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Network Working Group E. Beili Request for Comments: 5066 Actelis Networks Category: Standards Track November 2007 Ethernet in the First Mile Copper (EFMCu) Interfaces MIB Status of This Memo This document specifies an Internet standards track protocol for the Internet community, and requests discussion and suggestions for improvements. Please refer to the current edition of the "Internet Official Protocol Standards" (STD 1) for the standardization state and status of this protocol. Distribution of this memo is unlimited. Abstract This document defines Management Information Base (MIB) modules for use with network management protocols in TCP/IP-based internets. This document describes extensions to the Ethernet-like Interfaces MIB and Medium Attachment Unit (MAU) MIB modules with a set of objects for managing Ethernet in the First Mile Copper (EFMCu) interfaces 10PASS-TS and 2BASE-TL, defined in IEEE Std 802.3ah-2004 (note: IEEE Std 802.3ah-2004 has been integrated into IEEE Std 802.3- 2005). In addition, a set of objects is defined, describing cross- connect capability of a managed device with multi-layer (stacked) interfaces, extending the stack management objects in the Interfaces Group MIB and the Inverted Stack Table MIB modules. Beili Standards Track [Page 1]
RFC 5066 EFMCu Interfaces MIB November 2007 Table of Contents 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3 2. The Internet-Standard Management Framework . . . . . . . . . . 3 3. Relation to Other MIB Modules . . . . . . . . . . . . . . . . 4 3.1. Relation to Interfaces Group MIB Module . . . . . . . . . 4 3.1.1. Layering Model . . . . . . . . . . . . . . . . . . . . 4 3.1.2. PME Aggregation Function (PAF) . . . . . . . . . . . . 7 3.1.3. Discovery Operation . . . . . . . . . . . . . . . . . 7 3.1.4. EFMCu Ports Initialization . . . . . . . . . . . . . . 9 3.1.5. Usage of ifTable . . . . . . . . . . . . . . . . . . . 10 3.2. Relation to SHDSL MIB Module . . . . . . . . . . . . . . . 11 3.3. Relation to VDSL MIB Module . . . . . . . . . . . . . . . 12 3.4. Relation to Ethernet-Like and MAU MIB Modules . . . . . . 12 4. MIB Structure . . . . . . . . . . . . . . . . . . . . . . . . 13 4.1. EFM Copper MIB Overview . . . . . . . . . . . . . . . . . 13 4.2. Interface Stack Capability MIB Overview . . . . . . . . . 13 4.3. PME Profiles . . . . . . . . . . . . . . . . . . . . . . . 14 4.4. Mapping of IEEE 802.3ah Managed Objects . . . . . . . . . 14 5. Interface Stack Capability MIB Definitions . . . . . . . . . . 16 6. EFM Copper MIB Definitions . . . . . . . . . . . . . . . . . . 22 7. Security Considerations . . . . . . . . . . . . . . . . . . . 84 8. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 86 9. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 86 10. References . . . . . . . . . . . . . . . . . . . . . . . . . . 86 10.1. Normative References . . . . . . . . . . . . . . . . . . . 86 10.2. Informative References . . . . . . . . . . . . . . . . . . 88 Beili Standards Track [Page 2]
RFC 5066 EFMCu Interfaces MIB November 2007 1. Introduction New Ethernet-like interfaces have been defined in the Institute of Electrical and Electronics Engineers (IEEE) Standard 802.3ah-2004 [802.3ah], a.k.a. Ethernet in the First Mile (EFM), which is now a part of the base IEEE Standard 802.3-2005 [802.3]. In particular, 2BASE-TL and 10PASS-TS physical interfaces (PHYs), defined over voice-grade copper pairs, have been specified for the long and short reach, respectively. These interfaces, collectively called EFM Copper (EFMCu), are based on Single-pair High-speed Digital Subscriber Line (SHDSL) [G.991.2] and Very High speed Digital Subscriber Line (VDSL) [G.993.1] technology, supporting optional Physical Medium Entity (PME) aggregation (a.k.a. multi-pair bonding) with variable rates. 2BASE-TL PHY is capable of providing at least 2 Mbps over a 2700 m long single copper pair with a mean Bit Error Rate (BER) of 10^-7 (using 5 dB target noise margin). 10PASS-TS PHY is capable of providing at least 10 Mbps over a 750 m long single copper pair with a mean BER of 10^-7 (using 6 dB target noise margin). This memo defines a Management Information Base (MIB) module for use with network management protocols in the Internet community to manage EFMCu interfaces. In addition, a MIB module is defined describing the cross-connect capability of a stacked interface. Note that managed objects for Operation, Administration and Maintenance (OAM) and Ethernet over Passive Optical Networks (EPON) clauses of IEEE 802.3ah are defined in EFM-COMMON-MIB [RFC4878] and EFM-EPON-MIB [RFC4837], respectively. 2. The Internet-Standard Management Framework For a detailed overview of the documents that describe the current Internet-Standard Management Framework, please refer to section 7 of RFC 3410 [RFC3410]. Managed objects are accessed via a virtual information store, termed the Management Information Base or MIB. MIB objects are generally accessed through the Simple Network Management Protocol (SNMP). Objects in the MIB are defined using the mechanisms defined in the Structure of Management Information (SMI). This memo specifies MIB modules that are compliant to the SMIv2, which is described in STD 58, RFC 2578 [RFC2578], STD 58, RFC 2579 [RFC2579] and STD 58, RFC 2580 [RFC2580]. Beili Standards Track [Page 3]
RFC 5066 EFMCu Interfaces MIB November 2007 The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC 2119 [RFC2119]. 3. Relation to Other MIB Modules This section outlines the relationship of the MIB modules defined in this document with other MIB modules described in the relevant RFCs. Specifically, the Interfaces Group MIB (IF-MIB), Ethernet-Like (EtherLike-MIB), MAU (MAU-MIB), SHDSL (HDSL2-SHDSL-LINE-MIB), and VDSL (VDSL-LINE-EXT-MCM-MIB) modules are discussed. 3.1. Relation to Interfaces Group MIB Module 2BASE-TL and 10PASS-TS PHYs specified in the EFM-CU-MIB module are stacked (a.k.a. aggregated or bonded) Ethernet interfaces and as such are managed using generic interface management objects defined in the IF-MIB [RFC2863]. The stack management (i.e., actual connection of the sub-layers to the top-layer interface) is done via the ifStackTable, as defined in the IF-MIB [RFC2863], and its inverse ifInvStackTable, as defined in the IF-INVERTED-STACK-MIB [RFC2864]. The new tables ifCapStackTable and its inverse ifInvCapStackTable defined in the IF-CAP-STACK-MIB module below, extend the stack management with an ability to describe possible connections or cross- connect capability, when a flexible cross-connect matrix is present between the interface layers. 3.1.1. Layering Model An EFMCu interface can aggregate up to 32 Physical Medium Entity (PME) sub-layer devices (modems), using the so-called PME Aggregation Function (PAF). A generic EFMCu device can have a number of Physical Coding Sublayer (PCS) ports, each connected to a Media Access Controller (MAC) via a Medium Independent Interface (MII) at the upper layer, and cross- connected to a number of underlying PMEs, with a single PCS per PME relationship. See clause 61.1 of [802.3ah] for more details. Each PME in the aggregated EFMCu port is represented in the Interface table (ifTable) as a separate interface with ifType of shdsl(169) for 2BASE-TL or vdsl(97) for 10PASS-TS. The ifType values are defined in [IANAifType-MIB]. Beili Standards Track [Page 4]
RFC 5066 EFMCu Interfaces MIB November 2007 ifSpeed for each PME SHALL return the actual data bitrate of the active PME (e.g., for 2BaseTL PMEs it is a multiple of 64 Kbps). A zero value SHALL be returned when the PME is Initializing or Down. The ifSpeed of the PCS is the sum of the current operating data rates of all PMEs in the aggregation group, without the 64/65-octet encapsulation overhead and PAF overhead, but accounting for the Inter-Frame Gaps (IFGs). When using the stated definition of ifSpeed for the PCS, there would be no frame loss in the following configuration (the test-sets are configured to generate 100% of back-to-back traffic, i.e., minimal IFG, at 10 or 100 Mbps, with min and max frame sizes; the EFM interfaces are aggregated, to achieve the shown speed): .-------. .--. .---. .-------. |testset|--10BaseT--|CO|--2BaseTL--|CPE|--10BaseT--|testset| '-------' '--' '---' '-------' ifSpeed= 10 Mbps 10 Mbps 10 Mbps .-------. .--. .---. .-------. |testset|--100BaseT--|CO|--10PassTS--|CPE|--100BaseT--|testset| '-------' '--' '---' '-------' ifSpeed= 100 Mbps 100 Mbps 100 Mbps Figure 1: Example configuration with no frame loss Beili Standards Track [Page 5]
RFC 5066 EFMCu Interfaces MIB November 2007 The following figure shows the IEEE 802.3 layering diagram and corresponding use of ifTable and ifMauTable: .-------------------------. - | LLC | ^ +-------------------------+ | 1 ifEntry | MAC | | ifType: ethernetCsmacd(6) +-------------------------+ ) ifMauEntry | Reconsiliation | | ifMauType: dot3MauType2BaseTL or +-------------------------+ | dot3MauType10PassTS | PCS | v +-------------+---+-------+ - | TC \ | | | ^ +-----\ | | | | | PMA )PME 1 |...| PME N | ) N ifEntry (N=1..32) +-----/ | | | | ifType: shdsl(169) or vdsl(97) | PMD/ | | | v '-------------+---+-------' - LLC - Logical Link Control PMA - Physical Medium Attachment MAC - Media Access Control PMD - Physical Medium Dependent PCS - Physical Coding Sub-layer PME - Physical Medium Entity TC - Transmission Convergence Figure 2: Use of ifTable and ifMauTable for EFMCu ports The ifStackTable is indexed by the ifIndex values of the aggregated EFMCu port (PCS) and the PMEs connected to it. ifStackTable allows a Network Management application to determine which PMEs are connected to a particular PCS and change connections (if supported by the application). The ifInvStackTable, being an inverted version of the ifStackTable, provides an efficient means for a Network Management application to read a subset of the ifStackTable and thereby determine which PCS runs on top of a particular PME. A new table ifCapStackTable, defined in the IF-CAP-STACK-MIB module, specifies for each higher-layer interface (e.g., PCS port) a list of lower-layer interfaces (e.g., PMEs), which can possibly be cross- connected to that higher-layer interface, determined by the cross- connect capability of the device. This table, modeled after ifStackTable, is read-only, reflecting current cross-connect capability of stacked interface, which can be dynamic in some implementations (e.g., if PMEs are located on a pluggable module and the module is pulled out). Note that PME availability per PCS, described by ifCapStackTable, can be constrained by other parameters, for example, by aggregation capacity of a PCS or by the PME in question being already connected to another PCS. So, in order to Beili Standards Track [Page 6]
RFC 5066 EFMCu Interfaces MIB November 2007 ensure that a particular PME can be connected to the PCS, all respective parameters (e.g., ifCapStackTable, ifStackTable, and efmCuPAFCapacity) SHALL be inspected. The ifInvCapStackTable, also defined in the IF-CAP-STACK-MIB module, describes which higher-layer interfaces (e.g., PCS ports) can possibly be connected to a particular lower-layer interface (e.g., PME), providing an inverted mapping of the ifCapStackTable. While it contains no additional information beyond that already contained in the ifCapStackTable, the ifInvCapStackTable has the ifIndex values in its INDEX clause in the reverse order, i.e., the lower-layer interface first, and the higher-layer interface second, providing an efficient means for a Network Management application to read a subset of the ifCapStackTable and thereby determine which interfaces can be connected to run on top of a particular interface. 3.1.2. PME Aggregation Function (PAF) The PME Aggregation Function (PAF) allows a number of PMEs to be aggregated onto a PCS port, by fragmenting the Ethernet frames, transmitting the fragments over multiple PMEs, and assembling the original frames at the remote port. PAF is OPTIONAL, meaning that a device with a single PME MAY perform fragmentation and re-assembly if this function is supported by the device. Note however that the agent is REQUIRED to report on the PAF capability for all EFMCu ports (2BASE-TL and 10PASS-TS). The EFM-CU-MIB module allows a Network Management application to query the PAF capability and enable/disable it if supported. Note that enabling PAF effectively turns on fragmentation and re-assembly, even on a single-PME port. 3.1.3. Discovery Operation The EFMCu ports may optionally support discovery operation, whereby PMEs, during initialization, exchange information about their respective aggregation groups (PCS). This information can then be used to detect copper misconnections or for an automatic assignment of the local PMEs into aggregation groups instead of a fixed pre- configuration. The MIB modules defined in this document allow a Network Management application to control the EFM Discovery mechanism and query its results. Note that the Discovery mechanism can work only if PAF is supported and enabled. Beili Standards Track [Page 7]
RFC 5066 EFMCu Interfaces MIB November 2007 Two tables are used by the EFM Discovery mechanism: ifStackTable and ifCapStackTable. The following pseudo-code gives an example of the Discovery and automatic PME assignment for a generic PAF-enabled multi-PCS EFMCu device, located at Central Office (CO), using objects defined in these MIB modules and in the IF-MIB (Note that automatic PME assignment is only shown here for the purposes of the example. Fixed PME pre-assignment, manual assignment, or auto-assignment using an alternative internal algorithm may be chosen by a particular implementation): // Go over all PCS ports in the CO device FOREACH pcs[i] IN CO_device { // Perform discovery and auto-assignment only on PAF enabled ports // with room for more PMEs IF ( pcs[i].PAFSupported AND pcs[i].NumPMEs < pcs[i].PAFCapacity ) { // Assign a unique 6-octet local discovery code to the PCS // e.g., MAC address dc = pcs[i].DiscoveryCode = MAC[i]; // Go over all disconnected PMEs, which can // potentially be connected to the PCS FOREACH pme[j] IN ifCapStackTable[pcs[i]] AND NOT IN ifStackTable[pcs[i]] // not connected { // Try to grab the remote RT_device, by writing the value // of the local 6-octet discovery code to the remote // discovery code register (via handshake mechanism). // This operation is atomic Set-if-Clear action, i.e., it // would succeed only if the remote discovery register was // zero. Read the remote discovery code register via Get // operation to see if the RT_device, attached via the PME // is indeed marked as being the CO_device peer. pme[j].RemoteDiscoveryCode = dc; // Set-if-Clear r = pme[j].RemoteDiscoveryCode; // Get IF ( r == dc AND pcs[i].NumPMEs < pcs[i].PAFCapacity) { // Remote RT_device connected via PME[j] is/was a peer // for PCS[i] and there is room for another PME in the // PCS[i] aggregation group (max. PAF capacity is not // reached yet). // Connect this PME to the PCS (via ifStackTable, // ifInvStackTable being inverse of ifStackTable is // updated automatically, i.e., pcs[i] is auto-added // to ifInvStackTable[pme[j]]) ADD pme[j] TO ifStackTable[pcs[i]]; pcs[i].NumPMEs = pcs[i].NumPMEs + 1; // Discover all other disconnected PMEs, // attached to the same RT_device and connect them to // the PCS provided there is enough room for more PMEs. FOREACH pme[k] IN ifCapStackTable[pcs[i]] AND NOT IN ifStackTable[pcs[i]] Beili Standards Track [Page 8]
RFC 5066 EFMCu Interfaces MIB November 2007 { // Get Remote Discovery Code from the PME to see if // it belongs to a connected RT_device "grabbed" by // the CO_device. r = pme[k].RemoteDiscoveryCode; IF ( r == dc AND pcs[i].NumPMEs < pcs[i].PAFCapacity) { // Physically connect the PME to the PCS // (pcs[i] is auto-added TO ifInvStackTable[pme[k]]) ADD pme[k] TO ifStackTable[pcs[i]]; pcs[i].NumPMEs = pcs[i].NumPMEs + 1; } } } // At this point we have discovered all local PMEs which // are physically connected to the same remote RT_device // and connected them to PCS[i]. Go to the next PCS. BREAK; } } } An SNMP Agent for an EFMCu device builds the ifCapStackTable and its inverse ifInvCapStackTable according to the information contained in the Clause 45 PME_Available_register (see [802.3ah] 61.1.5.3 and 45.2.3.20). Adding a PME to the ifStackTable row for a specific PCS involves actual connection of the PME to the PCS, which can be done by modifying Clause 45 PME_Aggregate_register (see [802.3ah] 61.1.5.3 and 45.2.3.21). Note that the PCS port does not have to be operationally 'down' for the connection to succeed. In fact, a dynamic PME addition (and removal) MAY be implemented with an available PME being initialized first (by setting its ifAdminStatus to 'up') and then added to an operationally 'up' PCS port, by modifying a respective ifStackTable (and respective ifInvStackTable) entry. It is RECOMMENDED that a removal of the last operationally 'up' PME from an operationally 'up' PCS would be rejected by the implementation, as this action would completely drop the link. 3.1.4. EFMCu Ports Initialization EFMCu ports being built on top of xDSL technology require a lengthy initialization or 'training' process, before any data can pass. During this initialization, both ends of a link (peers) work cooperatively to achieve the required data rate on a particular Beili Standards Track [Page 9]
RFC 5066 EFMCu Interfaces MIB November 2007 copper pair. Sometimes, when the copper line is too long or the noise on the line is too high, that 'training' process may fail to achieve a specific target rate with required characteristics. The ifAdminStatus object from the IF-MIB controls the desired state of a PCS with all the PMEs connected to it or of an individual PME port. Setting this object to 'up' instructs a particular PCS or PME to start the initialization process, which may take tens of seconds for EFMCu ports, especially if PAF is involved. The ifOperStatus object shows the operational state of an interface (extended by the ifMauMediaAvailable object from MAU-MIB for PCS and efmCuPmeOperStatus defined in the EFM-CU-MIB module for PME interfaces). A disconnected PME may be initialized by changing the ifAdminState from 'down' to 'up'. Changing the ifAdminState to 'up' on the PCS initializes all PMEs connected to that particular PCS. Note that in case of PAF some interfaces may fail to initialize while others succeed. The PCS is considered operationally 'up' if at least one PME aggregated by its PAF is operationally 'up'. When all PMEs connected to the PCS are 'down', the PCS SHALL be considered operationally 'lowerLayerDown'. The PCS SHALL be considered operationally 'notPresent' if it is not connected to any PME. The PCS/PME interface SHALL remain operationally 'down' during initialization. The efmCuPmeOperStatus defined in the EFM-CU-MIB module expands PME's ifOperStatus value of 'down' to 'downReady', 'downNotReady', and 'init' values, indicating various EFMCu PME-specific states. 3.1.5. Usage of ifTable Both PME and PCS interfaces of the EFMCu PHY are managed using interface-specific management objects defined in the EFM-CU-MIB module and generic interface objects from the ifTable of IF-MIB, with all management table entries referenced by the interface index ifIndex. The following table summarizes EFMCu-specific interpretations for some of the ifTable objects specified in the mandatory ifGeneralInformationGroup: Beili Standards Track [Page 10]
RFC 5066 EFMCu Interfaces MIB November 2007 +---------------+---------------------------------------------------+ | IF-MIB object | EFMCu interpretation | +---------------+---------------------------------------------------+ | ifIndex | Interface index. Note that each PME and each PCS | | | in the EFMCu PHY MUST have a unique index, as | | | there are some PCS- and PME-specific attributes | | | accessible only on the PCS or PME level. | +---------------+---------------------------------------------------+ | ifType | ethernetCsmacd(6) for PCS, shdsl(169) for | | | 2BASE-TL PME, vdsl(97) for 10PASS-TS PME. | | ifSpeed | Operating data rate for the PME. For the PCS, it | | | is the sum of the current operating data rates of | | | all PMEs in the aggregation group, without the | | | 64/65-octet encapsulation overhead and PAF | | | overhead, but accounting for the Inter-Frame Gaps | | | (IFGs). | +---------------+---------------------------------------------------+ | ifAdminStatus | Setting this object to 'up' instructs a | | | particular PCS (with all PMEs connected to it) or | | | PME to start initialization process. | +---------------+---------------------------------------------------+ | ifOperStatus | efmCuPmeOperStatus supplements the 'down' value | | | of ifOperStatus for PMEs. | +---------------+---------------------------------------------------+ Table 1: EFMCu interpretation of IF-MIB objects 3.2. Relation to SHDSL MIB Module G.SHDSL.bis modems, similar to PMEs comprising a 2BASE-TL port, are described in the HDSL2-SHDSL-LINE-MIB module [RFC4319]. Note that not all attributes of G.SHDSL modems reflected in the HDSL2-SHDSL- LINE-MIB module have adequate management objects (Clause 30 attributes and Clause 45 registers) in the EFM standard. Because of these differences and for the purposes of simplicity, unification of attributes common to both 2BASE-TL and 10PASS-TS PMEs, and name consistency (e.g., prefixing the 2BASE-TL PME related objects with 'efmCuPme2B' instead of 'hdsl2shdsl'), it was decided not to reference HDSL2-SHDSL-LINE-MIB objects, but define all the relevant objects in the EFM-CU-MIB module. However, if some functionality not available in the EFM-CU-MIB module is required and supported by the PME, e.g., performance monitoring, relevant HDSL2-SHDSL-LINE-MIB groups MAY be included and applied for PMEs of 2BASE-TL subtype. Beili Standards Track [Page 11]
RFC 5066 EFMCu Interfaces MIB November 2007 3.3. Relation to VDSL MIB Module VDSL modems, similar to the PME(s) comprising a 10PASS-TS port, are described in the VDSL-LINE-EXT-MCM-MIB module [RFC4070]. Note that not all attributes of VDSL modems reflected in the VDSL-LINE-EXT-MCM- MIB module have adequate management objects (Clause 30 attributes and Clause 45 registers) in the EFM standard. Because of these differences and for the purposes of simplicity, unification of attributes common to both 2BASE-TL and 10PASS-TS PMEs, and name consistency, it was decided not to reference VDSL-LINE-EXT- MCM-MIB objects, but define all the relevant objects in the EFM-CU- MIB module. However, if some functionality not available in the EFM-CU-MIB module is required and supported by the PME, relevant VDSL-LINE-EXT-MCM-MIB groups MAY be included and applied for PMEs of 10PASS-TS subtype. 3.4. Relation to Ethernet-Like and MAU MIB Modules The implementation of the EtherLike-MIB [RFC3635] and MAU-MIB [RFC4836] modules is REQUIRED for EFMCu interfaces. Two new values of ifMauType (OBJECT-IDENTITIES of dot3MauType) and corresponding bit definitions of ifMauTypeListBits (IANAifMauTypeListBits) have been defined in the IANA-MAU-MIB module [RFC4836] for EFMCu MAUs: o dot3MauType2BaseTL and b2BaseTL - for 2BASE-TL MAU o dot3MauType10PassTS and b10PassTS - for 10PASS-TS MAU Additionally, the IANA-MAU-MIB module defines two new values of ifMauMediaAvailable, specifically for EFMCu ports: availableReduced and ready (in textual convention IANAifMauMediaAvailable). Due to the PME aggregation, the EFMCu interpretation of some possible ifMauMediaAvailable values differs from other MAUs as follows: o unknown - the EFMCu interface (PCS with connected PMEs) is Initializing o ready - the interface is Down, at least one PME in the aggregation group (all PMEs connected to the PCS) is ready for handshake o available - the interface is Up, all PMEs in the aggregation group are up Beili Standards Track [Page 12]
RFC 5066 EFMCu Interfaces MIB November 2007 o notAvailable - the interface is Down, all PMEs in the aggregation group are Down, no handshake tones are detected by any PME o availableReduced - the interface is Up, a link fault is detected at the receive direction by one or more PMEs in the aggregation group, but at least one PME is Up o pmdLinkFault - a link fault is detected at the receive direction by all PMEs in the aggregation group As an EtherLike interface, every EFMCu port (an ifEntry representing a consolidation of LLC, MAC, and PCS (sub)layers) SHALL return an ifType of ethernetCsmacd(6). While most of the MAU characteristics are not applicable to the EFMCu ports (no auto-negotiation, false carriers, or jabber), they SHALL return an appropriate ifMauType (dot3MauType2BaseTL or dot3mauType10PassTS) in order to direct the management software to look in the EFM-CU-MIB module for the desired information. For example, the information on the particular EFMCu flavor that an EFMCu port is running is available from efmCuOperSubType, defined in the EFM-CU-MIB module. Since EFMCu PMEs are not EtherLike interfaces, they cannot be instantiated as MAU interface objects. 4. MIB Structure 4.1. EFM Copper MIB Overview The main management objects defined in the EFM-CU-MIB module are split into 2 groups: o efmCuPort - containing objects for configuration, capabilities, status, and notifications, common to all EFMCu PHYs. o efmCuPme - containing objects for configuration, capabilities, status, and notifications of EFMCu PMEs. The efmCuPme group in turn contains efmCuPme2B and efmCuPme10P groups, which define PME profiles specific to 2BASE-TL and 10PASS-TS PMEs, respectively, as well as PME-specific status information. 4.2. Interface Stack Capability MIB Overview The IF-CAP-STACK-MIB module contains 2 tables: o ifCapStackTable - containing objects that define possible relationships among the sub-layers of an interface with flexible cross-connect (cross-connect capability). Beili Standards Track [Page 13]
RFC 5066 EFMCu Interfaces MIB November 2007 o ifInvCapStackTable - an inverse of the ifCapstackTable. 4.3. PME Profiles Since a managed node can have a large number of EFMCu PHYs, provisioning every parameter on every EFMCu PHY may become burdensome. Moreover, most PMEs are provisioned identically with the same set of parameters. To simplify the provisioning process, the EFM-CU-MIB module makes use of configuration profiles, similar to the HDSL2-SHDSL-LINE-MIB and VDSL-LINE-EXT-MCM-MIB modules. A profile is a set of parameters, used either for configuration or representation of a PME. The same profile can be shared by multiple PME ports using the same configuration. The PME profiles are defined in the efmCuPme2BProfileTable and efmCuPme10PProfileTable for 2BASE-TL and 10PASS-TS PMEs, respectively. There are 12 predefined standard profiles for 2BASE-TL and 22 standard profiles for 10PASS-TS, defined in 802.3ah and dedicated for rapid provisioning of EFMCu PHYs in most scenarios. In addition, the EFM-CU-MIB defines two additional predefined profiles for "best-effort" provisioning of 2BASE-TL PMEs. An ability to define new configuration profiles is also provided to allow for EFMCu deployment tailored to specific copper environments and spectral regulations. A specific configuration or administrative profile is assigned to a specific PME via the efmCuPmeAdminProfile object. If efmCuPmeAdminProfile is zero, then the efmCuAdminProfile object of the PCS port connected to the PME determines the configuration profile (or a list of possible profiles) for that PME. This mechanism allows specifying a common profile for all PMEs connected to the PCS port, with an ability to change individual PME profiles by setting efmCuPmeAdminProfile object, which overwrites the profile set by efmCuAdminProfile. A current operating PME profile is pointed to by the efmCuPmeOperProfile object. Note that this profile entry can be created automatically to reflect achieved parameters in adaptive (not fixed) initialization. 4.4. Mapping of IEEE 802.3ah Managed Objects This section contains the mapping between relevant managed objects (attributes) defined in [802.3ah] Clause 30, and managed objects defined in this document and in associated MIB modules, i.e., the IF- MIB [RFC2863]. Beili Standards Track [Page 14]
RFC 5066 EFMCu Interfaces MIB November 2007 Note that the majority of the objects defined in the EFM-CU-MIB module do not have direct counterparts in Clause 30 and instead refer to Clause 45 registers. +---------------------------------+---------------------------------+ | IEEE 802.3 Managed Object | Corresponding SNMP Object | +---------------------------------+---------------------------------+ | oMAU - Basic Package | | | (Mandatory) | | +---------------------------------+---------------------------------+ | aMAUType | ifMauType (MAU-MIB) | +---------------------------------+---------------------------------+ | aMAUTypeList | ifMauTypeListBits (MAU-MIB) | +---------------------------------+---------------------------------+ | aMediaAvailable | ifMediaAvailable (MAU-MIB) | +---------------------------------+---------------------------------+ | oPAF - Basic Package | | | (Mandatory) | | +---------------------------------+---------------------------------+ | aPAFID | ifIndex (IF-MIB) | +---------------------------------+---------------------------------+ | aPhyEnd | efmCuPhySide | +---------------------------------+---------------------------------+ | aPHYCurrentStatus | efmCuStatus | +---------------------------------+---------------------------------+ | aPAFSupported | efmCuPAFSupported | +---------------------------------+---------------------------------+ | oPAF - PME Aggregation Package | | | (Optional) | | +---------------------------------+---------------------------------+ | aPAFAdminState | efmCuPAFAdminState | +---------------------------------+---------------------------------+ | aLocalPAFCapacity | efmCuPAFCapacity | +---------------------------------+---------------------------------+ | aLocalPMEAvailable | ifCapStackTable | +---------------------------------+---------------------------------+ | aLocalPMEAggregate | ifStackTable (IF-MIB) | +---------------------------------+---------------------------------+ | aRemotePAFSupported | efmCuRemotePAFSupported | +---------------------------------+---------------------------------+ | aRemotePAFCapacity | efmCuRemotePAFCapacity | +---------------------------------+---------------------------------+ | aRemotePMEAggregate | | +---------------------------------+---------------------------------+ | oPME - 10P/2B Package | | | (Mandatory) | | +---------------------------------+---------------------------------+ | aPMEID | ifIndex (IF-MIB) | Beili Standards Track [Page 15]
RFC 5066 EFMCu Interfaces MIB November 2007 +---------------------------------+---------------------------------+ | aPMEAdminState | ifAdminState (IF-MIB) | +---------------------------------+---------------------------------+ | aPMEStatus | efmCuPmeStatus | | aPMESNRMgn | efmCuPmeSnrMgn | +---------------------------------+---------------------------------+ | aTCCodingViolations | efmCuPmeTCCodingErrors | +---------------------------------+---------------------------------+ | aTCCRCErrors | efmCuPmeTCCrcErrors | +---------------------------------+---------------------------------+ | aProfileSelect | efmCuAdminProfile, | | | efmCuPmeAdminProfile | +---------------------------------+---------------------------------+ | aOperatingProfile | efmCuPmeOperProfile | +---------------------------------+---------------------------------+ | aPMEFECCorrectedBlocks | efmCuPme10PFECCorrectedBlocks | +---------------------------------+---------------------------------+ | aPMEFECUncorrectableBlocks | efmCuPme10PFECUncorrectedBlocks | +---------------------------------+---------------------------------+ Table 2: Mapping of IEEE 802.3 Managed Objects 5. Interface Stack Capability MIB Definitions IF-CAP-STACK-MIB DEFINITIONS ::= BEGIN IMPORTS MODULE-IDENTITY, OBJECT-TYPE, mib-2 FROM SNMPv2-SMI -- [RFC2578] TruthValue FROM SNMPv2-TC -- [RFC2579] MODULE-COMPLIANCE, OBJECT-GROUP FROM SNMPv2-CONF -- [RFC2580] ifStackGroup2, ifStackHigherLayer, ifStackLowerLayer FROM IF-MIB -- [RFC2863] ifInvStackGroup FROM IF-INVERTED-STACK-MIB -- [RFC2864] ; ifCapStackMIB MODULE-IDENTITY LAST-UPDATED "200711070000Z" -- November 07, 2007 ORGANIZATION "IETF Ethernet Interfaces and Hub MIB Working Group" CONTACT-INFO "WG charter: http://www.ietf.org/html.charters/OLD/hubmib-charter.html Mailing Lists: General Discussion: hubmib@ietf.org Beili Standards Track [Page 16]
RFC 5066 EFMCu Interfaces MIB November 2007 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 Phone: +972-3-924-3491 EMail: edward.beili@actelis.com" DESCRIPTION "The objects in this MIB module are used to describe cross-connect capabilities of stacked (layered) interfaces, complementing ifStackTable and ifInvStackTable defined in IF-MIB and IF-INVERTED-STACK-MIB, respectively. Copyright (C) The IETF Trust (2007). This version of this MIB module is part of RFC 5066; see the RFC itself for full legal notices." REVISION "200711070000Z" -- November 07, 2007 DESCRIPTION "Initial version, published as RFC 5066." ::= { mib-2 166 } -- Sections of the module -- Structured as recommended by [RFC4181], see -- Appendix D: Suggested OID Layout ifCapStackObjects OBJECT IDENTIFIER ::= { ifCapStackMIB 1 } ifCapStackConformance OBJECT IDENTIFIER ::= { ifCapStackMIB 2 } -- Groups in the module -- -- ifCapStackTable group -- Beili Standards Track [Page 17]
RFC 5066 EFMCu Interfaces MIB November 2007 ifCapStackTable OBJECT-TYPE SYNTAX SEQUENCE OF IfCapStackEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table, modeled after ifStackTable from IF-MIB, contains information on the possible 'on-top-of' relationships between the multiple sub-layers of network interfaces (as opposed to actual relationships described in ifStackTable). In particular, it contains information on which sub-layers MAY possibly run 'on top of' which other sub-layers, as determined by cross-connect capability of the device, where each sub-layer corresponds to a conceptual row in the ifTable. For example, when the sub-layer with ifIndex value x can be connected to run on top of the sub-layer with ifIndex value y, then this table contains: ifCapStackStatus.x.y=true The ifCapStackStatus.x.y row does not exist if it is impossible to connect between the sub-layers x and y. Note that for most stacked interfaces (e.g., 2BASE-TL) there's always at least one higher-level interface (e.g., PCS port) for each lower-level interface (e.g., PME) and at least one lower-level interface for each higher-level interface, that is, there is at least a single row with a 'true' status for any such existing value of x or y. This table is read-only as it describes device capabilities." REFERENCE "IF-MIB, ifStackTable" ::= { ifCapStackObjects 1 } ifCapStackEntry OBJECT-TYPE SYNTAX IfCapStackEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Information on a particular relationship between two sub-layers, specifying that one sub-layer MAY possibly run on 'top' of the other sub-layer. Each sub-layer corresponds to a conceptual row in the ifTable (interface index for lower and higher layer, respectively)." INDEX { ifStackHigherLayer, ifStackLowerLayer } Beili Standards Track [Page 18]
RFC 5066 EFMCu Interfaces MIB November 2007 ::= { ifCapStackTable 1 } IfCapStackEntry ::= SEQUENCE { ifCapStackStatus TruthValue } ifCapStackStatus OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-only STATUS current DESCRIPTION "The status of the 'cross-connect capability' relationship between two sub-layers. The following values can be returned: true(1) - indicates that the sub-layer interface, identified by the ifStackLowerLayer MAY be connected to run 'below' the sub-layer interface, identified by the ifStackHigherLayer index. false(2) - the sub-layer interfaces cannot be connected temporarily due to unavailability of the interface(s), e.g., one of the interfaces is located on an absent pluggable module. Note that lower-layer interface availability per higher-layer, indicated by the value of 'true', can be constrained by other parameters, for example, by the aggregation capacity of a higher-layer interface or by the lower-layer interface in question being already connected to another higher-layer interface. In order to ensure that a particular sub-layer can be connected to another sub-layer, all respective objects (e.g., ifCapStackTable, ifStackTable, and efmCuPAFCapacity for EFMCu interfaces) SHALL be inspected. This object is read-only, unlike ifStackStatus, as it describes a cross-connect capability." ::= { ifCapStackEntry 1 } ifInvCapStackTable OBJECT-TYPE SYNTAX SEQUENCE OF IfInvCapStackEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A table containing information on the possible relationships between the multiple sub-layers of network interfaces. This table, modeled after ifInvStackTable from IF-INVERTED-STACK-MIB, is an inverse of the ifCapStackTable defined in this MIB module. Beili Standards Track [Page 19]
RFC 5066 EFMCu Interfaces MIB November 2007 In particular, this table contains information on which sub-layers MAY run 'underneath' which other sub-layers, where each sub-layer corresponds to a conceptual row in the ifTable. For example, when the sub-layer with ifIndex value x MAY be connected to run underneath the sub-layer with ifIndex value y, then this table contains: ifInvCapStackStatus.x.y=true This table contains exactly the same number of rows as the ifCapStackTable, but the rows appear in a different order. This table is read-only as it describes a cross-connect capability." REFERENCE "IF-INVERTED-STACK-MIB, ifInvStackTable" ::= { ifCapStackObjects 2 } ifInvCapStackEntry OBJECT-TYPE SYNTAX IfInvCapStackEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Information on a particular relationship between two sub- layers, specifying that one sub-layer MAY run underneath the other sub-layer. Each sub-layer corresponds to a conceptual row in the ifTable." INDEX { ifStackLowerLayer, ifStackHigherLayer } ::= { ifInvCapStackTable 1 } IfInvCapStackEntry ::= SEQUENCE { ifInvCapStackStatus TruthValue } ifInvCapStackStatus OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-only STATUS current DESCRIPTION "The status of the possible 'cross-connect capability' relationship between two sub-layers. An instance of this object exists for each instance of the ifCapStackStatus object, and vice versa. For example, if the variable ifCapStackStatus.H.L exists, then the variable ifInvCapStackStatus.L.H must also exist, and vice versa. In addition, the two variables always have the same value. Beili Standards Track [Page 20]
RFC 5066 EFMCu Interfaces MIB November 2007 The ifInvCapStackStatus object is read-only, as it describes a cross-connect capability." REFERENCE "ifCapStackStatus" ::= { ifInvCapStackEntry 1 } -- -- Conformance Statements -- ifCapStackGroups OBJECT IDENTIFIER ::= { ifCapStackConformance 1 } ifCapStackCompliances OBJECT IDENTIFIER ::= { ifCapStackConformance 2 } -- Units of Conformance ifCapStackGroup OBJECT-GROUP OBJECTS { ifCapStackStatus, ifInvCapStackStatus } STATUS current DESCRIPTION "A collection of objects providing information on the cross-connect capability of multi-layer (stacked) network interfaces." ::= { ifCapStackGroups 1 } -- Compliance Statements ifCapStackCompliance MODULE-COMPLIANCE STATUS current DESCRIPTION "The compliance statement for SNMP entities, which provide information on the cross-connect capability of multi-layer (stacked) network interfaces, with flexible cross-connect between the sub-layers." MODULE -- this module MANDATORY-GROUPS { ifCapStackGroup } OBJECT ifCapStackStatus Beili Standards Track [Page 21]
RFC 5066 EFMCu Interfaces MIB November 2007 SYNTAX TruthValue { true(1) } DESCRIPTION "Support for the false(2) value is OPTIONAL for implementations supporting pluggable interfaces." OBJECT ifInvCapStackStatus SYNTAX TruthValue { true(1) } DESCRIPTION "Support for the false(2) value is OPTIONAL for implementations supporting pluggable interfaces." MODULE IF-MIB MANDATORY-GROUPS { ifStackGroup2 } MODULE IF-INVERTED-STACK-MIB MANDATORY-GROUPS { ifInvStackGroup } ::= { ifCapStackCompliances 1 } END 6. EFM Copper MIB Definitions EFM-CU-MIB DEFINITIONS ::= BEGIN IMPORTS MODULE-IDENTITY, OBJECT-TYPE, NOTIFICATION-TYPE, Integer32, Unsigned32, Counter32, mib-2 FROM SNMPv2-SMI -- [RFC2578] TEXTUAL-CONVENTION, TruthValue, RowStatus, PhysAddress FROM SNMPv2-TC -- [RFC2579] MODULE-COMPLIANCE, OBJECT-GROUP, NOTIFICATION-GROUP FROM SNMPv2-CONF -- [RFC2580] SnmpAdminString FROM SNMP-FRAMEWORK-MIB -- [RFC3411] ifIndex, ifSpeed FROM IF-MIB -- [RFC2863] ; efmCuMIB MODULE-IDENTITY LAST-UPDATED "200711140000Z" -- November 14, 2007 ORGANIZATION "IETF Ethernet Interfaces and Hub MIB Working Group" CONTACT-INFO "WG charter: http://www.ietf.org/html.charters/OLD/hubmib-charter.html Beili Standards Track [Page 22]
RFC 5066 EFMCu Interfaces MIB November 2007 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 Phone: +972-3-924-3491 Email: edward.beili@actelis.com" DESCRIPTION "The objects in this MIB module are used to manage the Ethernet in the First Mile (EFM) Copper (EFMCu) Interfaces 2BASE-TL and 10PASS-TS, defined in IEEE Std. 802.3ah-2004, which is now a part of IEEE Std. 802.3-2005. The following references are used throughout this MIB module: [802.3ah] refers to: IEEE Std 802.3ah-2004: '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 - Amendment: Media Access Control Parameters, Physical Layers and Management Parameters for Subscriber Access Networks', 07 September 2004. Of particular interest are Clause 61, 'Physical Coding Sublayer (PCS) and common specifications, type 10PASS-TS and type 2BASE-TL', Clause 30, 'Management', Clause 45, 'Management Data Input/Output (MDIO) Interface', Annex 62A, 'PMD profiles for 10PASS-TS' and Annex 63A, 'PMD profiles for 2BASE-TL'. Beili Standards Track [Page 23]
RFC 5066 EFMCu Interfaces MIB November 2007 [G.991.2] refers to: ITU-T Recommendation G.991.2: 'Single-pair High-speed Digital Subscriber Line (SHDSL) transceivers', December 2003. [ANFP] refers to: NICC Document ND1602:2005/08: 'Specification of the Access Network Frequency Plan (ANFP) applicable to transmission systems used on the BT Access Network,' August 2005. The following normative documents are quoted by the DESCRIPTION clauses in this MIB module: [G.993.1] refers to: ITU-T Recommendation G.993.1: 'Very High speed Digital Subscriber Line transceivers', June 2004. [T1.424] refers to: ANSI T1.424-2004: 'Interface Between Networks and Customer Installation Very-high-bit-rate Digital Subscriber Lines (VDSL) Metallic Interface (DMT Based)', June 2004. [TS 101 270-1] refers to: ETSI TS 101 270-1: 'Transmission and Multiplexing (TM); Access transmission systems on metallic access cables; Very high speed Digital Subscriber Line (VDSL); Part 1: Functional requirements', October 2005. Naming Conventions: Atn - Attenuation CO - Central Office CPE - Customer Premises Equipment EFM - Ethernet in the First Mile EFMCu - EFM Copper MDIO - Management Data Input/Output Mgn - Margin PAF - PME Aggregation Function PBO - Power Back-Off PCS - Physical Coding Sublayer PMD - Physical Medium Dependent PME - Physical Medium Entity PSD - Power Spectral Density SNR - Signal to Noise Ratio TCPAM - Trellis Coded Pulse Amplitude Modulation Copyright (C) The IETF Trust (2007). This version of this MIB module is part of RFC 5066; see the RFC itself for full legal notices." Beili Standards Track [Page 24]
RFC 5066 EFMCu Interfaces MIB November 2007 REVISION "200711140000Z" -- November 14, 2007 DESCRIPTION "Initial version, published as RFC 5066." ::= { mib-2 167 } -- Sections of the module efmCuObjects OBJECT IDENTIFIER ::= { efmCuMIB 1 } efmCuConformance OBJECT IDENTIFIER ::= { efmCuMIB 2 } -- Groups in the module efmCuPort OBJECT IDENTIFIER ::= { efmCuObjects 1 } efmCuPme OBJECT IDENTIFIER ::= { efmCuObjects 2 } -- Textual Conventions EfmProfileIndex ::= TEXTUAL-CONVENTION DISPLAY-HINT "d" STATUS current DESCRIPTION "A unique value, greater than zero, for each PME configuration profile in the managed EFMCu port. It is RECOMMENDED that values are assigned contiguously starting from 1. The value for each profile MUST remain constant at least from one re-initialization of the entity's network management system to the next re-initialization." SYNTAX Unsigned32 (1..255) EfmProfileIndexOrZero ::= TEXTUAL-CONVENTION DISPLAY-HINT "d" STATUS current DESCRIPTION "This textual convention is an extension of the EfmProfileIndex convention. The latter defines a greater than zero value used to identify a PME profile in the managed EFMCu port. This extension permits the additional value of zero. The value of zero is object-specific and MUST therefore be defined as part of the description of any object that uses this syntax. Examples of the usage of zero value might include situations where the current operational profile is unknown." SYNTAX Unsigned32 (0..255) EfmProfileIndexList ::= TEXTUAL-CONVENTION DISPLAY-HINT "1d:" Beili Standards Track [Page 25]
RFC 5066 EFMCu Interfaces MIB November 2007 STATUS current DESCRIPTION "This textual convention represents a list of up to 6 EfmProfileIndex values, any of which can be chosen for configuration of a PME in a managed EFMCu port. The EfmProfileIndex textual convention defines a greater than zero value used to identify a PME profile. The value of this object is a concatenation of zero or more (up to 6) octets, where each octet contains an 8-bit EfmProfileIndex value. A zero-length octet string is object-specific and MUST therefore be defined as part of the description of any object that uses this syntax. Examples of the usage of a zero-length value might include situations where an object using this textual convention is irrelevant for a specific EFMCu port type." SYNTAX OCTET STRING (SIZE(0..6)) EfmTruthValueOrUnknown ::= TEXTUAL-CONVENTION STATUS current DESCRIPTION "This textual convention is an extension of the TruthValue convention. The latter defines a boolean value with possible values of true(1) and false(2). This extension permits the additional value of unknown(0), which can be returned as the result of a GET operation when an exact true or false value of the object cannot be determined." SYNTAX INTEGER { unknown(0), true(1), false(2) } -- Port Notifications Group efmCuPortNotifications OBJECT IDENTIFIER ::= { efmCuPort 0 } efmCuLowRateCrossing NOTIFICATION-TYPE OBJECTS { ifSpeed, efmCuThreshLowRate } STATUS current DESCRIPTION "This notification indicates that the EFMCu port's data rate has reached/dropped below or exceeded the low rate threshold, specified by efmCuThreshLowRate. This notification MAY be sent for the -O subtype ports (2BaseTL-O/10PassTS-O) while the port is Up, on the crossing event in both directions: from normal (rate is above the threshold) to low (rate equals the threshold or below it) and Beili Standards Track [Page 26]
RFC 5066 EFMCu Interfaces MIB November 2007 from low to normal. This notification is not applicable to the -R subtypes. It is RECOMMENDED that a small debouncing period of 2.5 sec, between the detection of the condition and the notification, is implemented to prevent simultaneous LinkUp/LinkDown and efmCuLowRateCrossing notifications to be sent. The adaptive nature of the EFMCu technology allows the port to adapt itself to the changes in the copper environment, e.g., an impulse noise, alien crosstalk, or a micro-interruption may temporarily drop one or more PMEs in the aggregation group, causing a rate degradation of the aggregated EFMCu link. The dropped PMEs would then try to re-initialize, possibly at a lower rate than before, adjusting the rate to provide required target SNR margin. Generation of this notification is controlled by the efmCuLowRateCrossingEnable object." ::= { efmCuPortNotifications 1 } -- PCS Port group efmCuPortConfTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPortConfEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table for Configuration of EFMCu 2BASE-TL/10PASS-TS (PCS) Ports. Entries in this table MUST be maintained in a persistent manner." ::= { efmCuPort 1 } efmCuPortConfEntry OBJECT-TYPE SYNTAX EfmCuPortConfEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the EFMCu Port Configuration table. Each entry represents an EFMCu port indexed by the ifIndex. Note that an EFMCu PCS port runs on top of a single or multiple PME port(s), which are also indexed by ifIndex." INDEX { ifIndex } ::= { efmCuPortConfTable 1 } EfmCuPortConfEntry ::= SEQUENCE { efmCuPAFAdminState INTEGER, Beili Standards Track [Page 27]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPAFDiscoveryCode PhysAddress, efmCuAdminProfile EfmProfileIndexList, efmCuTargetDataRate Unsigned32, efmCuTargetSnrMgn Unsigned32, efmCuAdaptiveSpectra TruthValue, efmCuThreshLowRate Unsigned32, efmCuLowRateCrossingEnable TruthValue } efmCuPAFAdminState OBJECT-TYPE SYNTAX INTEGER { enabled(1), disabled(2) } MAX-ACCESS read-write STATUS current DESCRIPTION "Administrative (desired) state of the PAF of the EFMCu port (PCS). When 'disabled', PME aggregation will not be performed by the PCS. No more than a single PME can be assigned to this PCS in this case. When 'enabled', PAF will be performed by the PCS when the link is Up, even on a single attached PME, if PAF is supported. PCS ports incapable of supporting PAF SHALL return a value of 'disabled'. Attempts to 'enable' such ports SHALL be rejected. A PAF 'enabled' port with multiple PMEs assigned cannot be 'disabled'. Attempts to 'disable' such port SHALL be rejected, until at most one PME is left assigned. Changing PAFAdminState is a traffic-disruptive operation and as such SHALL be done when the link is Down. Attempts to change this object SHALL be rejected if the link is Up or Initializing. This object maps to the Clause 30 attribute aPAFAdminState. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the PAF enable bit in the 10P/2B PCS control register. This object MUST be maintained in a persistent manner." REFERENCE "[802.3ah] 61.2.2, 45.2.3.18.3" ::= { efmCuPortConfEntry 1 } Beili Standards Track [Page 28]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPAFDiscoveryCode OBJECT-TYPE SYNTAX PhysAddress (SIZE(0|6)) MAX-ACCESS read-write STATUS current DESCRIPTION "PAF Discovery Code of the EFMCu port (PCS). A unique 6-octet code used by the Discovery function, when PAF is supported. PCS ports incapable of supporting PAF SHALL return a zero-length octet string on an attempt to read this object. An attempt to write to this object SHALL be rejected for such ports. This object MUST be instantiated for the -O subtype PCS before writing operations on the efmCuPAFRemoteDiscoveryCode (Set_if_Clear and Clear_if_Same) are performed by PMEs associated with the PCS. The initial value of this object for -R subtype ports after reset is all zeroes. For -R subtype ports, the value of this object cannot be changed directly. This value may be changed as a result of writing operation on the efmCuPAFRemoteDiscoveryCode object of remote PME of -O subtype, connected to one of the local PMEs associated with the PCS. Discovery MUST be performed when the link is Down. Attempts to change this object MUST be rejected (in case of SNMP with the error inconsistentValue), if the link is Up or Initializing. The PAF Discovery Code maps to the local Discovery code variable in PAF (note that it does not have a corresponding Clause 45 register)." REFERENCE "[802.3ah] 61.2.2.8.3, 61.2.2.8.4, 45.2.6.6.1, 45.2.6.8, 61A.2" ::= { efmCuPortConfEntry 2 } efmCuAdminProfile OBJECT-TYPE SYNTAX EfmProfileIndexList MAX-ACCESS read-write STATUS current DESCRIPTION "Desired configuration profile(s), common for all PMEs in the EFMCu port. This object is a list of pointers to entries in either efmCuPme2BProfileTable or efmCuPme10PProfileTable, depending on the current operating SubType of the EFMCu port as indicated by efmCuPortSide. Beili Standards Track [Page 29]
RFC 5066 EFMCu Interfaces MIB November 2007 The value of this object is a list of up to 6 indices of profiles. If this list consists of a single profile index, then all PMEs assigned to this EFMCu port SHALL be configured according to the profile referenced by that index, unless it is overwritten by a corresponding non-zero efmCuPmeAdminProfile instance, which takes precedence over efmCuAdminProfile. A list consisting of more than one index allows each PME in the port to be configured according to any profile specified in the list. By default, this object has a value of 0x01, referencing the 1st entry in efmCuPme2BProfileTable or efmCuPme10PProfileTable. This object is writable and readable for the -O subtype (2BaseTL-O or 10PassTS-O) EFMCu ports. It is irrelevant for the -R subtype (2BaseTL-R or 10PassTS-R) ports -- a zero-length octet string SHALL be returned on an attempt to read this object and an attempt to change this object MUST be rejected in this case. Note that the current operational profile value is available via the efmCuPmeOperProfile object. Any modification of this object MUST be performed when the link is Down. Attempts to change this object MUST be rejected, if the link is Up or Initializing. Attempts to set this object to a list with a member value that is not the value of the index for an active entry in the corresponding profile table MUST be rejected. This object maps to the Clause 30 attribute aProfileSelect. This object MUST be maintained in a persistent manner." REFERENCE "[802.3ah] 30.11.2.1.6" DEFVAL { '01'H } ::= { efmCuPortConfEntry 3 } efmCuTargetDataRate OBJECT-TYPE SYNTAX Unsigned32(1..100000|999999) UNITS "Kbps" MAX-ACCESS read-write STATUS current DESCRIPTION "Desired EFMCu port 'net' (as seen across MII) Data Rate in Kbps, to be achieved during initialization, under spectral restrictions placed on each PME via efmCuAdminProfile or Beili Standards Track [Page 30]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPmeAdminProfile, with the desired SNR margin specified by efmCuTargetSnrMgn. In case of PAF, this object represents a sum of individual PME data rates, modified to compensate for fragmentation and 64/65-octet encapsulation overhead (e.g., target data rate of 10 Mbps SHALL allow lossless transmission of a full-duplex 10 Mbps Ethernet frame stream with minimal inter-frame gap). The value is limited above by 100 Mbps as this is the max burst rate across MII for EFMCu ports. The value between 1 and 100000 indicates that the total data rate (ifSpeed) of the EFMCu port after initialization SHALL be equal to the target data rate or less, if the target data rate cannot be achieved under spectral restrictions specified by efmCuAdminProfile/efmCuPmeAdminProfile and with the desired SNR margin. In case the copper environment allows a higher total data rate to be achieved than that specified by the target, the excess capability SHALL be either converted to additional SNR margin or reclaimed by minimizing transmit power as controlled by efmCuAdaptiveSpectra. The value of 999999 means that the target data rate is not fixed and SHALL be set to the maximum attainable rate during initialization (Best Effort), under specified spectral restrictions and with the desired SNR margin. This object is read-write for the -O subtype EFMCu ports (2BaseTL-O/10PassTS-O) and not available for the -R subtypes. Changing of the Target Data Rate MUST be performed when the link is Down. Attempts to change this object MUST be rejected (in case of SNMP with the error inconsistentValue), if the link is Up or Initializing. Note that the current Data Rate of the EFMCu port is represented by the ifSpeed object of IF-MIB. This object MUST be maintained in a persistent manner." ::= { efmCuPortConfEntry 4 } efmCuTargetSnrMgn OBJECT-TYPE SYNTAX Unsigned32(0..21) UNITS "dB" MAX-ACCESS read-write STATUS current DESCRIPTION "Desired EFMCu port SNR margin to be achieved on all PMEs Beili Standards Track [Page 31]
RFC 5066 EFMCu Interfaces MIB November 2007 assigned to the port, during initialization. (The SNR margin is the difference between the desired SNR and the actual SNR). Note that 802.3ah recommends using a default target SNR margin of 5 dB for 2BASE-TL ports and 6 dB for 10PASS-TS ports in order to achieve a mean Bit Error Rate (BER) of 10^-7 at the PMA service interface. This object is read-write for the -O subtype EFMCu ports (2BaseTL-O/10PassTS-O) and not available for the -R subtypes. Changing of the target SNR margin MUST be performed when the link is Down. Attempts to change this object MUST be rejected (in case of SNMP with the error inconsistentValue), if the link is Up or Initializing. Note that the current SNR margin of the PMEs comprising the EFMCu port is represented by efmCuPmeSnrMgn. This object MUST be maintained in a persistent manner." REFERENCE "[802.3ah] 61.1.2" ::= { efmCuPortConfEntry 5 } efmCuAdaptiveSpectra OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates how to utilize excess capacity when the copper environment allows a higher total data rate to be achieved than that specified by the efmCuTargetDataRate. A value of true(1) indicates that the excess capability SHALL be reclaimed by minimizing transmit power, e.g., using higher constellations and Power Back-Off, in order to reduce interference to other copper pairs in the binder and the adverse impact to link/system performance. A value of false(2) indicates that the excess capability SHALL be converted to additional SNR margin and spread evenly across all active PMEs assigned to the (PCS) port, to increase link robustness. This object is read-write for the -O subtype EFMCu ports (2BaseTL-O/10PassTS-O) and not available for the -R subtypes. Changing of this object MUST be performed when the link is Beili Standards Track [Page 32]
RFC 5066 EFMCu Interfaces MIB November 2007 Down. Attempts to change this object MUST be rejected (in case of SNMP with the error inconsistentValue), if the link is Up or Initializing. This object MUST be maintained in a persistent manner." ::= { efmCuPortConfEntry 6 } efmCuThreshLowRate OBJECT-TYPE SYNTAX Unsigned32(1..100000) UNITS "Kbps" MAX-ACCESS read-write STATUS current DESCRIPTION "This object configures the EFMCu port low-rate crossing alarm threshold. When the current value of ifSpeed for this port reaches/drops below or exceeds this threshold, an efmCuLowRateCrossing notification MAY be generated if enabled by efmCuLowRateCrossingEnable. This object is read-write for the -O subtype EFMCu ports (2BaseTL-O/10PassTS-O) and not available for the -R subtypes. This object MUST be maintained in a persistent manner." ::= { efmCuPortConfEntry 7 } efmCuLowRateCrossingEnable OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates whether efmCuLowRateCrossing notifications should be generated for this interface. A value of true(1) indicates that efmCuLowRateCrossing notification is enabled. A value of false(2) indicates that the notification is disabled. This object is read-write for the -O subtype EFMCu ports (2BaseTL-O/10PassTS-O) and not available for the -R subtypes. This object MUST be maintained in a persistent manner." ::= { efmCuPortConfEntry 8 } efmCuPortCapabilityTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPortCapabilityEntry MAX-ACCESS not-accessible STATUS current Beili Standards Track [Page 33]
RFC 5066 EFMCu Interfaces MIB November 2007 DESCRIPTION "Table for Capabilities of EFMCu 2BASE-TL/10PASS-TS (PCS) Ports. Entries in this table MUST be maintained in a persistent manner" ::= { efmCuPort 2 } efmCuPortCapabilityEntry OBJECT-TYPE SYNTAX EfmCuPortCapabilityEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the EFMCu Port Capability table. Each entry represents an EFMCu port indexed by the ifIndex. Note that an EFMCu PCS port runs on top of a single or multiple PME port(s), which are also indexed by ifIndex." INDEX { ifIndex } ::= { efmCuPortCapabilityTable 1 } EfmCuPortCapabilityEntry ::= SEQUENCE { efmCuPAFSupported TruthValue, efmCuPeerPAFSupported EfmTruthValueOrUnknown, efmCuPAFCapacity Unsigned32, efmCuPeerPAFCapacity Unsigned32 } efmCuPAFSupported OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-only STATUS current DESCRIPTION "PME Aggregation Function (PAF) capability of the EFMCu port (PCS). This object has a value of true(1) when the PCS can perform PME aggregation on the available PMEs. Ports incapable of PAF SHALL return a value of false(2). This object maps to the Clause 30 attribute aPAFSupported. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the PAF available bit in the 10P/2B capability register." REFERENCE "[802.3ah] 61.2.2, 30.11.1.1.4, 45.2.3.17.1" ::= { efmCuPortCapabilityEntry 1 } efmCuPeerPAFSupported OBJECT-TYPE SYNTAX EfmTruthValueOrUnknown Beili Standards Track [Page 34]
RFC 5066 EFMCu Interfaces MIB November 2007 MAX-ACCESS read-only STATUS current DESCRIPTION "PME Aggregation Function (PAF) capability of the EFMCu port (PCS) link partner. This object has a value of true(1) when the remote PCS can perform PME aggregation on its available PMEs. Ports whose peers are incapable of PAF SHALL return a value of false(2). Ports whose peers cannot be reached because of the link state SHALL return a value of unknown(0). This object maps to the Clause 30 attribute aRemotePAFSupported. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the Remote PAF supported bit in the 10P/2B capability register." REFERENCE "[802.3ah] 61.2.2, 30.11.1.1.9, 45.2.3.17.2" ::= { efmCuPortCapabilityEntry 2 } efmCuPAFCapacity OBJECT-TYPE SYNTAX Unsigned32 (1..32) MAX-ACCESS read-only STATUS current DESCRIPTION "Number of PMEs that can be aggregated by the local PAF. The number of PMEs currently assigned to a particular EFMCu port (efmCuNumPMEs) is never greater than efmCuPAFCapacity. This object maps to the Clause 30 attribute aLocalPAFCapacity." REFERENCE "[802.3ah] 61.2.2, 30.11.1.1.6" ::= { efmCuPortCapabilityEntry 3 } efmCuPeerPAFCapacity OBJECT-TYPE SYNTAX Unsigned32 (0|1..32) MAX-ACCESS read-only STATUS current DESCRIPTION "Number of PMEs that can be aggregated by the PAF of the peer PHY (PCS port). A value of 0 is returned when peer PAF capacity is unknown (peer cannot be reached). Beili Standards Track [Page 35]
RFC 5066 EFMCu Interfaces MIB November 2007 This object maps to the Clause 30 attribute aRemotePAFCapacity." REFERENCE "[802.3ah] 61.2.2, 30.11.1.1.10" ::= { efmCuPortCapabilityEntry 4 } efmCuPortStatusTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPortStatusEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table provides overall status information of EFMCu 2BASE-TL/10PASS-TS ports, complementing the generic status information from the ifTable of IF-MIB and ifMauTable of MAU-MIB. Additional status information about connected PMEs is available from the efmCuPmeStatusTable. This table contains live data from the equipment. As such, it is NOT persistent." ::= { efmCuPort 3 } efmCuPortStatusEntry OBJECT-TYPE SYNTAX EfmCuPortStatusEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the EFMCu Port Status table. Each entry represents an EFMCu port indexed by the ifIndex. Note that an EFMCu PCS port runs on top of a single or multiple PME port(s), which are also indexed by ifIndex." INDEX { ifIndex } ::= { efmCuPortStatusTable 1 } EfmCuPortStatusEntry ::= SEQUENCE { efmCuFltStatus BITS, efmCuPortSide INTEGER, efmCuNumPMEs Unsigned32, efmCuPAFInErrors Counter32, efmCuPAFInSmallFragments Counter32, efmCuPAFInLargeFragments Counter32, efmCuPAFInBadFragments Counter32, efmCuPAFInLostFragments Counter32, efmCuPAFInLostStarts Counter32, efmCuPAFInLostEnds Counter32, efmCuPAFInOverflows Counter32 } Beili Standards Track [Page 36]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuFltStatus OBJECT-TYPE SYNTAX BITS { noPeer(0), peerPowerLoss(1), pmeSubTypeMismatch(2), lowRate(3) } MAX-ACCESS read-only STATUS current DESCRIPTION "EFMCu (PCS) port Fault Status. This is a bitmap of possible conditions. The various bit positions are: noPeer - the peer PHY cannot be reached (e.g., no PMEs attached, all PMEs are Down, etc.). More info is available in efmCuPmeFltStatus. peerPowerLoss - the peer PHY has indicated impending unit failure due to loss of local power ('Dying Gasp'). pmeSubTypeMismatch - local PMEs in the aggregation group are not of the same subtype, e.g., some PMEs in the local device are -O while others are -R subtype. lowRate - ifSpeed of the port reached or dropped below efmCuThreshLowRate. This object is intended to supplement the ifOperStatus object in IF-MIB and ifMauMediaAvailable in MAU-MIB. Additional information is available via the efmCuPmeFltStatus object for each PME in the aggregation group (single PME if PAF is disabled)." REFERENCE "IF-MIB, ifOperStatus; MAU-MIB, ifMauMediaAvailable; efmCuPmeFltStatus" ::= { efmCuPortStatusEntry 1 } efmCuPortSide OBJECT-TYPE SYNTAX INTEGER { subscriber(1), office(2), unknown(3) } MAX-ACCESS read-only STATUS current DESCRIPTION "EFM port mode of operation (subtype). The value of 'subscriber' indicates that the port is Beili Standards Track [Page 37]
RFC 5066 EFMCu Interfaces MIB November 2007 designated as '-R' subtype (all PMEs assigned to this port are of subtype '-R'). The value of the 'office' indicates that the port is designated as '-O' subtype (all PMEs assigned to this port are of subtype '-O'). The value of 'unknown' indicates that the port has no assigned PMEs yet or that the assigned PMEs are not of the same side (subTypePMEMismatch). This object partially maps to the Clause 30 attribute aPhyEnd." REFERENCE "[802.3ah] 61.1, 30.11.1.1.2" ::= { efmCuPortStatusEntry 2 } efmCuNumPMEs OBJECT-TYPE SYNTAX Unsigned32 (0..32) MAX-ACCESS read-only STATUS current DESCRIPTION "The number of PMEs that is currently aggregated by the local PAF (assigned to the EFMCu port using the ifStackTable). This number is never greater than efmCuPAFCapacity. This object SHALL be automatically incremented or decremented when a PME is added or deleted to/from the EFMCu port using the ifStackTable." REFERENCE "[802.3ah] 61.2.2, 30.11.1.1.6" ::= { efmCuPortStatusEntry 3 } efmCuPAFInErrors OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of fragments that have been received across the gamma interface with RxErr asserted and discarded. This read-only counter is inactive (not incremented) when the PAF is unsupported or disabled. Upon disabling the PAF, the counter retains its previous value. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the 10P/2B PAF RX error register. 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, Beili Standards Track [Page 38]
RFC 5066 EFMCu Interfaces MIB November 2007 defined in IF-MIB." REFERENCE "[802.3ah] 45.2.3.21" ::= { efmCuPortStatusEntry 4 } efmCuPAFInSmallFragments OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of fragments smaller than minFragmentSize (64 bytes) that have been received across the gamma interface and discarded. This read-only counter is inactive when the PAF is unsupported or disabled. Upon disabling the PAF, the counter retains its previous value. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the 10P/2B PAF small fragments register. 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, defined in IF-MIB." REFERENCE "[802.3ah] 45.2.3.22" ::= { efmCuPortStatusEntry 5 } efmCuPAFInLargeFragments OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of fragments larger than maxFragmentSize (512 bytes) that have been received across the gamma interface and discarded. This read-only counter is inactive when the PAF is unsupported or disabled. Upon disabling the PAF, the counter retains its previous value. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the 10P/2B PAF large fragments register. 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, defined in IF-MIB." REFERENCE Beili Standards Track [Page 39]
RFC 5066 EFMCu Interfaces MIB November 2007 "[802.3ah] 45.2.3.23" ::= { efmCuPortStatusEntry 6 } efmCuPAFInBadFragments OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of fragments that do not fit into the sequence expected by the frame assembly function and that have been received across the gamma interface and discarded (the frame buffer is flushed to the next valid frame start). This read-only counter is inactive when the PAF is unsupported or disabled. Upon disabling the PAF, the counter retains its previous value. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the 10P/2B PAF bad fragments register. 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, defined in IF-MIB." REFERENCE "[802.3ah] 45.2.3.25" ::= { efmCuPortStatusEntry 7 } efmCuPAFInLostFragments OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of gaps in the sequence of fragments that have been received across the gamma interface (the frame buffer is flushed to the next valid frame start, when fragment/fragments expected by the frame assembly function is/are not received). This read-only counter is inactive when the PAF is unsupported or disabled. Upon disabling the PAF, the counter retains its previous value. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the 10P/2B PAF lost fragment register. 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, defined in IF-MIB." REFERENCE Beili Standards Track [Page 40]
RFC 5066 EFMCu Interfaces MIB November 2007 "[802.3ah] 45.2.3.26" ::= { efmCuPortStatusEntry 8 } efmCuPAFInLostStarts OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of missing StartOfPacket indicators expected by the frame assembly function. This read-only counter is inactive when the PAF is unsupported or disabled. Upon disabling the PAF, the counter retains its previous value. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the 10P/2B PAF lost start of fragment register. 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, defined in IF-MIB." REFERENCE "[802.3ah] 45.2.3.27" ::= { efmCuPortStatusEntry 9 } efmCuPAFInLostEnds OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of missing EndOfPacket indicators expected by the frame assembly function. This read-only counter is inactive when the PAF is unsupported or disabled. Upon disabling the PAF, the counter retains its previous value. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the 10P/2B PAF lost start of fragment register. 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, defined in IF-MIB." REFERENCE "[802.3ah] 45.2.3.28" ::= { efmCuPortStatusEntry 10 } Beili Standards Track [Page 41]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPAFInOverflows OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of fragments, received across the gamma interface and discarded, which would have caused the frame assembly buffer to overflow. This read-only counter is inactive when the PAF is unsupported or disabled. Upon disabling the PAF, the counter retains its previous value. If a Clause 45 MDIO Interface to the PCS is present, then this object maps to the 10P/2B PAF overflow register. 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, defined in IF-MIB." REFERENCE "[802.3ah] 45.2.3.24" ::= { efmCuPortStatusEntry 11 } -- PME Notifications Group efmCuPmeNotifications OBJECT IDENTIFIER ::= { efmCuPme 0 } efmCuPmeLineAtnCrossing NOTIFICATION-TYPE OBJECTS { efmCuPmeLineAtn, efmCuPmeThreshLineAtn } STATUS current DESCRIPTION "This notification indicates that the loop attenuation threshold (as per the efmCuPmeThreshLineAtn value) has been reached/exceeded for the 2BASE-TL/10PASS-TS PME. This notification MAY be sent on the crossing event in both directions: from normal to exceeded and from exceeded to normal. It is RECOMMENDED that a small debouncing period of 2.5 sec, between the detection of the condition and the notification, is implemented to prevent intermittent notifications from being sent. Generation of this notification is controlled by the efmCuPmeLineAtnCrossingEnable object." Beili Standards Track [Page 42]
RFC 5066 EFMCu Interfaces MIB November 2007 ::= { efmCuPmeNotifications 1 } efmCuPmeSnrMgnCrossing NOTIFICATION-TYPE OBJECTS { efmCuPmeSnrMgn, efmCuPmeThreshSnrMgn } STATUS current DESCRIPTION "This notification indicates that the SNR margin threshold (as per the efmCuPmeThreshSnrMgn value) has been reached/exceeded for the 2BASE-TL/10PASS-TS PME. This notification MAY be sent on the crossing event in both directions: from normal to exceeded and from exceeded to normal. It is RECOMMENDED that a small debouncing period of 2.5 sec, between the detection of the condition and the notification, is implemented to prevent intermittent notifications from being sent. Generation of this notification is controlled by the efmCuPmeSnrMgnCrossingEnable object." ::= { efmCuPmeNotifications 2 } efmCuPmeDeviceFault NOTIFICATION-TYPE OBJECTS { efmCuPmeFltStatus } STATUS current DESCRIPTION "This notification indicates that a fault in the PME has been detected by a vendor-specific diagnostic or a self-test. Generation of this notification is controlled by the efmCuPmeDeviceFaultEnable object." ::= { efmCuPmeNotifications 3 } efmCuPmeConfigInitFailure NOTIFICATION-TYPE OBJECTS { efmCuPmeFltStatus, efmCuAdminProfile, efmCuPmeAdminProfile } STATUS current DESCRIPTION "This notification indicates that PME initialization has failed, due to inability of the PME link to achieve the Beili Standards Track [Page 43]
RFC 5066 EFMCu Interfaces MIB November 2007 requested configuration profile. Generation of this notification is controlled by the efmCuPmeConfigInitFailEnable object." ::= { efmCuPmeNotifications 4 } efmCuPmeProtocolInitFailure NOTIFICATION-TYPE OBJECTS { efmCuPmeFltStatus, efmCuPmeOperSubType } STATUS current DESCRIPTION "This notification indicates that the peer PME was using an incompatible protocol during initialization. Generation of this notification is controlled by the efmCuPmeProtocolInitFailEnable object." ::= { efmCuPmeNotifications 5 } -- The PME group efmCuPmeConfTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPmeConfEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table for Configuration of common aspects for EFMCu 2BASE-TL/10PASS-TS PME ports (modems). Configuration of aspects specific to 2BASE-TL or 10PASS-TS PME types is represented in efmCuPme2BConfTable and efmCuPme10PConfTable, respectively. Entries in this table MUST be maintained in a persistent manner." ::= { efmCuPme 1 } efmCuPmeConfEntry OBJECT-TYPE SYNTAX EfmCuPmeConfEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the EFMCu PME Configuration table. Each entry represents common aspects of an EFMCu PME port indexed by the ifIndex. Note that an EFMCu PME port can be stacked below a single PCS port, also indexed by ifIndex, possibly together with other PME ports if PAF is enabled." INDEX { ifIndex } Beili Standards Track [Page 44]
RFC 5066 EFMCu Interfaces MIB November 2007 ::= { efmCuPmeConfTable 1 } EfmCuPmeConfEntry ::= SEQUENCE { efmCuPmeAdminSubType INTEGER, efmCuPmeAdminProfile EfmProfileIndexOrZero, efmCuPAFRemoteDiscoveryCode PhysAddress, efmCuPmeThreshLineAtn Integer32, efmCuPmeThreshSnrMgn Integer32, efmCuPmeLineAtnCrossingEnable TruthValue, efmCuPmeSnrMgnCrossingEnable TruthValue, efmCuPmeDeviceFaultEnable TruthValue, efmCuPmeConfigInitFailEnable TruthValue, efmCuPmeProtocolInitFailEnable TruthValue } efmCuPmeAdminSubType OBJECT-TYPE SYNTAX INTEGER { ieee2BaseTLO(1), ieee2BaseTLR(2), ieee10PassTSO(3), ieee10PassTSR(4), ieee2BaseTLor10PassTSR(5), ieee2BaseTLor10PassTSO(6), ieee10PassTSor2BaseTLO(7) } MAX-ACCESS read-write STATUS current DESCRIPTION "Administrative (desired) subtype of the PME. Possible values are: ieee2BaseTLO - PME SHALL operate as 2BaseTL-O ieee2BaseTLR - PME SHALL operate as 2BaseTL-R ieee10PassTSO - PME SHALL operate as 10PassTS-O ieee10PassTSR - PME SHALL operate as 10PassTS-R ieee2BaseTLor10PassTSR - PME SHALL operate as 2BaseTL-R or 10PassTS-R. The actual value will be set by the -O link partner during initialization (handshake). ieee2BaseTLor10PassTSO - PME SHALL operate as 2BaseTL-O (preferred) or 10PassTS-O. The actual value will be set during initialization depending on the -R link partner capability (i.e., if -R is incapable of the preferred 2BaseTL mode, 10PassTS will be used). ieee10PassTSor2BaseTLO - PME SHALL operate as 10PassTS-O Beili Standards Track [Page 45]
RFC 5066 EFMCu Interfaces MIB November 2007 (preferred) or 2BaseTL-O. The actual value will be set during initialization depending on the -R link partner capability (i.e., if -R is incapable of the preferred 10PassTS mode, 2BaseTL will be used). Changing efmCuPmeAdminSubType is a traffic-disruptive operation and as such SHALL be done when the link is Down. Attempts to change this object SHALL be rejected if the link is Up or Initializing. Attempts to change this object to an unsupported subtype (see efmCuPmeSubTypesSupported) SHALL be rejected. The current operational subtype is indicated by the efmCuPmeOperSubType variable. If a Clause 45 MDIO Interface to the PMA/PMD is present, then this object combines values of the Port subtype select bits and the PMA/PMD type selection bits in the 10P/2B PMA/PMD control register." REFERENCE "[802.3ah] 61.1, 45.2.1.11.4, 45.2.1.11.7" ::= { efmCuPmeConfEntry 1 } efmCuPmeAdminProfile OBJECT-TYPE SYNTAX EfmProfileIndexOrZero MAX-ACCESS read-write STATUS current DESCRIPTION "Desired PME configuration profile. This object is a pointer to an entry in either the efmCuPme2BProfileTable or the efmCuPme10PProfileTable, depending on the current operating SubType of the PME. The value of this object is the index of the referenced profile. The value of zero (default) indicates that the PME is configured via the efmCuAdminProfile object for the PCS port to which this PME is assigned. That is, the profile referenced by efmCuPmeAdminProfile takes precedence over the profile(s) referenced by efmCuAdminProfile. This object is writable and readable for the CO subtype PMEs (2BaseTL-O or 10PassTS-O). It is irrelevant for the CPE subtype (2BaseTL-R or 10PassTS-R) -- a zero value SHALL be returned on an attempt to read this object and any attempt to change this object MUST be rejected in this case. Beili Standards Track [Page 46]
RFC 5066 EFMCu Interfaces MIB November 2007 Note that the current operational profile value is available via efmCuPmeOperProfile object. Any modification of this object MUST be performed when the link is Down. Attempts to change this object MUST be rejected, if the link is Up or Initializing. Attempts to set this object to a value that is not the value of the index for an active entry in the corresponding profile table MUST be rejected. This object maps to the Clause 30 attribute aProfileSelect. This object MUST be maintained in a persistent manner." REFERENCE "[802.3ah] 30.11.2.1.6" DEFVAL { 0 } ::= { efmCuPmeConfEntry 2 } efmCuPAFRemoteDiscoveryCode OBJECT-TYPE SYNTAX PhysAddress (SIZE(0|6)) MAX-ACCESS read-write STATUS current DESCRIPTION "PAF Remote Discovery Code of the PME port at the CO. The 6-octet Discovery Code of the peer PCS connected via the PME. Reading this object results in a Discovery Get operation. Setting this object to all zeroes results in a Discovery Clear_if_Same operation (the value of efmCuPAFDiscoveryCode at the peer PCS SHALL be the same as efmCuPAFDiscoveryCode of the local PCS associated with the PME for the operation to succeed). Writing a non-zero value to this object results in a Discovery Set_if_Clear operation. A zero-length octet string SHALL be returned on an attempt to read this object when PAF aggregation is not enabled. This object is irrelevant in CPE port (-R) subtypes: in this case, a zero-length octet string SHALL be returned on an attempt to read this object; writing to this object SHALL be rejected. Discovery MUST be performed when the link is Down. Attempts to change this object MUST be rejected (in case of SNMP with the error inconsistentValue), if the link is Up or Initializing. Beili Standards Track [Page 47]
RFC 5066 EFMCu Interfaces MIB November 2007 If a Clause 45 MDIO Interface to the PMA/PMD is present, then this object is a function of 10P/2B aggregation discovery control register, Discovery operation result bits in 10P/2B aggregation and discovery status register and 10P/2B aggregation discovery code register." REFERENCE "[802.3ah] 61.2.2.8.4, 45.2.6.6-45.2.6.8" ::= { efmCuPmeConfEntry 3 } efmCuPmeThreshLineAtn OBJECT-TYPE SYNTAX Integer32(-127..128) UNITS "dB" MAX-ACCESS read-write STATUS current DESCRIPTION "Desired Line Attenuation threshold for the 2B/10P PME. This object configures the line attenuation alarm threshold. When the current value of Line Attenuation reaches or exceeds this threshold, an efmCuPmeLineAtnCrossing notification MAY be generated, if enabled by efmCuPmeLineAtnCrossingEnable. This object is writable for the CO subtype PMEs (-O). It is read-only for the CPE subtype (-R). Changing of the Line Attenuation threshold MUST be performed when the link is Down. Attempts to change this object MUST be rejected (in case of SNMP with the error inconsistentValue), if the link is Up or Initializing. If a Clause 45 MDIO Interface to the PME is present, then this object maps to the loop attenuation threshold bits in the 2B PMD line quality thresholds register." REFERENCE "[802.3ah] 45.2.1.36" ::= { efmCuPmeConfEntry 4 } efmCuPmeThreshSnrMgn OBJECT-TYPE SYNTAX Integer32(-127..128) UNITS "dB" MAX-ACCESS read-write STATUS current DESCRIPTION "Desired SNR margin threshold for the 2B/10P PME. This object configures the SNR margin alarm threshold. When the current value of SNR margin reaches or exceeds this threshold, an efmCuPmeSnrMgnCrossing notification MAY be generated, if enabled by efmCuPmeSnrMgnCrossingEnable. Beili Standards Track [Page 48]
RFC 5066 EFMCu Interfaces MIB November 2007 This object is writable for the CO subtype PMEs (2BaseTL-O/10PassTS-O). It is read-only for the CPE subtype (2BaseTL-R/10PassTS-R). Changing of the SNR margin threshold MUST be performed when the link is Down. Attempts to change this object MUST be rejected (in case of SNMP with the error inconsistentValue), if the link is Up or Initializing. If a Clause 45 MDIO Interface to the PME is present, then this object maps to the SNR margin threshold bits in the 2B PMD line quality thresholds register." REFERENCE "[802.3ah] 45.2.1.36" ::= { efmCuPmeConfEntry 5 } efmCuPmeLineAtnCrossingEnable OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates whether efmCuPmeLineAtnCrossing notifications should be generated for this interface. A value of true(1) indicates that efmCuPmeLineAtnCrossing notification is enabled. A value of false(2) indicates that the notification is disabled." ::= { efmCuPmeConfEntry 6 } efmCuPmeSnrMgnCrossingEnable OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates whether efmCuPmeSnrMgnCrossing notifications should be generated for this interface. A value of true(1) indicates that efmCuPmeSnrMgnCrossing notification is enabled. A value of false(2) indicates that the notification is disabled." ::= { efmCuPmeConfEntry 7 } efmCuPmeDeviceFaultEnable OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates whether efmCuPmeDeviceFault notifications Beili Standards Track [Page 49]
RFC 5066 EFMCu Interfaces MIB November 2007 should be generated for this interface. A value of true(1) indicates that efmCuPmeDeviceFault notification is enabled. A value of false(2) indicates that the notification is disabled." ::= { efmCuPmeConfEntry 8 } efmCuPmeConfigInitFailEnable OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates whether efmCuPmeConfigInitFailure notifications should be generated for this interface. A value of true(1) indicates that efmCuPmeConfigInitFailure notification is enabled. A value of false(2) indicates that the notification is disabled." ::= { efmCuPmeConfEntry 9 } efmCuPmeProtocolInitFailEnable OBJECT-TYPE SYNTAX TruthValue MAX-ACCESS read-write STATUS current DESCRIPTION "Indicates whether efmCuPmeProtocolInitFailure notifications should be generated for this interface. A value of true(1) indicates that efmCuPmeProtocolInitFailure notification is enabled. A value of false(2) indicates that the notification is disabled." ::= { efmCuPmeConfEntry 10 } efmCuPmeCapabilityTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPmeCapabilityEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table for the configuration of common aspects for EFMCu 2BASE-TL/10PASS-TS PME ports (modems). The configuration of aspects specific to 2BASE-TL or 10PASS-TS PME types is represented in the efmCuPme2BConfTable and the efmCuPme10PConfTable, respectively. Entries in this table MUST be maintained in a persistent manner." ::= { efmCuPme 2 } Beili Standards Track [Page 50]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPmeCapabilityEntry OBJECT-TYPE SYNTAX EfmCuPmeCapabilityEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the EFMCu PME Capability table. Each entry represents common aspects of an EFMCu PME port indexed by the ifIndex. Note that an EFMCu PME port can be stacked below a single PCS port, also indexed by ifIndex, possibly together with other PME ports if PAF is enabled." INDEX { ifIndex } ::= { efmCuPmeCapabilityTable 1 } EfmCuPmeCapabilityEntry ::= SEQUENCE { efmCuPmeSubTypesSupported BITS } efmCuPmeSubTypesSupported OBJECT-TYPE SYNTAX BITS { ieee2BaseTLO(0), ieee2BaseTLR(1), ieee10PassTSO(2), ieee10PassTSR(3) } MAX-ACCESS read-only STATUS current DESCRIPTION "PME supported subtypes. This is a bitmap of possible subtypes. The various bit positions are: ieee2BaseTLO - PME is capable of operating as 2BaseTL-O ieee2BaseTLR - PME is capable of operating as 2BaseTL-R ieee10PassTSO - PME is capable of operating as 10PassTS-O ieee10PassTSR - PME is capable of operating as 10PassTS-R The desired mode of operation is determined by efmCuPmeAdminSubType, while efmCuPmeOperSubType reflects the current operating mode. If a Clause 45 MDIO Interface to the PCS is present, then this object combines the 10PASS-TS capable and 2BASE-TL capable bits in the 10P/2B PMA/PMD speed ability register and the CO supported and CPE supported bits in the 10P/2B PMA/PMD status register." REFERENCE "[802.3ah] 61.1, 45.2.1.4.1, 45.2.1.4.2, 45.2.1.12.2, 45.2.1.12.3" ::= { efmCuPmeCapabilityEntry 1 } Beili Standards Track [Page 51]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPmeStatusTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPmeStatusEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table provides common status information of EFMCu 2BASE-TL/10PASS-TS PME ports. Status information specific to 10PASS-TS PME is represented in efmCuPme10PStatusTable. This table contains live data from the equipment. As such, it is NOT persistent." ::= { efmCuPme 3 } efmCuPmeStatusEntry OBJECT-TYPE SYNTAX EfmCuPmeStatusEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the EFMCu PME Status table. Each entry represents common aspects of an EFMCu PME port indexed by the ifIndex. Note that an EFMCu PME port can be stacked below a single PCS port, also indexed by ifIndex, possibly together with other PME ports if PAF is enabled." INDEX { ifIndex } ::= { efmCuPmeStatusTable 1 } EfmCuPmeStatusEntry ::= SEQUENCE { efmCuPmeOperStatus INTEGER, efmCuPmeFltStatus BITS, efmCuPmeOperSubType INTEGER, efmCuPmeOperProfile EfmProfileIndexOrZero, efmCuPmeSnrMgn Integer32, efmCuPmePeerSnrMgn Integer32, efmCuPmeLineAtn Integer32, efmCuPmePeerLineAtn Integer32, efmCuPmeEquivalentLength Unsigned32, efmCuPmeTCCodingErrors Counter32, efmCuPmeTCCrcErrors Counter32 } efmCuPmeOperStatus OBJECT-TYPE SYNTAX INTEGER { up(1), downNotReady(2), downReady(3), init(4) } Beili Standards Track [Page 52]
RFC 5066 EFMCu Interfaces MIB November 2007 MAX-ACCESS read-only STATUS current DESCRIPTION "Current PME link Operational Status. Possible values are: up(1) - The link is Up and ready to pass 64/65-octet encoded frames or fragments. downNotReady(2) - The link is Down and the PME does not detect Handshake tones from its peer. This value may indicate a possible problem with the peer PME. downReady(3) - The link is Down and the PME detects Handshake tones from its peer. init(4) - The link is Initializing, as a result of ifAdminStatus being set to 'up' for a particular PME or a PCS to which the PME is connected. This object is intended to supplement the Down(2) state of ifOperStatus. This object partially maps to the Clause 30 attribute aPMEStatus. If a Clause 45 MDIO Interface to the PME is present, then this object partially maps to PMA/PMD link status bits in 10P/2B PMA/PMD status register." REFERENCE "[802.3ah] 30.11.2.1.3, 45.2.1.12.4" ::= { efmCuPmeStatusEntry 1 } efmCuPmeFltStatus OBJECT-TYPE SYNTAX BITS { lossOfFraming(0), snrMgnDefect(1), lineAtnDefect(2), deviceFault(3), configInitFailure(4), protocolInitFailure(5) } MAX-ACCESS read-only STATUS current DESCRIPTION "Current/Last PME link Fault Status. This is a bitmap of possible conditions. The various bit positions are: lossOfFraming - Loss of Framing for 10P or Loss of Sync word for 2B PMD or Loss of 64/65-octet framing. Beili Standards Track [Page 53]
RFC 5066 EFMCu Interfaces MIB November 2007 snrMgnDefect - SNR margin dropped below the threshold. lineAtnDefect - Line Attenuation exceeds the threshold. deviceFault - Indicates a vendor-dependent diagnostic or self-test fault has been detected. configInitFailure - Configuration initialization failure, due to inability of the PME link to support the configuration profile, requested during initialization. protocolInitFailure - Protocol initialization failure, due to an incompatible protocol used by the peer PME during init (that could happen if a peer PMD is a regular G.SDHSL/VDSL modem instead of a 2BASE-TL/10PASS-TS PME). This object is intended to supplement ifOperStatus in IF-MIB. This object holds information about the last fault. efmCuPmeFltStatus is cleared by the device restart. In addition, lossOfFraming, configInitFailure, and protocolInitFailure are cleared by PME init; deviceFault is cleared by successful diagnostics/test; snrMgnDefect and lineAtnDefect are cleared by SNR margin and Line attenuation, respectively, returning to norm and by PME init. This object partially maps to the Clause 30 attribute aPMEStatus. If a Clause 45 MDIO Interface to the PME is present, then this object consolidates information from various PMA/PMD registers, namely: Fault bit in PMA/PMD status 1 register, 10P/2B PMA/PMD link loss register, 10P outgoing indicator bits status register, 10P incoming indicator bits status register, 2B state defects register." REFERENCE "[802.3ah] 30.11.2.1.3, 45.2.1.2.1, 45.2.1.38, 45.2.1.39, 45.2.1.54" ::= { efmCuPmeStatusEntry 2 } efmCuPmeOperSubType OBJECT-TYPE SYNTAX INTEGER { ieee2BaseTLO(1), ieee2BaseTLR(2), Beili Standards Track [Page 54]
RFC 5066 EFMCu Interfaces MIB November 2007 ieee10PassTSO(3), ieee10PassTSR(4) } MAX-ACCESS read-only STATUS current DESCRIPTION "Current operational subtype of the PME. Possible values are: ieee2BaseTLO - PME operates as 2BaseTL-O ieee2BaseTLR - PME operates as 2BaseTL-R ieee10PassTSO - PME operates as 10PassTS-O ieee10PassTSR - PME operates as 10PassTS-R The desired operational subtype of the PME can be configured via the efmCuPmeAdminSubType variable. If a Clause 45 MDIO Interface to the PMA/PMD is present, then this object combines values of the Port subtype select bits, the PMA/PMD type selection bits in the 10P/2B PMA/PMD control register, and the PMA/PMD link status bits in the 10P/2B PMA/PMD status register." REFERENCE "[802.3ah] 61.1, 45.2.1.11.4, 45.2.1.11.7, 45.2.1.12.4" ::= { efmCuPmeStatusEntry 3 } efmCuPmeOperProfile OBJECT-TYPE SYNTAX EfmProfileIndexOrZero MAX-ACCESS read-only STATUS current DESCRIPTION "PME current operating profile. This object is a pointer to an entry in either the efmCuPme2BProfileTable or the efmCuPme10PProfileTable, depending on the current operating SubType of the PME as indicated by efmCuPmeOperSubType. Note that a profile entry to which efmCuPmeOperProfile is pointing can be created automatically to reflect achieved parameters in adaptive (not fixed) initialization, i.e., values of efmCuPmeOperProfile and efmCuAdminProfile or efmCuPmeAdminProfile may differ. The value of zero indicates that the PME is Down or Initializing. This object partially maps to the aOperatingProfile attribute in Clause 30." REFERENCE "[802.3ah] 30.11.2.1.7" ::= { efmCuPmeStatusEntry 4 } Beili Standards Track [Page 55]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPmeSnrMgn OBJECT-TYPE SYNTAX Integer32(-127..128|65535) UNITS "dB" MAX-ACCESS read-only STATUS current DESCRIPTION "The current Signal to Noise Ratio (SNR) margin with respect to the received signal as perceived by the local PME. The value of 65535 is returned when the PME is Down or Initializing. This object maps to the aPMESNRMgn attribute in Clause 30. If a Clause 45 MDIO Interface is present, then this object maps to the 10P/2B RX SNR margin register." REFERENCE "[802.3ah] 30.11.2.1.4, 45.2.1.16" ::= { efmCuPmeStatusEntry 5 } efmCuPmePeerSnrMgn OBJECT-TYPE SYNTAX Integer32(-127..128|65535) UNITS "dB" MAX-ACCESS read-only STATUS current DESCRIPTION "The current SNR margin in dB with respect to the received signal, as perceived by the remote (link partner) PME. The value of 65535 is returned when the PME is Down or Initializing. This object is irrelevant for the -R PME subtypes. The value of 65535 SHALL be returned in this case. If a Clause 45 MDIO Interface is present, then this object maps to the 10P/2B link partner RX SNR margin register." REFERENCE "[802.3ah] 45.2.1.17" ::= { efmCuPmeStatusEntry 6} efmCuPmeLineAtn OBJECT-TYPE SYNTAX Integer32(-127..128|65535) UNITS "dB" MAX-ACCESS read-only STATUS current DESCRIPTION "The current Line Attenuation in dB as perceived by the local PME. Beili Standards Track [Page 56]
RFC 5066 EFMCu Interfaces MIB November 2007 The value of 65535 is returned when the PME is Down or Initializing. If a Clause 45 MDIO Interface is present, then this object maps to the Line Attenuation register." REFERENCE "[802.3ah] 45.2.1.18" ::= { efmCuPmeStatusEntry 7 } efmCuPmePeerLineAtn OBJECT-TYPE SYNTAX Integer32(-127..128|65535) UNITS "dB" MAX-ACCESS read-only STATUS current DESCRIPTION "The current Line Attenuation in dB as perceived by the remote (link partner) PME. The value of 65535 is returned when the PME is Down or Initializing. This object is irrelevant for the -R PME subtypes. The value of 65535 SHALL be returned in this case. If a Clause 45 MDIO Interface is present, then this object maps to the 20P/2B link partner Line Attenuation register." REFERENCE "[802.3ah] 45.2.1.19" ::= { efmCuPmeStatusEntry 8 } efmCuPmeEquivalentLength OBJECT-TYPE SYNTAX Unsigned32(0..8192|65535) UNITS "m" MAX-ACCESS read-only STATUS current DESCRIPTION "An estimate of the equivalent loop's physical length in meters, as perceived by the PME after the link is established. An equivalent loop is a hypothetical 26AWG (0.4mm) loop with a perfect square root attenuation characteristic, without any bridged taps. The value of 65535 is returned if the link is Down or Initializing or the PME is unable to estimate the equivalent length. For a 10BASE-TL PME, if a Clause 45 MDIO Interface to the PME is present, then this object maps to the 10P Electrical Length register." Beili Standards Track [Page 57]
RFC 5066 EFMCu Interfaces MIB November 2007 REFERENCE "[802.3ah] 45.2.1.21" ::= { efmCuPmeStatusEntry 9 } efmCuPmeTCCodingErrors OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of 64/65-octet encapsulation errors. This counter is incremented for each 64/65-octet encapsulation error detected by the 64/65-octet receive function. This object maps to aTCCodingViolations attribute in Clause 30. If a Clause 45 MDIO Interface to the PME TC is present, then this object maps to the TC coding violations register (see 45.2.6.12). 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, defined in IF-MIB." REFERENCE "[802.3ah] 61.3.3.1, 30.11.2.1.5, 45.2.6.12" ::= { efmCuPmeStatusEntry 10 } efmCuPmeTCCrcErrors OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of TC-CRC errors. This counter is incremented for each TC-CRC error detected by the 64/65-octet receive function (see 61.3.3.3 and Figure 61-19). This object maps to aTCCRCErrors attribute in Clause 30. If a Clause 45 MDIO Interface to the PME TC is present, then this object maps to the TC CRC error register (see 45.2.6.11). 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, defined in IF-MIB." Beili Standards Track [Page 58]
RFC 5066 EFMCu Interfaces MIB November 2007 REFERENCE "[802.3ah] 61.3.3.3, 30.11.2.1.10, 45.2.6.11" ::= { efmCuPmeStatusEntry 11 } -- 2BASE-TL specific PME group efmCuPme2B OBJECT IDENTIFIER ::= { efmCuPme 5 } efmCuPme2BProfileTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPme2BProfileEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table supports definitions of administrative and operating profiles for 2BASE-TL PMEs. The first 14 entries in this table SHALL always be defined as follows (see 802.3ah Annex 63A): -------+-------+-------+-----+------+-------------+----------- Profile MinRate MaxRate Power Region Constellation Comment index (Kbps) (Kbps) (dBm) -------+-------+-------+-----+------+-------------+----------- 1 5696 5696 13.5 1 32-TCPAM default 2 3072 3072 13.5 1 32-TCPAM 3 2048 2048 13.5 1 16-TCPAM 4 1024 1024 13.5 1 16-TCPAM 5 704 704 13.5 1 16-TCPAM 6 512 512 13.5 1 16-TCPAM 7 5696 5696 14.5 2 32-TCPAM 8 3072 3072 14.5 2 32-TCPAM 9 2048 2048 14.5 2 16-TCPAM 10 1024 1024 13.5 2 16-TCPAM 11 704 704 13.5 2 16-TCPAM 12 512 512 13.5 2 16-TCPAM 13 192 5696 0 1 0 best effort 14 192 5696 0 2 0 best effort -------+-------+-------+-----+------+-------------+----------- These default entries SHALL be created during agent initialization and MUST NOT be deleted. Entries following the first 14 can be dynamically created and deleted to provide custom administrative (configuration) profiles and automatic operating profiles. This table MUST be maintained in a persistent manner." REFERENCE "[802.3ah] Annex 63A, 30.11.2.1.6" ::= { efmCuPme2B 2 } Beili Standards Track [Page 59]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPme2BProfileEntry OBJECT-TYPE SYNTAX EfmCuPme2BProfileEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Each entry corresponds to a single 2BASE-TL PME profile. Each profile contains a set of parameters, used either for configuration or representation of a 2BASE-TL PME. In case a particular profile is referenced via the efmCuPmeAdminProfile object (or efmCuAdminProfile if efmCuPmeAdminProfile is zero), it represents the desired parameters for the 2BaseTL-O PME initialization. If a profile is referenced via an efmCuPmeOperProfile object, it represents the current operating parameters of an operational PME. Profiles may be created/deleted using the row creation/ deletion mechanism via efmCuPme2BProfileRowStatus. If an active entry is referenced, the entry MUST remain 'active' until all references are removed. Default entries MUST NOT be removed." INDEX { efmCuPme2BProfileIndex } ::= { efmCuPme2BProfileTable 1 } EfmCuPme2BProfileEntry ::= SEQUENCE { efmCuPme2BProfileIndex EfmProfileIndex, efmCuPme2BProfileDescr SnmpAdminString, efmCuPme2BRegion INTEGER, efmCuPme2BsMode EfmProfileIndexOrZero, efmCuPme2BMinDataRate Unsigned32, efmCuPme2BMaxDataRate Unsigned32, efmCuPme2BPower Unsigned32, efmCuPme2BConstellation INTEGER, efmCuPme2BProfileRowStatus RowStatus } efmCuPme2BProfileIndex OBJECT-TYPE SYNTAX EfmProfileIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "2BASE-TL PME profile index. This object is the unique index associated with this profile. Entries in this table are referenced via efmCuAdminProfile or efmCuPmeAdminProfile objects." ::= { efmCuPme2BProfileEntry 1 } Beili Standards Track [Page 60]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPme2BProfileDescr OBJECT-TYPE SYNTAX SnmpAdminString MAX-ACCESS read-create STATUS current DESCRIPTION "A textual string containing information about a 2BASE-TL PME profile. The string may include information about the data rate and spectral limitations of this particular profile." ::= { efmCuPme2BProfileEntry 2 } efmCuPme2BRegion OBJECT-TYPE SYNTAX INTEGER { region1(1), region2(2) } MAX-ACCESS read-create STATUS current DESCRIPTION "Regional settings for a 2BASE-TL PME, as specified in the relevant Regional Annex of [G.991.2]. Regional settings specify the Power Spectral Density (PSD) mask and the Power Back-Off (PBO) values, and place limitations on the max allowed data rate, power, and constellation. Possible values for this object are: region1 - Annexes A and F (e.g., North America) region2 - Annexes B and G (e.g., Europe) Annex A/B specify regional settings for data rates 192-2304 Kbps using 16-TCPAM encoding. Annex F/G specify regional settings for rates 2320-3840 Kbps using 16-TCPAM encoding and 768-5696 Kbps using 32-TCPAM encoding. If a Clause 45 MDIO Interface to the PME is present, then this object partially maps to the Region bits in the 2B general parameter register." REFERENCE "[802.3ah] 45.2.1.42; [G.991.2] Annexes A, B, F and G" ::= { efmCuPme2BProfileEntry 3 } efmCuPme2BsMode OBJECT-TYPE SYNTAX EfmProfileIndexOrZero MAX-ACCESS read-create STATUS current DESCRIPTION "Desired custom Spectral Mode for a 2BASE-TL PME. This object Beili Standards Track [Page 61]
RFC 5066 EFMCu Interfaces MIB November 2007 is a pointer to an entry in efmCuPme2BsModeTable and a block of entries in efmCuPme2BRateReachTable, which together define (country-specific) reach-dependent rate limitations in addition to those defined by efmCuPme2BRegion. The value of this object is the index of the referenced spectral mode. The value of zero (default) indicates that no specific spectral mode is applicable. Attempts to set this object to a value that is not the value of the index for an active entry in the corresponding spectral mode table MUST be rejected." REFERENCE "efmCuPme2BsModeTable, efmCuPme2BRateReachTable" DEFVAL { 0 } ::= { efmCuPme2BProfileEntry 4 } efmCuPme2BMinDataRate OBJECT-TYPE SYNTAX Unsigned32(192..5696) UNITS "Kbps" MAX-ACCESS read-create STATUS current DESCRIPTION "Minimum Data Rate for the 2BASE-TL PME. This object can take values of (n x 64)Kbps, where n=3..60 for 16-TCPAM and n=12..89 for 32-TCPAM encoding. The data rate of the 2BASE-TL PME is considered 'fixed' when the value of this object equals that of efmCuPme2BMaxDataRate. If efmCuPme2BMinDataRate is less than efmCuPme2BMaxDataRate in the administrative profile, the data rate is considered 'adaptive', and SHALL be set to the maximum attainable rate not exceeding efmCuPme2BMaxDataRate, under the spectral limitations placed by the efmCuPme2BRegion and efmCuPme2BsMode. Note that the current operational data rate of the PME is represented by the ifSpeed object of IF-MIB. If a Clause 45 MDIO Interface to the PME is present, then this object maps to the Min Data Rate1 bits in the 2B PMD parameters register. This object MUST be maintained in a persistent manner." REFERENCE "[802.3ah] 45.2.1.43" ::= { efmCuPme2BProfileEntry 5 } Beili Standards Track [Page 62]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPme2BMaxDataRate OBJECT-TYPE SYNTAX Unsigned32(192..5696) UNITS "Kbps" MAX-ACCESS read-create STATUS current DESCRIPTION "Maximum Data Rate for the 2BASE-TL PME. This object can take values of (n x 64)Kbps, where n=3..60 for 16-TCPAM and n=12..89 for 32-TCPAM encoding. The data rate of the 2BASE-TL PME is considered 'fixed' when the value of this object equals that of efmCuPme2BMinDataRate. If efmCuPme2BMinDataRate is less than efmCuPme2BMaxDataRate in the administrative profile, the data rate is considered 'adaptive', and SHALL be set to the maximum attainable rate not exceeding efmCuPme2BMaxDataRate, under the spectral limitations placed by the efmCuPme2BRegion and efmCuPme2BsMode. Note that the current operational data rate of the PME is represented by the ifSpeed object of IF-MIB. If a Clause 45 MDIO Interface to the PME is present, then this object maps to the Max Data Rate1 bits in the 2B PMD parameters register. This object MUST be maintained in a persistent manner." REFERENCE "[802.3ah] 45.2.1.43" ::= { efmCuPme2BProfileEntry 6 } efmCuPme2BPower OBJECT-TYPE SYNTAX Unsigned32(0|10..42) UNITS "0.5 dBm" MAX-ACCESS read-create STATUS current DESCRIPTION "Signal Transmit Power. Multiple of 0.5 dBm. The value of 0 in the administrative profile means that the signal transmit power is not fixed and SHALL be set to maximize the attainable rate, under the spectral limitations placed by the efmCuPme2BRegion and efmCuPme2BsMode. If a Clause 45 MDIO Interface to the PME is present, then this object maps to the Power1 bits in the 2B PMD parameters register." REFERENCE "[802.3ah] 45.2.1.43" Beili Standards Track [Page 63]
RFC 5066 EFMCu Interfaces MIB November 2007 ::= { efmCuPme2BProfileEntry 7 } efmCuPme2BConstellation OBJECT-TYPE SYNTAX INTEGER { adaptive(0), tcpam16(1), tcpam32(2) } MAX-ACCESS read-create STATUS current DESCRIPTION "TCPAM Constellation of the 2BASE-TL PME. The possible values are: adaptive(0) - either 16- or 32-TCPAM tcpam16(1) - 16-TCPAM tcpam32(2) - 32-TCPAM The value of adaptive(0) in the administrative profile means that the constellation is not fixed and SHALL be set to maximize the attainable rate, under the spectral limitations placed by the efmCuPme2BRegion and efmCuPme2BsMode. If a Clause 45 MDIO Interface to the PME is present, then this object maps to the Constellation1 bits in the 2B general parameter register." REFERENCE "[802.3ah] 45.2.1.43" ::= { efmCuPme2BProfileEntry 8 } efmCuPme2BProfileRowStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object controls the creation, modification, or deletion of the associated entry in the efmCuPme2BProfileTable per the semantics of RowStatus. If an 'active' entry is referenced via efmCuAdminProfile or efmCuPmeAdminProfile instance(s), the entry MUST remain 'active'. An 'active' entry SHALL NOT be modified. In order to modify an existing entry, it MUST be taken out of service (by setting this object to 'notInService'), modified, and set 'active' again." ::= { efmCuPme2BProfileEntry 9 } Beili Standards Track [Page 64]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPme2BsModeTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPme2BsModeEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table, together with efmCu2BReachRateTable, supports definition of administrative custom spectral modes for 2BASE-TL PMEs, describing spectral limitations in addition to those specified by efmCuPme2BRegion. In some countries, spectral regulations (e.g., UK ANFP) limit the length of the loops for certain data rates. This table allows these country-specific limitations to be specified. Entries in this table referenced by the efmCuPme2BsMode MUST NOT be deleted until all the active references are removed. This table MUST be maintained in a persistent manner." REFERENCE "efmCu2BReachRateTable" ::= { efmCuPme2B 3 } efmCuPme2BsModeEntry OBJECT-TYPE SYNTAX EfmCuPme2BsModeEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Each entry specifies a spectral mode description and its index, which is used to reference corresponding entries in the efmCu2BReachRateTable. Entries may be created/deleted using the row creation/ deletion mechanism via efmCuPme2BsModeRowStatus." INDEX { efmCuPme2BsModeIndex } ::= { efmCuPme2BsModeTable 1 } EfmCuPme2BsModeEntry ::= SEQUENCE { efmCuPme2BsModeIndex EfmProfileIndex, efmCuPme2BsModeDescr SnmpAdminString, efmCuPme2BsModeRowStatus RowStatus } efmCuPme2BsModeIndex OBJECT-TYPE SYNTAX EfmProfileIndex MAX-ACCESS not-accessible STATUS current Beili Standards Track [Page 65]
RFC 5066 EFMCu Interfaces MIB November 2007 DESCRIPTION "2BASE-TL PME Spectral Mode index. This object is the unique index associated with this spectral mode. Entries in this table are referenced via the efmCuPme2BsMode object." ::= { efmCuPme2BsModeEntry 1 } efmCuPme2BsModeDescr OBJECT-TYPE SYNTAX SnmpAdminString MAX-ACCESS read-create STATUS current DESCRIPTION "A textual string containing information about a 2BASE-TL PME spectral mode. The string may include information about corresponding (country-specific) spectral regulations and rate/reach limitations of this particular spectral mode." ::= { efmCuPme2BsModeEntry 2 } efmCuPme2BsModeRowStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object controls creation, modification, or deletion of the associated entry in efmCuPme2BsModeTable per the semantics of RowStatus. If an 'active' entry is referenced via efmCuPme2BsMode instance(s), the entry MUST remain 'active'. An 'active' entry SHALL NOT be modified. In order to modify an existing entry, it MUST be taken out of service (by setting this object to 'notInService'), modified, and set 'active' again." ::= { efmCuPme2BsModeEntry 3 } efmCuPme2BReachRateTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPme2BReachRateEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table supports the definition of administrative custom spectral modes for 2BASE-TL PMEs, providing spectral limitations in addition to those specified by efmCuPme2BRegion. Beili Standards Track [Page 66]
RFC 5066 EFMCu Interfaces MIB November 2007 The spectral regulations in some countries (e.g., UK ANFP) limit the length of the loops for certain data rates. This table allows these country-specific limitations to be specified. Below is an example of this table for [ANFP]: ----------+-------+------- Equivalent MaxRate MaxRate Length PAM16 PAM32 (m) (Kbps) (Kbps) ----------+-------+------- 975 2304 5696 1125 2304 5504 1275 2304 5120 1350 2304 4864 1425 2304 4544 1500 2304 4288 1575 2304 3968 1650 2304 3776 1725 2304 3520 1800 2304 3264 1875 2304 3072 1950 2048 2688 2100 1792 2368 2250 1536 0 2400 1408 0 2550 1280 0 2775 1152 0 2925 1152 0 3150 1088 0 3375 1024 0 ----------+-------+------- Entries in this table referenced by an efmCuPme2BsMode instance MUST NOT be deleted. This table MUST be maintained in a persistent manner." REFERENCE "[ANFP]" ::= { efmCuPme2B 4 } efmCuPme2BReachRateEntry OBJECT-TYPE SYNTAX EfmCuPme2BReachRateEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Each entry specifies maximum 2BASE-TL PME data rates allowed for a certain equivalent loop length, when using Beili Standards Track [Page 67]
RFC 5066 EFMCu Interfaces MIB November 2007 16-TCPAM or 32-TCPAM encoding. When a 2BASE-TL PME is initialized, its data rate MUST NOT exceed one of the following limitations: - the value of efmCuPme2BMaxDataRate - maximum data rate allowed by efmCuPme2BRegion and efmCuPme2BPower - maximum data rate for a given encoding specified in the efmCuPme2BsModeEntry, corresponding to the equivalent loop length, estimated by the PME It is RECOMMENDED that the efmCuPme2BEquivalentLength values are assigned in increasing order, starting from the minimum value. Entries may be created/deleted using the row creation/ deletion mechanism via efmCuPme2ReachRateRowStatus." INDEX { efmCuPme2BsModeIndex, efmCuPme2BReachRateIndex } ::= { efmCuPme2BReachRateTable 1 } EfmCuPme2BReachRateEntry ::= SEQUENCE { efmCuPme2BReachRateIndex EfmProfileIndex, efmCuPme2BEquivalentLength Unsigned32, efmCuPme2BMaxDataRatePam16 Unsigned32, efmCuPme2BMaxDataRatePam32 Unsigned32, efmCuPme2BReachRateRowStatus RowStatus } efmCuPme2BReachRateIndex OBJECT-TYPE SYNTAX EfmProfileIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "2BASE-TL custom spectral mode Reach-Rate table index. This object is the unique index associated with each entry." ::= { efmCuPme2BReachRateEntry 1 } efmCuPme2BEquivalentLength OBJECT-TYPE SYNTAX Unsigned32(0..8192) UNITS "m" MAX-ACCESS read-create STATUS current DESCRIPTION "Maximum allowed equivalent loop's physical length in meters for the specified data rates. An equivalent loop is a hypothetical 26AWG (0.4mm) loop with a perfect square root attenuation characteristic, without any Beili Standards Track [Page 68]
RFC 5066 EFMCu Interfaces MIB November 2007 bridged taps." ::= { efmCuPme2BReachRateEntry 2 } efmCuPme2BMaxDataRatePam16 OBJECT-TYPE SYNTAX Unsigned32(0|192..5696) UNITS "Kbps" MAX-ACCESS read-create STATUS current DESCRIPTION "Maximum data rate for a 2BASE-TL PME at the specified equivalent loop's length using TC-PAM16 encoding. The value of zero means that TC-PAM16 encoding should not be used at this distance." ::= { efmCuPme2BReachRateEntry 3 } efmCuPme2BMaxDataRatePam32 OBJECT-TYPE SYNTAX Unsigned32(0|192..5696) UNITS "Kbps" MAX-ACCESS read-create STATUS current DESCRIPTION "Maximum data rate for a 2BASE-TL PME at the specified equivalent loop's length using TC-PAM32 encoding. The value of zero means that TC-PAM32 encoding should not be used at this distance." ::= { efmCuPme2BReachRateEntry 4 } efmCuPme2BReachRateRowStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object controls the creation, modification, or deletion of the associated entry in the efmCuPme2BReachRateTable per the semantics of RowStatus. If an 'active' entry is referenced via efmCuPme2BsMode instance(s), the entry MUST remain 'active'. An 'active' entry SHALL NOT be modified. In order to modify an existing entry, it MUST be taken out of service (by setting this object to 'notInService'), modified, and set 'active' again." ::= { efmCuPme2BReachRateEntry 5 } -- 10PASS-TS specific PME group Beili Standards Track [Page 69]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPme10P OBJECT IDENTIFIER ::= { efmCuPme 6 } efmCuPme10PProfileTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPme10PProfileEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table supports definitions of configuration profiles for 10PASS-TS PMEs. The first 22 entries in this table SHALL always be defined as follows (see 802.3ah Annex 62B.3, table 62B-1): -------+--------+----+---------+-----+-----+--------------- Profile Bandplan UPBO BandNotch DRate URate Comment Index PSDMask# p# p# p# p# -------+--------+----+---------+-----+-----+--------------- 1 1 3 2,6,10,11 20 20 default profile 2 13 5 0 20 20 3 1 1 0 20 20 4 16 0 0 100 100 5 16 0 0 70 50 6 6 0 0 50 10 7 17 0 0 30 30 8 8 0 0 30 5 9 4 0 0 25 25 10 4 0 0 15 15 11 23 0 0 10 10 12 23 0 0 5 5 13 16 0 2,5,9,11 100 100 14 16 0 2,5,9,11 70 50 15 6 0 2,6,10,11 50 10 16 17 0 2,5,9,11 30 30 17 8 0 2,6,10,11 30 5 18 4 0 2,6,10,11 25 25 19 4 0 2,6,10,11 15 15 20 23 0 2,5,9,11 10 10 21 23 0 2,5,9,11 5 5 22 30 0 0 200 50 -------+--------+----+---------+-----+-----+--------------- These default entries SHALL be created during agent initialization and MUST NOT be deleted. Entries following the first 22 can be dynamically created and deleted to provide custom administrative (configuration) profiles and automatic operating profiles. This table MUST be maintained in a persistent manner." REFERENCE Beili Standards Track [Page 70]
RFC 5066 EFMCu Interfaces MIB November 2007 "[802.3ah] Annex 62B.3, 30.11.2.1.6" ::= { efmCuPme10P 1 } efmCuPme10PProfileEntry OBJECT-TYPE SYNTAX EfmCuPme10PProfileEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Each entry corresponds to a single 10PASS-TS PME profile. Each profile contains a set of parameters, used either for configuration or representation of a 10PASS-TS PME. In case a particular profile is referenced via the efmCuPmeAdminProfile object (or efmCuAdminProfile if efmCuPmeAdminProfile is zero), it represents the desired parameters for the 10PassTS-O PME initialization. If a profile is referenced via an efmCuPmeOperProfile object, it represents the current operating parameters of the PME. Profiles may be created/deleted using the row creation/ deletion mechanism via efmCuPme10PProfileRowStatus. If an 'active' entry is referenced, the entry MUST remain 'active' until all references are removed. Default entries MUST NOT be removed." INDEX { efmCuPme10PProfileIndex } ::= { efmCuPme10PProfileTable 1 } EfmCuPme10PProfileEntry ::= SEQUENCE { efmCuPme10PProfileIndex EfmProfileIndex, efmCuPme10PProfileDescr SnmpAdminString, efmCuPme10PBandplanPSDMskProfile INTEGER, efmCuPme10PUPBOReferenceProfile INTEGER, efmCuPme10PBandNotchProfiles BITS, efmCuPme10PPayloadDRateProfile INTEGER, efmCuPme10PPayloadURateProfile INTEGER, efmCuPme10PProfileRowStatus RowStatus } efmCuPme10PProfileIndex OBJECT-TYPE SYNTAX EfmProfileIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "10PASS-TS PME profile index. This object is the unique index associated with this profile. Entries in this table are referenced via efmCuAdminProfile or efmCuPmeAdminProfile." Beili Standards Track [Page 71]
RFC 5066 EFMCu Interfaces MIB November 2007 ::= { efmCuPme10PProfileEntry 1 } efmCuPme10PProfileDescr OBJECT-TYPE SYNTAX SnmpAdminString MAX-ACCESS read-create STATUS current DESCRIPTION "A textual string containing information about a 10PASS-TS PME profile. The string may include information about data rate and spectral limitations of this particular profile." ::= { efmCuPme10PProfileEntry 2 } efmCuPme10PBandplanPSDMskProfile OBJECT-TYPE SYNTAX INTEGER { profile1(1), profile2(2), profile3(3), profile4(4), profile5(5), profile6(6), profile7(7), profile8(8), profile9(9), profile10(10), profile11(11), profile12(12), profile13(13), profile14(14), profile15(15), profile16(16), profile17(17), profile18(18), profile19(19), profile20(20), profile21(21), profile22(22), profile23(23), profile24(24), profile25(25), profile26(26), profile27(27), profile28(28), profile29(29), profile30(30) } MAX-ACCESS read-create STATUS current DESCRIPTION Beili Standards Track [Page 72]
RFC 5066 EFMCu Interfaces MIB November 2007 "The 10PASS-TS PME Bandplan and PSD Mask Profile, as specified in 802.3ah Annex 62A, table 62A-1. Possible values are: --------------+------------------------+------------+-------- Profile Name PSD Mask Bands G.993.1 0/1/2/3/4/5 Bandplan --------------+------------------------+------------+-------- profile1(1) T1.424 FTTCab.M1 x/D/U/D/U A profile2(2) T1.424 FTTEx.M1 x/D/U/D/U A profile3(3) T1.424 FTTCab.M2 x/D/U/D/U A profile4(4) T1.424 FTTEx.M2 x/D/U/D/U A profile5(5) T1.424 FTTCab.M1 D/D/U/D/U A profile6(6) T1.424 FTTEx.M1 D/D/U/D/U A profile7(7) T1.424 FTTCab.M2 D/D/U/D/U A profile8(8) T1.424 FTTEx.M2 D/D/U/D/U A profile9(9) T1.424 FTTCab.M1 U/D/U/D/x A profile10(10) T1.424 FTTEx.M1 U/D/U/D/x A profile11(11) T1.424 FTTCab.M2 U/D/U/D/x A profile12(12) T1.424 FTTEx.M2 U/D/U/D/x A profile13(13) TS 101 270-1 Pcab.M1.A x/D/U/D/U B profile14(14) TS 101 270-1 Pcab.M1.B x/D/U/D/U B profile15(15) TS 101 270-1 Pex.P1.M1 x/D/U/D/U B profile16(16) TS 101 270-1 Pex.P2.M1 x/D/U/D/U B profile17(17) TS 101 270-1 Pcab.M2 x/D/U/D/U B profile18(18) TS 101 270-1 Pex.P1.M2 x/D/U/D/U B profile19(19) TS 101 270-1 Pex.P2.M2 x/D/U/D/U B profile20(20) TS 101 270-1 Pcab.M1.A U/D/U/D/x B profile21(21) TS 101 270-1 Pcab.M1.B U/D/U/D/x B profile22(22) TS 101 270-1 Pex.P1.M1 U/D/U/D/x B profile23(23) TS 101 270-1 Pex.P2.M1 U/D/U/D/x B profile24(24) TS 101 270-1 Pcab.M2 U/D/U/D/x B profile25(25) TS 101 270-1 Pex.P1.M2 U/D/U/D/x B profile26(26) TS 101 270-1 Pex.P2.M2 U/D/U/D/x B profile27(27) G.993.1 F.1.2.1 x/D/U/D/U Annex F profile28(28) G.993.1 F.1.2.2 x/D/U/D/U Annex F profile29(29) G.993.1 F.1.2.3 x/D/U/D/U Annex F profile30(30) T1.424 FTTCab.M1 (ext.) x/D/U/D/U/D Annex A --------------+------------------------+------------+-------- " REFERENCE "[802.3ah] Annex 62A" ::= { efmCuPme10PProfileEntry 3 } efmCuPme10PUPBOReferenceProfile OBJECT-TYPE SYNTAX INTEGER { profile0(0), profile1(1), profile2(2), profile3(3), Beili Standards Track [Page 73]
RFC 5066 EFMCu Interfaces MIB November 2007 profile4(4), profile5(5), profile6(6), profile7(7), profile8(8), profile9(9) } MAX-ACCESS read-create STATUS current DESCRIPTION "The 10PASS-TS PME Upstream Power Back-Off (UPBO) Reference PSD Profile, as specified in 802.3 Annex 62A, table 62A-3. Possible values are: ------------+----------------------------- Profile Name Reference PSD ------------+----------------------------- profile0(0) no profile profile1(1) T1.424 Noise A M1 profile2(2) T1.424 Noise A M2 profile3(3) T1.424 Noise F M1 profile4(4) T1.424 Noise F M2 profile5(5) TS 101 270-1 Noise A&B profile6(6) TS 101 270-1 Noise C profile7(7) TS 101 270-1 Noise D profile8(8) TS 101 270-1 Noise E profile9(9) TS 101 270-1 Noise F ------------+----------------------------- " REFERENCE "[802.3ah] Annex 62A.3.5" ::= { efmCuPme10PProfileEntry 4 } efmCuPme10PBandNotchProfiles OBJECT-TYPE SYNTAX BITS { profile0(0), profile1(1), profile2(2), profile3(3), profile4(4), profile5(5), profile6(6), profile7(7), profile8(8), profile9(9), profile10(10), profile11(11) } MAX-ACCESS read-create Beili Standards Track [Page 74]
RFC 5066 EFMCu Interfaces MIB November 2007 STATUS current DESCRIPTION "The 10PASS-TS PME Egress Control Band Notch Profile bitmap, as specified in 802.3 Annex 62A, table 62A-4. Possible values are: --------------+--------+------+------------+------+------ Profile Name G.991.3 T1.424 TS 101 270-1 StartF EndF table table table (MHz) (MHz) --------------+--------+------+------------+------+------ profile0(0) no profile profile1(1) F-5 #01 - - 1.810 1.825 profile2(2) 6-2 15-1 17 1.810 2.000 profile3(3) F-5 #02 - - 1.907 1.912 profile4(4) F-5 #03 - - 3.500 3.575 profile5(5) 6-2 - 17 3.500 3.800 profile6(6) - 15-1 - 3.500 4.000 profile7(7) F-5 #04 - - 3.747 3.754 profile8(8) F-5 #05 - - 3.791 3.805 profile9(9) 6-2 - 17 7.000 7.100 profile10(10) F-5 #06 15-1 - 7.000 7.300 profile11(11) 6-2 15-1 1 10.100 10.150 --------------+--------+------+------------+------+------ Any combination of profiles can be specified by ORing individual profiles, for example, a value of 0x2230 selects profiles 2, 6, 10, and 11." REFERENCE "[802.3ah] Annex 62A.3.5" ::= { efmCuPme10PProfileEntry 5 } efmCuPme10PPayloadDRateProfile OBJECT-TYPE SYNTAX INTEGER { profile5(5), profile10(10), profile15(15), profile20(20), profile25(25), profile30(30), profile50(50), profile70(70), profile100(100), profile140(140), profile200(200) } MAX-ACCESS read-create STATUS current DESCRIPTION "The 10PASS-TS PME Downstream Payload Rate Profile, as Beili Standards Track [Page 75]
RFC 5066 EFMCu Interfaces MIB November 2007 specified in 802.3 Annex 62A. Possible values are: profile5(5) - 2.5 Mbps profile10(10) - 5 Mbps profile15(15) - 7.5 Mbps profile20(20) - 10 Mbps profile25(25) - 12.5 Mbps profile30(30) - 15 Mbps profile50(50) - 25 Mbps profile70(70) - 35 Mbps profile100(100) - 50 Mbps profile140(140) - 70 Mbps profile200(200) - 100 Mbps Each value represents a target for the PME's Downstream Payload Bitrate as seen at the MII. If the payload rate of the selected profile cannot be achieved based on the loop environment, bandplan, and PSD mask, the PME initialization SHALL fail." REFERENCE "[802.3ah] Annex 62A.3.6" ::= { efmCuPme10PProfileEntry 6 } efmCuPme10PPayloadURateProfile OBJECT-TYPE SYNTAX INTEGER { profile5(5), profile10(10), profile15(15), profile20(20), profile25(25), profile30(30), profile50(50), profile70(70), profile100(100) } MAX-ACCESS read-create STATUS current DESCRIPTION "The 10PASS-TS PME Upstream Payload Rate Profile, as specified in 802.3 Annex 62A. Possible values are: profile5(5) - 2.5 Mbps profile10(10) - 5 Mbps profile15(15) - 7.5 Mbps profile20(20) - 10 Mbps profile25(25) - 12.5 Mbps profile30(30) - 15 Mbps profile50(50) - 25 Mbps profile70(70) - 35 Mbps profile100(100) - 50 Mbps Beili Standards Track [Page 76]
RFC 5066 EFMCu Interfaces MIB November 2007 Each value represents a target for the PME's Upstream Payload Bitrate as seen at the MII. If the payload rate of the selected profile cannot be achieved based on the loop environment, bandplan, and PSD mask, the PME initialization SHALL fail." REFERENCE "[802.3ah] Annex 62A.3.6" ::= { efmCuPme10PProfileEntry 7 } efmCuPme10PProfileRowStatus OBJECT-TYPE SYNTAX RowStatus MAX-ACCESS read-create STATUS current DESCRIPTION "This object controls creation, modification, or deletion of the associated entry in efmCuPme10PProfileTable per the semantics of RowStatus. If an active entry is referenced via efmCuAdminProfile or efmCuPmeAdminProfile, the entry MUST remain 'active' until all references are removed. An 'active' entry SHALL NOT be modified. In order to modify an existing entry, it MUST be taken out of service (by setting this object to 'notInService'), modified, and set 'active' again." ::= { efmCuPme10PProfileEntry 8 } efmCuPme10PStatusTable OBJECT-TYPE SYNTAX SEQUENCE OF EfmCuPme10PStatusEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table provides status information of EFMCu 10PASS-TS PMEs (modems). This table contains live data from the equipment. As such, it is NOT persistent." ::= { efmCuPme10P 2 } efmCuPme10PStatusEntry OBJECT-TYPE SYNTAX EfmCuPme10PStatusEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "An entry in the EFMCu 10PASS-TS PME Status table." INDEX { ifIndex } Beili Standards Track [Page 77]
RFC 5066 EFMCu Interfaces MIB November 2007 ::= { efmCuPme10PStatusTable 1 } EfmCuPme10PStatusEntry ::= SEQUENCE { efmCuPme10PFECCorrectedBlocks Counter32, efmCuPme10PFECUncorrectedBlocks Counter32 } efmCuPme10PFECCorrectedBlocks OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of received and corrected Forward Error Correction (FEC) codewords in this 10PASS-TS PME. This object maps to the aPMEFECCorrectedBlocks attribute in Clause 30. If a Clause 45 MDIO Interface to the PMA/PMD is present, then this object maps to the 10P FEC correctable errors register. 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, defined in IF-MIB." REFERENCE "[802.3ah] 45.2.1.22, 30.11.2.1.8" ::= { efmCuPme10PStatusEntry 1 } efmCuPme10PFECUncorrectedBlocks OBJECT-TYPE SYNTAX Counter32 MAX-ACCESS read-only STATUS current DESCRIPTION "The number of received uncorrectable FEC codewords in this 10PASS-TS PME. This object maps to the aPMEFECUncorrectableBlocks attribute in Clause 30. If a Clause 45 MDIO Interface to the PMA/PMD is present, then this object maps to the 10P FEC uncorrectable errors register. Discontinuities in the value of this counter can occur at re-initialization of the management system, and at other times Beili Standards Track [Page 78]
RFC 5066 EFMCu Interfaces MIB November 2007 as indicated by the value of ifCounterDiscontinuityTime, defined in IF-MIB." REFERENCE "[802.3ah] 45.2.1.23, 30.11.2.1.9" ::= { efmCuPme10PStatusEntry 2 } -- -- Conformance Statements -- efmCuGroups OBJECT IDENTIFIER ::= { efmCuConformance 1 } efmCuCompliances OBJECT IDENTIFIER ::= { efmCuConformance 2 } -- Object Groups efmCuBasicGroup OBJECT-GROUP OBJECTS { efmCuPAFSupported, efmCuAdminProfile, efmCuTargetDataRate, efmCuTargetSnrMgn, efmCuAdaptiveSpectra, efmCuPortSide, efmCuFltStatus } STATUS current DESCRIPTION "A collection of objects representing management information common for all types of EFMCu ports." ::= { efmCuGroups 1 } efmCuPAFGroup OBJECT-GROUP OBJECTS { efmCuPeerPAFSupported, efmCuPAFCapacity, efmCuPeerPAFCapacity, efmCuPAFAdminState, efmCuPAFDiscoveryCode, efmCuPAFRemoteDiscoveryCode, efmCuNumPMEs } STATUS current DESCRIPTION "A collection of objects supporting OPTIONAL PME Aggregation Function (PAF) and PAF discovery in EFMCu ports." ::= { efmCuGroups 2 } Beili Standards Track [Page 79]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPAFErrorsGroup OBJECT-GROUP OBJECTS { efmCuPAFInErrors, efmCuPAFInSmallFragments, efmCuPAFInLargeFragments, efmCuPAFInBadFragments, efmCuPAFInLostFragments, efmCuPAFInLostStarts, efmCuPAFInLostEnds, efmCuPAFInOverflows } STATUS current DESCRIPTION "A collection of objects supporting OPTIONAL error counters of PAF on EFMCu ports." ::= { efmCuGroups 3 } efmCuPmeGroup OBJECT-GROUP OBJECTS { efmCuPmeAdminProfile, efmCuPmeOperStatus, efmCuPmeFltStatus, efmCuPmeSubTypesSupported, efmCuPmeAdminSubType, efmCuPmeOperSubType, efmCuPAFRemoteDiscoveryCode, efmCuPmeOperProfile, efmCuPmeSnrMgn, efmCuPmePeerSnrMgn, efmCuPmeLineAtn, efmCuPmePeerLineAtn, efmCuPmeEquivalentLength, efmCuPmeTCCodingErrors, efmCuPmeTCCrcErrors, efmCuPmeThreshLineAtn, efmCuPmeThreshSnrMgn } STATUS current DESCRIPTION "A collection of objects providing information about a 2BASE-TL/10PASS-TS PME." ::= { efmCuGroups 4 } efmCuAlarmConfGroup OBJECT-GROUP OBJECTS { efmCuThreshLowRate, efmCuLowRateCrossingEnable, efmCuPmeThreshLineAtn, Beili Standards Track [Page 80]
RFC 5066 EFMCu Interfaces MIB November 2007 efmCuPmeLineAtnCrossingEnable, efmCuPmeThreshSnrMgn, efmCuPmeSnrMgnCrossingEnable, efmCuPmeDeviceFaultEnable, efmCuPmeConfigInitFailEnable, efmCuPmeProtocolInitFailEnable } STATUS current DESCRIPTION "A collection of objects supporting configuration of alarm thresholds and notifications in EFMCu ports." ::= { efmCuGroups 5 } efmCuNotificationGroup NOTIFICATION-GROUP NOTIFICATIONS { efmCuLowRateCrossing, efmCuPmeLineAtnCrossing, efmCuPmeSnrMgnCrossing, efmCuPmeDeviceFault, efmCuPmeConfigInitFailure, efmCuPmeProtocolInitFailure } STATUS current DESCRIPTION "This group supports notifications of significant conditions associated with EFMCu ports." ::= { efmCuGroups 6 } efmCuPme2BProfileGroup OBJECT-GROUP OBJECTS { efmCuPme2BProfileDescr, efmCuPme2BRegion, efmCuPme2BsMode, efmCuPme2BMinDataRate, efmCuPme2BMaxDataRate, efmCuPme2BPower, efmCuPme2BConstellation, efmCuPme2BProfileRowStatus, efmCuPme2BsModeDescr, efmCuPme2BsModeRowStatus, efmCuPme2BEquivalentLength, efmCuPme2BMaxDataRatePam16, efmCuPme2BMaxDataRatePam32, efmCuPme2BReachRateRowStatus } STATUS current DESCRIPTION "A collection of objects that constitute a configuration Beili Standards Track [Page 81]
RFC 5066 EFMCu Interfaces MIB November 2007 profile for configuration of 2BASE-TL ports." ::= { efmCuGroups 7} efmCuPme10PProfileGroup OBJECT-GROUP OBJECTS { efmCuPme10PProfileDescr, efmCuPme10PBandplanPSDMskProfile, efmCuPme10PUPBOReferenceProfile, efmCuPme10PBandNotchProfiles, efmCuPme10PPayloadDRateProfile, efmCuPme10PPayloadURateProfile, efmCuPme10PProfileRowStatus } STATUS current DESCRIPTION "A collection of objects that constitute a configuration profile for configuration of 10PASS-TS ports." ::= { efmCuGroups 8 } efmCuPme10PStatusGroup OBJECT-GROUP OBJECTS { efmCuPme10PFECCorrectedBlocks, efmCuPme10PFECUncorrectedBlocks } STATUS current DESCRIPTION "A collection of objects providing status information specific to 10PASS-TS PMEs." ::= { efmCuGroups 9 } -- Compliance Statements efmCuCompliance MODULE-COMPLIANCE STATUS current DESCRIPTION "The compliance statement for 2BASE-TL/10PASS-TS interfaces. Compliance with the following external compliance statements is REQUIRED: MIB Module Compliance Statement ---------- -------------------- IF-MIB ifCompliance3 EtherLike-MIB dot3Compliance2 MAU-MIB mauModIfCompl3 Compliance with the following external compliance statements is OPTIONAL for implementations supporting PME Aggregation Function (PAF) with flexible cross-connect between the PCS Beili Standards Track [Page 82]
RFC 5066 EFMCu Interfaces MIB November 2007 and PME ports: MIB Module Compliance Statement ---------- -------------------- IF-INVERTED-STACK-MIB ifInvCompliance IF-CAP-STACK-MIB ifCapStackCompliance" MODULE -- this module MANDATORY-GROUPS { efmCuBasicGroup, efmCuPmeGroup, efmCuAlarmConfGroup, efmCuNotificationGroup } GROUP efmCuPme2BProfileGroup DESCRIPTION "Support for this group is only required for implementations supporting 2BASE-TL PHY." GROUP efmCuPme10PProfileGroup DESCRIPTION "Support for this group is only required for implementations supporting 10PASS-TS PHY." GROUP efmCuPAFGroup DESCRIPTION "Support for this group is only required for implementations supporting PME Aggregation Function (PAF)." GROUP efmCuPAFErrorsGroup DESCRIPTION "Support for this group is OPTIONAL for implementations supporting PME Aggregation Function (PAF)." GROUP efmCuPme10PStatusGroup DESCRIPTION "Support for this group is OPTIONAL for implementations supporting 10PASS-TS PHY." OBJECT efmCuPmeSubTypesSupported SYNTAX BITS { ieee2BaseTLO(0), ieee2BaseTLR(1), ieee10PassTSO(2), ieee10PassTSR(3) } DESCRIPTION Beili Standards Track [Page 83]
RFC 5066 EFMCu Interfaces MIB November 2007 "Support for all subtypes is not required. However, at least one value SHALL be supported." OBJECT efmCuPmeAdminSubType MIN-ACCESS read-only DESCRIPTION "Write access is not required (needed only for PMEs supporting more than a single subtype, e.g., ieee2BaseTLO and ieee2BaseTLR or ieee10PassTSO and ieee10PassTSR)." OBJECT efmCuTargetSnrMgn MIN-ACCESS read-only DESCRIPTION "Write access is OPTIONAL. For PHYs without write access, the target SNR margin SHALL be fixed at 5dB for 2BASE-TL and 6dB for 10PASS-TS." OBJECT efmCuAdaptiveSpectra MIN-ACCESS read-only DESCRIPTION "Write access is OPTIONAL. For PHYs without write access, the default value SHOULD be false." ::= { efmCuCompliances 1 } END 7. Security Considerations There is a number of managed objects defined in the EFM-CU-MIB module that have a MAX-ACCESS clause of read-write or read-create. Most objects are writeable only when the link is Down. Writing to these objects can have potentially disruptive effects on network operation, for example: o Changing of efmCuPmeAdminSubType may lead to a potential locking of the link, as peer PMEs of the same subtype cannot exchange handshake messages. o Changing of efmCuPAFAdminState to enabled may lead to a potential locking of the link, if the peer PHY does not support PAF. o Changing of efmCuPAFDiscoveryCode, before the discovery operation, may lead to a wrongful discovery, for example, when two -O ports are connected to the same multi-PME -R port and both -O ports have the same Discovery register value. Beili Standards Track [Page 84]
RFC 5066 EFMCu Interfaces MIB November 2007 o Changing PCS or PME configuration parameters (e.g., profile of a PCS or PME via efmCuAdminProfile or efmCuPmeAdminProfile) may lead to anything from link quality and rate degradation to a complete link initialization failure, as ability of an EFMCu port to support a particular configuration depends on the copper environment. o Activation of a PME can cause a severe degradation of service for another EFMCu PHY, whose PME(s) may be affected by the cross-talk from the newly activated PME. o Removal of a PME from an operationally 'up' EFMCu port, aggregating several PMEs, may cause port's rate degradation. The user of the EFM-CU-MIB module must therefore be aware that support for SET operations in a non-secure environment without proper protection can have a negative effect on network operations. The readable objects in the EFM-CU-MIB module (i.e., those with MAX- ACCESS other than not-accessible) may be considered sensitive in some environments since, collectively, they provide information about the performance of network interfaces and can reveal some aspects of their configuration. In particular, since EFMCu can be carried over Unshielded Twisted Pair (UTP) voice-grade copper in a bundle with other pairs belonging to another operator/customer, it is theoretically possible to eavesdrop to an EFMCu transmission simply by "listening" to a cross-talk from the EFMCu pairs, especially if the parameters of the EFMCu link in question are known. In such environments, it is important to control also GET and NOTIFY access to these objects and possibly even to encrypt their values when sending them over the network via SNMP. SNMP versions prior to SNMPv3 did not include adequate security. Even if the network itself is secure (for example by using IPsec), even then, there is no control as to who on the secure network is allowed to access and GET/SET (read/change/create/delete) the objects in these MIB modules. It is RECOMMENDED that implementers consider the security features as provided by the SNMPv3 framework (see [RFC3410], section 8), including full support for the SNMPv3 cryptographic mechanisms (for authentication and privacy). Further, deployment of SNMP versions prior to SNMPv3 is NOT RECOMMENDED. Instead, it is RECOMMENDED to deploy SNMPv3 and to enable cryptographic security. It is then a customer/operator responsibility to ensure that the SNMP entity giving access to an Beili Standards Track [Page 85]
RFC 5066 EFMCu Interfaces MIB November 2007 instance of these MIB modules is properly configured to give access to the objects only to those principals (users) that have legitimate rights to indeed GET or SET (change/create/delete) them. 8. IANA Considerations Object identifiers for the efmCuMIB MODULE-IDENTITY and ifCapStackMIB MODULE-IDENTITY have been allocated by IANA in the MIB-2 sub-tree. 9. Acknowledgments This document was produced by the [HUBMIB] working group, whose efforts were greatly advanced by the contributions of the following people (in alphabetical order): Udi Ashkenazi (Actelis) Mike Heard Alfred Hoenes (TR-Sys) Marina Popilov (Actelis) Mathias Riess (Infineon) Dan Romascanu (Avaya) Matt Squire (Hatteras) Bert Wijnen (Alcatel) 10. References 10.1. Normative References [802.3] IEEE, "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", IEEE Std 802.3-2005, December 2005. Beili Standards Track [Page 86]
RFC 5066 EFMCu Interfaces MIB November 2007 [802.3ah] IEEE, "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 - Amendment: Media Access Control Parameters, Physical Layers and Management Parameters for Subscriber Access Networks", IEEE Std 802.3ah-2004, September 2004. [G.991.2] ITU-T, "Single-pair High-speed Digital Subscriber Line (SHDSL) transceivers", ITU-T Recommendation G.991.2, December 2003, <http://www.itu.int/rec/T-REC-G.991.2/en>. [G.993.1] ITU-T, "Very High speed Digital Subscriber Line transceivers", ITU-T Recommendation G.993.1, June 2004, <http://www.itu.int/rec/T-REC-G.993.1/en>. [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC2578] McCloghrie, K., Ed., Perkins, D., Ed., and J. Schoenwaelder, Ed., "Structure of Management Information Version 2 (SMIv2)", STD 58, RFC 2578, April 1999. [RFC2579] McCloghrie, K., Ed., Perkins, D., Ed., and J. Schoenwaelder, Ed., "Textual Conventions for SMIv2", STD 58, RFC 2579, April 1999. [RFC2580] McCloghrie, K., Perkins, D., and J. Schoenwaelder, "Conformance Statements for SMIv2", STD 58, RFC 2580, April 1999. [RFC2863] McCloghrie, K. and F. Kastenholz, "The Interfaces Group MIB", RFC 2863, June 2000. [RFC2864] McCloghrie, K. and G. Hanson, "The Inverted Stack Table Extension to the Interfaces Group MIB", RFC 2864, June 2000. [RFC3411] Harrington, D., Presuhn, R., and B. Wijnen, "An Architecture for Describing Simple Network Management Protocol (SNMP) Management Frameworks", STD 62, RFC 3411, December 2002. Beili Standards Track [Page 87]
RFC 5066 EFMCu Interfaces MIB November 2007 [RFC3635] Flick, J., "Definitions of Managed Objects for the Ethernet-like Interface Types", RFC 3635, September 2003. [RFC4836] Beili, E., "Definitions of Managed Objects for IEEE 802.3 Medium Attachment Units (MAUs)", RFC 4836, April 2007. [T1.424] ANSI, "Interface Between Networks and Customer Installation Very-high-bit-rate Digital Subscriber Lines (VDSL) Metallic Interface (DMT Based)", American National Standard T1.424-2004, June 2004. [TS 101 270-1] ETSI, "Transmission and Multiplexing (TM); Access transmission systems on metallic access cables; Very high speed Digital Subscriber Line (VDSL); Part 1: Functional requirements", Technical Specification TS 101 270-1, October 2005. 10.2. Informative References [ANFP] Network Interoperability Consultative Committee (NICC), "Specification of the Access Network Frequency Plan (ANFP) applicable to transmission systems used on the BT Access Network", NICC Document ND1602:2005/08, August 2005. [HUBMIB] IETF, "Ethernet Interfaces and Hub MIB (hubmib) Charter", <http://www.ietf.org/html.charters/OLD/ hubmib-charter.html>. [IANAifType-MIB] Internet Assigned Numbers Authority (IANA), "IANAifType Textual Convention definition", <http://www.iana.org/assignments/ianaiftype-mib>. [RFC3410] Case, J., Mundy, R., Partain, D., and B. Stewart, "Introduction and Applicability Statements for Internet-Standard Management Framework", RFC 3410, December 2002. [RFC4070] Dodge, M. and B. Ray, "Definitions of Managed Object Extensions for Very High Speed Digital Subscriber Lines (VDSL) Using Multiple Carrier Modulation (MCM) Line Coding", RFC 4070, May 2005. [RFC4181] Heard, C., "Guidelines for Authors and Reviewers of MIB Documents", BCP 111, RFC 4181, September 2005. Beili Standards Track [Page 88]
RFC 5066 EFMCu Interfaces MIB November 2007 [RFC4319] Sikes, C., Ray, B., and R. Abbi, "Definitions of Managed Objects for High Bit-Rate DSL - 2nd generation (HDSL2) and Single-Pair High-Speed Digital Subscriber Line (SHDSL) Lines", RFC 4319, December 2005. [RFC4837] Khermosh, L., "Managed Objects of Ethernet Passive Optical Networks (EPON)", RFC 4837, July 2007. [RFC4878] Squire, M., "Definitions and Managed Objects for Operations, Administration, and Maintenance (OAM) Functions on Ethernet-Like Interfaces", RFC 4878, June 2007. Author's Address Edward Beili Actelis Networks Bazel 25 Petach-Tikva Israel Phone: +972-3-924-3491 EMail: edward.beili@actelis.com Beili Standards Track [Page 89]
RFC 5066 EFMCu Interfaces MIB November 2007 Full Copyright Statement Copyright (C) The IETF Trust (2007). This document is subject to the rights, licenses and restrictions contained in BCP 78, and except as set forth therein, the authors retain all their rights. This document and the information contained herein are provided on an "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY, THE IETF TRUST AND THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Intellectual Property The IETF takes no position regarding the validity or scope of any Intellectual Property Rights or other rights that might be claimed to pertain to the implementation or use of the technology described in this document or the extent to which any license under such rights might or might not be available; nor does it represent that it has made any independent effort to identify any such rights. Information on the procedures with respect to rights in RFC documents can be found in BCP 78 and BCP 79. Copies of IPR disclosures made to the IETF Secretariat and any assurances of licenses to be made available, or the result of an attempt made to obtain a general license or permission for the use of such proprietary rights by implementers or users of this specification can be obtained from the IETF on-line IPR repository at http://www.ietf.org/ipr. The IETF invites any interested party to bring to its attention any copyrights, patents or patent applications, or other proprietary rights that may cover technology that may be required to implement this standard. Please address the information to the IETF at ietf-ipr@ietf.org. Beili Standards Track [Page 90]