RFC 7181 The Optimized Link State Routing Protocol Version 2

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Updated by: 7183, 7187, 7188, 7466 PROPOSED STANDARD
Errata Exist
Internet Engineering Task Force (IETF)                        T. Clausen
Request for Comments: 7181                      LIX, Ecole Polytechnique
Category: Standards Track                                    C. Dearlove
ISSN: 2070-1721                                          BAE Systems ATC
                                                              P. Jacquet
                                                Alcatel-Lucent Bell Labs
                                                              U. Herberg
                                         Fujitsu Laboratories of America
                                                              April 2014


          The Optimized Link State Routing Protocol Version 2

Abstract

   This specification describes version 2 of the Optimized Link State
   Routing Protocol (OLSRv2) for Mobile Ad Hoc Networks (MANETs).

Status of This Memo

   This is an Internet Standards Track document.

   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).  Further information on
   Internet Standards is available in 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/rfc7181.

Copyright Notice

   Copyright (c) 2014 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.





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   This document may contain material from IETF Documents or IETF
   Contributions published or made publicly available before November
   10, 2008.  The person(s) controlling the copyright in some of this
   material may not have granted the IETF Trust the right to allow
   modifications of such material outside the IETF Standards Process.
   Without obtaining an adequate license from the person(s) controlling
   the copyright in such materials, this document may not be modified
   outside the IETF Standards Process, and derivative works of it may
   not be created outside the IETF Standards Process, except to format
   it for publication as an RFC or to translate it into languages other
   than English.

Table of Contents

   1. Introduction ....................................................5
   2. Terminology .....................................................6
   3. Applicability Statement .........................................9
   4. Protocol Overview and Functioning ..............................10
      4.1. Overview ..................................................10
      4.2. Routers and Interfaces ....................................12
      4.3. Information Base Overview .................................13
           4.3.1. Local Information Base .............................13
           4.3.2. Interface Information Base .........................14
           4.3.3. Neighbor Information Base ..........................14
           4.3.4. Topology Information Base ..........................14
           4.3.5. Received Message Information Base ..................16
      4.4. Signaling Overview ........................................16
      4.5. Link Metrics ..............................................17
      4.6. Flooding MPRs and Routing MPR .............................18
      4.7. Routing Set Use ...........................................19
   5. Protocol Parameters and Constants ..............................19
      5.1. Protocol and Port Numbers .................................19
      5.2. Multicast Address .........................................20
      5.3. Interface Parameters ......................................20
           5.3.1. Received Message Validity Time .....................20
      5.4. Router Parameters .........................................20
           5.4.1. Local History Times ................................20
           5.4.2. Link Metric Parameters .............................21
           5.4.3. Message Intervals ..................................21
           5.4.4. Advertised Information Validity Times ..............22
           5.4.5. Processing and Forwarding Validity Times ...........22
           5.4.6. Jitter .............................................23
           5.4.7. Hop Limit ..........................................23
           5.4.8. Willingness ........................................24
      5.5. Parameter Change Constraints ..............................25
      5.6. Constants .................................................27
           5.6.1. Link Metric Constants ..............................27
           5.6.2. Willingness Constants ..............................28



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           5.6.3. Time Constant ......................................28
   6. Link Metric Values .............................................28
      6.1. Link Metric Representation ................................28
      6.2. Link Metric Compressed Form ...............................29
   7. Local Information Base .........................................29
      7.1. Originator Set ............................................30
      7.2. Local Attached Network Set ................................30
   8. Interface Information Base .....................................31
      8.1. Link Set ..................................................31
      8.2. 2-Hop Set .................................................32
   9. Neighbor Information Base ......................................32
   10. Topology Information Base .....................................34
      10.1. Advertising Remote Router Set ............................34
      10.2. Router Topology Set ......................................35
      10.3. Routable Address Topology Set ............................35
      10.4. Attached Network Set .....................................36
      10.5. Routing Set ..............................................37
   11. Received Message Information Base .............................37
      11.1. Received Set .............................................38
      11.2. Processed Set ............................................38
      11.3. Forwarded Set ............................................39
   12. Information Base Properties ...................................39
      12.1. Corresponding Protocol Tuples ............................39
      12.2. Address Ownership ........................................40
   13. Packets and Messages ..........................................41
      13.1. Messages .................................................41
      13.2. Packets ..................................................41
      13.3. TLVs .....................................................42
           13.3.1. Message TLVs ......................................42
           13.3.2. Address Block TLVs ................................42
   14. Message Processing and Forwarding .............................45
      14.1. Actions When Receiving a Message .........................45
      14.2. Message Considered for Processing ........................46
      14.3. Message Considered for Forwarding ........................47
   15. HELLO Messages ................................................49
      15.1. HELLO Message Generation .................................49
      15.2. HELLO Message Transmission ...............................51
      15.3. HELLO Message Processing .................................51
           15.3.1. HELLO Message Discarding ..........................51
           15.3.2. HELLO Message Usage ...............................52
   16. TC Messages ...................................................56
      16.1. TC Message Generation ....................................56
      16.2. TC Message Transmission ..................................58
      16.3. TC Message Processing ....................................59
           16.3.1. TC Message Discarding .............................59
           16.3.2. TC Message Processing Definitions .................61
           16.3.3. Initial TC Message Processing .....................61
           16.3.4. Completing TC Message Processing ..................65



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   17. Information Base Changes ......................................66
      17.1. Originator Address Changes ...............................66
      17.2. Link State Changes .......................................66
      17.3. Neighbor State Changes ...................................67
      17.4. Advertised Neighbor Changes ..............................67
      17.5. Advertising Remote Router Tuple Expires ..................68
      17.6. Neighborhood Changes and MPR Updates .....................68
      17.7. Routing Set Updates ......................................70
   18. Selecting MPRs ................................................71
      18.1. Overview .................................................72
      18.2. Neighbor Graph ...........................................72
      18.3. MPR Properties ...........................................73
      18.4. Flooding MPRs ............................................74
      18.5. Routing MPRs .............................................76
      18.6. Calculating MPRs .........................................77
   19. Routing Set Calculation .......................................78
      19.1. Network Topology Graph ...................................78
      19.2. Populating the Routing Set ...............................80
   20. Proposed Values for Parameters ................................81
      20.1. Local History Time Parameters ............................82
      20.2. Message Interval Parameters ..............................82
      20.3. Advertised Information Validity Time Parameters ..........82
      20.4. Received Message Validity Time Parameters ................82
      20.5. Jitter Time Parameters ...................................82
      20.6. Hop Limit Parameter ......................................82
      20.7. Willingness Parameters ...................................82
   21. Sequence Numbers ..............................................83
   22. Extensions ....................................................83
   23. Security Considerations .......................................84
      23.1. Security Architecture ....................................84
      23.2. Integrity ................................................85
      23.3. Confidentiality ..........................................86
      23.4. Interaction with External Routing Domains ................87
      23.5. Mandatory Security Mechanisms ............................87
      23.6. Key Management ...........................................88
   24. IANA Considerations ...........................................90
      24.1. Expert Review: Evaluation Guidelines .....................91
      24.2. Message Types ............................................91
      24.3. Message-Type-Specific TLV Type Registries ................91
      24.4. Message TLV Types ........................................92
      24.5. Address Block TLV Types ..................................93
      24.6. NBR_ADDR_TYPE and MPR Values .............................96
   25. Contributors ..................................................96
   26. Acknowledgments ...............................................97
   27. References ....................................................97
      27.1. Normative References .....................................97
      27.2. Informative References ...................................98
   Appendix A.  Constraints .........................................100



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   Appendix B.  Example Algorithm for Calculating MPRs ..............104
     B.1.  Additional Notation ......................................104
     B.2.  MPR Selection Algorithm ................................. 105
   Appendix C.  Example Algorithm for Calculating the Routing Set ...105
     C.1.  Local Interfaces and Neighbors ...........................106
     C.2.  Add Neighbor Routers .....................................107
     C.3.  Add Remote Routers .......................................107
     C.4.  Add Neighbor Addresses ...................................108
     C.5.  Add Remote Routable Addresses ............................109
     C.6.  Add Attached Networks ....................................110
     C.7.  Add 2-Hop Neighbors ......................................110
   Appendix D.  TC Message Example ..................................111
   Appendix E.  Flow and Congestion Control .........................114

1.  Introduction

   The Optimized Link State Routing Protocol version 2 (OLSRv2) is the
   successor to OLSR (version 1) as published in [RFC3626].  Compared to
   [RFC3626], OLSRv2 retains the same basic mechanisms and algorithms,
   enhanced by the ability to use a link metric other than hop count in
   the selection of shortest routes.  OLSRv2 also uses a more flexible
   and efficient signaling framework and includes some simplification of
   the messages being exchanged.

   OLSRv2 is developed for Mobile Ad Hoc Networks (MANETs).  It operates
   as a table-driven, proactive protocol, i.e., it exchanges topology
   information with other routers in the network regularly.  OLSRv2 is
   an optimization of the classic link state routing protocol.  Its key
   concept is that of multipoint relays (MPRs).  Each router selects two
   sets of MPRs, each being a set of its neighbor routers that "cover"
   all of its symmetrically connected 2-hop neighbor routers.  These two
   sets are "flooding MPRs" and "routing MPRs", which are used to
   achieve flooding reduction and topology reduction, respectively.

   Flooding reduction is achieved by control traffic being flooded
   through the network using hop-by-hop forwarding, but with a router
   only needing to forward control traffic that is first received
   directly from one of the routers that have selected it as a flooding
   MPR (its "flooding MPR selectors").  This mechanism, denoted "MPR
   flooding", provides an efficient mechanism for information
   distribution within the MANET by reducing the number of transmissions
   required [MPR].

   Topology reduction is achieved by assigning a special responsibility
   to routers selected as routing MPRs when declaring link state
   information.  A sufficient requirement for OLSRv2 to provide shortest
   routes to all destinations is that routers declare link state
   information for their routing MPR selectors, if any.  Routers that



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   are not selected as routing MPRs need not send any link state
   information.  Based on this reduced link state information, routing
   MPRs are used as intermediate routers in multi-hop routes.

   Thus, the use of MPRs allows reduction of the number and the size of
   link state messages and reduction in the amount of link state
   information maintained in each router.  When possible (in particular
   if using a hop count metric), the same routers may be picked as both
   flooding MPRs and routing MPRs.

   A router selects both routing and flooding MPRs from among its one-
   hop neighbors connected by "symmetric", i.e., bidirectional, links.
   Therefore, selecting routes through routing MPRs avoids the problems
   associated with data packet transfer over unidirectional links (e.g.,
   the problem of not getting link-layer acknowledgments at each hop,
   for link layers employing this technique).

   OLSRv2 uses and extends the MANET Neighborhood Discovery Protocol
   (NHDP) defined in [RFC6130] and also uses the Generalized MANET
   Packet/Message Format [RFC5444], the TLVs specified in [RFC5497] and,
   optionally, message jitter as specified in [RFC5148].  These four
   other protocols and specifications were all originally created as
   part of OLSRv2 but have been specified separately for wider use.

   OLSRv2 makes no assumptions about the underlying link layer.  OLSRv2,
   through its use of [RFC6130], may use link-layer information and
   notifications when available and applicable.  In addition, OLSRv2
   uses link metrics that may be derived from link layer or any other
   information.  OLSRv2 does not specify the physical meaning of link
   metrics but specifies a means by which new types of link metrics may
   be specified in the future but used by OLSRv2 without modification.

   OLSRv2, like OLSR [RFC3626], inherits its concept of forwarding and
   relaying from the High Performance Radio Local Area Network
   (HIPERLAN) (a MAC-layer protocol), which is standardized by ETSI
   [HIPERLAN] [HIPERLAN2].  This document does not obsolete [RFC3626],
   which is left in place for further experimentation.

2.  Terminology

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
   "OPTIONAL" in this document are to be interpreted as described in
   [RFC2119].

   All terms introduced in [RFC5444], including "packet", "Packet
   Header", "message", "Message Header", "Message Body", "Message Type",
   "message sequence number", "hop limit", "hop count", "Address Block",



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   "TLV Block", "TLV", "Message TLV", "Address Block TLV", "type" (of
   TLV), "type extension" (of TLV), "value" (of TLV), "address",
   "address prefix", and "address object" are to be interpreted as
   described there.

   All terms introduced in [RFC6130], including "interface", "MANET
   interface", "network address", "link", "symmetric link", "symmetric
   1-hop neighbor", "symmetric 2-hop neighbor", "symmetric 1-hop
   neighborhood" "constant", "interface parameter", "router parameter",
   "Information Base", and "HELLO message" are to be interpreted as
   described there.

   Additionally, this specification uses the following terminology:

   Router:
      A MANET router that implements this protocol.

   OLSRv2 interface:
      A MANET interface running this protocol.  A router running this
      protocol MUST have at least one OLSRv2 interface.

   Routable address:
      A network address that may be used as the destination of a data
      packet.  A router that implements this protocol will need to
      distinguish a routable address from a non-routable address by
      direct inspection of the network address, based on global-scope
      address allocations by IANA and/or administrative configuration
      (consistently across the MANET).  Broadcast and multicast
      addresses, and addresses that are limited in scope to less than
      the entire MANET, MUST NOT be considered as routable addresses.
      Anycast addresses may be considered as routable addresses.

   Originator address:
      An address that is unique (within the MANET) to a router.  A
      router MUST select an originator address; it MAY choose one of its
      interface addresses as its originator address; and it MAY select
      either a routable or non-routable address.  A broadcast,
      multicast, or anycast address MUST NOT be chosen as an originator
      address.  If the router selects a routable address, then it MUST
      be one that the router will accept as destination.  An originator
      address MUST NOT have a prefix length, except when included in an
      Address Block where it MAY be associated with a prefix of maximum
      prefix length (e.g., if the originator address is an IPv6 address,
      it MUST have either no prefix length or have a prefix length of
      128).






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   Message originator address:
      The originator address of the router that created a message, as
      deduced from that message by its recipient.  For all messages used
      in this specification, including HELLO messages defined in
      [RFC6130], the recipient MUST be able to deduce an originator
      address.  The message originator address will usually be included
      in the message as its <msg-orig-addr> element as defined in
      [RFC5444].  However, an exceptional case, which does not add a
      <msg-orig-addr> element to a HELLO message, may be used by a
      router that only has a single address.

   Willingness:
      A numerical value between WILL_NEVER and WILL_ALWAYS (both
      inclusive) that represents the router's willingness to be selected
      as an MPR.  A router has separate willingness values to be a
      flooding MPR and a routing MPR.

   Willing symmetric 1-hop neighbor:
      A symmetric 1-hop neighbor that has willingness not equal to
      WILL_NEVER.

   Multipoint relay (MPR):
      A router, X, is an MPR for a router, Y, if router Y has indicated
      its selection of router X as an MPR in a recent HELLO message.
      Router X may be a flooding MPR for Y if it is indicated to
      participate in the flooding process of messages received from
      router Y, or it may be a routing MPR for Y if it is indicated to
      declare link state information for the link from X to Y.  It may
      also be both at the same time.

   MPR selector:
      A router, Y, is a flooding/routing MPR selector of router X if
      router Y has selected router X as a flooding/routing MPR.

   MPR flooding:
      The optimized MANET-wide information distribution mechanism,
      employed by this protocol, in which a message is relayed by only a
      reduced subset of the routers in the network.  MPR flooding is the
      mechanism by which flooding reduction is achieved.

   EXPIRED:
      Indicates that a timer is set to a value clearly preceding the
      current time (e.g., current time - 1).

   This specification employs the same notational conventions as
   [RFC5444] and [RFC6130].





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3.  Applicability Statement

   This document specifies OLSRv2, a proactive routing protocol intended
   for use in Mobile Ad Hoc Networks (MANETs) [RFC2501].  The protocol's
   applicability is determined by its characteristics, which are that
   this protocol:

   o  Is designed to work in networks with a dynamic topology and in
      which messages may be lost, such as due to collisions over
      wireless media.

   o  Supports routers that each have one or more participating OLSRv2
      interfaces, which will consist of some or all of its MANET
      interfaces using [RFC6130].  The set of a router's OLSRv2
      interfaces, and the sets of its other MANET and non-MANET
      interfaces, may change over time.  Each interface may have one or
      more network addresses (which may have prefix lengths), and these
      may also be dynamically changing.

   o  Enables hop-by-hop routing, i.e., each router can use its local
      information provided by this protocol to route packets.

   o  Continuously maintains routes to all destinations in the network,
      i.e., routes are instantly available and data traffic is subject
      to no delays due to route discovery.  Consequently, no data
      traffic buffering is required.

   o  Supports routers that have non-OLSRv2 interfaces that may be local
      to a router or that can serve as gateways towards other networks.

   o  Enables the use of bidirectional additive link metrics to use
      shortest distance routes (i.e., routes with smallest total of link
      metrics).  Incoming link metric values are to be determined by a
      process outside this specification.

   o  Is optimized for large and dense networks; the larger and more
      dense a network, the more optimization can be achieved by using
      MPRs, compared to the classic link state algorithm [MPR].

   o  Uses [RFC5444] as described in its "Intended Usage" appendix and
      by [RFC5498].

   o  Allows "external" and "internal" extensibility (adding new Message
      Types and adding information to existing messages) as enabled by
      [RFC5444].

   o  Is designed to work in a completely distributed manner and does
      not depend on any central entity.



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4.  Protocol Overview and Functioning

   The objectives of this protocol are for each router to:

   o  Identify all destinations in the network.

   o  Identify a sufficient subset of links in the network, in order
      that shortest routes can be calculated to all available
      destinations.

   o  Provide a Routing Set containing these shortest routes from this
      router to all destinations (routable addresses and local links).

4.1.  Overview

   These objectives are achieved, for each router, by:

   o  Using NHDP [RFC6130] to identify symmetric 1-hop neighbors and
      symmetric 2-hop neighbors.

   o  Reporting its participation in OLSRv2, and its willingness to be a
      flooding MPR and to be a routing MPR, by extending the HELLO
      messages defined in [RFC6130] by the addition of an MPR_WILLING
      Message TLV.  The router's "flooding willingness" indicates how
      willing it is to participate in MPR flooding.  The router's
      "routing willingness" indicates how willing it is to be an
      intermediate router for routing.  Note that a router is still able
      to be a routing source or destination, even if unwilling to
      perform either function.

   o  Extending the HELLO messages defined in [RFC6130] to allow the
      addition of directional link metrics to advertised links with
      other routers participating in OLSRv2 and to indicate which link
      metric type is being used by those routers.  Both incoming and
      outgoing link metrics may be reported, the former determined by
      the advertising router.

   o  Selecting flooding MPRs and routing MPRs from among its willing
      symmetric 1-hop neighbors such that, for each set of MPRs, all
      symmetric 2-hop neighbors are reachable either directly or via at
      least one selected MPR, using a path of appropriate minimum total
      metric for at least routing MPR selection.  An analysis and
      examples of MPR selection algorithms are given in [MPR]; a
      suggested algorithm, appropriately adapted for each set of MPRs,
      is included in Appendix B of this specification.  Note that it is
      not necessary for routers to use the same algorithm in order to
      interoperate in the same MANET, but each such algorithm must have
      the appropriate properties, described in Section 18.



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   o  Signaling its flooding MPR and routing MPR selections, by
      extending the HELLO messages defined in [RFC6130] to report this
      information by the addition of MPR Address Block TLV(s) associated
      with the appropriate network addresses.

   o  Extracting its flooding MPR selectors and routing MPR selectors
      from received HELLO messages, using the included MPR Address Block
      TLV(s).

   o  Defining a TC (Topology Control) Message Type using the message
      format specified in [RFC5444].  TC messages are used to
      periodically signal links between routing MPR selectors and itself
      throughout the MANET.  This signaling includes suitable
      directional neighbor metrics (the best link metric in that
      direction between those routers).

   o  Allowing its TC messages, as well as HELLO messages, to be
      included in packets specified in [RFC5444], using the "manet" IP
      protocol or UDP port as specified in [RFC5498].

   o  Diffusing TC messages by using a flooding reduction mechanism,
      denoted "MPR flooding"; only the flooding MPRs of a router will
      retransmit messages received from (i.e., originated or last
      relayed by) that router.

   Note that the indicated extensions to [RFC6130] are of forms
   permitted by that specification.

   This specification defines:

   o  The requirement to use [RFC6130], its parameters, constants, HELLO
      messages, and Information Bases, each as extended in this
      specification.

   o  Two new Information Bases: the Topology Information Base and the
      Received Message Information Base.

   o  TC messages, which are used for MANET wide signaling (using MPR
      flooding) of selected topology (link state) information.

   o  A requirement for each router to have an originator address to be
      included in, or deducible from, HELLO messages and TC messages.

   o  The specification of new Message TLVs and Address Block TLVs that
      are used in HELLO messages and TC messages, including for
      reporting neighbor status, MPR selection, external gateways, link
      metrics, willingness to be an MPR, and content sequence numbers.
      Note that the generation of (incoming) link metric values is to be



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      undertaken by a process outside this specification; this
      specification concerns only the distribution and use of those
      metrics.

   o  The generation of TC messages from the appropriate information in
      the Information Bases.

   o  The updating of the Topology Information Base according to
      received TC messages.

   o  The MPR flooding mechanism, including the inclusion of message
      originator address and sequence number to manage duplicate
      messages, using information recorded in the Received Message
      Information Base.

   o  The response to other events, such as the expiration of
      information in the Information Bases.

   This protocol inherits the stability of a link state algorithm and
   has the advantage of having routes immediately available when needed,
   due to its proactive nature.

   This protocol only interacts with IP through routing table management
   and the use of the sending IP address for IP datagrams containing
   messages used by this specification.

4.2.  Routers and Interfaces

   In order for a router to participate in a MANET using this protocol,
   it must have at least one, and possibly more, OLSRv2 interfaces.
   Each OLSRv2 interface:

   o  Is a MANET interface, as specified in [RFC6130].  In particular,
      it must be configured with one or more network addresses; these
      addresses must each be specific to this router and must include
      any address that will be used as the sending address of any IP
      packet sent on this OLSRv2 interface.

   o  Has a number of interface parameters, adding to those specified in
      [RFC6130].

   o  Has an Interface Information Base, extending that specified in
      [RFC6130].

   o  Generates and processes HELLO messages according to [RFC6130],
      extended as specified in Section 15.





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   In addition to a set of OLSRv2 interfaces as described above, each
   router:

   o  May have one or more non-OLSRv2 interfaces (which may include
      MANET interfaces and/or non-MANET interfaces) and/or local
      attached networks for which this router can accept IP packets.
      All routable addresses for which the router is to accept IP
      packets must be used as an (OLSRv2 or non-OLSRv2) interface
      network address or as an address of a local attached network of
      the router.

   o  Has a number of router parameters, adding to those specified in
      [RFC6130].

   o  Has a Local Information Base, extending that specified in
      [RFC6130], including selection of an originator address and
      recording any locally attached networks.

   o  Has a Neighbor Information Base, extending that specified in
      [RFC6130] to record MPR selection and advertisement information.

   o  Has a Topology Information Base, recording information received in
      TC messages.

   o  Has a Received Message Information Base, recording information
      about received messages to ensure that each TC message is only
      processed once, and forwarded at most once on each OLSRv2
      interface, by a router.

   o  Generates, receives, and processes TC messages.

4.3.  Information Base Overview

   Each router maintains the Information Bases described in the
   following sections.  These are used for describing the protocol in
   this specification.  An implementation of this protocol may maintain
   this information in the indicated form or in any other organization
   that offers access to this information.  In particular, note that it
   is not necessary to remove Tuples from Sets at the exact time
   indicated, only to behave as if the Tuples were removed at that time.

4.3.1.  Local Information Base

   The Local Information Base is specified in [RFC6130] and contains a
   router's local configuration.  It is extended in this specification
   to also record an originator address and to include a router's:





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   o  Originator Set, containing addresses that were recently used as
      this router's originator address, that is used, together with the
      router's current originator address, to enable a router to
      recognize and discard control traffic that was originated by the
      router itself.

   o  Local Attached Network Set, containing network addresses of
      networks to which this router can act as a gateway, that it
      advertises in its TC messages.

4.3.2.  Interface Information Base

   The Interface Information Base for each OLSRv2 interface is as
   specified in [RFC6130], extended to also record, in each Link Set,
   link metric values (incoming and outgoing) and flooding MPR selector
   information.

4.3.3.  Neighbor Information Base

   The Neighbor Information Base is specified in [RFC6130] and is
   extended to also record, in the Neighbor Tuple for each neighbor:

   o  Its originator address.

   o  Neighbor metric values, these being the minimum of the link metric
      values in the indicated direction for all symmetric 1-hop links
      with that neighbor.

   o  Its willingness to be a flooding MPR and to be a routing MPR.

   o  Whether it has been selected by this router as a flooding MPR or
      as a routing MPR and whether it is a routing MPR selector of this
      router.  (Whether it is a flooding MPR selector of this neighbor
      is recorded in the Interface Information Base.)

   o  Whether it is to be advertised in TC messages sent by this router.

4.3.4.  Topology Information Base

   The Topology Information Base in each router contains:

   o  An Advertising Remote Router Set, recording each remote router
      from which TC messages have been received.  This is used in order
      to determine if a received TC message contains fresh or outdated
      information; a received TC message is ignored in the latter case.

   o  A Router Topology Set, recording links between routers in the
      MANET, as described by received TC messages.



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   o  A Routable Address Topology Set, recording routable addresses in
      the MANET (available as IP packet destinations) and from which
      remote router these routable addresses can be directly reached
      (i.e., in a single IP hop from that remote router), as reported by
      received TC messages.

   o  An Attached Network Set, recording networks to which a remote
      router has advertised that it may act as a gateway.  These
      networks may be reached in one or more IP hops from that remote
      router.

   o  A Routing Set, recording routes from this router to all available
      destinations.  The IP routing table is to be updated using this
      Routing Set.  (A router may choose to use any or all destination
      network addresses in the Routing Set to update the IP routing
      table.  This selection is outside the scope of this
      specification.)

   The purpose of the Topology Information Base is to record information
   used, in addition to that in the Local Information Base, the
   Interface Information Bases, and the Neighbor Information Base, to
   construct the Routing Set (which is also included in the Topology
   Information Base).

   This specification describes the calculation of the Routing Set based
   on a Topology Graph constructed in two phases.  First, a "backbone"
   graph representing the routers in the MANET, and the connectivity
   between them, is constructed from the Local Information Base, the
   Neighbor Information Base, and the Router Topology Set.  Second, this
   graph is "decorated" with additional destination network addresses
   using the Local Information Base, the Routable Address Topology Set,
   and the Attached Network Set.

   The Topology Graph does not need to be recorded in the Topology
   Information Base; it can either be constructed as required when the
   Routing Set is to be changed or need not be explicitly constructed
   (as illustrated in Appendix C).  An implementation may, however,
   construct and retain the Topology Graph if preferred.













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4.3.5.  Received Message Information Base

   The Received Message Information Base in each router contains:

   o  A Received Set for each OLSRv2 interface, describing TC messages
      received by this router on that OLSRv2 interface.

   o  A Processed Set, describing TC messages processed by this router.

   o  A Forwarded Set, describing TC messages forwarded by this router.

   The Received Message Information Base serves the MPR flooding
   mechanism by ensuring that received messages are forwarded at most
   once by a router and also ensures that received messages are
   processed exactly once by a router.  The Received Message Information
   Base may also record information about other Message Types that use
   the MPR flooding mechanism.

4.4.  Signaling Overview

   This protocol generates and processes HELLO messages according to
   [RFC6130].  HELLO messages transmitted on OLSRv2 interfaces are
   extended according to Section 15 of this specification to include an
   originator address, link metrics, and MPR selection information.

   This specification defines a single Message Type, the TC message.  TC
   messages are sent by their originating router proactively, at a
   regular interval, on all OLSRv2 interfaces.  This interval may be
   fixed or dynamic, for example, it may be backed off due to congestion
   or network stability.  TC messages may also be sent as a response to
   a change in the router itself, or its advertised symmetric 1-hop
   neighborhood, for example, on first being selected as a routing MPR.

   Because TC messages are sent periodically, this protocol is tolerant
   of unreliable transmissions of TC messages.  Message losses may occur
   more frequently in wireless networks due to collisions or other
   transmission problems.  This protocol may use "jitter", randomized
   adjustments to message transmission times, to reduce the incidence of
   collisions, as specified in [RFC5148].

   This protocol is tolerant of out-of-sequence delivery of TC messages
   due to in-transit message reordering.  Each router maintains an
   Advertised Neighbor Sequence Number (ANSN) that is incremented when
   its recorded neighbor information that is to be included in its TC
   messages changes.  This ANSN is included in the router's TC messages.
   The recipient of a TC message can use this included ANSN to identify
   which of the information it has received is most recent, even if




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   messages have been reordered while in transit.  Only the most recent
   information received is used; older information received later is
   discarded.

   TC messages may be "complete" or "incomplete".  A complete TC message
   advertises all of the originating router's routing MPR selectors; it
   may also advertise other symmetric 1-hop neighbors.  Complete TC
   messages are generated periodically (and also, optionally, in
   response to symmetric 1-hop neighborhood changes).  Incomplete TC
   messages may be used to report additions to advertised information,
   without repeating unchanged information.

   TC messages, and HELLO messages as extended by this specification,
   define (by inclusion or by deduction when having a single address) an
   originator address for the router that created the message.  A TC
   message reports both the originator addresses and routable addresses
   of its advertised neighbors, distinguishing the two using an Address
   Block TLV (an address may be both routable and an originator
   address).  TC messages also report the originator's locally attached
   networks.

   TC messages are MPR flooded throughout the MANET.  A router
   retransmits a TC message received on an OLSRv2 interface if and only
   if the message did not originate at this router and has not been
   previously forwarded by this router, this is the first time the
   message has been received on this OLSRv2 interface, and the message
   is received from (i.e., originated from or was last relayed by) one
   of this router's flooding MPR selectors.

   Some TC messages may be MPR flooded over only part of the network,
   e.g., allowing a router to ensure that nearer routers are kept more
   up to date than distant routers, such as is used in Fisheye State
   Routing [FSR] and Fuzzy Sighted Link State routing [FSLS].  This is
   enabled using [RFC5497].

   TC messages include outgoing neighbor metrics that will be used in
   the selection of routes.

4.5.  Link Metrics

   OLSRv1 [RFC3626] created minimum hop routes to destinations.
   However, in many, if not most, circumstances, better routes (in terms
   of quality of service for end users) can be created by use of link
   metrics.







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   OLSRv2, as defined in this specification, supports metric-based
   routing, i.e., it allows links to each have a chosen metric.  Link
   metrics as defined in OLSRv2 are additive, and the routes that are to
   be created are those with the minimum sum of the link metrics along
   that route.

   Link metrics are defined to be directional; the link metric from one
   router to another may be different from that on the reverse link.
   The link metric is assessed at the receiver, as on a (typically)
   wireless link, that is the better informed as to link information.
   Both incoming and outgoing link information is used by OLSRv2; the
   distinctions in this specification must be clearly followed.

   This specification also defines both incoming and outgoing neighbor
   metrics for each symmetric 1-hop neighbor, these being the minimum
   value of the link metrics in the same direction for all symmetric
   links with that neighbor.  Note that this means that all neighbor
   metric values are link metric values and that specification of, for
   example, link metric value encoding also includes encoding of
   neighbor metric values.

   This specification does not define the nature of the link metric.
   However, this specification allows, through use of the type extension
   of a defined Address Block TLV, for link metrics with specific
   meanings to be defined and either allocated by IANA or privately
   used.  Each HELLO or TC message carrying link (or neighbor) metrics
   thus indicates which link metric information it is carrying, allowing
   routers to determine if they can interoperate.  If link metrics
   require additional signaling to determine their values, whether in
   HELLO messages or otherwise, then this is permitted but is outside
   the scope of this specification.

   Careful consideration should be given to how to use link metrics.  In
   particular, it is advisable to not simply default to use of all links
   with equal metrics (i.e., hop count) for routing without careful
   consideration of whether that is appropriate or not.

4.6.  Flooding MPRs and Routing MPR

   This specification uses two sets of MPRs: flooding MPRs and routing
   MPRs.  These are selected separately, because:

   o  Flooding MPRs may use metrics; routing MPRs must use metrics.

   o  When flooding MPRs use metrics, these are outgoing link metrics;
      routing MPRs use incoming neighbor metrics.





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   o  Flooding MPRs must be selected per OLSRv2 interface; routing MPRs
      need not be selected per OLSRv2 interface.

4.7.  Routing Set Use

   The purpose of the Routing Set is to determine and record routes
   (local interface network address and next-hop interface network
   address) to all possible routable addresses advertised by this
   protocol as well as all destinations that are local, i.e., within one
   hop, to the router (whether using routable addresses or not).  Only
   symmetric links are used in such routes.

   It is intended that the Routing Set can be used for IP packet
   routing, by using its contents to update the IP routing table.  That
   update, and whether any Routing Tuples are not used when updating the
   IP routing table, is outside the scope of this specification.

   The signaling in this specification has been designed so that a
   "backbone" Topology Graph of routers, each identified by its
   originator address, with at most one direct connection between any
   pair of routers, can be constructed (from the Neighbor Set and the
   Router Topology Set) using a suitable minimum path length algorithm.
   This Topology Graph can then have other network addresses (routable
   or of symmetric 1-hop neighbors) added to it (using the Interface
   Information Bases, the Routable Address Topology Set, and the
   Attached Network Set).

5.  Protocol Parameters and Constants

   The parameters and constants used in this specification are those
   defined in [RFC6130] plus those defined in this section.  The
   separation in [RFC6130] into interface parameters, router parameters,
   and constants is also used in this specification.

   Similarly to the parameters in [RFC6130], parameters defined in this
   specification MAY be changed dynamically by a router and need not be
   the same on different routers, even in the same MANET, or, for
   interface parameters, on different interfaces of the same router.

5.1.  Protocol and Port Numbers

   This protocol specifies TC messages, which are included in packets as
   defined by [RFC5444].  These packets MUST be sent either using the
   "manet" protocol number or the "manet" UDP well-known port number, as
   specified in [RFC5498].






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   TC messages and HELLO messages [RFC6130] MUST, in a given MANET,
   either both use IP or both use UDP, in order for it to be possible to
   combine messages of both protocols into the same [RFC5444] packet for
   transmission.

5.2.  Multicast Address

   This protocol specifies TC messages, which are included in packets as
   defined by [RFC5444].  These packets MAY be transmitted using the
   Link-Local multicast address "LL-MANET-Routers", as specified in
   [RFC5498].

5.3.  Interface Parameters

   A single additional interface parameter is specified for OLSRv2
   interfaces only.

5.3.1.  Received Message Validity Time

   The following parameter manages the validity time of recorded
   received message information:

   RX_HOLD_TIME:
      The period after receipt of a message by the appropriate OLSRv2
      interface of this router for which that information is recorded,
      in order that the message is recognized as having been previously
      received on this OLSRv2 interface.

   The following constraints apply to this parameter:

   o  RX_HOLD_TIME > 0

   o  RX_HOLD_TIME SHOULD be greater than the maximum difference in time
      that a message may take to traverse the MANET, taking into account
      any message forwarding jitter as well as propagation, queuing, and
      processing delays.

5.4.  Router Parameters

   The following router parameters are specified for routers.

5.4.1.  Local History Times

   The following router parameter manages the time for which local
   information is retained:






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   O_HOLD_TIME:
      The time for which a recently used and replaced originator address
      is used to recognize the router's own messages.

   The following constraint applies to this parameter:

   o  O_HOLD_TIME > 0

5.4.2.  Link Metric Parameters

   All routes found using this specification use a single link metric
   type that is specified by the router parameter LINK_METRIC_TYPE,
   which may take any value from 0 to 255, both inclusive.

5.4.3.  Message Intervals

   The following parameters regulate TC message transmissions by a
   router.  TC messages are usually sent periodically but MAY also be
   sent in response to changes in the router's Neighbor Set and/or Local
   Attached Network Set.  In a highly dynamic network, and with a larger
   value of the parameter TC_INTERVAL and a smaller value of the
   parameter TC_MIN_INTERVAL, TC messages MAY be transmitted more often
   in response to changes than periodically.  However, because a router
   has no knowledge of, for example, routers remote to it (i.e., beyond
   two hops away) joining the network, TC messages MUST NOT be sent
   purely responsively.

   TC_INTERVAL:
      The maximum time between the transmission of two successive TC
      messages by this router.  When no TC messages are sent in response
      to local network changes (by design or because the local network
      is not changing), then TC messages MUST be sent at a regular
      interval TC_INTERVAL, possibly modified by jitter, as specified in
      [RFC5148].

   TC_MIN_INTERVAL:
      The minimum interval between transmission of two successive TC
      messages by this router.  (This minimum interval MAY be modified
      by jitter, as specified in [RFC5148].)

   The following constraints apply to these parameters:

   o  TC_INTERVAL > 0

   o  0 <= TC_MIN_INTERVAL <= TC_INTERVAL






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   o  If TLVs with Type = INTERVAL_TIME, as defined in [RFC5497], are
      included in TC messages, then TC_INTERVAL MUST be representable by
      way of the exponent-mantissa notation described in Section 5 of
      [RFC5497].

5.4.4.  Advertised Information Validity Times

   The following parameters manage the validity time of information
   advertised in TC messages:

   T_HOLD_TIME:
      Used as the minimum value in the TLV with Type = VALIDITY_TIME
      included in all TC messages sent by this router.  If a single
      value of parameter TC_HOP_LIMIT (see Section 5.4.7) is used, then
      this will be the only value in that TLV.

   A_HOLD_TIME:
      The period during which TC messages are sent after they no longer
      have any advertised information to report but are sent in order to
      accelerate outdated information removal by other routers.

   The following constraints apply to these parameters:

   o  T_HOLD_TIME > 0

   o  A_HOLD_TIME >= 0

   o  T_HOLD_TIME >= TC_INTERVAL

   o  If TC messages can be lost, then both T_HOLD_TIME and A_HOLD_TIME
      SHOULD be significantly greater than TC_INTERVAL; a value >= 3 x
      TC_INTERVAL is RECOMMENDED.

   o  T_HOLD_TIME MUST be representable by way of the exponent-mantissa
      notation described in Section 5 of [RFC5497].

5.4.5.  Processing and Forwarding Validity Times

   The following parameters manage the processing and forwarding
   validity time of recorded message information:

   P_HOLD_TIME:
      The period after receipt of a message that is processed by this
      router for which that information is recorded, in order that the
      message is not processed again if received again.






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   F_HOLD_TIME:
      The period after receipt of a message that is forwarded by this
      router for which that information is recorded, in order that the
      message is not forwarded again if received again.

   The following constraints apply to these parameters:

   o  P_HOLD_TIME > 0

   o  F_HOLD_TIME > 0

   o  Both of these parameters SHOULD be greater than the maximum
      difference in time that a message may take to traverse the MANET,
      taking into account any message forwarding jitter as well as
      propagation, queuing, and processing delays.

5.4.6.  Jitter

   If jitter, as defined in [RFC5148], is used, then the governing
   jitter parameters are as follows:

   TP_MAXJITTER:
      Represents the value of MAXJITTER used in [RFC5148] for
      periodically generated TC messages sent by this router.

   TT_MAXJITTER:
      Represents the value of MAXJITTER used in [RFC5148] for externally
      triggered TC messages sent by this router.

   F_MAXJITTER:
      Represents the default value of MAXJITTER used in [RFC5148] for
      messages forwarded by this router.  However, before using
      F_MAXJITTER, a router MAY attempt to deduce a more appropriate
      value of MAXJITTER, for example, based on any TLVs with Type =
      INTERVAL_TIME or Type = VALIDITY_TIME contained in the message to
      be forwarded.

   For constraints on these parameters, see [RFC5148].

5.4.7.  Hop Limit

   The parameter TC_HOP_LIMIT is the hop limit set in each TC message.
   TC_HOP_LIMIT MAY be a single fixed value or MAY be different in TC
   messages sent by the same router.  However, each other router, at any
   hop count distance, MUST see a regular pattern of TC messages in
   order that meaningful values of TLVs with Type = INTERVAL_TIME and
   Type = VALIDITY_TIME at each hop count distance can be included as
   defined in [RFC5497].  Thus, the pattern of TC_HOP_LIMIT MUST be



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   defined to have this property.  For example, the repeating pattern
   (255 4 4) satisfies this property (having period TC_INTERVAL at hop
   counts up to 4, inclusive, and 3 x TC_INTERVAL at hop counts greater
   than 4), but the repeating pattern (255 255 4 4) does not satisfy
   this property because at hop counts greater than 4, message intervals
   are alternately TC_INTERVAL and 3 x TC_INTERVAL.

   The following constraints apply to this parameter:

   o  The maximum value of TC_HOP_LIMIT >= the network diameter in hops;
      a value of 255 is RECOMMENDED.  Note that if using a pattern of
      different values of TC_HOP_LIMIT as described above, then only the
      maximum value in the pattern is so constrained.

   o  All values of TC_HOP_LIMIT >= 2.

5.4.8.  Willingness

   Each router has two willingness parameters: WILL_FLOODING and
   WILL_ROUTING, each of which MUST be in the range WILL_NEVER to
   WILL_ALWAYS, inclusive.

   WILL_FLOODING represents the router's willingness to be selected as a
   flooding MPR and hence to participate in MPR flooding, in particular
   of TC messages.

   WILL_ROUTING represents the router's willingness to be selected as a
   routing MPR and hence to be an intermediate router on routes.

   In either case, the higher the value, the greater the router's
   willingness to be a flooding or routing MPR, as appropriate.  If a
   router has a willingness value of WILL_NEVER (the lowest possible
   value), it does not perform the corresponding task.  A MANET using
   this protocol with too many routers having either of the willingness
   parameters WILL_FLOODING or WILL_ROUTING equal to WILL_NEVER will not
   function; it MUST be ensured, by administrative or other means, that
   this does not happen.

   Note that the proportion at which the routers having a willingness
   value equal to WILL_NEVER is "too many" depends on the network
   topology -- which, in a MANET, may change dynamically.  Willingness
   is intended to enable that certain routers (e.g., routers that have
   generous resources, such as a permanent power supply) can be
   configured to assume more of the network operation, while others
   (e.g., routers that have lesser resources, such as are battery
   operated) can avoid such tasks.  A general guideline would be that





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   only if a router is not actually able to assume the task (flooding or
   routing) should it be configured with the corresponding willingness
   WILL_NEVER.

   If a router has a willingness value equal to WILL_ALWAYS (the highest
   possible value), then it will always be selected as a flooding or
   routing MPR, as appropriate, by all symmetric 1-hop neighbors.

   In a MANET in which all routers have WILL_FLOODING = WILL_ALWAYS,
   flooding reduction will effectively be disabled, and flooding will
   perform as blind flooding.

   In a MANET in which all routers have WILL_ROUTING = WILL_ALWAYS,
   topology reduction will effectively be disabled, and all routers will
   advertise all of their links in TC messages.

   A router that has WILL_ROUTING = WILL_NEVER will not act as an
   intermediate router in the MANET.  Such a router can act as a source,
   destination, or gateway to another routing domain.

   Different routers MAY have different values for WILL_FLOODING and/or
   WILL_ROUTING.

   The following constraints apply to these parameters:

   o  WILL_NEVER <= WILL_FLOODING <= WILL_ALWAYS

   o  WILL_NEVER <= WILL_ROUTING <= WILL_ALWAYS

5.5.  Parameter Change Constraints

   If protocol parameters are changed dynamically, then the constraints
   in this section apply.

   RX_HOLD_TIME

      *  If RX_HOLD_TIME for an OLSRv2 interface changes, then the
         expiry time for all Received Tuples for that OLSRv2 interface
         MAY be changed.

   O_HOLD_TIME

      *  If O_HOLD_TIME changes, then the expiry time for all Originator
         Tuples MAY be changed.







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   TC_INTERVAL

      *  If TC_INTERVAL increases, then the next TC message generated by
         this router MUST be generated according to the previous,
         shorter TC_INTERVAL.  Additional subsequent TC messages MAY be
         generated according to the previous, shorter, TC_INTERVAL.

      *  If TC_INTERVAL decreases, then the following TC messages from
         this router MUST be generated according to the current,
         shorter, TC_INTERVAL.

   P_HOLD_TIME

      *  If P_HOLD_TIME changes, then the expiry time for all Processed
         Tuples MAY be changed.

   F_HOLD_TIME

      *  If F_HOLD_TIME changes, then the expiry time for all Forwarded
         Tuples MAY be changed.

   TP_MAXJITTER

      *  If TP_MAXJITTER changes, then the periodic TC message schedule
         on this router MAY be changed immediately.

   TT_MAXJITTER

      *  If TT_MAXJITTER changes, then externally triggered TC messages
         on this router MAY be rescheduled.

   F_MAXJITTER

      *  If F_MAXJITTER changes, then TC messages waiting to be
         forwarded with a delay based on this parameter MAY be
         rescheduled.

   TC_HOP_LIMIT

      *  If TC_HOP_LIMIT changes, and the router uses multiple values
         after the change, then message intervals and validity times
         included in TC messages MUST be respected.  The simplest way to
         do this is to start any new repeating pattern of TC_HOP_LIMIT
         values with its largest value.







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   LINK_METRIC_TYPE

      *  If LINK_METRIC_TYPE changes, then all link metric information
         recorded by the router is invalid.  The router MUST take the
         following actions and all consequent actions described in
         Section 17 and [RFC6130].

         +  For each Link Tuple in any Link Set for an OLSRv2 interface,
            either update L_in_metric (the value MAXIMUM_METRIC MAY be
            used) or remove the Link Tuple from the Link Set.

         +  For each Link Tuple that is not removed, set:

            -  L_out_metric := UNKNOWN_METRIC;

            -  L_SYM_time := EXPIRED;

            -  L_MPR_selector := false.

         +  Remove all Router Topology Tuples, Routable Address Topology
            Tuples, Attached Network Tuples, and Routing Tuples from
            their respective Protocol Sets in the Topology Information
            Base.

5.6.  Constants

   The following constants are specified for routers.  Unlike router
   parameters, constants MUST NOT change and MUST be the same on all
   routers.

5.6.1.  Link Metric Constants

   The constant minimum and maximum link metric values are defined by:

   o  MINIMUM_METRIC := 1

   o  MAXIMUM_METRIC := 16776960

   The symbolic value UNKNOWN_METRIC is defined in Section 6.1.












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5.6.2.  Willingness Constants

   The constant minimum, RECOMMENDED default, and maximum willingness
   values are defined by:

   o  WILL_NEVER := 0

   o  WILL_DEFAULT := 7

   o  WILL_ALWAYS := 15

5.6.3.  Time Constant

   The constant C (time granularity) is used as specified in [RFC5497].
   It MUST be the same as is used by [RFC6130], with RECOMMENDED value:

   o  C := 1/1024 second

   Note that this constant is used in the representation of time
   intervals.  Time values (such as are stored in Protocol Tuples) are
   not so represented.  A resolution of C in such values is sufficient
   (but not necessary) for such values.

6.  Link Metric Values

   A router records a link metric value for each direction of a link of
   which it has knowledge.  These link metric values are used to create
   metrics for routes by the addition of link metric values.

6.1.  Link Metric Representation

   Link metrics are reported in messages using a compressed
   representation that occupies 12 bits, consisting of a 4-bit field and
   an 8-bit field.  The compressed representation represents positive
   integer values with a minimum value of 1 and a maximum value that is
   slightly smaller than the maximum 24-bit value.  Only those values
   that have exact representation in the compressed form are used.
   Route metrics are the summation of no more than 256 link metric
   values and can therefore be represented using no more than 32 bits.

   Link and route metrics used in the Information Bases defined in this
   specification refer to the uncompressed values, and arithmetic
   involving them does likewise and assumes full precision in the
   result.  (How an implementation records the values is not part of
   this specification, as long as it behaves as if recording
   uncompressed values.  An implementation can, for example, use 32-bit
   values for all link and route metrics.)




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   In some cases, a link metric value may be unknown.  This is indicated
   in this specification by the symbolic value UNKNOWN_METRIC.  An
   implementation may use any representation of UNKNOWN_METRIC as it is
   never included in messages or used in any computation.  (Possible
   representations are zero or any value greater than the maximum
   representable metric value.)

6.2.  Link Metric Compressed Form

   The 12-bit compressed form of a link metric uses a modified form of a
   representation with an 8-bit mantissa (denoted a) and a 4-bit
   exponent (denoted b).  Note that if represented as the 12-bit value
   256b+a, then the ordering of those 12-bit values is identical to the
   ordering of the represented values.

   The value so represented is (257+a)2^b - 256, where ^ denotes
   exponentiation.  This has a minimum value (when a = 0 and b = 0) of
   MINIMUM_METRIC = 1 and a maximum value (when a = 255 and b = 15) of
   MAXIMUM_METRIC = 2^24 - 256.

   An algorithm for computing a and b for the smallest representable
   value not less than a link metric value v such that MINIMUM_METRIC <=
   v <= MAXIMUM_METRIC is:

   1.  Find the smallest integer b such that v + 256 <= 2^(b + 9).

   2.  Set a := (v - 256(2^b - 1)) / (2^b) - 1, rounded up to the
       nearest integer.

7.  Local Information Base

   The Local Information Base, as defined for each router in [RFC6130],
   is extended by this protocol by:

   o  Recording the router's originator address.  The originator address
      MUST be unique to this router.  It MUST NOT be used by any other
      router as an originator address.  It MAY be included in any
      network address in any I_local_iface_addr_list of this router; it
      MUST NOT be included in any network address in any
      I_local_iface_addr_list of any other router.  It MAY be included
      in, but MUST NOT be equal to, the AL_net_addr in any Local
      Attached Network Tuple in this or any other router.

   o  The addition of an Originator Set, defined in Section 7.1, and a
      Local Attached Network Set, defined in Section 7.2.






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   All routable addresses of the router for which it is to accept IP
   packets as destination MUST be included in the Local Interface Set or
   the Local Attached Network Set.

7.1.  Originator Set

   A router's Originator Set records addresses that were recently used
   as originator addresses by this router.  If a router's originator
   address is immutable, then the Originator Set is always empty and MAY
   be omitted.  It consists of Originator Tuples:

      (O_orig_addr, O_time)

   where:

      O_orig_addr is a recently used originator address; note that this
      does not include a prefix length.

      O_time specifies the time at which this Tuple expires and MUST be
      removed.

7.2.  Local Attached Network Set

   A router's Local Attached Network Set records its local non-OLSRv2
   interfaces via which it can act as a gateway to other networks.  The
   Local Attached Network Set MUST be provided to this protocol and MUST
   reflect any changes in the router's status.  (In cases where the
   router's configuration is static, the Local Attached Network Set will
   be constant; in cases where the router has no such non-OLSRv2
   interfaces, the Local Attached Network Set will be empty.)  The Local
   Attached Network Set is not modified by this protocol.  This protocol
   will respond to (externally provided) changes to the Local Attached
   Network Set.  It consists of Local Attached Network Tuples:

      (AL_net_addr, AL_dist, AL_metric)

   where:

      AL_net_addr is the network address of an attached network that can
      be reached via this router.  This SHOULD be a routable address.
      It is constrained as described below.

      AL_dist is the number of hops to the network with network address
      AL_net_addr from this router.

      AL_metric is the metric of the link to the attached network with
      address AL_net_addr from this router.




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   Attached networks local to this router only (i.e., not reachable
   except via this router) SHOULD be treated as local non-MANET
   interfaces and added to the Local Interface Set, as specified in
   [RFC6130], rather than added to the Local Attached Network Set.

   Because an attached network is not specific to the router and may be
   outside the MANET, an attached network MAY also be attached to other
   routers.  Routing to an AL_net_addr will use maximum prefix length
   matching; consequently, an AL_net_addr MAY include, but MUST NOT
   equal or be included in, any network address that is of any interface
   of any router (i.e., is included in any I_local_iface_addr_list) or
   equal any router's originator address.

   It is not the responsibility of this protocol to maintain routes from
   this router to networks recorded in the Local Attached Network Set.

   Local Attached Network Tuples are removed from the Local Attached
   Network Set only when the router's local attached network
   configuration changes, i.e., they are not subject to timer-based
   expiration or changes due to received messages.

8.  Interface Information Base

   An Interface Information Base, as defined in [RFC6130], is maintained
   for each MANET interface.  The Link Set and 2-Hop Set in the
   Interface Information Base for an OLSRv2 interface are modified by
   this protocol.  In some cases, it may be convenient to consider these
   Sets as also containing these additional elements for other MANET
   interfaces, taking the indicated values on creation but never being
   updated.

8.1.  Link Set

   The Link Set is modified by adding these additional elements to each
   Link Tuple:

      L_in_metric is the metric of the link from the OLSRv2 interface
      with addresses L_neighbor_iface_addr_list to this OLSRv2
      interface;

      L_out_metric is the metric of the link to the OLSRv2 interface
      with addresses L_neighbor_iface_addr_list from this OLSRv2
      interface;

      L_mpr_selector is a boolean flag, describing if this neighbor has
      selected this router as a flooding MPR, i.e., is a flooding MPR
      selector of this router.




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   L_in_metric will be specified by a process that is external to this
   specification.  Any Link Tuple with L_status = HEARD or L_status =
   SYMMETRIC MUST have a specified value of L_in_metric if it is to be
   used by this protocol.

   A Link Tuple created (but not updated) by [RFC6130] MUST set:

   o  L_in_metric := UNKNOWN_METRIC;

   o  L_out_metric := UNKNOWN_METRIC;

   o  L_mpr_selector := false.

8.2.  2-Hop Set

   The 2-Hop Set is modified by adding these additional elements to each
   2-Hop Tuple:

      N2_in_metric is the neighbor metric from the router with address
      N2_2hop_iface_addr to the router with OLSRv2 interface addresses
      N2_neighbor_iface_addr_list;

      N2_out_metric is the neighbor metric to the router with address
      N2_2hop_iface_addr from the router with OLSRv2 interface addresses
      N2_neighbor_iface_addr_list.

   A 2-Hop Tuple created (but not updated) by [RFC6130] MUST set:

   o  N2_in_metric := UNKNOWN_METRIC;

   o  N2_out_metric := UNKNOWN_METRIC.

9.  Neighbor Information Base

   A Neighbor Information Base, as defined in [RFC6130], is maintained
   for each router.  It is modified by this protocol by adding these
   additional elements to each Neighbor Tuple in the Neighbor Set.  In
   some cases, it may be convenient to consider these Sets as also
   containing these additional elements for other MANET interfaces,
   taking the indicated values on creation but never being updated.

      N_orig_addr is the neighbor's originator address, which may be
      unknown.  Note that this originator address does not include a
      prefix length;







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      N_in_metric is the neighbor metric of any link from this neighbor
      to an OLSRv2 interface of this router, i.e., the minimum of all
      corresponding L_in_metric with L_status = SYMMETRIC and
      L_in_metric != UNKNOWN_METRIC, UNKNOWN_METRIC if there are no such
      Link Tuples;

      N_out_metric is the neighbor metric of any link from an OLSRv2
      interface of this router to this neighbor, i.e., the minimum of
      all corresponding L_out_metric with L_status = SYMMETRIC and
      L_out_metric != UNKNOWN_METRIC, UNKNOWN_METRIC if there are no
      such Link Tuples;

      N_will_flooding is the neighbor's willingness to be selected as a
      flooding MPR, in the range from WILL_NEVER to WILL_ALWAYS, both
      inclusive, taking the value WILL_NEVER if no OLSRv2-specific
      information is received from this neighbor;

      N_will_routing is the neighbor's willingness to be selected as a
      routing MPR, in the range from WILL_NEVER to WILL_ALWAYS, both
      inclusive, taking the value WILL_NEVER if no OLSRv2-specific
      information is received from this neighbor;

      N_flooding_mpr is a boolean flag, describing if this neighbor is
      selected as a flooding MPR by this router;

      N_routing_mpr is a boolean flag, describing if this neighbor is
      selected as a routing MPR by this router;

      N_mpr_selector is a boolean flag, describing if this neighbor has
      selected this router as a routing MPR, i.e., is a routing MPR
      selector of this router.

      N_advertised is a boolean flag, describing if this router has
      elected to advertise a link to this neighbor in its TC messages.

   A Neighbor Tuple created (but not updated) by [RFC6130] MUST set:

   o  N_orig_addr := unknown;

   o  N_in_metric := UNKNOWN_METRIC;

   o  N_out_metric := UNKNOWN_METRIC;

   o  N_will_flooding := WILL_NEVER;

   o  N_will_routing := WILL_NEVER;

   o  N_routing_mpr := false;



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   o  N_flooding_mpr := false;

   o  N_mpr_selector := false;

   o  N_advertised := false.

   The Neighbor Information Base also includes a variable, the
   Advertised Neighbor Sequence Number (ANSN), whose value is included
   in TC messages to indicate the freshness of the information
   transmitted.  The ANSN is incremented whenever advertised information
   (the originator and routable addresses included in Neighbor Tuples
   with N_advertised = true and local attached networks recorded in the
   Local Attached Network Set in the Local Information Base) changes,
   including addition or removal of such information.

10.  Topology Information Base

   The Topology Information Base, defined for each router by this
   specification, stores information received in TC messages in the
   Advertising Remote Router Set, the Router Topology Set, the Routable
   Address Topology Set, and the Attached Network Set.

   Additionally, a Routing Set is maintained, derived from the
   information recorded in the Local Information Base, the Interface
   Information Bases, the Neighbor Information Base, and the rest of the
   Topology Information Base.

10.1.  Advertising Remote Router Set

   A router's Advertising Remote Router Set records information
   describing each remote router in the network that transmits TC
   messages, allowing outdated TC messages to be recognized and
   discarded.  It consists of Advertising Remote Router Tuples:

      (AR_orig_addr, AR_seq_number, AR_time)

   where:

      AR_orig_addr is the originator address of a received TC message,
      note that this does not include a prefix length;

      AR_seq_number is the greatest ANSN in any TC message received that
      originated from the router with originator address AR_orig_addr
      (i.e., that contributed to the information contained in this
      Tuple);

      AR_time is the time at which this Tuple expires and MUST be
      removed.



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10.2.  Router Topology Set

   A router's Topology Set records topology information about the links
   between routers in the MANET.  It consists of Router Topology Tuples:

      (TR_from_orig_addr, TR_to_orig_addr, TR_seq_number, TR_metric,
       TR_time)

   where:

      TR_from_orig_addr is the originator address of a router that can
      reach the router with originator address TR_to_orig_addr in one
      hop (note that this does not include a prefix length);

      TR_to_orig_addr is the originator address of a router that can be
      reached by the router with originator address TR_from_orig_addr in
      one hop (note that this does not include a prefix length);

      TR_seq_number is the greatest ANSN in any TC message received that
      originated from the router with originator address
      TR_from_orig_addr (i.e., that contributed to the information
      contained in this Tuple);

      TR_metric is the neighbor metric from the router with originator
      address TR_from_orig_addr to the router with originator address
      TR_to_orig_addr;

      TR_time specifies the time at which this Tuple expires and MUST be
      removed.

10.3.  Routable Address Topology Set

   A router's Routable Address Topology Set records topology information
   about the routable addresses within the MANET, including via which
   routers they may be reached.  It consists of Routable Address
   Topology Tuples:

      (TA_from_orig_addr, TA_dest_addr, TA_seq_number, TA_metric,
       TA_time)

   where:

      TA_from_orig_addr is the originator address of a router that can
      reach the router with routable address TA_dest_addr in one hop
      (note that this does not include a prefix length);






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      TA_dest_addr is a routable address of a router that can be reached
      by the router with originator address TA_from_orig_addr in one
      hop;

      TA_seq_number is the greatest ANSN in any TC message received that
      originated from the router with originator address
      TA_from_orig_addr (i.e., that contributed to the information
      contained in this Tuple);

      TA_metric is the neighbor metric from the router with originator
      address TA_from_orig_addr to the router with OLSRv2 interface
      address TA_dest_addr;

      TA_time specifies the time at which this Tuple expires and MUST be
      removed.

10.4.  Attached Network Set

   A router's Attached Network Set records information about networks
   (which may be outside the MANET) attached to other routers and their
   routable addresses.  It consists of Attached Network Tuples:

      (AN_orig_addr, AN_net_addr, AN_seq_number, AN_dist, AN_metric,
       AN_time)

   where:

      AN_orig_addr is the originator address of a router that can act as
      gateway to the network with network address AN_net_addr (note that
      this does not include a prefix length);

      AN_net_addr is the network address of an attached network that may
      be reached via the router with originator address AN_orig_addr;

      AN_seq_number is the greatest ANSN in any TC message received that
      originated from the router with originator address AN_orig_addr
      (i.e., that contributed to the information contained in this
      Tuple);

      AN_dist is the number of hops to the network with network address
      AN_net_addr from the router with originator address AN_orig_addr;

      AN_metric is the metric of the link from the router with
      originator address AN_orig_addr to the attached network with
      address AN_net_addr;

      AN_time specifies the time at which this Tuple expires and MUST be
      removed.



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10.5.  Routing Set

   A router's Routing Set records the first hop along a selected path to
   each destination for which any such path is known.  It consists of
   Routing Tuples:

      (R_dest_addr, R_next_iface_addr, R_local_iface_addr, R_dist,
       R_metric)

   where:

      R_dest_addr is the network address of the destination, either the
      network address of an interface of a destination router or the
      network address of an attached network;

      R_next_iface_addr is the network address of the "next hop" on the
      selected path to the destination;

      R_local_iface_addr is an address of the local interface over which
      an IP packet MUST be sent to reach the destination by the selected
      path.

      R_dist is the number of hops on the selected path to the
      destination;

      R_metric is the metric of the route to the destination with
      address R_dest_addr.

   The Routing Set for a router is derived from the contents of other
   Protocol Sets of the router (the Link Sets, the Neighbor Set, the
   Router Topology Set, the Routable Address Topology Set, the Attached
   Network Set, and OPTIONAL use of the 2-Hop Sets).  The Routing Set is
   updated (Routing Tuples added or removed, or the complete Routing Set
   recalculated) when routing paths are calculated, based on changes to
   these other Protocol Sets.  Routing Tuples are not subject to timer-
   based expiration.

11.  Received Message Information Base

   The Received Message Information Base, defined by this specification,
   records information required to ensure that a message is processed at
   most once and is forwarded at most once per OLSRv2 interface of a
   router, using MPR flooding.  Messages are recorded using their
   "signature", consisting of their type, originator address, and
   message sequence number.






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11.1.  Received Set

   A router has a Received Set per OLSRv2 interface.  Each Received Set
   records the signatures of messages that have been received over that
   OLSRv2 interface.  Each consists of Received Tuples:

      (RX_type, RX_orig_addr, RX_seq_number, RX_time)

   where:

      RX_type is the received Message Type;

      RX_orig_addr is the originator address of the received message
      (note that this does not include a prefix length);

      RX_seq_number is the message sequence number of the received
      message;

      RX_time specifies the time at which this Tuple expires and MUST be
      removed.

11.2.  Processed Set

   A router has a single Processed Set that records signatures of
   messages that have been processed by the router.  It consists of
   Processed Tuples:

      (P_type, P_orig_addr, P_seq_number, P_time)

   where:

      P_type is the processed Message Type;

      P_orig_addr is the originator address of the processed message
      (note that this does not include a prefix length);

      P_seq_number is the message sequence number of the processed
      message;

      P_time specifies the time at which this Tuple expires and MUST be
      removed.










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11.3.  Forwarded Set

   A router has a single Forwarded Set that records signatures of
   messages that have been forwarded by the router.  It consists of
   Forwarded Tuples:

      (F_type, F_orig_addr, F_seq_number, F_time)

   where:

      F_type is the forwarded Message Type;

      F_orig_addr is the originator address of the forwarded message
      (note that this does not include a prefix length);

      F_seq_number is the message sequence number of the forwarded
      message;

      F_time specifies the time at which this Tuple expires and MUST be
      removed.

12.  Information Base Properties

   This section describes some additional properties of Information
   Bases and their contents.

12.1.  Corresponding Protocol Tuples

   As part of this specification, in a number of cases, there is a
   natural correspondence from a Protocol Tuple in one Protocol Set to a
   single Protocol Tuple in another Protocol Set, in the same or another
   Information Base.  The latter Protocol Tuple is referred to as
   "corresponding" to the former Protocol Tuple.

   Specific examples of corresponding Protocol Tuples include:

   o  There is a Local Interface Tuple corresponding to each Link Tuple,
      where the Link Tuple is in the Link Set for a MANET interface and
      the Local Interface Tuple represents that MANET interface.

   o  There is a Neighbor Tuple corresponding to each Link Tuple that
      has L_HEARD_time not EXPIRED, such that N_neighbor_addr_list
      contains L_neighbor_iface_addr_list.

   o  There is a Link Tuple (in the Link Set in the same Interface
      Information Base) corresponding to each 2-Hop Tuple such that
      L_neighbor_iface_addr_list = N2_neighbor_iface_addr_list.




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   o  There is a Neighbor Tuple corresponding to each 2-Hop Tuple, such
      that N_neighbor_addr_list contains N2_neighbor_iface_addr_list.
      (This is the Neighbor Tuple corresponding to the Link Tuple
      corresponding to the 2-Hop Tuple.)

   o  There is an Advertising Remote Router Tuple corresponding to each
      Router Topology Tuple such that AR_orig_addr = TR_from_orig_addr.

   o  There is an Advertising Remote Router Tuple corresponding to each
      Routable Address Topology Tuple such that AR_orig_addr =
      TA_from_orig_addr.

   o  There is an Advertising Remote Router Tuple corresponding to each
      Attached Network Tuple such that AR_orig_addr = AN_orig_addr.

   o  There is a Neighbor Tuple corresponding to each Routing Tuple such
      that N_neighbor_addr_list contains R_next_iface_addr.

12.2.  Address Ownership

   Addresses or network addresses with the following properties are
   considered as "fully owned" by a router when processing a received
   message:

   o  Equaling its originator address; OR

   o  Equaling the O_orig_addr in an Originator Tuple; OR

   o  Equaling or being a sub-range of the I_local_iface_addr_list in a
      Local Interface Tuple; OR

   o  Equaling or being a sub-range of the IR_local_iface_addr in a
      Removed Interface Address Tuple; OR

   o  Equaling an AL_net_addr in a Local Attached Network Tuple.

   Addresses or network addresses with the following properties are
   considered as "partially owned" (which may include being fully owned)
   by a router when processing a received message:

   o  Overlapping (equaling or containing) its originator address; OR

   o  Overlapping (equaling or containing) the O_orig_addr in an
      Originator Tuple; OR

   o  Overlapping the I_local_iface_addr_list in a Local Interface
      Tuple; OR




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   o  Overlapping the IR_local_iface_addr in a Removed Interface Address
      Tuple; OR

   o  Equaling or having as a sub-range an AL_net_addr in a Local
      Attached Network Tuple.

13.  Packets and Messages

   The packet and message format used by this protocol is defined in
   [RFC5444].  Except as otherwise noted, options defined in [RFC5444]
   may be freely used, in particular alternative formats defined by
   packet, message, Address Block, and TLV flags.

   This section describes the usage of the packets and messages defined
   in [RFC5444] by this specification and the TLVs defined by, and used
   in, this specification.

13.1.  Messages

   Routers using this protocol exchange information through messages.
   The Message Types used by this protocol are the HELLO message and the
   TC message.  The HELLO message is defined by [RFC6130] and extended
   by this specification (see Section 15).  The TC message is defined by
   this specification (see Section 16).

13.2.  Packets

   One or more messages sent by a router at the same time SHOULD be
   combined into a single packet, subject to any constraints on maximum
   packet size (such as derived from the MTU over a local single hop)
   that MAY be imposed.  These messages may have originated at the
   sending router or at another router and are being forwarded by the
   sending router.  Messages with different originating routers MAY be
   combined for transmission within the same packet.  Messages from
   other protocols defined using [RFC5444], including but not limited to
   NHDP [RFC6130], MAY be combined for transmission within the same
   packet.  This specification does not define or use any contents of
   the Packet Header.

   Forwarded messages MAY be jittered as described in [RFC5148],
   including the observation that the forwarding jitter of all messages
   received in a single packet SHOULD be the same.  The value of
   MAXJITTER used in jittering a forwarded message MAY be based on
   information in that message (in particular any Message TLVs with Type
   = INTERVAL_TIME or Type = VALIDITY_TIME) or otherwise SHOULD be with
   a maximum delay of F_MAXJITTER.  A router MAY modify the jitter
   applied to a message in order to more efficiently combine messages in
   packets, as long as the maximum jitter is not exceeded.



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13.3.  TLVs

   This specification defines two Message TLVs and four Address Block
   TLVs.

   All references in this specification to TLVs that do not indicate a
   type extension assume Type Extension = 0.  TLVs in processed messages
   with a type extension that is neither zero as so assumed, nor a
   specifically indicated non-zero type extension, are ignored.

   Note that, following [RFC5444] and network byte order, bits in an
   octet are numbered from 0 (most significant) to 7 (least
   significant).

13.3.1.  Message TLVs

   The MPR_WILLING TLV is used in HELLO messages.  A message MUST NOT
   contain more than one MPR_WILLING TLV.

   +-------------+--------------+--------------------------------------+
   |     Type    | Value Length | Value                                |
   +-------------+--------------+--------------------------------------+
   | MPR_WILLING |   1 octet    | Bits 0-3 encode the parameter        |
   |             |              | WILL_FLOODING; bits 4-7 encode the   |
   |             |              | parameter WILL_ROUTING.              |
   +-------------+--------------+--------------------------------------+

                    Table 1: MPR_WILLING TLV Definition

   The CONT_SEQ_NUM TLV is used in TC messages.  A message MUST NOT
   contain more than one CONT_SEQ_NUM TLV.

   +--------------+--------------+-------------------------------------+
   |     Type     | Value Length | Value                               |
   +--------------+--------------+-------------------------------------+
   | CONT_SEQ_NUM |   2 octets   | The ANSN contained in the Neighbor  |
   |              |              | Information Base.                   |
   +--------------+--------------+-------------------------------------+

                   Table 2: CONT_SEQ_NUM TLV Definition

13.3.2.  Address Block TLVs

   The LINK_METRIC TLV is used in HELLO messages and TC messages.  It
   MAY use any type extension; only LINK_METRIC TLVs with type extension
   equal to LINK_METRIC_TYPE will be used by this specification.  An





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   address MUST NOT be associated with more than one link metric value
   for any given type extension, kind (link or neighbor), and direction
   using this TLV.

   +-------------+--------------+--------------------------------------+
   |     Type    | Value Length | Value                                |
   +-------------+--------------+--------------------------------------+
   | LINK_METRIC |   2 octets   | Bits 0-3 indicate kind(s) and        |
   |             |              | direction(s); bits 4-7 indicate      |
   |             |              | exponent (b); and bits 8-15 indicate |
   |             |              | mantissa (a).                        |
   +-------------+--------------+--------------------------------------+

                    Table 3: LINK_METRIC TLV Definition

   The exponent and mantissa use the representation defined in
   Section 6.  Each bit of the types and directions sub-field, if set
   ('1'), indicates that the link metric is of the indicated kind and
   direction.  Any combination of these bits MAY be used.

                   +-----+-----------------+-----------+
                   | Bit |       Kind      | Direction |
                   +-----+-----------------+-----------+
                   |  0  |   Link metric   | Incoming  |
                   |  1  |   Link metric   | Outgoing  |
                   |  2  | Neighbor metric | Incoming  |
                   |  3  | Neighbor metric | Outgoing  |
                   +-----+-----------------+-----------+

               Table 4: LINK_METRIC TLV Types and Directions

   The MPR TLV is used in HELLO messages and indicates that an address
   with which it is associated is of a symmetric 1-hop neighbor that has
   been selected as an MPR.

   +------+--------------+---------------------------------------------+
   | Type | Value Length | Value                                       |
   +------+--------------+---------------------------------------------+
   | MPR  |   1 octet    | FLOODING indicates that the corresponding   |
   |      |              | address is of a neighbor selected as a      |
   |      |              | flooding MPR; ROUTING indicates that the    |
   |      |              | corresponding address is of a neighbor      |
   |      |              | selected as a routing MPR; and FLOOD_ROUTE  |
   |      |              | indicates both (see Section 24.6).          |
   +------+--------------+---------------------------------------------+

                        Table 5: MPR TLV Definition




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   The NBR_ADDR_TYPE TLV is used in TC messages.

   +---------------+--------------+------------------------------------+
   |      Type     | Value Length | Value                              |
   +---------------+--------------+------------------------------------+
   | NBR_ADDR_TYPE |   1 octet    | ORIGINATOR indicates that the      |
   |               |              | corresponding address (which MUST  |
   |               |              | have maximum prefix length) is an  |
   |               |              | originator address; ROUTABLE       |
   |               |              | indicates that the corresponding   |
   |               |              | network address is a routable      |
   |               |              | address of an interface; and       |
   |               |              | ROUTABLE_ORIG indicates that the   |
   |               |              | corresponding address is both (see |
   |               |              | Section 24.6).                     |
   +---------------+--------------+------------------------------------+

                   Table 6: NBR_ADDR_TYPE TLV Definition

   If an address is both an originator address and a routable address,
   then it may be associated with either one Address Block TLV with Type
   := NBR_ADDR_TYPE and Value := ROUTABLE_ORIG, or with two Address
   Block TLVs with Type:= NBR_ADDR_TYPE, one with Value := ORIGINATOR
   and one with Value := ROUTABLE.

   The GATEWAY TLV is used in TC messages.  An address MUST NOT be
   associated with more than one hop count value using this TLV.

     +---------+--------------+-------------------------------------+
     |   Type  | Value Length | Value                               |
     +---------+--------------+-------------------------------------+
     | GATEWAY |   1 octet    | Number of hops to attached network. |
     +---------+--------------+-------------------------------------+

                      Table 7: GATEWAY TLV Definition

   All address objects included in a TC message according to this
   specification MUST be associated either with at least one TLV with
   Type := NBR_ADDR_TYPE or with a TLV with Type := GATEWAY, but not
   both.  Any other address objects MAY be included in Address Blocks in
   a TC message but are ignored by this specification.










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14.  Message Processing and Forwarding

   This section describes the optimized flooding operation (MPR
   flooding) used when control messages, as instances of [RFC5444], are
   intended for MANET-wide distribution.  This flooding mechanism
   defines when a received message is, or is not, processed and/or
   forwarded.

   This flooding mechanism is used by this protocol and MAY be used by
   extensions to this protocol that define, and hence own, other Message
   Types, to manage processing and/or forwarding of these messages.
   This specification contains elements (P_type, RX_type, F_type)
   required only for such usage.

   This flooding mechanism is always used for TC messages (see
   Section 16).  Received HELLO messages (see Section 15) are, unless
   invalid, always processed and never forwarded by this flooding
   mechanism.  They thus do not need to be recorded in the Received
   Message Information Base.

   The processing selection and forwarding mechanisms are designed to
   only need to parse the Message Header in order to determine whether a
   message is to be processed and/or forwarded and not to have to parse
   the Message Body even if the message is forwarded (but not
   processed).  An implementation MAY only parse the Message Body if
   necessary or MAY always parse the Message Body and reject the message
   if it cannot be so parsed or any other error is identified.

   An implementation MUST discard the message silently if it is unable
   to parse the Message Header or (if attempted) the Message Body, or if
   a message (other than a HELLO message) does not include a message
   sequence number.

14.1.  Actions When Receiving a Message

   On receiving, on an OLSRv2 interface, a message of a type specified
   to be using this mechanism, which includes the TC messages defined in
   this specification, a router MUST perform the following:

   1.  If the router recognizes from the originator address of the
       message that the message is one that the receiving router itself
       originated (i.e., the message originator address is the
       originator address of this router or is an O_orig_addr in an
       Originator Tuple), then the message MUST be silently discarded.







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   2.  Otherwise:

       1.  If the message is of a type that may be processed, then the
           message is considered for processing according to
           Section 14.2.

       2.  If the message is of a type that may be forwarded, AND:

           +  <msg-hop-limit> is present and <msg-hop-limit> > 1; AND

           +  <msg-hop-count> is not present or <msg-hop-count> < 255,

           then the message is considered for forwarding according to
           Section 14.3.

14.2.  Message Considered for Processing

   If a message (the "current message") is considered for processing,
   then the following tasks MUST be performed:

   1.  If the sending address (i.e., the source address of the IP
       datagram containing the current message) does not match (taking
       into account any address prefix) a network address in an
       L_neighbor_iface_addr_list of a Link Tuple, with L_status =
       SYMMETRIC, in the Link Set for the OLSRv2 interface on which the
       current message was received (the "receiving interface"), then
       processing the current message is OPTIONAL.  If the current
       message is not processed, then the following steps are not
       carried out.

   2.  If a Processed Tuple exists with:

       *  P_type = the Message Type of the current message; AND

       *  P_orig_addr = the originator address of the current message;
          AND

       *  P_seq_number = the message sequence number of the current
          message,

       then the current message MUST NOT be processed.

   3.  Otherwise:

       1.  Create a Processed Tuple in the Processed Set with:

           +  P_type := the Message Type of the current message;




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           +  P_orig_addr := the originator address of the current
              message;

           +  P_seq_number := the sequence number of the current
              message;

           +  P_time := current time + P_HOLD_TIME.

       2.  Process the current message according to its Message Type.
           For a TC message, this is as defined in Section 16.3.

14.3.  Message Considered for Forwarding

   If a message (the "current message") is considered for forwarding,
   then the following tasks MUST be performed:

   1.  If the sending address (i.e., the source address of the IP
       datagram containing the current message) does not match (taking
       into account any address prefix) a network address in an
       L_neighbor_iface_addr_list of a Link Tuple, with L_status =
       SYMMETRIC, in the Link Set for the OLSRv2 interface on which the
       current message was received (the "receiving interface"), then
       the current message MUST be silently discarded.

   2.  Otherwise:

       1.  If a Received Tuple exists in the Received Set for the
           receiving interface, with:

           +  RX_type = the Message Type of the current message; AND

           +  RX_orig_addr = the originator address of the current
              message; AND

           +  RX_seq_number = the sequence number of the current
              message,

           then the current message MUST be silently discarded.

       2.  Otherwise:

           1.  Create a Received Tuple in the Received Set for the
               receiving interface with:

               -  RX_type := the Message Type of the current message;

               -  RX_orig_addr := originator address of the current
                  message;



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               -  RX_seq_number := sequence number of the current
                  message;

               -  RX_time := current time + RX_HOLD_TIME.

           2.  If a Forwarded Tuple exists with:

               -  F_type = the Message Type of the current message; AND

               -  F_orig_addr = the originator address of the current
                  message; AND

               -  F_seq_number = the sequence number of the current
                  message,

               then the current message MUST be silently discarded.

           3.  Otherwise, if the sending address matches (taking account
               of any address prefix), any network address in an
               L_neighbor_iface_addr_list of a Link Tuple in the Link
               Set for the receiving OLSRv2 interface that has L_status
               = SYMMETRIC and L_mpr_selector = true, then:

               1.  Create a Forwarded Tuple in the Forwarded Set with:

                   o  F_type := the Message Type of the current message;

                   o  F_orig_addr := originator address of the current
                      message;

                   o  F_seq_number := sequence number of the current
                      message;

                   o  F_time := current time + F_HOLD_TIME.

               2.  The Message Header of the current message is modified
                   by:

                   o  Decrement <msg-hop-limit> in the Message Header by
                      1; AND

                   o  If present, increment <msg-hop-count> in the
                      Message Header by 1.

               3.  The message is transmitted over all OLSRv2
                   interfaces, as described in Section 13.





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           4.  Otherwise, the current message MUST be silently
               discarded.

15.  HELLO Messages

   The HELLO Message Type is owned by NHDP [RFC6130], and HELLO messages
   are thus generated, transmitted, received, and processed by NHDP.
   This protocol, as permitted by [RFC6130], also uses HELLO messages,
   including adding to HELLO message generation and implementing
   additional processing based on received HELLO messages.  HELLO
   messages are not forwarded by NHDP [RFC6130] or by OLSRv2.

15.1.  HELLO Message Generation

   HELLO messages sent over OLSRv2 interfaces are generated as defined
   in [RFC6130] and then modified as described in this section.  HELLO
   messages sent on other MANET interfaces are not modified by this
   specification.

   HELLO messages sent over OLSRv2 interfaces are extended by adding the
   following elements:

   o  A message originator address, recording this router's originator
      address.  This MUST use a <msg-orig-addr> element, unless:

      *  The message specifies only a single local interface address
         (i.e., contains only one address object that is associated with
         an Address Block TLV with Type = LOCAL_IF and that has no
         prefix length or a maximum prefix length) that will then be
         used as the message originator address; OR

      *  The message does not include any local interface network
         addresses (i.e., has no address objects associated with an
         Address Block TLV with Type = LOCAL_IF), as permitted by the
         specification in [RFC6130], when the router that generated the
         HELLO message has only one interface address and will use that
         as the sending address of the IP datagram in which the HELLO
         message is contained.  In this case, that address will be used
         as the message originator address.

   o  A Message TLV with Type := MPR_WILLING MUST be included.

   o  The following cases associate Address Block TLVs with one or more
      addresses from a Link Tuple or a Neighbor Tuple if these are
      included in the HELLO message.  In each case, the TLV MUST be
      associated with at least one address object for an address from
      the relevant Tuple; the TLV MAY be associated with more such
      addresses (including a copy of that address object, possibly not



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      itself associated with any other indicated TLVs, in the same or a
      different Address Block).  These additional TLVs MUST NOT be
      associated with any other addresses in a HELLO message that will
      be processed by NHDP [RFC6130].

      *  For each Link Tuple for which L_in_metric != UNKNOWN_METRIC and
         for which one or more addresses in its
         L_neighbor_iface_addr_list are included as address objects with
         an associated Address Block TLV with Type = LINK_STATUS and
         Value = HEARD or Value = SYMMETRIC, at least one of these
         addresses MUST be associated with an Address Block TLV with
         Type := LINK_METRIC indicating an incoming link metric with
         value L_in_metric.

      *  For each Link Tuple for which L_out_metric != UNKNOWN_METRIC
         and for which one or more addresses in its
         L_neighbor_iface_addr_list are included as address objects with
         an associated Address Block TLV with Type = LINK_STATUS and
         Value = SYMMETRIC, at least one of these addresses MUST be
         associated with an Address Block TLV with Type := LINK_METRIC
         indicating an outgoing link metric with value L_out_metric.

      *  For each Neighbor Tuple for which N_symmetric = true and for
         which one or more addresses in its N_neighbor_addr_list are
         included as address objects with an associated Address Block
         TLV with Type = LINK_STATUS or Type = OTHER_NEIGHB and Value =
         SYMMETRIC, at least one of these addresses MUST be associated
         with an Address Block TLV with Type := LINK_METRIC indicating
         an incoming neighbor metric with value N_in_metric.

      *  For each Neighbor Tuple for which N_symmetric = true and for
         which one or more addresses in its N_neighbor_addr_list are
         included as address objects with an associated Address Block
         TLV with Type = LINK_STATUS or Type = OTHER_NEIGHB and Value =
         SYMMETRIC, at least one of these addresses MUST be associated
         with an Address Block TLV with Type := LINK_METRIC indicating
         an outgoing neighbor metric with value N_out_metric.

      *  For each Neighbor Tuple with N_flooding_mpr = true and for
         which one or more network addresses in its N_neighbor_addr_list
         are included as address objects in the HELLO message with an
         associated Address Block TLV with Type = LINK_STATUS and Value
         = SYMMETRIC, at least one of these addresses MUST be associated
         with an Address Block TLV with Type := MPR and Value :=
         FLOODING or Value := FLOOD_ROUTE.






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      *  For each Neighbor Tuple with N_routing_mpr = true and for which
         one or more network addresses in its N_neighbor_addr_list are
         included as address objects in the HELLO message with an
         associated Address Block TLV with Type = LINK_STATUS and Value
         = SYMMETRIC, at least one of these addresses MUST be associated
         with an Address Block TLV with Type := MPR and Value := ROUTING
         or Value := FLOOD_ROUTE.

15.2.  HELLO Message Transmission

   HELLO messages are scheduled and transmitted by NHDP [RFC6130].  This
   protocol MAY require that an additional HELLO message be sent on each
   OLSRv2 interface when either of the router's sets of MPRs changes, in
   addition to the cases specified in [RFC6130] and subject to the
   constraints specified in [RFC6130] (notably on minimum HELLO message
   transmission intervals).

15.3.  HELLO Message Processing

   When received on an OLSRv2 interface, HELLO messages are made
   available to this protocol in two ways, both as permitted by
   [RFC6130]:

   o  Such received HELLO messages MUST be made available to this
      protocol on reception, which allows them to be discarded before
      being processed by NHDP [RFC6130], for example, if the information
      added to the HELLO message by this specification is inconsistent.

   o  Such received HELLO messages MUST be made available to OLSRv2
      after NHDP [RFC6130] has completed its processing thereof, unless
      discarded as malformed by NHDP, for processing by OLSRv2.

15.3.1.  HELLO Message Discarding

   In addition to the reasons specified in [RFC6130] for discarding a
   HELLO message on reception, a HELLO message received on an OLSRv2
   interface MUST be discarded before processing by NHDP [RFC6130] or
   this specification if it:

   o  Has more than one Message TLV with Type = MPR_WILLING.

   o  Has a message originator address, or a network address
      corresponding to an address object associated with an Address
      Block TLV with Type = LOCAL_IF, that is partially owned by this
      router.  (Some of these cases are already excluded by [RFC6130].)






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   o  Includes any address object associated with an Address Block TLV
      with Type = LINK_STATUS or Type = OTHER_NEIGHB that overlaps the
      message's originator address.

   o  Contains any address that will be processed by NHDP [RFC6130] that
      is associated, using the same or different address objects, with
      two different values of link metric with the same kind and
      direction using a TLV with Type = LINK_METRIC and Type Extension =
      LINK_METRIC_TYPE.  This also applies to different addresses that
      are both of the OLSRv2 interface on which the HELLO message was
      received.

   o  Contains any address object associated with an Address Block TLV
      with Type = MPR that is not also associated with an Address Block
      TLV with Type = LINK_STATUS and Value = SYMMETRIC (including using
      a different copy of that address object in the same or a different
      Address Block).

15.3.2.  HELLO Message Usage

   HELLO messages are first processed as specified in [RFC6130].  That
   processing includes identifying (or creating) a Link Tuple and a
   Neighbor Tuple corresponding to the originator of the HELLO message
   (the "current Link Tuple" and the "current Neighbor Tuple").  After
   this, the following processing MUST also be performed if the HELLO
   message is received on an OLSRv2 interface and contains a TLV with
   Type = MPR_WILLING:

   1.  If the HELLO message has a well-defined message originator
       address, i.e., has an <msg-orig-addr> element or has zero or one
       network addresses associated with a TLV with Type = LOCAL_IF:

       1.  Remove any Neighbor Tuple, other than the current Neighbor
           Tuple, with N_orig_addr = message originator address, taking
           any consequent action (including removing one or more Link
           Tuples) as specified in [RFC6130].

       2.  The current Link Tuple is then updated according to:

           1.  Update L_in_metric and L_out_metric as described in
               Section 15.3.2.1;

           2.  Update L_mpr_selector as described in Section 15.3.2.3.

       3.  The current Neighbor Tuple is then updated according to:

           1.  N_orig_addr := message originator address;




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           2.  Update N_in_metric and N_out_metric as described in
               Section 15.3.2.1;

           3.  Update N_will_flooding and N_will_routing as described in
               Section 15.3.2.2;

           4.  Update N_mpr_selector as described in Section 15.3.2.3.

       4.  All 2-Hop Tuples that were updated as described in [RFC6130]
           are then updated according to:

           1.  Update N2_in_metric and N2_out_metric as described in
               Section 15.3.2.1.

   2.  If there are any changes to the router's Information Bases, then
       perform the processing defined in Section 17.

15.3.2.1.  Updating Metrics

   For each address in a received HELLO message with an associated TLV
   with Type = LINK_STATUS and Value = HEARD or Value = SYMMETRIC, an
   incoming (to the message originator) link metric value is defined.
   If the HELLO message contains a TLV with Type = LINK_METRIC and Type
   Extension = LINK_METRIC_TYPE that associates that address value with
   a metric value of the appropriate kind (link) and direction
   (incoming) of metric, then the incoming link metric is that metric
   value; otherwise, the incoming link metric is defined as
   UNKNOWN_METRIC.

   For each address in a received HELLO message with an associated TLV
   with Type = LINK_STATUS and Value = SYMMETRIC, an outgoing (from the
   message originator) link metric value is defined.  If the HELLO
   message contains a TLV with Type = LINK_METRIC and Type Extension =
   LINK_METRIC_TYPE that associates that address value with a metric
   value of the appropriate kind (link) and direction (outgoing) of
   metric, then the outgoing link metric is that metric value;
   otherwise, the outgoing link metric is defined as UNKNOWN_METRIC.

   For each address in a received HELLO message with an associated TLV
   with Type = LINK_STATUS or Type = OTHER_NEIGHB and Value = SYMMETRIC,
   an incoming (to the message originator) neighbor metric value is
   defined.  If the HELLO message contains a TLV with Type = LINK_METRIC
   and Type Extension = LINK_METRIC_TYPE that associates that address
   value with a metric value of the appropriate kind (neighbor) and
   direction (incoming) of metric, then the incoming neighbor metric is
   that metric value; otherwise, the incoming neighbor metric is defined
   as UNKNOWN_METRIC.




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   For each address in a received HELLO message with an associated TLV
   with Type = LINK_STATUS or Type = OTHER_NEIGHB and Value = SYMMETRIC,
   an outgoing (from the message originator) neighbor metric value is
   defined.  If the HELLO message contains a TLV with Type = LINK_METRIC
   and Type Extension = LINK_METRIC_TYPE that associates that address
   value with a metric value of the appropriate kind (neighbor) and
   direction (outgoing) of metric, then the outgoing neighbor metric is
   that metric value; otherwise, the outgoing neighbor metric is defined
   as UNKNOWN_METRIC.

   The link metric elements L_in_metric and L_out_metric in a Link Tuple
   are updated according to the following:

   o  For any Link Tuple, L_in_metric MAY be set to any representable
      value by a process outside this specification at any time.
      L_in_metric MUST be so set whenever L_status becomes equal to
      HEARD or SYMMETRIC (if no other value is available, then the value
      MAXIMUM_METRIC MUST be used).  Setting L_in_metric MAY use
      information based on the receipt of a packet including a HELLO
      message that causes the creation or updating of the Link Tuple.

   o  When, as specified in [RFC6130], a Link Tuple is updated (possibly
      immediately after being created) due to the receipt of a HELLO
      message, if L_status = SYMMETRIC, then L_out_metric is set equal
      to the incoming link metric for any included address of the
      interface on which the HELLO message was received.  (Note that the
      rules for discarding HELLO messages in Section 15.3.1 make this
      value unambiguous.)  If there is any such address, but no such
      link metric, then L_out_metric is set to UNKNOWN_METRIC.

   The neighbor metric elements N_in_metric and N_out_metric in a
   Neighbor Tuple are updated according to Section 17.3.

   The metric elements N2_in_metric and N2_out_metric in any 2-Hop Tuple
   updated as defined in [RFC6130] are updated to equal the incoming
   neighbor metric and outgoing neighbor metric, respectively,
   associated with the corresponding N2_2hop_addr.  If there are no such
   metrics, then these elements are set to UNKNOWN_METRIC.

15.3.2.2.  Updating Willingness

   N_will_flooding and N_will_routing in the current Neighbor Tuple are
   updated using the Message TLV with Type = MPR_WILLING (note that this
   must be present) as follows:







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   o  N_will_flooding := bits 0-3 of the value of that TLV; AND

   o  N_will_routing := bits 4-7 of the value of that TLV.

   (Each being in the range 0 to 15, i.e., WILL_NEVER to WILL_ALWAYS.)

15.3.2.3.  Updating MPR Selector Status

   L_mpr_selector is updated as follows:

   1.  If a router finds an address object representing any of its
       relevant local interface network addresses (i.e., those contained
       in the I_local_iface_addr_list of an OLSRv2 interface) with an
       associated Address Block TLV with Type = MPR and Value = FLOODING
       or Value = FLOOD_ROUTE in the HELLO message (indicating that the
       originating router has selected the receiving router as a
       flooding MPR), then, for the current Link Tuple:

       *  L_mpr_selector := true.

   2.  Otherwise (i.e., if no such address object and Address Block TLV
       was found), if a router finds an address object representing any
       of its relevant local interface network addresses (i.e., those
       contained in the I_local_iface_addr_list of an OLSRv2 interface)
       with an associated Address Block TLV with Type = LINK_STATUS and
       Value = SYMMETRIC in the HELLO message, then, for the current
       Link Tuple:

       *  L_mpr_selector := false.

   N_mpr_selector is updated as follows:

   1.  If a router finds an address object representing any of its
       relevant local interface network addresses (those contained in
       the I_local_iface_addr_list of an OLSRv2 interface) with an
       associated Address Block TLV with Type = MPR and Value = ROUTING
       or Value = FLOOD_ROUTE in the HELLO message (indicating that the
       originating router has selected the receiving router as a routing
       MPR), then, for the current Neighbor Tuple:

       *  N_mpr_selector := true;

       *  N_advertised := true.

   2.  Otherwise (i.e., if no such address object and Address Block TLV
       was found), if a router finds an address object representing any
       of its relevant local interface network addresses (those
       contained in the I_local_iface_addr_list of an OLSRv2 interface)



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       with an associated Address Block TLV with Type = LINK_STATUS and
       Value = SYMMETRIC in the HELLO message, then, for the current
       Neighbor Tuple:

       *  N_mpr_selector := false;

       *  The router MAY also set N_advertised := false.

16.  TC Messages

   This protocol defines, and hence owns, the TC Message Type (see
   Section 24).  Thus, as specified in [RFC5444], this protocol
   generates and transmits all TC messages, receives all TC messages,
   and is responsible for determining whether and how each TC message is
   to be processed (updating the Topology Information Base) and/or
   forwarded, according to this specification.

16.1.  TC Message Generation

   A TC message is a message as defined in [RFC5444].  A generated TC
   message MUST contain the following elements as defined in [RFC5444]:

   o  A message originator address, recording this router's originator
      address.  This MUST use a <msg-orig-addr> element.

   o  <msg-seq-num> element containing the message sequence number.

   o  A <msg-hop-limit> element, containing TC_HOP_LIMIT.  A router MAY
      use the same or different values of TC_HOP_LIMIT in its TC
      messages (see Section 5.4.7).

   o  A <msg-hop-count> element, containing zero, if the message
      contains a TLV with either Type = VALIDITY_TIME or Type =
      INTERVAL_TIME (as specified in [RFC5497]) indicating more than one
      time value according to distance.  A TC message MAY contain such a
      <msg-hop-count> element even if it does not need to.

   o  A single Message TLV with Type := CONT_SEQ_NUM and Value := ANSN
      from the Neighbor Information Base.  If the TC message is
      complete, then this Message TLV MUST have Type Extension :=
      COMPLETE; otherwise, it MUST have Type Extension := INCOMPLETE.
      (Exception: a TC message MAY omit such a Message TLV if the TC
      message does not include any address objects with an associated
      Address Block TLV with Type = NBR_ADDR_TYPE or Type = GATEWAY.)

   o  A single Message TLV with Type := VALIDITY_TIME, as specified in
      [RFC5497].  If all TC messages are sent with the same hop limit,
      then this TLV MUST have a value encoding the period T_HOLD_TIME.



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      If TC messages are sent with different hop limits (more than one
      value of TC_HOP_LIMIT), then this TLV MUST specify times that vary
      with the number of hops appropriate to the chosen pattern of TC
      message hop limits, as specified in [RFC5497]; these times SHOULD
      be appropriate multiples of T_HOLD_TIME.  The options included in
      [RFC5497] for representing zero and infinite times MUST NOT be
      used.

   o  If the TC message is complete, all network addresses that are the
      N_orig_addr of a Neighbor Tuple with N_advertised = true, MUST be
      represented by address objects in one or more Address Blocks.  If
      the TC message is incomplete, then any such address objects MAY be
      included.  At least one copy of each such address object that is
      included MUST be associated with an Address Block TLV with Type :=
      NBR_ADDR_TYPE and Value := ORIGINATOR or with Value :=
      ROUTABLE_ORIG if that address object is also to be associated with
      Value = ROUTABLE.

   o  If the TC message is complete, all routable addresses that are in
      the N_neighbor_addr_list of a Neighbor Tuple with N_advertised =
      true MUST be represented by address objects in one or more Address
      Blocks.  If the TC message is incomplete, then any such address
      objects MAY be included.  At least one copy of each such address
      object MUST be associated with an Address Block TLV with Type =
      NBR_ADDR_TYPE and Value = ROUTABLE or with Value = ROUTABLE_ORIG
      if also to be associated with Value = ORIGINATOR.  At least one
      copy of each such address object MUST be associated with an
      Address Block TLV with Type = LINK_METRIC and Type Extension =
      LINK_METRIC_TYPE indicating an outgoing neighbor metric with value
      equal to the corresponding N_out_metric.

   o  If the TC message is complete, all network addresses that are the
      AL_net_addr of a Local Attached Network Tuple MUST be represented
      by address objects in one or more Address Blocks.  If the TC
      message is incomplete, then any such address objects MAY be
      included.  At least one copy of each such address object MUST be
      associated with an Address Block TLV with Type := GATEWAY and
      Value := AN_dist.  At least one copy of each such address object
      MUST be associated with an Address Block TLV with Type =
      LINK_METRIC and Type Extension = LINK_METRIC_TYPE indicating an
      outgoing neighbor metric equal to the corresponding AL_metric.

   A TC message MAY contain:

   o  A single Message TLV with Type := INTERVAL_TIME, as specified in
      [RFC5497].  If all TC messages are sent with the same hop limit,
      then this TLV MUST have a value encoding the period TC_INTERVAL.
      If TC messages are sent with different hop limits, then this TLV



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      MUST specify times that vary with the number of hops appropriate
      to the chosen pattern of TC message hop limits, as specified in
      [RFC5497]; these times MUST be appropriate multiples of
      TC_INTERVAL.  The options included in [RFC5497] for representing
      zero and infinite times MUST NOT be used.

16.2.  TC Message Transmission

   A router with one or more OLSRv2 interfaces, and with any Neighbor
   Tuples with N_advertised = true, or with a non-empty Local Attached
   Network Set MUST generate TC messages.  A router that does not have
   such information to advertise MUST also generate "empty" TC messages
   for a period A_HOLD_TIME after it last generated a non-empty TC
   message.

   Complete TC messages are generated and transmitted periodically on
   all OLSRv2 interfaces, with a default interval between two
   consecutive TC message transmissions by the same router of
   TC_INTERVAL.

   TC messages MAY be generated in response to a change in the
   information that they are to advertise, indicated by a change in the
   ANSN in the Neighbor Information Base.  In this case, a router MAY
   send a complete TC message and, if so, MAY restart its TC message
   schedule.  Alternatively, a router MAY send an incomplete TC message
   with at least the newly advertised network addresses (i.e., not
   previously, but now, an N_orig_addr or in an N_neighbor_addr_list in
   a Neighbor Tuple with N_advertised = true or an AL_net_addr) in its
   Address Blocks, with associated Address Block TLV(s).  Note that a
   router cannot report removal of advertised content using an
   incomplete TC message.

   When sending a TC message in response to a change of advertised
   network addresses, a router MUST respect a minimum interval of
   TC_MIN_INTERVAL between sending TC messages (complete or incomplete)
   and a maximum interval of TC_INTERVAL between sending complete TC
   messages.  Thus, a router MUST NOT send an incomplete TC message if
   within TC_MIN_INTERVAL of the next scheduled time to send a complete
   TC message.

   The generation of TC messages, whether scheduled or triggered by a
   change of contents, MAY be jittered as described in [RFC5148].  The
   values of MAXJITTER used MUST be:

   o  TP_MAXJITTER for periodic TC message generation;

   o  TT_MAXJITTER for responsive TC message generation.




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16.3.  TC Message Processing

   On receiving a TC message on an OLSRv2 interface, the receiving
   router MUST then follow the processing and forwarding procedures
   defined in Section 14.

   If the message is considered for processing (Section 14.2), then a
   router MUST first check if the message is invalid for processing by
   this router, as defined in Section 16.3.1.  A router MAY make a
   similar check before considering a message for forwarding; it MUST
   check the aspects that apply to elements in the Message Header.

   If the TC message is not invalid, then the processing specific to TC
   Message Type, described in Section 16.3.2, MUST be applied.  This
   will update its appropriate Interface Information Bases and its
   Router Information Base.  Following this, if there are any changes in
   these Information Bases, then the processing in Section 17 MUST be
   performed.

16.3.1.  TC Message Discarding

   A received TC message is invalid for processing by this router if the
   message:

   o  Has an address length specified in the Message Header that is not
      equal to the length of the addresses used by this router.

   o  Does not include a message originator address and a message
      sequence number.

   o  Does not include a hop count and contains a multi-value TLV with
      Type = VALIDITY_TIME or Type = INTERVAL_TIME, as defined in
      [RFC5497].

   o  Does not have exactly one Message TLV with Type = VALIDITY_TIME.

   o  Has more than one Message TLV with Type = INTERVAL_TIME.

   o  Does not have a Message TLV with Type = CONT_SEQ_NUM and Type
      Extension = COMPLETE or Type Extension = INCOMPLETE and contains
      at least one address object associated with an Address Block TLV
      with Type = NBR_ADDR_TYPE or Type = GATEWAY.

   o  Has more than one Message TLV with Type = CONT_SEQ_NUM and Type
      Extension = COMPLETE or Type Extension = INCOMPLETE.

   o  Has a message originator address that is partially owned by this
      router.



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   o  Includes any address object with a prefix length that is not
      maximal (equal to the address length, in bits), associated with an
      Address Block TLV with Type = NBR_ADDR_TYPE and Value = ORIGINATOR
      or Value = ROUTABLE_ORIG.

   o  Includes any address object that represents a non-routable
      address, associated with an Address Block TLV with Type =
      NBR_ADDR_TYPE and Value = ROUTABLE or Value = ROUTABLE_ORIG.

   o  Includes any address object associated with an Address Block TLV
      with Type = NBR_ADDR_TYPE or Type = GATEWAY that also represents
      the message's originator address.

   o  Includes any address object (including different copies of an
      address object in the same or different Address Blocks) that is
      associated with an Address Block TLV with Type = NBR_ADDR_TYPE or
      Type = GATEWAY that is also associated with more than one outgoing
      neighbor metric using a TLV with Type = LINK_METRIC and Type
      Extension = LINK_METRIC_TYPE.

   o  Associates any address object (including different copies of an
      address object in the same or different Address Blocks) with more
      than one single hop count value using one or more Address Block
      TLV(s) with Type = GATEWAY.

   o  Associates any address object (including different copies of an
      address object in the same or different Address Blocks) with
      Address Block TLVs with Type = NBR_ADDR_TYPE and Type = GATEWAY.

   A router MAY recognize additional reasons for identifying that a
   message is invalid.  An invalid message MUST be silently discarded,
   without updating the router's Information Bases.

   Note that a router that acts inconsistently, for example, rejecting
   TC messages "at random", may cause parts of the network to not be
   able to communicate with other parts of the network.  It is
   RECOMMENDED that such "additional reasons for identifying that a
   message is invalid" be a consistent network-wide policy (e.g., as
   part of a security policy), implemented on all participating routers.












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16.3.2.  TC Message Processing Definitions

   When, according to Section 14.2, a TC message is to be "processed
   according to its type", this means that:

   o  If the TC message contains a Message TLV with Type = CONT_SEQ_NUM
      and Type Extension = COMPLETE, then processing according to
      Section 16.3.3 and then according to Section 16.3.4 is carried
      out.

   o  If the TC message contains a Message TLV with Type = CONT_SEQ_NUM
      and Type Extension = INCOMPLETE, then only processing according to
      Section 16.3.3 is carried out.

   For the purposes of the TC message processing in Section 16.3.3 and
   Section 16.3.4:

   o  "validity time" is calculated from a VALIDITY_TIME Message TLV in
      the TC message according to the specification in [RFC5497].  All
      information in the TC message has the same validity time.

   o  "received ANSN" is defined as being the value of a Message TLV
      with Type = CONT_SEQ_NUM.

   o  "associated metric value" is defined for any address in the TC
      message as being either the outgoing neighbor metric value
      indicated by a TLV with Type = LINK_METRIC and Type Extension =
      LINK_METRIC_TYPE that is associated with any address object in the
      TC message that is equal to that address or as UNKNOWN_METRIC
      otherwise.  (Note that the rules in Section 16.3.1 make this
      definition unambiguous.)

   o  Comparisons of sequence numbers are carried out as specified in
      Section 21.

16.3.3.  Initial TC Message Processing

   The TC message is processed as follows:

   1.  The Advertising Remote Router Set is updated according to
       Section 16.3.3.1.  If the TC message is indicated as discarded in
       that processing, then the following steps are not carried out.

   2.  The Router Topology Set is updated according to Section 16.3.3.2.

   3.  The Routable Address Topology Set is updated according to
       Section 16.3.3.3.




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   4.  The Attached Network Set is updated according to
       Section 16.3.3.4.

16.3.3.1.  Populating the Advertising Remote Router Set

   The router MUST update its Advertising Remote Router Set as follows:

   1.  If there is an Advertising Remote Router Tuple with:

       *  AR_orig_addr = message originator address; AND

       *  AR_seq_number > received ANSN,

       then the TC message MUST be discarded.

   2.  Otherwise:

       1.  If there is no Advertising Remote Router Tuple such that:

           +  AR_orig_addr = message originator address;

           then create an Advertising Remote Router Tuple with:

           +  AR_orig_addr := message originator address.

       2.  This Advertising Remote Router Tuple (existing or new) is
           then modified as follows:

           +  AR_seq_number := received ANSN;

           +  AR_time := current time + validity time.

16.3.3.2.  Populating the Router Topology Set

   The router MUST update its Router Topology Set as follows:

   1.  For each address (henceforth, advertised address) that
       corresponds to one or more address objects with an associated
       Address Block TLV with Type = NBR_ADDR_TYPE and Value =
       ORIGINATOR or Value = ROUTABLE_ORIG and that is not partially
       owned by this router, perform the following processing:

       1.  If the associated metric is UNKNOWN_METRIC, then remove any
           Router Topology Tuple such that:

           +  TR_from_orig_addr = message originator address; AND

           +  TR_to_orig_addr = advertised address.



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       2.  Otherwise, if there is no Router Topology Tuple such that:

           +  TR_from_orig_addr = message originator address; AND

           +  TR_to_orig_addr = advertised address,

           then create a new Router Topology Tuple with:

           +  TR_from_orig_addr := message originator address;

           +  TR_to_orig_addr := advertised address.

       3.  This Router Topology Tuple (existing or new) is then modified
           as follows:

           +  TR_seq_number := received ANSN;

           +  TR_metric := associated link metric;

           +  TR_time := current time + validity time.

16.3.3.3.  Populating the Routable Address Topology Set

   The router MUST update its Routable Address Topology Set as follows:

   1.  For each network address (henceforth, advertised address) that
       corresponds to one or more address objects with an associated
       Address Block TLV with Type = NBR_ADDR_TYPE and Value = ROUTABLE
       or Value = ROUTABLE_ORIG and that is not partially owned by this
       router, perform the following processing:

       1.  If the associated metric is UNKNOWN_METRIC, then remove any
           Routable Address Topology Tuple such that:

           +  TA_from_orig_addr = message originator address; AND

           +  TA_dest_addr = advertised address.

       2.  Otherwise, if there is no Routable Address Topology Tuple
           such that:

           +  TA_from_orig_addr = message originator address; AND

           +  TA_dest_addr = advertised address,







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           then create a new Routable Address Topology Tuple with:

           +  TA_from_orig_addr := message originator address;

           +  TA_dest_addr := advertised address.

       3.  This Routable Address Topology Tuple (existing or new) is
           then modified as follows:

           +  TA_seq_number := received ANSN;

           +  TA_metric := associated link metric;

           +  TA_time := current time + validity time.

16.3.3.4.  Populating the Attached Network Set

   The router MUST update its Attached Network Set as follows:

   1.  For each network address (henceforth, attached address) that
       corresponds to one or more address objects with an associated
       Address Block TLV with Type = GATEWAY and that is not fully owned
       by this router, perform the following processing:

       1.  If the associated metric is UNKNOWN_METRIC, then remove any
           Attached Network Tuple such that:

           +  AN_net_addr = attached address; AND

           +  AN_orig_addr = message originator address.

       2.  Otherwise, if there is no Attached Network Tuple such that:

           +  AN_net_addr = attached address; AND

           +  AN_orig_addr = message originator address,

           then create a new Attached Network Tuple with:

           +  AN_net_addr := attached address;

           +  AN_orig_addr := message originator address.

       3.  This Attached Network Tuple (existing or new) is then
           modified as follows:

           +  AN_seq_number := received ANSN;




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           +  AN_dist := the Value of the associated GATEWAY TLV;

           +  AN_metric := associated link metric;

           +  AN_time := current time + validity time.

16.3.4.  Completing TC Message Processing

   The TC message is processed as follows:

   1.  The Router Topology Set is updated according to Section 16.3.4.1.

   2.  The Routable Address Topology Set is updated according to
       Section 16.3.4.2.

   3.  The Attached Network Set is updated according to
       Section 16.3.4.3.

16.3.4.1.  Purging the Router Topology Set

   The Router Topology Set MUST be updated as follows:

   1.  Any Router Topology Tuples with:

       *  TR_from_orig_addr = message originator address; AND

       *  TR_seq_number < received ANSN,

       MUST be removed.

16.3.4.2.  Purging the Routable Address Topology Set

   The Routable Address Topology Set MUST be updated as follows:

   1.  Any Routable Address Topology Tuples with:

       *  TA_from_orig_addr = message originator address; AND

       *  TA_seq_number < received ANSN,

       MUST be removed.










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16.3.4.3.  Purging the Attached Network Set

   The Attached Network Set MUST be updated as follows:

   1.  Any Attached Network Tuples with:

       *  AN_orig_addr = message originator address; AND

       *  AN_seq_number < received ANSN,

       MUST be removed.

17.  Information Base Changes

   The changes described in the following sections MUST be carried out
   when any Information Base changes as indicated.

17.1.  Originator Address Changes

   If the router changes its originator address, then:

   1.  If there is no Originator Tuple with:

       *  O_orig_addr = old originator address

       then create an Originator Tuple with:

       *  O_orig_addr := old originator address

       The Originator Tuple (existing or new) with:

       *  O_orig_addr = new originator address

       is then modified as follows:

       *  O_time := current time + O_HOLD_TIME

17.2.  Link State Changes

   The consistency of a Link Tuple MUST be maintained according to the
   following rules, in addition to those in [RFC6130]:

   o  If L_status = HEARD or L_status = SYMMETRIC, then L_in_metric MUST
      be set (by a process outside this specification).

   o  If L_status != SYMMETRIC, then set L_mpr_selector := false.





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   o  If L_out_metric = UNKNOWN_METRIC, then L_status MUST NOT equal
      SYMMETRIC; set L_SYM_time := EXPIRED if this would otherwise be
      the case.

17.3.  Neighbor State Changes

   The consistency of a Neighbor Tuple MUST be maintained according to
   the following rules, in addition to those in [RFC6130]:

   1.  If N_symmetric = true, then N_in_metric MUST equal the minimum
       value of all L_in_metric of corresponding Link Tuples with
       L_status = SYMMETRIC and L_in_metric != UNKNOWN_METRIC.  If there
       are no such Link Tuples, then N_in_metric MUST equal
       UNKNOWN_METRIC.

   2.  If N_symmetric = true, then N_out_metric MUST equal the minimum
       value of all L_out_metric of corresponding Link Tuples with
       L_status = SYMMETRIC and L_out_metric != UNKNOWN_METRIC.  If
       there are no such Link Tuples, then N_out_metric MUST equal
       UNKNOWN_METRIC.

   3.  If N_symmetric = false, then N_flooding_mpr, N_routing_mpr,
       N_mpr_selector, and N_advertised MUST all be equal to false.

   4.  If N_mpr_selector = true, then N_advertised MUST be equal to
       true.

   5.  If N_symmetric = true, N_out_metric != UNKNOWN_METRIC and
       N_mpr_selector = false, then a router MAY select N_advertised =
       true or N_advertised = false.  The more neighbors that are
       advertised, the larger TC messages become, but the more
       redundancy is available for routing.  A router SHOULD consider
       the nature of its network in making such a decision and SHOULD
       avoid unnecessary changes in advertising status, which may result
       in unnecessary changes to routing.

17.4.  Advertised Neighbor Changes

   The router MUST increment the ANSN in the Neighbor Information Base
   whenever:

   1.  Any Neighbor Tuple changes its N_advertised value, or any
       Neighbor Tuple with N_advertised = true is removed.

   2.  Any Neighbor Tuple with N_advertised = true changes its
       N_orig_addr or has any routable address added to or removed from
       N_neighbor_addr_list.




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   3.  Any Neighbor Tuple with N_advertised = true has N_out_metric
       changed.

   4.  There is any change to the Local Attached Network Set.

17.5.  Advertising Remote Router Tuple Expires

   The Router Topology Set, the Routable Address Topology Set, and the
   Attached Network Set MUST be changed when an Advertising Remote
   Router Tuple expires (AR_time is reached).  The following changes are
   required before the Advertising Remote Router Tuple is removed:

   1.  All Router Topology Tuples with:

       *  TR_from_orig_addr = AR_orig_addr of the Advertising Remote
          Router Tuple

       are removed.

   2.  All Routable Address Topology Tuples with:

       *  TA_from_orig_addr = AR_orig_addr of the Advertising Remote
          Router Tuple

       are removed.

   3.  All Attached Network Tuples with:

       *  AN_orig_addr = AR_orig_addr of the Advertising Remote Router
          Tuple

       are removed.

17.6.  Neighborhood Changes and MPR Updates

   The sets of symmetric 1-hop neighbors selected as flooding MPRs and
   routing MPRs MUST satisfy the conditions defined in Section 18.  To
   ensure this:

   1.  The set of flooding MPRs of a router MUST be recalculated if:

       *  A Link Tuple is added with L_status = SYMMETRIC and
          L_out_metric != UNKNOWN_METRIC; OR

       *  A Link Tuple with L_status = SYMMETRIC and L_out_metric !=
          UNKNOWN_METRIC is removed; OR





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       *  A Link Tuple with L_status = SYMMETRIC and L_out_metric !=
          UNKNOWN_METRIC changes to having L_status = HEARD, L_status =
          LOST, or L_out_metric = UNKNOWN_METRIC; OR

       *  A Link Tuple with L_status = HEARD or L_status = LOST changes
          to having L_status = SYMMETRIC and L_out_metric !=
          UNKNOWN_METRIC; OR

       *  The flooding MPR selection process uses metric values (see
          Section 18.4) and the L_out_metric of any Link Tuple with
          L_status = SYMMETRIC changes; OR

       *  The N_will_flooding of a Neighbor Tuple with N_symmetric =
          true and N_out_metric != UNKNOWN_METRIC changes from
          WILL_NEVER to any other value; OR

       *  The N_will_flooding of a Neighbor Tuple with N_flooding_mpr =
          true changes to WILL_NEVER from any other value; OR

       *  The N_will_flooding of a Neighbor Tuple with N_symmetric =
          true, N_out_metric != UNKNOWN_METRIC, and N_flooding_mpr =
          false changes to WILL_ALWAYS from any other value; OR

       *  A 2-Hop Tuple with N2_out_metric != UNKNOWN_METRIC is added or
          removed; OR

       *  The N2_out_metric of any 2-Hop Tuple changes and either the
          flooding MPR selection process uses metric values (see
          Section 18.4) or the change is to or from UNKNOWN_METRIC.

   2.  Otherwise, the set of flooding MPRs of a router MAY be
       recalculated if the N_will_flooding of a Neighbor Tuple with
       N_symmetric = true changes in any other way; it SHOULD be
       recalculated if N_flooding_mpr = false and this is an increase in
       N_will_flooding or if N_flooding_mpr = true and this is a
       decrease in N_will_flooding.

   3.  The set of routing MPRs of a router MUST be recalculated if:

       *  A Neighbor Tuple is added with N_symmetric = true and
          N_in_metric != UNKNOWN_METRIC; OR

       *  A Neighbor Tuple with N_symmetric = true and N_in_metric !=
          UNKNOWN_METRIC is removed; OR

       *  A Neighbor Tuple with N_symmetric = true and N_in_metric !=
          UNKNOWN_METRIC changes to having N_symmetric = false; OR




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       *  A Neighbor Tuple with N_symmetric = false changes to having
          N_symmetric = true and N_in_metric != UNKNOWN_METRIC; OR

       *  The N_in_metric of any Neighbor Tuple with N_symmetric = true
          changes; OR

       *  The N_will_routing of a Neighbor Tuple with N_symmetric = true
          and N_in_metric != UNKNOWN_METRIC changes from WILL_NEVER to
          any other value; OR

       *  The N_will_routing of a Neighbor Tuple with N_routing_mpr =
          true changes to WILL_NEVER from any other value; OR

       *  The N_will_routing of a Neighbor Tuple with N_symmetric =
          true, N_in_metric != UNKNOWN_METRIC and N_routing_mpr = false
          changes to WILL_ALWAYS from any other value; OR

       *  A 2-Hop Tuple with N2_in_metric != UNKNOWN_METRIC is added or
          removed; OR

       *  The N2_in_metric of any 2-Hop Tuple changes.

   4.  Otherwise, the set of routing MPRs of a router MAY be
       recalculated if the N_will_routing of a Neighbor Tuple with
       N_symmetric = true changes in any other way; it SHOULD be
       recalculated if N_routing_mpr = false and this is an increase in
       N_will_routing or if N_routing_mpr = true and this is a decrease
       in N_will_routing.

   If either set of MPRs of a router is recalculated, this MUST be as
   described in Section 18.

17.7.  Routing Set Updates

   The Routing Set MUST be updated, as described in Section 19, when
   changes in the Local Information Base, the Neighborhood Information
   Base, or the Topology Information Base indicate a change (including
   of any potentially used outgoing neighbor metric values) of the known
   symmetric links and/or attached networks in the MANET, hence changing
   the Topology Graph.  It is sufficient to consider only changes that
   affect at least one of:

   o  The Local Interface Set for an OLSRv2 interface, if the change
      removes any network address in an I_local_iface_addr_list.  In
      this case, unless the OLSRv2 interface is removed, it may not be
      necessary to do more than replace such network addresses, if used,
      by an alternative network address from the same
      I_local_iface_addr_list.



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   o  The Local Attached Set, if the change removes any AL_net_addr that
      is also an AN_net_addr.  In this case, it may not be necessary to
      do more than add Routing Tuples with R_dest_addr equal to that
      AN_net_addr.

   o  The Link Set of any OLSRv2 interface, considering only Link Tuples
      that have, or just had, L_status = SYMMETRIC and L_out_metric !=
      UNKNOWN_METRIC (including removal of such Link Tuples).

   o  The Neighbor Set of the router, considering only Neighbor Tuples
      that have, or just had, N_symmetric = true and N_out_metric !=
      UNKNOWN_METRIC and do not have N_orig_addr = unknown.

   o  The 2-Hop Set of any OLSRv2 interface, if used in the creation of
      the Routing Set and if the change affects any 2-Hop Tuples with
      N2_out_metric != UNKNOWN_METRIC.

   o  The Router Topology Set of the router.

   o  The Routable Address Topology Set of the router.

   o  The Attached Network Set of the router.

18.  Selecting MPRs

   Each router MUST select, from among its willing symmetric 1-hop
   neighbors, two subsets of these routers, as flooding and routing
   MPRs.  This selection is recorded in the router's Neighbor Set and
   reported in the router's HELLO messages.  Routers MAY select their
   MPRs by any process that satisfies the conditions that follow, which
   may, but need not, use the organization of the data described.
   Routers can freely interoperate whether they use the same or
   different MPR selection algorithms.

   Only flooding MPRs forward control messages flooded through the
   MANET, thus effecting a flooding reduction, an optimization of the
   flooding mechanism, known as MPR flooding.  Routing MPRs are used to
   effect a topology reduction in the MANET.  (If no such reduction is
   required, then a router can select all of its relevant neighbors as
   routing MPRs.)  Consequently, while it is not essential that these
   two sets of MPRs are minimal, keeping the numbers of MPRs small
   ensures that the overhead of this protocol is kept to a minimum.









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18.1.  Overview

   MPRs are selected according to the following steps, defined in the
   following sections:

   o  A data structure known as a Neighbor Graph is defined.

   o  The properties of an MPR Set derived from a Neighbor Graph are
      defined.  Any algorithm that creates an MPR Set that satisfies
      these properties is a valid MPR selection algorithm.  An example
      algorithm that creates such an MPR Set is given in Appendix B.

   o  How to create a Neighbor Graph for each interface based on the
      corresponding Interface Information Base is defined, and how to
      combine the resulting MPR Sets to determine the router's flooding
      MPRs and record those in the router's Neighbor Set are described.

   o  How to create a single Neighbor Graph based on all Interface
      Information Bases and the Neighbor Information Base is defined,
      and how to record the resulting MPR Set as the router's routing
      MPRs in the router's Neighbor Set is described.

   o  A specification as to when MPRs MUST be calculated is given.

   When a router selects its MPRs, it MAY consider any characteristics
   of its neighbors that it is aware of.  In particular, it SHOULD
   consider the willingness of the neighbor, as recorded by the
   corresponding N_will_flooding or N_will_routing value, as
   appropriate, preferring neighbors with higher values.  (Note that
   willingness values equal to WILL_NEVER and WILL_ALWAYS are always
   considered, as described.)  However, a router MAY consider other
   characteristics to have a greater significance.

   Each router MAY select its flooding and routing MPRs independently of
   each other or coordinate its selections.  A router MAY make its MPR
   selections independently of the MPR selection by other routers, or it
   MAY, for example, give preference to routers that either are, or are
   not, already selected as MPRs by other routers.

18.2.  Neighbor Graph

   A Neighbor Graph is a structure defined here as consisting of sets N1
   and N2 and some associated metric and willingness values.  Elements
   of set N1 represent willing symmetric 1-hop neighbors, and elements
   of set N2 represent addresses of a symmetric 2-hop neighbor.






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   A Neighbor Graph has the following properties:

   o  It contains two disjoint sets N1 and N2.

   o  For each element x in N1, there is an associated willingness value
      W(x) such that WILL_NEVER < W(x) <= WILL_ALWAYS.

   o  For each element x in N1, there is an associated metric d1(x) > 0.

   o  For some elements y in N2, there is an associated metric d1(y) >
      0.  (Other elements y in N2 have undefined d1(y); this may be
      considered to be infinite.)

   o  For each element x in N1, there is a subset N2(x) of elements of
      N2; this subset may be empty.  For each x in N1 and each y in
      N2(x), there is an associated metric d2(x,y) > 0.  (For other x in
      N1 and y in N2, d2(x,y) is undefined and may be considered
      infinite.)

   o  N2 is equal to the union of all the N2(x) for all x in N1, i.e.,
      for each y in N2, there is at least one x in N1 such that y is in
      N2(x).

   It is convenient to also define:

   o  For each y in N2, the set N1(y) that contains x in N1 if and only
      if y is in N2(x).  From the final property above, N1(y) is not
      empty.

   o  For each x in N1 and y in N2, if d2(x,y) is defined, then d(x,y)
      := d1(x)+d2(x,y); otherwise, d(x,y) is not defined.  (Thus, d(x,y)
      is defined if y is in N2(x) or, equivalently, if x is in N1(y).)

   o  For any subset S of N1 and for each y in N2, the metric d(y,S) is
      the minimum value of d1(y), if defined, and of all d(x,y) for x in
      N1(y) and in S.  If there are no such metrics to take the minimum
      value of, then d(y,S) is undefined (may be considered to be
      infinite).  From the final property above, d(y,N1) is defined for
      all y.

18.3.  MPR Properties

   Given a Neighbor Graph as defined in Section 18.2, an MPR Set for
   that Neighbor Graph is a subset M of the set N1 that satisfies the
   following properties:






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   o  If x in N1 has W(x) = WILL_ALWAYS, then x is in M.

   o  For any y in N2 that does not have a defined d1(y), there is at
      least one element in M that is also in N1(y).  This is equivalent
      to the requirement that d(y,M) is defined.

   o  For any y in N2, d(y,M) = d(y,N1).

   These properties reflect that the MPR Set consists of a set of
   symmetric 1-hop neighbors that cover all the symmetric 2-hop
   neighbors and that they do so retaining a minimum distance route
   (1-hop, if present, or 2-hop) to each symmetric 2-hop neighbor.

   Note that if M is an MPR Set, then so is any subset of N1 that
   contains M; also note that N1 is always an MPR Set.  An MPR Set may
   be empty but cannot be empty if N2 contains any elements y that do
   not have a defined d1(y).

18.4.  Flooding MPRs

   Whenever flooding MPRs are to be calculated, an implementation MUST
   determine and record a set of flooding MPRs that is equivalent to one
   calculated as described in this section.

   The calculation of flooding MPRs need not use link metrics or,
   equivalently, may use link metrics with a fixed value, here taken to
   be 1.  However, links with unknown metric (L_out_metric =
   UNKNOWN_METRIC) MUST NOT be used even if link metrics are otherwise
   not used.

   Routers MAY make individual decisions as to whether to use link
   metrics for the calculation of flooding MPRs.  A router MUST use the
   same approach to the choice of whether to use link metrics for all
   links, i.e., in the cases indicated by A or B, the same choice MUST
   be made in each case.

   For each OLSRv2 interface (the "current interface"), define a
   Neighbor Graph as defined in Section 18.2 according to the following:

   o  Define a reachable Link Tuple to be a Link Tuple in the Link Set
      for the current interface with L_status = SYMMETRIC and
      L_out_metric != UNKNOWN_METRIC.

   o  Define an allowed Link Tuple to be a reachable Link Tuple whose
      corresponding Neighbor Tuple has N_will_flooding > WILL_NEVER.






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   o  Define an allowed 2-Hop Tuple to be a 2-Hop Tuple in the 2-Hop Set
      for the current interface for which N2_out_metric !=
      UNKNOWN_METRIC and there is an allowed Link Tuple with
      L_neighbor_iface_addr_list = N2_neighbor_iface_addr_list.

   o  Define an element of N1 for each allowed Link Tuple.  This then
      defines the corresponding Link Tuple for each element of N1 and
      the corresponding Neighbor Tuple for each element of N1, being the
      Neighbor Tuple corresponding to that Link Tuple.

   o  For each element x in N1, define W(x) := N_will_flooding of the
      corresponding Neighbor Tuple.

   o  For each element x in N1, define d1(x) as either:

      A.  L_out_metric of the corresponding Link Tuple; OR

      B.  1.

   o  Define an element of N2 for each network address that is the
      N2_2hop_addr of one or more allowed 2-Hop Tuples.  This then
      defines the corresponding address for each element of N2.

   o  For each element y in N2, if the corresponding address is in the
      N_neighbor_addr_list of a Neighbor Tuple that corresponds to one
      or more reachable Link Tuples, then define d1(y) as either:

      A.  the minimum value of the L_out_metric of those Link Tuples; OR

      B.  1.

      Otherwise, d1(y) is not defined.  In the latter case, where d1(y)
      := 1, all such y in N2 may instead be removed from N2.

   o  For each element x in N1, define N2(x) as the set of elements y in
      N2 whose corresponding address is the N2_2hop_addr of an allowed
      2-Hop Tuple that has N2_neighbor_iface_addr_list =
      L_neighbor_iface_addr_list of the Link Tuple corresponding to x.
      For all such x and y, define d2(x,y) as either:

      A.  N2_out_metric of that 2-Hop Tuple; OR

      B.  1.

   It is up to an implementation to decide how to label each element of
   N1 or N2.  For example, an element of N1 may be labeled with one or
   more addresses from the corresponding L_neighbor_iface_addr_list or
   with a pointer or reference to the corresponding Link Tuple.



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   Using these Neighbor Graphs, flooding MPRs are selected and recorded
   by:

   o  For each OLSRv2 interface, determine an MPR Set as specified in
      Section 18.3.

   o  A Neighbor Tuple represents a flooding MPR and has N_flooding_mpr
      := true (otherwise, N_flooding_mpr := false) if and only if that
      Neighbor Tuple corresponds to an element in an MPR Set created for
      any interface as described above.  That is, the overall set of
      flooding MPRs is the union of the sets of flooding MPRs for all
      OLSRv2 interfaces.

   A router MAY select its flooding MPRs for each OLSRv2 interface
   independently, or it MAY coordinate its MPR selections across its
   OLSRv2 interfaces, as long as the required condition is satisfied for
   each OLSRv2 interface.  One such coordinated approach is to process
   the OLSRv2 interfaces sequentially and, for each OLSRv2 interface,
   start with flooding MPRs selected (and not removable) if the neighbor
   has been already selected as an MPR for an OLSRv2 interface that has
   already been processed.  The algorithm specified in Appendix B can be
   used in this way.

18.5.  Routing MPRs

   Whenever routing MPRs are to be calculated, an implementation MUST
   determine and record a set of routing MPRs that is equivalent to one
   calculated as described in this section.

   Define a single Neighbor Graph as defined in Section 18.2 according
   to the following:

   o  Define a reachable Neighbor Tuple to be a Neighbor Tuple with
      N_symmetric = true and N_in_metric != UNKNOWN_METRIC.

   o  Define an allowed Neighbor Tuple to be a reachable Neighbor Tuple
      with N_will_routing > WILL_NEVER.

   o  Define an allowed 2-Hop Tuple to be a 2-Hop Tuple in the 2-Hop Set
      for any OLSRv2 interface with N2_in_metric != UNKNOWN_METRIC and
      for which there is an allowed Neighbor Tuple with
      N_neighbor_addr_list containing N2_neighbor_iface_addr_list.

   o  Define an element of N1 for each allowed Neighbor Tuple.  This
      then defines the corresponding Neighbor Tuple for each element of
      N1.





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   o  For each element x in N1, define W(x) := N_will_routing of the
      corresponding Neighbor Tuple.

   o  For each element x in N1, define d1(x) := N_in_metric of the
      corresponding Neighbor Tuple.

   o  Define an element of N2 for each network address that is the
      N2_2hop_addr of one or more allowed 2-Hop Tuples.  This then
      defines the corresponding address for each element of N2.

   o  For each element y in N2, if the corresponding address is in the
      N_neighbor_addr_list of a reachable Neighbor Tuple, then define
      d1(y) to be the N_in_metric of that Neighbor Tuple; otherwise,
      d1(y) is not defined.

   o  For each element x in N1, define N2(x) as the set of elements y in
      N2 whose corresponding address is the N2_2hop_addr of an allowed
      2-Hop Tuple that has N2_neighbor_iface_addr_list contained in
      N_neighbor_addr_list of the Neighbor Tuple corresponding to x.
      For all such x and y, define d2(x,y) := N2_out_metric of that
      2-Hop Tuple.

   It is up to an implementation to decide how to label each element of
   N1 or N2.  For example, an element of N1 may be labeled with one or
   more addresses from the corresponding N_neighbor_addr_list or with a
   pointer or reference to the corresponding Neighbor Tuple.

   Using these Neighbor Graphs, routing MPRs are selected and recorded
   according to the following:

   o  Determine an MPR Set as specified in Section 18.3.

   o  A Neighbor Tuple represents a routing MPR and has N_routing_mpr :=
      true (otherwise, N_routing_mpr := false) if and only if that
      Neighbor Tuple corresponds to an element in the MPR Set created as
      described above.

18.6.  Calculating MPRs

   A router MUST recalculate each of its sets of MPRs whenever the
   currently selected set of MPRs does not still satisfy the required
   conditions.  It MAY recalculate its MPRs if the current set of MPRs
   is still valid but could be more efficient.  Sufficient conditions to
   recalculate a router's sets of MPRs are given in Section 17.6.







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19.  Routing Set Calculation

   The Routing Set of a router is populated with Routing Tuples that
   represent paths from that router to all destinations in the network.
   These paths are calculated based on the Network Topology Graph, which
   is constructed from information in the Information Bases, obtained
   via HELLO and TC message exchange.

   Changes to the Routing Set do not require any messages to be
   transmitted.  The state of the Routing Set SHOULD, however, be
   reflected in the IP routing table by adding and removing entries from
   that routing table as appropriate.  Only appropriate Routing Tuples
   (in particular only those that represent local links or paths to
   routable addresses) need be reflected in the IP routing table.

19.1.  Network Topology Graph

   The Network Topology Graph is formed from information from the
   router's Local Interface Set, Link Sets for OLSRv2 interfaces,
   Neighbor Set, Router Topology Set, Routable Address Topology Set, and
   Attached Network Set.  The Network Topology Graph MAY also use
   information from the router's 2-Hop Sets for OLSRv2 interfaces.  The
   Network Topology Graph forms the router's topological view of the
   network in the form of a directed graph.  Each edge in that graph has
   a metric value.  The Network Topology Graph has a "backbone" (within
   which minimum total metric routes will be constructed) containing the
   following edges:

   o  Edges X -> Y for all possible Y, and one X per Y, such that:

      *  Y is the N_orig_addr of a Neighbor Tuple; AND

      *  N_orig_addr is not unknown; AND

      *  X is in the I_local_iface_addr_list of a Local Interface Tuple;
         AND

      *  There is a Link Tuple with L_status = SYMMETRIC and
         L_out_metric != UNKNOWN_METRIC such that this Neighbor Tuple
         and this Local Interface Tuple correspond to it.  A network
         address from L_neighbor_iface_addr_list will be denoted R in
         this case.

      It SHOULD be preferred, where possible, to select R = Y and to
      select X from the Local Interface Tuple corresponding to the Link
      Tuple from which R was selected.  The metric for such an edge is
      the corresponding N_out_metric.




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   o  All edges W -> U such that:

      *  W is the TR_from_orig_addr of a Router Topology Tuple; AND

      *  U is the TR_to_orig_addr of the same Router Topology Tuple.

      The metric of such an edge is the corresponding TR_metric.

   The Network Topology Graph is further "decorated" with the following
   edges.  If a network address S, V, Z, or T equals a network address Y
   or W, then the edge terminating in the network address S, V, Z, or T
   MUST NOT be used in any path.

   o  Edges X -> S for all possible S, and one X per S, such that:

      *  S is in the N_neighbor_addr_list of a Neighbor Tuple; AND

      *  X is in the I_local_iface_addr_list of a Local Interface Tuple;
         AND

      *  There is a Link Tuple with L_status = SYMMETRIC and
         L_out_metric != UNKNOWN_METRIC such that this Neighbor Tuple
         and this Local Interface Tuple correspond to it.  A network
         address from L_neighbor_iface_addr_list will be denoted R in
         this case.

      It SHOULD be preferred, where possible, to select R = S and to
      select X from the Local Interface Tuple corresponding to the Link
      Tuple from which R was selected.  The metric for such an edge is
      the corresponding N_out_metric.

   o  All edges W -> V such that:

      *  W is the TA_from_orig_addr of a Routable Address Topology
         Tuple; AND

      *  V is the TA_dest_addr of the same Routable Address Topology
         Tuple.

      The metric for such an edge is the corresponding TA_metric.

   o  All edges W -> T such that:

      *  W is the AN_orig_addr of an Attached Network Tuple; AND

      *  T is the AN_net_addr of the same Attached Network Tuple.

      The metric for such an edge is the corresponding AN_metric.



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   o  (OPTIONAL) All edges Y -> Z such that:

      *  Z is a routable address and is the N2_2hop_addr of a 2-Hop
         Tuple with N2_out_metric != UNKNOWN_METRIC; AND

      *  Y is the N_orig_addr of the corresponding Neighbor Tuple; AND

      *  This Neighbor Tuple has N_will_routing not equal to WILL_NEVER.

      A path terminating with such an edge MUST NOT be used in
      preference to any other path.  The metric for such an edge is the
      corresponding N2_out_metric.

   Any part of the Topology Graph that is not connected to a local
   network address X is not used.  Only one selection X SHOULD be made
   from each I_local_iface_addr_list, and only one selection R SHOULD be
   made from any L_neighbor_iface_addr_list.  All edges have a hop count
   of 1, except edges W -> T that have a hop count of the corresponding
   value of AN_dist.

19.2.  Populating the Routing Set

   The Routing Set MUST contain the shortest paths for all destinations
   from all local OLSRv2 interfaces using the Network Topology Graph.
   This calculation MAY use any algorithm, including any means of
   choosing between paths of equal total metric.  (In the case of two
   paths of equal total metric but differing hop counts, the path with
   the lower hop count SHOULD be used.)

   Using the notation of Section 19.1, initially "backbone" paths using
   only edges X -> Y and W -> U need be constructed (using a minimum
   distance algorithm).  Then paths using only a final edge of the other
   types may be added.  These MUST NOT replace backbone paths with the
   same destination (and paths terminating in an edge Y -> Z SHOULD NOT
   replace paths with any other form of terminating edge).

   Each path will correspond to a Routing Tuple.  These will be of two
   types.  The first type will represent single edge paths, of type X ->
   S or X -> Y, by:

   o  R_local_iface_addr := X;

   o  R_next_iface_addr := R;

   o  R_dest_addr := S or Y;






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   o  R_dist := 1;

   o  R_metric := edge metric,

   where R is as defined in Section 19.1 for these types of edge.

   The second type will represent a multiple edge path, which will
   always have first edge of type X -> Y, and will have final edge of
   type W -> U, W -> V, W -> T, or Y -> Z.  The Routing Tuple will be:

   o  R_local_iface_addr := X;

   o  R_next_iface_addr := Y;

   o  R_dest_addr := U, V, T or Z;

   o  R_dist := the total hop count of all edges in the path;

   o  R_metric := the total metric of all edges in the path.

   Finally, Routing Tuples of the second type whose R_dest_addr is not
   routable MAY be discarded.

   An example algorithm for calculating the Routing Set of a router is
   given in Appendix C.

20.  Proposed Values for Parameters

   This protocol uses all parameters defined in [RFC6130] and additional
   parameters defined in this specification.  All but one (RX_HOLD_TIME)
   of these additional parameters are router parameters as defined in
   [RFC6130].  The proposed values of the additional parameters defined
   in the following sections are appropriate to the case where all
   parameters (including those defined in [RFC6130]) have a single
   value.  Proposed values for parameters defined in [RFC6130] are given
   in that specification.

   The following proposed values are based on experience with [RFC3626]
   deployments (such as documented in [McCabe]) and are considered
   typical.  They can be changed to accommodate different deployment
   requirements -- for example, a network with capacity-limited network
   interfaces would be expected to use greater values for message
   intervals, whereas a highly mobile network would be expected to use
   lower values for message intervals.  When determining these values,
   the constraints specified in Section 5 MUST be respected.






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   Note that routers in a MANET need not all use the same set of
   parameters, and those parameters that are indicated as interface
   parameters need not be the same on all OLSRv2 interfaces of a single
   router.

20.1.  Local History Time Parameters

   o  O_HOLD_TIME := 30 seconds

20.2.  Message Interval Parameters

   o  TC_INTERVAL := 5 seconds

   o  TC_MIN_INTERVAL := TC_INTERVAL/4

20.3.  Advertised Information Validity Time Parameters

   o  T_HOLD_TIME := 3 x TC_INTERVAL

   o  A_HOLD_TIME := T_HOLD_TIME

20.4.  Received Message Validity Time Parameters

   o  RX_HOLD_TIME := 30 seconds

   o  P_HOLD_TIME := 30 seconds

   o  F_HOLD_TIME := 30 seconds

20.5.  Jitter Time Parameters

   o  TP_MAXJITTER := HP_MAXJITTER

   o  TT_MAXJITTER := HT_MAXJITTER

   o  F_MAXJITTER := TT_MAXJITTER

20.6.  Hop Limit Parameter

   o  TC_HOP_LIMIT := 255

20.7.  Willingness Parameters

   o  WILL_FLOODING := WILL_DEFAULT

   o  WILL_ROUTING := WILL_DEFAULT





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21.  Sequence Numbers

   Sequence numbers are used in this specification for the purpose of
   discarding "old" information, i.e., messages received out of order.
   However, with a limited number of bits for representing sequence
   numbers, wraparound (in which the sequence number is incremented from
   the maximum possible value to zero) will occur.  To prevent this from
   interfering with the operation of this protocol, the following MUST
   be observed when determining the ordering of sequence numbers.

   The term MAXVALUE designates in the following one more than the
   largest possible value for a sequence number.  For a 16-bit sequence
   number (like those defined in this specification), MAXVALUE is 65536.

   The sequence number S1 is said to be "greater than" the sequence
   number S2 if:

   o  S1 > S2 AND S1 - S2 < MAXVALUE/2, OR

   o  S2 > S1 AND S2 - S1 > MAXVALUE/2

   When sequence numbers S1 and S2 differ by MAXVALUE/2, their ordering
   cannot be determined.  In this case, which should not occur, either
   ordering may be assumed.

   Thus, when comparing two messages, it is possible -- even in the
   presence of wraparound -- to determine which message contains the
   most recent information.

22.  Extensions

   An extension to this protocol will need to interact with this
   specification and possibly also with [RFC6130].  This protocol is
   designed to permit such interactions, in particular:

   o  Through accessing, and possibly extending, the information in the
      Information Bases.  All updates to the elements specified in this
      specification are subject to the normative constraints specified
      in [RFC6130] and Appendix A.  Note that the processing specified
      in this document ensures that these constraints are satisfied.

   o  Through accessing an outgoing message prior to it being
      transmitted over any OLSRv2 interface and adding information to it
      as specified in [RFC5444].  This MAY include Message TLVs and/or
      network addresses with associated Address Block TLVs.  (Network
      addresses without new associated TLVs SHOULD NOT be added to





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      messages.)  This may, for example, be to allow a security
      protocol, as suggested in Section 23, to add a TLV containing a
      cryptographic signature to the message.

   o  Through accessing an incoming message and potentially discarding
      it prior to processing by this protocol.  This may, for example,
      allow a security protocol, as suggested in Section 23, to perform
      verification of message signatures and prevent processing and/or
      forwarding of unverifiable messages by this protocol.

   o  Through accessing an incoming message after it has been completely
      processed by this protocol.  In particular, this may allow a
      protocol that has added information, by way of inclusion of
      appropriate TLVs or of network addresses associated with new TLVs,
      access to such information after appropriate updates have been
      recorded in the Information Bases in this protocol.

   o  Through requesting that a message be generated at a specific time.
      In that case, message generation MUST still respect the
      constraints in [RFC6130] and Section 5.4.3.

23.  Security Considerations

   As a proactive routing protocol, OLSRv2 is a potential target for
   various attacks.  This section presents the envisioned security
   architecture for OLSRv2 and gives guidelines on how to provide
   integrity, confidentiality, and integration into external routing
   domains.  Separately specified mandatory security mechanisms are
   summarized, and some observations on key management are given.

23.1.  Security Architecture

   OLSRv2 integrates into the architecture specified in Appendix A of
   [RFC5444], in [RFC5498], and in Section 16 of [RFC6130], the latter
   by using and extending its messages and Information Bases.

   As part of this architecture, OLSRv2 and NHDP [RFC6130] recognize
   that there may be external reasons for rejecting messages that would
   be considered "badly formed" or "insecure", e.g., if an Integrity
   Check Value (ICV) included in a message by an external mechanism
   cannot be verified.  This architecture allows options as to whether
   and how to implement security features, reflecting the situation that
   MANET routing protocol deployment domains have varying security
   requirements, ranging from "practically unbreakable" to "virtually
   none".  This approach allows MANET routing protocol specifications to
   remain generic, with extensions to them and/or extensions to the





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   multiplexing and demultiplexing process described in Appendix A of
   [RFC5444], providing security mechanisms appropriate to a given
   deployment domain.

   The following sections provide guidelines on how to provide
   integrity, confidentiality, and integration with external routing
   domains in such extensions.

23.2.  Integrity

   Each router injects topological information into the network by
   transmitting HELLO messages and, for some routers, also TC messages.
   If some routers for some reason (malice or malfunction) inject
   invalid control traffic, network integrity may be compromised.
   Therefore, message, or packet, authentication is strongly advised.

   Different such situations may occur, for example:

   1.  A router generates TC messages, advertising links to non-neighbor
       routers;

   2.  A router generates TC messages, pretending to be another router;

   3.  A router generates HELLO messages, advertising non-neighbor
       routers;

   4.  A router generates HELLO messages, pretending to be another
       router;

   5.  A router forwards altered control messages;

   6.  A router does not forward control messages;

   7.  A router does not select multipoint relays correctly;

   8.  A router forwards broadcast control messages unaltered but does
       not forward unicast data traffic;

   9.  A router "replays" previously recorded control traffic from
       another router.

   Authentication of the originator router for control messages (for
   situations 2, 4, and 5) and of the individual links announced in the
   control messages (for situations 1 and 3) may be used as a
   countermeasure.  However, to prevent routers from repeating old (and
   correctly authenticated) information (situation 9), additional
   information is required (e.g., a timestamp or sequence number),
   allowing a router to positively identify such replayed messages.



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   In general, ICVs (e.g., digital signatures) and other required
   security information can be transmitted within the HELLO and TC
   messages or within a packet header using the TLV mechanism.  Either
   option permits different levels of protection to coexist in the same
   network, if desired.

   An important consideration is that all control messages (HELLO
   messages and TC messages) are transmitted to all routers in the 1-hop
   neighborhood and some control messages (TC messages) are flooded to
   all routers in the network.  This is done in a packet that is
   transmitted to all routers in the 1-hop neighborhood, the current set
   of which may not be known.  Thus, a control message or packet used by
   this protocol is always contained in a transmission destined for
   multiple destinations, and it is important that the authentication
   mechanism employed permits any receiving router to validate the
   authenticity of a message or packet.

   [RFC7182] specifies a common exchange format for cryptographic
   information in the form of Packet TLVs, Message TLVs, and Address
   Block TLVs, as specified in [RFC5444].  These may be used (and
   shared) among MANET routing protocol security extensions.  In
   particular, [RFC7182] specifies the format of TLVs for containing
   Integrity Check Values (ICVs), i.e., signatures, for providing
   integrity, as well as TLVs for containing temporal information for
   preventing replay attacks.  [RFC7182] specifies registries for using
   different ciphers and formats of temporal information.  When using
   ICV TLVs in an OLSRv2 deployment, failure to verify an included ICV
   mandates rejection of an incoming message or packet as "invalid",
   according to Section 12.1 of [RFC6130] and according to
   Section 16.3.1 of this specification when using the multiplexing and
   demultiplexing process described in Appendix A of [RFC5444].

   [RFC7182] specifies how to insert ICVs into generated messages, how
   to verify incoming messages, and to reject "insecure" messages (i.e.,
   messages without an ICV or with an ICV that cannot be verified).
   Different MANET deployments may, as a result of the purpose for which
   they are used and the possibility and nature of their configuration,
   require different ICV algorithms and timestamps or multiple keys, and
   thus, a security extension may use any of the different options
   provided in [RFC7182].

23.3.  Confidentiality

   OLSRv2 periodically MPR floods topological information to all routers
   in the network.  Hence, if used in an unprotected network, in
   particular, an unprotected wireless network, the network topology is
   revealed to anyone who successfully listens to the control messages.
   This information may serve an attacker to acquire details about the



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   topology and therefore to initiate more effective attacks against
   routers in the routing domain, e.g., by spoofing addresses of routers
   in the network and attracting traffic for these addresses.  Note that
   this is independent of the data traffic and purely protects the
   control traffic, i.e., information about the network topology.

   In situations where the confidentiality of the network topology is of
   importance, regular cryptographic techniques, such as use of OLSRv2
   multicast control packets encrypted using IPsec (e.g., with a shared
   secret key), can be applied to ensure that control traffic can be
   read and interpreted by only those authorized to do so.
   Alternatively, a security extension may specify a mechanism to
   provide confidentiality for control messages and/or packets.
   However, unless the information about the network topology itself is
   confidential, integrity of control messages (as specified in
   Section 23.2) is sufficient to admit only trusted routers (i.e.,
   routers with valid credentials) to the network.

23.4.  Interaction with External Routing Domains

   This protocol provides a basic mechanism for injecting external
   routing information into this protocol's routing domain.  Routing
   information can also be extracted from this protocol's Information
   Bases, in particular the Routing Set, and injected into an external
   routing domain, if the routing protocol governing that routing domain
   permits this.

   When operating routers connecting a routing domain using this
   protocol to an external routing domain, care MUST be taken not to
   allow potentially insecure and untrustworthy information to be
   injected from this routing domain to an external routing domain.
   Care MUST also be taken to validate the correctness of information
   prior to it being injected, so as to avoid polluting routing tables
   with invalid information.

   A recommended way of extending connectivity from an external routing
   domain to this routing domain, which is routed using this protocol,
   is to assign an IP prefix (under the authority of the routers/
   gateways connecting this routing domain with the external routing
   domain) exclusively to this routing domain and to configure the
   gateways to advertise routes for that IP prefix into the external
   routing domain.

23.5.  Mandatory Security Mechanisms

   A conformant implementation of OLSRv2 MUST, at minimum, implement the
   security mechanisms specified in [RFC7183], providing integrity and
   replay protection of OLSRv2 control messages, including of HELLO



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   messages specified by [RFC6130] and used by OLSRv2, by inclusion of a
   timestamp TLV and an Integrity Check Value (ICV) TLV.  This ICV TLV
   uses a SHA-256-based HMAC and one or more manually managed shared
   secret keys.  The timestamp TLV is based on Portable Operating System
   Interface (POSIX) time, assuming router time synchronization.

   The baseline use case, for which this security mechanism provides
   adequate integrity protection without rekeying, is for short-lived
   (for example, up to a couple of months) OLSRv2 deployments.

   Any deployment of OLSRv2 SHOULD use the security mechanism specified
   in [RFC7183] but MAY use another mechanism if more appropriate in an
   OLSRv2 deployment.  For example, for longer-term OLSRv2 deployments,
   alternative security mechanisms (e.g., rekeying) SHOULD be
   considered.

23.6.  Key Management

   This specification, as well as [RFC7183], does not mandate automated
   key management (AKM) as part of the security architecture for OLSRv2.
   While some use cases for OLSRv2 may require AKM, the baseline
   assumption is that many use cases do not, for the reasons detailed
   below.

   Bootstrapping a key is hard in a radio network, where it is, in
   general, not possible to determine from where a received signal was
   transmitted or if two transmissions come from the same or from
   different sources.

   The widespread use of radio networks and mobile phone networks works
   under the assumptions that (i) secret information is embedded in
   mobile phones at manufacture, and (ii) a centralized database of this
   is accessible during the network lifetime.

   As a primary use case of a MANET is to provide connectivity without
   centralized entities and with minimal management, a solution such as
   described in the previous paragraph is not feasible.  In many
   instances, a cryptographic authority may not be present in the MANET
   at all, since such a cryptographic authority would be too vulnerable.
   Due to the potentially dynamic topology of a MANET, a cryptographic
   authority may also become unreachable (to some or all of the MANET
   routers) without prior warning.

   [BCP107] provides guidelines for cryptographic key management.
   Specifically, Section 2.1 sets forth requirements for when AKM is
   required, and Section 2.2 sets forth conditions under which manual
   key management is acceptable.




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   Section 2.1 of [BCP107] stipulates that "Automated key management
   MUST be used if any of [a set of given] conditions hold".  These
   conditions are listed below, and arguments for each are provided in
   regard to their applicability for the baseline use case of OLSRv2.

   o  A party will have to manage n^2 static keys, where n may become
      large.

      The baseline use case of OLSRv2 uses only one or a small set of
      manually managed shared secrets in the whole MANET.

   o  Any stream cipher (such as RC4 [RFC6229][RC4], AES-CTR
      [RFC3610][NIST-SP-800-38A], or AES-CCM [RFC3686][NIST-SP-800-38C])
      is used.

      A stream cipher is not envisioned for use to generate ICVs for
      OLSRv2 control messages.

   o  An initialization vector (IV) might be reused, especially an
      implicit IV.  Note that random or pseudo-random explicit IVs are
      not a problem unless the probability of repetition is high.

      An IV is not envisioned for use to generate ICVs for OLSRv2
      control messages.

   o  Large amounts of data might need to be encrypted in a short time,
      causing frequent change of the short-term session key.

      Integrity Check Values (ICVs) are required only for OLSRv2 control
      messages, which are low-volume messages.

   o  Long-term session keys are used by more than two parties.
      Multicast is a necessary exception, but multicast key management
      standards are emerging in order to avoid this in the future.
      Sharing long-term session keys should generally be discouraged.

      OLSRv2 control messages are all sent using link-local multicast.

   o  The likely operational environment is one where personnel (or
      device) turnover is frequent, causing frequent change of the
      short-term session key.

      This is not an intended deployment of OLSRv2.  For longer-term
      OLSRv2 deployments, alternative security mechanisms (e.g.,
      including rekeying) SHOULD be considered.






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   Section 2.2 of [BCP107] stipulates that "Manual key management may be
   a reasonable approach in any of [a given set of] situations".  These
   situations are listed below, and arguments for each are provided in
   regard to their applicability for the baseline use case of OLSRv2.

   o  The environment has very limited available bandwidth or very high
      round-trip times.  Public key systems tend to require long
      messages and lots of computation; symmetric key alternatives, such
      as Kerberos, often require several round trips and interaction
      with third parties.

      As previously noted, there may not be the required infrastructure
      (cryptographic authority) present (or, if present, may not be
      reachable) in the MANET.  Bandwidth in a MANET is commonly
      limited, both by being a radio environment and by the need for any
      signaling to consume a minimal proportion thereof, and round trip
      times may also be significant.

   o  The information being protected has low value.

      This depends on the OLSRv2 use case, but the information being
      protected is OLSRv2 control traffic, which is of at least moderate
      value; thus, this case does not apply.

   o  The total volume of traffic over the entire lifetime of the long-
      term session key will be very low.

      Integrity Check Values (ICVs) are required only for OLSRv2 control
      messages, which are low-volume messages.

   o  The scale of each deployment is very limited.

      A typical use case for OLSRv2 may involve only tens of devices --
      with even the largest use cases for OLSRv2 being small by Internet
      standards.

24.  IANA Considerations

   This specification defines one Message Type, which has been allocated
   from the "Message Types" registry of [RFC5444], two Message TLV
   Types, which have been allocated from the "Message TLV Types"
   registry of [RFC5444], and four Address Block TLV Types, which have
   been allocated from the "Address Block TLV Types" registry of
   [RFC5444].







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24.1.  Expert Review: Evaluation Guidelines

   For the registries where an Expert Review is required, the designated
   expert SHOULD take the same general recommendations into
   consideration as are specified by [RFC5444].

24.2.  Message Types

   This specification defines one Message Type, allocated from the 0-223
   range of the "Message Types" namespace defined in [RFC5444], as
   specified in Table 8.

          +------+----------------------------------------------+
          | Type | Description                                  |
          +------+----------------------------------------------+
          |  1   | TC : Topology Control (MANET-wide signaling) |
          +------+----------------------------------------------+

                     Table 8: Message Type Assignment

24.3.  Message-Type-Specific TLV Type Registries

   IANA has created a registry for Message-Type-specific Message TLVs
   for TC messages, in accordance with Section 6.2.1 of [RFC5444] and
   with initial assignments and allocation policies as specified in
   Table 9.

               +---------+-------------+-------------------+
               |   Type  | Description | Allocation Policy |
               +---------+-------------+-------------------+
               | 128-223 | Unassigned  | Expert Review     |
               +---------+-------------+-------------------+

            Table 9: TC Message-Type-Specific Message TLV Types

   IANA has created a registry for Message-Type-specific Address Block
   TLVs for TC messages, in accordance with Section 6.2.1 of [RFC5444]
   and with initial assignments and allocation policies as specified in
   Table 10.

               +---------+-------------+-------------------+
               |   Type  | Description | Allocation Policy |
               +---------+-------------+-------------------+
               | 128-223 | Unassigned  | Expert Review     |
               +---------+-------------+-------------------+

        Table 10: TC Message-Type-Specific Address Block TLV Types




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24.4.  Message TLV Types

   This specification defines two Message TLV Types, which have been
   allocated from the "Message TLV Types" namespace defined in
   [RFC5444].  IANA has made allocations in the 0-127 range for these
   types.  Two new Type Extension registries have been created with
   assignments as specified in Table 11 and Table 12.  Specifications of
   these TLVs are in Section 13.3.1.  Each of these TLVs MUST NOT be
   included more than once in a Message TLV Block.

   +-------------+------+-----------+---------------------+------------+
   |     Name    | Type |    Type   | Description         | Allocation |
   |             |      | Extension |                     | Policy     |
   +-------------+------+-----------+---------------------+------------+
   | MPR_WILLING |  7   |     0     | Bits 0-3 specify    |            |
   |             |      |           | the originating     |            |
   |             |      |           | router's            |            |
   |             |      |           | willingness to act  |            |
   |             |      |           | as a flooding MPR;  |            |
   |             |      |           | bits 4-7 specify    |            |
   |             |      |           | the originating     |            |
   |             |      |           | router's            |            |
   |             |      |           | willingness to act  |            |
   |             |      |           | as a routing MPR.   |            |
   | MPR_WILLING |  7   |   1-255   | Unassigned.         | Expert     |
   |             |      |           |                     | Review     |
   +-------------+------+-----------+---------------------+------------+

            Table 11: Message TLV Type Assignment: MPR_WILLING






















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   +--------------+------+-----------+--------------------+------------+
   |     Name     | Type |    Type   | Description        | Allocation |
   |              |      | Extension |                    | Policy     |
   +--------------+------+-----------+--------------------+------------+
   | CONT_SEQ_NUM |  8   |     0     | COMPLETE:          |            |
   |              |      |           | Specifies a        |            |
   |              |      |           | content sequence   |            |
   |              |      |           | number for this    |            |
   |              |      |           | complete message.  |            |
   | CONT_SEQ_NUM |  8   |     1     | INCOMPLETE:        |            |
   |              |      |           | Specifies a        |            |
   |              |      |           | content sequence   |            |
   |              |      |           | number for this    |            |
   |              |      |           | incomplete         |            |
   |              |      |           | message.           |            |
   | CONT_SEQ_NUM |  8   |   2-255   | Unassigned.        | Expert     |
   |              |      |           |                    | Review     |
   +--------------+------+-----------+--------------------+------------+

            Table 12: Message TLV Type Assignment: CONT_SEQ_NUM

   Type extensions indicated as Expert Review SHOULD be allocated as
   described in [RFC5444], based on Expert Review as defined in
   [RFC5226].

24.5.  Address Block TLV Types

   This specification defines four Address Block TLV Types, which have
   been allocated from the "Address Block TLV Types" namespace defined
   in [RFC5444].  IANA has made allocations in the 8-127 range for these
   types.  Four new Type Extension registries have been created with
   assignments as specified in Tables 13, 14, 15, and 16.
   Specifications of these TLVs are in Section 13.3.2.

   The registration procedure for the "LINK_METRIC Address Block TLV
   Type Extensions" registry is Expert Review.

   +-------------+------+-----------+----------------------------------+
   |     Name    | Type |    Type   | Description                      |
   |             |      | Extension |                                  |
   +-------------+------+-----------+----------------------------------+
   | LINK_METRIC |  7   |     0     | Link metric meaning assigned by  |
   |             |      |           | administrative action.           |
   | LINK_METRIC |  7   |   1-223   | Unassigned.                      |
   | LINK_METRIC |  7   |  224-255  | Reserved for Experimental Use    |
   +-------------+------+-----------+----------------------------------+

         Table 13: Address Block TLV Type Assignment: LINK_METRIC



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   All LINK_METRIC TLVs, whatever their type extension, MUST use their
   value field to encode the kind and value (in the interval
   MINIMUM_METRIC to MAXIMUM_METRIC, inclusive) of a link metric as
   specified in Sections 6 and 13.3.2.  An assignment of a LINK_METRIC
   TLV type extension MUST specify the physical meaning of the link
   metric and the mapping of that physical meaning to the representable
   values in the indicated interval.

   +------+------+-----------+----------------------------+------------+
   | Name | Type |    Type   | Description                | Allocation |
   |      |      | Extension |                            | Policy     |
   +------+------+-----------+----------------------------+------------+
   | MPR  |  8   |     0     | Specifies that a given     |            |
   |      |      |           | network address is of a    |            |
   |      |      |           | router selected as a       |            |
   |      |      |           | flooding MPR (FLOODING =   |            |
   |      |      |           | 1), that a given network   |            |
   |      |      |           | address is of a router     |            |
   |      |      |           | selected as a routing MPR  |            |
   |      |      |           | (ROUTING = 2), or both     |            |
   |      |      |           | (FLOOD_ROUTE = 3).         |            |
   | MPR  |  8   |   1-255   | Unassigned.                | Expert     |
   |      |      |           |                            | Review     |
   +------+------+-----------+----------------------------+------------+

             Table 14: Address Block TLV Type Assignment: MPR

























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   +---------------+------+-----------+-------------------+------------+
   |      Name     | Type |    Type   | Description       | Allocation |
   |               |      | Extension |                   | Policy     |
   +---------------+------+-----------+-------------------+------------+
   | NBR_ADDR_TYPE |  9   |     0     | Specifies that a  |            |
   |               |      |           | given network     |            |
   |               |      |           | address is of a   |            |
   |               |      |           | neighbor reached  |            |
   |               |      |           | via the           |            |
   |               |      |           | originating       |            |
   |               |      |           | router, if it is  |            |
   |               |      |           | an originator     |            |
   |               |      |           | address           |            |
   |               |      |           | (ORIGINATOR = 1), |            |
   |               |      |           | is a routable     |            |
   |               |      |           | address (ROUTABLE |            |
   |               |      |           | = 2), or if it is |            |
   |               |      |           | both              |            |
   |               |      |           | (ROUTABLE_ORIG =  |            |
   |               |      |           | 3).               |            |
   | NBR_ADDR_TYPE |  9   |   1-255   | Unassigned.       | Expert     |
   |               |      |           |                   | Review     |
   +---------------+------+-----------+-------------------+------------+

        Table 15: Address Block TLV Type Assignment: NBR_ADDR_TYPE

   +---------+------+-----------+-------------------------+------------+
   |   Name  | Type |    Type   | Description             | Allocation |
   |         |      | extension |                         | Policy     |
   +---------+------+-----------+-------------------------+------------+
   | GATEWAY |  10  |     0     | Specifies that a given  |            |
   |         |      |           | network address is      |            |
   |         |      |           | reached via a gateway   |            |
   |         |      |           | on the originating      |            |
   |         |      |           | router, with value      |            |
   |         |      |           | equal to the number of  |            |
   |         |      |           | hops.                   |            |
   | GATEWAY |  10  |   1-255   |                         | Expert     |
   |         |      |           |                         | Review     |
   +---------+------+-----------+-------------------------+------------+

           Table 16: Address Block TLV Type Assignment: GATEWAY

   Type extensions indicated as Expert Review SHOULD be allocated as
   described in [RFC5444], based on Expert Review as defined in
   [RFC5226].





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24.6.  NBR_ADDR_TYPE and MPR Values

   Note: This section does not require any IANA action, as the required
   information is included in the descriptions of the MPR and
   NBR_ADDR_TYPE Address Block TLVs allocated in Section 24.5.  This
   information is recorded here for clarity and for use elsewhere in
   this specification.

   The Values that the MPR Address Block TLV can use are as follows:

   o  FLOODING := 1;

   o  ROUTING := 2;

   o  FLOOD_ROUTE := 3.

   The Values that the NBR_ADDR_TYPE Address Block TLV can use are
   follows:

   o  ORIGINATOR := 1;

   o  ROUTABLE := 2;

   o  ROUTABLE_ORIG := 3.

25.  Contributors

   This specification is the result of the joint efforts of the
   following contributors, listed alphabetically.

   o  Cedric Adjih, INRIA, France, <Cedric.Adjih@inria.fr>

   o  Emmanuel Baccelli, INRIA , France, <Emmanuel.Baccelli@inria.fr>

   o  Thomas Heide Clausen, LIX, France, <T.Clausen@computer.org>

   o  Justin Dean, NRL, USA, <jdean@itd.nrl.navy.mil>

   o  Christopher Dearlove, BAE Systems, UK,
      <chris.dearlove@baesystems.com>

   o  Ulrich Herberg, Fujitsu Laboratories of America, USA,
      <ulrich@herberg.name>

   o  Satoh Hiroki, Hitachi SDL, Japan, <hiroki.satoh.yj@hitachi.com>

   o  Philippe Jacquet, Alcatel Lucent Bell Labs, France,
      <philippe.jacquet@alcatel-lucent.fr>



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   o  Monden Kazuya, Hitachi SDL, Japan, <kazuya.monden.vw@hitachi.com>

   o  Kenichi Mase, Niigata University, Japan, <mase@ie.niigata-u.ac.jp>

   o  Ryuji Wakikawa, Toyota, Japan, <ryuji@sfc.wide.ad.jp>

26.  Acknowledgments

   The authors would like to acknowledge the team behind OLSRv1, as
   listed in RFC 3626, including Anis Laouiti (INT), Pascale Minet
   (INRIA), Paul Muhlethaler (INRIA), Amir Qayyum (M.A. Jinnah
   University), and Laurent Viennot (INRIA) for their contributions.

   The authors would like to gratefully acknowledge the following people
   for intense technical discussions, early reviews, and comments on the
   specification and its components (listed alphabetically): Khaldoun Al
   Agha (LRI), Teco Boot (Infinity Networks), Ross Callon (Juniper),
   Song-Yean Cho (Samsung), Alan Cullen (BAE Systems), Louise Lamont
   (CRC), Li Li (CRC), Joseph Macker (NRL), Richard Ogier (SRI), Charles
   E. Perkins (Futurewei), Henning Rogge (Frauenhofer FKIE), and the
   entire IETF MANET Working Group.

   Finally, the authors would like to express their gratitude to the
   Area Directors for providing valuable review comments during the IESG
   evaluation, in particular (listed alphabetically) Benoit Claise,
   Adrian Farrel, Stephen Farrell, Barry Leiba, Pete Resnick, and Martin
   Stiemerling.

27.  References

27.1.  Normative References

   [RFC2119]   Bradner, S., "Key words for use in RFCs to Indicate
               Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC5148]   Clausen, T., Dearlove, C., and B. Adamson, "Jitter
               Considerations in Mobile Ad Hoc Networks (MANETs)", RFC
               5148, February 2008.

   [RFC5226]   Narten, T. and H. Alvestrand, "Guidelines for Writing an
               IANA Considerations Section in RFCs", BCP 26, RFC 5226,
               May 2008.

   [RFC5444]   Clausen, T., Dearlove, C., Dean, J., and C. Adjih,
               "Generalized Mobile Ad Hoc Network (MANET) Packet/Message
               Format", RFC 5444, February 2009.





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   [RFC5497]   Clausen, T. and C. Dearlove, "Representing Multi-Value
               Time in Mobile Ad Hoc Networks (MANETs)", RFC 5497, March
               2009.

   [RFC5498]   Chakeres, I., "IANA Allocations for Mobile Ad Hoc Network
               (MANET) Protocols", RFC 5498, March 2009.

   [RFC6130]   Clausen, T., Dearlove, C., and J. Dean, "Mobile Ad Hoc
               Network (MANET) Neighborhood Discovery Protocol (NHDP)",
               RFC 6130, April 2011.

   [RFC7182]   Herberg, U., Clausen, T., and C. Dearlove, "Integrity
               Check Value and Timestamp TLV Definitions for Mobile Ad
               Hoc Networks (MANETs)", RFC 7182, April 2014.

   [RFC7183]   Herberg, U., Dearlove, C., and T. Clausen, "Integrity
               Protection for the Neighborhood Discovery Protocol (NHDP)
               and Optimized Link State Routing Protocol Version 2
               (OLSRv2)", RFC 7183, April 2014.

27.2.  Informative References

   [BCP107]    Bellovin, S. and R. Housley, "Guidelines for
               Cryptographic Key Management", BCP 107, RFC 4107, June
               2005.

   [FSLS]      Santivanez, C., Ramanathan, R., and I. Stavrakakis,
               "Making Link-State Routing Scale for Ad Hoc Networks",
               MobiHoc '01, Proceedings of the 2nd ACM International
               Symposium on Mobile Ad Hoc Networking & Computing, 2001.

   [FSR]       Pei, G., Gerla, M., and T. Chen, "Fisheye State Routing
               in Mobile Ad Hoc Networks", ICDCS Workshop on Wireless
               Networks and Mobile Computing, 2000.

   [HIPERLAN]  ETSI, "Radio Equipment and Systems (RES); HIgh
               PErformance Radio Local Area Network (HIPERLAN) Type 1;
               Functional Specification", ETSI 300-652, June 1996.

   [HIPERLAN2] Jacquet, P., Minet, P., Muhlethaler, P., and N. Rivierre,
               "Increasing Reliability in Cable-Free Radio LANs: Low
               Level Forwarding in HIPERLAN", Wireless Personal
               Communications, Volume 4, Issue 1, 1997.

   [MPR]       Qayyum, A., Viennot, L., and A. Laouiti, "Multipoint
               relaying: An efficient technique for flooding in mobile
               wireless Networks", INRIA, No. 3898, March 2000.




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   [McCabe]    McCabe, A., Dearlove, C., Fredin, M., and L. Axelsson,
               "Scalability modelling of ad hoc routing protocols - a
               comparison of OLSR and DSR", Scandinavian Wireless Adhoc
               Networks '04, 2004.

   [NIST-SP-800-38A]
               National Institute of Standards and Technology,
               "Recommendation for Block Cipher Modes of Operation:
               Methods and Techniques", Special Publication 800-38A,
               December 2001.

   [NIST-SP-800-38C]
               National Institute of Standards and Technology,
               "Recommendation for Block Cipher Modes of Operation: The
               CCM Mode for Authentication and Confidentiality", Special
               Publication 800-38C, May 2004.

   [RC4]       Schneier, B., "Applied Cryptography: Protocols,
               Algorithms, and Source Code in C", Second Edition, John
               Wiley and Sons, New York, 1996.

   [RFC2501]   Corson, M. and J. Macker, "Mobile Ad hoc Networking
               (MANET): Routing Protocol Performance Issues and
               Evaluation Considerations", RFC 2501, January 1999.

   [RFC3610]   Whiting, D., Housley, R., and N. Ferguson, "Counter with
               CBC-MAC (CCM)", RFC 3610, September 2003.

   [RFC3626]   Clausen, T. and P. Jacquet, "Optimized Link State Routing
               Protocol (OLSR)", RFC 3626, October 2003.

   [RFC3686]   Housley, R., "Using Advanced Encryption Standard (AES)
               Counter Mode With IPsec Encapsulating Security Payload
               (ESP)", RFC 3686, January 2004.

   [RFC6229]   Strombergson, J. and S. Josefsson, "Test Vectors for the
               Stream Cipher RC4", RFC 6229, May 2011.














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Appendix A.  Constraints

   Updates to the Local Information Base, the Neighborhood Information
   Base, or the Topology Information Base MUST ensure that all
   constraints specified in this appendix are maintained, as well as
   those specified in [RFC6130].  This is the case for the processing,
   specified in this document.  Any protocol extension or outside
   process, which updates the Neighborhood Information Base or the
   Topology Information Base, MUST also ensure that these constraints
   are maintained.

   In each Originator Tuple:

   o  O_orig_addr MUST NOT equal any other O_orig_addr.

   o  O_orig_addr MUST NOT equal this router's originator address.

   In each Local Attached Network Tuple:

   o  AL_net_addr MUST NOT equal any other AL_net_addr.

   o  AL_net_addr MUST NOT equal or be a sub-range of any network
      address in the I_local_iface_addr_list of any Local Interface
      Tuple.

   o  AL_net_addr MUST NOT equal this router's originator address or
      equal the O_orig_addr in any Originator Tuple.

   o  AL_dist MUST NOT be less than zero.

   In each Link Tuple:

   o  L_neighbor_iface_addr_list MUST NOT contain any network address
      that AL_net_addr of any Local Attached Network Tuple equals or is
      a sub-range of.

   o  If L_in_metric != UNKNOWN_METRIC, then L_in_metric MUST be
      representable in the defined compressed form.

   o  If L_out_metric != UNKNOWN_METRIC, then L_out_metric MUST be
      representable in the defined compressed form.

   o  If L_mpr_selector = true, then L_status = SYMMETRIC.








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   In each Neighbor Tuple:

   o  N_orig_addr MUST NOT be changed to unknown.

   o  N_orig_addr MUST NOT equal this router's originator address or
      equal O_orig_addr in any Originator Tuple.

   o  N_orig_addr MUST NOT equal the AL_net_addr in any Local Attached
      Network Tuple.

   o  If N_orig_addr != unknown, then N_orig_addr MUST NOT equal the
      N_orig_addr in any other Neighbor Tuple.

   o  N_neighbor_addr_list MUST NOT contain any network address that
      includes this router's originator address, the O_orig_addr in any
      Originator Tuple, or equal or have as a sub-range the AL_net_addr
      in any Local Attached Network Tuple.

   o  If N_orig_addr = unknown, then N_will_flooding = WILL_NEVER,
      N_will_routing = WILL_NEVER, N_flooding_mpr = false, N_routing_mpr
      = false, N_mpr_selector = false, and N_advertised = false.

   o  N_in_metric MUST equal the minimum value of the L_in_metric values
      of all corresponding Link Tuples with L_status = SYMMETRIC and
      L_in_metric != UNKNOWN_METRIC, if any; otherwise, N_in_metric =
      UNKNOWN_METRIC.

   o  N_out_metric MUST equal the minimum value of the L_out_metric
      values of all corresponding Link Tuples with L_status = SYMMETRIC
      and L_out_metric != UNKNOWN_METRIC, if any; otherwise,
      N_out_metric = UNKNOWN_METRIC.

   o  N_will_flooding and N_will_routing MUST be in the range from
      WILL_NEVER to WILL_ALWAYS, inclusive.

   o  If N_flooding_mpr = true, then N_symmetric MUST be true,
      N_out_metric MUST NOT equal UNKNOWN_METRIC, and N_will_flooding
      MUST NOT equal WILL_NEVER.

   o  If N_routing_mpr = true, then N_symmetric MUST be true,
      N_in_metric MUST NOT equal UNKNOWN_METRIC, and N_will_routing MUST
      NOT equal WILL_NEVER.

   o  If N_symmetric = true and N_flooding_mpr = false, then
      N_will_flooding MUST NOT equal WILL_ALWAYS.

   o  If N_symmetric = true and N_routing_mpr = false, then
      N_will_routing MUST NOT equal WILL_ALWAYS.



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   o  If N_mpr_selector = true, then N_advertised MUST be true.

   o  If N_advertised = true, then N_symmetric MUST be true and
      N_out_metric MUST NOT equal UNKNOWN_METRIC.

   In each Lost Neighbor Tuple:

   o  NL_neighbor_addr MUST NOT include this router's originator
      address, the O_orig_addr in any Originator Tuple, or equal or have
      as a sub-range the AL_net_addr in any Local Attached Network
      Tuple.

   In each 2-Hop Tuple:

   o  N2_2hop_addr MUST NOT equal this router's originator address,
      equal the O_orig_addr in any Originator Tuple, or equal or have as
      a sub-range the AL_net_addr in any Local Attached Network Tuple.

   o  If N2_in_metric != UNKNOWN_METRIC, then N2_in_metric MUST be
      representable in the defined compressed form.

   o  If N2_out_metric != UNKNOWN_METRIC, then N2_out_metric MUST be
      representable in the defined compressed form.

   In each Advertising Remote Router Tuple:

   o  AR_orig_addr MUST NOT be in any network address in the
      I_local_iface_addr_list in any Local Interface Tuple or be in the
      IR_local_iface_addr in any Removed Interface Address Tuple.

   o  AR_orig_addr MUST NOT equal this router's originator address or
      equal the O_orig_addr in any Originator Tuple.

   o  AR_orig_addr MUST NOT be in the AL_net_addr in any Local Attached
      Network Tuple.

   o  AR_orig_addr MUST NOT equal the AR_orig_addr in any other
      Advertising Remote Router Tuple.

   In each Router Topology Tuple:

   o  There MUST be an Advertising Remote Router Tuple with AR_orig_addr
      = TR_from_orig_addr.

   o  TR_to_orig_addr MUST NOT be in any network address in the
      I_local_iface_addr_list in any Local Interface Tuple or be in the
      IR_local_iface_addr in any Removed Interface Address Tuple.




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   o  TR_to_orig_addr MUST NOT equal this router's originator address or
      equal the O_orig_addr in any Originator Tuple.

   o  TR_to_orig_addr MUST NOT be in the AL_net_addr in any Local
      Attached Network Tuple.

   o  The ordered pair (TR_from_orig_addr, TR_to_orig_addr) MUST NOT
      equal the corresponding pair for any other Router Topology Tuple.

   o  TR_seq_number MUST NOT be greater than AR_seq_number in the
      Advertising Remote Router Tuple with AR_orig_addr =
      TR_from_orig_addr.

   o  TR_metric MUST be representable in the defined compressed form.

   In each Routable Address Topology Tuple:

   o  There MUST be an Advertising Remote Router Tuple with AR_orig_addr
      = TA_from_orig_addr.

   o  TA_dest_addr MUST be routable.

   o  TA_dest_addr MUST NOT overlap any network address in the
      I_local_iface_addr_list in any Local Interface Tuple or overlap
      the IR_local_iface_addr in any Removed Interface Address Tuple.

   o  TA_dest_addr MUST NOT include this router's originator address or
      include the O_orig_addr in any Originator Tuple.

   o  TA_dest_addr MUST NOT equal or have as a sub-range the AL_net_addr
      in any Local Attached Network Tuple.

   o  The ordered pair (TA_from_orig_addr, TA_dest_addr) MUST NOT equal
      the corresponding pair for any other Attached Network Tuple.

   o  TA_seq_number MUST NOT be greater than AR_seq_number in the
      Advertising Remote Router Tuple with AR_orig_addr =
      TA_from_orig_addr.

   o  TA_metric MUST be representable in the defined compressed form.

   In each Attached Network Tuple:

   o  There MUST be an Advertising Remote Router Tuple with AR_orig_addr
      = AN_orig_addr.






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   o  AN_net_addr MUST NOT equal or be a sub-range of any network
      address in the I_local_iface_addr_list in any Local Interface
      Tuple or equal or be a sub-range of the IR_local_iface_addr in any
      Removed Interface Address Tuple.

   o  AN_net_addr MUST NOT equal this router's originator address or
      equal the O_orig_addr in any Originator Tuple.

   o  The ordered pair (AN_orig_addr, AN_net_addr) MUST NOT equal the
      corresponding pair for any other Attached Network Tuple.

   o  AN_seq_number MUST NOT be greater than AR_seq_number in the
      Advertising Remote Router Tuple with AR_orig_addr = AN_orig_addr.

   o  AN_dist MUST NOT be less than zero.

   o  AN_metric MUST be representable in the defined compressed form.

Appendix B.  Example Algorithm for Calculating MPRs

   The following specifies an algorithm that MAY be used to select an
   MPR Set given a Neighbor Graph, as defined in Section 18.2 and
   Section 18.3.

   This algorithm selects an MPR Set M that is a subset of the set N1
   that is part of the Neighbor Graph.  This algorithm assumes that a
   subset I of N1 is pre-selected as MPRs, i.e., that M will contain I.

B.1.  Additional Notation

   The following additional notation, in addition to that in
   Section 18.2, will be used by this algorithm:

   N:
      A subset of N2, consisting of those elements y in N2 such that
      either d1(y) is not defined, or there is at least one x in N1 such
      that d(x,y) is defined and d(x,y) < d1(y).

   D(x):
      For an element x in N1, the number of elements y in N for which
      d(x,y) is defined and has minimal value among the d(z,y) for all z
      in N1.

   R(x,M):
      For an element x in N1, the number of elements y in N for which
      d(x,y) is defined has minimal value among the d(z,y) for all z in
      N1 and no such minimal values have z in M.  (Note that, denoting
      the empty set by 0, D(x) = R(x,0).)



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B.2.  MPR Selection Algorithm

   To create the MPR Set M, starting with M := I:

   1.  Add all elements x in N1 that have W(x) = WILL_ALWAYS to M.

   2.  For each element y in N for which there is only one element x in
       N1 such that d2(x,y) is defined, add that element x to M.

   3.  While there exists any element x in N1 with R(x,M) > 0:

       1.  Select an element x in N1 with R(x,M) > 0 in the following
           order of priority, and then add to M:

           +  greatest W(x), THEN

           +  greatest R(x,M), THEN

           +  greatest D(x), THEN

           +  any choice, which MAY be based on other criteria (for
              example, a router MAY choose to prefer a neighbor as an
              MPR if that neighbor has already selected the router as an
              MPR of the same type, MAY prefer a neighbor based on
              information freshness, or MAY prefer a neighbor based on
              length of time previously selected as an MPR) or MAY be
              random.

   4.  OPTIONAL: consider each element x in M, but not in I, in turn and
       if x can be removed from M while still leaving it satisfying the
       definition of an MPR Set, then remove that element x from M.
       Elements MAY be considered in any order, e.g., in order of
       increasing W(x).

Appendix C.  Example Algorithm for Calculating the Routing Set

   The following procedure is given as an example for calculating the
   Routing Set using a variation of Dijkstra's algorithm.  First, all
   Routing Tuples are removed, and then, using the selections and
   definitions in Appendix C.1, the procedures in the following sections
   (each considered a "stage" of the processing) are applied in turn.










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C.1.  Local Interfaces and Neighbors

   The following selections and definitions are made:

   1.  For each Local Interface Tuple, select a network address from its
       I_local_iface_addr_list.  This is defined as the selected address
       for this Local Interface Tuple.

   2.  For each Link Tuple, the selected address of its corresponding
       Local Interface Tuple is defined as the selected local address
       for this Link Tuple.

   3.  For each Neighbor Tuple with N_symmetric = true and N_out_metric
       != UNKNOWN_METRIC, select a Link Tuple with L_status = SYMMETRIC
       for which this is the corresponding Neighbor Tuple and has
       L_out_metric = N_out_metric.  This is defined as the selected
       Link Tuple for this Neighbor Tuple.

   4.  For each network address (N_orig_addr or in N_neighbor_addr_list,
       the "neighbor address") from a Neighbor Tuple with N_symmetric =
       true and N_out_metric != UNKNOWN_METRIC, select a Link Tuple (the
       "selected Link Tuple") from those for which this is the
       corresponding Neighbor Tuple, have L_status = SYMMETRIC, and have
       L_out_metric = N_out_metric, by:

       1.  If there is such a Link Tuple whose
           L_neighbor_iface_addr_list contains the neighbor address,
           select that Link Tuple.

       2.  Otherwise, select the selected Link Tuple for this Neighbor
           Tuple.

       Then for this neighbor address:

       3.  The selected local address is defined as the selected local
           address for the selected Link Tuple.

       4.  The selected link address is defined as an address from the
           L_neighbor_iface_addr_list of the selected Link Tuple, if
           possible equal to this neighbor address.

   5.  Routing Tuple preference is decided by preference for minimum
       R_metric, then for minimum R_dist, and then for preference for
       corresponding Neighbor Tuples in this order:

       *  For greater N_will_routing.

       *  For N_mpr_selector = true over N_mpr_selector = false.



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       Note that preferred Routing Tuples SHOULD be used.  Routing
       Tuples with minimum R_metric MUST be used; this is specified
       outside the definition of preference.  An implementation MAY
       modify this definition of preference (including for minimum
       R_dist) without otherwise affecting this algorithm.

C.2.  Add Neighbor Routers

   The following procedure is executed once.

   1.  For each Neighbor Tuple with N_symmetric = true and N_out_metric
       != UNKNOWN_METRIC, add a Routing Tuple with:

       *  R_dest_addr := N_orig_addr;

       *  R_next_iface_addr := selected link address for N_orig_addr;

       *  R_local_iface_addr := selected local address for N_orig_addr;

       *  R_metric := N_out_metric;

       *  R_dist := 1.

C.3.  Add Remote Routers

   The following procedure is executed once.

   1.  Add a label that may be "used" or "unused" to each Routing Tuple,
       with all initial values equal to unused.  (Note that this label
       is only required during this algorithm.)

   2.  If there are no unused Routing Tuples, then this stage is
       complete; otherwise, repeat the following until that is the case.

       1.  Find the unused Routing Tuple with minimum R_metric (if more
           than one, pick any) and denote it the "current Routing
           Tuple".

       2.  Mark the current Routing Tuple as used.

       3.  For each Router Topology Tuple, with
           TR_from_orig_addr = R_dest_addr of the current Routing Tuple:

           1.  Define:

               -  new_metric := R_metric of the current Routing Tuple +
                  TR_metric;




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               -  new_dist := R_dist of the current Routing Tuple + 1.

           2.  If there is no Routing Tuple with R_dest_addr =
               TR_to_orig_addr, then create an unused Routing Tuple
               with:

               -  R_dest_addr := TR_to_orig_addr;

               -  R_next_iface_addr := R_next_iface_addr of the current
                  Routing Tuple;

               -  R_local_iface_addr := R_local_iface_addr of the
                  current Routing Tuple;

               -  R_metric := new_metric;

               -  R_dist := new_dist.

           3.  Otherwise, if there is an unused Routing Tuple with
               R_dest_addr = TR_to_orig_addr, and either new_metric <
               R_metric or (new_metric = R_metric and the updated
               Routing Tuple would be preferred), then update this
               Routing Tuple to have:

               -  R_next_iface_addr := R_next_iface_addr of the current
                  Routing Tuple;

               -  R_local_iface_addr := R_local_iface_addr of the
                  current Routing Tuple;

               -  R_metric := new_metric;

               -  R_dist := new_dist.

C.4.  Add Neighbor Addresses

   The following procedure is executed once.

   1.  For each Neighbor Tuple with N_symmetric = true and N_out_metric
       != UNKNOWN_METRIC:

       1.  For each network address (the "neighbor address") in
           N_neighbor_addr_list, if the neighbor address is not equal to
           the R_dest_addr of any Routing Tuple, then add a new Routing
           Tuple, with:

           +  R_dest_addr := neighbor address;




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           +  R_next_iface_addr := selected link address for the
              neighbor address;

           +  R_local_iface_addr := selected local address for the
              neighbor address;

           +  R_metric := N_out_metric;

           +  R_dist := 1.

C.5.  Add Remote Routable Addresses

   The following procedure is executed once.

   1.  For each Routable Address Topology Tuple, if:

       *  TA_dest_addr is not equal to the R_dest_addr of any Routing
          Tuple added in an earlier stage; AND

       *  TA_from_orig_addr is equal to the R_dest_addr of a Routing
          Tuple (the "previous Routing Tuple"),

       then add a new Routing Tuple, with:

       *  R_dest_addr := TA_dest_addr;

       *  R_next_iface_addr := R_next_iface_addr of the previous Routing
          Tuple;

       *  R_local_iface_addr := R_local_iface_addr of the previous
          Routing Tuple;

       *  R_metric := R_metric of the previous Routing Tuple +
          TA_metric;

       *  R_dist := R_dist of the previous Routing Tuple + 1.

       There may be more than one Routing Tuple that may be added for an
       R_dest_addr in this stage.  If so, then for each such
       R_dest_addr, a Routing Tuple with minimum R_metric MUST be added;
       otherwise, a Routing Tuple that is preferred SHOULD be added.










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C.6.  Add Attached Networks

   The following procedure is executed once.

   1.  For each Attached Network Tuple, if:

       *  AN_net_addr is not equal to the R_dest_addr of any Routing
          Tuple added in an earlier stage; AND

       *  AN_orig_addr is equal to the R_dest_addr of a Routing Tuple
          (the "previous Routing Tuple"),

       then add a new Routing Tuple, with:

       *  R_dest_addr := AN_net_addr;

       *  R_next_iface_addr := R_next_iface_addr of the previous Routing
          Tuple;

       *  R_local_iface_addr := R_local_iface_addr of the previous
          Routing Tuple;

       *  R_metric := R_metric of the previous Routing Tuple +
          AN_metric;

       *  R_dist := R_dist of the previous Routing Tuple + AN_dist.

       There may be more than one Routing Tuple that may be added for an
       R_dest_addr in this stage.  If so, then for each such
       R_dest_addr, a Routing Tuple with minimum R_metric MUST be added;
       otherwise, a Routing Tuple that is preferred SHOULD be added.

C.7.  Add 2-Hop Neighbors

   The following procedure is OPTIONAL according to Section 19.1 and MAY
   be executed once.

   1.  For each 2-Hop Tuple with N2_out_metric != UNKNOWN_METRIC, if:

       *  N2_2hop_addr is a routable address; AND

       *  N2_2hop_addr is not equal to the R_dest_addr of any Routing
          Tuple added in an earlier stage; AND

       *  the Routing Tuple with R_dest_addr = N_orig_addr of the
          corresponding Neighbor Tuple (the "previous Routing Tuple")
          has R_dist = 1,




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       then add a new Routing Tuple, with:

       *  R_dest_addr := N2_2hop_addr;

       *  R_next_iface_addr := R_next_iface_addr of the previous Routing
          Tuple;

       *  R_local_iface_addr := R_local_iface_addr of the previous
          Routing Tuple;

       *  R_metric := R_metric of the previous Routing Tuple +
          N_out_metric of the corresponding Neighbor Tuple;

       *  R_dist := 2.

       There may be more than one Routing Tuple that may be added for an
       R_dest_addr in this stage.  If so, then for each such
       R_dest_addr, a Routing Tuple with minimum R_metric MUST be added;
       otherwise, a Routing Tuple that is preferred SHOULD be added.

Appendix D.  TC Message Example

   TC messages are instances of [RFC5444] messages.  This specification
   requires that TC messages contain <msg-hop-limit> and <msg-orig-addr>
   fields.  It supports TC messages with any combination of remaining
   message header options and address encodings enabled by [RFC5444]
   that convey the required information.  As a consequence, there is no
   single way to represent how all TC messages look.  This appendix
   illustrates a TC message; the exact values and content included are
   explained in the following text.

   The TC message's four-bit Message Flags (MF) field has a value of 15,
   indicating that the message header contains originator address, hop
   limit, hop count, and message sequence number fields.  Its four-bit
   Message Address Length (MAL) field has value 3, indicating addresses
   in the message have a length of four octets, here being IPv4
   addresses.  The overall message length is 75 octets.

   The message has a Message TLV Block with a content length of 17
   octets containing four TLVs.  The first two TLVs are validity and
   interval times for the message.  The third TLV is the content
   sequence number TLV used to carry the 2-octet ANSN and (with default
   type extension zero, i.e., COMPLETE) indicates that the TC message is
   complete.  The fourth TLV contains forwarding and routing willingness
   values for the originating router (FWILL and RWILL, respectively).
   Each TLV uses a TLV with Flags octet (MTLVF) value 16, indicating





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   that it has a Value, but no type extension or start and stop indexes.
   The first two TLVs have a Value Length of 1 octet; the last has a
   Value Length of 2 octets.

   The message has two Address Blocks.  (This is not necessary.  The
   information could be conveyed using a single Address Block; the use
   of two Address Blocks, which is also allowed, is illustrative only.)
   The first Address Block contains 3 addresses, with Flags octet (ABF)
   value 128, hence with a Head section (with length 2 octets) but no
   Tail section and with Mid sections with length two octets.  The
   following TLV Block (content length 13 octets) contains two TLVs.
   The first TLV is a NBR_ADDR_TYPE TLV with Flags octet (ATLVF) value
   16, indicating a single Value but no indexes.  Thus, all these
   addresses are associated with the Value (with Value Length 1 octet)
   ROUTABLE_ORIG, i.e., they are originator addresses of advertised
   neighbors that are also routable addresses.  The second TLV is a
   LINK_METRIC TLV with Flags octet (ATLVF) value 20, indicating a Value
   for each address, i.e., as the total Value Length is 6 octets, each
   address is associated with a Value with length two octets.  These
   Value fields are each shown as having four bits indicating that they
   are outgoing neighbor metric values and as having twelve bits that
   represent the metric value (the first four bits being the exponent,
   the remaining eight bits the mantissa).

   The second Address Block contains 1 address, with Flags octet (ATLVF)
   176, indicating that there is a Head section (with length 2 octets),
   that the Tail section (with length 2 octets) consists of zero valued
   octets (not included), and that there is a single prefix length,
   which is 16.  The network address is thus Head.0.0/16.  The following
   TLV Block (content length 9 octets) includes two TLVs.  The first has
   a Flags octet (ATLVF) of 16, again indicating that no indexes are
   needed, but that a Value (with Value Length 1 octet) is present,
   indicating the address distance as a number of hops.  The second TLV
   is another LINK_METRIC TLV, as in the first Address TLV Block except
   with a Flags octet (ATLVF) value 16, indicating that a single Value
   is present.















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      0                   1                   2                   3
      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |      TC       | MF=15 | MAL=3 |      Message Length = 75      |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |                      Originator Address                       |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |   Hop Limit   |   Hop Count   |    Message Sequence Number    |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Message TLV Block Length = 17 | VALIDITY_TIME |  MTLVF = 16   |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Value Len = 1 | Value (Time)  | INTERVAL_TIME |  MTLVF = 16   |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Value Len = 1 | Value (Time)  | CONT_SEQ_NUM  |  MTLVF = 16   |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Value Len = 2 |         Value (ANSN)          |  MPR_WILLING  |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |  MTLVF = 16   | Value Len = 1 | FWILL | RWILL | Num Addrs = 3 |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |   ABF = 128   | Head Len = 2  |             Head              |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |              Mid              |              Mid              |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |              Mid              | Address TLV Block Length = 13 |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | NBR_ADDR_TYPE |  ATLVF = 16   | Value Len = 1 | ROUTABLE_ORIG |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |  LINK_METRIC  |  ATLVF = 20   | Value Len = 6 |0|0|0|1|Metric |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Metric (cont) |0|0|0|1|        Metric         |0|0|0|1|Metric |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Metric (cont) | Num Addrs = 1 |   ABF = 176   | Head Len = 2  |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     |             Head              | Tail Len = 2  | Pref Len = 16 |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Address TLV Block Length = 9  |    GATEWAY    |  ATLVF = 16   |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Value Len = 1 | Value (Hops)  |  LINK_METRIC  |  ATLVF = 16   |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
     | Value Len = 2 |0|0|0|1|        Metric         |
     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+










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Appendix E.  Flow and Congestion Control

   Due to its proactive nature, this protocol has a natural control over
   the flow of its control traffic.  Routers transmit control messages
   at predetermined rates specified and bounded by message intervals.

   This protocol employs [RFC6130] for local signaling, embedding MPR
   selection advertisement through a simple Address Block TLV and router
   willingness advertisement (if any) as a single Message TLV.  Local
   signaling, therefore, shares the characteristics and constraints of
   [RFC6130].

   Furthermore, the use of MPRs can greatly reduce the signaling
   overhead from link state information dissemination in two ways,
   attaining both flooding reduction and topology reduction.  First,
   using MPR flooding, the cost of distributing link state information
   throughout the network is reduced, as compared to when using blind
   flooding, since only MPRs need to forward link state declaration
   messages.  Second, the amount of link state information for a router
   to declare is reduced; it only needs to contain that router's MPR
   selectors.  This reduces the size of a link state declaration as
   compared to declaring full link state information.  In particular,
   some routers may not need to declare any such information.  In dense
   networks, the reduction of control traffic can be of several orders
   of magnitude compared to routing protocols using blind flooding
   [MPR].  This feature naturally provides more bandwidth for useful
   data traffic and further pushes the frontier of congestion.

   Since the control traffic is continuous and periodic, it keeps the
   quality of the links used in routing more stable.  However, using
   some options, some control messages (HELLO messages or TC messages)
   may be intentionally sent in advance of their deadline in order to
   increase the responsiveness of the protocol to topology changes.
   This may cause a small, temporary, and local increase of control
   traffic; however, this is at all times bounded by the use of minimum
   message intervals.

   A router that recognizes that the network is suffering from
   congestion can increase its message interval parameters.  If this is
   done by most or all routers in the network, then the overall control
   traffic in the network will be reduced.  When using this capability,
   routers will have to take care not to increase message interval
   parameters such that they cannot cope with network topology changes.
   Note that routers can make such decisions independently; it is not
   necessary for all routers to be using the same parameter values, nor
   is it necessary that all routers decide to change their intervals at
   the same time.




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Authors' Addresses

   Thomas Heide Clausen
   LIX, Ecole Polytechnique

   Phone: +33 6 6058 9349
   EMail: T.Clausen@computer.org
   URI:   http://www.ThomasClausen.org/


   Christopher Dearlove
   BAE Systems Advanced Technology Centre
   West Hanningfield Road
   Great Baddow, Chelmsford
   United Kingdom

   Phone: +44 1245 242194
   EMail: chris.dearlove@baesystems.com
   URI:   http://www.baesystems.com/


   Philippe Jacquet
   Alcatel-Lucent Bell Labs

   Phone: +33 6 7337 1880
   EMail: philippe.jacquet@alcatel-lucent.com


   Ulrich Herberg
   Fujitsu Laboratories of America
   1240 E. Arques Ave.
   Sunnyvale, CA  94085
   USA

   EMail: ulrich@herberg.name
   URI:   http://www.herberg.name/















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