mibs/hp/ICF-VG-RPTR
ICF-VG-RPTR DEFINITIONS ::= BEGIN
IMPORTS
Integer32, Counter32, Counter64,
OBJECT-TYPE, MODULE-IDENTITY, NOTIFICATION-TYPE
FROM SNMPv2-SMI
DisplayString, MacAddress, TruthValue, TimeStamp
FROM SNMPv2-TC
MODULE-COMPLIANCE, OBJECT-GROUP, NOTIFICATION-GROUP
FROM SNMPv2-CONF
hpicfObjectModules, icfVgRepeater
FROM HP-ICF-OID;
icfVgRepeaterMib MODULE-IDENTITY
LAST-UPDATED "200011032225Z" -- November 3, 2000
ORGANIZATION "Hewlett Packard Company,
Network Infrastructure Solutions"
CONTACT-INFO
"Hewlett Packard Company
8000 Foothills Blvd.
Roseville, CA 95747"
DESCRIPTION
"This MIB module contains objects for managing
HP AdvanceStack 100VG-AnyLAN repeaters. It is
expected that this module will be superceded by
a standard 802.12 Repeater MIB."
REVISION "200011032225Z" -- November 3, 2000
DESCRIPTION "Updated division name."
REVISION "9703060347Z" -- March 6, 1997
DESCRIPTION
"Added NOTIFICATION-GROUP information."
REVISION "9609100203Z" -- September 10, 1996
DESCRIPTION
"Updated division name and STATUS info."
REVISION "9601250356Z" -- January 25, 1996
DESCRIPTION
"Split this MIB module from the former monolithic
hp-icf MIB. Added support for and full 802.12
compliance."
REVISION "9501180000Z" -- January 18, 1995
DESCRIPTION
"Initial version of this MIB module. Released with
the HPJ2414A agent card for the HPJ2410A 100VG
repeater."
::= { hpicfObjectModules 10 }
icfVgBasic OBJECT IDENTIFIER ::= { icfVgRepeater 1 }
icfVgBasicRptr OBJECT IDENTIFIER ::= { icfVgBasic 1 }
icfVgMACAddress OBJECT-TYPE
SYNTAX MacAddress
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The MAC address used by the repeater when it
initiates training on the uplink port. Repeaters
are allowed to train with an assigned MAC address or
a null (all zeroes) MAC address."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.1, aMACAddress."
::= { icfVgBasicRptr 1 }
icfVgCurrentFramingType OBJECT-TYPE
SYNTAX INTEGER {
frameType88023(1),
frameType88025(2)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The type of framing (802.3 or 802.5) currently in
use by the repeater."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.1, aCurrentFramingType."
::= { icfVgBasicRptr 2 }
icfVgDesiredFramingType OBJECT-TYPE
SYNTAX INTEGER {
frameType88023(1),
frameType88025(2)
}
MAX-ACCESS read-write
STATUS current
DESCRIPTION
"The type of framing which will be used by the
repeater after the next time it is reset. The value
of this object should be preserved across repeater
resets and power failures"
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.1, aDesiredFramingType."
::= { icfVgBasicRptr 3 }
icfVgFramingCapability OBJECT-TYPE
SYNTAX INTEGER {
frameType88023(1),
frameType88025(2),
frameTypeEither(3)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The type of framing this repeater is capable of
supporting."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.1, aFramingCapability."
::= { icfVgBasicRptr 4 }
icfVgTrainingVersion OBJECT-TYPE
SYNTAX Integer32 (0..7)
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The highest version bits (vvv bits) supported by the
repeater during training."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.1, aRMACVersion."
::= { icfVgBasicRptr 5 }
icfVgRepeaterGroupCapacity OBJECT-TYPE
SYNTAX Integer32 (1..1024)
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The icfVgGroupCapacity is the number of groups that
can be contained within the repeater. Within each
managed repeater, the groups are uniquely numbered in
the range from 1 to icfVgRepeaterGroupCapacity.
Some groups may not be present in the repeater, in
which case the actual number of groups present will
be less than icfVgRepeaterGroupCapacity. The number
of groups present is never greater than
icfVgRepeaterGroupCapacity."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.1, aRepeaterGroupCapacity."
::= { icfVgBasicRptr 6 }
icfVgRepeaterHealthState OBJECT-TYPE
SYNTAX INTEGER {
other(1),
ok(2),
rptrFailure(3),
groupFailure(4),
portFailure(5),
generalFailure(6)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The icfVgRepeaterHealthState object indicates the
operational state of the repeater. The
icfVgRepeaterHealthText may be consulted for more
specific information about the state of the
repeater's health.
In the case of multiple kinds of failures (e.g.,
repeater failure and port failure), the value of this
attribute shall reflect the highest priority failure
in the following order, listed highest priority
first:
rptrFailure(3)
groupFailure(4)
portFailure(5)
generalFailure(6)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.1, aRepeaterHealthState."
::= { icfVgBasicRptr 7 }
icfVgRepeaterHealthText OBJECT-TYPE
SYNTAX DisplayString (SIZE(0..255))
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The health text object is a text string that
provides information relevant to the operational
state of the repeater. Agents may use this string to
provide detailed information on current failures,
including how they were detected, and/or instructions
for problem resolution. The contents are agent
specific."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.1, aRepeaterHealthText."
::= { icfVgBasicRptr 8 }
icfVgRepeaterReset OBJECT-TYPE
SYNTAX INTEGER {
noReset(1),
reset(2)
}
MAX-ACCESS read-write
STATUS current
DESCRIPTION
"Setting this object to reset(2) causes the repeater
to transition to its initial state as specified in
clause 12 [IEEE Draft Std 802.12].
Setting this object to noReset(1) has no effect. The
agent will always return the value noReset(1) when
this object is read.
After receiving a request to set this variable to
reset(2), the agent is allowed to delay the reset for
a short period. For example, the implementor may
choose to delay the reset long enough to allow the
SNMP response to be transmitted. In any event, the
SNMP response must be transmitted.
This action does not reset the management counters
defined in this document nor does it affect the
icfVgPortAdminStatus parameters. Included in this
action is the execution of a disruptive Self-Test
with the following characteristics: a) The nature
of the tests is not specified. b) The test resets
the repeater but without affecting management
information about the repeater. c) The test does not
inject packets onto any segment. d) Packets received
during the test may or may not be transferred.
e) The test does not interfere with management
functions.
After performing this self-test, the agent will
update the repeater health information (including
icfVgRepeaterHealthState and
icfVgRepeaterHealthText)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.2, acResetRepeater."
::= { icfVgBasicRptr 9 }
icfVgRepeaterNonDisruptTest OBJECT-TYPE
SYNTAX INTEGER {
noSelfTest(1),
selfTest(2)
}
MAX-ACCESS read-write
STATUS current
DESCRIPTION
"Setting this object to selfTest(2) causes the
repeater to perform an agent-specific, non-disruptive
self-test that has the following characteristics:
a) The nature of the tests is not specified. b) The
test does not change the state of the repeater or
management information about the repeater. c) The
test does not inject packets onto any segment.
d) The test does not prevent the relay of any
packets. e) The test does not interfere with
management functions.
After performing this test, the agent will update the
repeater health information (including
icfVgRepeaterHealthState and
icfVgRepeaterHealthText).
Note that this definition allows returning an 'okay'
result after doing a trivial test.
Setting this object to noSelfTest(1) has no effect.
The agent will always return the value noSelfTest(1)
when this object is read."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.2, acExecuteNonDisruptiveSelfTest."
::= { icfVgBasicRptr 10 }
icfVgBasicGroup OBJECT IDENTIFIER ::= { icfVgBasic 2 }
icfVgBasicGroupTable OBJECT-TYPE
SYNTAX SEQUENCE OF IcfVgBasicGroupEntry
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"A table containing information about groups of
ports."
::= { icfVgBasicGroup 1 }
icfVgBasicGroupEntry OBJECT-TYPE
SYNTAX IcfVgBasicGroupEntry
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"An entry in the icfVgBasicGroupTable, containing
information about a single group of ports."
INDEX { icfVgGroupIndex }
::= { icfVgBasicGroupTable 1 }
IcfVgBasicGroupEntry ::=
SEQUENCE {
icfVgGroupIndex Integer32,
icfVgGroupDescr DisplayString,
icfVgGroupObjectID OBJECT IDENTIFIER,
icfVgGroupOperStatus INTEGER,
icfVgGroupLastOperStatusChange TimeStamp,
icfVgGroupPortCapacity Integer32,
icfVgGroupCablesBundled INTEGER
}
icfVgGroupIndex OBJECT-TYPE
SYNTAX Integer32 (1..1024)
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"This object identifies the group within the repeater
for which this entry contains information. This
value is never greater than
icfVgRepeaterGroupCapacity."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.4.1, aGroupID."
::= { icfVgBasicGroupEntry 1 }
icfVgGroupDescr OBJECT-TYPE
SYNTAX DisplayString (SIZE (0..255))
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"A textual description of the group. This value
should include the full name and version
identification of the group's hardware type and
indicate how the group is differentiated from other
types of groups in the repeater. 'Plug-in Module,
Rev A' or 'Barney Rubble 100BaseVG 4-port socket
Version 2.1' are examples of valid group
descriptions.
It is mandatory that this only contain printable
ASCII characters."
::= { icfVgBasicGroupEntry 2 }
icfVgGroupObjectID OBJECT-TYPE
SYNTAX OBJECT IDENTIFIER
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The vendor's authoritative identification of the
group. This value may be allocated within the SMI
enterprises subtree (1.3.6.1.4.1) and provides a
straight-forward and unambiguous means for
determining what kind of group is being managed.
For example, this object could take the value
1.3.6.1.4.1.4242.1.2.14 if vendor 'Flintstones, Inc.'
was assigned the subtree 1.3.6.1.4.1.4242, and had
assigned the identifier 1.3.6.1.4.1.4242.1.2.14 to
its 'Wilma Flintstone 6-Port Plug-in Module.'"
::= { icfVgBasicGroupEntry 3 }
icfVgGroupOperStatus OBJECT-TYPE
SYNTAX INTEGER {
other(1),
operational(2),
malfunctioning(3),
notPresent(4),
underTest(5),
resetInProgress(6)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"An object that indicates the operational status of
the group.
A status of notPresent(4) indicates that the group is
temporarily or permanently physically and/or
logically not a part of the repeater. It is an
implementation-specific matter as to whether the
agent effectively removes notPresent entries from the
table.
A status of operational(2) indicates that the group
is functioning, and a status of malfunctioning(3)
indicates that the group is malfunctioning in some
way."
::= { icfVgBasicGroupEntry 4 }
icfVgGroupLastOperStatusChange OBJECT-TYPE
SYNTAX TimeStamp
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"An object that contains the value of sysUpTime at
the time that the value of the icfVgGroupOperStatus
object for this group last changed.
A value of zero indicates that the group's
operational status has not changed since the agent
last restarted."
::= { icfVgBasicGroupEntry 5 }
icfVgGroupPortCapacity OBJECT-TYPE
SYNTAX Integer32 (1..1024)
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The icfVgGroupPortCapacity is the number of ports
that can be contained within the group. Valid range
is 1-1024. Within each group, the ports are uniquely
numbered in the range from 1 to
icfVgGroupPortCapacity. Some ports may not be
present in a given group instance, in which case the
actual number of ports present is less than
icfVgGroupPortCapacity. The number of ports present
is never greater than icfVgGroupPortCapacity."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.4.1, aGroupPortCapacity."
::= { icfVgBasicGroupEntry 6 }
icfVgGroupCablesBundled OBJECT-TYPE
SYNTAX INTEGER {
someCablesBundled(1),
noCablesBundled(2)
}
MAX-ACCESS read-write
STATUS current
DESCRIPTION
"This configuration flag is used to select either
bundled or unbundled cabling. When this flag is
'someCablesBundled(1)' and the port is not
promiscuous or cascaded, frames received from ports
on this group and destined to go out multiple ports
on this group will be buffered completely before
being repeated out ports on this group. When this
flag is 'noCablesBundled(2)' or the port is
promiscuous or cascaded, these frames will be
repeated out ports on this group as the frame is
being received.
Note that the value 'someCablesBundled(1)' will work
in the vast majority of installations, regardless of
whether or not any cables are physically in a bundle,
since promiscuous and cascaded ports automatically
avoid the store and forward. The main situation in
which 'noCablesBundled(2)' is beneficial is when
there is a large amount of multicast traffic and the
cables are not in a bundle. The value of this
object should be preserved across repeater resets
and power failures."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.4.1, aGroupCablesBundled."
::= { icfVgBasicGroupEntry 7 }
icfVgBasicPort OBJECT IDENTIFIER ::= { icfVgBasic 3 }
icfVgBasicPortTable OBJECT-TYPE
SYNTAX SEQUENCE OF IcfVgBasicPortEntry
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"A table containing information about ports."
::= { icfVgBasicPort 1 }
icfVgBasicPortEntry OBJECT-TYPE
SYNTAX IcfVgBasicPortEntry
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"An entry in the icfVgBasicPortTable, containing
information about a single port."
INDEX { icfVgPortGroupIndex, icfVgPortIndex }
::= { icfVgBasicPortTable 1 }
IcfVgBasicPortEntry ::=
SEQUENCE {
icfVgPortGroupIndex Integer32,
icfVgPortIndex Integer32,
icfVgPortType INTEGER,
icfVgPortAdminStatus INTEGER,
icfVgPortStatus INTEGER,
icfVgPortSupportedPromiscMode INTEGER,
icfVgPortSupportedCascadeMode INTEGER,
icfVgPortAllowedTrainType INTEGER,
icfVgPortLastTrainConfig OCTET STRING,
icfVgPortTrainingResult OCTET STRING,
icfVgPortPriorityEnable TruthValue,
icfVgPortMediaType INTEGER
}
icfVgPortGroupIndex OBJECT-TYPE
SYNTAX Integer32 (1..1024)
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"This object identifies the group containing the port
for which this entry contains information."
::= { icfVgBasicPortEntry 1 }
icfVgPortIndex OBJECT-TYPE
SYNTAX Integer32 (1..1024)
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"This object identifies the port within the group for
which this entry contains information. This value
can never be greater than icfVgGroupPortCapacity for
the associated group."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aPortID."
::= { icfVgBasicPortEntry 2 }
icfVgPortType OBJECT-TYPE
SYNTAX INTEGER {
cascadeExternal(1),
cascadeInternal(2),
localExternal(3),
localInternal(4)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"Describes the type of port. One of the following:
cascadeExternal - Port is an uplink with physical
connections which are
externally visible
cascadeInternal - Port is an uplink with physical
connections which are not
externally visible, such as a
connection to an internal
backplane in a chassis
localExternal - Port is a downlink or local
port with externally visible
connections
localInternal - Port is a downlink or local
port with connections which are
not externally visible, such as
a connection to an internal
agent
'internal' is used to identify ports which place
traffic into the repeater, but do not have any
external connections. Note that both DTE and
cascaded repeater downlinks are considered 'local'
ports."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aPortType."
::= { icfVgBasicPortEntry 3 }
icfVgPortAdminStatus OBJECT-TYPE
SYNTAX INTEGER {
enabled(1),
disabled(2)
}
MAX-ACCESS read-write
STATUS current
DESCRIPTION
"Port enable/disable function. Enabling a disabled
port will cause training to be initiated. Setting
this object to disabled(2) disables the port. A
disabled port neither transmits nor receives. Once
disabled, a port must be explicitly enabled to
restore operation. A port which is disabled when
power is lost or when a reset is exerted shall remain
disabled when normal operation resumes."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aPortAdministrativeState."
::= { icfVgBasicPortEntry 4 }
icfVgPortStatus OBJECT-TYPE
SYNTAX INTEGER {
active(1),
inactive(2),
training(3)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"Current status for the port as specified by the
PORT_META_STATE in the port process module of clause
12 [IEEE Draft Std 802.12].
During initialization or any link warning conditions,
icfVgPortStatus will be 'inactive(2)'.
When Training_Up is received by the repeater on a
local port (or when Training_Down is received on
a cascade port), icfVgPortStatus will change to
'training(3)' and icfVgTrainingResult can be
monitored to see the detailed status regarding
training.
When 24 consecutive good FCS packets are received and
the configuration bits are OK, icfVgPortStatus will
change to 'active(1)'.
A disabled port shall have a port status of
'inactive(2)'."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aPortStatus."
::= { icfVgBasicPortEntry 5 }
icfVgPortSupportedPromiscMode OBJECT-TYPE
SYNTAX INTEGER {
singleModeOnly(1),
singleOrPromiscMode(2),
promiscModeOnly(3)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object describes whether the port hardware is
capable of supporting promiscuous mode, single
address mode (i.e., repeater filters unicasts not
addressed to the end station attached to this port),
or both. A port for which icfVgPortType is equal to
'cascadeInternal' or 'cascadeExternal' will always
have a value of 'promiscModeOnly' for this object."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aSupportedPromiscMode."
::= { icfVgBasicPortEntry 6 }
icfVgPortSupportedCascadeMode OBJECT-TYPE
SYNTAX INTEGER {
endNodesOnly(1),
endNodesOrRepeaters(2),
cascadePort(3)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object describes whether the port hardware is
capable of supporting cascaded repeaters, end nodes,
or both. A port for which icfVgPortType is equal to
'cascadeInternal' or 'cascadeExternal' will always
have a value of 'cascadePort' for this object."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aSupportedCascadeMode."
::= { icfVgBasicPortEntry 7 }
icfVgPortAllowedTrainType OBJECT-TYPE
SYNTAX INTEGER {
allowEndNodesOnly(1),
allowPromiscuousEndNodes(2),
allowEndNodesOrRepeaters(3),
allowAnything(4)
}
MAX-ACCESS read-write
STATUS current
DESCRIPTION
"This security object is set by the network manager
to configure what type of device is permitted to
connect to the port. One of the following values:
allowEndNodesOnly - only non-promiscuous
end nodes permitted.
allowPromiscuousEndNodes - promiscuous or non-
promiscuous end nodes
permitted
allowEndNodesOrRepeaters - repeaters or non-
promiscuous end nodes
permitted
allowAnything - repeaters, promiscuous
or non-promiscuous end
nodes permitted
For a port for which icfVgPortType is equal to
'cascadeInternal' or 'cascadeExternal', the
corresponding instance of this object may not be set
to 'allowEndNodesOnly' or 'allowPromiscuousEndNodes'.
The agent must reject a SET of this object if the
value includes no capabilities that are supported by
this port's hardware, as defined by the values of the
corresponding instances of
icfVgPortSupportedPromiscMode and
icfVgPortSupportedCascadeMode."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aAllowableTrainingType."
::= { icfVgBasicPortEntry 8 }
icfVgPortLastTrainConfig OBJECT-TYPE
SYNTAX OCTET STRING (SIZE(2))
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This 16 bit field contains the most recent training
configuration in an error-free training frame
sent by the end node connected to the port. For
cascade ports, this is the responder's configuration
field from the most recent error-free training
response frame received in response to training
initiated by this repeater. This object is formatted
as follows:
First Octet: Second Octet:
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+
|v|v|v|0|0|0|0|0| |0|0|0|F|F|P|P|R|
+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+
vvv: The version of the 802.12 training protocol
with which the training initiator is
compliant
FF: 00 = frameType88023 is requested
01 = frameType88025 is requested
10 = reserved
11 = either frameType88023 or frameType88025
is acceptable
PP: 00 = request singleAddressMode
01 = request promiscuousMode
10 = reserved
11 = reserved
R: 0 = request is from an end node
1 = request is from a repeater"
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aLastTrainingConfig."
::= { icfVgBasicPortEntry 9 }
icfVgPortTrainingResult OBJECT-TYPE
SYNTAX OCTET STRING (SIZE(3))
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This 18 bit field is used to indicate the result of
training. It contains two bits which indicate if
error-free training frames have been received, and it
also contains the 16 bits of the most recent valid
training response frame on the port.
First Octet: Second Octet: Third Octet:
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+
|0|0|0|0|0|0|V|G| |v|v|v|D|C|N|0|0| |0|0|0|F|F|P|P|R|
+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+
V: Valid: set when at least one error-free
training frame has been received. Indicates
the 16 training configuration bits in
icfVgPortLastTrainConfig and
icfVgPortTrainingResult contain valid
information. This bit is cleared when
icfVgPortStatus transitions to the
'inactive' or 'training' state.
G: LinkGood: indicates the link hardware is OK.
Set if 24 consecutive error-free training
packets have been received. Cleared when a
training packet with errors is received, and
when icfVgPortStatus transitions to the
'inactive' or 'training' state.
vvv: The version of the 802.12 training protocol
with which the training responder is
compliant
D: 0 = no duplicate address has been detected
1 = duplicate address has been detected
C: 0 = the requested configuration is
compatible with the port
1 = the requested configuration is not
compatible with the port. The FF, PP
and R bits indicate the configuration
which would be allowed (providing
N = 0).
N: 0 = access will be allowed, providing the
configuration is compatible (C = 0).
1 = access not allowed because of security
restrictions
FF: 00 = frameType88023 will be used
01 = frameType88025 will be used
10 = reserved
11 = reserved
PP: 00 = singleAddressMode will be used
01 = promiscuousMode will be used
10 = reserved
11 = reserved
R: 0 = requested access as an end node is
allowed
1 = requested access as a repeater is
allowed
If the port is in training, a management station can
examine this object to see if any training packets
have been passed successfully. If there have been
any good training packets, the Valid bit will be set
and the management station can examine the 16
training response bits to see if there is a duplicate
address, configuration, or security problem.
Note that on a repeater local port, this repeater
generates the training response bits, while on the
cascade port, the higher level repeater originated
the training response bits."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aTrainingResult."
::= { icfVgBasicPortEntry 10 }
icfVgPortPriorityEnable OBJECT-TYPE
SYNTAX TruthValue
MAX-ACCESS read-write
STATUS current
DESCRIPTION
"A configuration flag used to determine whether the
repeater will service high priority requests received
on the port as high priority or normal priority.
When 'false', high priority requests on this port
will be serviced as normal priority. The value of
this object should be preserved across repeater
resets and power failures. The setting of this
object has no effect on a cascade port."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aPriorityEnable."
::= { icfVgBasicPortEntry 11 }
icfVgPortMediaType OBJECT-TYPE
SYNTAX INTEGER {
other(1),
unknown(2),
pmdMissing(3),
utp4(4),
stp2(5),
fibre(6)
}
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"The type of physical media in use. One of the
following values:
other undefined
unknown true state not known
pmdMissing PMD device not attached
utp4 4-pair unshielded twisted pair
stp2 2-pair shielded twisted pair
fibre 802.12 fibre optic cabling
This object may be 'unknown' if the implementation is
not capable of identifying the PMD media type, or
whether or not the PMD is even present."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aMediaType."
::= { icfVgBasicPortEntry 12 }
icfVgMonitor OBJECT IDENTIFIER ::= { icfVgRepeater 2 }
icfVgMonRptr OBJECT IDENTIFIER ::= { icfVgMonitor 1 }
-- Currently unused
icfVgMonGroup OBJECT IDENTIFIER ::= { icfVgMonitor 2 }
-- Currently unused
icfVgMonPort OBJECT IDENTIFIER ::= { icfVgMonitor 3 }
icfVgMonPortTable OBJECT-TYPE
SYNTAX SEQUENCE OF IcfVgMonPortEntry
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"A table of performance and error statistics for the
ports."
::= { icfVgMonPort 1 }
icfVgMonPortEntry OBJECT-TYPE
SYNTAX IcfVgMonPortEntry
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"An entry in the icfVgMonPortTable, containing
performance and error statistics for a single port."
INDEX { icfVgPortGroupIndex, icfVgPortIndex }
::= { icfVgMonPortTable 1 }
IcfVgMonPortEntry ::=
SEQUENCE {
icfVgPortReadableFrames Counter32,
icfVgPortReadableOctets Counter32,
icfVgPortUnreadableOctets Counter32,
icfVgPortHighPriorityFrames Counter32,
icfVgPortHighPriorityOctets Counter32,
icfVgPortBroadcastFrames Counter32,
icfVgPortMulticastFrames Counter32,
icfVgPortIPMFrames Counter32,
icfVgPortDataErrorFrames Counter32,
icfVgPortPriorityPromotions Counter32,
icfVgPortHCReadableOctets Counter64,
icfVgPortHCUnreadableOctets Counter64,
icfVgPortHCHighPriorityOctets Counter64,
icfVgPortHCNormPriorityOctets Counter64,
icfVgPortNormPriorityFrames Counter32,
icfVgPortNormPriorityOctets Counter32,
icfVgPortNullAddressedFrames Counter32,
icfVgPortOversizeFrames Counter32,
icfVgPortTransitionToTrainings Counter32
}
icfVgPortReadableFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is the number of good frames of valid
frame length that have been received on this port.
This counter is incremented by one for each frame
received on the port which is not counted by
icfVgPortIPMFrames or icfVgPortDataErrorFrames."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aReadableFramesReceived."
::= { icfVgMonPortEntry 1 }
icfVgPortReadableOctets OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of octets
contained in good frames that have been received on
this port. This counter is incremented by OctetCount
for each frame received on this port which has been
determined to be a readable frame (i.e. each frame
counted by icfVgPortReadableFrames).
Note that this counter will roll over very quickly.
It is provided for backward compatibility for Network
Management protocols that do not support 64 bit
counters (e.g. SNMP version 1)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aReadableOctetsReceived."
::= { icfVgMonPortEntry 2 }
icfVgPortUnreadableOctets OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of octets
contained in invalid frames that have been received
on this port. This counter is incremented by
OctetCount for each frame received on this port which
is counted by icfVgPortIPMFrames or
icfVgPortDataErrorFrames. This counter can be
combined with icfVgPortReadableOctets to calculate
network utilization.
Note that this counter will roll over very quickly.
It is provided for backward compatibility for Network
Management protocols that do not support 64 bit
counters (e.g. SNMP version 1)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aOctetsInUnreadableFramesRcvd."
::= { icfVgMonPortEntry 3 }
icfVgPortHighPriorityFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of high priority frames
that have been received on this port. This counter
is incremented by one for each high priority frame
received on this port, including readable, invalid,
and training frames. This counter does not include
normal priority frames which were priority promoted."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aHighPriorityFramesReceived."
::= { icfVgMonPortEntry 4 }
icfVgPortHighPriorityOctets OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of octets
contained in high priority frames that have been
received on this port. This counter is incremented
by OctetCount for each frame received on this port
which is counted by icfVgPortHighPriorityFrames.
Note that this counter will roll over very quickly.
It is provided for backward compatibility for Network
Management protocols that do not support 64 bit
counters (e.g. SNMP version 1)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aHighPriorityOctetsReceived."
::= { icfVgMonPortEntry 5 }
icfVgPortBroadcastFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of broadcast packets that
have been received on this port. This counter is
incremented by one for each readable frame received
on this port whose destination MAC address is the
broadcast address. Frames counted by this counter
are also counted by icfVgPortReadableFrames."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aBroadcastFramesReceived."
::= { icfVgMonPortEntry 6 }
icfVgPortMulticastFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of multicast packets that
have been received on this port. This counter is
incremented by one for each readable frame received
on this port whose destination MAC address has the
group address bit set, but is not the broadcast
address. Frames counted by this counter are also
counted by icfVgPortReadableFrames, but not by
icfVgPortBroadcastFrames"
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aMulticastFramesReceived."
::= { icfVgMonPortEntry 7 }
icfVgPortIPMFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of frames that
have been received on this port with an invalid
packet marker and no PMI errors. A repeater will
write an invalid packet marker to the end of a frame
containing errors as it is forwarded through the
repeater to the other ports. This counter is
incremented by one for each frame received on this
port which has had an invalid packet marker added to
the end of the frame. This counter indicates
problems with remote cable segments, as opposed to
problems with cables directly attached to this
repeater."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aIPMFramesReceived."
::= { icfVgMonPortEntry 8 }
icfVgPortDataErrorFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of errored frames received on
this port. This counter is incremented by one for
each frame received on this port with any of the
following errors: bad FCS (with no IPM), PMI errors
(excluding frames with an IPM error as the only PMI
error), or undersize (with no IPM). Does not include
packets counted by icfVgPortIPMFrames,
icfVgPortOversizeFrames, or
icfVgPortNullAddressedFrames.
This counter indicates problems with the cable
directly attached to this repeater, while
icfVgPortIPMFrames indicates problems with remote
cables attached to other repeaters."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aDataErrorFramesReceived."
::= { icfVgMonPortEntry 9 }
icfVgPortPriorityPromotions OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This counter is incremented by one each time the
priority promotion timer has expired on this port and
a normal priority frame was priority promoted."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aPriorityPromotions."
::= { icfVgMonPortEntry 10 }
icfVgPortHCReadableOctets OBJECT-TYPE
SYNTAX Counter64
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of octets
contained in good frames that have been received on
this port. This counter is incremented by OctetCount
for each frame received on this port which has been
determined to be a readable frame (i.e. each frame
counted by icfVgPortReadableFrames).
This counter is a 64 bit version of
icfVgPortReadableOctets. It should be used by
Network Management protocols which support 64 bit
counters (e.g. SNMPv2)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aReadableOctetsReceived."
::= { icfVgMonPortEntry 11 }
icfVgPortHCUnreadableOctets OBJECT-TYPE
SYNTAX Counter64
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of octets
contained in invalid frames that have been received
on this port. This counter is incremented by
OctetCount for each frame received on this port which
is counted by icfVgPortIPMFrames or
icfVgPortDataErrorFrames. This counter can be
combined with icfVgPortHCReadableOctets to calculate
network utilization.
This counter is a 64 bit version of
icfVgPortUnReadableOctets. It should be used by
Network Management protocols which support 64 bit
counters (e.g. SNMPv2)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aOctetsInUnreadableFramesRcvd."
::= { icfVgMonPortEntry 12 }
icfVgPortHCHighPriorityOctets OBJECT-TYPE
SYNTAX Counter64
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of octets
contained in high priority frames that have been
received on this port. This counter is incremented
by OctetCount for each frame received on this port
which is counted by icfVgPortHighPriorityFrames.
This counter is a 64 bit version of
icfVgPortHighPriorityOctets. It should be used by
Network Management protocols which support 64 bit
counters (e.g. SNMPv2)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aHighPriorityOctetsReceived."
::= { icfVgMonPortEntry 13 }
icfVgPortHCNormPriorityOctets OBJECT-TYPE
SYNTAX Counter64
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of octets
contained in normal priority frames that have been
received on this port. This counter is incremented
by OctetCount for each frame received on this port
which is counted by icfVgPortNormPriorityFrames.
This counter is a 64 bit version of
icfVgPortNormPriorityOctets. It should be used by
Network Management protocols which support 64 bit
counters (e.g. SNMPv2)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aNormalPriorityOctetsReceived."
::= { icfVgMonPortEntry 14 }
icfVgPortNormPriorityFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of normal priority frames
that have been received on this port. This counter
is incremented by one for each normal priority frame
received on this port. This counter includes both
good and bad normal priority frames, as well as
normal priority training frames and normal priority
frames which were priority promoted."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aNormalPriorityFramesReceived."
::= { icfVgMonPortEntry 15 }
icfVgPortNormPriorityOctets OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of the number of octets
contained in normal priority frames that have been
received on this port. This counter is incremented
by OctetCount for each frame received on this port
which is counted by icfVgPortNormPriorityFrames.
Note that this counter will roll over very quickly.
It is provided for backward compatibility for Network
Management protocols that do not support 64 bit
counters (e.g. SNMP version 1)."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aNormalPriorityOctetsReceived."
::= { icfVgMonPortEntry 16 }
icfVgPortNullAddressedFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of null addressed packets
that have been received on this port. This counter
is incremented by one for each frame received on this
port with a destination MAC address consisting of all
zero bits. Both void and training frames are
included in this counter."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aNullAddressedFramesReceived."
::= { icfVgMonPortEntry 17 }
icfVgPortOversizeFrames OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is a count of oversize frames received
on this port. This counter is incremented by one for
each frame received on this port whose OctetCount is
larger than the maximum legal frame size.
The frame size which causes this counter to increment
is dependent on the current value of
icfVgCurrentFramingType. When
icfVgCurrentFramingType is equal to frameType88023
this counter will increment for frames that are 1519
octets or larger. When icfVgCurrentFramingType is
equal to frameType88025 this counter will increment
for frames that are 4521 octets or larger."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aOversizeFramesReceived."
::= { icfVgMonPortEntry 18 }
icfVgPortTransitionToTrainings OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This counter is incremented by one each time the
icfVgPortStatus object for this port transitions into
the 'training' state."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aTransitionsIntoTraining."
::= { icfVgMonPortEntry 19 }
icfVgAddrTrack OBJECT IDENTIFIER ::= { icfVgRepeater 3 }
icfVgAddrTrackRptr OBJECT IDENTIFIER ::= { icfVgAddrTrack 1 }
-- Currently unused
icfVgAddrTrackGroup OBJECT IDENTIFIER ::= { icfVgAddrTrack 2 }
-- Currently unused
icfVgAddrTrackPort OBJECT IDENTIFIER ::= { icfVgAddrTrack 3 }
icfVgAddrTrackTable OBJECT-TYPE
SYNTAX SEQUENCE OF IcfVgAddrTrackEntry
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"Table of address mapping information about the
ports."
::= { icfVgAddrTrackPort 1 }
icfVgAddrTrackEntry OBJECT-TYPE
SYNTAX IcfVgAddrTrackEntry
MAX-ACCESS not-accessible
STATUS current
DESCRIPTION
"An entry in the table, containing address mapping
information about a single port."
INDEX { icfVgPortGroupIndex, icfVgPortIndex }
::= { icfVgAddrTrackTable 1 }
IcfVgAddrTrackEntry ::=
SEQUENCE {
icfVgAddrLastTrainedAddress OCTET STRING,
icfVgAddrTrainedAddrChanges Counter32,
icfVgRptrDetectedDupAddress TruthValue,
icfVgMgrDetectedDupAddress TruthValue
}
icfVgAddrLastTrainedAddress OBJECT-TYPE
SYNTAX OCTET STRING (SIZE(0 | 6))
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is the MAC address of the last station
which succeeded in training on this port. A
cascaded repeater may train using the null address.
If no stations have succeeded in training on this
port since the agent began monitoring the port
activity, the agent shall return a string of length
zero."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aLastTrainedAddress."
::= { icfVgAddrTrackEntry 1 }
icfVgAddrTrainedAddrChanges OBJECT-TYPE
SYNTAX Counter32
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This counter is incremented by one for each time
that the icfVgAddrLastTrainedAddress object for this
port has changed."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aTrainedAddressChanges."
::= { icfVgAddrTrackEntry 2 }
icfVgRptrDetectedDupAddress OBJECT-TYPE
SYNTAX TruthValue
MAX-ACCESS read-only
STATUS current
DESCRIPTION
"This object is used to indicate that the repeater
detected an error-free training frame on this port
with a source MAC address which matches the value of
icfVgAddrLastTrainedAddress of another active port.
This is reset to 'false' when an error-free training
frame is received with a source MAC address which
does not match icfVgAddrLastTrainedAddress of another
port which is active. For the cascade port, this
object will be 'true' if the 'D' bit in the most
recently received error-free training response frame
was set."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aLocalRptrDetectedDupAddr."
::= { icfVgAddrTrackEntry 3 }
icfVgMgrDetectedDupAddress OBJECT-TYPE
SYNTAX TruthValue
MAX-ACCESS read-write
STATUS current
DESCRIPTION
"This object can be set by a management station when
it detects that there is a duplicate MAC address.
This object is OR'd with icfVgRptrDetectedDupAddress
to form the value of the 'D' bit in training response
frames on this port.
The purpose of this object is to provide a means for
network management software to inform an end station
that it is using a duplicate station address.
Setting this object does not affect the current state
of the link; the end station will not be informed of
the duplicate address until it retrains for some
reason. Note that regardless of its station address,
the end station will not be able to train
successfully until the network management software
has set this object back to 'false'. Although this
object exists on cascade ports, it does not perform
any function since this repeater is the initiator of
training on a cascade port."
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.5.1, aCentralMgmtDetectedDupAddr."
::= { icfVgAddrTrackEntry 4 }
icfVgRptrTraps OBJECT IDENTIFIER ::= { icfVgRepeater 4 }
icfVgRptrTrapsPrefix OBJECT IDENTIFIER ::= { icfVgRptrTraps 0 }
icfVgRptrHealth NOTIFICATION-TYPE
OBJECTS { icfVgRepeaterHealthState }
STATUS current
DESCRIPTION
"A icfVgRptrHealth trap conveys information related
to the operational state of the repeater. This trap
is sent either when the value of
icfVgRepeaterHealthState changes, or upon completion
of a non-disruptive test. The icfVgRptrHealth trap
is not sent as a result of powering up a repeater.
The icfVgRptrHealth trap must contain the
icfVgRepeaterHealthState object. The agent may
optionally include the icfVgRepeaterHealthText object
in the varBind list. See the
icfVgRepeaterHealthState and icfVgRepeaterHealthText
objects for descriptions of the information that is
sent.
The agent must throttle the generation of consecutive
icfVgRptrHealth traps so that there is at least a
five-second gap between traps of this type. When
traps are throttled, they are dropped, not queued for
sending at a future time. (Note that 'generating' a
trap means sending to all configured recipients.)"
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.3, nRepeaterHealth."
::= { icfVgRptrTrapsPrefix 1 }
icfVgRptrResetEvent NOTIFICATION-TYPE
OBJECTS { icfVgRepeaterHealthState }
STATUS current
DESCRIPTION
"An icfVgRptrResetEvent trap conveys information
related to the operational state of the repeater.
This trap is sent on completion of a repeater reset
action. A repeater reset action is defined as a
transition to its initial state as specified in
clause 12 [IEEE Draft Std 802.12] when triggered by a
management command.
The icfVgRptrResetEvent trap is not sent when the
agent restarts and sends an SNMP coldStart or
warmStart trap. However, it is recommended that an
802.12 repeater agent send the
icfVgRepeaterHealthState object as an optional object
with its coldStart and warmStart trap PDUs.
The icfVgRptrResetEvent trap must contain the
icfVgRepeaterHealthState object. The agent may
optionally include the icfVgRepeaterHealthText object
in the varBind list. See the
icfVgRepeaterHealthState and icfVgRepeaterHealthText
objects for descriptions of the information that is
sent.
The agent must throttle the generation of consecutive
icfVgRptrResetEvent traps so that there is at least a
five-second gap between traps of this type. When
traps are throttled, they are dropped, not queued for
sending at a future time. (Note that 'generating' a
trap means sending to all configured recipients.)"
REFERENCE
"IEEE Draft Std. 802.12, Draft 6, 23 November, 1994,
13.2.4.2.3, nRepeaterReset."
::= { icfVgRptrTrapsPrefix 3 }
-- conformance information
icfVgRepeaterConformance
OBJECT IDENTIFIER ::= { icfVgRepeaterMib 1 }
icfVgRepeaterCompliances
OBJECT IDENTIFIER ::= { icfVgRepeaterConformance 1 }
icfVgRepeaterGroups
OBJECT IDENTIFIER ::= { icfVgRepeaterConformance 2 }
-- Compliance statements
icfVgRptrPreStdCompliance MODULE-COMPLIANCE
STATUS obsolete
DESCRIPTION
"********* THIS COMPLIANCE IS OBSOLETE *********
The compliance statement for pre-standard 802.12
repeater management."
MODULE
MANDATORY-GROUPS { icfVgRptrBasicGroup,
icfVgRptrPreStdMonitorGroup,
icfVgRptrPreStdAddrTrackGroup,
icfVgRptrNotificationsGroup }
::= { icfVgRepeaterCompliances 1 }
icfVgRptrCompliance MODULE-COMPLIANCE
STATUS current
DESCRIPTION
"The compliance statement for 802.12 repeater
management."
MODULE
MANDATORY-GROUPS { icfVgRptrBasicGroup,
icfVgRptrMonitorGroup,
icfVgRptrAddrTrackGroup,
icfVgRptrNotificationsGroup }
::= { icfVgRepeaterCompliances 2 }
-- Units of conformance
icfVgRptrBasicGroup OBJECT-GROUP
OBJECTS { icfVgMACAddress,
icfVgCurrentFramingType,
icfVgDesiredFramingType,
icfVgFramingCapability,
icfVgTrainingVersion,
icfVgRepeaterGroupCapacity,
icfVgRepeaterHealthState,
icfVgRepeaterHealthText,
icfVgRepeaterReset,
icfVgRepeaterNonDisruptTest,
icfVgGroupDescr,
icfVgGroupObjectID,
icfVgGroupOperStatus,
icfVgGroupLastOperStatusChange,
icfVgGroupPortCapacity,
icfVgGroupCablesBundled,
icfVgPortType,
icfVgPortAdminStatus,
icfVgPortStatus,
icfVgPortSupportedPromiscMode,
icfVgPortSupportedCascadeMode,
icfVgPortAllowedTrainType,
icfVgPortLastTrainConfig,
icfVgPortTrainingResult,
icfVgPortPriorityEnable,
icfVgPortMediaType
}
STATUS current
DESCRIPTION
"A collection of objects for managing the status
and configuration of IEEE 802.12 repeaters."
::= { icfVgRepeaterGroups 1 }
icfVgRptrPreStdMonitorGroup OBJECT-GROUP
OBJECTS { icfVgPortReadableFrames,
icfVgPortReadableOctets,
icfVgPortUnreadableOctets,
icfVgPortHighPriorityFrames,
icfVgPortHighPriorityOctets,
icfVgPortBroadcastFrames,
icfVgPortMulticastFrames,
icfVgPortIPMFrames,
icfVgPortDataErrorFrames,
icfVgPortPriorityPromotions,
icfVgPortHCReadableOctets,
icfVgPortHCUnreadableOctets,
icfVgPortHCHighPriorityOctets
}
STATUS obsolete
DESCRIPTION
"********* THIS GROUP IS OBSOLETE *********
A collection of objects for providing statistics
for pre-standard IEEE 802.12 repeaters."
::= { icfVgRepeaterGroups 2 }
icfVgRptrPreStdAddrTrackGroup OBJECT-GROUP
OBJECTS { icfVgAddrLastTrainedAddress,
icfVgAddrTrainedAddrChanges
}
STATUS obsolete
DESCRIPTION
"********* THIS GROUP IS OBSOLETE *********
A collection of objects for tracking addresses
on pre-standard IEEE 802.12 repeaters."
::= { icfVgRepeaterGroups 3 }
icfVgRptrMonitorGroup OBJECT-GROUP
OBJECTS { icfVgPortReadableFrames,
icfVgPortReadableOctets,
icfVgPortUnreadableOctets,
icfVgPortHighPriorityFrames,
icfVgPortHighPriorityOctets,
icfVgPortBroadcastFrames,
icfVgPortMulticastFrames,
icfVgPortIPMFrames,
icfVgPortDataErrorFrames,
icfVgPortPriorityPromotions,
icfVgPortHCReadableOctets,
icfVgPortHCUnreadableOctets,
icfVgPortHCHighPriorityOctets,
icfVgPortHCNormPriorityOctets,
icfVgPortNormPriorityFrames,
icfVgPortNormPriorityOctets,
icfVgPortNullAddressedFrames,
icfVgPortOversizeFrames,
icfVgPortTransitionToTrainings
}
STATUS current
DESCRIPTION
"A collection of objects for providing statistics
for IEEE 802.12 repeaters."
::= { icfVgRepeaterGroups 4 }
icfVgRptrAddrTrackGroup OBJECT-GROUP
OBJECTS { icfVgAddrLastTrainedAddress,
icfVgAddrTrainedAddrChanges,
icfVgRptrDetectedDupAddress,
icfVgMgrDetectedDupAddress
}
STATUS current
DESCRIPTION
"A collection of objects for tracking addresses
on IEEE 802.12 repeaters."
::= { icfVgRepeaterGroups 5 }
icfVgRptrNotificationsGroup NOTIFICATION-GROUP
NOTIFICATIONS { icfVgRptrHealth,
icfVgRptrResetEvent
}
STATUS current
DESCRIPTION
"A collection of notifications used to indicate
802.12 repeater general status changes."
::= { icfVgRepeaterGroups 6 }
END