Internet Engineering Task Force M. Goyal, Ed.
Internet-Draft University of Wisconsin
Intended status: Experimental Milwaukee
Expires: November 6, 2012 E. Baccelli
M. Philipp
INRIA
A. Brandt
Sigma Designs
J. Martocci
Johnson Controls
May 5, 2012
Reactive Discovery of Point-to-Point Routes in Low Power and Lossy
Networks
draft-ietf-roll-p2p-rpl-10
Abstract
This document specifies a point-to-point route discovery mechanism,
complementary to the RPL core functionality. This mechanism allows
an IPv6 router to discover "on demand" routes to one or more IPv6
routers in the LLN such that the discovered routes meet specified
metrics constraints.
Status of this Memo
This Internet-Draft is submitted to IETF in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF). Note that other groups may also distribute
working documents as Internet-Drafts. The list of current Internet-
Drafts is at http://datatracker.ietf.org/drafts/current/.
Internet-Drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
material or to cite them other than as "work in progress."
This Internet-Draft will expire on November 6, 2012.
Copyright Notice
Copyright (c) 2012 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
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Provisions Relating to IETF Documents
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. The Use Cases . . . . . . . . . . . . . . . . . . . . . . . . 3
3. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
4. Applicability . . . . . . . . . . . . . . . . . . . . . . . . 5
5. Functional Overview . . . . . . . . . . . . . . . . . . . . . 6
6. P2P Route Discovery Mode Of Operation . . . . . . . . . . . . 9
6.1. Setting a P2P Mode DIO . . . . . . . . . . . . . . . . . . 9
7. New RPL Control Message Options . . . . . . . . . . . . . . . 11
7.1. P2P Route Discovery Option (P2P-RDO) . . . . . . . . . . . 12
7.2. Data Option . . . . . . . . . . . . . . . . . . . . . . . 15
8. The Discovery Reply Object (DRO) . . . . . . . . . . . . . . . 15
8.1. Secure DRO . . . . . . . . . . . . . . . . . . . . . . . . 17
8.2. Setting a P2P-RDO Carried in a Discovery Reply Object . . 18
9. P2P-RPL Route Discovery By Creating a Temporary DAG . . . . . 18
9.1. Joining a Temporary DAG . . . . . . . . . . . . . . . . . 18
9.2. Trickle Operation For P2P Mode DIOs . . . . . . . . . . . 19
9.3. Processing a P2P Mode DIO . . . . . . . . . . . . . . . . 20
9.4. Additional Processing of a P2P Mode DIO At An
Intermediate Router . . . . . . . . . . . . . . . . . . . 21
9.5. Additional Processing of a P2P Mode DIO At The Target . . 22
9.6. Processing a DRO At An Intermediate Router . . . . . . . . 24
9.7. Processing a DRO At The Origin . . . . . . . . . . . . . . 25
10. The Discovery Reply Object Acknowledgement (DRO-ACK) . . . . . 26
11. Packet Forwarding Along a Route Discovered Using P2P-RPL . . . 27
12. Interoperability with Core RPL . . . . . . . . . . . . . . . . 28
13. Security Considerations . . . . . . . . . . . . . . . . . . . 28
14. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 29
14.1. Additions to DIO Mode of Operation . . . . . . . . . . . . 29
14.2. Additions to RPL Control Message Options . . . . . . . . . 29
14.3. Additions to RPL Control Codes . . . . . . . . . . . . . . 30
14.4. New Registry for Upper Layer Headers inside Data Option . 30
15. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 30
16. References . . . . . . . . . . . . . . . . . . . . . . . . . . 31
16.1. Normative References . . . . . . . . . . . . . . . . . . . 31
16.2. Informative References . . . . . . . . . . . . . . . . . . 31
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 32
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1. Introduction
Targeting Low power and Lossy Networks (LLNs), the RPL routing
protocol [RFC6550] provides paths along a Directed Acyclic Graph
(DAG) rooted at a single router in the network. Establishment and
maintenance of a DAG is performed by routers in the LLN using DODAG
Information Object (DIO) messages. When two arbitrary routers
(neither of which is the DAG's root) need to communicate, the data
packets are restricted to travel only along the links in the DAG.
Such point-to-point (P2P) routing functionality may not be sufficient
for several Home and Building Automation applications [RFC5826]
[RFC5867] due to the following reasons:
o The need to pre-establish routes: each potential destination in
the network must declare itself as such ahead of the time a source
needs to reach it.
o The need to route only along the links in the DAG: A DAG is built
to optimize the routing cost to reach the root. Restricting P2P
routes to use only the in-DAG links may result in significantly
suboptimal routes and severe traffic congestion near the DAG root.
This document describes an extension to core RPL that enables an IPv6
router in the LLN to discover routes to one or more IPv6 routers in
the LLN "on demand", such that the discovered routes meet the
specified metrics constraints, without necessarily going along the
links in an existing DAG. This reactive P2P route discovery
mechanism is henceforth referred to as P2P-RPL. P2P-RPL does not
guarantee discovery of a route. Also, the discovered routes may not
be optimal. However, any discovered routes are guaranteed to satisfy
the desired constraints in terms of the routing metrics and are thus
considered "good enough" from the application's perspective.
A mechanism to measure the end-to-end cost of an existing route is
specified in [I-D.ietf-roll-p2p-measurement]. As discussed in
Section 4, measuring the end-to-end cost of an existing route may
help decide whether to initiate the discovery of a better route using
P2P-RPL and the metric constraints to be used for this purpose.
2. The Use Cases
One use case, common in home and commercial building environments,
involves a device (say a remote control or an airduct controller)
that suddenly needs to communicate with another device (say a lamp or
a humidity sensor) to which it does not already have a route. In
this case, the remote control (or the airduct controller) must be
able to discover a route to the lamp (or the humidity sensor) "on
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demand".
Another use case, common in a commercial building environment,
involves a large LLN deployment where P2P communication along a
particular DAG among hundreds (or thousands) of routers creates
severe traffic congestion near that DAG's root, and thus routes
across this DAG are desirable.
Other use cases involve scenarios where energy or latency constraints
are not satisfied by the P2P routes along an existing DAG because
they involve traversing many more intermediate routers than necessary
to reach the destination.
3. Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in
[RFC2119].
Additionally, this document uses terminology from [RFC6550]. This
document introduces the following terms:
Origin : The IPv6 router initiating the P2P-RPL route discovery.
Target : The IPv6 router at the other end point of the P2P route(s)
to be discovered. A P2P-RPL route discovery can discover routes to
multiple Targets at the same time.
Intermediate Router: An IPv6 router that is neither the Origin nor a
Target.
Forward direction: The direction from the Origin to the Target.
Backward direction: The direction from the Target to the Origin.
Forward Route: A route in the Forward direction.
Backward Route: A route in the Backward direction.
Bidirectional Route: A route that can be used in both Forward and
Backward directions.
Source Route: A complete and ordered list of routers that can be used
by a packet to travel from a source to a destination node.
Hop-by-hop Route: The route characterized by each router on the route
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using its routing table to determine the next hop on the route.
4. Applicability
A route discovery using P2P-RPL may be performed by an Origin when no
route exists between itself and the Target(s) or when the existing
routes do not satisfy the application requirements. P2P-RPL is
designed to discover Hop-by-hop or Source Routes to one or more
Targets such that the discovered routes meet the specified
constraints. In some application contexts, the constraints that the
discovered routes must satisfy are intrinsically known or can be
specified by the application. For example, an Origin that expects
its Targets to be less than 5 hops away may use "hop-count < 5" as
the constraint. In other application contexts, the Origin may need
to measure the cost of the existing route to a Target to determine
the constraints. For example, an Origin that measures the total ETX
along its current route to a Target to be 20 may use "ETX < x*20",
where x is a fraction that the Origin decides, as the constraint. A
mechanism to measure the cost of an existing route between two IPv6
routers is specified in [I-D.ietf-roll-p2p-measurement]. If there is
no existing route between the Origin and the Target(s) or the cost
measurement for the existing routes fails, the Origin will have to
guess the constraints to be used in the initial route discovery.
Once, the initial route discovery succeeds or fails, the Origin will
have a better estimate for the constraints to be used in the
subsequent route discovery.
P2P-RPL may result in discovery of better P2P routes than the ones
available along a global DAG designed to optimize routing cost to the
DAG's root. The improvement in route quality depends on a number of
factors including the network topology, the "distance" between the
Origin and the Target (in terms of the routing metrics in use) and
the prevalent conditions in the network. In general, a P2P-RPL route
may be better than the one along a global DAG if the Origin and the
Target are nearby. Similarly, a P2P-RPL route may not be much better
than the one along a global DAG if the Origin and the Target are far
apart. Note that, even when P2P-RPL routes are not much better than
those along a global DAG, P2P-RPL routes may still be able to avoid
congestion that might occur near the root if the routing takes place
only along a global DAG. In general, the costs associated with a
P2P-RPL route discovery (in terms of the control messages, mostly
DIOs, generated) increases with the distance between the Origin and
the Target. However, it is possible to limit the cost of route
discovery by carefully setting the routing constraints, the Trickle
parameters (that govern the DIO generation) and the lifetime of the
temporary DAG created for the route discovery. A network designer
may take into consideration both the benefits (potentially better
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routes; no need to maintain routes proactively; avoid congestion near
the global DAG's root) and costs when using P2P-RPL. The latency
associated with a P2P-RPL route discovery again depends on the
distance between the Origin and the Target and the Trickle
parameters.
Note that the participation in a P2P-RPL route discovery is limited
to the routers with IPv6 addresses that are reachable in both Forward
and Backward directions.
5. Functional Overview
This section contains a high level description of P2P-RPL.
A P2P-RPL route discovery takes place by forming a DAG rooted at the
Origin. As is the case with core RPL, P2P-RPL uses IPv6 link-local
multicast DIO messages to establish a DAG. However, unlike core RPL,
this DAG is temporary in nature and routers in the DAG leave once the
DAG's life time is over. The sole purpose of DAG creation is to
discover routes to the Target(s) and DIOs serve as the route
discovery messages. Each router joining the DAG determines a rank
for itself in the DAG and ignores the subsequent DIOs received from
lower (higher in numerical value) ranked neighbors. Thus, the route
discovery messages propagate away from the Origin rather than return
back to it. As in core RPL, DIO generation at a router is controlled
by a Trickle timer [RFC6206] that allows a router to avoid generating
unnecessary messages while providing protection against packet loss.
P2P-RPL also uses the routing metrics [RFC6551], objective functions
and packet forwarding framework [RFC6554][RFC6553] developed for core
RPL.
An Origin may use P2P-RPL to discover routes to one or more Targets
identified by one or more unicast/multicast addresses. P2P-RPL
allows for the discovery of one Hop-by-hop Route or up to four Source
Routes per Target. P2P-RPL allows an Origin to piggyback time-
critical application data on the DIO messages for delivery to the
Target(s). P2P-RPL does not guarantee discovery of a route to a
Target. Also, the discovered routes may not be the best available.
However, any discovered routes are guaranteed to satisfy the desired
constraints in terms of the routing metrics and are thus considered
"good enough" from the application's perspective.
A P2P-RPL route discovery takes place by forming a temporary DAG
rooted at the Origin. The DIOs, used to create the temporary DAG,
are identified by a new Mode of Operation (P2P Route Discovery mode
defined in Section 6). The DIOs, listing the P2P Route Discovery
mode as the Mode of Operation, are henceforth referred to as the P2P
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mode DIOs. A P2P mode DIO always carries one P2P Route Discovery
Option (defined in Section 7.1) in which the Origin specifies the
following information:
o The IPv6 address of a Target. This could be a unicast address or
a multicast one. Any additional Targets may be specified by
including one or more RPL Target Options [RFC6550] inside the DIO.
o The nature of the route(s) to be discovered: hop-by-hop or Source
Routes. This specification allows for the discovery of one Hop-
by-hop Route or up to four Source Routes per Target.
o The desired number of routes (if Source Routes are being
discovered).
o Whether the Target(s) should send Discovery Reply Object (DRO)
messages (defined in Section 8) back to the Origin on receiving a
DIO message. A DRO message carries a discovered Source Route back
to the Origin or establishes a Hop-by-hop Route between the Origin
and the Target. By not allowing the generation of DRO messages,
an Origin can use P2P-RPL as purely a mechanism to deliver time-
critical application data to the Target(s).
A P2P Route Discovery Option also accumulates a route from the Origin
to a Target as the routers join the temporary DAG.
A P2P mode DIO MAY also carry:
o One or more Metric Container Options to specify:
* The relevant routing metrics.
* The constraints that the discovered route must satisfy. These
constraints also limit how far the DIOs message may travel.
o One or more RPL Target options to specify additional unicast or
multicast Targets.
o One Data Option (defined in Section 7.2) to carry time-critical
application-level data to be delivered to the Target(s).
As the routers join the temporary DAG, they keep track of the best
(partial) route(s) they have seen and advertise these routes, along
with the corresponding routing metrics, in their P2P mode DIOs. A
router, including the Target(s), discards a received P2P mode DIO if
the aggregated routing metrics on the route advertised by the DIO do
not satisfy the listed constraints. These constraints can be used to
limit the propagation of P2P mode DIO messages. A router may also
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discard a received P2P mode DIO if it does not wish to be a part of
the discovered route due to limited resources or due to policy
reasons.
When a Target receives a P2P mode DIO, it forwards the data in the
Data Option, if present, to the higher layer. The Target may
remember the discovered route for use as a Source Route to reach the
Origin. If the Origin has requested DRO messages to be sent back,
the Target may select the route contained in the received DIO for
further processing as described next. This document does not specify
a particular method for the Target to use to select a route for
further processing. Example methods include selecting any route that
meets the constraints or selecting the best route(s) discovered over
a certain time period.
If one or more Source Routes are being discovered, the Target sends
the selected Source Routes to the Origin via DRO messages with one
DRO message carrying one discovered route. On receiving a DRO
message, the Origin stores the discovered route in its memory. If a
Hop-by-hop Route is being discovered, the Target sends a DRO message
containing the selected route to the Origin. The DRO message travels
back to the Origin along the selected route, establishing state for
this route in the routers on the path. The Target may include a Data
Option in a DRO message to deliver any time-critical application data
to the Origin.
The Target may request the Origin to acknowledge the receipt of a DRO
message by sending back a DRO Acknowledgement (DRO-ACK) message
(defined in Section 10). The Origin unicasts a DRO-ACK message to
the Target. If the Target does not receive the requested DRO-ACK
within a certain time interval of sending a DRO, it resends the DRO
message (up to a certain number of times) carrying the same route as
before.
The use of trickle timers to delay the propagation of DIO messages
may cause some nodes to generate these messages even when the desired
routes have already been discovered. In order to preempt the
generation of such unnecessary messages, the Target may set a "stop"
flag in the DRO message to let the nodes in the LLN know about the
completion of the route discovery process. The routers receiving
such a DRO should not generate any more DIOs for this temporary DAG.
Neither should they process any received DIOs for this temporary DAG
in future. However, such routers must still process the DROs
received for this temporary DAG.
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6. P2P Route Discovery Mode Of Operation
This section specifies a new RPL Mode of Operation (MOP), P2P Route
Discovery mode (or P2P mode, for short), with value 4 (to be
confirmed by IANA). A DIO message, listing P2P mode as the MOP, is
identified as performing a P2P-RPL route discovery by creating a
temporary DAG. A P2P mode DIO MUST carry one and only one P2P Route
Discovery Option (specified in Section 7.1).
6.1. Setting a P2P Mode DIO
The Base Object in a P2P mode DIO message MUST be set in the
following manner:
o RPLInstanceID: RPLInstanceID MUST be a local value as described in
Section 5.1 of [RFC6550]. The Origin MUST NOT use the same
RPLInstanceID in two or more concurrent route discoveries. When
initiating a new route discovery to a particular Target, the
Origin MUST NOT reuse the RPLInstanceID used in a previous route
discovery to this Target if the previously discovered routes might
still exist. The Default Lifetime and Lifetime Unit parameters in
the DODAG Configuration Option specify the lifetime of the state
the routers, including the Origin and the Target, maintain for a
hop-by-hop or a Source Route discovered using P2P-RPL. Thus, an
Origin can safely reuse an RPLInstanceID to discover a new route
to a Target if the lifetime of all previously discovered routes to
this Target using this RPLInstanceID is over.
o Version Number: MUST be set to zero. The temporary DAG used for
P2P-RPL route discovery does not exist long enough to have new
versions.
o Grounded (G) Flag: This flag MUST be set to one. Unlike a global
RPL instance, the concept of a floating DAG, used to provide
connectivity within a sub-DAG detached from a grounded DAG, does
not apply to a local RPL instance. Hence, an Origin MUST always
set the G flag to one when initiating a P2P-RPL route discovery.
Further, clause 3 of Section 8.2.2.2 in [RFC6550] does not apply
and a node MUST NOT initiate a new DAG if it does not have any
parent left in a P2P-RPL DAG.
o Mode of Operation (MOP): MUST be set to 4, corresponding to P2P
Route Discovery mode.
o DTSN: MUST be set to zero on transmission and ignored on
reception.
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o DODAGPreference (Prf): This field MUST be set to zero (least
preferred).
o DODAGID: This field MUST be set to an IPv6 address of the Origin.
o The other fields in the DIO Base Object can be set in the desired
fashion as per the rules described in [RFC6550].
The DODAG Configuration Option, inside a P2P mode DIO MUST be set in
the following manner:
o The Origin MUST set the MaxRankIncrease parameter to zero to
disable local repair of the temporary DAG.
o The Origin SHOULD set the Trickle parameters
(DIOIntervalDoublings, DIOIntervalMin, DIORedundancyConstant) as
recommended in Section 9.2.
o The Origin sets the Default Lifetime and Lifetime Unit parameters
to indicate the lifetime of the state the routers, including the
Origin and the Target(s), maintain for a hop-by-hop or a Source
Route discovered using P2P-RPL.
o The Origin sets the other fields in the DODAG Configuration
Option, including the OCP identifying the Objective function, in
the desired fashion as per the rules described in [RFC6550].
o An Intermediate Router (or a Target) MUST set various fields in
the DODAG Configuration Option in the outgoing P2P mode DIOs to
the values they had in the incoming P2P mode DIOs for this DAG.
A default DODAG Configuration Option comes in effect if a P2P mode
DIO does not carry an explicit one. The default DODAG Configuration
Option has the following parameter values:
o Authentication Enabled: 0
o DIOIntervalMin: 6, which translates to 64ms as the value for Imin
parameter in Trickle operation.
o DIORedundancyConstant: 1
o MaxRankIncrease: 0
o Default Lifetime: 0xFF
o Lifetime Unit: 0xFFFF
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o Objective Code Point: 0, i.e., OF0 [RFC6552] is the default
objective function.
o The remaining parameters have default values as specified in
[RFC6550].
The routing metrics and constraints [RFC6551] used in P2P-RPL route
discovery are included in one or more Metric Container Options
[RFC6550] inside the P2P mode DIO. Note that a DIO need not include
a Metric Container if OF0 is the objective function in effect. In
that case, a P2P mode DIO may still specify an upper limit on the
maximum rank, that a router may have in the temporary DAG, inside the
P2P Route Discovery Option (described in Section 7.1).
A P2P mode DIO:
o MUST carry one (and only one) P2P Route Discovery Option
(described in Section 7.1). The P2P Route Discovery Option allows
for the specification of one unicast or multicast address for the
Target.
o MAY carry one or more RPL Target Options to specify additional
unicast/multicast addresses for the Target.
o MAY carry one or more Metric Container Options to specify routing
metrics and constraints.
o MAY carry one Data Option (described in Section 7.2) containing
time-critical application data to be delivered to the Target(s).
o MAY carry one or more Route Information or Prefix Information
Options (described in [RFC6550]).
A router MUST discard a received P2P mode DIO if it violates any of
the rules listed above.
7. New RPL Control Message Options
This document defines two new RPL control message options: the P2P
Route Discovery Option and the Data Option.
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7.1. P2P Route Discovery Option (P2P-RDO)
-
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 = 10 | Option Length |R|H| N | Compr | L |MaxRank/NH |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
| Target |
| |
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
| Address[1..n] |
| |
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 1: Format of P2P Route Discovery Option (P2P-RDO)
The format of a P2P Route Discovery Option (P2P-RDO) is illustrated
in Figure 1. A P2P mode DIO and a DRO (defined in Section 8) message
MUST carry one and at most one P2P-RDO. A P2P-RDO consists of the
following fields:
o Option Type: 0x0A (to be confirmed by IANA).
o Option Length: 8-bit unsigned integer, representing the length in
octets of the option, not including the Option Type and Option
Length fields.
o Reply (R): The Origin sets this flag to one to allow the Target(s)
to send DRO messages back to the Origin. If this flag is zero, a
Target MUST NOT generate any DRO message.
o Hop-by-hop (H): This flag is valid only if the R flag is set to
one. The Origin sets this flag to one if it desires Hop-by-hop
Routes. The Origin sets this flag to zero if it desires Source
Routes. This specification allows for the establishment of one
hop-by-hop route or up to four Source Routes per Target. The Hop-
by-hop Route is established in the Forward direction, i.e. from
the Origin to the Target. This specification does not allow for
the establishment of Hop-by-hop Routes in the Backward direction.
o Number of Routes (N): This flag is valid only if the R flag is one
and H flag is zero, i.e. the Targets are allowed to generate DRO
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messages carrying discovered Source Routes back to the Origin. In
this case, the value in the N field plus one indicates the number
of Source Routes that each Target should convey to the Origin.
When Hop-by-hop Routes are being discovered, the N field MUST be
set to zero on transmission and ignored on reception.
o Compr: 4-bit unsigned integer indicating the number of prefix
octets that are elided from the Target field and the Address
vector. For example, Compr value will be zero if full IPv6
addresses are carried in the Target field and the Address vector.
o Life Time (L): A 2-bit field that indicates the minimum life time
of the temporary DAG, i.e., the minimum duration a router joining
the temporary DAG MUST maintain its membership in the DAG. The
mapping between the values in this field and the life time of the
temporary DAG is as follows:
* 0x00: 1 second;
* 0x01: 4 seconds;
* 0x02: 16 seconds;
* 0x03: 64 seconds;
The Origin sets this field based on its expectation regarding the
time required for the route discovery to complete, which includes
the time required for the DIOs to reach the Target(s) and the DROs
to travel back to the Origin. While deciding the temporary DAG's
lifetime, the Origin should also take in account the fact that all
nodes joining the temporary DAG would need to stay in the DAG for
at least this much time.
o MaxRank/NH:
* When a P2P-RDO is included in a P2P mode DIO, this field
indicates the upper limit on the integer portion of the rank
(calculated using the DAGRank() macro defined in [RFC6550])
that a router may have in the temporary DAG being created. An
Intermediate Router MUST NOT join a temporary DAG being created
by a P2P mode DIO if the integer portion of its rank would be
equal to or higher (in numerical value) than the MaxRank limit.
A Target can join the temporary DAG at a rank whose integer
portion is equal to the MaxRank. A router MUST discard a
received P2P mode DIO if the integer part of the advertized
rank equals or exceeds the MaxRank limit. A value 0 in this
field indicates that the MaxRank is infinity.
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* When a P2P-RDO is included in a DRO message, this field
indicates the index of the next hop address inside the Address
vector.
o Target: An IPv6 address of the Target after eliding Compr number
of prefix octets. When the P2P-RDO is included in a P2P mode DIO,
this field may contain a unicast address or a multicast one. Any
additional Target addresses can be specified by including one or
more RPL Target Options [RFC6550] in the DIO. When the P2P-RDO is
included in a DRO, this field MUST contain a unicast IPv6 address
of the Target generating the DRO.
o Address[1..n]: A vector of IPv6 addresses representing a (partial)
route in the Forward direction:
* Each element in the Address vector has size (16 - Compr) octets
and MUST contain a valid IPv6 address with first Compr octets
elided.
* The total number of elements inside the Address vector is given
by n = (Option Length - 2 - (16 - Compr))/(16 - Compr).
* The IPv6 addresses in the Address vector MUST be reachable in
both Forward and Backward directions. Reachability in the
Backward direction allows a DRO message to use the route
accumulated in the Address vector to travel from the Target to
the Origin.
* The Address vector MUST carry the accumulated route in the
Forward direction, i.e., the first element in the Address
vector must contain the IPv6 address of the router next to the
Origin and so on.
* The Origin and Target addresses MUST NOT be included in the
Address vector.
* A router adding its address to the vector MUST ensure that its
address does not already exist in the vector. A router
specifying a complete route in the Address vector MUST ensure
that the vector does not contain any address more than once.
* The Address vector MUST NOT contain any multicast addresses.
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7.2. Data Option
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 = 11 | Option Length | SeqNo | Upper | Data |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+...
Figure 2: Format of Data Option
The format of a Data Option is illustrated in Figure 2. A P2P mode
DIO and a DRO (defined in Section 8) message MAY carry one or more
Data Options. A P2P-RDO consists of the following fields:
o Option Type: 0x0B (to be confirmed by IANA).
o Option Length: An 8-bit unsigned integer, representing the length
in octets of the option, not including the Option Type and Option
Length fields.
o SeqNo: A 4-bit field representing the sequence number of the data
carried by the Data Option.
o Upper: A 4-bit field that identifies the upper layer protocol
header with which the information in the Data field starts. A
value 0x00 in this field identifies UDP as the upper layer
protocol. The other values are reserved at present.
o Data: If the Data Option is contained in a DIO, this field
contains application data to be delivered to the Target(s). If
the Data Option is contained in a DRO, this field contains
application data to be delivered to the Origin.
8. The Discovery Reply Object (DRO)
This section defines two new RPL Control Message types, the Discovery
Reply Object (DRO), with code 0x04 (to be confirmed by IANA), and the
Secure DRO, with code 0x84 (to be confirmed by IANA). A DRO serves
one of the following functions:
o Carry a discovered Source Route from a Target to the Origin;
o Establish a Hop-by-hop Route as it travels from a Target to the
Origin.
A DRO message MAY serve the function of letting the routers in the
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LLN know that a P2P-RPL route discovery is complete and no more DIO
messages need to be generated for the corresponding temporary DAG. A
DRO message MAY also carry time-critical application data from the
Target to the Origin in a Data Option. A DRO message MUST carry one
P2P-RDO whose Target field MUST contain a unicast IPv6 address of the
Target that generated the DRO. A DRO message travels from the Target
to the Origin via link-local multicast along the route specified
inside the Address vector in the P2P-RDO.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| RPLInstanceID | Version |S|A|Seq| Reserved |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
| DODAGID |
| |
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Option(s)...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+...
Figure 3: Format of the base Discovery Reply Object (DRO)
The format of the base Discovery Reply Object (DRO) is shown in
Figure 3. A base DRO consists of the following fields:
o RPLInstanceID: The RPLInstanceID of the temporary DAG used for
route discovery.
o Version: The Version of the temporary DAG used for route
discovery. Since a temporary DAG always has value zero for the
Version, this field MUST always be set to zero.
o Stop (S): This flag, when set to one by a Target, indicates that
the P2P-RPL route discovery is over. All the routers receiving
such a DRO, including the ones not listed in the route carried
inside P2P-RDO,
* SHOULD NOT process any more DIOs received for this temporary
DAG;
* SHOULD NOT generate any more DIOs for this temporary DAG;
* SHOULD cancel any pending DIO transmission for this temporary
DAG.
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Note that the stop flag serves to stop further DIO generation/
processing for a P2P-RPL route discovery but it does not affect
the processing of DRO messages at either the Origin or the
Intermediate Routers. In other words, a router (the Origin or an
Intermediate Router) MUST continue to process the DRO messages
even if an earlier DRO message (with the same RPLInstanceID and
DODAGID fields) had the stop flag set to one.
o Ack Required (A): This flag, when set to one by the Target,
indicates that the Origin MUST unicast a DRO-ACK message (defined
in Section 10) to the Target when it receives the DRO.
o Sequence Number (Seq): This 2-bit field indicates the sequence
number for the DRO. This field is relevant when the A flag is set
to one, i.e., the Target requests an acknowledgement from the
Origin for a received DRO. The Origin includes the RPLInstanceID,
the DODAGID and the Sequence Number of the received DRO inside the
DRO-ACK message it sends back to the Target.
o Reserved: These bits are reserved for future use. These bits MUST
be set to zero on transmission and MUST be ignored on reception.
o DODAGID: The DODAGID of the temporary DAG used for route
discovery. The DODAGID also identifies the Origin. The
RPLInstanceID, the Version and the DODAGID together uniquely
identify the temporary DAG used for route discovery and can be
copied from the DIO message advertizing the temporary DAG.
o Options: The DRO message:
* MUST carry one P2P-RDO that MUST specify a complete route
between the Target and the Origin;
* MAY carry one or more Metric Container Options that contains
the aggregated routing metrics values for the route specified
in P2P-RDO;
* MAY carry one Data Option to carry any time-critical
application data to the Origin.
8.1. Secure DRO
A Secure DRO message follows the format in Figure 7 of [RFC6550],
where the base format is the base DRO shown in Figure 3.
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8.2. Setting a P2P-RDO Carried in a Discovery Reply Object
A Discovery Reply Object MUST carry one P2P-RDO, which MUST be set as
defined in Section 7.1. Specifically, the following fields MUST be
set as specified next:
o Reply (R): This flag MUST be set to zero on transmission and
ignored on reception.
o Hop-by-Hop (H): The H flag in the P2P-RDO included in a DRO
message MUST have the same value as the H flag in the P2P-RDO
inside the corresponding DIO message.
o Number of Routes (N): This field MUST be set to zero on
transmission and ignored on reception.
o Life Time (L): This field MUST be set to zero on transmission and
ignored on reception.
o MaxRank/NH: This field indicates the index of the next hop address
in the Address vector. When a Target generates a DRO message, the
NH field is set to n = (Option Length - 2 - (16 - Compr))/(16 -
Compr).
o Target: This field MUST contain a unicast IPv6 address of the
Target generating the DRO.
o Address[1..n]: The Address vector MUST contain a complete route
between the Origin and the Target such that the first element in
the vector contains the IPv6 address of the router next to the
Origin and the last element contains the IPv6 address of the
router next to the Target.
9. P2P-RPL Route Discovery By Creating a Temporary DAG
This section details the P2P-RPL route discovery operation.
9.1. Joining a Temporary DAG
All the routers participating in a P2P-RPL route discovery, including
the Origin and the Target(s), MUST join the temporary DAG being
created for the purpose. When a router joins a temporary DAG
advertized by a P2P mode DIO, it SHOULD maintain its membership in
the temporary DAG for the suggested Life Time duration listed in the
P2P-RDO. The only purpose of a temporary DAG's existence is to
facilitate the P2P-RPL route discovery process. The temporary DAG
MUST NOT be used to route packets. A router SHOULD detach from the
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temporary DAG once the duration of its membership in the DAG has
exceeded the DAG's life time. After receiving a DRO with the stop
flag set to one, a router SHOULD NOT send or receive any more DIOs
for this temporary DAG and SHOULD also cancel any pending DIO
transmission.
9.2. Trickle Operation For P2P Mode DIOs
An RPL router uses a Trickle timer [RFC6206] to control DIO
transmissions. The Trickle control of DIO transmissions provides
quick resolution of any "inconsistency" while avoiding redundant DIO
transmissions. The Trickle algorithm also imparts protection against
loss of DIOs due to inherent lack of reliability in LLNs. When
controlling the transmissions of a P2P mode DIO, a Trickle timer
SHOULD follow the following rules:
o The receipt of a P2P mode DIO, that allows the router to advertise
a better route (in terms of the routing metrics and the OF in use)
than before, is considered "inconsistent" and hence resets the
Trickle timer. Note that the first receipt of a P2P mode DIO
advertising a particular temporary DAG is always considered an
"inconsistent" event.
o The receipt of a P2P mode DIO from a parent in the temporary DAG
is considered neither "consistent" nor "inconsistent" if it does
not allow the router to advertise a better route than before.
Thus, the receipt of such DIOs has no impact on the Trickle
operation. Note that this document does not impose any
requirements on how a router might choose its parents in the
temporary DAG.
o The receipt of a P2P mode DIO is considered "consistent" if the
source of the DIO is not a parent in the temporary DAG and either
of the following conditions is true:
* The DIO advertises a better route than the router but does not
allow the router to advertise a better route itself; or
* The DIO advertises a route as good as the route (to be)
advertised by the router.
Note that Trickle algorithm's DIO suppression rules are in effect
at all times. Hence, a P2P-RPL router may suppress a DIO
transmission even if it has not made any DIO transmission yet.
o The receipt of a P2P mode DIO, that advertises a worse route than
what the router advertises (or would advertise when it gets a
chance to generate its DIO), is considered neither "consistent"
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nor "inconsistent", i.e., the receipt of such a DIO has no impact
on the Trickle operation.
o The Imin parameter SHOULD be set taking in account the
connectivity within the network. For highly connected networks, a
small Imin value (of the order of the typical transmission delay
for a DIO) may lead to congestion in the network as a large number
of routers reset their Trickle timers in response to the first
receipt of a DIO from the Origin. These routers would generate
their DIOs within Imin interval and cause additional routers to
reset their trickle timers and generate more DIOs. Thus, for
highly connected networks, the Imin parameter SHOULD be set to a
value at least one order of magnitude larger than the typical
transmission delay for a DIO. For sparsely connected networks,
the Imin parameter can be set to a value that is a small multiple
of the typical transmission delay for a DIO. Note that the Imin
value has a direct impact on the time required for a P2P-RPL route
discovery to complete. In general, the time required for a P2P-
RPL route discovery would increase approximately linearly with the
value of the Imin parameter.
o The Imax parameter SHOULD be set to a large value (several orders
of magnitude higher than the Imin value) and is unlikely to be
critical for P2P-RPL operation. This is because the first receipt
of a P2P mode DIO for a particular temporary DAG is considered an
inconsistent event and would lead to resetting of Trickle timer
duration to the Imin value. Given the temporary nature of the
DAGs used in P2P-RPL, Trickle timer may not get a chance to
increase much.
o The recommended value of redundancy constant "k" is 1. With this
value of "k", a DIO transmission will be suppressed if the router
receives even a single "consistent" DIO during a timer interval.
This setting for the redundancy constant is designed to reduce the
number of messages generated during a route discovery process and
is suitable for environments with low or moderate packet loss
rates. In environments with high packet loss rates, a higher
value for the redundancy constant may be more suitable.
9.3. Processing a P2P Mode DIO
The rules for DIO processing and transmission, described in Section 8
of RPL [RFC6550], apply to P2P mode DIOs as well except as modified
in this document.
The following rules for processing a received P2P mode DIO apply to
both Intermediate Routers and the Target.
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A router SHOULD discard a received P2P mode DIO with no further
processing if it does not have bidirectional reachability with the
neighbor that generated the received DIO. Note that bidirectional
reachability does not mean that the link must have the same values
for a routing metric in both directions. A router SHOULD calculate
the values of the link-level routing metrics included in the received
DIO taking in account the metric's value in both forward and Backward
directions. Bidirectional reachability along a discovered route
allows the Target to use this route to reach the Origin. In
particular, the DRO messages travel from the Target to the Origin
along a discovered route.
A router MUST discard a received P2P mode DIO with no further
processing:
o If the DIO advertises INFINITE_RANK as defined in [RFC6550].
o If the integer part of the rank advertised in the DIO equals or
exceeds the MaxRank limit listed in the P2P Route Discovery
Option.
o If the router cannot evaluate the mandatory route constraints
listed in the DIO or if the routing metric values do not satisfy
one or more of the mandatory constraints.
o If the router previously received a DRO message with the same
RPLInstanceID and DODAGID as the received DIO and with the stop
flag set to one.
The router MUST check the Target addresses listed in the P2P-RDO and
any RPL Target Options included in the received DIO. If one of its
IPv6 addresses is listed as a Target address or if it belongs to the
multicast group specified as one of the Target addresses, the router
considers itself a Target and processes the received DIO as specified
in Section 9.5. Otherwise, the router considers itself an
Intermediate Router and processes the received DIO as specified in
Section 9.4.
9.4. Additional Processing of a P2P Mode DIO At An Intermediate Router
An Intermediate Router MUST discard a received P2P mode DIO with no
further processing if the router cannot elide Compr (as specified in
the P2P-RDO) prefix octets from its IPv6 address.
On receiving a P2P mode DIO, an Intermediate Router MUST do the
following:
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o The router updates the Data Option to be carried in the router's
DIOs if the one in the received DIO has a higher sequence number
than what the router currently has (or if the router currently is
not aware of any Data Option).
o The router determines whether this DIO advertises a better route
than the router itself and whether the receipt of the DIO would
allow the router to advertise a better route than before.
Accordingly, the router SHOULD consider this DIO as consistent/
inconsistent from Trickle perspective as described in Section 9.2.
Note that the route comparison in a P2P-RPL route discovery is
performed using the parent selection rules of the OF in use as
specified in Section 14 of RPL [RFC6550]. If the received DIO
would allow the router to advertise a better route, the router
MUST remember the route advertised (inside the P2P-RDO) in the DIO
(after adding its own IPv6 address to the route) for inclusion in
its future DIOs. When an Intermediate Router adds itself to a
route, it MUST ensure that the IPv6 address added to the route is
reachable in both Forward and Backward directions. To improve the
diversity of the routes being discovered, an Intermediate Router
SHOULD keep track of multiple partial routes to be advertised in
the P2P-RDO inside its DIO. When the router generates its DIO, it
SHOULD randomly select the partial route to be included in the
P2P-RDO. Note that the route accumulation in a P2P mode DIO MUST
take place even if the Origin does not want any DRO messages to be
generated (i.e., the R flag inside the P2P-RDO is set to zero).
This is because the Target may still be able to use the
accumulated route as a source route to reach the Origin.
9.5. Additional Processing of a P2P Mode DIO At The Target
The Target MUST determine if the received DIO contains a Data Option
and deliver the data to the specified upper layer protocol if the
option's sequence number is higher than that of the options in the
previously received DIOs for this route discovery (or if the DIOs
received earlier did not have a Data Option). If this route
discovery involves multiple Targets, the Target MUST remember the
Data Option with highest sequence number for inclusion in its own
DIOs.
The Target MAY store the route contained in the P2P-RDO in the
received DIO for use as a Source Route to reach the Origin. The
lifetime of this Source Route is specified by the Default Lifetime
and Lifetime Unit parameters inside the DODAG Configuration Option
currently in effect. This lifetime can be extended (or shortened)
appropriately following a hint from an upper-layer protocol.
If the Reply flag inside the P2P-RDO in the received DIO is zero, the
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Target MUST discard the received DIO with no further processing.
Otherwise, the Target MAY select the route contained in the P2P-RDO
to send a DRO message back to the Origin. If the H flag inside the
P2P-RDO is one, the Target needs to select one route and send a DRO
message along this route back to the Origin. If the H flag is zero,
the number of routes to be selected (and the number of DRO messages
to be sent back) is given by one plus the value of the N field in the
P2P-RDO. This document does not prescribe a particular method for
the Target to select the routes. Example methods include selecting
each route that meets the specified routing constraints until the
desired number have been selected or selecting the best routes
discovered over a certain time period. If multiple routes are to be
selected, the Target SHOULD avoid selecting routes that have large
segments in common.
If the Target selects the route contained in the P2P-RDO in the
received DIO, it sends a DRO message back to the Origin (identified
by the DODAGID field in the DIO). The DRO message MUST include a
P2P-RDO that contains the selected route inside the Address vector.
Various fields inside the P2P-RDO MUST be set as specified in
Section 8.2. The Target MAY set the A flag inside the DRO message to
one if it desires the Origin to send back a DRO-ACK message on
receiving the DRO. In this case, the Target waits for
DRO_ACK_WAIT_TIME duration for the DRO-ACK message to arrive.
Failure to receive the DRO-ACK message within this time duration
causes the Target to retransmit the DRO message. The Target MAY
retransmit the DRO message in this fashion up to
MAX_DRO_RETRANSMISSIONS times. Both DRO_ACK_WAIT_TIME and
MAX_DRO_RETRANSMISSIONS are configurable parameters to be decided
based on the characteristics of individual deployments. Note that
all DRO transmissions and retransmissions MUST take place while the
Target is still a part of the temporary DAG created for the route
discovery. A Target MUST NOT transmit a DRO if it no longer belongs
to this DAG.
The Target MAY set the stop flag inside the DRO message to one if
o this router is the only Target specified in the corresponding DIO,
i.e., the corresponding DIO specified a unicast address of the
router as the Target inside the P2P-RDO with no additional Targets
specified via RPL Target Options; and
o the Target has already selected the desired number of routes.
The Target MAY include a Metric Container Option in the DRO message.
This Metric Container contains the end-to-end routing metric values
for the route specified in the P2P-RDO. The Target MAY include one
Data Option in the DRO message to carry time-critical application
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data for the Origin. Note that this Data Option is not same as the
Data Option that the Target may include in the DIOs it generates for
this route discovery (if the route discovery involves multiple
Targets). The Target MUST transmit the DRO message via a link-local
multicast.
A Target MUST NOT forward a P2P mode DIO any further if no other
Targets are to be discovered, i.e., if a unicast IPv6 address (of
this Target) is specified as the Target inside the P2P-RDO and no
additional Targets are specified via RPL Target Options inside the
DIOs for this route discovery. Otherwise, the Target MUST generate
DIOs for this route discovery as an Intermediate Router would.
9.6. Processing a DRO At An Intermediate Router
If the DODAGID field in the received DRO does not list a router's own
IPv6 address, the router considers itself an Intermediate Router and
MUST process the received message in the following manner:
o The router MUST discard the received DRO with no further
processing if it does not belong to the temporary DAG identified
by the RPLInstanceID and the DODAGID fields in the DRO.
o If the stop flag inside the received DRO is set to one, the router
SHOULD NOT send or receive any more DIOs for this temporary DAG
and SHOULD cancel any pending DIO transmission.
o The router MUST ignore any Metric Container and Data Options
contained in the DRO message.
o If Address[NH] element inside the P2P-RDO lists the router's own
unicast IPv6 address, the router is a part of the route carried in
the P2P-RDO. In this case, the router MUST do the following:
* To prevent loops, the router MUST discard the DRO message with
no further processing if the Address vector in the P2P-RDO
includes multiple IPv6 addresses assigned to the router's
interfaces and if such addresses do not appear back to back
inside the Address vector.
* If the H flag inside the P2P-RDO is one, the router MUST store
the state for the forward hop-by-hop route carried inside the
P2P-RDO. This state consists of:
+ The RPLInstanceID and the DODAGID fields of the DRO.
+ The route's destination, the Target (identified by Target
field inside P2P-RDO).
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+ The IPv6 address of the next hop, Address[NH+1] (unless NH
value equals the number of elements in the Address vector,
in which case the Target itself is the next hop).
This hop-by-hop routing state MUST expire at the end of the
lifetime specified by the Default Lifetime and Lifetime Unit
parameters inside the DODAG Configuration Option used in P2P
mode DIOs for this route discovery.
* If the router already maintains a hop-by-hop state listing the
Target as the destination and carrying same RPLInstanceID and
DODAGID fields as the received DRO and the next hop information
in the state does not match the next hop indicated in the
received DRO, the router MUST discard the DRO message with no
further processing.
* The router MUST decrement the NH field inside the P2P-RDO and
send the DRO further via link-local multicast.
9.7. Processing a DRO At The Origin
When a router receives a DRO message that lists its IPv6 address in
the DODAGID field, the router recognizes itself as the Origin for the
corresponding P2P-RPL route discovery and processes the message in
the following manner:
o The Origin MUST discard the received DRO with no further
processing if it no longer belongs to the temporary DAG identified
by the RPLInstanceID and the DODAGID fields in the DRO.
o The Origin MUST check if the received DRO contains a Data Option
with higher sequence number than what was received previously (or
if this Data Option is the first one received). In that case, the
Origin MUST deliver the data inside the Data Option to the upper
layer protocol identified inside the Data Option.
o If the stop flag inside the received DRO is set to one, the Origin
SHOULD NOT generate any more DIOs for this temporary DAG and
SHOULD cancel any pending DIO transmission.
o If the P2P-RDO inside the DRO identifies the discovered route as a
Source Route (H=0), the Origin MUST store in its memory the
discovered route contained in the Address vector. The lifetime of
this Source Route is specified by the Default Lifetime and
Lifetime Unit parameters inside the DODAG Configuration Option in
the P2P mode DIOs used for this route discovery. This lifetime
could be extended (or shortened) appropriately following a hint
from an upper-layer protocol.
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o If the P2P-RDO inside the DRO identifies the discovered route as a
Hop-by-hop Route (H=1), the Origin MUST store in its memory the
state for the discovered route in the manner described in
Section 9.6. This hop-by-hop routing state MUST expire at the end
of the lifetime specified by the Default Lifetime and Lifetime
Unit parameters inside the DODAG Configuration Option used in P2P
mode DIOs for this route discovery. A future version of this
document may consider specifying a signaling mechanism that will
allow the Origin to extend (or shorten) the lifetime of a P2P-RPL
Hop-by-hop Route following a suitable hint from an upper-layer
protocol.
o If the received DRO message contains one or more Metric Container
Options, the Origin MAY store the values of the routing metrics
associated with the discovered route in its memory. This
information may be useful in formulating the constraints for any
future P2P-RPL route discovery to the Target.
o If the A flag is set to one in the received DRO message, the
Origin MUST generate a DRO-ACK message as described in Section 10
and unicast the message to the Target (identified by the Target
field inside the P2P-RDO). The Origin MAY use the route just
discovered to send the DRO-ACK message to the Target. Section 11
describes how a packet may be forwarded along a source/Hop-by-hop
Route discovered using P2P-RPL.
10. The Discovery Reply Object Acknowledgement (DRO-ACK)
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| RPLInstanceID | Version |Seq| Reserved |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
| DODAGID |
| |
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 4: Format of the base Discovery Reply Object Acknowledgement
(DRO-ACK)
A DRO message may fail to reach the Origin due to a number of
reasons. Unlike the DIO messages that benefit from Trickle-
controlled retransmissions, the DRO messages are prone to loss due to
unreliable packet transmission in LLNs. Since a DRO message travels
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via link-local multicast, it cannot use link-level acknowledgements
to improve the reliability of its transmission. Also, an
Intermediate Router may drop the DRO message (e.g., because of its
inability to store the state for the Hop-by-hop Route the DRO is
establishing). To protect against the potential failure of a DRO
message to reach the Origin, the Target MAY request the Origin to
send back a DRO Acknowledgement (DRO-ACK) message on receiving a DRO
message. Failure to receive such an acknowledgement within the
DRO_ACK_WAIT_TIME interval of sending the DRO message forces the
Target to resend the message.
This section defines two new RPL Control Message types: DRO
Acknowledgement (DRO-ACK; with code 0x05; to be confirmed by IANA)
and Secure DRO-ACK (with code 0x85; to be confirmed by IANA). A DRO-
ACK message MUST travel as a unicast message from the Origin to the
Target. The format of a base DRO-ACK message is shown in Figure 4.
Various fields in a DRO-ACK message MUST have the same values as the
corresponding fields in the DRO message. The field marked as
"Reserved" MUST be set to zero on transmission and MUST be ignored on
reception. A Secure DRO-ACK message follows the format in Figure 7
of [RFC6550], where the base format is same as the base DRO-ACK shown
in Figure 4.
11. Packet Forwarding Along a Route Discovered Using P2P-RPL
An Origin MAY use a Source Routing Header (SRH) [RFC6554] to send a
packet along a Source Route discovered using P2P-RPL.
Travel along a Hop-by-hop Route, established using P2P-RPL, requires
specifying the RPLInstanceID and the DODAGID (of the temporary DAG
used for the route discovery) to identify the route. This is because
a P2P-RPL route discovery does not use globally unique RPLInstanceID
values and hence both the RPLInstanceID (a local value assigned by
the Origin) and the DODAGID (an IPv6 address of the Origin) are
required to uniquely identify a P2P-RPL Hop-by-hop Route to a
particular destination.
An Origin MAY include an RPL option [RFC6553] inside the IPv6 hop-by-
hop options header of a packet to send it along a Hop-by-hop Route
established using P2P-RPL. For this purpose, the Origin MUST set the
DODAGID of the temporary DAG used for the route discovery as the
source IPv6 address of the packet. Further, the Origin MUST specify
inside the RPL option the RPLInstanceID of the temporary DAG used for
the route discovery and set the O flag inside the RPL option to one.
On receiving this packet, an Intermediate Router checks the O flag
and correctly infer the source IPv6 address of the packet as the
DODAGID of the Hop-by-hop Route. The router then uses the DODAGID,
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the RPLInstanceID and the destination address to identify the routing
state to be used to forward the packet further.
12. Interoperability with Core RPL
This section describes how RPL routers that implement P2P-RPL
interact with RPL routers that do not. In general, P2P-RPL operation
does not affect core RPL operation and vice versa. However, core RPL
does allow a router to join a DAG as a leaf node even if it does not
understand the Mode of Operation (MOP) used in the DAG. Thus, an RPL
router that does not implement P2P-RPL may conceivably join a
temporary DAG being created for a P2P-RPL route discovery as a leaf
node and maintain its membership even though the DAG no longer
exists. This may impose a drain on the router's memory. However,
such RPL-only leaf nodes do not interfere with P2P-RPL route
discovery since a leaf node may only generate a DIO advertising an
INFINITE_RANK and all routers implementing P2P-RPL are required to
discard such DIOs. Note that core RPL does not require a router to
join a DAG whose MOP it does not understand. Moreover, RPL routers
in a particular deployment may have strict restrictions on the DAGs
they may join, thereby mitigating the problem.
The P2P-RPL mechanism described in this document works best when all
the RPL routers in the LLN implement P2P-RPL. In general, the
ability to discover routes as well as the quality of discovered
routes would deteriorate with the fraction of RPL routers that
implement P2P-RPL.
13. Security Considerations
A P2P-RPL deployment may be susceptible to denial of service attacks
by rogue routers that initiate fake route discoveries. A rogue
router could join a temporary DAG and advertise false information in
its DIOs in order to include itself in the discovered route(s). It
could generate bogus DRO messages carrying bad routes or maliciously
modify genuine DRO messages it receives.
In general, the security considerations for the operation of P2P-RPL
are similar to the ones for the operation of RPL (as described in
Section 19 of [RFC6550]). Section 10 of RPL specification [RFC6550]
describes a variety of security mechanisms that provide data
confidentiality, authentication, replay protection and delay
protection services. Each RPL control message has a secure version
that allows the specification of the level of security and the
algorithms used to secure the message. The mechanism defined in this
document is based on the use of DIOs to form a temporary DAG and
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discover P2P routes. These DIOs can be used in their secure versions
if desired. New RPL control messages defined in this document (DRO
and DRO-ACK) have secure versions as well. In addition, a P2P-RPL
deployment may use the security features provided by the link layer
in use. Thus, a particular P2P-RPL deployment can analyze its
security requirements and use the appropriate set of RPL (or link
layer) security mechanisms that meet those requirements.
Since a DRO message travels along a Source Route specified inside the
message, some of the security concerns that led to the deprecation of
Type 0 routing header [RFC5095] may apply. To avoid the possibility
of a DRO message traveling in a routing loop, this document requires
each Intermediate Router to confirm that the Source Route listed
inside the message does not contain any routing loop involving itself
before the router could forward the message further. As specified in
Section 9.6, this check involves the router making sure that its IPv6
addresses do not appear multiple times inside the Source Route with
one or more other IPv6 addresses in between.
14. IANA Considerations
14.1. Additions to DIO Mode of Operation
IANA is requested to allocate a new value in the "DIO Mode of
Operation" registry for the "P2P Route Discovery Mode" described in
this document.
+----------+-----------------------------------------+--------------+
| MOP | Description | Reference |
| Value | | |
+----------+-----------------------------------------+--------------+
| 4 | Reactive P2P route discovery mode of | This |
| | operation | document |
+----------+-----------------------------------------+--------------+
DIO Mode of Operation
14.2. Additions to RPL Control Message Options
IANA is requested to allocate new values in the "RPL Control Message
Options" registry for the "P2P Route Discovery Option" and the "Data
Option" described in this document.
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+-------+---------------------+---------------+
| Value | Meaning | Reference |
+-------+---------------------+---------------+
| 10 | P2P Route Discovery | This document |
| 11 | Data | This document |
+-------+---------------------+---------------+
RPL Control Message Options
14.3. Additions to RPL Control Codes
IANA is requested to allocate new code points in the "RPL Control
Codes" registry for the "Discovery Reply Object" and "Discovery Reply
Object Acknowledgement" (and their secure versions) described in this
document.
+------+--------------------------------------------+---------------+
| Code | Description | Reference |
+------+--------------------------------------------+---------------+
| 0x04 | Discovery Reply Object | This document |
| 0x05 | Discovery Reply Object Acknowledgement | This document |
| 0x84 | Secure Discovery Reply Object | This document |
| 0x85 | Secure Discovery Reply Object | This document |
| | Acknowledgement | |
+------+--------------------------------------------+---------------+
RPL Control Codes
14.4. New Registry for Upper Layer Headers inside Data Option
This document creates a new IANA registry for the Upper Layer Header
type inside the RPL Data Option, with the following initial content:
+-------+-------------+---------------+
| Value | Description | Reference |
+-------+-------------+---------------+
| 0x00 | UDP Header | This document |
+-------+-------------+---------------+
Upper Layer Header Types inside RPL Data Option
15. Acknowledgements
Authors gratefully acknowledge the contributions of the following
individuals (in alphabetical order) in the development of this
document: Dominique Barthel, Jakob Buron, Thomas Clausen, Richard
Kelsey, Phil Levis, Zach Shelby, Pascal Thubert, Hristo Valev and JP
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Vasseur.
16. References
16.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC6206] Levis, P., Clausen, T., Hui, J., Gnawali, O., and J. Ko,
"The Trickle Algorithm", RFC 6206, March 2011.
[RFC6550] Winter, T., Thubert, P., Brandt, A., Hui, J., Kelsey, R.,
Levis, P., Pister, K., Struik, R., Vasseur, JP., and R.
Alexander, "RPL: IPv6 Routing Protocol for Low-Power and
Lossy Networks", RFC 6550, March 2012.
[RFC6551] Vasseur, JP., Kim, M., Pister, K., Dejean, N., and D.
Barthel, "Routing Metrics Used for Path Calculation in
Low-Power and Lossy Networks", RFC 6551, March 2012.
16.2. Informative References
[I-D.ietf-roll-p2p-measurement]
Goyal, M., Baccelli, E., Brandt, A., and J. Martocci, "A
Mechanism to Measure the Quality of a Point-to-point Route
in a Low Power and Lossy Network",
draft-ietf-roll-p2p-measurement-04 (work in progress),
March 2012.
[RFC5095] Abley, J., Savola, P., and G. Neville-Neil, "Deprecation
of Type 0 Routing Headers in IPv6", RFC 5095,
December 2007.
[RFC5826] Brandt, A., Buron, J., and G. Porcu, "Home Automation
Routing Requirements in Low-Power and Lossy Networks",
RFC 5826, April 2010.
[RFC5867] Martocci, J., De Mil, P., Riou, N., and W. Vermeylen,
"Building Automation Routing Requirements in Low-Power and
Lossy Networks", RFC 5867, June 2010.
[RFC6552] Thubert, P., "Objective Function Zero for the Routing
Protocol for Low-Power and Lossy Networks (RPL)",
RFC 6552, March 2012.
[RFC6553] Hui, J. and JP. Vasseur, "The Routing Protocol for Low-
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Power and Lossy Networks (RPL) Option for Carrying RPL
Information in Data-Plane Datagrams", RFC 6553,
March 2012.
[RFC6554] Hui, J., Vasseur, JP., Culler, D., and V. Manral, "An IPv6
Routing Header for Source Routes with the Routing Protocol
for Low-Power and Lossy Networks (RPL)", RFC 6554,
March 2012.
Authors' Addresses
Mukul Goyal (editor)
University of Wisconsin Milwaukee
3200 N Cramer St
Milwaukee, WI 53201
USA
Phone: +1 414 2295001
Email: mukul@uwm.edu
Emmanuel Baccelli
INRIA
Phone: +33-169-335-511
Email: Emmanuel.Baccelli@inria.fr
URI: http://www.emmanuelbaccelli.org/
Matthias Philipp
INRIA
Phone: +33-169-335-511
Email: Matthias.Philipp@inria.fr
Anders Brandt
Sigma Designs
Emdrupvej 26A, 1.
Copenhagen, Dk-2100
Denmark
Phone: +45-29609501
Email: abr@sdesigns.dk
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Jerald Martocci
Johnson Controls
507 E Michigan St
Milwaukee, WI 53202
USA
Phone: +1 414-524-4010
Email: jerald.p.martocci@jci.com
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