<- RFC Index (7701..7800)
RFC 7722
Updates RFC 7188, RFC 7631
Internet Engineering Task Force (IETF) C. Dearlove
Request for Comments: 7722 BAE Systems
Updates: 7188, 7631 T. Clausen
Category: Experimental LIX, Ecole Polytechnique
ISSN: 2070-1721 December 2015
Multi-Topology Extension
for the Optimized Link State Routing Protocol Version 2 (OLSRv2)
Abstract
This specification describes an extension to the Optimized Link State
Routing Protocol version 2 (OLSRv2) to support multiple routing
topologies, while retaining interoperability with OLSRv2 routers that
do not implement this extension.
This specification updates RFCs 7188 and 7631 by modifying and
extending TLV registries and descriptions.
Status of This Memo
This document is not an Internet Standards Track specification; it is
published for examination, experimental implementation, and
evaluation.
This document defines an Experimental Protocol for the Internet
community. This document is a product of the Internet Engineering
Task Force (IETF). It represents the consensus of the IETF
community. It has received public review and has been approved for
publication by the Internet Engineering Steering Group (IESG). Not
all documents approved by the IESG are a candidate for any level of
Internet Standard; see Section 2 of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc7722.
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Copyright Notice
Copyright (c) 2015 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
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Table of Contents
1. Introduction ....................................................4
1.1. Motivation and Experimentation .............................4
2. Terminology and Notation ........................................5
3. Applicability Statement .........................................6
4. Protocol Overview and Functioning ...............................6
5. Parameters ......................................................8
6. Information Bases ...............................................9
6.1. Local Attached Network Set .................................9
6.2. Link Sets ..................................................9
6.3. 2-Hop Sets .................................................9
6.4. Neighbor Set ...............................................9
6.5. Router Topology Set .......................................10
6.6. Routable Address Topology Set .............................10
6.7. Attached Network Set ......................................10
6.8. Routing Sets ..............................................11
7. TLVs ...........................................................11
7.1. Message TLVs ..............................................11
7.1.1. MPR_TYPES TLV ......................................11
7.1.2. MPR_WILLING TLV ....................................11
7.2. Address Block TLVs ........................................12
7.2.1. LINK_METRIC TLV ....................................12
7.2.2. MPR TLV ............................................13
7.2.3. GATEWAY TLV ........................................13
8. HELLO Messages .................................................14
8.1. HELLO Message Generation ..................................14
8.2. HELLO Message Processing ..................................15
9. TC Messages ....................................................15
9.1. TC Message Generation .....................................15
9.2. TC Message Processing .....................................16
10. MPR Calculation ...............................................16
11. Routing Set Calculation .......................................17
12. Management Considerations .....................................17
13. IANA Considerations ...........................................18
13.1. Expert Review: Evaluation Guidelines .....................18
13.2. Message TLV Types ........................................18
13.3. Address Block TLV Types ..................................20
14. Security Considerations .......................................21
15. References ....................................................22
15.1. Normative References .....................................22
15.2. Informative References ...................................22
Acknowledgments ...................................................23
Authors' Addresses ................................................23
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1. Introduction
The Optimized Link State Routing Protocol version 2 [RFC7181]
(OLSRv2) is a proactive link state routing protocol designed for use
in Mobile Ad Hoc Networks (MANETs) [RFC2501]. One of the significant
improvements of OLSRv2 over its Experimental precursor [RFC3626] is
the ability of OLSRv2 to use link metrics to select routes other than
minimum hop routes.
A limitation that remains in OLSRv2 is that it uses a single link
metric type for all routes. However, in some MANETs it would be
desirable to be able to route packets using more than one link metric
type. This specification describes an extension to OLSRv2 that is
designed to permit this, while maintaining maximal interoperability
with OLSRv2 routers not implementing this extension.
The purpose of OLSRv2 can be described as to create and maintain a
Routing Set, which contains all the necessary information to populate
an IP routing table. In a similar way, the role of this extension
can be described as to create and maintain multiple Routing Sets, one
for each link metric type supported by the router maintaining the
sets.
1.1. Motivation and Experimentation
Multi-topology routing is a natural extension to a link state routing
protocol, such as OSPF (see [RFC4915]). However multi-topology
routing for OLSRv2 does not yet benefit from extensive operational,
or even experimental, experience. This specification is published to
facilitate collecting such experience, with the intent that once
suitable experimental evidence has been collected, an OLSRv2 Multi-
Topology Routing Extension will be proposed for advancement onto the
Standards Track.
Any experiments using this protocol extension are encouraged.
Reports from such experiments planned with pre-specified objectives
and scenarios (including link, position, and mobility information)
are particularly encouraged. Results from such experiments,
documenting the following, are of particular importance:
o Operation in networks that contain both routers implementing this
extension and routers implementing only [RFC7181]. In particular,
are there any unexpected interactions that can break the network?
o Operation in networks with dynamic topologies, both due to
mobility and due to link metric changes for reasons other than
mobility.
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o Operation in realistic deployments, and details thereof, including
how many concurrent topologies were required.
o Behavior of Routing Sets, including measures of successful route
establishment.
In addition, reports from experiments covering the following are also
of value:
o Which link metric types were useful, and how the metrics to
associate with a given link were established.
o How packet types were associated with link metric types (whether
using Diffserv or an alternative mechanism).
o Any data link-layer issues, and any cross-layer issues, including
whether and how Neighborhood Discovery Protocol (NHDP) link
quality was used.
o Transport- and higher-layer issues observed, if any.
o Resource requirements observed from running the protocol,
including processing, storage, and bandwidth.
o Network performance, including packet delivery results.
o Any other implementation issues.
The first bullet in the list directly above applies to unextended
OLSRv2 [RFC7181] as well as with this extension, and potentially to
other MANET routing protocols. This specification also allows
experimentation with link metric types that are not compromises for
handling multiple traffic types.
2. Terminology and Notation
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in
[RFC2119].
This specification uses the terminology of [RFC5444], [RFC6130], and
[RFC7181], which is to be interpreted as described in those
specifications.
Additionally, this specification uses the following terminology:
Router - A MANET router that implements [RFC7181].
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MT-OLSRv2 - The protocol defined in this specification as an
extension to OLSRv2 [RFC7181].
This specification introduces the notation map[A -> B] to represent
an associative mapping. The domain of this mapping (A) is, in this
specification, always a set of link metric types that the router
supports: either IFACE_METRIC_TYPES or ROUTER_METRIC_TYPES, as
defined in Section 5. The codomain of this mapping (B) is a set of
all possible values of an appropriate type. In this specification,
this type is always one of:
o boolean (true or false),
o willingness (a 4-bit unsigned integer from 0 to 15),
o number of hops (an 8-bit unsigned integer from 0 to 255), or
o link metric (either a representable link metric value, as
described in [RFC7181], or UNKNOWN_METRIC).
3. Applicability Statement
The protocol described in this specification is applicable to a MANET
for which OLSRv2 is otherwise applicable (see [RFC7181], Section 3),
but in which multiple topologies are maintained, each characterized
by a different choice of link metric type. It is assumed, but
outside the scope of this specification, that the network layer is
able to choose which topology to use for each packet, for example,
using the Diffserv Code Point (DSCP) defined in [RFC2474]. This
selection of topology MUST be consistent; that is, each router
receiving a packet must make the same choice of link metric type, in
order that each packet uses a single topology. This is necessary to
avoid the possibility of a packet "looping" in the network.
4. Protocol Overview and Functioning
The purpose of this specification is to extend OLSRv2 [RFC7181] so as
to enable a router to establish and maintain multiple routing
topologies in a MANET, each topology associated with a link metric
type. Routers in the MANET may each form part of some or all of
these topologies, and each router will maintain a Routing Set for
each topology that it forms part of, allowing separate routing of
packets for each topology.
MT-OLSRv2 is designed to interoperate with OLSRv2; a MANET can be
created containing both routers that implement MT-OLSRv2 (MT-OLSRv2
routers) and routers that do not implement MT-OLSRv2 and may be
unaware of its existence (non-MT-OLSRv2 routers). MANETs may also be
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created that are known to contain only MT-OLSRv2 routers. In both
cases, but especially where a MANET contains both MT-OLSRv2 routers
and non-MT-OLSRv2 routers, management may be required to ensure that
the MANET will function as required, and will not, for example,
unnecessarily fragment. (Such issues already arise in an
OLSRv2-based MANET using multiple interfaces.)
OLSRv2 is an extension of NHDP [RFC6130]. However, the extension in
this specification does not modify NHDP, it only modifies Protocol
Sets that are specific to OLSRv2, or elements in Protocol Tuples that
were added by OLSRv2 and that are neither included in nor used by
NHDP. In addition it does not use or modify the link quality
mechanism in [RFC6130].
Each router implementing this specification selects a set of link
metric types for each of its OLSRv2 interfaces. If all routers in
the MANET implement MT-OLSRv2, then there are no restrictions within
this specification on how these sets of link metrics are selected.
(However, the issues described in the preceding paragraph still
apply.) On the other hand, in MANETs containing non-MT-OLSRv2
routers, the single link metric used by these non-MT-OLSRv2 routers
must be included in the set of link metrics for each OLSRv2 interface
of an MT-OLSRv2 router that may be heard on an OLSRv2 interface of a
non-MT-OLSRv2 router in the MANET.
Each router then determines an incoming link metric for each link
metric type selected for each of its OLSRv2 interfaces. These link
metrics are distributed using link metric TLVs contained in all HELLO
messages sent on OLSRv2 interfaces and in all TC messages. Unless
using only the single metric type used by non-MT-OLSRv2 routers, both
HELLO and TC messages generated by an MT-OLSRv2 router include an
MPR_TYPES Message TLV that indicates that this is an MT-OLSRv2 router
and which metric types it supports (on the sending OLSRv2 interface
for a HELLO message).
An MT-OLSRv2 router maintains, for each supported neighbour metric
type and for each symmetric 1-hop neighbor, the following:
o link and neighbour metric values,
o routing MPR status,
o routing MPR selector status, and
o advertised neighbour status.
Each router may choose a different willingness to be a routing MPR
for each link metric type that it supports.
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A network using MT-OLSRv2 will usually require greater management
than one using unmodified OLSRv2. In particular, the use of multiple
metric types across the MANET must be managed, by administrative
configuration or otherwise. As also for other decisions that may be
made when using OLSRv2, a bad collective choice of metric type use
will make the MANET anywhere from inefficient to nonfunctional, so
care will be needed in selecting supported link metric types across
the MANET.
The meanings of link metric types are at the discretion of the MANET
operator. They could be used, for example, to represent packets of
different types, packets in streams of different rates, or packets
with different trust requirements. Note that packets will generally
not be delivered to routers that do not support that link metric
type, and the MANET, and the packets sent in it, will need to be
managed accordingly (especially if the MANET contains any
non-MT-OLSRv2 routers).
5. Parameters
The parameters used in [RFC7181], and in its normative references,
are used in this specification with the following changes.
Each OLSRv2 interface will support a number of link metric types,
corresponding to Type Extensions of the LINK_METRIC TLV defined in
[RFC7181]. The router parameter LINK_METRIC_TYPE, used by routers
that do not implement MT-OLSRv2, and used with that definition in
this specification, is replaced in routers implementing MT-OLSRv2 by
an interface parameter array IFACE_METRIC_TYPES and a router
parameter array ROUTER_METRIC_TYPES. Each element in these arrays is
a link metric type (i.e., a type extension used by the LINK_METRIC
TLV [RFC7181]).
The interface parameter array IFACE_METRIC_TYPES contains the link
metric types supported on that OLSRv2 interface. The router
parameter array ROUTER_METRIC_TYPES is the union of all of the
IFACE_METRIC_TYPES. Both arrays MUST be without repetitions.
If in a given deployment there might be routers that do not implement
MT-OLSRv2, then IFACE_METRIC_TYPES MUST include LINK_METRIC_TYPE as
its first element, so that the OLSRv2 interface can communicate with
those routers. In that case, ROUTER_METRIC_TYPES MUST also include
LINK_METRIC_TYPE as its first element.
In addition, the router parameter WILL_ROUTING is extended to an
array of values, one each for each link metric type in the router
parameter list ROUTER_METRIC_TYPES.
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6. Information Bases
The Information Bases specified in [RFC7181], which extend those
specified in [RFC6130], are further extended in this specification.
With the exception of the Routing Set, the extensions in this
specification are the replacement of single values (boolean,
willingness, number of hops, or link metric) from [RFC7181] with
elements representing multiple values (associative mappings from a
set of metric types to their corresponding values). The following
subsections detail these extensions.
Note that, as in [RFC7181], an implementation is free to organize its
internal data in any manner it chooses; it needs only to behave as if
it were organized as described in [RFC7181] and this specification.
6.1. Local Attached Network Set
Each element AL_dist becomes a map[ROUTER_METRIC_TYPES -> number of
hops].
Each element AL_metric becomes a map[ROUTER_METRIC_TYPES -> link
metric].
6.2. Link Sets
Each element L_in_metric becomes a map[IFACE_METRIC_TYPES -> link
metric].
Each element L_out_metric becomes a map[IFACE_METRIC_TYPES -> link
metric].
The elements of L_in_metric MUST be set following the same rules that
apply to the setting of the single element L_in_metric in [RFC7181].
6.3. 2-Hop Sets
Each element N2_in_metric becomes a map[ROUTER_METRIC_TYPES -> link
metric].
Each element N2_out_metric becomes a map[ROUTER_METRIC_TYPES -> link
metric].
6.4. Neighbor Set
Each element N_in_metric becomes a map[ROUTER_METRIC_TYPES -> link
metric].
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Each element N_out_metric becomes a map[ROUTER_METRIC_TYPES -> link
metric].
Each element N_will_routing becomes a map[ROUTER_METRIC_TYPES ->
willingness].
Each element N_routing_mpr becomes a map[ROUTER_METRIC_TYPES ->
boolean].
Each element N_mpr_selector becomes a map[ROUTER_METRIC_TYPES ->
boolean].
Each element N_advertised becomes a map[ROUTER_METRIC_TYPES ->
boolean].
6.5. Router Topology Set
Each element TR_metric becomes a map[ROUTER_METRIC_TYPES -> link
metric].
Note that some values of TR_metric may now take the value
UNKNOWN_METRIC. When used to construct a Routing Set, where just the
corresponding link metric value from this mapping is used, Router
Topology Tuples whose corresponding value from TR_metric is
UNKNOWN_METRIC are ignored.
6.6. Routable Address Topology Set
Each element TA_metric becomes a map[ROUTER_METRIC_TYPES -> link
metric].
Note that some values of TA_metric may now take the value
UNKNOWN_METRIC. When used to construct a Routing Set, where just the
corresponding link metric value from this mapping is used, Routable
Address Topology Tuples whose corresponding value from TA_metric is
UNKNOWN_METRIC are ignored.
6.7. Attached Network Set
Each element AN_dist becomes a map[ROUTER_METRIC_TYPES -> number of
hops].
Each element AN_metric becomes a map[ROUTER_METRIC_TYPES -> link
metric].
Note that some values of AN_metric may now take the value
UNKNOWN_METRIC. When used to construct a Routing Set, where just the
corresponding link metric value from this mapping is used, Attached
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Network Tuples whose corresponding value from AN_metric is
UNKNOWN_METRIC are ignored.
6.8. Routing Sets
There is a separate Routing Set for each link metric type in
ROUTER_METRIC_TYPES.
7. TLVs
This specification makes the following additions and extensions to
the TLVs defined in [RFC7181].
7.1. Message TLVs
One new Message TLV is defined in this specification, and one
existing Message TLV is extended by this specification.
7.1.1. MPR_TYPES TLV
The MPR_TYPES TLV is used in both HELLO messages sent over OLSRv2
interfaces and TC messages. A message MUST NOT contain more than one
MPR_TYPES TLV.
The presence of this TLV in a message is used to indicate that the
router supports MT-OLSRv2, in the same way that the presence of the
MPR_WILLING TLV is used to indicate that the router supports OLSRv2,
as specified in [RFC7181]. For this reason, the MPR_TYPES TLV has
been defined with the same Type as the MPR_WILLING TLV, but with Type
Extension = 1.
This TLV may take a Value field of any size. Each octet in its Value
field will contain a link metric type that is supported, either on
any OLSRv2 interface, when included in a TC message, or on the OLSRv2
interface on which a HELLO message including this TLV is sent. These
octets MAY be in any order, but if there might be routers in the
MANET that do not implement MT-OLSRv2, then the first octet MUST be
LINK_METRIC_TYPE.
7.1.2. MPR_WILLING TLV
The MPR_WILLING TLV, which is used in HELLO messages, is specified in
[RFC7181], and extended in this specification as enabled by
[RFC7188].
The interpretation of this TLV, which is specified by [RFC7181] and
uses all of its single-octet Value field, is unchanged. That
interpretation uses bits 0-3 of its Value field to specify its
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willingness to be a flooding TLV, and bits 4-7 of its Value field to
be a routing TLV. Those latter bits are, when using this
specification, interpreted as its willingness to be a routing TLV
using the link metric type LINK_METRIC_TYPE.
The extended use of this message TLV, as defined by this
specification, defines additional 4-bit sub-fields of the Value
field, starting with bits 4-7 of the first octet and continuing with
bits 0-3 of the second octet, to represent willingness to be a
routing MPR using the link metric types specified in this OLSRv2
interface's IFACE_METRIC_TYPES parameter, ordered as reported in the
included MPR_TYPES Message TLV. Note that this means that, if there
might be any non-MT-OLSRv2 routers, then the link metric type
LINK_METRIC_TYPE will continue to occupy bits 4-7 of the first octet.
(If there is no such TLV included, then the router does not support
MT-OLSRv2, and only the first octet of the Value field will be used.)
If the number of link metric types in this OLSRv2 interface's
IFACE_METRIC_TYPES parameter is even, then there will be an unused
4-bit sub-field in bits 4-7 of the last octet of a full-sized Value
field. These bits will not be used; they SHOULD all be cleared ('0')
on transmission and MUST be ignored on receipt.
If the Value field in an MPR_WILLING TLV is shorter than its full
length, then, as specified in [RFC7188], missing Value octets, i.e.,
missing willingness values, are considered as zero (WILL_NEVER).
This is the correct behavior. (In particular, it means that an
OLSRv2 router that is not implementing MT-OLSRv2 will not act as a
routing MPR for any link metric that it does not recognize.)
7.2. Address Block TLVs
New Type Extensions are defined for the LINK_METRIC TLV defined in
[RFC7181], and the Value fields of the MPR TLV and the GATEWAY TLV,
both defined in [RFC7181], are extended, as enabled by [RFC7188].
7.2.1. LINK_METRIC TLV
The LINK_METRIC TLV is used in HELLO messages and TC messages. This
TLV is unchanged from the definition in [RFC7181].
Only a single Type Extension was specified by [RFC7181] -- 0 for
"Link metric meaning as assigned by administrative action". This
specification extends it to the range 0-7. This specification will
work with any combination of Type Extensions both within and outside
that range (assuming that the latter are defined as specified in
[RFC7181]).
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7.2.2. MPR TLV
The MPR TLV is used in HELLO messages and indicates that an address
with which it is associated is of a symmetric 1-hop neighbor that has
been selected as an MPR.
The Value field of this address block TLV is, in [RFC7181], defined
to be one octet long, with the values 1, 2, and 3 defined. [RFC7188]
redefines this Value field to be a bitfield where bit 7 (the least
significant bit) denotes flooding status, bit 6 denotes routing MPR
status, and bits 5-0 are unallocated (respecting the semantics of the
bits/values 1, 2, and 3 from [RFC7181]).
This specification, as enabled by [RFC7188], extends the MPR TLV to
have a variable-length Value field. Bits are allocated in increasing
significance within as many octets as are required. These bits
specify, in order, that:
o The neighbor with that network address has been selected as
flooding MPR (1 bit).
o The neighbor with that network address has been selected as
routing MPR for each link metric type (1 bit each), in the same
order as indicated in the Value field of an MPR_TYPES Message TLV.
For interoperability with a router not implementing MT-OLSRv2, the
two least significant bits of the first octet in the Value field of
this TLV is as the TLV Value of an MPR TLV generated according to
[RFC7181], as updated by [RFC7188].
7.2.3. GATEWAY TLV
The GATEWAY TLV is used in TC messages to indicate that a network
address is of an attached network.
The Value field of this address block TLV is defined by [RFC7181] to
be one octet long, containing the number of hops to that attached
network.
This specification, as enabled by [RFC7188], allows the extension of
the GATEWAY TLV to have a variable-length Value field when the number
of hops to each attached network is different for different link
metric types. For interoperability with a router not implementing
MT-OLSRv2, the first octet in the Value field of this TLV MUST be the
TLV Value of the GATEWAY TLV generated according to [RFC7181].
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Any subsequent octets in the TLV Value field indicate the number of
hops to the attached network for each other link metric type. Link
metric types (including the first) are ordered as indicated in the
Value field of an MPR_TYPES Message TLV.
+---------+---------------------------------------------------------+
| Type | Value |
+---------+---------------------------------------------------------+
| GATEWAY | Number of hops to attached network for each link metric |
| | type. |
+---------+---------------------------------------------------------+
Table 1: GATEWAY TLV Definition
8. HELLO Messages
The following changes are made to the generation and processing of
HELLO messages compared to the description in [RFC7181] for routers
that implement MT-OLSRv2.
8.1. HELLO Message Generation
A generated HELLO message to be sent on an OLSRv2 interface (whose
IFACE_METRIC_TYPES parameter will be that used) is extended by:
o Adding an MPR_TYPES Message TLV. The Value octets will be the
link metric types in IFACE_METRIC_TYPES. This TLV MAY be omitted
if the only link metric type included would be LINK_METRIC_TYPE.
o Extending the MPR_WILLING Message TLV Value field to report the
willingness values from the WILL_ROUTING parameter list that
correspond to the link metric types in IFACE_METRIC_LIST, in the
same order as reported in the MPR_TYPES TLV, each value (also
including one representing WILL_FLOODING) occupying 4 bits.
o Including LINK_METRIC Address Block TLVs that report all values in
L_in_metric, L_out_metric, N_in_metric, and N_out_metric elements
that are not equal to UNKNOWN_METRIC, with the TLV Type Extension
being the link metric type, and otherwise following the rules for
such inclusions specified in [RFC7181].
o Including MPR Address Block TLVs such that for each link metric
type in IFACE_METRIC_TYPES, and for the choice of flooding MPRs,
the indicated addresses MUST be of the MPRs in an MPR set as
specified for a single link metric type in [RFC7181].
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8.2. HELLO Message Processing
On receipt of a HELLO message on an OLSRv2 interface, a router
implementing MT-OLSRv2 MUST do the following, in addition to the
processing described in [RFC7181]:
1. If in this deployment there might be routers that do not
implement MT-OLSRv2, the HELLO message contains an MPR_TYPES
Message TLV, and the first link metric type that it reports is
not LINK_METRIC_TYPE, then the HELLO message MUST be silently
discarded.
2. Determine the list of link metric types supported by the sending
router on its corresponding OLSRv2 interface, either from an
MPR_TYPES Message TLV (if present) or from the single link metric
type LINK_METRIC_TYPE.
3. For all link metric types reported and supported by the receiving
router, set the appropriate L_out_metric, N_in_metric,
N_out_metric, N_will_routing, N_mpr_selector, N_advertised,
N2_in_metric, and N2_out_metric elements using the rules for
setting the single elements of those types specified in
[RFC7181].
4. For any other metric types supported by the receiving router only
(i.e. in IFACE_METRIC for the receiving OLSRv2 interface), set
the elements listed in the previous point to their default
values, i.e., UNKNOWN_METRIC, WILL_NEVER (not WILL_DEFAULT), or
false.
9. TC Messages
The following changes are made to the generation and processing of TC
messages compared to that described in [RFC7181] by routers that
implement MT-OLSRv2.
9.1. TC Message Generation
A generated TC message is extended by:
o Adding an MPR_TYPES TLV. The Value octets will be the link metric
types in ROUTER_METRIC_TYPES. This TLV MAY be omitted if the only
link metric type included would be LINK_METRIC_TYPE.
o Including LINK_METRIC TLVs that report all values of N_out_metric
that are not equal to UNKNOWN_METRIC, with the TLV Type Extension
being the link metric type, and otherwise following the rules for
such inclusions specified in [RFC7181].
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o Including a number of hops per reported (in an MPR_TYPES Message
TLV) link metric type in the Value field of each GATEWAY TLV
included, in the same order as reported in the MPR_TYPES TLV.
9.2. TC Message Processing
On receipt of a TC message, a router implementing this extension MUST
do the following, in addition to the processing specified in
[RFC7181]:
o If in this deployment there might be routers that do not implement
MT-OLSRv2, the TC message contains an MPR_TYPES Message TLV, and
the first link metric type that it reports is not
LINK_METRIC_TYPE, then the TC message MUST be silently discarded.
o For all link metric types reported and supported by the receiving
router, set the appropriate TR_metric, TA_metric, AN_dist, and
AN_metric elements using the rules for setting the single elements
of those types specified in [RFC7181].
o For any other metric types supported by the receiving router that
do not have an advertised outgoing neighbor metric of that type,
set the corresponding elements of TR_metric, TA_metric, and
AN_metric to UNKNOWN_METRIC. (The corresponding element of
AN_dist may be set to any value.)
10. MPR Calculation
Routing MPRs are calculated for each link metric type in
ROUTER_METRIC_TYPES. Links to symmetric 1-hop neighbors via OLSRv2
interfaces that do not support that link metric type are not
considered. The determined status (routing MPR or not routing MPR)
for each link metric type is recorded in the relevant element of
N_routing_mpr.
Each router may make its own decision as to whether or not to use a
link metric, or link metrics, for flooding MPR calculation. If using
link metric(s), each router decides which one(s) and how they are
used. These decisions MUST be made in a manner that ensures that
flooded messages will reach the same symmetric 2-hop neighbors as
would be the case for a router not supporting MT-OLSRv2.
Note that it is possible that a 2-Hop Tuple in the Information Base
for a given OLSRv2 interface does not support any of the link metric
types that are in the router's corresponding IFACE_METRIC_TYPES;
nevertheless, that 2-Hop Tuple MUST be considered when determining
flooding MPRs.
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11. Routing Set Calculation
A Routing Set is calculated for each link metric type in
ROUTER_METRIC_TYPES. The calculation may be as for [RFC7181], except
that where an element is now represented by a map, the value from the
map for the selected link metric type is used. Where this is a link
metric of value UNKNOWN_METRIC, that protocol Tuple is ignored for
the calculation.
12. Management Considerations
MT-OLSRv2 may require greater management than unextended OLSRv2. In
particular, a MANET using MT-OLSRv2 requires the following management
considerations:
o Deciding which link metric, and hence which Routing Set to use,
for received packets, hence how to use the Routing Sets to
configure the network layer (IP). All routers MUST make the same
decision for the same packet. An obvious approach is to map each
DSCP [RFC2474] to a single link metric. (This may be a many-to-
one mapping.)
o Selecting which link metrics to support on each OLSRv2 interface
and implementing that decision. (Different interfaces may have
different physical and data link-layer properties, and this may
inform the selection of link metrics to support, and their
values.) If the MANET might contain non-MT-OLSRv2 routers, which
are also subject to management, then the rules in this
specification for link metric assignment to OLSRv2 interfaces for
that case MUST be followed.
o Ensuring that the MANET is sufficiently connected, by ensuring
that, for example, sufficiently many routers implement each metric
type required. (This is easier in, for example, a denser network.)
Note that if there is any possibility that there are routers not
implementing MT-OLSRv2, then the MANET will be connected, to the
maximum extent possible, using the link metric type
LINK_METRIC_TYPE, but this will only serve to deliver packets that
use that link metric type.
o Non-MT-OLSRv2 routers SHOULD be managed so as not produce packets
that will be routed by a topology that they are not part of.
However, if that were to happen, then such packets will be routed
until either they reach their destination or they reach an
MT-OLSRv2 router. In the latter case, the packet then either will
be dropped (if that MT-OLSRv2 router is not part of that topology,
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RFC 7722 Multi-Topology OLSRv2 December 2015
or is not aware of the destination within that topology) or will
be routed by that topology to the destination. Such a packet will
not loop.
o If a packet is created for a destination that is not part of the
corresponding topology, then it may or may not be delivered (if
the originating router is a non-MT-OLSRv2 router) or will not be
sent (if the originating router is an MT-OLSRv2 router). Routers
SHOULD be managed so that topologies are as complete as possible
and that packets are not sent if they may not be delivered. In
particular, non-MT-OLSRv2 routers SHOULD only send packets that
will be routed using the topology using the link metric type
LINK_METRIC_TYPE.
13. IANA Considerations
This specification adds one new Message TLV, allocated as a new Type
Extension to an existing Message TLV, using a new name. It also
modifies the Value field of an existing Message TLV and that of an
existing Address Block TLV. Finally, this specification makes
additional allocations from the LINK_METRIC Address Block TLV Type
registry.
13.1. Expert Review: Evaluation Guidelines
For the registry where an Expert Review is required, the designated
expert SHOULD take the same general recommendations into
consideration as are specified by [RFC5444] and [RFC7631].
13.2. Message TLV Types
This specification modifies the Message TLV Type 7, replacing Table 4
of [RFC7631] by Table 2, changing the description of the Type
Extension MPR_WILLING, and adding the Type Extension TLV_TYPES. Each
of these TLVs MUST NOT be included more than once in a Message TLV
Block.
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RFC 7722 Multi-Topology OLSRv2 December 2015
+-----------+-------------+-------------------------+---------------+
| Type | Name | Description | Reference |
| Extension | | | |
+-----------+-------------+-------------------------+---------------+
| 0 | MPR_WILLING | First (most | [RFC7181] |
| | | significant) half-octet | [RFC7631] |
| | | of Value field | RFC 7722 |
| | | specifies the | |
| | | originating router's | |
| | | willingness to act as a | |
| | | flooding MPR; | |
| | | subsequent half-octets | |
| | | specify the originating | |
| | | router's willingness to | |
| | | act as a routing MPR, | |
| | | either for the link | |
| | | metric types reported | |
| | | in an MPR_TYPES TLV (in | |
| | | the same order), or (if | |
| | | no MPR_TYPES TLV is | |
| | | present) for the single | |
| | | administratively agreed | |
| | | link metric type | |
| 1 | MPR_TYPES | The link metric types | RFC 7722 |
| | | supported on this | |
| | | OLSRv2 interface of | |
| | | this router (one octet | |
| | | each). | |
| 2-223 | | Unassigned | |
| 224-255 | | Reserved for | [RFC7181] |
| | | Experimental Use | |
+-----------+-------------+-------------------------+---------------+
Table 2: Type 7 Message TLV Type Extensions
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13.3. Address Block TLV Types
Table 7 of [RFC7188] is replaced by Table 3.
+-------+-------+----------+----------------------------------------+
| Bit | Value | Name | Description |
+-------+-------+----------+----------------------------------------+
| First | First | Flooding | If set, then the neighbor with that |
| octet | octet | | network address has been selected as |
| bit 7 | 0x01 | | flooding MPR |
| From | From | Routing | If set, then the neighbor with that |
| first | first | | network address has been selected as |
| octet | octet | | routing MPR, either for the link |
| bit 6 | 0x02 | | metric types reported in an MPR_TYPES |
| | | | TLV (in the same order), or (if no |
| | | | MPR_TYPES TLV is present) then (first |
| | | | octet bit 6, value 0x02) for the |
| | | | single administratively agreed link |
| | | | metric type |
+-------+-------+----------+----------------------------------------+
Table 3: MPR TLV Bit Values
Table 14 of [RFC7631] is replaced by Table 4. The only changes are
to the Description and the References for the GATEWAY TLV.
+-----------+---------+-----------------------------+---------------+
| Type | Name | Description | References |
| Extension | | | |
+-----------+---------+-----------------------------+---------------+
| 0 | GATEWAY | Specifies that a given | [RFC7181] |
| | | network address is reached | RFC 7722 |
| | | via a gateway on the | |
| | | originating router. The | |
| | | number of hops is indicated | |
| | | by the Value field, one | |
| | | octet per link metric type | |
| | | reported in an MPR_TYPES | |
| | | Message TLV (in the same | |
| | | order) or (if no MPR_TYPES | |
| | | Message TLV is present) | |
| | | using a single octet | |
| 1-223 | | Unassigned | |
| 224-255 | | Reserved for Experimental | [RFC7631] |
| | | Use | |
+-----------+---------+-----------------------------+---------------+
Table 4: Type 10 Address Block TLV Type Extensions
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Table 13 of [RFC7181] is replaced by Table 5. The only change is
that 8 Type Extensions are allocated as assigned by administrative
action, in order to support administratively determined multi-
topologies.
+-------------+------+-----------+-------------------+--------------+
| Name | Type | Type | Description | Allocation |
| | | Extension | | Policy |
+-------------+------+-----------+-------------------+--------------+
| LINK_METRIC | 7 | 0-7 | Link metric | |
| | | | meaning assigned | |
| | | | by administrative | |
| | | | action. | |
| LINK_METRIC | 7 | 8-223 | Unassigned. | Expert |
| | | | | Review |
| LINK_METRIC | 7 | 224-255 | Unassigned. | Experimental |
| | | | | Use |
+-------------+------+-----------+-------------------+--------------+
Table 5: Address Block TLV Type assignment: LINK_METRIC
14. Security Considerations
This extension to OLSRv2 allows a router to support more than one
link metric type for each link advertised in HELLO and TC messages,
and for routers to support different sets of types. Link metric
values of additional types are reported by the inclusion of
additional TLVs in the messages sent by a router, which will report
known values of all supported types.
HELLO and TC message processing is then extended simply to record,
for each supported type, all of the received link metric values for
each link. Protocol-internal processing (specifically, MPR set and
shortest path calculations) then operates as specified in [RFC7181]
for each link metric type that the router supports.
Consequently, the security considerations, including the security
architecture and the mandatory security mechanisms, from [RFC7181]
are directly applicable to MT-OLSRv2.
Furthermore, this extension does not introduce any additional
vulnerabilities beyond those of [RFC7181], because each link metric
type is used independently, and each one could have been the single
link metric type supported by an implementation of [RFC7181]
receiving the same information, as received information of an
unsupported type is ignored by all routers.
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15. References
15.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<http://www.rfc-editor.org/info/rfc2119>.
[RFC5444] Clausen, T., Dearlove, C., Dean, J., and C. Adjih,
"Generalized Mobile Ad Hoc Network (MANET) Packet/Message
Format", RFC 5444, DOI 10.17487/RFC5444, February 2009,
<http://www.rfc-editor.org/info/rfc5444>.
[RFC6130] Clausen, T., Dearlove, C., and J. Dean, "Mobile Ad Hoc
Network (MANET) Neighborhood Discovery Protocol (NHDP)",
RFC 6130, DOI 10.17487/RFC6130, April 2011,
<http://www.rfc-editor.org/info/rfc6130>.
[RFC7181] Clausen, T., Dearlove, C., Jacquet, P., and U. Herberg,
"The Optimized Link State Routing Protocol Version 2",
RFC 7181, DOI 10.17487/RFC7181, April 2014,
<http://www.rfc-editor.org/info/rfc7181>.
[RFC7188] Dearlove, C. and T. Clausen, "Optimized Link State Routing
Protocol Version 2 (OLSRv2) and MANET Neighborhood
Discovery Protocol (NHDP) Extension TLVs", RFC 7188,
DOI 10.17487/RFC7188, April 2014,
<http://www.rfc-editor.org/info/rfc7188>.
[RFC7631] Dearlove, C. and T. Clausen, "TLV Naming in the Mobile Ad
Hoc Network (MANET) Generalized Packet/Message Format",
RFC 7631, DOI 10.17487/RFC7631, September 2015,
<http://www.rfc-editor.org/info/rfc7631>.
15.2. Informative References
[RFC2474] Nichols, K., Blake, S., Baker, F., and D. Black,
"Definition of the Differentiated Services Field (DS
Field) in the IPv4 and IPv6 Headers", RFC 2474,
DOI 10.17487/RFC2474, December 1998,
<http://www.rfc-editor.org/info/rfc2474>.
[RFC2501] Corson, S. and J. Macker, "Mobile Ad hoc Networking
(MANET): Routing Protocol Performance Issues and
Evaluation Considerations", RFC 2501,
DOI 10.17487/RFC2501, January 1999,
<http://www.rfc-editor.org/info/rfc2501>.
Dearlove & Clausen Experimental [Page 22]
RFC 7722 Multi-Topology OLSRv2 December 2015
[RFC3626] Clausen, T., Ed., and P. Jacquet, Ed., "Optimized Link
State Routing Protocol (OLSR)", RFC 3626,
DOI 10.17487/RFC3626, October 2003,
<http://www.rfc-editor.org/info/rfc3626>.
[RFC4915] Psenak, P., Mirtorabi, S., Roy, A., Nguyen, L., and P.
Pillay-Esnault, "Multi-Topology (MT) Routing in OSPF",
RFC 4915, DOI 10.17487/RFC4915, June 2007,
<http://www.rfc-editor.org/info/rfc4915>.
Acknowledgments
The authors would like to thank (in alphabetical order): Juliusz
Chroboczek (University of Paris Diderot), Alan Cullen (BAE Systems),
Susan Hares (Huawei), and Henning Rogge (FGAN) for discussions and
suggestions.
Authors' Addresses
Christopher Dearlove
BAE Systems Applied Intelligence Laboratories
West Hanningfield Road
Great Baddow, Chelmsford
United Kingdom
Phone: +44 1245 242194
Email: chris.dearlove@baesystems.com
URI: http://www.baesystems.com/
Thomas Heide Clausen
LIX, Ecole Polytechnique
Phone: +33 6 6058 9349
Email: T.Clausen@computer.org
URI: http://www.ThomasClausen.org/
Dearlove & Clausen Experimental [Page 23]