A table that contains port-specific information

for the Spanning Tree Protocol."

::= { dot1dStp 15 }

dot1dStpPortEntry OBJECT-TYPE

SYNTAX Dot1dStpPortEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A list of information maintained by every port

about the Spanning Tree Protocol state for that

port."

INDEX { dot1dStpPort }

::= { dot1dStpPortTable 1 }

Dot1dStpPortEntry ::=

SEQUENCE {

dot1dStpPort

INTEGER,

dot1dStpPortPriority

INTEGER,

dot1dStpPortState

INTEGER,

dot1dStpPortEnable

INTEGER,

dot1dStpPortPathCost

INTEGER,

dot1dStpPortDesignatedRoot

BridgeId,

dot1dStpPortDesignatedCost

INTEGER,

dot1dStpPortDesignatedBridge

BridgeId,

dot1dStpPortDesignatedPort

OCTET STRING,

dot1dStpPortForwardTransitions

Counter

}

dot1dStpPort OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The port number of the port for which this entry

contains Spanning Tree Protocol management

information."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.8.2.1.2"

::= { dot1dStpPortEntry 1 }

dot1dStpPortPriority OBJECT-TYPE

SYNTAX INTEGER (0..255)

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The value of the priority field which is

contained in the first (in network byte order)

octet of the (2 octet long) Port ID. The other

octet of the Port ID is given by the value of

dot1dStpPort."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.5.1"

::= { dot1dStpPortEntry 2 }

dot1dStpPortState OBJECT-TYPE

SYNTAX INTEGER {

disabled(1),

blocking(2),

listening(3),

learning(4),

forwarding(5),

broken(6)

}

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The port's current state as defined by

application of the Spanning Tree Protocol. This

state controls what action a port takes on

reception of a frame. If the bridge has detected

a port that is malfunctioning it will place that

port into the broken(6) state. For ports which

are disabled (see dot1dStpPortEnable), this object

will have a value of disabled(1)."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.5.2"

::= { dot1dStpPortEntry 3 }

dot1dStpPortEnable OBJECT-TYPE

SYNTAX INTEGER {

enabled(1),

disabled(2)

}

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The enabled/disabled status of the port."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.5.2"

::= { dot1dStpPortEntry 4 }

dot1dStpPortPathCost OBJECT-TYPE

SYNTAX INTEGER (1..65535)

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The contribution of this port to the path cost of

paths towards the spanning tree root which include

this port."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.5.3"

::= { dot1dStpPortEntry 5 }

dot1dStpPortDesignatedRoot OBJECT-TYPE

SYNTAX BridgeId

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The unique Bridge Identifier of the Bridge

recorded as the Root in the Configuration BPDUs

transmitted by the Designated Bridge for the

segment to which the port is attached."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.5.4"

::= { dot1dStpPortEntry 6 }

dot1dStpPortDesignatedCost OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The path cost of the Designated Port of the

segment connected to this port. This value is

compared to the Root Path Cost field in received

bridge PDUs."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.5.5"

::= { dot1dStpPortEntry 7 }

dot1dStpPortDesignatedBridge OBJECT-TYPE

SYNTAX BridgeId

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The Bridge Identifier of the bridge which this

port considers to be the Designated Bridge for

this port's segment."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.5.6"

::= { dot1dStpPortEntry 8 }

dot1dStpPortDesignatedPort OBJECT-TYPE

SYNTAX OCTET STRING (SIZE (2))

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The Port Identifier of the port on the Designated

Bridge for this port's segment."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 4.5.5.7"

::= { dot1dStpPortEntry 9 }

dot1dStpPortForwardTransitions OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of times this port has transitioned

from the Learning state to the Forwarding state."

::= { dot1dStpPortEntry 10 }

-- the dot1dSr group

-- Implementation of the dot1dSr group is optional. It is

-- implemented by those bridges that support the source route

-- bridging mode, including Source Route and SRT bridges.

dot1dSrPortTable OBJECT-TYPE

SYNTAX SEQUENCE OF Dot1dSrPortEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A table that contains information about every

port that is associated with this source route

bridge."

::= { dot1dSr 1 }

dot1dSrPortEntry OBJECT-TYPE

SYNTAX Dot1dSrPortEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A list of information for each port of a source

route bridge."

INDEX { dot1dSrPort }

::= { dot1dSrPortTable 1 }

Dot1dSrPortEntry ::=

SEQUENCE {

dot1dSrPort

INTEGER,

dot1dSrPortHopCount

INTEGER,

dot1dSrPortLocalSegment

INTEGER,

dot1dSrPortBridgeNum

INTEGER,

dot1dSrPortTargetSegment

INTEGER,

dot1dSrPortLargestFrame

INTEGER,

dot1dSrPortSTESpanMode

INTEGER,

dot1dSrPortSpecInFrames

Counter,

dot1dSrPortSpecOutFrames

Counter,

dot1dSrPortApeInFrames

Counter,

dot1dSrPortApeOutFrames

Counter,

dot1dSrPortSteInFrames

Counter,

dot1dSrPortSteOutFrames

Counter,

dot1dSrPortSegmentMismatchDiscards

Counter,

dot1dSrPortDuplicateSegmentDiscards

Counter,

dot1dSrPortHopCountExceededDiscards

Counter

}

dot1dSrPort OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The port number of the port for which this entry

contains Source Route management information."

::= { dot1dSrPortEntry 1 }

dot1dSrPortHopCount OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The maximum number of routing descriptors allowed

in an All Paths or Spanning Tree Explorer frames."

::= { dot1dSrPortEntry 2 }

dot1dSrPortLocalSegment OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The segment number that uniquely identifies the

segment to which this port is connected. Current

source routing protocols limit this value to the

range: 0 through 4095. A value of 65535 signifies

that no segment number is assigned to this port."

::= { dot1dSrPortEntry 3 }

dot1dSrPortBridgeNum OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-write

STATUS mandatory

DESCRIPTION

"A bridge number uniquely identifies a bridge when

more than one bridge is used to span the same two

segments. Current source routing protocols limit

this value to the range: 0 through 15. A value of

65535 signifies that no bridge number is assigned

to this bridge."

::= { dot1dSrPortEntry 4 }

dot1dSrPortTargetSegment OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The segment number that corresponds to the target

segment this port is considered to be connected to

by the bridge. Current source routing protocols

limit this value to the range: 0 through 4095. A

value of 65535 signifies that no target segment is

assigned to this port."

::= { dot1dSrPortEntry 5 }

-- It would be nice if we could use ifMtu as the size of the

-- largest frame, but we can't because ifMtu is defined to be

-- the size that the (inter-)network layer can use which can

-- differ from the MAC layer (especially if several layers of

-- encapsulation are used).

dot1dSrPortLargestFrame OBJECT-TYPE

SYNTAX INTEGER {

dot1dSrMtu516 (516),

dot1dSrMtu1500 (1500),

dot1dSrMtu2052 (2052),

dot1dSrMtu4472 (4472),

dot1dSrMtu8144 (8144),

dot1dSrMtu11407 (11407), -- yes this is correct don't

dot1dSrMtu17800 (17800), -- ask me where it came from.

dot1dSrMtu65535 (65535)

}

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The maximum size of the INFO field (LLC and

above) that this port can send/receive. It does

not include any MAC level (framing) octets. The

value of this object is used by this bridge to

determine whether a modification of the

LargestFrame (LF, see [14]) field of the Routing

Control field of the Routing Information Field is

necessary. Valid values as defined by the 802.5

source routing bridging specification[14] are 516,

1500, 2052, 4472, 8144, 11407, 17800, and 65535

octets. Behavior of the port when an illegal

value is written is implementation specific. It

is recommended that a reasonable legal value be

chosen."

::= { dot1dSrPortEntry 6 }

dot1dSrPortSTESpanMode OBJECT-TYPE

SYNTAX INTEGER {

auto-span(1),

disabled(2),

forced(3)

}

ACCESS read-write

STATUS mandatory

DESCRIPTION

"Determines how this port behaves when presented

with a Spanning Tree Explorer frame. The value

'disabled(2)' indicates that the port will not

accept or send Spanning Tree Explorer packets; any

STE packets received will be silently discarded.

The value 'forced(3)' indicates the port will

always accept and propagate Spanning Tree Explorer

frames. This allows a manually configured

Spanning Tree for this class of packet to be

configured. Note that unlike transparent bridging

this is not catastrophic to the network if there

are loops. The value 'auto-span(1)' can only be

returned by a bridge that both implements the

Spanning Tree Protocol and has use of the protocol

enabled on this port. The behavior of the port for

Spanning Tree Explorer frames is determined by the

state of dot1dStpPortState. If the port is in the

'forwarding' state, the frame will be accepted or

propagated. Otherwise it will be silently

discarded."

::= { dot1dSrPortEntry 7 }

dot1dSrPortSpecInFrames OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of specifically routed frames that

have been received from this port's segment."

::= { dot1dSrPortEntry 8 }

dot1dSrPortSpecOutFrames OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of specifically routed frames that

this port has transmitted on its segment."

::= { dot1dSrPortEntry 9 }

dot1dSrPortApeInFrames OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of all paths explorer frames that have

been received by this port from its segment."

::= { dot1dSrPortEntry 10 }

dot1dSrPortApeOutFrames OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of all paths explorer frames that have

been transmitted by this port on its segment."

::= { dot1dSrPortEntry 11 }

dot1dSrPortSteInFrames OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of spanning tree explorer frames that

have been received by this port from its segment."

::= { dot1dSrPortEntry 12 }

dot1dSrPortSteOutFrames OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of spanning tree explorer frames that

have been transmitted by this port on its

segment."

::= { dot1dSrPortEntry 13 }

dot1dSrPortSegmentMismatchDiscards OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of explorer frames that have been

discarded by this port because the routing

descriptor field contained an invalid adjacent

segment value."

::= { dot1dSrPortEntry 14 }

dot1dSrPortDuplicateSegmentDiscards OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of frames that have been discarded by

this port because the routing descriptor field

contained a duplicate segment identifier."

::= { dot1dSrPortEntry 15 }

dot1dSrPortHopCountExceededDiscards OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of explorer frames that have been

discarded by this port because the Routing

Information Field has exceeded the maximum route

descriptor length."

::= { dot1dSrPortEntry 16 }

-- the dot1dTp group

-- Implementation of the dot1dTp group is optional. It is

-- implemented by those bridges that support the transparent

-- bridging mode. A transparent or SRT bridge will implement

-- this group.

dot1dTpLearnedEntryDiscards OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The total number of Forwarding Database entries,

which have been or would have been learnt, but

have been discarded due to a lack of space to

store them in the Forwarding Database. If this

counter is increasing, it indicates that the

Forwarding Database is regularly becoming full (a

condition which has unpleasant performance effects

on the subnetwork). If this counter has a

significant value but is not presently increasing,

it indicates that the problem has been occurring

but is not persistent."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.7.1.1.3"

::= { dot1dTp 1 }

dot1dTpAgingTime OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The timeout period in seconds for aging out

dynamically learned forwarding information."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.7.1.1.3"

::= { dot1dTp 2 }

-- The Forwarding Database for Transparent Bridges

dot1dTpFdbTable OBJECT-TYPE

SYNTAX SEQUENCE OF Dot1dTpFdbEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A table that contains information about unicast

entries for which the bridge has forwarding and/or

filtering information. This information is used

by the transparent bridging function in

determining how to propagate a received frame."

::= { dot1dTp 3 }

dot1dTpFdbEntry OBJECT-TYPE

SYNTAX Dot1dTpFdbEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"Information about a specific unicast MAC address

for which the bridge has some forwarding and/or

filtering information."

INDEX { dot1dTpFdbAddress }

::= { dot1dTpFdbTable 1 }

Dot1dTpFdbEntry ::=

SEQUENCE {

dot1dTpFdbAddress

MacAddress,

dot1dTpFdbPort

INTEGER,

dot1dTpFdbStatus

INTEGER

}

dot1dTpFdbAddress OBJECT-TYPE

SYNTAX MacAddress

ACCESS read-only

STATUS mandatory

DESCRIPTION

"A unicast MAC address for which the bridge has

forwarding and/or filtering information."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 3.9.1, 3.9.2"

::= { dot1dTpFdbEntry 1 }

dot1dTpFdbPort OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"Either the value '0', or the port number of the

port on which a frame having a source address

equal to the value of the corresponding instance

of dot1dTpFdbAddress has been seen. A value of

'0' indicates that the port number has not been

learned but that the bridge does have some

forwarding/filtering information about this

address (e.g. in the dot1dStaticTable).

Implementors are encouraged to assign the port

value to this object whenever it is learned even

for addresses for which the corresponding value of

dot1dTpFdbStatus is not learned(3)."

::= { dot1dTpFdbEntry 2 }

dot1dTpFdbStatus OBJECT-TYPE

SYNTAX INTEGER {

other(1),

invalid(2),

learned(3),

self(4),

mgmt(5)

}

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The status of this entry. The meanings of the

values are:

other(1) : none of the following. This would

include the case where some other

MIB object (not the corresponding

instance of dot1dTpFdbPort, nor an

entry in the dot1dStaticTable) is

being used to determine if and how

frames addressed to the value of

the corresponding instance of

dot1dTpFdbAddress are being

forwarded.

invalid(2) : this entry is not longer valid

(e.g., it was learned but has since

aged-out), but has not yet been

flushed from the table.

learned(3) : the value of the corresponding

instance of dot1dTpFdbPort was

learned, and is being used.

self(4) : the value of the corresponding

instance of dot1dTpFdbAddress

represents one of the bridge's

addresses. The corresponding

instance of dot1dTpFdbPort

indicates which of the bridge's

ports has this address.

mgmt(5) : the value of the corresponding

instance of dot1dTpFdbAddress is

also the value of an existing

instance of dot1dStaticAddress."

::= { dot1dTpFdbEntry 3 }

-- Port Table for Transparent Bridges

dot1dTpPortTable OBJECT-TYPE

SYNTAX SEQUENCE OF Dot1dTpPortEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A table that contains information about every

port that is associated with this transparent

bridge."

::= { dot1dTp 4 }

dot1dTpPortEntry OBJECT-TYPE

SYNTAX Dot1dTpPortEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A list of information for each port of a

transparent bridge."

INDEX { dot1dTpPort }

::= { dot1dTpPortTable 1 }

Dot1dTpPortEntry ::=

SEQUENCE {

dot1dTpPort

INTEGER,

dot1dTpPortMaxInfo

INTEGER,

dot1dTpPortInFrames

Counter,

dot1dTpPortOutFrames

Counter,

dot1dTpPortInDiscards

Counter

}

dot1dTpPort OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The port number of the port for which this entry

contains Transparent bridging management

information."

::= { dot1dTpPortEntry 1 }

-- It would be nice if we could use ifMtu as the size of the

-- largest INFO field, but we can't because ifMtu is defined

-- to be the size that the (inter-)network layer can use which

-- can differ from the MAC layer (especially if several layers

-- of encapsulation are used).

dot1dTpPortMaxInfo OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The maximum size of the INFO (non-MAC) field that

this port will receive or transmit."

::= { dot1dTpPortEntry 2 }

dot1dTpPortInFrames OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of frames that have been received by

this port from its segment. Note that a frame

received on the interface corresponding to this

port is only counted by this object if and only if

it is for a protocol being processed by the local

bridging function."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.6.1.1.3"

::= { dot1dTpPortEntry 3 }

dot1dTpPortOutFrames OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"The number of frames that have been transmitted

by this port to its segment. Note that a frame

transmitted on the interface corresponding to this

port is only counted by this object if and only if

it is for a protocol being processed by the local

bridging function."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.6.1.1.3"

::= { dot1dTpPortEntry 4 }

dot1dTpPortInDiscards OBJECT-TYPE

SYNTAX Counter

ACCESS read-only

STATUS mandatory

DESCRIPTION

"Count of valid frames received which were

discarded (i.e., filtered) by the Forwarding

Process."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.6.1.1.3"

::= { dot1dTpPortEntry 5 }

-- The Static (Destination-Address Filtering) Database

-- Implementation of this group is optional.

dot1dStaticTable OBJECT-TYPE

SYNTAX SEQUENCE OF Dot1dStaticEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"A table containing filtering information

configured into the bridge by (local or network)

management specifying the set of ports to which

frames received from specific ports and containing

specific destination addresses are allowed to be

forwarded. The value of zero in this table as the

port number from which frames with a specific

destination address are received, is used to

specify all ports for which there is no specific

entry in this table for that particular

destination address. Entries are valid for

unicast and for group/broadcast addresses."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 6.7.2"

::= { dot1dStatic 1 }

dot1dStaticEntry OBJECT-TYPE

SYNTAX Dot1dStaticEntry

ACCESS not-accessible

STATUS mandatory

DESCRIPTION

"Filtering information configured into the bridge

by (local or network) management specifying the

set of ports to which frames received from a

specific port and containing a specific

destination address are allowed to be forwarded."

REFERENCE

"P802.1d/D9, July 14,1989: Section 6.7.2"

INDEX { dot1dStaticAddress, dot1dStaticReceivePort }

::= { dot1dStaticTable 1 }

Dot1dStaticEntry ::=

SEQUENCE {

dot1dStaticAddress

MacAddress,

dot1dStaticReceivePort

INTEGER,

dot1dStaticAllowedToGoTo

OCTET STRING,

dot1dStaticStatus

INTEGER

}

dot1dStaticAddress OBJECT-TYPE

SYNTAX MacAddress

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The destination MAC address in a frame to which

this entry's filtering information applies. This

object can take the value of a unicast address, a

group address or the broadcast address."

REFERENCE

"P802.1d/D9, July 14, 1989: Section 3.9.1, 3.9.2"

::= { dot1dStaticEntry 1 }

dot1dStaticReceivePort OBJECT-TYPE

SYNTAX INTEGER

ACCESS read-write

STATUS mandatory

DESCRIPTION

"Either the value '0', or the port number of the

port from which a frame must be received in order

for this entry's filtering information to apply.

A value of zero indicates that this entry applies

on all ports of the bridge for which there is no

other applicable entry."

::= { dot1dStaticEntry 2 }

dot1dStaticAllowedToGoTo OBJECT-TYPE

SYNTAX OCTET STRING

ACCESS read-write

STATUS mandatory

DESCRIPTION

"The set of ports to which frames received from a

specific port and destined for a specific MAC

address, are allowed to be forwarded. Each octet

within the value of this object specifies a set of

eight ports, with the first octet specifying ports

1 through 8, the second octet specifying ports 9

through 16, etc. Within each octet, the most

significant bit represents the lowest numbered

port, and the least significant bit represents the

highest numbered port. Thus, each port of the

bridge is represented by a single bit within the

value of this object. If that bit has a value of

'1' then that port is included in the set of

ports; the port is not included if its bit has a

value of '0'. (Note that the setting of the bit

corresponding to the port from which a frame is

received is irrelevant.)"

::= { dot1dStaticEntry 3 }

dot1dStaticStatus OBJECT-TYPE

SYNTAX INTEGER {

other(1),

invalid(2),

permanent(3),

deleteOnReset(4),

deleteOnTimeout(5)

}

ACCESS read-write

STATUS mandatory

DESCRIPTION

"This object indicates the status of this entry.

other(1) - this entry is currently in use but

the conditions under which it will

remain so are different from each of the

following values.

invalid(2) - writing this value to the object

removes the corresponding entry.

permanent(3) - this entry is currently in use

and will remain so after the next reset

of the bridge.

deleteOnReset(4) - this entry is currently in

use and will remain so until the next

reset of the bridge.

deleteOnTimeout(5) - this entry is currently

in use and will remain so until it is

aged out."

::= { dot1dStaticEntry 4 }

-- Traps for use by Bridges

-- Traps for the Spanning Tree Protocol

newRoot TRAP-TYPE

ENTERPRISE dot1dBridge

DESCRIPTION

"The newRoot trap indicates that the sending agent

has become the new root of the Spanning Tree; the

trap is sent by a bridge soon after its election

as the new root, e.g., upon expiration of the

Topology Change Timer immediately subsequent to

its election."

::= 1

topologyChange TRAP-TYPE

ENTERPRISE dot1dBridge

DESCRIPTION

"A topologyChange trap is sent by a bridge when

any of its configured ports transitions from the

Learning state to the Forwarding state, or from

the Forwarding state to the Blocking state. The

trap is not sent if a newRoot trap is sent for the

same transition."

::= 2

END

6. Acknowledgments

This document was produced on behalf of the Bridge Sub-Working Group

of the SNMP Working Group of the Internet Engineering Task Force.

Over the course of its deliberations, the working group received four

separate documents for consideration as the basis for its work. The

first was submitted by Stan Froyd of Advanced Computer

Communications; the second by Richard Fox of SynOptics; the third by

Eric Decker of cisco Inc. and Keith McCloghrie of Hughes LAN Systems;

and the fourth by Paul Langille and Anil Rijsinghani of Digital

Equipment Corp. After considering the submissions, the working group

chose to proceed with a document formed as a conjunction of the

latter two submissions. This document is the result.

The authors wish to thank the members of the Bridge Working Group for

their many comments and suggestions which improved this effort. In

particular, Fred Baker (chairman of the working group) of ACC, Steve

Sherry of Xyplex, and Frank Kastenholz of Clearpoint Research Corp.

Others members of the Bridge Working Group who contributed to this

effort are:

Bill Anderson, Mitre

Karl Auerbach, Epilogue

Fred Baker, ACC (chair)

Terry Bradley, Wellfleet

Ted Brunner, Bellcore

Jeffrey Buffum, Apollo

Chris ChioTasso, Fibronics

Anthony Chung, HLS

Chuck Davin, MIT-LCS

Andy Davis, Spider

Eric Decker, cisco

Nadya El-Afandi, Network Systems

Gary Ellis,HP/Apollo

Richard Fox, SynOptics

Stan Froyd, ACC

Frank Kastenholz, Clearpoint Research

Shirnshon Kaufman,

Jim Kinder, Fibercom

Cheryl Krupczak,NCR

Paul Langille, Digital

Peter Lin,Vitalink

Keith McCloghrie, HLS

Donna McMaster, SynOptics

Dave Perkins, 3Com

Jim Reinstedler, Ungermann Bass

Anil Rijsinghani, Digital

Mark Schaefer, David Systems

Steve Sherry, Xyplex

Bob Stewart, Xyplex

Emil Sturniolo,

Kevin Synott, Retix

Ian Thomas, Chipcom

Maurice Turcott, Racal

Fei Xu,

7. References

[1] Cerf, V., "IAB Recommendations for the Development of Internet

Network Management Standards", RFC1052, NRI, April 1988.

[2] Cerf, V., "Report of the Second Ad Hoc Network Management Review

Group", RFC1109, NRI, August 1989.

[3] Rose M., and K. McCloghrie, "Structure and Identification of

Management Information for TCP/IP-based internets", RFC1155,

Performance Systems International, Hughes LAN Systems, May 1990.

[4] McCloghrie K., and M. Rose, "Management Information Base for

Network Management of TCP/IP-based internets", RFC1156, Hughes

LAN Systems, Performance Systems International, May 1990.

[5] Case, J., Fedor, M., Schoffstall, M., and J. Davin, "Simple

Network Management Protocol", RFC1157, SNMP Research,

Performance Systems International, Performance Systems

International, MIT Laboratory for Computer Science, May 1990.

[6] McCloghrie K., and M. Rose, Editors, "Management Information Base

for Network Management of TCP/IP-based internets", RFC1213,

Performance Systems International, March 1991.

[7] Information processing systems - Open Systems Interconnection -

Specification of Abstract Syntax Notation One (ASN.1),

International Organization for Standardization, International

Standard 8824, December 1987.

[8] Information processing systems - Open Systems Interconnection -

Specification of Basic Encoding Rules for Abstract Notation One

(ASN.1), International Organization for Standardization,

International Standard 8825, December 1987.

[9] Rose, M., and K. McCloghrie, Editors, "Concise MIB Definitions",

RFC1212, Performance Systems International, Hughes LAN Systems,

March 1991.

[10] Rose, M., Editor, "A Convention for Defining Traps for use with

the SNMP", RFC1215, Performance Systems International, March

1991.

[11] ANSI/IEEE Draft P802.1d/D9 MAC Bridges, "IEEE Project 802 Local

and Metropolitan Area Networks", July 14, 1989.

[12] I.B.M. Token Ring Architecture Reference.

[13] ISO DIS 10038 MAC Bridges.

[14] ANSI/IEEE P802.1x/P802.5x, "Proposed Draft Local Area Network

Standard -- MAC Bridges, Source Routing Supplement", IEEE Project

802, September 1990.

[15] ANSI/IEEE 802.1y, "Source Routing Tutorial for End System

Operation", September 1990.

8. Security Considerations

Security issues are not discussed in this memo.

9. Authors' Addresses

Eric B. Decker

cisco Systems, Inc.

1525 O'Brien Dr.

Menlo Park, CA 94025

Phone: (415) 326-1941

Email: cire@cisco.com

Paul Langille

Digital Equipment Corporation

Digital Drive, MK02-2/K03

Merrimack, NH 03054

Phone: (603) 884-4045

EMail: langille@edwin.enet.dec.com

Anil Rijsinghani

Digital Equipment Corporation

153 Taylor St.

Littleton, MA 01460

Phone: (508)952-3520

EMail: anil@levers.enet.dec.com

Keith McCloghrie

Hughes LAN Systems

1225 Charleston Road

Mountain View, CA 94043

Phone: (415) 966-7934

EMail: kzm@hls.com