/*
* This module has been generated by smidump 0.4.5:
*
* smidump -f yang MAU-MIB
*
* Do not edit. Edit the source file instead!
*/
module MAU-MIB {
/*** NAMESPACE / PREFIX DEFINITION ***/
namespace "urn:ietf:params:xml:ns:yang:smiv2:MAU-MIB";
prefix "mau-mib";
/*** LINKAGE (IMPORTS / INCLUDES) ***/
import IANA-MAU-MIB { prefix "iana-mau"; }
import IF-MIB { prefix "if-mib"; }
import SNMPv2-TC { prefix "smiv2"; }
import yang-types { prefix "yang"; }
/*** META INFORMATION ***/
organization
"IETF Ethernet Interfaces and Hub MIB Working Group";
contact
"WG charter:
http://www.ietf.org/html.charters/hubmib-charter.html
Mailing Lists:
General Discussion: hubmib@ietf.org
To Subscribe: hubmib-request@ietf.org
In Body: subscribe your_email_address
Chair: Bert Wijnen
Postal: Alcatel-Lucent
Schagen 33
3461 GL Linschoten
Netherlands
Phone: +31-348-407-775
EMail: bwijnen@alcatel-lucent.com
Editor: Edward Beili
Postal: Actelis Networks Inc.
25 Bazel St., P.O.B. 10173
Petach-Tikva 10173
Israel
Tel: +972-3-924-3491
EMail: edward.beili@actelis.com";
description
"Management information for 802.3 MAUs.
The following reference is used throughout this MIB module:
[IEEE802.3] refers to:
IEEE Std 802.3, 2005 Edition: 'IEEE Standard for Information
technology - Telecommunications and information exchange
between systems - Local and metropolitan area networks -
Specific requirements - Part 3: Carrier sense multiple
access with collision detection (CSMA/CD) access method and
physical layer specifications'.
Of particular interest is Clause 30, 'Management'.
Copyright (C) The IETF Trust (2007).
This version of this MIB module is part of RFC 4836;
see the RFC itself for full legal notices.";
revision "2007-04-21" {
description
"Updated to reference IANA maintaned textual
conventions for MAU types, Media Availability state,
Auto Negotiation capabilities, and jack types,
instead of using internally defined values.
This version is published as RFC 4836.";
}
revision "2003-09-19" {
description
"Updated to include support for 10 Gb/s MAUs.
This resulted in the following revisions:
- Added OBJECT-IDENTITY definitions for
10 gigabit MAU types
- Added fiberLC jack type to JackType TC
- Extended ifMauTypeListBits with bits for
the 10 gigabit MAU types
- Added enumerations to ifMauMediaAvailable,
and updated its DESCRIPTION to reflect
behaviour at 10 Gb/s
- Added 64-bit version of ifMauFalseCarriers
and added mauIfGrpHCStats object group to
contain the new object
- Deprecated mauModIfCompl2 and replaced it
with mauModIfCompl3, which includes the new
object group
This version published as RFC 3636.";
}
revision "1999-08-24" {
description
"This version published as RFC 2668. Updated
to include support for 1000 Mb/sec
MAUs and flow control negotiation.";
}
revision "1997-10-31" {
description
"Version published as RFC 2239.";
}
revision "1993-09-30" {
description
"Initial version, published as RFC 1515.";
}
/*** TYPE DEFINITIONS ***/
typedef JackType {
type enumeration {
enum other { value 1; }
enum rj45 { value 2; }
enum rj45S { value 3; }
enum db9 { value 4; }
enum bnc { value 5; }
enum fAUI { value 6; }
enum mAUI { value 7; }
enum fiberSC { value 8; }
enum fiberMIC { value 9; }
enum fiberST { value 10; }
enum telco { value 11; }
enum mtrj { value 12; }
enum hssdc { value 13; }
enum fiberLC { value 14; }
}
status deprecated;
description
"********* THIS TC IS DEPRECATED **********
This TC has been deprecated in favour of
IANAifJackType.
Common enumeration values for repeater
and interface MAU jack types.";
}
container dot3RpMauBasicGroup {
/* XXX table comments here XXX */
list rpMauEntry {
key "rpMauGroupIndex rpMauPortIndex rpMauIndex";
description
"An entry in the table, containing information
about a single MAU.";
leaf rpMauGroupIndex {
type int32 {
range "1..2147483647";
}
config false;
description
"This variable uniquely identifies the group
containing the port to which the MAU described
by this entry is connected.
Note: In practice, a group will generally be
a field-replaceable unit (i.e., module, card,
or board) that can fit in the physical system
enclosure, and the group number will correspond
to a number marked on the physical enclosure.
The group denoted by a particular value of this
object is the same as the group denoted by the
same value of rptrGroupIndex.";
reference
"RFC 2108, rptrGroupIndex.";
}
leaf rpMauPortIndex {
type int32 {
range "1..2147483647";
}
config false;
description
"This variable uniquely identifies the repeater
port within group rpMauGroupIndex to which the
MAU described by this entry is connected.";
reference
"RFC 2108, rptrPortIndex.";
}
leaf rpMauIndex {
type int32 {
range "1..2147483647";
}
config false;
description
"This variable uniquely identifies the MAU
described by this entry from among other
MAUs connected to the same port
(rpMauPortIndex).";
reference
"[IEEE802.3], 30.5.1.1.1, aMAUID.";
}
leaf rpMauType {
type smiv2:AutonomousType;
config false;
description
"This object identifies the MAU type. Values for
standard IEEE 802.3 MAU types are defined in the
IANA maintained IANA-MAU-MIB module, as
OBJECT-IDENTITIES of dot3MauType.
If the MAU type is unknown, the object identifier
zeroDotZero is returned.";
reference
"[IEEE802.3], 30.5.1.1.2, aMAUType.";
}
leaf rpMauStatus {
type enumeration {
enum other { value 1; }
enum unknown { value 2; }
enum operational { value 3; }
enum standby { value 4; }
enum shutdown { value 5; }
enum reset { value 6; }
}
config true;
description
"The current state of the MAU. This object MAY
be implemented as a read-only object by those
agents and MAUs that do not implement software
control of the MAU state. Some agents may not
support setting the value of this object to some
of the enumerated values.
The value other(1) is returned if the MAU is in
a state other than one of the states 2 through
6.
The value unknown(2) is returned when the MAU's
true state is unknown; for example, when it is
being initialized.
A MAU in the operational(3) state is fully
functional; it operates, and passes signals to its
attached DTE or repeater port in accordance to
its specification.
A MAU in standby(4) state forces DI and CI to
idle, and the media transmitter to idle or fault,
if supported. Standby(4) mode only applies to
link type MAUs. The state of
rpMauMediaAvailable is unaffected.
A MAU in shutdown(5) state assumes the same
condition on DI, CI, and the media transmitter,
as though it were powered down or not connected.
The MAU MAY return other(1) value for the
rpMauJabberState and rpMauMediaAvailable objects
when it is in this state. For an AUI, this
state will remove power from the AUI.
Setting this variable to the value reset(6)
resets the MAU in the same manner as a
power-off, power-on cycle of at least one-half
second would. The agent is not required to
return the value reset(6).
Setting this variable to the value
operational(3), standby(4), or shutdown(5)
causes the MAU to assume the respective state,
except that setting a mixing-type MAU or an AUI
to standby(4) will cause the MAU to enter the
shutdown state.";
reference
"[IEEE802.3], 30.5.1.1.7, aMAUAdminState,
30.5.1.2.2, acMAUAdminControl, and 30.5.1.2.1,
acResetMAU.";
}
leaf rpMauMediaAvailable {
type iana-mau:IANAifMauMediaAvailable;
config false;
description
"This object identifies Media Available state of
the MAU, complementary to the rpMauStatus. Values
for the standard IEEE 802.3 Media Available states
are defined in the IANA maintained IANA-MAU-MIB
module, as IANAifMauMediaAvailable TC.";
reference
"[IEEE802.3], 30.5.1.1.4, aMediaAvailable.";
}
leaf rpMauMediaAvailableStateExits {
type yang:counter32;
config false;
description
"A count of the number of times that
rpMauMediaAvailable for this MAU instance leaves
the state available(3).
Discontinuities in the value of this counter can
occur at re-initialization of the management
system and at other times, as indicated by the
value of rptrMonitorPortLastChange.";
reference
"[IEEE802.3], 30.5.1.1.5, aLoseMediaCounter.
RFC 2108, rptrMonitorPortLastChange";
}
leaf rpMauJabberState {
type enumeration {
enum other { value 1; }
enum unknown { value 2; }
enum noJabber { value 3; }
enum jabbering { value 4; }
}
config false;
description
"The value other(1) is returned if the jabber
state is not 2, 3, or 4. The agent MUST always
return other(1) for MAU type dot3MauTypeAUI.
The value unknown(2) is returned when the MAU's
true state is unknown; for example, when it is
being initialized.
If the MAU is not jabbering the agent returns
noJabber(3). This is the 'normal' state.
If the MAU is in jabber state the agent returns
the jabbering(4) value.";
reference
"[IEEE802.3], 30.5.1.1.6, aJabber.jabberFlag.";
}
leaf rpMauJabberingStateEnters {
type yang:counter32;
config false;
description
"A count of the number of times that
mauJabberState for this MAU instance enters the
state jabbering(4). For MAUs of type
dot3MauTypeAUI, dot3MauType100BaseT4,
dot3MauType100BaseTX, dot3MauType100BaseFX, and
all 1000Mbps types, this counter will always
indicate zero.
Discontinuities in the value of this counter can
occur at re-initialization of the management
system and at other times, as indicated by the
value of rptrMonitorPortLastChange.";
reference
"[IEEE802.3], 30.5.1.1.6, aJabber.jabberCounter.
RFC 2108, rptrMonitorPortLastChange";
}
leaf rpMauFalseCarriers {
type yang:counter32;
config false;
description
"A count of the number of false carrier events
during IDLE in 100BASE-X links. This counter
does not increment at the symbol rate. It can
increment after a valid carrier completion at a
maximum rate of once per 100 ms until the next
carrier event.
This counter increments only for MAUs of type
dot3MauType100BaseT4, dot3MauType100BaseTX,
dot3MauType100BaseFX, and all 1000Mbps types.
For all other MAU types, this counter will
always indicate zero.
The approximate minimum time for rollover of
this counter is 7.4 hours.
Discontinuities in the value of this counter can
occur at re-initialization of the management
system and at other times, as indicated by the
value of rptrMonitorPortLastChange.";
reference
"[IEEE802.3], 30.5.1.1.10, aFalseCarriers.
RFC 2108, rptrMonitorPortLastChange";
}
}
/* XXX table comments here XXX */
list rpJackEntry {
key "rpMauGroupIndex rpMauPortIndex rpMauIndex rpJackIndex";
description
"An entry in the table, containing information
about a particular jack.";
leaf rpMauGroupIndex {
type keyref {
path "/mau-mib:dot3RpMauBasicGroup/mau-mib:rpMauEntry/mau-mib:rpMauGroupIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf rpMauPortIndex {
type keyref {
path "/mau-mib:dot3RpMauBasicGroup/mau-mib:rpMauEntry/mau-mib:rpMauPortIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf rpMauIndex {
type keyref {
path "/mau-mib:dot3RpMauBasicGroup/mau-mib:rpMauEntry/mau-mib:rpMauIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf rpJackIndex {
type int32 {
range "1..2147483647";
}
config false;
description
"This variable uniquely identifies the jack
described by this entry from among other jacks
attached to the same MAU (rpMauIndex).";
}
leaf rpJackType {
type iana-mau:IANAifJackType;
config false;
description
"The jack connector type, as it appears on the
outside of the system.";
}
}
}
container dot3IfMauBasicGroup {
/* XXX table comments here XXX */
list ifMauEntry {
key "ifMauIfIndex ifMauIndex";
description
"An entry in the table, containing information
about a single MAU.";
leaf ifMauIfIndex {
type if-mib:InterfaceIndex;
config false;
description
"This variable uniquely identifies the interface
to which the MAU described by this entry is
connected.";
reference
"RFC 2863, ifIndex";
}
leaf ifMauIndex {
type int32 {
range "1..2147483647";
}
config false;
description
"This variable uniquely identifies the MAU
described by this entry from among other MAUs
connected to the same interface (ifMauIfIndex).";
reference
"[IEEE802.3], 30.5.1.1.1, aMAUID.";
}
leaf ifMauType {
type smiv2:AutonomousType;
config false;
description
"This object identifies the MAU type. Values for
standard IEEE 802.3 MAU types are defined in the
IANA maintained IANA-MAU-MIB module, as
OBJECT-IDENTITIES of dot3MauType.
If the MAU type is unknown, the object identifier
zeroDotZero is returned.
This object represents the operational type of
the MAU, as determined by either 1) the result
of the auto-negotiation function or 2) if
auto-negotiation is not enabled or is not
implemented for this MAU, by the value of the
object ifMauDefaultType. In case 2), a set to
the object ifMauDefaultType will force the MAU
into the new operating mode.";
reference
"[IEEE802.3], 30.5.1.1.2, aMAUType.";
}
leaf ifMauStatus {
type enumeration {
enum other { value 1; }
enum unknown { value 2; }
enum operational { value 3; }
enum standby { value 4; }
enum shutdown { value 5; }
enum reset { value 6; }
}
config true;
description
"The current state of the MAU. This object MAY
be implemented as a read-only object by those
agents and MAUs that do not implement software
control of the MAU state. Some agents may not
support setting the value of this object to some
of the enumerated values.
The value other(1) is returned if the MAU is in
a state other than one of the states 2 through
6.
The value unknown(2) is returned when the MAU's
true state is unknown; for example, when it is
being initialized.
A MAU in the operational(3) state is fully
functional; it operates, and passes signals to its
attached DTE or repeater port in accordance to
its specification.
A MAU in standby(4) state forces DI and CI to
idle and the media transmitter to idle or fault,
if supported. Standby(4) mode only applies to
link type MAUs. The state of
ifMauMediaAvailable is unaffected.
A MAU in shutdown(5) state assumes the same
condition on DI, CI, and the media transmitter,
as though it were powered down or not connected.
The MAU MAY return other(1) value for the
ifMauJabberState and ifMauMediaAvailable objects
when it is in this state. For an AUI, this
state will remove power from the AUI.
Setting this variable to the value reset(6)
resets the MAU in the same manner as a
power-off, power-on cycle of at least one-half
second would. The agent is not required to
return the value reset(6).
Setting this variable to the value
operational(3), standby(4), or shutdown(5)
causes the MAU to assume the respective state,
except that setting a mixing-type MAU or an AUI
to standby(4) will cause the MAU to enter the
shutdown state.";
reference
"[IEEE802.3], 30.5.1.1.7, aMAUAdminState,
30.5.1.2.2, acMAUAdminControl, and 30.5.1.2.1,
acResetMAU.";
}
leaf ifMauMediaAvailable {
type iana-mau:IANAifMauMediaAvailable;
config false;
description
"This object identifies Media Available state of
the MAU, complementary to the ifMauStatus. Values
for the standard IEEE 802.3 Media Available states
are defined in the IANA maintained IANA-MAU-MIB
module, as IANAifMauMediaAvailable TC.";
reference
"[IEEE802.3], 30.5.1.1.4, aMediaAvailable.";
}
leaf ifMauMediaAvailableStateExits {
type yang:counter32;
config false;
description
"A count of the number of times that
ifMauMediaAvailable for this MAU instance leaves
the state available(3).
Discontinuities in the value of this counter can
occur at re-initialization of the management
system and at other times, as indicated by the
value of ifCounterDiscontinuityTime.";
reference
"[IEEE802.3], 30.5.1.1.5, aLoseMediaCounter.
RFC 2863, ifCounterDiscontinuityTime.";
}
leaf ifMauJabberState {
type enumeration {
enum other { value 1; }
enum unknown { value 2; }
enum noJabber { value 3; }
enum jabbering { value 4; }
}
config false;
description
"The value other(1) is returned if the jabber
state is not 2, 3, or 4. The agent MUST always
return other(1) for MAU type dot3MauTypeAUI.
The value unknown(2) is returned when the MAU's
true state is unknown; for example, when it is
being initialized.
If the MAU is not jabbering the agent returns
noJabber(3). This is the 'normal' state.
If the MAU is in jabber state the agent returns
the jabbering(4) value.";
reference
"[IEEE802.3], 30.5.1.1.6, aJabber.jabberFlag.";
}
leaf ifMauJabberingStateEnters {
type yang:counter32;
config false;
description
"A count of the number of times that
mauJabberState for this MAU instance enters the
state jabbering(4). This counter will always
indicate zero for MAUs of type dot3MauTypeAUI
and those of speeds above 10Mbps.
Discontinuities in the value of this counter can
occur at re-initialization of the management
system and at other times, as indicated by the
value of ifCounterDiscontinuityTime.";
reference
"[IEEE802.3], 30.5.1.1.6, aJabber.jabberCounter.
RFC 2863, ifCounterDiscontinuityTime.";
}
leaf ifMauFalseCarriers {
type yang:counter32;
config false;
description
"A count of the number of false carrier events
during IDLE in 100BASE-X and 1000BASE-X links.
For all other MAU types, this counter will
always indicate zero. This counter does not
increment at the symbol rate.
It can increment after a valid carrier
completion at a maximum rate of once per 100 ms
for 100BASE-X and once per 10us for 1000BASE-X
until the next CarrierEvent.
This counter can roll over very quickly. A
management station is advised to poll the
ifMauHCFalseCarriers instead of this counter in
order to avoid loss of information.
Discontinuities in the value of this counter can
occur at re-initialization of the management
system and at other times, as indicated by the
value of ifCounterDiscontinuityTime.";
reference
"[IEEE802.3], 30.5.1.1.10, aFalseCarriers.
RFC 2863, ifCounterDiscontinuityTime.";
}
leaf ifMauTypeList {
type int32;
config false;
status deprecated;
description
"********* THIS OBJECT IS DEPRECATED **********
This object has been deprecated in favour of
ifMauTypeListBits.
A value that uniquely identifies the set of
possible IEEE 802.3 types that the MAU could be.
The value is a sum that initially takes the
value zero. Then, for each type capability of
this MAU, 2 raised to the power noted below is
added to the sum. For example, a MAU that has
the capability to be only 10BASE-T would have a
value of 512 (2**9). In contrast, a MAU that
supports both 10Base-T (full duplex) and
100BASE-TX (full duplex) would have a value of
((2**11) + (2**16)), or 67584.
The powers of 2 assigned to the capabilities are
these:
Power Capability
0 other or unknown
1 AUI
2 10BASE-5
3 FOIRL
4 10BASE-2
5 10BASE-T duplex mode unknown
6 10BASE-FP
7 10BASE-FB
8 10BASE-FL duplex mode unknown
9 10BROAD36
10 10BASE-T half duplex mode
11 10BASE-T full duplex mode
12 10BASE-FL half duplex mode
13 10BASE-FL full duplex mode
14 100BASE-T4
15 100BASE-TX half duplex mode
16 100BASE-TX full duplex mode
17 100BASE-FX half duplex mode
18 100BASE-FX full duplex mode
19 100BASE-T2 half duplex mode
20 100BASE-T2 full duplex mode
If auto-negotiation is present on this MAU, this
object will map to ifMauAutoNegCapability.";
}
leaf ifMauDefaultType {
type smiv2:AutonomousType;
config true;
description
"This object identifies the default
administrative baseband MAU type to be used in
conjunction with the operational MAU type
denoted by ifMauType.
The set of possible values for this object is
the same as the set defined for the ifMauType
object.
This object represents the
administratively-configured type of the MAU. If
auto-negotiation is not enabled or is not
implemented for this MAU, the value of this
object determines the operational type of the
MAU. In this case, a set to this object will
force the MAU into the specified operating mode.
If auto-negotiation is implemented and enabled
for this MAU, the operational type of the MAU
is determined by auto-negotiation, and the value
of this object denotes the type to which the MAU
will automatically revert if/when
auto-negotiation is later disabled.
NOTE TO IMPLEMENTORS: It may be necessary to
provide for underlying hardware implementations
which do not follow the exact behavior specified
above. In particular, when
ifMauAutoNegAdminStatus transitions from enabled
to disabled, the agent implementation MUST
ensure that the operational type of the MAU (as
reported by ifMauType) correctly transitions to
the value specified by this object, rather than
continuing to operate at the value earlier
determined by the auto-negotiation function.";
reference
"[IEEE802.3], 30.5.1.1.1, aMAUID, and 22.2.4.1.4.";
}
leaf ifMauAutoNegSupported {
type smiv2:TruthValue;
config false;
description
"This object indicates whether or not
auto-negotiation is supported on this MAU.";
}
leaf ifMauTypeListBits {
type iana-mau:IANAifMauTypeListBits;
config false;
description
"A value that uniquely identifies the set of
possible IEEE 802.3 types that the MAU could be.
If auto-negotiation is present on this MAU, this
object will map to ifMauAutoNegCapabilityBits.
Note that this MAU may be capable of operating
as a MAU type that is beyond the scope of this
MIB. This is indicated by returning the
bit value bOther in addition to any bit values
for standard capabilities that are listed in the
IANAifMauTypeListBits TC.";
}
leaf ifMauHCFalseCarriers {
type yang:counter64;
config false;
description
"A count of the number of false carrier events
during IDLE in 100BASE-X and 1000BASE-X links.
For all other MAU types, this counter will
always indicate zero. This counter does not
increment at the symbol rate.
This counter is a 64-bit version of
ifMauFalseCarriers. Since the 32-bit version of
this counter can roll over very quickly,
management stations are advised to poll the
64-bit version instead, in order to avoid loss
of information.
Discontinuities in the value of this counter can
occur at re-initialization of the management
system and at other times, as indicated by the
value of ifCounterDiscontinuityTime.";
reference
"[IEEE802.3], 30.5.1.1.10, aFalseCarriers.
RFC 2863, ifCounterDiscontinuityTime.";
}
}
/* XXX table comments here XXX */
list ifJackEntry {
key "ifMauIfIndex ifMauIndex ifJackIndex";
description
"An entry in the table, containing information
about a particular jack.";
leaf ifMauIfIndex {
type keyref {
path "/mau-mib:dot3IfMauBasicGroup/mau-mib:ifMauEntry/mau-mib:ifMauIfIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf ifMauIndex {
type keyref {
path "/mau-mib:dot3IfMauBasicGroup/mau-mib:ifMauEntry/mau-mib:ifMauIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf ifJackIndex {
type int32 {
range "1..2147483647";
}
config false;
description
"This variable uniquely identifies the jack
described by this entry from among other jacks
attached to the same MAU.";
}
leaf ifJackType {
type iana-mau:IANAifJackType;
config false;
description
"The jack connector type, as it appears on the
outside of the system.";
}
}
}
container dot3IfMauAutoNegGroup {
/* XXX table comments here XXX */
list ifMauAutoNegEntry {
key "ifMauIfIndex ifMauIndex";
description
"An entry in the table, containing configuration
and status information for the auto-negotiation
function of a particular MAU.";
leaf ifMauIfIndex {
type keyref {
path "/mau-mib:dot3IfMauBasicGroup/mau-mib:ifMauEntry/mau-mib:ifMauIfIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf ifMauIndex {
type keyref {
path "/mau-mib:dot3IfMauBasicGroup/mau-mib:ifMauEntry/mau-mib:ifMauIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf ifMauAutoNegAdminStatus {
type enumeration {
enum enabled { value 1; }
enum disabled { value 2; }
}
config true;
description
"Setting this object to enabled(1) will cause
the interface that has the auto-negotiation
signaling ability to be enabled.
If the value of this object is disabled(2) then
the interface will act as it would if it had no
auto-negotiation signaling. Under these
conditions, an IEEE 802.3 MAU will immediately
be forced to the state indicated by the value of
the object ifMauDefaultType.
NOTE TO IMPLEMENTORS: When
ifMauAutoNegAdminStatus transitions from enabled
to disabled, the agent implementation MUST
ensure that the operational type of the MAU (as
reported by ifMauType) correctly transitions to
the value specified by the ifMauDefaultType
object, rather than continuing to operate at the
value earlier determined by the auto-negotiation
function.";
reference
"[IEEE802.3], 30.6.1.1.2, aAutoNegAdminState,
and 30.6.1.2.2, acAutoNegAdminControl.";
}
leaf ifMauAutoNegRemoteSignaling {
type enumeration {
enum detected { value 1; }
enum notdetected { value 2; }
}
config false;
description
"A value indicating whether the remote end of
the link is using auto-negotiation signaling. It
takes the value detected(1) if and only if,
during the previous link negotiation, FLP Bursts
were received.";
reference
"[IEEE802.3], 30.6.1.1.3,
aAutoNegRemoteSignaling.";
}
leaf ifMauAutoNegConfig {
type enumeration {
enum other { value 1; }
enum configuring { value 2; }
enum complete { value 3; }
enum disabled { value 4; }
enum parallelDetectFail { value 5; }
}
config false;
description
"A value indicating the current status of the
auto-negotiation process. The enumeration
parallelDetectFail(5) maps to a failure in
parallel detection as defined in 28.2.3.1 of
[IEEE802.3].";
reference
"[IEEE802.3], 30.6.1.1.4, aAutoNegAutoConfig.";
}
leaf ifMauAutoNegCapability {
type int32;
config false;
status deprecated;
description
"********* THIS OBJECT IS DEPRECATED **********
This object has been deprecated in favour of
ifMauAutoNegCapabilityBits.
A value that uniquely identifies the set of
capabilities of the local auto-negotiation
entity. The value is a sum that initially
takes the value zero. Then, for each capability
of this interface, 2 raised to the power noted
below is added to the sum. For example, an
interface that has the capability to support
only 100Base-TX half duplex would have a value
of 32768 (2**15). In contrast, an interface
that supports both 100Base-TX half duplex and
100Base-TX full duplex would have a value of
98304 ((2**15) + (2**16)).
The powers of 2 assigned to the capabilities are
these:
Power Capability
0 other or unknown
(1-9) (reserved)
10 10BASE-T half duplex mode
11 10BASE-T full duplex mode
12 (reserved)
13 (reserved)
14 100BASE-T4
15 100BASE-TX half duplex mode
16 100BASE-TX full duplex mode
17 (reserved)
18 (reserved)
19 100BASE-T2 half duplex mode
20 100BASE-T2 full duplex mode
Note that interfaces that support this MIB may
have capabilities that extend beyond the scope
of this MIB.";
reference
"[IEEE802.3], 30.6.1.1.5,
aAutoNegLocalTechnologyAbility.";
}
leaf ifMauAutoNegCapAdvertised {
type int32;
config true;
status deprecated;
description
"********* THIS OBJECT IS DEPRECATED **********
This object has been deprecated in favour of
ifMauAutoNegCapAdvertisedBits.
A value that uniquely identifies the set of
capabilities advertised by the local
auto-negotiation entity. Refer to
ifMauAutoNegCapability for a description of the
possible values of this object.
Capabilities in this object that are not
available in ifMauAutoNegCapability cannot be
enabled.";
reference
"[IEEE802.3], 30.6.1.1.6,
aAutoNegAdvertisedTechnologyAbility.";
}
leaf ifMauAutoNegCapReceived {
type int32;
config false;
status deprecated;
description
"********* THIS OBJECT IS DEPRECATED **********
This object has been deprecated in favour of
ifMauAutoNegCapReceivedBits.
A value that uniquely identifies the set of
capabilities received from the remote
auto-negotiation entity. Refer to
ifMauAutoNegCapability for a description of the
possible values of this object.
Note that interfaces that support this MIB may
be attached to remote auto-negotiation entities
that have capabilities beyond the scope of this
MIB.";
reference
"[IEEE802.3], 30.6.1.1.7,
aAutoNegReceivedTechnologyAbility.";
}
leaf ifMauAutoNegRestart {
type enumeration {
enum restart { value 1; }
enum norestart { value 2; }
}
config true;
description
"If the value of this object is set to
restart(1) then this will force auto-negotiation
to begin link renegotiation. If auto-negotiation
signaling is disabled, a write to this object
has no effect.
Setting the value of this object to norestart(2)
has no effect.";
reference
"[IEEE802.3], 30.6.1.2.1,
acAutoNegRestartAutoConfig.";
}
leaf ifMauAutoNegCapabilityBits {
type iana-mau:IANAifMauAutoNegCapBits;
config false;
description
"A value that uniquely identifies the set of
capabilities of the local auto-negotiation
entity. Note that interfaces that support this
MIB may have capabilities that extend beyond the
scope of this MIB.
Note that the local auto-negotiation entity may
support some capabilities beyond the scope of
this MIB. This is indicated by returning the
bit value bOther in addition to any bit values
for standard capabilities that are listed in the
IANAifMauAutoNegCapBits TC.";
reference
"[IEEE802.3], 30.6.1.1.5,
aAutoNegLocalTechnologyAbility.";
}
leaf ifMauAutoNegCapAdvertisedBits {
type iana-mau:IANAifMauAutoNegCapBits;
config true;
description
"A value that uniquely identifies the set of
capabilities advertised by the local
auto-negotiation entity.
Capabilities in this object that are not
available in ifMauAutoNegCapabilityBits cannot
be enabled.
Note that the local auto-negotiation entity may
advertise some capabilities beyond the scope of
this MIB. This is indicated by returning the
bit value bOther in addition to any bit values
for standard capabilities that are listed in the
IANAifMauAutoNegCapBits TC.";
reference
"[IEEE802.3], 30.6.1.1.6,
aAutoNegAdvertisedTechnologyAbility.";
}
leaf ifMauAutoNegCapReceivedBits {
type iana-mau:IANAifMauAutoNegCapBits;
config false;
description
"A value that uniquely identifies the set of
capabilities received from the remote
auto-negotiation entity.
Note that interfaces that support this MIB may
be attached to remote auto-negotiation entities
that have capabilities beyond the scope of this
MIB. This is indicated by returning the bit
value bOther in addition to any bit values for
standard capabilities that are listed in the
IANAifMauAutoNegCapBits TC.";
reference
"[IEEE802.3], 30.6.1.1.7,
aAutoNegReceivedTechnologyAbility.";
}
leaf ifMauAutoNegRemoteFaultAdvertised {
type enumeration {
enum noError { value 1; }
enum offline { value 2; }
enum linkFailure { value 3; }
enum autoNegError { value 4; }
}
config true;
description
"A value that identifies any local fault
indications that this MAU has detected and will
advertise at the next auto-negotiation
interaction for 1000Mbps MAUs.";
reference
"[IEEE802.3], 30.6.1.1.6,
aAutoNegAdvertisedTechnologyAbility.";
}
leaf ifMauAutoNegRemoteFaultReceived {
type enumeration {
enum noError { value 1; }
enum offline { value 2; }
enum linkFailure { value 3; }
enum autoNegError { value 4; }
}
config false;
description
"A value that identifies any fault indications
received from the far end of a link by the
local auto-negotiation entity for 1000Mbps
MAUs.";
reference
"[IEEE802.3], 30.6.1.1.7,
aAutoNegReceivedTechnologyAbility.";
}
}
}
notification rpMauJabberTrap {
description
"This trap is sent whenever a managed repeater
MAU enters the jabber state.
The agent MUST throttle the generation of
consecutive rpMauJabberTraps so that there is at
least a five-second gap between them.";
reference
"[IEEE802.3], 30.5.1.3.1, nJabber notification.";
container rpMauJabberTrap-rpMauJabberState {
leaf rpMauGroupIndex {
type keyref {
path "/mau-mib:dot3RpMauBasicGroup/mau-mib:rpMauEntry/mau-mib:rpMauGroupIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf rpMauPortIndex {
type keyref {
path "/mau-mib:dot3RpMauBasicGroup/mau-mib:rpMauEntry/mau-mib:rpMauPortIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf rpMauIndex {
type keyref {
path "/mau-mib:dot3RpMauBasicGroup/mau-mib:rpMauEntry/mau-mib:rpMauIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf rpMauJabberState {
type enumeration {
enum other { value 1; }
enum unknown { value 2; }
enum noJabber { value 3; }
enum jabbering { value 4; }
}
config false;
description
"The value other(1) is returned if the jabber
state is not 2, 3, or 4. The agent MUST always
return other(1) for MAU type dot3MauTypeAUI.
The value unknown(2) is returned when the MAU's
true state is unknown; for example, when it is
being initialized.
If the MAU is not jabbering the agent returns
noJabber(3). This is the 'normal' state.
If the MAU is in jabber state the agent returns
the jabbering(4) value.";
reference
"[IEEE802.3], 30.5.1.1.6, aJabber.jabberFlag.";
}
}
}
notification ifMauJabberTrap {
description
"This trap is sent whenever a managed interface
MAU enters the jabber state.
The agent MUST throttle the generation of
consecutive ifMauJabberTraps so that there is at
least a five-second gap between them.";
reference
"[IEEE802.3], 30.5.1.3.1, nJabber notification.";
container ifMauJabberTrap-ifMauJabberState {
leaf ifMauIfIndex {
type keyref {
path "/mau-mib:dot3IfMauBasicGroup/mau-mib:ifMauEntry/mau-mib:ifMauIfIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf ifMauIndex {
type keyref {
path "/mau-mib:dot3IfMauBasicGroup/mau-mib:ifMauEntry/mau-mib:ifMauIndex";
}
config false;
description
"Automagically generated keyref leaf.";
}
leaf ifMauJabberState {
type enumeration {
enum other { value 1; }
enum unknown { value 2; }
enum noJabber { value 3; }
enum jabbering { value 4; }
}
config false;
description
"The value other(1) is returned if the jabber
state is not 2, 3, or 4. The agent MUST always
return other(1) for MAU type dot3MauTypeAUI.
The value unknown(2) is returned when the MAU's
true state is unknown; for example, when it is
being initialized.
If the MAU is not jabbering the agent returns
noJabber(3). This is the 'normal' state.
If the MAU is in jabber state the agent returns
the jabbering(4) value.";
reference
"[IEEE802.3], 30.5.1.1.6, aJabber.jabberFlag.";
}
}
}
} /* end of module MAU-MIB */