One document matched: draft-ogier-manet-ospf-extension-09.txt
Differences from draft-ogier-manet-ospf-extension-08.txt
OSPF/MANET Working Groups R. Ogier
Internet-Draft SRI International
Expires: September 5, 2007 P. Spagnolo
Boeing
March 5, 2007
MANET Extension of OSPF using CDS Flooding
draft-ogier-manet-ospf-extension-09.txt
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Copyright Notice
Copyright (C) The IETF Trust (2007).
Abstract
This document specifies an extension of OSPF for IPv6 to support
mobile ad hoc networks (MANETs). The extension, called OSPF-MDR, is
designed as a new OSPF interface type for MANETs. OSPF-MDR is based
on the selection of a subset of MANET routers, consisting of MANET
Designated Routers (MDRs) and Backup MDRs. The MDRs form a connected
dominating set (CDS), and the MDRs and Backup MDRs together form a
biconnected CDS for robustness. This CDS is exploited in two ways.
First, to reduce flooding overhead, an optimized flooding procedure
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is used in which only (Backup) MDRs flood new LSAs back out the
receiving interface; reliable flooding is ensured by retransmitting
LSAs along adjacencies. Second, adjacencies are formed only between
(Backup) MDRs and a subset of their neighbors, allowing for much
better scaling in dense networks. The CDS is constructed using 2-hop
neighbor information provided in a Hello protocol extension. The
Hello protocol is further optimized by allowing differential Hellos
that report only changes in neighbor states. Options are specified
for originating router-LSAs that provide full or partial topology
information, allowing overhead to be reduced by advertising less
topology information.
Table of Contents
1 Introduction ................................................. 4
1.1 Terminology .................................................. 5
1.2 Draft Modifications .......................................... 6
2 Overview of OSPF-MDR ......................................... 7
2.1 Selection of MDRs, BMDRs, Parents, and Adjacencies ........... 7
2.2 Flooding Procedure ........................................... 8
2.3 Link State Acknowledgments ................................... 9
2.4 Routable Neighbors ........................................... 9
2.5 Partial and Full Topology LSAs .............................. 10
2.6 Modified Hello Protocol ..................................... 10
3 Interface and Neighbor Data Structures ...................... 11
3.1 Changes to Interface Data Structure ......................... 11
3.2 New Configurable Interface Parameters ....................... 12
3.3 Changes to Neighbor Data Structure .......................... 13
4 Hello Protocol .............................................. 15
4.1 Sending Hello Packets ....................................... 15
4.2 Receiving Hello Packets ..................................... 16
4.3 Neighbor Acceptance Condition ............................... 20
5 MDR Selection Algorithm ..................................... 20
5.1 Phase 1: Creating the Neighbor Connectivity Matrix .......... 21
5.2 Phase 2: MDR Selection ...................................... 22
5.3 Phase 3: Backup MDR Selection ............................... 23
5.4 Phase 4: Selection of the (Backup) MDR Parent ............... 23
6 Interface State Machine ..................................... 24
6.1 Interface states ............................................ 24
6.2 Events that cause interface state changes ................... 25
6.3 Changes to Interface State Machine .......................... 25
7 Adjacency Maintenance ....................................... 27
7.1 Changes to Neighbor State Machine ........................... 27
7.2 Whether to Become Adjacent .................................. 28
7.3 Whether to Eliminate an Adjacency ........................... 29
7.4 Sending Database Description Packets ........................ 29
7.5 Receiving Database Description Packets ...................... 30
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8 Flooding Procedure .......................................... 31
8.1 LSA Forwarding Procedure .................................... 31
8.2 Sending Link State Acknowledgments .......................... 34
8.3 Retransmitting LSAs ......................................... 35
8.4 Receiving Link State Acknowledgments ........................ 36
9 Originating LSAs ............................................ 36
9.1 Routable Neighbors .......................................... 37
9.2 Partial and Full Topology LSAs .............................. 38
10 Calculating the Routing Table ............................... 40
11 Acknowledgments ............................................. 40
12 Normative References ........................................ 40
13 Informative References ...................................... 41
A Packet Formats .............................................. 41
A.1 Options Field ............................................... 41
A.2 Link-Local Signaling ........................................ 41
A.3 Hello Packet DR and Backup DR Fields ........................ 48
A.4 LSA Formats and Examples .................................... 48
B Detailed Algorithms for MDR/BMDR Selection .................. 52
B.1 Detailed Algorithm for Step 2.4 (MDR Selection) ............. 52
B.2 Detailed Algorithm for Step 3.2 (BMDR Selection) ............ 53
C Min-Cost LSA Algorithm ...................................... 55
D Non-Ackable LSAs for Periodic Flooding ...................... 57
Authors Addresses ........................................... 58
Intellectual Property and Copyright Statements .............. 59
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1. Introduction
This document specifies an extension of OSPF for IPv6 [RFC2328,
RFC2740], to support a new interface type for mobile ad hoc networks
(MANETs), i.e., for broadcast-capable, multihop wireless networks in
which routers and hosts can be mobile. Existing OSPF interface types
do not perform adequately in such an environment, due to scaling
issues regarding the flooding protocol operation, inability of the
Designated Router election protocol to converge in all scenarios, and
large numbers of adjacencies when using a Point-to-Multipoint
interface type.
An OSPF implementation that is extended with this MANET interface
type does not preclude the use of any existing interface types, and
is fully compatible with a legacy OSPF implementation. MANET
networks are represented externally as Point-to-Multipoint networks,
although the design borrows concepts used by the OSPF broadcast
interface type.
The approach taken is to generalize the concept of an OSPF Designated
Router (DR) and Backup DR to multihop wireless networks, in order to
reduce overhead by reducing the number of routers that must flood new
LSAs and reducing the number of adjacencies. The generalized
(Backup) Designated Routers are called (Backup) MANET Designated
Routers (MDRs). The MDRs form a connected dominating set (CDS), and
the MDRs and Backup MDRs together form a biconnected CDS for
robustness. By definition, all routers in the MANET either belong to
the CDS or are one hop away from it. A distributed algorithm is used
to select and dynamically maintain the biconnected CDS. Adjacencies
are established only between (Backup) MDRs and a subset of their
neighbors, thus resulting in a dramatic reduction in the number of
adjacencies in dense networks, compared to the approach of forming
adjacencies between all neighbor pairs. The OSPF extension is called
OSPF-MDR.
Hello packets are modified, using LLS TLVs, for two purposes: to
provide neighbors with 2-hop neighbor information that is required by
the MDR selection algorithm, and to allow differential Hellos that
report only changes in neighbor states. Differential Hellos can be
sent more frequently without a significant increase in overhead, in
order to respond more quickly to topology changes.
Each MANET router advertises a subset of its MANET neighbors as
point-to-point links in its router-LSA. The choice of which
neighbors to advertise is flexible, allowing overhead to be reduced
by advertising less topology information. Options are specified for
originating router-LSAs that provide full or partial topology
information.
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This document is organized as follows. Section 2 presents an overview
of OSPF-MDR, Section 3 presents the new interface and neighbor data
items that are required for the extension, Section 4 describes the
Hello protocol, including procedures for maintaining the 2-hop
neighbor information, Section 5 describes the MDR selection
algorithm, Section 6 describes changes to the Interface state
machine, section 7 describes the procedures for forming adjacencies
and deciding which neighbors should become adjacent, Section 8
describes the flooding procedure, Section 9 specifies the
requirements and options for what to include in router-LSAs, and
Section 10 describes changes in the calculation of the routing table.
The appendix specifies packet formats, detailed algorithms for the
MDR selection algorithm, an algorithm for the selection of neighbors
to advertise in the router-LSA to provide min-cost routing, and a
proposed option that uses "non-ackable" LSAs to provide periodic
flooding that reduces overhead in highly mobile networks.
1.1. Terminology
The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC2119]. In
addition, this document uses the following terms:
MANET Interface
A new OSPF interface type that supports broadcast-capable,
multihop wireless networks. Two neighboring routers on a MANET
interface may not be able to communicate directly with each other.
A neighboring router on a MANET interface is called a MANET
neighbor. MANET neighbors are discovered dynamically using a
modification of OSPF's Hello protocol, which takes advantage of
the broadcast capability.
MANET Router
An OSPF router that has at least one MANET interface.
Differential Hello
A Hello packet that reduces the overhead of sending full state
Hellos, by including only the Router IDs of neighbors whose state
changed recently.
2-Hop Neighbor Information
Information that specifies the Router IDs of each neighbor's
neighbors. The modified Hello protocol provides each MANET router
with 2-hop neighbor information, which is used for selecting MDRs
and Backup MDRs.
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MANET Designated Router (MDR)
One of a set of routers responsible for flooding new LSAs, and for
determining the set of adjacencies that must be formed. The set
of MDRs forms a connected dominating set and is a generalization
of the DR found in the broadcast network.
Backup MANET Designated Router (Backup MDR or BMDR)
One of a set of routers responsible for providing backup flooding
when neighboring MDRs fail, and for determining the set of
adjacencies that must be formed. The set of MDRs and Backup MDRs
forms a biconnected dominating set. The Backup MDR is a
generalization of the Backup DR found in the broadcast network.
MDR Other
A router is an MDR Other for a particular MANET interface if it is
neither an MDR nor a Backup MDR for that interface.
(Backup) MDR Parent
Each Backup MDR and MDR Other selects a Parent, which will be a
neighboring MDR if one exists. If the option of biconnected
adjacencies is chosen, then each MDR Other also selects a Backup
Parent, which will be a neighboring MDR/BMDR if one exists that is
not the Parent. Each router forms an adjacency with its Parent
and its Backup Parent (if it exists).
Bidirectional Neighbor
A neighboring router whose neighbor state is 2-Way or greater.
Routable Neighbor
A bidirectional MANET neighbor becomes routable if its state is
Full, or if the SPF calculation has produced a route to the
neighbor and the neighbor satisfies a quality condition. Once a
neighbor becomes routable, it remains routable as long as it
remains bidirectional. Only routable MANET neighbors can be used
as next hops in the SPF calculation, and can be included in LSAs
originated by the router.
1.2. Draft Modifications
The main changes from version 08 to version 09 of this draft are as
follows:
o The detailed algorithm for BMDR selection (Section B.2) has been
simplified.
o The min-cost LSA algorithm has been modified to use link costs
obtained from received Hellos, and to ensure that the router
advertises a neighbor if the neighbor advertises the router.
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o Router Priority is now given higher precedence than MDR Level in
the MDR selection algorithm, i.e., a router is preferred if it has
a lexicographically larger value of (RtrPri, MDR Level, RID).
2. Overview
This section provides an overview of OSPF-MDR, including motivation
and rationale for some of the design choices.
OSPF-MDR was motivated by the desire to extend OSPF to support
MANETs, while keeping the same design philosophy as OSPF and using
techniques that are similar to those of OSPF. For example, OSPF
reduces overhead in a broadcast network by electing a Designated
Router (DR) and Backup DR, and by having two neighboring routers form
an adjacency only if one of them is the DR or Backup DR. This idea
can be generalized to a multihop wireless network by forming a
spanning tree, with the edges of the tree being the adjacencies and
the interior (non-leaf) nodes of the tree being the generalized DRs,
called MANET Designated Routers (MDRs).
To provide better robustness and fast response to topology changes,
it was decided that a router should decide whether it is an MDR based
only on 2-hop neighbor information that can be obtained from
neighbors' Hellos (similar to OSPF). The resulting set of
adjacencies therefore does not always form a tree globally, but
appears to be a tree locally. Similarly, the Backup DR can be
generalized to Backup MDRs (BMDRs), to provide robustness through
biconnected redundancy. The set of MDRs forms a connected dominating
set (CDS), and the set of MDRs and BMDRs forms a biconnected
dominating set.
The following subsections provide an overview of each of the main
features of OSPF-MDR, starting with a summary of how MDRs, BMDRs, and
adjacencies are selected.
2.1. Selection of MDRs, BMDRs, Parents, and Adjacencies
The selection of MDRs can be summarized as follows. Let Rmax denote
the neighbor with the lexicographically largest value of (RtrPri, MDR
Level, RID), where MDR Level is 2 for an MDR, 1 for a BMDR, and 0 for
an MDR Other. Then a router selects itself as an MDR unless each
neighbor can be reached from Rmax in at most k hops via neighbors
that have a larger value of (RtrPri, MDR Level, RID) than the router
itself, where k is the parameter MDRConstraint, whose default value
is 3.
Similarly, a router that does not select itself as an MDR will select
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itself as a BMDR unless each neighbor can be reached from Rmax via
two node-disjoint paths, using as intermediate hops only neighbors
that have a larger value of (RtrPri, MDR Level, RID) than the router
itself.
When a router selects itself as an MDR, it also decides which MDR
neighbors it should become adjacent with, to ensure that the set of
MDRs and the adjacencies between them form a connected backbone.
Each non-MDR router selects and becomes adjacent with an MDR neighbor
called its parent, thus ensuring that all routers are connected to
the MDR backbone.
If the option of biconnected adjacencies is chosen (AdjConnectivity =
2), then additional adjacencies are selected to ensure that the set
of MDRs and BMDRs, and the adjacencies between them, form a
biconnected backbone. In this case, each MDR Other selects and
becomes adjacent with an MDR/BMDR neighbor called its backup parent,
in addition to its MDR parent.
OSPF-MDR will also provide the option of full-topology adjacencies.
A router that selects this option will always form an adjacency with
each bidirectional neighbor that also selects this option.
Prioritizing routers according to (RtrPri, MDR Level, RID) allows
neighboring routers to agree on which routers should become an MDR,
and gives higher priority to existing MDRs, which increases the
lifetime of MDRs and the adjacencies between them. In addition,
parents are selected to be existing adjacent neighbors whenever
possible, to avoid forming new adjacencies unless necessary. Once a
neighbor becomes adjacent, it remain adjacent as long as the neighbor
is bidirectional and either the neighbor or the router itself is an
MDR or BMDR (similar to OSPF). The above rules reduce the rate at
which new adjacencies are formed, which is important since database
exchange must be performed whenever a new adjacency is formed.
Prioritizing routers according to (RtrPri, MDR Level, RID) not only
increases the lifetime of MDRs and adjacencies, but also achieves
consistency with the DR election algorithm, which gives highest
priority to existing DRs. As a result, when applied to a fully
connected MANET, the MDR selection algorithm and the DR election
algorithm both select the same two routers as DR/MDR and BDR/BMDR.
(The MDR section algorithm also selects a second BMDR so that the
MDR/BMDR backbone is biconnected.)
2.2. Flooding Procedure
When an MDR receives a new LSA on a MANET interface, it immediately
floods the LSA back out the receiving interface (unless it can be
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determined that such flooding is unnecessary). When a Backup MDR
receives a new LSA on a MANET interface, it waits a short interval
(BackupWaitInterval), and then floods the LSA only if there exists a
neighbor that is not covered by another neighbor from which the LSA
has been received.
MDR Other routers never flood LSAs back out the receiving interface.
To exploit the broadcast nature of MANETs, a new LSA is processed
(and possibly forwarded) if it is received from any neighbor in state
2-Way or greater. The flooding procedure also avoids redundant
forwarding of LSAs when multiple interfaces exist.
2.3. Link State Acknowledgments
All Link State Acks are multicast. An LSA is acknowledged if it is a
new LSA, or if it is a duplicate LSA received as a unicast. (A
duplicate LSA received as multicast is not acknowledged.) An LSA
that is flooded back out the same interface is treated as an implicit
Ack. Link State Acks may be delayed up to AckInterval seconds to
allow coalescing multiple Acks in the same packet. The only
exception is that (Backup) MDRs send a multicast Ack immediately when
a duplicate LSA is received as a unicast, in order to prevent
additional retransmissions. Only Acks from adjacent neighbors are
processed, and retransmitted LSAs are sent (via unicast) only to
adjacent neighbors.
2.4. Routable Neighbors
A bidirectional MANET neighbor becomes routable if its state is Full,
or if the SPF calculation has produced a route to the neighbor and
the neighbor satisfies a flexible quality condition. Once a neighbor
becomes routable, it remains routable as long as it remains
bidirectional. Only routable MANET neighbors can be used as next
hops in the SPF calculation, and can be included in the router-LSA
originated by the router. The idea is that if the SPF calculation
has produced a route to the neighbor, then it makes sense to take a
"shortcut" and forward packets directly to the neighbor.
Note that OSPF already allows a non-adjacent neighbor to be used as a
next hop, if both routers are fully adjacent to the DR of a broadcast
network. The routability condition is a generalization of this
condition to MANETs. The network-LSA of an OSPF broadcast network
implies that a router can use a non-adjacent neighbor as a next hop.
But a network-LSA cannot describe the general topology of a MANET,
making it necessary to explicitly include non-adjacent neighbors in
the router-LSA. Allowing only adjacent neighbors in LSAs would
either result in suboptimal paths or would require a large number of
adjacencies.
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2.5. Partial and Full Topology LSAs
Each router advertises a subset of its routable neighbors as point-
to-point connections in its router-LSA. The choice of which
neighbors to advertise is flexible, and is determined by the
configurable parameter LSAFullness. As a minimum requirement, each
router must advertise all of its fully adjacent neighbors in its
router-LSA. This minimum choice corresponds to LSAFullness = 0. This
choice results in the minimum amount of LSA flooding overhead, but
does not provide routing along shortest paths.
Setting LSAFullness to 1 or 2 results in min-cost LSAs, which provide
min-hop routing, and can provide min-cost routing under certain
assumptions. Each router decides which neighbors to include in its
router-LSA by looking at the router-LSAs originated by its neighbors,
and including in its LSA the minimum set of neighbors necessary to
provide a shortest path (if LSAFullness = 1) or two shortest paths
(if LSAFullness = 2) between each pair of neighbors.
Setting LSAFullness to 3 results in MDR full LSAs. Each (Backup) MDR
originates a full LSA that includes all routable neighbors, while
each MDR Other originates minimal LSAs. This choice provides routing
along nearly min-hop paths.
If LSAFullness = 4, then each router originates a full LSA, which
includes all routable neighbors.
The above LSA options are interoperable with each other, since they
all require the router-LSA to include all fully adjacent neighbors.
2.6. Modified Hello Protocol
Hellos are used both for neighbor discovery and for advertising the
set of bidirectional neighbors (in state 2-Way or greater), to be
used by neighbors to learn 2-hop neighbor information. Differential
Hellos are sent every HelloInterval seconds, except when full Hellos
are sent, which happens every 2HopRefresh Hellos. The default values
for HelloInterval and 2HopRefresh are 2 seconds and 3 Hellos,
respectively. Differential Hellos are used to reduce overhead and to
allow Hellos to be sent more frequently, for faster reaction to
topology changes. Full Hellos are sent less frequently to ensure
that all neighbors have current 2-hop neighbor information. The use
of differential Hellos allows HelloInterval to be smaller (e.g. 1
second) while making 2HopRefresh larger (e.g. every 6th Hello),
without a significant increase in overhead, allowing faster response
to topology changes in a highly mobile network.
Each Hello contains a sequence number, which is incremented each time
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a Hello is sent on a given interface. As in OSPF, the state of a
neighbor transitions to Down if no Hello is heard for
RouterDeadInterval. In addition, the state of a neighbor transitions
to Init if HelloRepeatCount Hellos are missed, based on the Hello
sequence number.
Both differential and full Hellos may contain a list of Heard
Neighbors (in state Init) and a list of Reported Neighbors (in state
2-Way or greater). In addition, differential Hellos may contain a
list of Lost Neighbors (which recently transitioned to the Down
state). A neighbor that transitions to a different one of these three
categories is included in the appropriate list for the next
HelloRepeatCount Hellos. This ensures that the neighbor will either
learn the new state within HelloRepeatCount Hellos, or will declare
the neighbor to be Down or Init.
3. Interface and Neighbor Data Structures
3.1. Changes to Interface Data Structure
The following modified or new data items are required for the
Interface Data Structure of a MANET interface:
Type
A router that implements this extension can have one or more
interfaces of type MANET, in addition to the OSPF interface types
defined in RFC 2328.
State
The possible states for a MANET interface are the same as for a
broadcast interface. However, the DR and Backup states now imply
that the router is an MDR or Backup MDR, respectively.
MDR Level
The MDR Level is equal to MDR (value 2) if the router is an MDR,
Backup MDR (value 1) if the router is a Backup MDR, and MDR Other
(value 0) otherwise. The MDR Level is used by the MDR selection
algorithm.
MDR Parent
Each non-MDR router selects an MDR Parent, as described in Section
5.4. The MDR Parent will be a neighboring MDR, if one exists.
The MDR Parent is initialized to 0.0.0.0, indicating the lack of
an MDR Parent. A non-MDR router includes the Router ID of its MDR
Parent in the DR field of each Hello sent on the interface.
Backup MDR Parent
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If the option of biconnected adjacencies is chosen, then each MDR
Other selects a Backup MDR Parent, as described in Section 5.4.
The Backup MDR Parent will be a neighboring MDR/BMDR, if one
exists that is not the MDR Parent. The Backup MDR Parent is
initialized to 0.0.0.0, indicating the lack of a Backup MDR
Parent. An MDR Other includes the Router ID of its Backup MDR
Parent in the Backup DR field of each Hello sent on the interface.
Router Priority
An 8-bit unsigned integer. A router with a larger Router Priority
is more likely to be selected as an MDR. The Router Priority for
a MANET interface can be changed dynamically based on any
criteria, including bandwidth capacity, willingness to be a relay
(which can depend on battery life, for example), number of
neighbors (degree), and neighbor stability. A router that has
been a (Backup) MDR for a certain amount of time can reduce its
Router Priority so that the burden of being a (Backup) MDR can be
shared among all routers.
Hello Sequence Number (HSN)
The 16-bit sequence number carried by the Hello Sequence TLV. The
HSN is incremented by 1 every time a (differential or full) Hello
is sent on the interface.
Lost Neighbor List (LNL)
A list of the Router IDs of neighbors whose states have recently
changed to Down. These Router IDs are included in the Lost
Neighbor List TLV of Hello packets sent on the interface.
Selected Advertised Neighbor List (SANL)
A list of the Router IDs of neighbors that have been selected by
the min-cost LSA algorithm to be advertised in the router-LSA and
in the SANL TLV included in Hellos.
3.2. New Configurable Interface Parameters
The following new configurable interface parameters are required for
a MANET interface. The default values for HelloInterval,
RouterDeadInterval, and RxmtInterval for a MANET interface are 2, 6,
and 7 seconds, respectively.
2HopRefresh
Full neighbor state must be included in one of every 2HopRefresh
Hello packets. Other Hellos include only differential state
information. Default value is 3.
HelloRepeatCount
The number of consecutive Hellos in which a neighbor must be
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included when its state changes. Default value is 3.
AckInterval
The maximum number of seconds that an acknowledgment may be held
before it is multicast so that acknowledgments may be coalesced.
Default value is 2 seconds.
BackupWaitInterval
The number of seconds that a Backup MDR must wait after receiving
a new LSA, before it decides whether to flood the LSA. Default
value is 0.5 second.
AdjConnectivity
If equal to the default value of 1, then the set of adjacencies
forms a (uni)connected graph. If equal to the optional value of 2,
then the set of adjacencies forms a biconnected graph. If
AdjConnectivity is 0, then adjacency reduction is not used, i.e.,
the router becomes adjacent with all of its neighbors.
MDRConstraint
A parameter of the MDR selection algorithm, which affects the
number of MDRs selected. The default value of 3 results in nearly
the minimum number of MDRs. The optional value 2 results in a
larger number of MDRs.
LSAFullness
Determines which neighbors a router should advertise in its
router-LSA. The value 0 results in minimal LSAs that include only
fully adjacent neighbors. The value 1 results in partial-topology
LSAs that provide min-cost routing. The value 3 results in
(Backup) MDRs originating full LSAs and other routers originating
minimal LSAs. The value 4 results in all routers originating full
LSAs. The default value is 1.
3.3. Changes to Neighbor Data Structure
The following new data items are required for the Neighbor Data
Structure of a neighbor on a MANET interface:
Neighbor Hello Sequence Number (NHSN)
The Hello sequence number contained in the last Hello received
from the neighbor.
Reported Neighbor List (RNL)
The Reported Neighbor List for the neighbor, which is updated when
a Hello is received from the neighbor that contains an RNL TLV.
The Reported Neighbor Lists for all neighbors represent the 2-hop
neighbor information.
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Dependent Neighbor List (DNL)
The Dependent Neighbor List for the neighbor, which is updated
when a Hello is received from the neighbor that contains a DNL
TLV.
Report2Hop
A single-bit variable equal to 1 if a full Hello (which contains a
full Reported Neighbor List) has been received from the neighbor.
Neighbor's MDR Level
The MDR Level of the neighbor, based on the DR and Backup DR
fields of the last Hello packet received from the neighbor or from
the MDR TLV in a DD packet received from the neighbor.
Neighbor's MDR Parent
The neighbor's choice for MDR Parent, obtained from the DR field
of the last Hello packet received from the neighbor or from the
MDR TLV in a DD packet received from the neighbor.
Neighbor's Backup MDR Parent
The neighbor's choice for Backup MDR Parent, obtained from the
Backup DR field of the last Hello packet received from the
neighbor or from the MDR TLV in a DD packet received from the
neighbor.
Child
A single-bit variable equal to 1 if the neighbor is a child, i.e.,
if the neighbor has selected the router as a (Backup) MDR Parent.
Dependent
A single-bit variable equal to 1 if the neighbor is a Dependent
Neighbor, which is decided by the MDR selection algorithm.
Dependent Neighbors become adjacent.
Dependent Selector
A single-bit variable equal to 1 if the neighbor has selected the
router to be Dependent.
Routable
A single-bit variable equal to 1 if the neighbor is routable. A
neighbor is routable if either its state is Full, or the routing
table includes a route to the neighbor. Only routable neighbors
are included in the router-LSA and are allowed as next hops in the
routing table.
Neighbor's Selected Advertised Neighbor List (SANL)
The Selected Advertised Neighbor List for the neighbor, which is
updated when a Hello is received from the neighbor that includes
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an SANL TLV.
4. Hello Protocol
The MANET interface utilizes Hellos for neighbor discovery and for
enabling neighbors to learn 2-hop neighbor information. The protocol
is flexible because it allows the use of full state or differential
Hellos. Differential Hellos are used to reduce overhead, and they
allow Hellos to be sent more frequently (for faster reaction to
topology changes). If differential Hellos are used, full Hellos are
sent less frequently to ensure that all neighbors have current 2-hop
neighbor information.
4.1. Sending Hello Packets
Hello packets are sent according to [RFC2740] Section 3.2.1.1 and
[RFC2328] Section 9.5 with the following MANET specific
specifications beginning after paragraph 3 of Section 9.5. The Hello
packet format is defined in [RFC2740] A.3.2.
There are no changes to the Hello packet format. However, the
meaning of the DR and Backup DR fields has changed. Similar to
[RFC2328], if the router is an MDR, then the DR field is the router's
own Router ID, and if the router is a Backup MDR, then the Backup DR
field is the router's own Router ID. However, these fields are also
used to advertise the router's MDR Parent and Backup MDR Parent, as
specified in Appendix A.3. The Hello packet's Neighbor Router ID
list is not used on the MANET interface.
Hellos are sent every HelloInterval seconds. Full state Hellos are
sent every 2HopRefresh Hellos, and differential Hellos are sent at
all other times. For example, if 2HopRefresh is equal to 3, then
every third Hello contains full neighbor state information. If
2HopRefresh is set to 1, then all Hellos are full state. The first
Hello sent by a neighbor should be a full state Hello.
MANET Hellos require the use of the Heard Neighbor List (HNL) TLV,
Reported Neighbor List (RNL) TLV, Lost Neighbor List (LNL) TLV,
Dependent Neighbor List (DNL) TLV, and Hello Sequence (HS) TLV (see
Appendix A.2.2). Depending on the need, each of these TLVs are
appended to the Hello packet with LLS (see Appendix A.2 for link-
local signaling).
If the router has any Dependent Neighbors, then the Hello, whether
full or differential, contains the DNL TLV, which is built by
including a list of all Dependent Neighbors. If the router does not
have any Dependent Neighbors, then the Hello does not contain the DNL
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TLV. Note that only (Backup) MDRs have any Dependent Neighbors.
4.1.1. Full State Hello Packets
The full state Hello requires the HS TLV and may include the HNL TLV
and RNL TLV appended with LLS. The L bit is set in the Hello's
option field to indicate LLS.
The HS TLV is built by populating the Sequence Number field with the
interface's Hello Sequence Number (HSN). The HSN is then
incremented.
If the router has neighbor(s) in state Init, the HNL TLV is built by
including a list of all neighbors in state Init.
If the router has neighbor(s) in state 2-Way or greater, the RNL TLV
is built by including a list of all neighbors in state 2-Way or
greater, excluding any Dependent Neighbors (which are included in the
DNL TLV).
4.1.2. Differential Hello Packets
The differential Hello requires the HS TLV and may include the HNL
TLV, RNL TLV, and LNL TLV based on need. The D and L bits are set in
the Hello's option field to indicate differential Hellos and link-
local signaling.
The HS TLV is built by populating the Hello Sequence Number field
with the interface's HSN. The HSN is then incremented.
The HNL TLV is built by including a list of all neighbors that have
transitioned to state Init within the last HelloRepeatCount Hellos.
If none exist, the HNL TLV is not appended.
The RNL TLV is built by including a list of all neighbors that have
transitioned from Init to state 2-Way or greater within the last
HelloRepeatCount Hellos, and all neighbors in state 2-Way or greater
such that the router is not in the neighbor's Reported Neighbor List.
If none exist, the RNL TLV is not appended.
The LNL TLV is built by including a list of all neighbors that have
transitioned to state Down within the last HelloRepeatCount Hellos.
These neighbors are found in the Lost Neighbor List. If none exist,
the LNL TLV is not appended. Neighbors that have been in the Lost
Neighbor List longer than HelloRepeatCount Hellos should be removed
from the list and not included in the LNL TLV.
4.2. Receiving Hello Packets
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Hello packets are received according to [RFC2740] Section 3.2.2.1
and [RFC2328] Section 10.5 with the following MANET specific
specifications beginning after paragraph 3 of Section 10.5. The
Hello packet format is defined in [RFC2740] A.3.2.
On a MANET interface, the source of a Hello packet is identified by
the neighbor's Router ID, and the neighbor is identified by its
Router ID.
Now the rest of the Hello Packet is examined, generating events to be
given to the neighbor and interface state machines. These state
machines are specified either to be executed or scheduled (see
[RFC2328] Section 4.4 "Tasking support"). For example, by specifying
below that the neighbor state machine be executed in line, several
neighbor state transitions may be affected by a single received
Hello.
o If the L bit is set in the options field, then there are TLVs to
be processed.
o If the LLS contains an HS TLV, the neighbor state machine is
executed with the event HelloReceived. Otherwise, an error has
occurred and the Hello should be discarded.
o The Hello Sequence Number in the HS TLV should be stored in the
neighbor's data structure.
o The DR and Backup DR fields should be processed as follows.
(1) If the DR field is equal to the neighbor's Router ID,
set the MDR Level of the neighbor to MDR.
(2) Else if the Backup DR field is equal to the neighbor's
Router ID, set the MDR Level of the neighbor to Backup MDR.
(3) Else, set the MDR Level of the neighbor to MDR Other.
(4) If the DR or Backup DR field is equal to the router's own
Router ID, the neighbor's Child variable is set to 1,
otherwise it is zero.
o If the router itself appears in the DNL TLV neighbor list, the
neighbor's Dependent Selector variable is set to 1.
o If the router itself does not appear in the DNL TLV, or if the
Hello packet does not contain a DNL TLV, the neighbor's Dependent
Selector variable is set to 0.
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Further processing of the TLV depends on whether the Hello is full
state or differential, which is indicated by the value of the D
option bit.
4.2.1. Full State Hello Packets
o Report2Hop is set to 1.
o If the router itself appears in the HNL, RNL, or DNL TLV neighbor
list, the neighbor state machine should be executed with the event
2-WayReceived. Otherwise, the neighbor state machine should be
executed with the event 1-WayReceived.
o If the neighbor list in the RNL TLV differs from the Reported
Neighbor List for the neighbor, the receiving interface's state
machine is scheduled with the event MDRNeighborChange.
o The Reported Neighbor List for the neighbor should be replaced
with the union of the RNL TLV neighbor list and the DNL TLV
neighbor list.
4.2.2. Differential Hello Packets
o If an LNL TLV exists, then perform the following steps.
(1) If the router itself appears in the LNL TLV neighbor list,
(a) The neighbor state machine should be executed with the
event 1-WayReceived.
(b) Remove the router from the Reported Neighbor List (for
the neighbor) if it is in the list.
(2) If a Router ID in the LNL TLV neighbor list is in the
Reported Neighbor List,
(a) Remove the Router ID from the Reported Neighbor List.
(b) Schedule the receiving interface's state machine
with the event MDRNeighborChange.
o If an HNL TLV exists, then perform the following steps.
(1) If the router itself appears in the HNL TLV neighbor list
and did not appear in the LNL TLV neighbor list,
(a) The neighbor state machine should be executed with the
event 2-WayReceived.
(b) Remove the router from the Reported Neighbor List if it
is in the list.
(2) If a Router ID in the HNL TLV neighbor list is in the
Reported Neighbor List,
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(a) Remove the Router ID from the Reported Neighbor List.
(b) Schedule the receiving interface's state machine
with the event MDRNeighborChange.
o If an RNL TLV exists, then perform the following steps.
(1) If the router itself appears in the RNL TLV neighbor list
and did not appear in the LNL or HNL TLV neighbor list,
(a) The neighbor state machine should be executed with the
event 2-WayReceived.
(b) Add the router itself to the Reported Neighbor List if
it does not belong.
(2) If a Router ID in the RNL TLV neighbor list is not in the
Reported Neighbor List,
(a) Add the Router ID to the Reported Neighbor List.
(b) Schedule the receiving interface's state machine
with the event MDRNeighborChange.
o If the router itself did not appear in any of the TLV neighbor
lists, the neighbor state is 2-Way or greater, and the Hello
Sequence Number is less than or equal to the previous sequence
number plus HelloRepeatCount, then the neighbor state machine
should be executed with the event 2-WayReceived (the state does
not change).
o If 2-WayReceived or 1-WayReceived was not executed, then the
neighbor state machine should be executed with the event
1-WayReceived.
The following applies to both full state and differential Hellos.
o If a change in the neighbor's Router Priority field was noted, the
receiving interface's state machine is scheduled with the event
MDRNeighborChange.
o If the neighbor is bidirectional and its MDR Level has changed,
then the receiving interface's state machine is scheduled with the
event MDRNeighborChange, and the neighbor state machine is
scheduled with the event AdjOK?.
o If the neighbor's Child status or Dependent Selector status has
changed from 0 to 1, the neighbor state machine is scheduled with
the event AdjOK?.
o If the neighbor's state changed from less than 2-Way to 2-Way or
greater, the receiving interface's state machine is scheduled with
the event MDRNeighborChange and the neighbor state machine is
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scheduled with the event AdjOK?. Else if the neighbor's state
changed from 2-Way or greater to below 2-Way, the receiving
interface's state machine is scheduled with the event
MDRNeighborChange.
4.3. Neighbor Acceptance Condition
In wireless networks, a single Hello can be received from a neighbor
with which a poor connection exists, e.g., because the neighbor is
almost out of range. To avoid accepting poor quality neighbors, and
to employ hysteresis, a router may require that a stricter condition
be satisfied before changing the state of a MANET neighbor from Down
to Init or greater. This condition is called the "neighbor
acceptance condition", which by default is the reception of a single
Hello or DD packet. For example, the neighbor acceptance condition
may require that 2 consecutive Hellos be received from a neighbor
before changing the neighbor's state from Down to Init. Other
possible conditions include the reception of 3 consecutive Hellos, or
the reception of 2 of the last 3 Hellos. The neighbor acceptance
condition may also impose thresholds on other measurements such as
received signal strength.
The neighbor state transition for state Down and event HelloReceived
is thus modified (see Section 7.1) to depend on the neighbor
acceptance condition.
5. MDR Selection Algorithm
This section describes the MDR selection algorithm, which determines
whether the router is an MDR, Backup MDR, or MDR Other on a given
interface. The algorithm also selects the Dependent Neighbors and
the (Backup) MDR Parent, which are used to decide which neighbors
should become adjacent (see Section 7).
The MDR selection algorithm is invoked by the interface event
MDRNeighborChange as described in Section 6. After running the MDR
selection algorithm, the AdjOK? event may be invoked for some or all
neighbors as specified in Section 7.
The purpose of the MDRs is to provide a minimal set of relays for
flooding LSAs, and the purpose of the Backup MDRs is to provide
backup relays to flood LSAs when flooding by MDRs does not succeed.
The set of MDRs forms a CDS, and the set of (Backup) MDRs forms a
biconnected CDS. Note that there may be fewer Backup MDRs than MDRs,
since the MDRs themselves may already provide some redundancy.
Each MDR will become adjacent with each Dependent Neighbor that is an
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MDR, forming a connected backbone network. If AdjConnectivity = 2,
then each (Backup) MDR will become adjacent with each Dependent
Neighbor that is a (Backup) MDR, forming a biconnected backbone
network. The (Backup) MDR Parents that are selected (as described
below) will then connect each MDR Other router with this biconnected
backbone, via two adjacencies. This ensures that the set of
adjacencies forms a biconnected subgraph that spans all routers.
The MDR selection algorithm is a distributed CDS algorithm that uses
2-hop neighbor information obtained from Hellos. More specifically,
it uses as inputs the set of bidirectional neighbors (in state 2-Way
or greater), the triplet (MDR Level, Router Priority, Router ID) for
each such neighbor and for the router itself, and the neighbor
variables Reported Neighbor List (RNL) and Report2Hop for each such
neighbor. The MDR selection algorithm can be implemented in O(d^2)
time, where d is the number of neighbors.
The above triplet will be abbreviated as (RtrPri, MDR Level, RID).
The triplet (RtrPri, MDR Level, RID) is said to be larger for Router
A than for Router B if the triplet for Router A is lexicographically
greater than the triplet for Router B. Routers that have larger
values of this triplet are preferred for selection as an MDR. The
algorithm therefore prefers routers that are already MDRs, resulting
in a longer average MDR lifetime.
The MDR selection algorithm consists of four phases. Phase 1 creates
the neighbor connectivity matrix, which determines which pairs of
neighbors are neighbors of each other. Phase 2 decides whether the
calculating router is an MDR, and which MDR neighbors are Dependent.
Phase 3 decides whether the calculating router is a Backup MDR and,
if AdjConnectivity = 2, which additional MDR/BMDR neighbors are
Dependent. Finally, Phase 4 selects the MDR Parent and Backup MDR
Parent.
The second phase depends on the parameter MDRConstraint, which
affects the number of MDRs selected. The default value of 3 results
in nearly the minimum number of MDRs, while the value 2 results in a
larger number of MDRs.
For convenience, in the following description, the term "neighbor"
will refer to a neighbor on the MANET interface that is bidirectional
(in state 2-Way or greater).
5.1. Phase 1: Creating the Neighbor Connectivity Matrix
The neighbor connectivity matrix (NCM) assigns a value of 0 or 1 for
each pair of (bidirectional) neighbors, depending on the Reported
Neighbor List (RNL) and the value of Report2Hop for each neighbor.
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NCM is a symmetric matrix that defines a topology graph for the set
of neighbors (not including the router itself). A value of 1 for a
given pair of neighbors indicates that the neighbors are assumed to
be neighbors of each other in the MDR selection algorithm. The value
of the matrix is set as follows for each pair of neighbors j and k.
(1.1) If Report2Hop is 1 for both neighbors j and k: NCM(j,k) =
NCM(k,j) is 1 only if j belongs to the RNL of neighbor k and k
belongs to the RNL of neighbor j.
(1.2) If Report2Hop is 1 for neighbor j and is 0 for neighbor k:
NCM(j,k) = NCM(k,j) is 1 only if k belongs to the RNL of
neighbor j.
(1.3) If Report2Hop is 0 for both neighbors j and k: NCM(j,k) =
NCM(k,j) = 0.
In step 1.1 above, two neighbors are considered to be neighbors of
each other only if they both agree that the other router is a
neighbor. This provides faster response to the failure of a link
between two neighbors, since it is likely that one router will detect
the failure before the other router. In step 1.2 above, only neighbor
j has reported its full RNL, so neighbor j is believed in deciding
whether j and k are neighbors of each other. As Step 1.3 indicates,
two neighbors are assumed not to be neighbors of each other if
neither neighbor has reported its full RNL.
5.2. Phase 2: MDR Selection
(2.1) The set of Dependent Neighbors is initialized to be empty.
(2.2) If the router has a larger value of (RtrPri, MDR Level, RID)
than all of its neighbors, the router selects itself as an MDR,
selects all of its MDR neighbors as Dependent Neighbors, and if
AdjConnectivity = 2, selects all of its BMDR neighbors as
Dependent Neighbors. Else, proceed to Step 2.3.
(2.3) Let Rmax be the neighbor that has the largest value of (RtrPri,
MDR Level, RID).
(2.4) Using NCM to determine the connectivity of neighbors, compute
the minimum number of hops, denoted hops(u), from Rmax to each
other neighbor u, using only intermediate nodes that are
neighbors with a larger value of (RtrPri, MDR Level, RID) than
the router itself. If no such path from Rmax to u exists, then
hops(u) equals infinity. (See Appendix B for a detailed
algorithm.)
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(2.5) If hops(u) is at most MDRConstraint for each neighbor u, then
the router does not select itself as an MDR, and selects no
Dependent Neighbors.
(2.6) Else, the router selects itself as an MDR, and selects the
following neighbors as Dependent Neighbors: Rmax, each MDR
neighbor u such that hops(u) is greater than MDRConstraint, and
if AdjConnectivity = 2, each BMDR neighbor u such that hops(u)
is greater than MDRConstraint.
Step 2.4 can be implemented using a breadth-first-search (BFS)
algorithm to compute min-hop paths from node Rmax to all other
neighbors, modified to allow a node as an intermediate node only if
its value of (RtrPri, MDR Level, RID) is larger than that of the
router itself. A detailed description of this algorithm, which runs
in O(d^2) time, is given in Appendix B.
5.3. Phase 3: Backup MDR Selection
(3.1) The set of Dependent Neighbors initially includes the neighbors
selected in Phase 2.
(3.2) Using NCM to determine the connectivity of neighbors, determine
whether or not there exist two node-disjoint paths from Rmax to
each other neighbor u, using only intermediate nodes that are
neighbors with a larger value of (RtrPri, MDR Level, RID) than
the router itself. (See Appendix B for a detailed algorithm.)
(3.3) If there exist two such node-disjoint paths from Rmax to each
other neighbor u, then the router does not select itself as a
Backup MDR, and selects no additional Dependent Neighbors.
(3.4) Else, the router selects itself as a Backup MDR (unless it
already selected itself as an MDR in Phase 2), and if
AdjConnectivity = 2, selects each of the following neighbors as
a Dependent Neighbor: Rmax, and each MDR/BMDR neighbor u such
that step 3.2 did not find two node-disjoint paths from Rmax to
u.
Step 3.2 can be implemented in O(d^2) time using the algorithm given
in Appendix B.
5.4. Phase 4: Selection of the (Backup) MDR Parent
Each BMDR and MDR Other selects (for each MANET interface) a Parent,
which will be a neighboring MDR if one exists. If AdjConnectivity =
2, then each MDR Other also selects a Backup Parent, which will be a
neighboring MDR/BMDR if one exists that is not the Parent. Each
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router forms an adjacency with its Parent and its Backup Parent (if
it exists).
One property of the (Backup) Parent is that it always has a larger
value of (RtrPri, MDR Level, RID) than the router itself. Thus, the
directed graph defined by the parent relationship will not contain
any cycles. All paths in this directed graph lead to an MDR that has
a larger value of (RtrPri, MDR Level, RID) than all of its neighbors.
For a given MANET interface, let Rmax denote the router with the
largest value of (RtrPri, MDR Level, RID) among all bidirectional
neighbors, if such a neighbor exists that has a larger value of
(RtrPri, MDR Level, RID) than the router itself. Otherwise, Rmax is
null.
If the calculating router has selected itself as an MDR, then the
Parent is equal to Rmax (which can be null).
Otherwise (the router is a BMDR or MDR Other), the Parent is selected
to be any adjacent neighbor that is an MDR, if such a neighbor
exists. If no adjacent MDR neighbor exists, then the Parent is
selected to be Rmax. (By giving preference to neighbors that are
already adjacent, the formation of a new adjacency is avoided when
possible.)
If AdjConnectivity = 2 and the calculating router is an MDR Other,
then the Backup Parent is selected to be any adjacent neighbor that
is an MDR or BMDR, other than the selected Parent, if such a neighbor
exists. If no such neighbor exists, then the Backup Parent is
selected to be the bidirectional neighbor, excluding the selected
Parent, with the largest value of (RtrPri, MDR Level, RID).
6. Interface State Machine
6.1. Interface states
No new states are defined for a MANET interface. However, the DR and
Backup states now imply that the router is an MDR or Backup MDR,
respectively. The following modified definitions apply to MANET
interfaces:
Waiting
In this state, the router learns neighbor information from the
Hello packets it receives, but is not allowed to run the MDR
selection algorithm until it transitions out of the Waiting state
(when the Wait Timer expires). This prevents unnecessary changes
in the MDR selection resulting from incomplete neighbor
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information. The length of the Wait Timer is 2HopRefresh *
HelloInterval seconds (the interval between full state Hellos).
DR Other
The router has run the MDR selection algorithm and determined that
it is not an MDR or a Backup MDR.
Backup
The router has selected itself as a Backup MDR.
DR
The router has selected itself as an MDR.
6.2. Events that cause interface state changes
All interface events defined in RFC 2328, Section 9.2 apply to MANET
interfaces, except for BackupSeen and NeighborChange. BackupSeen is
never invoked for a MANET interface (since seeing a Backup MDR does
not imply that the router itself cannot also be an MDR or Backup
MDR). The event NeighborChange is replaced with the new event
MDRNeighborChange, defined as follows.
MDRNeighborChange
There has been a change in neighbor information that requires the
MDR selection algorithm to be run. The following neighbor changes
lead to the MDRNeighborChange event:
o The state of a neighbor changes from Init or lower to 2-Way or
greater, or vice versa.
o The MDR Level of a bidirectional neighbor has changed, as
detected via Hello packets from the neighbor.
o The advertised Router Priority of a bidirectional neighbor has
changed, as detected via Hello packets from the neighbor.
o The Router Priority of the router itself has changed.
o The Reported Neighbor List or Report2Hop has changed for a
bidirectional neighbor, as detected via Hello packets from the
neighbor.
6.3. Changes to Interface State Machine
This section describes the changes to the interface state machine for
a MANET interface. The first two state transitions are for state-
event pairs that are described in RFC 2328, but have modified action
descriptions because MDRs are selected instead of DRs. The third
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state transition describes the action taken when the event
MDRNeighborChange is invoked, and replaces the corresponding state
transition in RFC 2328 for the event NeighborChange. The state
transition for the event BackupSeen does not apply to MANET
interfaces, since this event is never invoked for a MANET interface.
The interface state transitions for the events Loopback and UnloopInd
are unchanged from RFC 2328.
State: Down
Event: InterfaceUp
New state: Depends on action routine.
Action: Start the interval Hello Timer, enabling the periodic
sending of Hello packets out the interface. If the router
is not eligible to become an MDR (Router Priority is 0),
the state transitions to DR Other. Otherwise, the state
transitions to Waiting and the single shot Wait Timer is
started.
State: Waiting
Event: WaitTimer
New state: Depends on action routine.
Action: Run the MDR selection algorithm, which may result in a
change to the router's MDR Level, Dependent Neighbors,
and (Backup) MDR Parent. As a result of this calculation,
the new interface state will be DR Other, Backup, or DR.
As a result of these changes, the AdjOK? neighbor event
may be invoked for some or all neighbors. (See
Section 7.)
State(s): DR Other, Backup or DR
Event: MDRNeighborChange
New state: Depends on action routine.
Action: Run the MDR selection algorithm, which may result in a
change to the router's MDR Level, Dependent Neighbors,
and (Backup) MDR Parent. As a result of this calculation,
the new interface state will be DR Other, Backup, or DR.
As a result of these changes, the AdjOK? neighbor event
may be invoked for one or more neighbors. (See
Section 7.) To limit the amount of processing, the router
may delay running the MDR selection algorithm for up to
HelloInterval seconds. (For example, a router may wait
until just before the next Hello is sent, allowing the
updated MDR Parents to be included in the next Hello.)
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7. Adjacency Maintenance
Adjacency forming and eliminating on non-MANET interfaces remain
unchanged. Adjacency maintenance on a MANET interface requires
changes to transitions in the neighbor state machine ([RFC2328]
Section 10.3), to deciding whether to become adjacent ([RFC2328]
Section 10.4), sending of DD packets ([RFC2328] Section 10.8), and
receiving of DD packets ([RFC2328] Section 10.6). The specification
below relates to the MANET interface only.
Adjacencies are established with some subset of the router's
neighbors. Each (Backup) MDR forms adjacencies with a subset of its
(Backup) MDR neighbors to form a biconnected backbone, and each MDR
Other forms adjacencies with two selected (Backup) MDR neighbors
called "parents", thus providing a biconnected subgraph of
adjacencies.
An adjacency maintenance decision is made when any of the following
four events occur between a router and its neighbor. The decision is
made by executing the neighbor event AdjOK?.
(1) The neighbor state changes from Init to 2-Way.
(2) The MDR Level changes for the neighbor or for the router itself.
(3) The neighbor is selected to be the (Backup) MDR Parent.
(4) The neighbor selects the router to be its (Backup) MDR Parent.
7.1. Changes to Neighbor State Machine
The following specifies new transitions in the neighbor state
machine.
State(s): Down
Event: HelloReceived
New state: Depends on action routine.
Action: If the neighbor acceptance condition is satisfied (see
Section 4.3), the neighbor state transitions to Init and
the Inactivity Timer is started. Otherwise, the neighbor
remains in the Down state.
State(s): Init
Event: 2-WayReceived
New state: 2-Way
Action: Transition to neighbor state 2-Way.
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State(s): 2-Way
Event: AdjOK?
New state: Depends on action routine.
Action: Determine whether an adjacency should be formed with the
neighboring router (see Section 7.2). If not, the
neighbor state remains at 2-Way and no further action is
taken.
Otherwise, the neighbor state changes to ExStart, and the
following actions are performed. If the neighbor has a
larger Router ID than the router's own ID, and the
received packet is a DD packet with the initialize (I),
more (M), and master (MS) bits set, then execute the
event NegotiationDone, which causes the state to
transition to Exchange.
Otherwise (negotiation is not complete), the router
increments the DD sequence number in the neighbor data
structure. If this is the first time that an adjacency
has been attempted, the DD sequence number should be
assigned a unique value (like the time of day clock). It
then declares itself master (sets the master/slave bit to
master), and starts sending Database Description Packets,
with the initialize (I), more (M) and master (MS) bits
set, the MDR TLV included in an LLS, and the L bit set.
This Database Description Packet should be otherwise
empty. This Database Description Packet should be
retransmitted at intervals of RxmtInterval until the next
state is entered (see [RFC2328] Section 10.8).
State(s): ExStart or greater
Event: AdjOK?
New state: Depends on action routine.
Action: Determine whether the neighboring router should still be
adjacent (see Section 7.3). If yes, there is no state
change and no further action is necessary. Otherwise,
the (possibly partially formed) adjacency must be
destroyed. The neighbor state transitions to 2-Way. The
Link state retransmission list, Database summary list,
and Link state request list are cleared of LSAs.
7.2. Whether to Become Adjacent
The following defines the method to determine if an adjacency should
be formed between neighbors in state 2-Way. If the interface event
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MDRNeighborChange is scheduled, it should be executed before
proceeding. The following procedure does not depend on whether
AdjConnectivity is 1 or 2, but the selection of Dependent Neighbors
(by the MDR selection algorithm) depends on AdjConnectivity.
If adjacency reduction is not used (AdjConnectivity is 0), then an
adjacency is formed with each neighbor in state 2-Way. Otherwise an
adjacency is formed with a neighbor in state 2-Way if any of the
following conditions is true:
(1) The router is a (Backup) MDR and the neighbor is a (Backup)
MDR and is either a Dependent Neighbor or a Dependent Selector.
(2) The router is a (Backup) MDR and the neighbor is a child.
(3) The neighbor is a (Backup) MDR and is the router's (Backup)
Parent.
Otherwise, an adjacency is not established and the neighbor remains
in state 2-Way.
7.3. Whether to Eliminate an Adjacency
The following defines the method to determine if an adjacency should
be eliminated between neighbors in a state above 2-way. If the
interface event MDRNeighborChange is scheduled, it should be executed
before proceeding.
An adjacency is maintained if one of the following is true.
(1) The router is an MDR.
(2) The router is a Backup MDR.
(3) The neighbor is an MDR.
(4) The neighbor is a Backup MDR.
Otherwise, the adjacency MAY be eliminated.
7.4 Sending Database Description Packets
Sending a DD packet on a MANET interface is the same as [RFC2740]
Section 3.2.1.2 and [RFC2328] Section 10.8 with the following
additions to paragraph 3 of Section 10.8.
If the neighbor state is ExStart, the standard initialization packet
is sent with an MDR TLV appended using LLS, and the L bit is set in
the DD packet's option field. The DR and Backup DR fields of the MDR
TLV are set exactly the same as the DR and Backup DR fields of a
Hello sent on the same interface, as specified in Appendix A.3.
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7.5. Receiving Database Description Packets
Processing a DD packet received on a MANET interface is the same as
[RFC2328] Section 10.6, except for the changes described in this
section. The following additional steps are performed before
processing the packet based on neighbor state in paragraph 3 of
Section 10.6.
o If the DD packet's L bit is set in the options field and an MDR
TLV is appended, then the MDR TLV is processed as follows.
(1) If the DR field is equal to the neighhor's Router ID,
(a) Set the MDR Level of the neighbor to MDR.
(b) Set the neighbor's Dependent Selector variable to 1.
(2) Else if the Backup DR field is equal to the neighbor's
Router ID,
(a) Set the MDR Level of the neighbor to Backup MDR.
(b) Set the neighbor's Dependent Selector variable to 1.
(3) Else,
(a) Set the MDR Level of the neighbor to MDR Other.
(b) Set the neighbor's Dependent Selector variable to 0.
(4) If the DR or Backup DR field is equal to the router's own
Router ID, the neighbor's Child variable is set to 1,
otherwise it is zero.
o If the neighbor state is Init, the neighbor event 2-WayReceived is
executed.
o If the MDR Level of the neighbor changed, the neighbor state
machine is scheduled with the event AdjOK?.
o If the neighbor's Child status has changed from 0 to 1, the
neighbor state machine is scheduled with the event AdjOK?.
o If the neighbor's neighbor state changed from less than 2-Way to
2-Way or greater, the neighbor state machine is scheduled with the
event AdjOK?.
In addition, if the router accepts a received DD packet and processes
its contents, then the following action SHOULD be performed for each
LSA listed in the DD packet (whether the router is master or slave).
If the router has an instance of the LSA in the Database summary list
for the neighbor, which is the same or less recent than the LSA
listed in the packet, then the LSA is removed from the Database
summary list. This avoids including the LSA in a DD packet sent to
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the neighbor, when the neighbor already has an instance of the LSA
that is the same or more recent. This optimization reduces overhead
due to DD packets by approximately 50% in large networks.
8. Flooding Procedure
This section specifies the changes to RFC 2328, Section 13 for
routers that support OSPF-MDR. The first part of Section 13 (before
Section 13.1) is the same except for the following three changes.
o To exploit the broadcast nature of MANETs, if the Link State
Update (LSU) packet was received on a MANET interface, then the
packet is dropped without further processing only if the sending
neighbor is in a lesser state than 2-Way. Otherwise, the LSU
packet is processed as described in this section.
o If the received LSA is the same instance as the database copy, the
following actions are performed in addition to step 7. For each
MANET interface for which a BackupWait Neighbor List exists for
the LSA (see Section 8.1):
(a) Remove the sending neighbor from the BackupWait Neighbor list
if it belongs to the list.
(b) For each neighbor on the receiving interface that belongs
to the RNL for the sending neighbor, remove the neighbor
from the BackupWait Neighbor list if it belongs to the list.
o Step 8, which handles the case in which the database copy of the
LSA is more recent than the received LSA, is modified as follows.
If the sending neighbor is in a lesser state than Exchange, then
the router does not send the LSA back to the sending neighbor.
There are no changes to Sections 13.1, 13.2, or 13.4. The following
subsections describe the changes to Sections 13.3 (Next step in the
flooding procedure), 13.5 (Sending Link State Acknowledgments), 13.6
(Retransmitting LSAs), and 13.7 (Receiving Link State
Acknowledgments) of RFC 2328.
8.1. LSA Forwarding Procedure
Step 1 of [RFC2328], Section 13.3 should be performed, with the
following change, so that the new LSA is placed on the Link State
retransmission list for each appropriate adjacent neighbor. Step
1(c) is replaced with the following action, so that the LSA is not
placed on the retransmission list for a neighbor that has already
acknowledged the LSA.
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o If the new LSA was received from this neighbor, or an LS ACK for
the new LSA has already been received from this neighbor, examine
the next neighbor.
To determine whether an ACK for the new LSA has been received from
the neighbor, the router maintains an Acked LSA List for each
adjacent neighbor, as described in Section 8.4. When a new LSA is
received, the Acked LSA List for each neighbor, on each MANET
interface, should be updated by removing any LS ACK that is for an
older instance of the LSA than the one received.
The following description will use the notion of a "covered"
neighbor. A neighbor is defined to be covered if it belongs to the
Reported Neighbor List (RNL) for the neighbor from which the new LSA
was received.
Steps 2 through 5 of [RFC2328], Section 13.3 are unchanged if the
outgoing interface (on which the LSA may be forwarded) is not of type
MANET. If the outgoing interface is of type MANET, then steps 2
through 5 are replaced with the following steps, to determine whether
the LSA should be forwarded on each eligible MANET interface.
(2) If either of the following two conditions is satisfied for every
bidirectional neighbor on the interface, examine the next
interface (the LSA is not flooded out this interface).
(a) The LSA or an ACK for the LSA has been received from the
neighbor (over any interface).
(b) The LSA was received on a MANET interface, and the neighbor
is covered (defined above).
Note that the above two conditions do not assume the outgoing
interface is the same as the receiving interface.
(3) If the LSA was received on this interface, and the router is an
MDR Other for this interface, examine the next interface (the LSA
is not flooded out this interface).
(4) If the LSA was received on this interface, and the router is a
Backup MDR for this interface, then the router waits
BackupWaitInterval before deciding whether to flood the LSA. To
accomplish this, the router creates a BackupWait Neighbor List
for the LSA, which initially includes every bidirectional
neighbor on this interface that fails to satisfy both conditions
(a) and (b) in step 2. A single shot BackupWait Timer associated
with the LSA is started, which is set to expire after
BackupWaitInterval seconds plus a small amount of random jitter.
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(The actions performed when the BackupWait Timer expires are
described below.) Examine the next interface (the LSA is not
immediately flooded out this interface).
(5) If the router is an MDR for this interface, or if the LSA was
originated by the router itself, then the LSA is flooded out the
interface (whether or not the LSA was received on this
interface). The LSA is included in an LSU packet which is
multicast out the interface using the destination IP address
AllSPFRouters.
(6) If the LSA was received on a MANET interface that is different
from this (outgoing) interface, then the following two steps
SHOULD be performed to avoid redundant flooding.
(a) If the router has a larger value of (RtrPri, MDR Level, RID)
on the outgoing interface than every covered neighbor
(defined above) that is a neighbor on BOTH the receiving and
outgoing interfaces (or if no such neighbor exists), then the
LSA is flooded out the interface.
(b) Else, the router waits BackupWaitInterval before deciding
whether to flood the LSA on the interface, by performing the
actions in step 4 for a Backup MDR (whether or not the router
is a Backup MDR on this interface). A separate BackupWait
Neighbor List is created for each interface, but only one
BackupWait Timer is associated with the LSA. Examine the
next interface (the LSA is not immediately flooded out this
interface).
(7) If the optional step 6 is not performed, then the LSA is flooded
out the interface. The LSA is included in an LSU packet which is
multicast out the interface using the destination IP address
AllSPFRouters.
8.1.1. BackupWait Timer Expiration
If the BackupWait Timer for an LSA expires, then the following steps
are performed for each (MANET) interface for which a BackupWait
Neighbor List exists for the LSA.
(1) If the BackupWait Neighbor List for the interface contains at
least one router that is currently a bidirectional neighbor, the
following actions are performed.
(a) The LSA is flooded out the interface.
(b) If the LSA is on the Ack List for the interface (i.e., is
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scheduled to be included in a delayed Link State
Acknowledgment packet), then the router SHOULD remove the LSA
from the Ack List, since the flooded LSA will be treated as
an implicit ACK.
(c) If the LSA is on the Link State retransmission list for any
neighbor, the retransmission SHOULD be rescheduled (if
necessary) so that it does not occur within AckInterval plus
propagation delays.
(2) The BackupWait Neighbor list is then deleted (whether or not the
LSA is flooded).
8.1.2. Optional Treatment of Broadcast Network as MANET
In the LSA forwarding procedure described above, a router MAY treat
each of its broadcast interfaces the same as a MANET interface, with
the following substitutions. A DR is treated as an MDR, a Backup DR
is treated as a Backup MDR, and all neighbors on a broadcast
interface are considered to be covered if the LSA was sent by the DR
or Backup DR on the same interface. As in RFC 2328, Section 13.3,
only the DR and Backup DR use the IP address AllSPFRouters to flood
an LSA on a broadcast interface; all other routers use AllDRouters to
flood an LSA on a broadcast interface.
Treating a broadcast network as a MANET can greatly reduce flooding
overhead in some cases. For example, assume the LSA was received from
the DR of a broadcast network that includes 100 routers, and 50 of
the routers (not including the DR) are also attached to a MANET.
Assume that these 50 routers are neighbors of each other in the
MANET, and that each has a neighbor in the MANET that is not attached
to the broadcast network (and is therefore not covered). Then by
treating the broadcast network as a MANET in step 6 of the LSA
forwarding procedure, the number of routers that forward the LSA from
the broadcast network to the MANET is reduced from 50 to just 1
(assuming that at most one of the 50 routers is an MDR).
8.2. Sending Link State Acknowledgments
This section describes the procedure for sending Link State
Acknowledgments (LS ACKs) on MANET interfaces. Section 13.5 of RFC
2328 remains unchanged for non-MANET interfaces, but does not apply
to MANET interfaces. To minimize overhead due to LS ACKs, and to
take advantage of the broadcast nature of MANETs, all LS ACK packets
sent on a MANET interface are multicast using the IP address
AllSPFRouters. In addition, duplicate LSAs received as a multicast
are not acknowledged.
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When a router receives an LSA, it must decide whether to send a
delayed ACK, an immediate ACK, or no ACK. (However, a non-ackable
LSA is never acknowledged, as described in Appendix D.) A delayed
ACK may be delayed for up to AckInterval seconds, and allows several
LS ACKs to be grouped into a single multicast LS ACK packet. An
immediate ACK is also sent in a multicast LS ACK packet, and may
include other LS ACKs that were scheduled to be sent as delayed ACKs.
The decision depends on whether the received LSA is new (i.e., is
more recent than the database copy) or a duplicate (the same instance
as the database copy), and on whether the LSA was received as a
multicast or a unicast (which indicates a retransmitted LSA). The
following rules are used to make this decision.
(1) If the received LSA is new, a delayed ACK is sent on each
MANET interface associated with the area, unless the LSA is
flooded out the interface.
(2) If the LSA is a duplicate and was received as a multicast,
the LSA is not acknowledged.
(3) If the LSA is a duplicate and was received as a unicast:
(a) If the router is a (Backup) MDR, an immediate ACK is
sent out the receiving interface.
(b) If the router is an MDR Other, a delayed ACK is sent
out the receiving interface.
The reason that (Backup) MDRs send an immediate ACK when a
retransmitted LSA is received, is to try to prevent other adjacent
neighbors from retransmitting the LSA, since (Backup) MDRs usually
have a large number of adjacent neighbors. MDR Other routers do not
send an immediate ACK because they have fewer adjacent neighbors, and
so the potential benefit does not justify the additional overhead
resulting from sending immediate ACKs.
8.3. Retransmitting LSAs
LSAs are retransmitted according to Section 13.6 of RFC 2328. Thus,
LSAs are retransmitted only to adjacent routers. Therefore, since
OSPF-MDR does not allow an adjacency to be formed between two MDR
Other routers, an MDR Other never retransmits an LSA to another MDR
Other, only to its parents, which are (Backup) MDRs.
Retransmitted LSAs are included in LSU packets that are sent directly
to an adjacent neighbor that did not acknowledge the LSA (explicitly
or implicitly). The length of time between retransmissions is given
by the configurable interface parameter RxmtInterval, whose default
is 7 seconds for a MANET interface. To reduce overhead, several
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retransmitted LSAs should be included in a single LSU packet whenever
possible.
8.4. Receiving Link State Acknowledgments
A Link State Acknowledgment (LS ACK) packet that is received from an
adjacent neighbor (in state Exchange or greater) is processed as
described in Section 13.7 of RFC 2328, with the additional steps
described in this section. An LS ACK packet that is received from a
neighbor in a lesser state than Exchange is discarded.
Each router maintains an Acked LSA List for each adjacent neighbor,
to keep track of any LSA instances the neighbor has acknowledged, but
which the router itself has NOT yet received. This is necessary
because (unlike RFC 2328) each router acknowledges an LSA only the
first time it is received as a multicast.
If the neighbor from which the LS ACK packet was received is in state
Exchange or greater, then the following steps are performed for each
ACK in the received LS ACK packet:
(1) If the router does not have a database copy of the LSA being
acknowledged, or has a database copy which is less recent than
the one being acknowledged, the LS ACK is added to the Acked LSA
List for the sending neighbor.
(2) If the router has a database copy of the LSA being acknowledged,
which is the same as the instance being acknowledged, then the
following action is performed. For each MANET interface for which
a BackupWait Neighbor List exists for the LSA (see Section 8.1),
remove the sending neighbor from the BackupWait Neighbor list if
it belongs to the list.
9. Originating LSAs
Unlike the DR of an OSPF broadcast network, an MDR does not originate
a network-LSA, since a network-LSA cannot be used to describe the
general topology of a MANET. Instead, each router advertises a
subset of its MANET neighbors as point-to-point links in its router-
LSA. The choice of which neighbors to advertise is flexible, and is
determined by the configurable parameter LSAFullness.
If adjacency reduction is used (AdjConnectivity is 1 or 2), then as a
minimum requirement each router must advertise all of its fully
adjacent backbone neighbors in its router-LSA, where a backbone
neighbor is a neighbor that currently satisfies the condition for
becoming adjacent given in Section 7.2.
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This minimum choice corresponds to LSAFullness = 0, and results in
the minimum amount of LSA flooding overhead, but does not provide
routing along shortest paths.
Therefore, to allow routers to calculate shortest paths, without
requiring every pair of neighboring routers along the shortest paths
to be adjacent (which would be inefficient due to requiring a large
number of adjacencies), a router-LSA may also advertise non-adjacent
neighbors that satisfy a synchronization condition described below.
To motivate this, we note that OSPF already allows a non-adjacent
neighbor to be a next hop, if both the router and the neighbor belong
to the same broadcast network (and are both adjacent to the DR). A
network-LSA for a broadcast network (which includes all routers
attached to the network) implies that any router attached to the
network can forward packets directly to any other router attached to
the network (which is why the distance from the network to all
attached routers is zero in the graph representing the link-state
database).
Since a network-LSA cannot be used to describe the general topology
of a MANET, the only way to advertise non-adjacent neighbors that can
be used as next hops, is to include them in the router-LSA. However,
to ensure that such neighbors are sufficiently synchronized, only
"routable" neighbors are allowed to be included in LSAs, and to be
used as next hops in the SPF calculation.
9.1. Routable Neighbors
A bidirectional MANET neighbor becomes routable if its state is Full,
or if the SPF calculation has produced a route to the neighbor and
the neighbor satisfies the routable neighbor quality condition
(defined below). Since only routable neighbors are advertised in
router-LSAs, this definition implies that there exists, or recently
existed, a path of full adjacencies from the router to the routable
neighbor. The idea is that, since a routable neighbor can be reached
through an acceptable path, it makes sense to take a "shortcut" and
forward packets directly to the routable neighbor.
This requirement does not guarantee perfect synchronization, but
simulations have shown that it performs well in mobile networks.
This requirement avoids, for example, forwarding packets to a new
neighbor that is poorly synchronized because it was not reachable
before it became a neighbor.
To avoid selecting poor quality neighbors as routable neighbors, a
neighbor that is selected as a routable neighbor must satisfy the
routable neighbor quality condition. By default, this condition is
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that the neighbor's RNL must include the router itself (indicating
that the neighbor agrees the connection is bidirectional).
Optionally, a router may impose a stricter condition. For example, a
router may require that two Hellos have been received from the
neighbor that (explicitly or implicitly) indicate that the neighbor's
RNL includes the router itself.
The single-bit neighbor variable Routable indicates whether the
neighbor is routable. This variable is initially 0, and is updated
as follows when the state of the neighbor changes, or the SPF
calculation finds a route to the neighbor, or a Hello is received
that affects the routable neighbor quality condition:
(1) If Routable is 0 for the neighbor and the state of the neighbor
changes to Full, Routable is set to 1 for the neighbor.
(2) If Routable is 0 for the neighbor, the state of the neighbor is
2-Way or greater, there exists a route to the neighbor, and the
routable neighbor quality condition (defined above) is satisfied,
then Routable is set to 1 for the neighbor.
(3) If Routable is 1 for the neighbor and the state of the neighbor
is less than 2-Way, Routable is set to 0 for the neighbor.
9.2. Partial and Full Topology LSAs
The choice of which MANET neighbors to include in the router-LSA is
flexible, subject only to the following requirements:
(1) A router MUST include all fully adjacent backbone neighbors in
its router-LSA, i.e., all neighbors in state Full that currently
satisfy the condition for becoming adjacent.
(2) A router MUST NOT include any non-routable neighbors in its LSA.
Thus, a minimum LSA includes only Full neighbors, corresponding to
LSAFullness = 0. At the other extreme, a router may include all
routable neighbors in its router-LSA, corresponding to LSAFullness =
4 (full-topology LSAs). Between these two extremes, a router may
include any subset of routable neighbors in its router-LSA, as long
as all Full neighbors are included. It is not necessary for
different routers to make the same choice; the different choices are
interoperable because each router-LSA must include all Full
neighbors, which allows the SPF calculation to find routes to all
reachable routers.
A new router-LSA is originated whenever an event occurs that causes
the contents of the LSA to change (which depends on the choice of the
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LSA contents). However, as stated in RFC 2328, Section 12.4, two
instances of the same LSA may not be originated within the time
period MinLSInterval. This may require that the generation of the
next instance be delayed by up to MinLSInterval. When a new LSA is
originated, it is installed in the database as described in Section
13.2 of RFC 2328, which may cause the routing table to be
recalculated. The new LSA is also flooded as described in Section 8
of this document.
This document specifies two additional choices for partial-topology
LSAs, which provide shorter paths than minimal LSAs, but generate
substantially less overhead than full-topology LSAs.
9.2.1. Min-Cost LSAs (LSAFullness = 1)
Appendix C describes the algorithm for determining which neighbors to
include in the router-LSA when LSAFullness is 1 (min-cost LSAs). The
min-cost LSA algorithm ensures that the link-state database provides
sufficient information to calculate at least one shortest (minimum-
cost) path to each destination.
The input to this algorithm includes information obtained from Hellos
received from each MANET neighbor, including the Reported Neighbor
List (RNL), Dependent Neighbor List (DNL), Selected Advertised
Neighbor List (SANL), and the Metric TLV. The Metric TLV, described
in Section A.2.2.8, is included in each Hello and advertises the link
cost to each bidirectional neighbor. To minimize overhead, it allows
the option of advertising only a single metric for the interface
(equal to the link cost to each neighbor).
The output of the algorithm is the set of advertised neighbors to be
included in the router-LSA, and the SANL for the router, which
consists of the selected advertised neighbors that are listed in the
SANL TLV in each Hello. The algorithm also determines whether a new
LSA should be originated.
9.2.2. MDR Full LSAs (LSAFullness = 3)
Each (Backup) MDR originates a full LSA (which includes all routable
neighbors), while each MDR Other originates a minimum LSA (which
includes only Full neighbors). If a router has multiple MANET
interfaces, its LSA includes all routable neighbors on the interfaces
for which it is a (Backup) MDR, and includes only Full neighbors on
its other interfaces. When a router changes its MDR Level from MDR
Other to (Backup) MDR on a given interface, it originates a new LSA.
This choice provides routing along nearly min-cost paths.
A variation of MDR Full LSAs is possible, in which some MDR Other
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routers also select themselves to originate full LSAs, based on 2-hop
neighbor information. A heuristic can be used for such a selection
that results in routes that are arbitrarily close to min-cost on
average. Such a heuristic may be described in a future version of
this draft.
10. Calculating the Routing Table
The routing table calculation is the same as specified in RFC 2328,
except for the following change to Section 16.1 (Calculating the
shortest-path tree for an area).
Recall from Section 9 that a router can use any routable neighbor as
a next hop to a destination. However, unless LSAFullness = 4 (full
topology LSAs), the router-LSA originated by the router usually does
not include all routable neighbors. Therefore, the shortest-path
tree calculation described in Section 16.1 of RFC 2328 must be
modified to allow any routable neighbor on a MANET interface to be
used as a next hop. This is accomplished simply by modifying step 2
so that the router-LSA associated with the root vertex (i.e., the
router doing the calculation) is augmented to include all routable
neighbors on each MANET interface. That is, the router-LSA used in
the SPF calculation is the one that the router would originate if
LSAFullness were equal to 4 (even if LSAFullness is actually less
than 4).
Note that, if LSAFullness is less than 4, then the set of routable
neighbors can change without causing the contents of the router-LSA
to change. This could happen, for example, if a routable neighbor
that was not included in the router-LSA transitions to the Down or
Init state. Therefore, if the set of routable neighbors changes, the
routing table must be recalculated even if the router-LSA does not
change.
11. Security Considerations
This document does not currently specify security considerations.
12. IANA Considerations
This document does not currently specify IANA considerations.
13. Acknowledgments
Thanks to Aniket Desai for helpful discussions and comments,
including the suggestion that Router Priority should come before MDR
Level in the lexicographical comparison of (RtrPri, MDR Level, RID)
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when selecting MDRs and BMDRs. Thanks also to Tom Henderson for
helpful discussions and comments.
14. Normative References
[RFC2328] J. Moy. "OSPF Version 2", RFC 2328, April 1998.
[RFC2740] R. Coltun, D. Ferguson, and J. Moy. "OSPF for IPv6", RFC
2740, December 1999.
[LLS] A. Zinin, B. Friedman, A. Roy, L. Nguyen, and D. Young, "OSPF
Link-local Signaling", draft-ietf-ospf-lls-02.txt (work in
progress), January 2007.
[RFC2119] Bradner, S., "Key words for use in RFC's to Indicate
Requirement Levels", RFC 2119, March 1997.
15. Informative References
[Lawler] E. Lawler. "Combinatorial Optimization: Networks and
Matroids", Holt, Rinehart, and Winston, New York, 1976.
[Suurballe] J.W. Suurballe and R.E. Tarjan. "A Quick Method for
Finding Shortest Pairs of Disjoint Paths", Networks, Vol. 14,
pp. 325-336, 1984.
A. Packet Formats
A.1. Options Field
A new bit, called L (for LLS) is introduced to OSPFv3 Options field
(see Figure A.1). The mask for the bit is 0x200. Routers set the L
bit in Hello and DD packets to indicate that the packet contains LLS
data block. Routers set the L bit in a self-originated router-LSA to
indicate that the LSA is non-ackable.
A new D bit is defined in the OSPFv3 option field. The bit is
defined for Hello packets and indicates that only differential
information is present. The mask for the bit is 0x400.
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0 1 2
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+-+-+--+--+--+--+--+--+
| | | | | | | | | | | | | |D|L|AF|*|*|DC| R| N|MC| E|V6|
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+-+-+--+--+--+--+--+--+
Figure A.1: The Options field
A.2. Link-Local Signaling
Link-local signaling (LLS) [LLS] describes an extension to OSPFv2 and
OSPFv3 which allows the exchange of arbitrary data using existing,
standard OSPF packet types. Here we use LLS for OSPFv3, which is
accomplished by adding an LLS data block at the end of the OSPFv3
packet.
The IPv6 header length includes the total length of the OSPFv3
header, OSPFv3 data, and LLS data, but the OSPFv3 header does not
contain the LLS data length in its length field. The IPv6 packet
format is depicted in Figure A.2 below.
+---------------------+ --
| IPv6 Header | ^
| Length = HL+X+Y | | Header Length = HL
| | v
+---------------------+ --
| OSPFv3 Header | ^
| Length = X | |
|.....................| | X
| | |
| OSPFv3 Data | |
| | v
+---------------------+ --
| | ^
| LLS Data | | Y
| | v
+---------------------+ --
Figure A.2: Attaching LLS Data Block
The LLS data block may be attached to OSPFv3 Hello and Database
Description (DD) packets. The data included in the LLS block
attached to a Hello packet may be used for dynamic signaling, since
Hello packets may be sent at any moment in time. However, delivery of
LLS data in Hello packets is not guaranteed. The data sent with DD
packets is guaranteed to be delivered as part of the adjacency
forming process.
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A.2.1 LLS Data Block
The data block used for link-local signaling is formatted as
described below (see Figure A.3 for illustration).
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Checksum | LLS Data Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
| LLS TLVs |
. .
. .
. .
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure A.3: Format of LLS Data Block
The Checksum field contains the standard IP checksum of the entire
contents of the LLS block.
The 16-bit LLS Data Length field contains the length (in 32-bit
words) of the LLS block including the header and payload.
Implementations should not use the Length field in the IPv6 packet
header to determine the length of the LLS data block.
The rest of the block contains a set of Type/Length/Value (TLV)
triplets as described in the following section. All TLVs must be
32-bit aligned (with padding if necessary).
A.2.2 LLS TLVs
The contents of LLS data block is constructed using TLVs. See Figure
A.4 for the TLV format.
The type field contains the TLV ID which is unique for each type of
TLVs. The Length field contains the length of the Value field (in
bytes) that is variable and contains arbitrary data.
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
. .
. Value .
. .
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure A.4: Format of LLS TLVs
Note that TLVs are always padded to 32-bit boundary, but padding
bytes are not included in TLV Length field (though it is included in
the LLS Data Length field of the LLS block header). All unknown TLVs
MUST be silently ignored.
A.2.2.1 Heard Neighbor List (HNL) TLV
A new TLV is defined in this document which indicates neighbor(s)
that are in state Init (or recently changed to Init if the Hello is
differential). This TLV is used in conjunction with a Hello packet.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Heard Neighbor(s) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+--+-+-+-+-+-+-+-+-+-+-+-+-+
| ....
+--------------------
o Type: Set to 11.
o Length: Set to the number of heard neighbors included in
the TLV multiplied by 4.
o Heard Neighbor(s) - Router ID of the heard neighbor.
A.2.2.2 Reported Neighbor List (RNL) TLV
A new TLV is defined in this document which indicates neighbor(s)
that are in state 2-Way or greater (or recently changed to 2-Way or
greater if the Hello is differential). This TLV is used in
conjunction with a Hello packet.
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Reported Neighbor(s) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ....
+--------------------
o Type: Set to 12.
o Length: Set to the number of reported neighbors included in
the TLV multiplied by 4.
o Reported Neighbor(s) - Router ID of the reported neighbor.
A.2.2.3 Lost Neighbor List (LNL) TLV
A new TLV is defined in this document which indicates neighbor(s)
that have recently been lost by the sender. This TLV is used in
conjunction with a Hello packet.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Lost Neighbor(s) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ....
+--------------------
o Type: Set to 13.
o Length: Set to the number of lost neighbors included in
the TLV multiplied by 4.
o Lost Neighbor(s) - Router ID of the reported neighbor.
A.2.2.4 Hello Sequence TLV
A new TLV is defined that indicates the current Hello sequence number
(HSN) for the transmitting interface. This TLV is used in
conjunction with a Hello packet.
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+--+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+--+-+-+-+-+-+-+-+-+-+-+-+-+
| Hello Sequence Number | Reserved |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+--+-+-+-+-+-+-+-+-+-+-+-+-+
o Type: Set to 14.
o Length: Set to 4.
o Hello Sequence Number: A circular two octet unsigned integer
indicating the current HSN for the transmitting interface. The
HSN for the interface MUST be incremented by 1 every time a
(differential or full) Hello is sent on the interface.
o Reserved: Set to 0. Reserved for future use.
A.2.2.5 MDR TLV
A new TLV is defined which includes the same two Router IDs that are
included in the DR and Backup DR fields of a Hello sent by the
router. This TLV is used in conjunction with a Database Description
packet, and is used to indicate the router's MDR Level and selected
parent(s).
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+--+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+--+-+-+-+-+-+-+-+-+-+-+-+-+
| DR |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+--+-+-+-+-+-+-+-+-+-+-+-+-+
| Backup DR |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+--+--+-+-+-+-+-+-+-+-+-+-+-+-+
o Type: Set to 15.
o Length: Set to 8.
o DR: The same Router ID that is included in the DR field of a
Hello sent by the router (see Appendix A.3).
o Backup DR: The same Router ID that is included in the Backup DR
field of a Hello sent by the router (see Appendix A.3).
A.2.2.6 Dependent Neighbor List (DNL) TLV
A new TLV is defined which indicates neighbor(s) that are currently
selected as Dependent Neighbors. This TLV is used in conjunction
with a Hello packet.
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Dependent Neighbor(s) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ....
+--------------------
o Type: Set to 16.
o Length: Set to the number of reported neighbors included in
the TLV multiplied by 4.
o Dependent Neighbor(s) - Router ID of the reported neighbor.
A.2.2.7 Selected Advertised Neighbor List (SANL) TLV
A new TLV is defined in this document which indicates neighbor(s)
that belong to the Selected Advertised Neighbor List (SANL), which is
calculated by the min-cost LSA algorithm. This TLV is included in
Hello packets.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Selected Advertised Neighbor(s) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ....
+--------------------
o Type: Set to 17.
o Length: Set to the number of neighbors included in the TLV
multiplied by 4.
o Selected Advertised Neighbor(s) - Router ID of each selected
advertised neighbor.
A.2.2.8 Metric TLV
A new TLV is defined in this document which advertises the link cost
to each bidirectional neighbor. At a minimum, this TLV advertises a
single default cost for the interface. In addition, the link cost is
advertised for each neighbor whose link cost is not equal to the
default cost. The link cost for any neighbor not included is assumed
to be equal to the default cost. This format reduces overhead when
all neighbors have the same link cost, or only a few neighbors have a
link cost that differs from the default cost. This TLV is included
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in Hello packets.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Default Metric | Reserved |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Neighbor (1) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Neighbor (2) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ... |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Metric (1) | Metric (2) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
o Type: Set to 18.
o Length: Set to 4 + 6*N, where N is the number of neighbors
included in the TLV.
o Neighbor - Router ID of each neighbor included in the TLV.
o Metric - Link cost for each neighbor, listed in the same order
as the Router IDs.
A.3. Hello Packet DR and Backup DR Fields
The Designated Router (DR) and Backup DR fields of a Hello packet are
set as follows:
o DR: If the router is an MDR, this field is the router's own
Router ID. Otherwise, this field is the router's MDR Parent,
or is 0.0.0.0 if the MDR Parent is null.
o Backup DR: If the router is a BMDR, this field is the router's
own Router ID. If the router is an MDR, this field is the
router's MDR Parent. Otherwise, this field is the router's
Backup MDR Parent, or is 0.0.0.0 if the Backup MDR Parent
is null.
A.4. LSA Formats and Examples
LSA formats are specified in [RFC2740] Section 3.4.3. Figure A.5
below gives an example network map for a MANET in a single area.
o Four MANET nodes RT1, RT2, RT3, and RT4 are in area 1.
o RT1's MANET interface has links to RT2 and RT3's MANET interfaces.
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o RT2's MANET interface has links to RT1 and RT3's MANET interfaces.
o RT3's MANET interface has links to RT1, RT2, and RT3's MANET
interfaces.
o RT4's MANET interface has a link to RT3's MANET interface.
o RT1 and RT2 have stub networks attached on broadcast interfaces.
o RT3 has a transit network attached on a broadcast interface.
..........................................
. Area 1.
. + .
. | .
. | 2+---+1 1+---+
. N1 |--|RT1|-----+ +---|RT4|----
. | +---+ | / +---+
. | | / .
. + | N3 / .
. | / .
. + | / .
. | | / .
. | 2+---+1 | / .
. N2 |--|RT2|-----+-------+ .
. | +---+ |1 .
. | +---+ .
. | |RT3|----------------
. + +---+ .
. |2 .
. +------------+ .
. |1 N4 .
. +---+ .
. |RT5| .
. +---+ .
..........................................
Figure A.5: Area 1 with IP addresses shown
Network IPv6 prefix
-----------------------------------
N1 5f00:0000:c001:0200::/56
N2 5f00:0000:c001:0300::/56
N4 5f00:0000:c001:0400::/56
Table 1: IPv6 link prefixes for sample network
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Router interface Interface ID IPv6 global unicast prefix
-----------------------------------------------------------
RT1 LOOPBACK 0 5f00:0001::/64
to N3 1 n/a
to N1 2 5f00:0000:c001:0200::RT1/56
RT2 LOOPBACK 0 5f00:0002::/64
to N3 1 n/a
to N2 2 5f00:0000:c001:0300::RT2/56
RT3 LOOPBACK 0 5f00:0003::/64
to N3 1 n/a
to N4 2 5f00:0000:c001:0400::RT3/56
RT4 LOOPBACK 0 5f00:0004::/64
to N3 1 n/a
RT5 to N4 1 5f00:0000:c001:0400::RT5/56
Table 2: IPv6 link prefixes for sample network
Router interface Interface ID link-local address
-------------------------------------------------------
RT1 LOOPBACK 0 n/a
to N1 1 fe80:0001::RT1
to N3 2 fe80:0002::RT1
RT2 LOOPBACK 0 n/a
to N2 1 fe80:0001::RT2
to N3 2 fe80:0002::RT2
RT3 LOOPBACK 0 n/a
to N3 1 fe80:0001::RT3
to N4 2 fe80:0002::RT3
RT4 LOOPBACK 0 n/a
to N3 1 fe80:0001::RT4
RT5 to N4 1 fe80:0002::RT5
Table 3: OSPF Interface IDs and link-local addresses
A.4.1 Router-LSAs
As an example, consider the router-LSA that node RT3 would originate.
The node consists of one MANET, one broadcast, and one loopback
interface.
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RT3's router-LSA
LS age = DoNotAge+0 ;newly originated
LS type = 0x2001 ;router-LSA
Link State ID = 0 ;first fragment
Advertising Router = 192.1.1.3 ;RT3's Router ID
bit E = 0 ;not an AS boundary router
bit B = 1 ;area border router
Options = (V6-bit|E-bit|R-bit)
Type = 1 ;p2p link to RT1
Metric = 11 ;cost to RT1
Interface ID = 1 ;Interface ID
Neighbor Interface ID = 1 ;Interface ID
Neighbor Router ID = 192.1.1.1 ;RT1's Router ID
Type = 1 ;p2p link to RT2
Metric = 12 ;cost to RT2
Interface ID = 1 ;Interface ID
Neighbor Interface ID = 1 ;Interface ID
Neighbor Router ID = 192.1.1.2 ;RT2's Router ID
Type = 1 ;p2p link to RT4
Metric = 13 ;cost to RT4
Interface ID = 1 ;Interface ID
Neighbor Interface ID = 1 ;Interface ID
Neighbor Router ID = 192.1.1.4 ;RT4's Router ID
Type = 2 ;connects to N4
Metric = 1 ;cost to N4
Interface ID = 2 ;RT3's Interface ID
Neighbor Interface ID = 1 ;RT5's Interface ID (elected DR)
Neighbor Router ID = 192.1.1.5 ;RT5's Router ID (elected DR)
A.4.2 Link-LSAs
Consider the link-LSA that RT3 would originate for its MANET
interface.
RT3's Link-LSA for its MANET interface
LS age = DoNotAge+0 ;newly originated
LS type = 0x0008 ;Link-LSA
Link State ID = 1 ;Interface ID
Advertising Router = 192.1.1.3 ;RT3's Router ID
RtrPri = 1 ;default priority
Options = (V6-bit|E-bit|R-bit)
Link-local Interface Address = fe80:0001::RT3
# prefixes = 0 ;no global unicast address
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A.4.3 Intra-Area-Prefix-LSAs
A MANET node originates an intra-area-prefix-LSA to advertise its own
prefixes, and those of its attached networks or stub links. As an
example, consider the intra-area-prefix-LSA that RT3 will build.
RT2's intra-area-prefix-LSA for its own prefixes
LS age = DoNotAge+0 ;newly originated
LS type = 0x2009 ;intra-area-prefix-LSA
Link State ID = 177 ;or something
Advertising Router = 192.1.1.3 ;RT3's Router ID
# prefixes = 2
Referenced LS type = 0x2001 ;router-LSA reference
Referenced Link State ID = 0 ;always 0 for router-LSA reference
Referenced Advertising Router = 192.1.1.3 ;RT2's Router ID
PrefixLength = 64 ;prefix on RT3's LOOPBACK
PrefixOptions = 0
Metric = 0 ;cost of RT3's LOOPBACK
Address Prefix = 5f00:0003::/64
PrefixLength = 56 ;prefix on RT3's interface 2
PrefixOptions = 0
Metric = 1 ;cost of RT3's interface 2
Address Prefix = 5f00:0000:c001:0400::RT3/56 ;pad
B. Detailed Algorithms for MDR/BMDR Selection
This section provides detailed algorithms for Step 2.4 of Phase 2
(MDR Selection) and Step 3.2 of Phase 3 (BMDR Selection) of the MDR
selection algorithm described in Section 5. Step 2.4 uses a breadth-
first search (BFS) algorithm, and Step 3.2 uses an efficient
algorithm for finding pairs of node-disjoint paths from Rmax to all
other neighbors. Both algorithms run in O(d^2) time, where d is the
number of neighbors.
For convenience, in the following descriptions, the term "neighbor"
will refer to a neighbor on the MANET interface that is bidirectional
(in state 2-Way or greater). Also, node i denotes the router
performing the calculation.
B.1. Detailed Algorithm for Step 2.4 (MDR Selection)
The following algorithm performs Step 2.4 of the MDR selection
algorithm, and assumes that Phase 1 and Steps 2.1 through 2.3 have
been performed, so that the neighbor connectivity matrix NCM has been
computed, and Rmax is the neighbor with the (lexicographically)
largest value of (RtrPri, MDR Level, RID). The BFS algorithm uses a
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FIFO queue so that all nodes 1 hop from node Rmax are processed
first, then 2 hops, etc. When the BFS algorithm terminates, hops(u),
for each neighbor node u of node i, will be equal to the minimum
number of hops from node Rmax to node u, using only intermediate
nodes that are neighbors of node i and that have a larger value of
(RtrPri, MDR Level, RID) than node i. The algorithm also computes,
for each node u, the tree parent p(u) and the second node r(u) on the
tree path from Rmax to u, which will be used in Step 3.2
(a) Compute a matrix of link costs c(u,v) for each pair of
neighbors u and v as follows: If node u has a larger value
of (RtrPri, MDR Level, RID) than node i, and NCM(u,v) = 1,
then set c(u,v) to 1. Otherwise, set c(u,v) to infinity.
(Note that the matrix NCM(u,v) is symmetric, but the matrix
c(u,v) is not.)
(b) Set hops(u) = infinity for all neighbors u other than Rmax,
and set hops(Rmax) = 0. Initially, p(u) is undefined for each
neighbor u. For each neighbor u that is a neighbor of Rmax,
set r(u) = u; for all other u, r(u) is initially undefined.
Add node Rmax to the FIFO queue.
(c) While the FIFO queue is nonempty:
Remove the node at the head of the queue; call it node u.
For each neighbor v of node i such that c(u,v) = 1:
If hops(v) > hops(u) + 1, then set hops(v) = hops(u) + 1,
set p(v) = u, set r(v) = r(u) if hops(v) > 1, and add
node v to the tail of the queue.
B.2. Detailed Algorithm for Step 3.2 (BMDR Selection)
Step 3.2 of the MDR selection algorithm requires the router to
determine whether there exist two node-disjoint paths from Rmax to
each other neighbor u, via neighbor nodes that have a larger value of
(RtrPri, MDR Level, RID) than the router itself. This information is
needed to determine whether the router should select itself as a
BMDR.
It is possible to determine separately for each neighbor u whether
there exist two node-disjoint paths from Rmax to u, using the well-
known augmenting path algorithm [Lawler] which runs in O(n^2) time,
but this must be done for all neighbors u, thus requiring a total run
time of O(n^3). The algorithm described below makes the same
determination simultaneously for all neighbors u, achieving a much
faster total run time of O(n^2). The algorithm is a simplified
variation of the Suurballe-Tarjan algorithm [Suurballe] for finding
pairs of disjoint paths.
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The algorithm described below uses the following output of Phase 2:
the tree parent p(u) of each node (which defines the BFS tree
computed in Phase 2), and the second node r(u) on the tree path from
Rmax to u.
The algorithm uses the following concepts. For any node u on the BFS
tree other than Rmax, we define g(u) to be the first labeled node on
the reverse tree path from u to Rmax, if such a labeled node exists
other than Rmax. (The reverse tree path consists of u, p(u),
p(p(u)), ..., Rmax.) If no such labeled node exists, then g(u) is
defined to be r(u). In particular, if u is labeled then g(u) = u.
Note that g(u) either must be labeled or must be a neighbor of Rmax.
For any node k that either is labeled or is a neighbor of Rmax, we
define the unlabeled subtree rooted at k, denoted S(k), to be the set
of nodes u such that g(u) = k. Thus, S(k) includes node k itself and
the set of unlabeled nodes downstream of k on the BFS tree that can
be reached without going through any labeled nodes. This set can be
obtained in linear time using a depth-first search starting at node
k, and using labeled nodes to indicate the boundaries of the search.
Note that g(u) and S(k) are not maintained as variables in the
algorithm given below, but simply refer to the definitions given
above.
The BMDR algorithm maintains a set B, which is initially empty. A
node u is added to B when it is known that two node-disjoint paths
exist from Rmax to u via nodes that have a larger value of (RtrPri,
MDR Level, RID) than the router itself. When the algorithm
terminates, B consists of all neighbors that have this property.
The algorithm consists of the following two steps.
(a) Mark Rmax as labeled. For each pair of nodes u, v on the BFS
tree other than Rmax such that r(u) is not equal to r(v) (i.e.,
u and v have different second nodes), NCM(u,v) = 1, and node u
has a greater value of (RtrPri, MDR level, RID) than the router
itself, add v to B. (Clearly there are two disjoint paths from
Rmax to v.)
(b) While there exists a node in B that is not labeled, do the
following. Choose any node k in B that is not labeled, and let
j = g(k). Now mark k as labeled. (This creates a new unlabeled
subtree S(k), and makes S(j) smaller by removing S(k) from it.)
For each pair of nodes u, v such that u is in S(k), v is in
S(j), and NCM(u,v) = 1:
o If u has a larger value of (RtrPri, MDR level, RID) than the
router itself, and v is not in B, then add v to B.
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o If v has a larger value of (RtrPri, MDR level, RID) than the
router itself, and u is not in B, then add u to B.
The above algorithm can be executed in O(n^2) time, where n is the
number of neighbors. Step 1 clearly requires O(n^2) time since it
considers all pairs of nodes u and v. Step 2 also requires O(n^2)
time because each pair of nodes is considered at most once. This is
because labeling nodes divides unlabeled subtrees into smaller
unlabeled subtrees, and a given pair u, v is considered only the
first time u and v belong to different unlabeled subtrees.
C. Min-Cost LSA Algorithm
This section describes the algorithm for determining which neighbors
to include in the router-LSA when LSAFullness is 1 (min-cost LSAs).
The min-cost LSA algorithm ensures that the link-state database
provides sufficient information to calculate at least one shortest
(minimum-cost) path to each destination.
The input to this algorithm includes information obtained from Hellos
received from each MANET neighbor, including the Reported Neighbor
List (RNL), Dependent Neighbor List (DNL), Selected Advertised
Neighbor List (SANL), and the Metric TLV.
The output of the algorithm is the set of advertised neighbors to be
included in the router-LSA, and the SANL for the router, which
includes the selected advertised neighbors to be advertised in
Hellos. The min-cost LSA algorithm must be run to possibly originate
a new router-LSA whenever any of the following events occurs:
o The state or routability of a neighbor changes.
o A Hello received from a neighbor indicates a change in its
RNL, DNL, SANL, neighbor metrics, MDR level, or MDR parent(s).
Although the algorithm described below runs in O(d^3) time, where d
is the number of neighbors, an incremental version for a single
topology change runs in O(d^2) time, as discussed following the
algorithm description.
For simplicity, the algorithm is described assuming that each router
has a single MANET interface. The extension to multiple interfaces
is straightforward and will be described in a future version of this
draft.
For convenience, in the following description, the term "neighbor"
will refer to a neighbor that is bidirectional (in state 2-Way or
greater). Also, router i will denote the router doing the
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calculation. To perform the min-cost LSA algorithm, the following
steps are performed.
(1) Create the neighbor connectivity matrix (NCM) as described in
Section 5.1.
(2) Create the inter-neighbor cost matrix (INCM) as follows. For
each pair j, k of routers such that j is a neighbor, and k is
either a neighbor or router i itself:
(a) If NCM(j,k) = 1 (j and k are neighbors of each other), set
INCM(j,k) to the metric of the link from j to k obtained from
j's Hellos.
(b) If NCM(j,k) = 0, set INCM(j,k) to LSInfinity.
(3) Create the required advertised neighbor matrix (RANM) as follows.
If adjacency reduction is used and NCM(j,k) = 1, RANM(j,k) is set
to 1 if any of the following conditions is satisfied (equivalent
to the conditions for becoming adjacent):
(a) Routers j and k are both (Backup) MDRs, and either k is
included in j's DNL or j is included in k's DNL.
(b) Router j is a (Backup) MDR and is the (Backup) Parent of
router k.
(c) Router k is a (Backup) MDR and is the (Backup) Parent of
router j.
Otherwise, RANM(j,k) is set to 0.
(4) Create the selected advertised neighbor matrix (SANM) as follows.
If NCM(j,k) = 1, then SANM(j,k) is set to 1 if k is included in
j's SANL. Otherwise, SANM(j,k) is set to 0. SANM(j,k) is
defined similarly if j or k is equal to the router i
(5) Compute the new set of selected advertised neighbors as follows.
For each (bidirectional) MANET neighbor j, initialize the bit
variable new_sel_adv(j) to 0. (This bit will be set to 1 if j is
selected.) For each MANET neighbor j:
(a) For each neighbor k not equal to j, determine whether there
exists a 1-hop or 2-hop path from k to j, allowing only
neighbors of i to be used as an intermediate hop, that is
"better" than the 2-hop path k -> i -> j through router i.
The 1-hop path k -> j is considered better if it has the same
or smaller cost, i.e., if INCM(k,j) <= INCM(k,i) + INCM(i,j).
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A 2-hop path k -> u -> j, where u is a neighbor of i, is
considered better if it has smaller cost, i.e., INCM(k,u) +
INCM(u,j) < INCM(k,i) + INCM(i,j), or if it has the same cost
and (SANM(j,u), SANM(u,j), RtrPri(u), MDR_Level(u), RID(u))
is lexicographically greater than (SANM(j,i), SANM(i,j),
RtrPri(i), MDR_Level(i), RID(i)).
(b) If for some neighbor k, there does not exist a better 1-hop
or 2-hop path from k to j (as defined above), then set
new_sel_adv(j) = 1.
(6) Update the SANL to include all neighbors j such that
new_sel_adv(j) = 1. Update the set of advertised neighbors to
include all routable MANET neighbors j that satisfy at least one
of the following three conditions:
(a) j is a selected advertised neighbor (belongs to the router
i's SANL)
(b) The SANL for j includes i (to ensure symmetry)
(c) Adjacency reduction is used and router j satisfies the
condition for becoming adjacent, as specified in Section 7.2.
(7) A new LSA is originated that includes the new set of advertised
neighbors if either of the following conditions holds:
(a) The existing LSA does not include all neighbors in the new
set of advertised neighbors.
(b) The existing LSA includes a neighbor that is no longer
bidirectional.
The lexicographical comparison of Step 5a gives preference to links
that are already advertised, in order to improve LSA stability.
The above algorithm can be run in O(d^2) time if a single link change
occurs. For example, if link (x,y) fails where x and y are neighbors
of router i, and either SANL(x,y) = 1 or RANL(x,y) = 1, then Step 5
need only be performed for pairs j, k such that either j or k is
equal to x or y.
D. Non-Ackable LSAs for Periodic Flooding
In a highly mobile network, it is possible that a router almost
always originates a new router-LSA every MinLSInterval seconds. In
this case, it should not be necessary to send ACKs for such an LSA,
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or to retransmit such an LSA as a unicast, or to describe such an LSA
in a DD packet. In this case, the originator of an LSA MAY indicate
that the router-LSA is "non-ackable" by setting the L bit in the
options field of the LSA. For example, a router can originate non-
ackable LSAs if it determines (e.g., based on an exponential moving
average) that a new LSA is originated every MinLSInterval seconds at
least 90 percent of the time. (Simulations are needed to determine
the best threshold.)
A non-ackable LSA is never acknowledged, nor is it ever retransmitted
as a unicast or described in a DD packet, thus saving substantial
overhead. However, the originating router must periodically
retransmit the current instance of its router-LSA as a multicast
(until it originates a new LSA, which will usually happen before the
previous instance is retransmitted), and each MDR must periodically
retransmit each non-ackable LSA as a multicast (until it receives a
new instance of the LSA, which will usually happen before the
previous instance is retransmitted). The retransmission interval
should be slightly larger than MinLSInterval (e.g., MinLSInterval +
1) so that a new instance of the LSA is usually received before the
previous one is retransmitted. Note that the reception of a
retransmitted (duplicate) LSA does not result in immediate forwarding
of the LSA; only a new LSA (with a larger sequence number) may be
forwarded immediately, according to the flooding procedure of
Section 8.
Authors' Addresses
Richard G. Ogier
SRI International
Email: rich.ogier@earthlink.net, richard.ogier@sri.com
Phil Spagnolo
Boeing Phantom Works
Email: phillip.a.spagnolo@boeing.com
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