Internet Engineering Task Force (IETF)                       Y. Shi, Ed.
Request for Comments: 5834                  Hangzhou H3C Tech. Co., Ltd.
Category: Informational                                  D. Perkins, Ed.
ISSN: 2070-1721                                          C. Elliott, Ed.

                                                           Y. Zhang, Ed.
                                                          Fortinet, Inc.
                                                                May 2010


  Control and Provisioning of Wireless Access Points (CAPWAP) Protocol
                      Binding MIB for IEEE 802.11

Abstract

   This memo defines a portion of the Management Information Base (MIB)
   for use with network management protocols.  In particular, it
   describes managed objects for modeling the Control And Provisioning
   of Wireless Access Points (CAPWAP) protocol for IEEE 802.11 wireless
   binding.  This MIB module is presented as a basis for future work on
   the management of the CAPWAP protocol using the Simple Network
   Management Protocol (SNMP).

Status of This Memo

   This document is not an Internet Standards Track specification; it is
   published for informational purposes.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Not all documents
   approved by the IESG are a candidate for any level of Internet
   Standard; see Section 2 of RFC 5741.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   http://www.rfc-editor.org/info/rfc5834.













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Copyright Notice

   Copyright (c) 2010 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (http://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must
   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

Table of Contents

   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  3
   2.  The Internet-Standard Management Framework . . . . . . . . . .  3
   3.  Terminology  . . . . . . . . . . . . . . . . . . . . . . . . .  3
   4.  Conventions  . . . . . . . . . . . . . . . . . . . . . . . . .  5
   5.  Overview . . . . . . . . . . . . . . . . . . . . . . . . . . .  5
     5.1.  WLAN Profile . . . . . . . . . . . . . . . . . . . . . . .  5
     5.2.  Requirements and Constraints . . . . . . . . . . . . . . .  5
     5.3.  Mechanism of Reusing Wireless Binding MIB Module . . . . .  6
   6.  Structure of MIB Module  . . . . . . . . . . . . . . . . . . .  6
   7.  Relationship to Other MIB Modules  . . . . . . . . . . . . . .  7
     7.1.  Relationship to SNMPv2-MIB Module  . . . . . . . . . . . .  7
     7.2.  Relationship to IF-MIB Module  . . . . . . . . . . . . . .  7
     7.3.  Relationship to CAPWAP-BASE-MIB Module . . . . . . . . . .  7
     7.4.  Relationship to MIB Module in the IEEE 802.11 Standard . .  8
     7.5.  MIB Modules Required for IMPORTS . . . . . . . . . . . . .  8
   8.  Example of CAPWAP-DOT11-MIB Module Usage . . . . . . . . . . .  8
   9.  Definitions  . . . . . . . . . . . . . . . . . . . . . . . . . 14
   10. Security Considerations  . . . . . . . . . . . . . . . . . . . 21
   11. IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 22
     11.1. IANA Considerations for CAPWAP-DOT11-MIB Module  . . . . . 22
     11.2. IANA Considerations for ifType . . . . . . . . . . . . . . 22
   12. Contributors . . . . . . . . . . . . . . . . . . . . . . . . . 22
   13. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 23
   14. References . . . . . . . . . . . . . . . . . . . . . . . . . . 23
     14.1. Normative References . . . . . . . . . . . . . . . . . . . 23
     14.2. Informative References . . . . . . . . . . . . . . . . . . 24








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1.  Introduction

   The CAPWAP protocol [RFC5415] defines a standard, interoperable
   protocol, which enables an Access Controller (AC) to manage a
   collection of Wireless Termination Points (WTPs).  CAPWAP supports
   the use of various wireless technologies by the WTPs, with one
   specified in the CAPWAP Protocol Binding for IEEE 802.11 [RFC5416].

   This document defines a MIB module that can be used to manage CAPWAP
   implementations for IEEE 802.11 wireless binding.  This MIB module
   covers both configuration for Wireless Local Area Network (WLAN) and
   a way to reuse the IEEE 802.11 MIB module [IEEE.802-11.2007].  It is
   presented as a basis for future work on the SNMP management of the
   CAPWAP protocol.

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 a MIB
   module that is compliant to the SMIv2, which is described in STD 58,
   RFC 2578 [RFC2578], STD 58, RFC 2579 [RFC2579], and STD 58, RFC 2580
   [RFC2580].

3.  Terminology

   This document uses terminology from the CAPWAP protocol specification
   [RFC5415], the CAPWAP Protocol Binding for IEEE 802.11 [RFC5416], and
   the CAPWAP Protocol Base MIB [RFC5833].

   Access Controller (AC): The network entity that provides WTP access
   to the network infrastructure in the data plane, control plane,
   management plane, or a combination therein.

   Wireless Termination Point (WTP): The physical or network entity that
   contains an RF antenna and wireless physical layer (PHY) to transmit
   and receive station traffic for wireless access networks.








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   Control And Provisioning of Wireless Access Points (CAPWAP): It is a
   generic protocol defining AC and WTP control and data plane
   communication via a CAPWAP protocol transport mechanism.  CAPWAP
   control messages, and optionally CAPWAP data messages, are secured
   using Datagram Transport Layer Security (DTLS) [RFC4347].

   CAPWAP Control Channel: A bi-directional flow defined by the AC IP
   Address, WTP IP Address, AC control port, WTP control port, and the
   transport-layer protocol (UDP or UDP-Lite) over which CAPWAP control
   packets are sent and received.

   CAPWAP Data Channel: A bi-directional flow defined by the AC IP
   Address, WTP IP Address, AC data port, WTP data port, and the
   transport-layer protocol (UDP or UDP-Lite) over which CAPWAP data
   packets are sent and received.

   Station (STA): A device that contains an interface to a wireless
   medium (WM).

   Split and Local MAC: The CAPWAP protocol supports two modes of
   operation: Split and Local MAC (medium access control).  In Split MAC
   mode, all Layer 2 wireless data and management frames are
   encapsulated via the CAPWAP protocol and exchanged between the AC and
   the WTPs.  The Local MAC mode of operation allows the data frames to
   be either locally bridged or tunneled as 802.3 frames.

   Wireless Binding: The CAPWAP protocol is independent of a specific
   WTP radio technology, as well its associated wireless link layer
   protocol.  Elements of the CAPWAP protocol are designed to
   accommodate the specific needs of each wireless technology in a
   standard way.  Implementation of the CAPWAP protocol for a particular
   wireless technology MUST define a binding protocol for it, e.g., the
   binding for IEEE 802.11, provided in [RFC5416].

   Wireless Local Area Network (WLAN): A WLAN refers to a logical
   component instantiated on a WTP device.  A single physical WTP MAY
   operate a number of WLANs.  Each Basic Service Set Identifier (BSSID)
   and its constituent wireless terminal radios are denoted as a
   distinct WLAN on a physical WTP.  To support a physical WTP with
   multiple WLANs is an important feature for CAPWAP protocol's 802.11
   binding, and it is also for MIB module design.

   Wireless Binding MIB Module: Other Standards Development
   Organizations (SDOs), such as IEEE, already defined MIB modules for
   specific wireless technologies, e.g., the IEEE 802.11 MIB module
   [IEEE.802-11.2007].  Such MIB modules are called wireless binding MIB
   modules.




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   CAPWAP Protocol Wireless Binding MIB Module: It is a MIB module
   corresponding to the CAPWAP Protocol Binding for a wireless binding.
   Sometimes, not all the technology-specific message elements in a
   CAPWAP binding protocol have MIB objects defined by other SDOs.  For
   example, the protocol of [RFC5416] defines WLAN conception.  Also,
   Local or Split MAC modes could be specified for a WLAN.  The MAC mode
   for a WLAN is not in the scope of IEEE 802.11 [IEEE.802-11.2007].  In
   such cases, in addition to the existing wireless binding MIB modules
   defined by other SDOs, a CAPWAP protocol wireless binding MIB module
   is required to be defined for a wireless binding.

4.  Conventions

   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].

5.  Overview

5.1.  WLAN Profile

   A WLAN profile stores configuration parameters such as MAC type and
   tunnel mode for a WLAN.  Each WLAN profile is identified by a profile
   identifier.  The operator needs to create WLAN profiles before WTPs
   connect to the AC.  To provide WLAN service, the operator SHOULD bind
   WLAN profiles to a WTP Virtual Radio Interface that corresponds to a
   PHY radio.  During the binding operation, the AC MUST select an
   unused WLAN ID between 1 and 16 [RFC5416].  For example, to bind one
   more WLAN profile to a radio that has been bound with a WLAN profile,
   the AC SHOULD allocate WLAN ID 2 to the radio.  Although the maximum
   value of a WLAN ID is 16, the operator could configure more than 16
   WLAN Profiles on the AC.

5.2.  Requirements and Constraints

   The IEEE 802.11 MIB module [IEEE.802-11.2007] already defines MIB
   objects for most IEEE 802.11 Message Elements in the CAPWAP Protocol
   Binding for IEEE 802.11 [RFC5416].  As a CAPWAP protocol 802.11
   binding MIB module, the CAPWAP-DOT11-MIB module MUST be able to reuse
   such MIB objects in the IEEE 802.11 MIB module and support functions
   (such as MAC mode for WLAN in the [RFC5416]) that are not in the
   scope of IEEE 802.11 standard.  The CAPWAP-DOT11-MIB module MUST
   support such functions.

   In summary, the CAPWAP-DOT11-MIB module needs to support:

   - Reuse of wireless binding MIB modules in the IEEE 802.11 standard;




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   - Centralized management and configuration of WLAN profiles on the
     AC;

   - Configuration of a MAC type and tunnel mode for a specific WLAN
     profile.

5.3.  Mechanism of Reusing Wireless Binding MIB Module

   In the IEEE 802.11 MIB module, the MIB tables such as
   dot11AuthenticationAlgorithmsTable are able to support WLAN
   configuration (such as authentication algorithm), and these tables
   use the ifIndex as the index which works well in the autonomous WLAN
   architecture.

   Reuse of such wireless binding MIB modules is very important to
   centralized WLAN architectures.  The key point is to abstract a WLAN
   profile as a WLAN Profile Interface on the AC, which could be
   identified by an ifIndex.  The MIB objects in the IEEE 802.11 MIB
   module which are associated with this interface can be used to
   configure WLAN parameters for the WLAN, such as authentication
   algorithm.  With the ifIndex of a WLAN Profile Interface, the AC is
   able to reuse the IEEE 802.11 MIB module.

   In the CAPWAP-BASE-MIB module, each PHY radio is identified by a WTP
   ID and a radio ID, and has a corresponding WTP Virtual Radio
   Interface on the AC.  The IEEE 802.11 MIB module associated with this
   interface can be used to configure IEEE 802.11 wireless binding
   parameters for the radio such as RTS Threshold.  A WLAN Basic Service
   Set (BSS) Interface, created by binding a WLAN to a WTP Virtual Radio
   Interface, is used for data forwarding.

6.  Structure of MIB Module

   The MIB objects are derived from the CAPWAP protocol binding for IEEE
   802.11 document [RFC5416].

      capwapDot11WlanTable

      The table allows the operator to display and configure WLAN
      profiles, such as specifying the MAC type and tunnel mode for a
      WLAN.  Also, it helps the AC to configure a WLAN through the IEEE
      802.11 MIB module.









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      capwapDot11WlanBindTable

      The table provides a way to bind WLAN profiles to a WTP Virtual
      Radio Interface, which has a corresponding PHY radio.  A binding
      operation dynamically creates a WLAN BSS Interface, which is used
      for data forwarding.

7.  Relationship to Other MIB Modules

7.1.  Relationship to SNMPv2-MIB Module

   The CAPWAP-DOT11-MIB module does not duplicate the objects of the
   'system' group in the SNMPv2-MIB [RFC3418] that is defined as being
   mandatory for all systems, and the objects apply to the entity as a
   whole.  The 'system' group provides identification of the management
   entity and certain other system-wide data.

7.2.  Relationship to IF-MIB Module

   The Interfaces Group [RFC2863] defines generic managed objects for
   managing interfaces.  This memo contains the media-specific
   extensions to the Interfaces Group for managing WLAN that are modeled
   as interfaces.

   Each WLAN profile corresponds to a WLAN Profile Interface on the AC.
   The interface MUST be modeled as an ifEntry, and ifEntry objects such
   as ifIndex, ifDescr, ifName, and ifAlias are to be used as per
   [RFC2863].  The WLAN Profile Interface provides a way to configure
   IEEE 802.11 parameters for a specific WLAN and reuse the IEEE 802.11
   MIB module.

   To provide data forwarding service, the AC dynamically creates WLAN
   BSS Interfaces.  A WLAN BSS Interface MUST be modeled as an ifEntry,
   and ifEntry objects such as ifIndex, ifDescr, ifName, and ifAlias are
   to be used as per [RFC2863].  The interface enables a single physical
   WTP to support multiple WLANs.

   Also, the AC MUST have a mechanism that preserves the value of the
   ifIndexes (of both the WLAN Profile Interfaces and the WLAN BSS
   Interfaces) in the ifTable at AC reboot.

7.3.  Relationship to CAPWAP-BASE-MIB Module

   The CAPWAP-BASE-MIB module provides a way to manage and control WTP
   and radio objects.  Especially, it provides the WTP Virtual Radio
   Interface mechanism to enable the AC to reuse the IEEE 802.11 MIB
   module.  With this mechanism, an operator could configure an IEEE




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   802.11 radio's parameters and view the radio's traffic statistics on
   the AC.  Based on the CAPWAP-BASE-MIB module, the CAPWAP-DOT11-MIB
   module provides more WLAN information.

7.4.  Relationship to MIB Module in the IEEE 802.11 Standard

   With the ifIndex of WLAN Profile Interface and WLAN BSS Interface,
   the MIB module is able to reuse the IEEE 802.11 MIB module
   [IEEE.802-11.2007].  The CAPWAP-DOT11-MIB module does not duplicate
   those objects in the IEEE 802.11 MIB module.

   The CAPWAP Protocol Binding for IEEE 802.11 [RFC5416] involves some
   of the MIB objects defined in the IEEE 802.11 standard.  Although
   CAPWAP-DOT11-MIB module uses it [RFC5416] as a reference, it could
   reuse all the MIB objects in the IEEE 802.11 standard , and is not
   limited by the scope of CAPWAP Protocol Binding for IEEE 802.11.

7.5.  MIB Modules Required for IMPORTS

   The following MIB modules are required for IMPORTS: SNMPv2-SMI
   [RFC2578], SNMPv2-TC [RFC2579], SNMPv2-CONF [RFC2580], IF-MIB
   [RFC2863], and CAPWAP-BASE-MIB [RFC5833].

8.  Example of CAPWAP-DOT11-MIB Module Usage

   1) Create a WTP profile.

      Suppose the WTP's base MAC address is '00:01:01:01:01:00'.
      Creates a WTP profile for it through the capwapBaseWtpProfileTable
      [RFC5833] as follows:

     In capwapBaseWtpProfileTable
     {
       capwapBaseWtpProfileId                  = 1,
       capwapBaseWtpProfileName                = 'WTP Profile 123456',
       capwapBaseWtpProfileWtpMacAddress       = '00:01:01:01:01:00',
       capwapBaseWtpProfileWTPModelNumber             = 'WTP123',
       capwapBaseWtpProfileWtpName                    = 'WTP 123456',
       capwapBaseWtpProfileWtpLocation                = 'office',
       capwapBaseWtpProfileWtpStaticIpEnable          = true(1),
       capwapBaseWtpProfileWtpStaticIpType            = ipv4(1),
       capwapBaseWtpProfileWtpStaticIpAddress         = '192.0.2.10',
       capwapBaseWtpProfileWtpNetmask                 = '255.255.255.0',
       capwapBaseWtpProfileWtpGateway                 = '192.0.2.1',
       capwapBaseWtpProfileWtpFallbackEnable          = true(1),
       capwapBaseWtpProfileWtpEchoInterval            = 30,
       capwapBaseWtpProfileWtpIdleTimeout             = 300,
       capwapBaseWtpProfileWtpMaxDiscoveryInterval    = 20,



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       capwapBaseWtpProfileWtpReportInterval          = 120,
       capwapBaseWtpProfileWtpStatisticsTimer         = 120,
       capwapBaseWtpProfileWtpEcnSupport              = limited(0)
     }

      Suppose the WTP with model number 'WTP123' has one PHY radio and
      this PHY radio is identified by ID 1.  The creation of this WTP
      profile triggers the AC to automatically create a WTP Virtual
      Radio Interface and add a new row object to the
      capwapBaseWirelessBindingTable without manual intervention.
      Suppose the ifIndex of the WTP Virtual Radio Interface is 10.  The
      following information is stored in the
      capwapBaseWirelessBindingTable.

      In capwapBaseWirelessBindingTable
      {
        capwapBaseWtpProfileId                          = 1,
        capwapBaseWirelessBindingRadioId                = 1,
        capwapBaseWirelessBindingVirtualRadioIfIndex    = 10,
        capwapBaseWirelessBindingType                   = dot11(2)
      }

      The WTP Virtual Radio Interfaces on the AC correspond to the PHY
      radios on the WTP.  The WTP Virtual Radio Interface is modeled by
      ifTable [RFC2863].

      In ifTable
      {
        ifIndex              = 10,
        ifDescr              = 'WTP Virtual Radio Interface',
        ifType               = 254,
        ifMtu                = 0,
        ifSpeed              = 0,
        ifPhysAddress        = '00:00:00:00:00:00',
        ifAdminStatus        = true(1),
        ifOperStatus         = false(0),
        ifLastChange         = 0,
        ifInOctets           = 0,
        ifInUcastPkts        = 0,
        ifInDiscards         = 0,
        ifInErrors           = 0,
        ifInUnknownProtos    = 0,
        ifOutOctets          = 0,
        ifOutUcastPkts       = 0,
        ifOutDiscards        = 0,
        ifOutErrors          = 0
       }




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   2) Query the ifIndexes of WTP Virtual Radio Interfaces.

      Before configuring PHY radios, the operator needs to get the
      ifIndexes of WTP Virtual Radio Interfaces corresponding to the PHY
      radios.

      As the capwapBaseWirelessBindingTable already stores the mappings
      between PHY radios (Radio IDs) and the ifIndexes of WTP Virtual
      Radio Interfaces, the operator can get the ifIndex information by
      querying this table.  Such a query operation SHOULD run from radio
      ID 1 to radio ID 31 (according to [RFC5415]), and stop when an
      invalid ifIndex value (0) is returned.

      This example uses capwapBaseWtpProfileId = 1 and
      capwapBaseWirelessBindingRadioId = 1 as inputs to query the
      capwapBaseWirelessBindingTable, and gets
      capwapBaseWirelessBindingVirtualRadioIfIndex = 10.  Then it uses
      capwapBaseWtpProfileId = 1 and capwapBaseWirelessBindingRadioId =
      2, and gets an invalid ifIndex value (0), so the query operation
      ends.  This method gets not only the ifIndexes of WTP Virtual
      Radio Interfaces, but also the numbers of PHY radios.  Besides
      checking whether the ifIndex value is valid, the operator SHOULD
      check whether the capwapBaseWirelessBindingType is the desired
      binding type.

   3) Configure IEEE 802.11 parameters for a WTP Virtual Radio Interface

      This configuration is made on the AC through the IEEE 802.11 MIB
      module.

      The following shows an example of configuring parameters for a WTP
      Virtual Radio Interface with ifIndex 10 through the
      dot11OperationTable [IEEE.802-11.2007].

      In dot11OperationTable
      {
        ifIndex                                  = 10,
        dot11MACAddress                          = '00:00:00:00:00:00',
        dot11RTSThreshold                        = 2347,
        dot11ShortRetryLimit                     = 7,
        dot11LongRetryLimit                      = 4,
        dot11FragmentationThreshold              = 256,
        dot11MaxTransmitMSDULifetime             = 512,
        dot11MaxReceiveLifetime                  = 512,
        dot11ManufacturerID                      = 'capwap',
        dot11ProductID                           = 'capwap',
        dot11CAPLimit                            = 2,
        dot11HCCWmin                             = 0,



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        dot11HCCWmax                             = 0,
        dot11HCCAIFSN                            = 1,
        dot11ADDBAResponseTimeout                = 1,
        dot11ADDTSResponseTimeout                = 1,
        dot11ChannelUtilizationBeaconInterval    = 50,
        dot11ScheduleTimeout                     = 10,
        dot11DLSResponseTimeout                  = 10,
        dot11QAPMissingAckRetryLimit             = 1,
        dot11EDCAAveragingPeriod                 = 5
      }

   4) Configure a WLAN Profile.

      WLAN configuration is made on the AC through the CAPWAP-DOT11-MIB
      module, and IEEE 802.11 MIB module.

      The first step is to create a WLAN Profile Interface through the
      CAPWAP-DOT11-MIB module on the AC.

      For example, when you configure a WLAN profile that is identified
      by capwapDot11WlanProfileId 1, the capwapDot11WlanTable creates
      the following row object for it.

      In capwapDot11WlanTable
      {
        capwapDot11WlanProfileId          = 1,
        capwapDot11WlanProfileIfIndex     = 20,
        capwapDot11WlanMacType            = splitMAC(2),
        capwapDot11WlanTunnelMode         = dot3Tunnel(2),
        capwapDot11WlanRowStatus          = createAndGo(4)
      }

      The creation of a row object triggers the AC to automatically
      create a WLAN Profile Interface and it is identified by ifIndex 20
      without manual intervention.

      A WLAN Profile Interface MUST be modeled as an ifEntry on the AC
      that provides appropriate interface information.  The
      capwapDot11WlanTable stores the mappings between
      capwapDot11WlanProfileIds and the ifIndexes of WLAN Profile
      Interfaces.

      In ifTable
      {
        ifIndex              = 20,
        ifDescr              = 'WLAN Profile Interface',
        ifType               = 252,
        ifMtu                = 0,



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        ifSpeed              = 0,
        ifPhysAddress        = '00:00:00:00:00:00',
        ifAdminStatus        = true(1),
        ifOperStatus         = true(1),
        ifLastChange         = 0,
        ifInOctets           = 0,
        ifInUcastPkts        = 0,
        ifInDiscards         = 0,
        ifInErrors           = 0,
        ifInUnknownProtos    = 0,
        ifOutOctets          = 0,
        ifOutUcastPkts       = 0,
        ifOutDiscards        = 0,
        ifOutErrors          = 0
      }

      The second step is to configure WLAN parameters for the WLAN
      Profile Interface through the IEEE 802.11 MIB module on the AC.

      The following example configures an authentication algorithm for a
      WLAN.

      In dot11AuthenticationAlgorithmsTable
      {
        ifIndex                                = 20,
        dot11AuthenticationAlgorithmsIndex     = 1,
        dot11AuthenticationAlgorithm           = Shared Key(2),
        dot11AuthenticationAlgorithmsEnable    = true(1)
      }

      Here, ifIndex 20 identifies the WLAN Profile Interface, and the
      index of the configured authentication algorithm is 1.

   5) Bind WLAN Profiles to a WTP radio.

      On the AC, the capwapDot11WlanBindTable in the CAPWAP-DOT11-MIB
      stores the bindings between WLAN profiles(identified by
      capwapDot11WlanProfileId) and WTP Virtual Radio Interfaces
      (identified by the ifIndex).

      For example, after the operator binds a WLAN profile with
      capwapDot11WlanProfileId 1 to WTP Virtual Radio Interface with
      ifIndex 10, the capwapDot11WlanBindTable creates the following row
      object.







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      In capwapDot11WlanBindTable
      {
        ifIndex                          = 10,
        capwapDot11WlanProfileId         = 1,
        capwapDot11WlanBindBssIfIndex    = 30,
        capwapDot11WlanBindRowStatus     = createAndGo(4)
      }

      If the capwapDot11WlanMacType of the WLAN is splitMAC(2), the
      creation of the row object in the capwapDot11WlanBindTable
      triggers the AC to automatically create a WLAN BSS Interface
      identified by ifIndex 30 without manual intervention.

      The WLAN BSS Interface MUST be modeled as an ifEntry on the AC,
      which provides appropriate interface information.  The
      capwapDot11WlanBindTable stores the mappings among the ifIndex of
      a WTP Virtual Radio Interface, WLAN profile ID, WLAN ID, and the
      ifIndex of a WLAN BSS Interface.

   6) Get the current configuration status report from the WTP to the
      AC.

      Before a WTP that has joined the AC gets configuration from the
      AC, it needs to report its current configuration status by sending
      a configuration status request message to the AC, which uses the
      message to update corresponding MIB objects on the AC.  For
      example, for ifIndex 10 (which identifies a WLAN Virtual Radio
      Interface), its ifOperStatus in the ifTable is updated according
      to the current radio operational status in the CAPWAP message
      [RFC5415].

   7) Query WTP and radio statistical data.

      After WTPs start to run, the operator could query WTP and radio
      statistics data through the CAPWAP-BASE-MIB and CAPWAP-DOT11-MIB
      modules.  For example, through the dot11CountersTable
      [IEEE.802-11.2007], the operator could query counter data of a
      radio that is identified by the ifIndex of the corresponding WLAN
      Virtual Radio Interface.

   8) Query other statistical data.

      The operator could query the configuration of a WLAN through the
      dot11AuthenticationAlgorithmsTable [IEEE.802-11.2007] and the
      statistical data of a WLAN BSS Interface through the ifTable
      [RFC2863].





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9.  Definitions

CAPWAP-DOT11-MIB DEFINITIONS ::= BEGIN

IMPORTS
   RowStatus, TEXTUAL-CONVENTION
       FROM SNMPv2-TC
   OBJECT-GROUP, MODULE-COMPLIANCE
       FROM SNMPv2-CONF
   MODULE-IDENTITY, OBJECT-TYPE, mib-2, Unsigned32
       FROM SNMPv2-SMI
   ifIndex, InterfaceIndex
       FROM IF-MIB
   CapwapBaseMacTypeTC, CapwapBaseTunnelModeTC
       FROM CAPWAP-BASE-MIB;

capwapDot11MIB MODULE-IDENTITY
    LAST-UPDATED "201004300000Z"        -- 30 April 2010
    ORGANIZATION "IETF Control And Provisioning of Wireless Access
                  Points (CAPWAP) Working Group
                  http://www.ietf.org/html.charters/capwap-charter.html"
    CONTACT-INFO
        "General Discussion: capwap@frascone.com
         To Subscribe: http://lists.frascone.com/mailman/listinfo/capwap

         Yang Shi (editor)
         Hangzhou H3C Tech. Co., Ltd.
         Beijing R&D Center of H3C, Digital Technology Plaza
         NO. 9 Shangdi 9th Street, Haidian District
         Beijing  100085
         China
         Phone: +86 010 82775276
         Email: rishyang@gmail.com

         David T. Perkins (editor)
         228 Bayview Dr.
         San Carlos, CA  94070
         USA
         Phone: +1 408 394-8702
         Email:  dperkins@dsperkins.com

         Chris Elliott (editor)
         1516 Kent St.
         Durham, NC  27707
         USA
         Phone: +1 919-308-1216
         Email: chelliot@pobox.com




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RFC 5834               CAPWAP Protocol Binding MIB              May 2010


         Yong Zhang (editor)
         Fortinet, Inc.
         1090 Kifer Road
         Sunnyvale, CA  94086
         USA
         Email: yzhang@fortinet.com"

   DESCRIPTION
       "Copyright (c) 2010 IETF Trust and the persons identified as
        authors of the code.  All rights reserved.

        Redistribution and use in source and binary forms, with or
        without modification, is permitted pursuant to, and subject
        to the license terms contained in, the Simplified BSD License
        set forth in Section 4.c of the IETF Trust's Legal Provisions
        Relating to IETF Documents
        (http://trustee.ietf.org/license-info).

        This version of this MIB module is part of RFC 5834;
        see the RFC itself for full legal notices.

        This MIB module contains managed object definitions for
        CAPWAP Protocol binding for IEEE 802.11."
   REVISION    "201004300000Z"
   DESCRIPTION
       "Initial version, published as RFC 5834"
        ::= { mib-2 195 }

-- Textual conventions

CapwapDot11WlanIdTC ::= TEXTUAL-CONVENTION
    DISPLAY-HINT "d"
    STATUS      current
    DESCRIPTION
        "Represents the unique identifier of a Wireless Local Area
         Network (WLAN)."
    SYNTAX      Unsigned32 (1..16)

CapwapDot11WlanIdProfileTC ::= TEXTUAL-CONVENTION
    DISPLAY-HINT "d"
    STATUS      current
    DESCRIPTION
        "Represents the unique identifier of a WLAN profile."
    SYNTAX      Unsigned32 (1..512)

-- Top level components of this MIB module

-- Tables, Scalars



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capwapDot11Objects OBJECT IDENTIFIER
    ::= { capwapDot11MIB 1 }
-- Conformance
capwapDot11Conformance OBJECT IDENTIFIER
    ::= { capwapDot11MIB 2 }

-- capwapDot11WlanTable Table

capwapDot11WlanTable OBJECT-TYPE
    SYNTAX      SEQUENCE OF CapwapDot11WlanEntry
    MAX-ACCESS  not-accessible
    STATUS      current
    DESCRIPTION
        "A table that allows the operator to display and configure
         WLAN profiles, such as specifying the MAC type and tunnel mode
         for a WLAN.  Also, it helps the AC to configure a WLAN through
         the IEEE 802.11 MIB module.
         Values of all objects in this table are persistent at
         restart/reboot."
    ::= { capwapDot11Objects 1 }

capwapDot11WlanEntry  OBJECT-TYPE
    SYNTAX      CapwapDot11WlanEntry
    MAX-ACCESS  not-accessible
    STATUS      current
    DESCRIPTION
        "A set of objects that stores the settings of a WLAN profile."
    INDEX { capwapDot11WlanProfileId }
    ::= { capwapDot11WlanTable 1 }

CapwapDot11WlanEntry ::=
    SEQUENCE {
      capwapDot11WlanProfileId          CapwapDot11WlanIdProfileTC,
      capwapDot11WlanProfileIfIndex     InterfaceIndex,
      capwapDot11WlanMacType            CapwapBaseMacTypeTC,
      capwapDot11WlanTunnelMode         CapwapBaseTunnelModeTC,
      capwapDot11WlanRowStatus          RowStatus
    }

capwapDot11WlanProfileId OBJECT-TYPE
    SYNTAX      CapwapDot11WlanIdProfileTC
    MAX-ACCESS  not-accessible
    STATUS      current
    DESCRIPTION
        "Represents the identifier of a WLAN profile that has a
         corresponding capwapDot11WlanProfileIfIndex."
    ::= { capwapDot11WlanEntry 1 }




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capwapDot11WlanProfileIfIndex OBJECT-TYPE
    SYNTAX      InterfaceIndex
    MAX-ACCESS  read-only
    STATUS      current
    DESCRIPTION
        "Represents the index value that uniquely identifies a
         WLAN Profile Interface.  The interface identified by a
         particular value of this index is the same interface as
         identified by the same value of the ifIndex.
         The creation of a row object in the capwapDot11WlanTable
         triggers the AC to automatically create an WLAN Profile
         Interface identified by an ifIndex without manual
         intervention.
         Most MIB tables in the IEEE 802.11 MIB module
         [IEEE.802-11.2007] use an ifIndex to identify an interface
         to facilitate the configuration and maintenance, for example,
         dot11AuthenticationAlgorithmsTable.
         Using the ifIndex of a WLAN Profile Interface, the Operator
         could configure a WLAN through the IEEE 802.11 MIB module."
    ::= { capwapDot11WlanEntry 2 }

capwapDot11WlanMacType OBJECT-TYPE
    SYNTAX      CapwapBaseMacTypeTC
    MAX-ACCESS  read-create
    STATUS      current
    DESCRIPTION
        "Represents whether the WTP SHOULD support the WLAN in
         Local or Split MAC modes."
    REFERENCE
        "Section 6.1 of CAPWAP Protocol Binding for IEEE 802.11,
         RFC 5416."
    ::= { capwapDot11WlanEntry 3 }

capwapDot11WlanTunnelMode OBJECT-TYPE
    SYNTAX      CapwapBaseTunnelModeTC
    MAX-ACCESS  read-create
    STATUS      current
    DESCRIPTION
        "Represents the frame tunneling mode to be used for IEEE 802.11
         data frames from all stations associated with the WLAN.
         Bits are exclusive with each other for a specific WLAN profile,
         and only one tunnel mode could be configured.
         If the operator set more than one bit, the value of the
         Response-PDU's error-status field is set to 'wrongValue',
         and the value of its error-index field is set to the index of
         the failed variable binding."
    REFERENCE
        "Section 6.1 of CAPWAP Protocol Binding for IEEE 802.11,



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         RFC 5416."
    ::= { capwapDot11WlanEntry 4 }

capwapDot11WlanRowStatus OBJECT-TYPE
    SYNTAX      RowStatus
    MAX-ACCESS  read-create
    STATUS      current
    DESCRIPTION
        "This variable is used to create, modify, and/or delete a row
         in this table.
         All the objects in a row can be modified only when the value
         of this object in the corresponding conceptual row is not
         'active'.  Thus, to modify one or more of the objects in
         this conceptual row:
              a. change the row status to 'notInService',
              b. change the values of the row
              c. change the row status to 'active'
         The capwapDot11WlanRowStatus may be changed to 'active'
         if all the managed objects in the conceptual row with
         MAX-ACCESS read-create have been assigned valid values.

         When the operator deletes a WLAN profile, the AC SHOULD
         check whether the WLAN profile is bound with a radio.
         If yes, the value of the Response-PDU's error-status field
         is set to 'inconsistentValue', and the value of its
         error-index field is set to the index of the failed variable
         binding.  If not, the row object could be deleted."
    ::= { capwapDot11WlanEntry 5 }

-- End of capwapDot11WlanTable Table


-- capwapDot11WlanBindTable Table

capwapDot11WlanBindTable OBJECT-TYPE
    SYNTAX      SEQUENCE OF CapwapDot11WlanBindEntry
    MAX-ACCESS  not-accessible
    STATUS      current
    DESCRIPTION
        "A table that stores bindings between WLAN profiles
         (identified by capwapDot11WlanProfileId) and WTP Virtual Radio
         Interfaces.  The WTP Virtual Radio Interfaces on the AC
         correspond to physical layer (PHY) radios on the WTPs.
         It also stores the mappings between WLAN IDs and WLAN
         Basic Service Set (BSS) Interfaces.
         Values of all objects in this table are persistent at
         restart/reboot."
    REFERENCE



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        "Section 6.1 of CAPWAP Protocol Binding for IEEE 802.11,
         RFC 5416."
    ::= { capwapDot11Objects 2 }

capwapDot11WlanBindEntry OBJECT-TYPE
    SYNTAX      CapwapDot11WlanBindEntry
    MAX-ACCESS  not-accessible
    STATUS      current
    DESCRIPTION
        "A set of objects that stores the binding of a WLAN profile
         to a WTP Virtual Radio Interface.  It also stores the mapping
         between WLAN ID and WLAN BSS Interface.
         The INDEX object ifIndex is the ifIndex of a WTP Virtual
         Radio Interface."
    INDEX { ifIndex, capwapDot11WlanProfileId }
    ::= { capwapDot11WlanBindTable 1 }

CapwapDot11WlanBindEntry ::=
    SEQUENCE {
      capwapDot11WlanBindWlanId        CapwapDot11WlanIdTC,
      capwapDot11WlanBindBssIfIndex    InterfaceIndex,
      capwapDot11WlanBindRowStatus     RowStatus
    }

capwapDot11WlanBindWlanId OBJECT-TYPE
    SYNTAX      CapwapDot11WlanIdTC
    MAX-ACCESS  read-only
    STATUS      current
    DESCRIPTION
        "Represents the WLAN ID of a WLAN.
         During a binding operation, the AC MUST select an unused
         WLAN ID from between 1 and 16 [RFC5416].  For example, to bind
         another WLAN profile to a radio that has been bound with
         a WLAN profile, WLAN ID 2 should be assigned."
    REFERENCE
        "Section 6.1 of CAPWAP Protocol Binding for IEEE 802.11,
         RFC 5416."
    ::= { capwapDot11WlanBindEntry 1 }

capwapDot11WlanBindBssIfIndex OBJECT-TYPE
    SYNTAX      InterfaceIndex
    MAX-ACCESS  read-only
    STATUS      current
    DESCRIPTION
        "Represents the index value that uniquely identifies a
         WLAN BSS Interface.  The interface identified by a
         particular value of this index is the same interface as
         identified by the same value of the ifIndex.



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         The ifIndex here is for a WLAN BSS Interface.
         The creation of a row object in the capwapDot11WlanBindTable
         triggers the AC to automatically create a WLAN BSS Interface
         identified by an ifIndex without manual intervention.
         The PHY address of the capwapDot11WlanBindBssIfIndex is the
         BSSID.  While manufacturers are free to assign BSSIDs by using
         any arbitrary mechanism, it is advised that where possible the
         BSSIDs are assigned as a contiguous block.
         When assigned as a block, implementations can still assign
         any of the available BSSIDs to any WLAN.  One possible method
         is for the WTP to assign the address using the following
         algorithm: base BSSID address + WLAN ID."
    REFERENCE
        "Section 2.4 of CAPWAP Protocol Binding for IEEE 802.11,
         RFC 5416."
    ::= { capwapDot11WlanBindEntry 2 }

capwapDot11WlanBindRowStatus OBJECT-TYPE
    SYNTAX      RowStatus
    MAX-ACCESS  read-create
    STATUS      current
    DESCRIPTION
        "This variable is used to create, modify, and/or delete a row
         in this table.
         All the objects in a row can be modified only when the value
         of this object in the corresponding conceptual row is not
         'active'.  Thus, to modify one or more of the objects in
         this conceptual row:
              a. change the row status to 'notInService',
              b. change the values of the row
              c. change the row status to 'active'"
    ::= { capwapDot11WlanBindEntry 3 }

-- End of capwapDot11WlanBindTable Table


-- Module compliance

capwapDot11Groups OBJECT IDENTIFIER
    ::= { capwapDot11Conformance 1 }

capwapDot11Compliances OBJECT IDENTIFIER
    ::= { capwapDot11Conformance 2 }

capwapDot11Compliance MODULE-COMPLIANCE
    STATUS current
    DESCRIPTION
        "Describes the requirements for conformance to the



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         CAPWAP-DOT11-MIB module."

    MODULE -- this module
      MANDATORY-GROUPS {
        capwapDot11WlanGroup,
        capwapDot11WlanBindGroup
      }
    ::= { capwapDot11Compliances 1 }

capwapDot11WlanGroup    OBJECT-GROUP
    OBJECTS {
      capwapDot11WlanProfileIfIndex,
      capwapDot11WlanMacType,
      capwapDot11WlanTunnelMode,
      capwapDot11WlanRowStatus
    }
    STATUS  current
    DESCRIPTION
        "A collection of objects that is used to configure
         the properties of a WLAN profile."
    ::= { capwapDot11Groups 1 }

capwapDot11WlanBindGroup    OBJECT-GROUP
    OBJECTS {
      capwapDot11WlanBindWlanId,
      capwapDot11WlanBindBssIfIndex,
      capwapDot11WlanBindRowStatus
    }
    STATUS  current
    DESCRIPTION
        "A collection of objects that is used to bind the
         WLAN profiles with a radio."
    ::= { capwapDot11Groups 2 }

END

10.  Security Considerations

   There are a number of management objects defined in this MIB module
   with a MAX-ACCESS clause of read-write and/or read-create.  Such
   objects MAY be considered sensitive or vulnerable in some network
   environments.  The support for SET operations in a non-secure
   environment without proper protection can have a negative effect on
   network operations.  The following are the tables and objects and
   their sensitivity/vulnerability:






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   o  Unauthorized changes to the capwapDot11WlanTable and
      capwapDot11WlanBindTable MAY disrupt allocation of resources in
      the network, and also change the behavior of the WLAN system such
      as MAC type.

   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 this MIB module.

   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
   instance of this MIB module 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.

11.  IANA Considerations

11.1.  IANA Considerations for CAPWAP-DOT11-MIB Module

        The MIB module in this document uses the following IANA-assigned
        OBJECT IDENTIFIER value recorded in the SMI Numbers registry:

        Descriptor      OBJECT IDENTIFIER value
        ----------      -----------------------
        capwapDot11MIB  { mib-2 195 }

11.2.  IANA Considerations for ifType

   IANA has assigned the following ifTypes:

       Decimal   Name                Description
       -------   ------------        -------------------------------
       252       capwapDot11Profile  WLAN Profile Interface
       253       capwapDot11Bss      WLAN BSS Interface

12.  Contributors

   This MIB module is based on contributions from Long Gao.




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13.  Acknowledgements

   Thanks to David Harrington, Dan Romascanu, Abhijit Choudhury, and
   Elwyn Davies for helpful comments on this document and guiding some
   technical solutions.

   The authors also thank their friends and coworkers Fei Fang, Xuebin
   Zhu, Hao Song, Yu Liu, Sachin Dutta, Ju Wang, Yujin Zhao, Haitao
   Zhang, Xiansen Cai, and Xiaolan Wan.

14.  References

14.1.  Normative References

   [IEEE.802-11.2007]  "Information technology - Telecommunications and
                       information exchange between systems  - Local and
                       metropolitan area networks - Specific
                       requirements - Part 11: Wireless LAN Medium
                       Access Control (MAC) and Physical Layer (PHY)
                       specifications", IEEE Standard 802.11, 2007, <htt
                       p://standards.ieee.org/getieee802/download/
                       802.11-2007.pdf>.

   [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.

   [RFC3418]           Presuhn, R., "Management Information Base (MIB)
                       for the Simple Network Management Protocol
                       (SNMP)", STD 62, RFC 3418, December 2002.





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RFC 5834               CAPWAP Protocol Binding MIB              May 2010


   [RFC5415]           Calhoun, P., Montemurro, M., and D. Stanley,
                       "Control And Provisioning of Wireless Access
                       Points (CAPWAP) Protocol Specification",
                       RFC 5415, March 2009.

   [RFC5416]           Calhoun, P., Montemurro, M., and D. Stanley,
                       "Control and Provisioning of Wireless Access
                       Points (CAPWAP) Protocol Binding for IEEE
                       802.11", RFC 5416, March 2009.

   [RFC5833]           Shi, Y., Ed., Perkins, D., Ed., Elliott, C., Ed.,
                       and Y. Zhang, Ed., "Control and Provisioning of
                       Wireless Access Points (CAPWAP) Protocol Base
                       MIB", RFC 5833, May 2010.

14.2.  Informative References

   [RFC3410]           Case, J., Mundy, R., Partain, D., and B. Stewart,
                       "Introduction and Applicability Statements for
                       Internet-Standard Management Framework",
                       RFC 3410, December 2002.

   [RFC4347]           Rescorla, E. and N. Modadugu, "Datagram Transport
                       Layer Security", RFC 4347, April 2006.



























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RFC 5834               CAPWAP Protocol Binding MIB              May 2010


Authors' Addresses

   Yang Shi (editor)
   Hangzhou H3C Tech. Co., Ltd.
   Beijing R&D Center of H3C, Digital Technology Plaza
   NO. 9 Shangdi 9th Street, Haidian District
   Beijing  100085
   China

   Phone: +86 010 82775276
   EMail: rishyang@gmail.com


   David T. Perkins (editor)
   228 Bayview Dr.
   San Carlos, CA  94070
   USA

   Phone: +1 408 394-8702
   EMail: dperkins@dsperkins.com


   Chris Elliott (editor)
   1516 Kent St.
   Durham, NC  27707
   USA

   Phone: +1 919-308-1216
   EMail: chelliot@pobox.com


   Yong Zhang (editor)
   Fortinet, Inc.
   1090 Kifer Road
   Sunnyvale, CA  94086
   USA

   EMail: yzhang@fortinet.com













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