Rfc | 5015 |
Title | Bidirectional Protocol Independent Multicast (BIDIR-PIM) |
Author | M.
Handley, I. Kouvelas, T. Speakman, L. Vicisano |
Date | October 2007 |
Format: | TXT, HTML |
Updated by | RFC8736, RFC9436 |
Status: | PROPOSED
STANDARD |
|
Network Working Group M. Handley
Request for Comments: 5015 UCL
Category: Standards Track I. Kouvelas
T. Speakman
Cisco
L. Vicisano
Digital Fountain
October 2007
Bidirectional Protocol Independent Multicast (BIDIR-PIM)
Status of This Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Abstract
This document discusses Bidirectional PIM (BIDIR-PIM), a variant of
PIM Sparse-Mode that builds bidirectional shared trees connecting
multicast sources and receivers. Bidirectional trees are built using
a fail-safe Designated Forwarder (DF) election mechanism operating on
each link of a multicast topology. With the assistance of the DF,
multicast data is natively forwarded from sources to the Rendezvous-
Point (RP) and hence along the shared tree to receivers without
requiring source-specific state. The DF election takes place at RP
discovery time and provides the route to the RP, thus eliminating the
requirement for data-driven protocol events.
Table of Contents
1. Introduction ....................................................3
2. Terminology .....................................................4
2.1. Definitions ................................................4
2.2. Pseudocode Notation ........................................6
3. Protocol Specification ..........................................6
3.1. BIDIR-PIM Protocol State ...................................7
3.1.1. General Purpose State ...............................8
3.1.2. RPA State ...........................................8
3.1.3. Group State .........................................9
3.1.4. State Summarization Macros .........................10
3.2. PIM Neighbor Discovery ....................................11
3.3. Data Packet Forwarding Rules ..............................11
3.3.1. Upstream Forwarding at RP ..........................12
3.3.2. Source-Only Branches ...............................12
3.3.3. Directly Connected Sources .........................13
3.4. PIM Join/Prune Messages ...................................13
3.4.1. Receiving (*,G) Join/Prune Messages ................13
3.4.2. Sending Join/Prune Messages ........................16
3.5. Designated Forwarder (DF) Election ........................18
3.5.1. DF Requirements ....................................18
3.5.2. DF Election Description ............................19
3.5.2.1. Bootstrap Election ........................20
3.5.2.2. Loser Metric Changes ......................20
3.5.2.3. Winner Metric Changes .....................21
3.5.2.4. Winner Loses Path .........................22
3.5.2.5. Late Router Starting Up ...................22
3.5.2.6. Winner Dies ...............................22
3.5.3. Election Protocol Specification ....................22
3.5.3.1. Election State ............................22
3.5.3.2. Election Messages .........................23
3.5.3.3. Election Events ...........................24
3.5.3.4. Election Actions ..........................25
3.5.3.5. Election State Transitions ................26
3.5.4. Election Reliability Enhancements ..................30
3.5.5. Missing Pass .......................................30
3.5.6. Periodic Winner Announcement .......................30
3.6. Timers, Counters, and Constants ...........................31
3.7. BIDIR-PIM Packet Formats ..................................34
3.7.1. DF Election Packet Formats .........................34
3.7.2. Backoff Message ....................................36
3.7.3. Pass Message .......................................36
3.7.4. Bidirectional Capable PIM-Hello Option .............37
4. RP Discovery ...................................................37
5. Security Considerations ........................................38
5.1. Attacks Based on Forged Messages ..........................38
5.1.1. Election of an Incorrect DF ........................38
5.1.2. Preventing Election Convergence ....................39
5.2. Non-Cryptographic Authentication Mechanisms ...............39
5.2.1. Basic Access Control ...............................39
5.3. Authentication Using IPsec ................................40
5.4. Denial-of-Service Attacks .................................40
6. IANA Considerations ............................................40
7. Acknowledgments ................................................40
8. Normative References ...........................................40
9. Informative References .........................................41
List of Figures
Figure 1. Downstream group per-interface state machine ............15
Figure 2. Upstream group state machine ............................17
Figure 3. Designated Forwarder election state machine .............27
1. Introduction
This document specifies Bidirectional PIM (BIDIR-PIM), a variant of
PIM Sparse-Mode (PIM-SM) [4] that builds bidirectional shared trees
connecting multicast sources and receivers.
PIM-SM constructs unidirectional shared trees that are used to
forward data from senders to receivers of a multicast group. PIM-SM
also allows the construction of source-specific trees, but this
capability is not related to the protocol described in this document.
The shared tree for each multicast group is rooted at a multicast
router called the Rendezvous Point (RP). Different multicast groups
can use separate RPs within a PIM domain.
In unidirectional PIM-SM, there are two possible methods for
distributing data packets on the shared tree. These differ in the
way packets are forwarded from a source to the RP:
o Initially, when a source starts transmitting, its first hop router
encapsulates data packets in special control messages (Registers)
that are unicast to the RP. After reaching the RP, the packets are
decapsulated and distributed on the shared tree.
o A transition from the above distribution mode can be made at a
later stage. This is achieved by building source-specific state on
all routers along the path between the source and the RP. This
state is then used to natively forward packets from that source.
Both of these mechanisms suffer from problems. Encapsulation results
in significant processing, bandwidth, and delay overheads.
Forwarding using source-specific state has additional protocol and
memory requirements.
Bidirectional PIM dispenses with both encapsulation and source state
by allowing packets to be natively forwarded from a source to the RP
using shared tree state. In contrast to PIM-SM, this mode of
forwarding does not require any data-driven events.
The protocol specification in this document assumes familiarity with
the PIM-SM specification in [4]. Portions of the BIDIR-PIM protocol
operation that are identical to that of PIM-SM are only defined by
reference.
2. Terminology
In this document, the key words "MUST", "MUST NOT", "REQUIRED",
"SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY",
and "OPTIONAL" are to be interpreted as described in RFC 2119 [1] and
indicate requirement levels for compliant BIDIR-PIM implementations.
2.1. Definitions
This specification uses a number of terms to refer to the roles of
routers participating in BIDIR-PIM. The following terms have special
significance for BIDIR-PIM:
Multicast Routing Information Base (MRIB)
The multicast topology table, which is typically derived from the
unicast routing table, or routing protocols such as Multiprotocol
BGP (MBGP) [8] that carry multicast-specific topology information.
It is used by PIM for establishing the RPF interface (used in the
forwarding rules). In PIM-SM, the MRIB is also used to make
decisions regarding where to forward Join/Prune messages, whereas
in BIDIR-PIM, it is used as a source for routing metrics for the
DF election process.
Rendezvous Point Address (RPA)
An RPA is an address that is used as the root of the distribution
tree for a range of multicast groups. The RPA must be routable
from all routers in the PIM domain. The RPA does not need to
correspond to an address for an interface of a real router. In
this respect, BIDIR-PIM differs from PIM-SM, which requires an
actual router to be configured as the Rendezvous Point (RP). Join
messages from receivers for a BIDIR-PIM group propagate hop-by-hop
towards the RPA.
Rendezvous Point Link (RPL)
An RPL for a particular RPA is the physical link to which the RPA
belongs. In BIDIR-PIM, all multicast traffic to groups mapping to
a specific RPA is forwarded on the RPL of that RPA. The RPL is
special within a BIDIR-PIM domain as it is the only link on which
a Designated Forwarder election does not take place (see DF
definition below).
Upstream
Towards the root (RPA) of the tree. The direction used by packets
traveling from sources to the RPL.
Downstream
Away from the root of the tree. The direction on which packets
travel from the RPL to receivers.
Designated Forwarder (DF)
The protocol presented in this document is largely based on the
concept of a Designated Forwarder (DF). A single DF exists for
each RPA on every link within a BIDIR-PIM domain (this includes
both multi-access and point-to-point links). The only exception
is the RPL on which no DF exists. The DF is the router on the
link with the best route to the RPA (determined by comparing MRIB
provided metrics). A DF for a given RPA is in charge of
forwarding downstream traffic onto its link, and forwarding
upstream traffic from its link towards the RPL. It does this for
all the bidirectional groups that map to the RPA. The DF on a
link is also responsible for processing Join messages from
downstream routers on the link as well as ensuring that packets
are forwarded to local receivers (discovered through a local
membership mechanism such as MLD [3] or IGMP [2]).
RPF Interface
RPF stands for "Reverse Path Forwarding". The RPF Interface of a
router with respect to an address is the interface that the MRIB
indicates should be used to reach that address. In the case of a
BIDIR-PIM multicast group, the RPF interface is determined by
looking up the RPA in the MRIB. The RPF information determines
the interface of the router that would be used to send packets
towards the RPL for the group.
RPF Neighbor
The RPF Neighbor of a router with respect to an address is the
neighbor that the MRIB indicates should be used to reach that
address. Note that in BIDIR-PIM, the RPF neighbor for a group is
not necessarily the router on the RPF interface that Join messages
for that group would be directed to (Join messages are only
directed to the DF on the RPF interface for the group).
Tree Information Base (TIB)
This is the collection of state at a PIM router that has been
created by receiving PIM Join/Prune messages, PIM DF election
messages, and IGMP or MLD information from local hosts. It
essentially stores the state of all multicast distribution trees
at that router.
Multicast Forwarding Information Base (MFIB)
The TIB holds all the state that is necessary to forward multicast
packets at a router. However, although this specification defines
forwarding in terms of the TIB, to actually forward packets using
the TIB is very inefficient. Instead, a real router
implementation will normally build an efficient MFIB from the TIB
state to perform forwarding. How this is done is implementation-
specific, and is not discussed in this document.
2.2. Pseudocode Notation
We use set notation in several places in this specification.
A (+) B
is the union of two sets, A and B.
A (-) B is the elements of set A that are not in set B.
NULL
is the empty set or list.
In addition, we use C-like syntax:
= denotes assignment of a variable.
== denotes a comparison for equality.
!= denotes a comparison for inequality.
Braces { and } are used for grouping.
3. Protocol Specification
The specification of BIDIR-PIM is broken into several parts:
o Section 3.1 details the protocol state stored.
o Section 3.2 defines the BIDIR-PIM extensions to the PIM-SM [4]
neighbor discovery mechanism.
o Section 3.3 specifies the data packet forwarding rules.
o Section 3.4 specifies the BIDIR-PIM Join/Prune generation and
processing rules.
o Section 3.5 specifies the Designated Forwarder (DF) election.
o Section 3.7 specifies the PIM packet formats.
o Section 3.6 summarizes BIDIR-PIM timers and gives their default
values.
3.1. BIDIR-PIM Protocol State
This section specifies all the protocol state that a BIDIR-PIM
implementation should maintain in order to function correctly. We
term this state the Tree Information Base or TIB, as it holds the
state of all the multicast distribution trees at this router. In
this specification, we define PIM mechanisms in terms of the TIB.
However, only a very simple implementation would actually implement
packet forwarding operations in terms of this state. Most
implementations will use this state to build a multicast forwarding
table, which would then be updated when the relevant state in the TIB
changes.
Although we specify precisely the state to be kept, this does not
mean that an implementation of BIDIR-PIM needs to hold the state in
this form. This is actually an abstract state definition, which is
needed in order to specify the router's behavior. A BIDIR-PIM
implementation is free to hold whatever internal state it requires,
and will still be conformant with this specification so long as it
results in the same externally visible protocol behavior as an
abstract router that holds the following state.
We divide TIB state into two sections:
RPA state
State that maintains the DF election information for each RPA.
Group state
State that maintains a group-specific tree for groups that map to
a given RPA.
The state that should be kept is described below. Of course,
implementations will only maintain state when it is relevant to
forwarding operations - for example, the "NoInfo" state might be
assumed from the lack of other state information, rather than being
held explicitly.
3.1.1. General Purpose State
A router holds the following state that is not specific to an RPA or
group:
Neighbor State:
For each neighbor:
o Neighbor's Gen ID
o Neighbor liveness timer (NLT)
o Other information from neighbor's Hello
For more information on Hello information, look at Section 3.2 as
well as the PIM-SM specification in [4].
3.1.2. RPA State
A router maintains a multicast-group to RPA mapping, which is built
through static configuration or by using an automatic RP discovery
mechanism like BSR or AUTO-RP (see Section 4). For each BIDIR-PIM
RPA, a router holds the following state:
o RPA (actual address)
Designated Forwarder (DF) State:
For each router interface:
Acting DF information:
o DF IP Address
o DF metric
Election information:
o Election State
o DF election-Timer (DFT)
o Message-Count (MC)
Current best offer:
o IP address of best offering router
o Best offering router metric
Designated Forwarder state is described in Section 3.5.
3.1.3. Group State
For every group G, a router keeps the following state:
Group state:
For each interface:
Local Membership:
o State: One of {"NoInfo", "Include"}
PIM Join/Prune State:
o State: One of {"NoInfo" (NI), "Join" (J),
"PrunePending" (PP)}
o PrunePendingTimer (PPT)
o Join/Prune Expiry Timer (ET)
Not interface specific:
o Upstream Join/Prune Timer (JT)
o Last RPA Used
Local membership is the result of the local membership mechanism
(such as IGMP [2]) running on that interface. This information is
used by the pim_include(*,G) macro described in Section 3.1.4.
PIM Join/Prune state is the result of receiving PIM (*,G) Join/Prune
messages on this interface, and is specified in Section 3.4.1. The
state is used by the macros that calculate the outgoing interface
list in Section 3.1.4, and in the JoinDesired(G) macro (defined in
Section 3.4.2) that is used in deciding whether a Join(*,G) should be
sent upstream.
The upstream Join/Prune timer is used to send out periodic Join(*,G)
messages, and to override Prune(*,G) messages from peers on an
upstream LAN interface.
The last RPA used must be stored because if the group to RPA mapping
changes (see RP Set changes in [4]), then state must be torn down and
rebuilt for groups whose RPA changes.
3.1.4. State Summarization Macros
Using this state, we define the following "macro" definitions that we
will use in the descriptions of the state machines and pseudocode in
the following sections.
olist(G) =
RPF_interface(RPA(G)) (+) joins(G) (+) pim_include(G)
RPF_interface(RPA) is the interface the MRIB indicates would be used
to route packets to RPA. The olist(G) is the list of interfaces on
which packets to group G must be forwarded.
The macro pim_include(G) indicates the interfaces to which traffic
might be forwarded because of hosts that are local members on that
interface.
pim_include(G) =
{ all interfaces I such that:
I_am_DF(RPA(G),I) AND local_receiver_include(G,I) }
The clause "I_am_DF(RPA,I)" is TRUE if the router is in the Win or
Backoff states in the DF election state machine (described in Section
3.5) for the given RPA on interface I. Otherwise, it is FALSE.
The clause "local_receiver_include(G,I)" is true if the IGMP module,
MLD module, or other local membership mechanism has determined that
there are local members on interface I that desire to receive traffic
sent to group G.
The set "joins(G)" is the set of all interfaces on which the router
has received (*,G) Joins:
joins(G) =
{ all interfaces I such that
I_am_DF(RPA(G),I) AND
DownstreamJPState(G,I) is either Joined or PrunePending }
DownstreamJPState(G,I) is the state of the finite state machine in
Section 3.4.1.
RPF_DF(RPA) is the neighbor that Join messages must be sent to in
order to build the group shared tree rooted at the RPL for the given
RPA. This is the Designated-Forwarder on the RPF_interface(RPA).
3.2. PIM Neighbor Discovery
PIM routers exchange PIM-Hello messages with their neighboring PIM
routers. These messages are used to update the Neighbor State
described in Section 3.1. The procedures for generating and
processing Hello messages as well as maintaining Neighbor State are
specified in the PIM-SM [4] documentation.
BIDIR-PIM introduces the Bidirectional Capable PIM-Hello option that
MUST be included in all Hello messages from a BIDIR-PIM capable
router. The Bidirectional Capable option advertises the router's
ability to participate in the BIDIR-PIM protocol. The format of the
Bidirectional Capable option is described in Section 3.7.
If a BIDIR-PIM router receives a PIM-Hello message that does not
contain the Bidirectional Capable option from one of its neighbors,
the error must be logged to the router administrator in a rate-
limited manner.
3.3. Data Packet Forwarding Rules
For groups mapping to a given RPA, the following responsibilities are
uniquely assigned to the DF for that RPA on each link:
o The DF is the only router that forwards packets traveling
downstream onto the link.
o The DF is the only router that picks-up upstream traveling packets
off the link to forward towards the RPL.
Non-DF routers on a link, which use that link as their RPF interface
to reach the RPA, may perform the following forwarding actions for
bidirectional groups:
o Forward packets from the link towards downstream receivers.
o Forward packets from downstream sources onto the link (provided
they are the DF for the downstream link from which the packet was
picked-up).
The BIDIR-PIM packet forwarding rules are defined below in
pseudocode.
iif is the incoming interface of the packet.
G is the destination address of the packet (group address).
RPA is the Rendezvous Point Address for this group.
First we check to see whether the packet should be accepted based on
TIB state and the interface that the packet arrived on. A packet is
accepted if it arrives on the RPF interface to reach the RPA
(downstream traveling packet) or if the router is the DF on the
interface the packet arrives (upstream traveling packet).
If the packet should be forwarded, we build an outgoing interface
list for the packet.
Finally, we remove the incoming interface from the outgoing interface
list we've created, and if the resulting outgoing interface list is
not empty, we forward the packet out of those interfaces.
On receipt of data to G on interface iif:
if( iif == RPF_interface(RPA) || I_am_DF(RPA,iif) ) {
oiflist = olist(G) (-) iif
forward packet on all interfaces in oiflist
}
3.3.1. Upstream Forwarding at RP
When configuring a BIDIR-PIM domain, it is possible to assign the
Rendezvous Point Address (RPA) such that it does not belong to a
physical box but instead is simply a routable address. Routers that
have interfaces on the RPL that the RPA belongs to will upstream
forward traffic onto the link. Joins from receivers in the domain
will propagate hop-by-hop till they reach one of the routers
connected to the RPL where they will terminate (as there will be no
DF elected on the RPL).
If instead the administrator chooses to configure the RPA to be the
address of a physical interface of a specific router, then nothing
changes. That router must still upstream forward traffic on to the
RPL and behave no differently than any other router with an interface
on the RPL.
To configure a BIDIR-PIM network to operate in a mode similar to that
of PIM-SM where a single router (the RP) is acting as the root of the
distribution tree, the RPA can be configured to be the loopback
interface of a router.
3.3.2. Source-Only Branches
Source-only branches of the distribution tree for a group G are
branches that do not lead to any receivers, but that are used to
forward packets traveling upstream from sources towards the RPL.
Routers along source-only branches only have the RPF interface to the
RPA in their olist for G, and hence do not need to maintain any group
specific state. Upstream forwarding can be performed using only RPA
specific state. An implementation may decide to maintain group state
for source-only branches for accounting or performance reasons.
However, doing so requires data-driven events (to discover the groups
with active sources), thus sacrificing one of the main benefits of
BIDIR-PIM.
3.3.3. Directly Connected Sources
A major advantage of using a Designated Forwarder in BIDIR-PIM
compared to PIM-SM is that special treatment is no longer required
for sources that are directly connected to a router. Data from such
sources does not need to be differentiated from other multicast
traffic and will automatically be picked up by the DF and forwarded
upstream. This removes the need for performing a directly-
connected-source check for data to groups that do not have existing
state.
3.4. PIM Join/Prune Messages
BIDIR-PIM Join/Prune messages are used to construct group-specific
distribution trees between receivers and the RPL. Joins are
originated by last-hop routers that are elected as the DF on an
interface with directly connected receivers. The Joins propagate
hop-by-hop towards the RPA until they reach a router connected to the
RPL.
A BIDIR-PIM Join/Prune message consists of a list of Joined and
Pruned Groups. When processing a received Join/Prune message, each
Joined or Pruned Group is effectively considered individually by
applying the following state machines. When considering a Join/Prune
message whose PIM Destination field addresses this router, (*,G)
Joins and Prunes can affect the downstream state machine. When
considering a Join/Prune message whose PIM Destination field
addresses another router, most Join or Prune entries could affect the
upstream state machine.
3.4.1. Receiving (*,G) Join/Prune Messages
When a router receives a Join(*,G) or Prune(*,G), it MUST first check
to see whether the RP address in the message matches RPA(G) (the
router's idea of what the Rendezvous Point Address is). If the RP
address in the message does not match RPA(G), the Join or Prune MUST
be silently dropped.
If a router has no RPA information for the group (e.g., has not
recently received a BSR message), then it MAY choose to accept
Join(*,G) or Prune(*,G) and treat the RP address in the message as
RPA(G). If the newly discovered RPA did not previously exist for any
other group, a DF election has to be initiated.
Note that a router will process a Join(*,G) targeted to itself even
if it is not the DF for RP(G) on the interface on which the message
was received. This is an optimisation to eliminate the Join delay of
one Join period (t_periodic) in the case where a new DF processes the
received Pass and Join messages in reverse order. The BIDIR-PIM
forwarding logic will ensure that data packets are not forwarded on
such an interface while the router is not the DF (unless it is the
RPF interface towards the RPA).
The per-interface state machine for receiving (*,G) Join/Prune
Messages is given below. There are three states:
NoInfo (NI)
The interface has no (*,G) Join state and no timers running.
Join (J)
The interface has (*,G) Join state. If the router is the DF on
this interface (I_am_DF(RPA(G),I) is TRUE), the Join state will
cause us to forward packets destined for G on this interface.
PrunePending (PP)
The router has received a Prune(*,G) on this interface from a
downstream neighbor and is waiting to see whether the Prune
will be overridden by another downstream router. For
forwarding purposes, the PrunePending state functions exactly
like the Join state.
In addition, the state machine uses two timers:
ExpiryTimer (ET)
This timer is restarted when a valid Join(*,G) is received.
Expiry of the ExpiryTimer causes the interface state to revert
to NoInfo for this group.
PrunePendingTimer (PPT)
This timer is set when a valid Prune(*,G) is received. Expiry
of the PrunePendingTimer causes the interface state to revert
to NoInfo for this group.
Figure 1: Downstream group per-interface state machine in tabular
form
+---------------++---------------------------------------------------+
| || Prev State |
|Event ++---------------+-----------------+-----------------+
| || NoInfo (NI) | Join (J) | PrunePending |
| || | | (PP) |
+---------------++---------------+-----------------+-----------------+
| || -> J state | -> J state | -> J state |
|Receive || start Expiry | restart Expiry | restart Expiry |
|Join(*,G) || Timer | Timer | Timer; stop |
| || | | PrunePending- |
| || | | Timer |
+---------------++---------------+-----------------+-----------------+
|Receive || - | -> PP state | -> PP state |
|Prune(*,G) || | start Prune- | |
| || | PendingTimer | |
+---------------++---------------+-----------------+-----------------+
|PrunePending- || - | - | -> NI state |
|Timer Expires || | | Send Prune- |
| || | | Echo(*,G) |
+---------------++---------------+-----------------+-----------------+
|Expiry Timer || - | -> NI state | -> NI state |
|Expires || | | |
+---------------++---------------+-----------------+-----------------+
|Stop Being DF || - | -> NI state | -> NI state |
|on I || | | |
+---------------++---------------+-----------------+-----------------+
The transition events "Receive Join(*,G)" and "Receive Prune(*,G)"
imply receiving a Join or Prune targeted to this router's address on
the received interface. If the destination address is not correct,
these state transitions in this state machine must not occur,
although seeing such a packet may cause state transitions in other
state machines.
On unnumbered interfaces on point-to-point links, the router's
address should be the same as the source address it chose for the
Hello packet it sent over that interface. However, on point-to-point
links, we also RECOMMEND that PIM messages with a destination address
of all zeros also be accepted.
The transition event "Stop Being DF" implies a DF re-election taking
place on this router interface for RPA(G) and the router changing
status from being the active DF to being a non-DF router (the value
of the I_am_DF macro changing to FALSE).
When ExpiryTimer is started or restarted, it is set to the HoldTime
from the Join/Prune message that triggered the timer.
When PrunePendingTimer is started, it is set to the
J/P_Override_Interval if the router has more than one neighbor on
that interface; otherwise, it is set to zero causing it to expire
immediately.
The action "Send PruneEcho(*,G)" is triggered when the router stops
forwarding on an interface as a result of a Prune. A PruneEcho(*,G)
is simply a Prune(*,G) message sent by the upstream router to itself
on a LAN. Its purpose is to add additional reliability so that if a
Prune that should have been overridden by another router is lost
locally on the LAN, then the PruneEcho may be received and cause the
override to happen. A PruneEcho(*,G) need not be sent when the
router has only one neighbor on the link.
3.4.2. Sending Join/Prune Messages
The downstream per-interface state machines described above hold Join
state from downstream PIM routers. This state then determines
whether a router needs to propagate a Join(*,G) upstream towards the
RPA. Such Join(*,G) messages are sent on the RPF interface towards
the RPA and are targeted at the DF on that interface.
If a router wishes to propagate a Join(*,G) upstream, it must also
watch for messages on its upstream interface from other routers on
that subnet, and these may modify its behavior. If it sees a
Join(*,G) to the correct upstream neighbor, it should suppress its
own Join(*,G). If it sees a Prune(*,G) to the correct upstream
neighbor, it should be prepared to override that Prune by sending a
Join(*,G) almost immediately. Finally, if it sees the Generation ID
(see PIM-SM specification [4]) of the correct upstream neighbor
change, it knows that the upstream neighbor has lost state, and it
should be prepared to refresh the state by sending a Join(*,G) almost
immediately.
In addition, changes in the next hop towards the RPA trigger a Prune
off from the old next hop and join towards the new next hop. Such a
change can be caused by the following two events:
o The MRIB indicates that the RPF Interface towards the RPA has
changed. In this case the DF on the new RPF interface becomes
the new RPF Neighbor.
o There is a DF re-election on the RPF interface and a new router
emerges as the DF.
The upstream (*,G) state machine only contains two states:
Not Joined
The downstream state machines indicate that the router does not
need to join the RPA tree for this group.
Joined
The downstream state machines indicate that the router would
like to join the RPA tree for this group.
In addition, one timer JT(G) is kept, which is used to trigger the
sending of a Join(*,G) to the upstream next hop towards the RPA (the
DF on the RPF interface for RPA(G)).
Figure 2: Upstream group state machine in tabular form
+---------------------+----------------------------------------------+
| | Event |
| Prev State +-----------------------+----------------------+
| | JoinDesired(G) | JoinDesired(G) |
| | ->True | ->False |
+---------------------+-----------------------+----------------------+
| | -> J state | - |
| NotJoined (NJ) | Send Join(*,G); | |
| | Set Timer to | |
| | t_periodic | |
+---------------------+-----------------------+----------------------+
| Joined (J) | - | -> NJ state |
| | | Send Prune(*,G) |
+---------------------+-----------------------+----------------------+
In addition, we have the following transitions that occur within the
Joined state:
+--------------------------------------------------------------------+
| In Joined (J) State |
+----------------+----------------+-----------------+----------------+
|Timer Expires | See Join(*,G) | See Prune(*,G) | RPF_DF(RPA(G)) |
| | to | to | GenID changes |
| | RPF_DF(RPA(G)) | RPF_DF(RPA(G)) | |
+----------------+----------------+-----------------+----------------+
|Send | Increase Timer | Decrease Timer | Decrease Timer |
|Join(*,G); Set | to | to t_override | to t_override |
|Timer to | t_suppressed | | |
|t_periodic | | | |
+----------------+----------------+-----------------+----------------+
+--------------------------------------------------------------------+
| In Joined (J) State |
+-----------------------------------+--------------------------------+
| Change of RPF_DF(RPA(G)) | RPF_DF(RPA(G)) GenID |
| | changes |
+-----------------------------------+--------------------------------+
| Send Join(*,G) to new | Decrease Timer to |
| DF; Send Prune(*,G) to | t_override |
| old DF; set Timer to | |
| t_periodic | |
+-----------------------------------+--------------------------------+
This state machine uses the following macro:
bool JoinDesired(G) {
if (olist(G) (-) RPF_interface(RPA(G))) != NULL
return TRUE
else
return FALSE
}
3.5. Designated Forwarder (DF) Election
This section presents a fail-safe mechanism for electing a per-RPA
designated router on each link in a BIDIR-PIM domain. We call this
router the Designated Forwarder (DF). The DF election does not take
place on the RPL for an RPA.
3.5.1. DF Requirements
The DF election chooses the best router on a link to assume
responsibility for forwarding traffic between the RPL and the link
for the range of multicast groups served by the RPA. Different
multicast groups that share a common RPA share the same upstream
direction. Hence, the election of an upstream forwarder on each link
does not have to be a group-specific decision but instead can be
RPA-specific. As the number of RPAs is typically small, the number
of elections that have to be performed is significantly reduced by
this observation.
To optimise tree creation, it is desirable that the winner of the
election process should be the router on the link with the "best"
unicast routing metric (as reported by the MRIB) to reach the RPA.
When comparing metrics from different unicast routing protocols, we
use the same comparison rules used by the PIM-SM assert process [4].
The election process needs to take place when information on a new
RPA initially becomes available. The result can be re-used as new
bidir groups that map to the same RPA are encountered. However,
there are some conditions under which an update to the election is
required:
o There is a change in unicast metric to reach the RPA for any of
the routers on the link.
o The interface on which the RPA is reachable (RPF Interface)
changes to an interface for which the router was previously the
DF.
o A new PIM neighbor starts up on a link that must participate in
the elections and be informed of the current outcome.
o The elected DF fails (detected through neighbor information
timeout or MRIB RPF change at downstream router).
The election process has to be robust enough to ensure with very high
probability that all routers on the link have a consistent view of
the DF. Given the forwarding rules described in Section 3.3, loops
may result if multiple routers end-up thinking that they should be
responsible for forwarding. To minimize the possibility of this
occurrence, the election algorithm has been biased towards discarding
DF information and suspending forwarding during periods of ambiguity.
3.5.2. DF Election Description
This section gives an outline of the DF election process. It does
not provide the definitive specification for the DF election. If any
discrepancy exists between Section 3.5.3 and this section, the
specification in Section 3.5.3 is to be assumed correct.
To perform the election of the DF for a particular RPA, routers on a
link need to exchange their unicast routing metric information for
reaching the RPA. Routers advertise their own metrics in Offer,
Winner, Backoff, and Pass messages. The advertised metric is
calculated using the RPF Interface and metric to reach the RPA
available through the MRIB. When a router is participating in a DF
election for an RPA on the interface that its MRIB indicates as the
RPF Interface, then that router MUST always advertise an infinite
metric in its election messages. When a router is participating in a
DF election on an interface other than the MRIB-indicated RPF
Interface then it MUST advertise the MRIB-provided metrics in its
election messages.
In the election protocol described below, many message exchanges are
repeated Election_Robustness times for reliability. In all those
cases, the message retransmissions are spaced in time by a small
random interval. All of the following description is specific to the
election on a single link for a single RPA.
3.5.2.1. Bootstrap Election
Initially, when no DF has been elected, routers finding out about a
new RPA start participating in the election by sending Offer
messages. Offer messages include the router's metric to reach the
RPA. Offers are periodically retransmitted with a period of
Offer_Interval.
If a router hears a better offer than its own from a neighbor, it
stops participating in the election for a period of
Election_Robustness * Offer_Interval, thus giving a chance to the
neighbor with the better metric to be elected DF. If during this
period no winner is elected, the router restarts the election from
the beginning. If at any point during the initial election a router
receives an out of order offer with worse metrics than its own, then
it restarts the election from the beginning.
The result should be that all routers except the best candidate stop
advertising their offers.
A router assumes the role of the DF after having advertised its
metrics Election_Robustness times without receiving any offer from
any other neighbor. At that point, it transmits a Winner message
that declares to every other router on the link the identity of the
winner and the metrics it is using.
Routers receiving a Winner message stop participating in the election
and record the identity and metrics of the winner. If the local
metrics are better than those of the winner, then the router records
the identity of the winner (accepting it as the acting DF) but re-
initiates the election to try and take over.
3.5.2.2. Loser Metric Changes
Whenever the unicast metric to an RPA changes at a non-DF router to a
value that is better than that previously advertised by the acting
DF, the router with the new better metric should take action to
eventually assume forwarding responsibility. When the metric change
is detected, the non-DF router with the now better metric restarts
the DF election process by sending Offer messages with this new
metric. Note that at any point during an election if no response is
received after Election_Robustness retransmissions of an offer, a
router assumes the role of the DF following the usual Winner
announcement procedure.
Upon receipt of an offer that is worse than its current metric, the
DF will respond with a Winner message declaring its status and
advertising its better metric. Upon receiving the Winner message,
the originator of the Offer records the identity of the DF and aborts
the election.
Upon receipt of an offer that is better than its current metric, the
DF records the identity and metrics of the offering router and
responds with a Backoff message. This instructs the offering router
to hold off for a short period of time while the unicast routing
stabilizes and other routers get a chance to put in their offers.
The Backoff message includes the offering router's new metric and
address. All routers on the link that have pending offers with
metrics worse than those in the Backoff message (including the
original offering router) will hold further offers for a period of
time defined in the Backoff message.
If a third router sends a better offer during the Backoff_Period, the
Backoff message is repeated for the new offer and the Backoff_Period
is restarted.
Before the Backoff_Period expires, the acting DF nominates the router
having made the best offer as the new DF using a Pass message. This
message includes the IDs and metrics of both the old and new DFs.
The old DF stops performing its tasks at the time the Pass message
transmission is made. The new DF assumes the role of the DF as soon
as it receives the Pass message. All other routers on the link take
note of the new DF and its metric. Note that this event constitutes
an RPF Neighbor change, which may trigger Join messages to the new DF
(see Section 3.4).
3.5.2.3. Winner Metric Changes
If the DF's routing metric to reach the RPA changes to a worse value,
it sends a set of Election_Robustness randomly spaced Winner messages
on the link, advertising the new metric. Routers that receive this
announcement but have a better metric may respond with an Offer
message that results in the same handoff procedure described above.
All routers assume the DF has not changed until they see a Pass or
Winner message indicating the change.
There is no pressure to make this handoff quickly if the acting DF
still has a path to the RPL. The old path may now be suboptimal, but
it will still work while the re-election is in progress.
3.5.2.4. Winner Loses Path
If a router's RPF Interface to the RPA switches to be on a link for
which it is acting as the DF, then it can no longer provide
forwarding services for that link. It therefore immediately stops
being the DF and restarts the election. As its path to the RPA is
through the link, an infinite metric is used in the Offer message it
sends.
3.5.2.5. Late Router Starting Up
A late router starting up after the DF election process has completed
will have no immediate knowledge of the election outcome. As a
result, it will start advertising its metric in Offer messages. As
soon as this happens, the currently elected DF will respond with a
Winner message if its metric is better than the metric in the Offer
message, or with a Backoff message if its metric is worse than the
metric in the Offer message.
3.5.2.6. Winner Dies
Whenever the DF dies, a new DF has to be elected. The speed at which
this can be achieved depends on whether there are any downstream
routers on the link.
If there are downstream routers, typically their MRIB reported next-
hop before the DF dies will be the DF itself. They will therefore
notice either a change in the metric for the route to the RPA or a
change in next-hop away from the DF and can restart the election by
transmitting Offer messages. If according to the MRIB the RPA is now
reachable through the same link via another upstream router, an
infinite metric will be used in the Offer.
If no downstream routers are present, the only way for other upstream
routers to detect a DF failure is by the timeout of the PIM neighbor
information, which will take significantly longer.
3.5.3. Election Protocol Specification
This section provides the definitive specification for the DF
election process. If any discrepancy exists between Section 3.5.2
and this section, the specification in this section is to be assumed
correct.
3.5.3.1. Election State
The DF election state is maintained per RPA for each multicast
enabled interface I on the router as introduced in Section 3.1.
The state machine has the following four states:
Offer
Initial election state. When in the Offer state, a router
thinks it can eventually become the winner and periodically
generates Offer messages.
Lose
In this state, the router knows that there either is a
different election winner or that no router on the link has a
path to the RPA.
Win
The router is the acting DF without any contest.
Backoff
The router is the acting DF but another router has made a bid
to take over.
In the state machine, a router is considered to be an acting DF if it
is in the Win or Backoff states.
The operation of the election protocol makes use of the variables and
timers described below:
Acting DF information
Used to store the identity and advertised metrics of the
election winner that is the currently acting DF.
DF election-Timer (DFT)
Used to schedule transmission of Offer, Winner, and Pass
messages.
Message-Count (MC)
Used to maintain the number of times an Offer or Winner message
has been transmitted.
Best-Offer
Used by the DF to record the identity and advertised metrics of
the router that has made the last offer, for use when sending
the Path message.
3.5.3.2. Election Messages
The election process uses the following PIM control messages. The
packet format is described in Section 3.7:
Offer (OfferingID, Metric)
Sent by routers that believe they have a better metric to the
RPA than the metric that has been on offer so far.
Winner (DF-ID, DF-Metric)
Sent by a router when assuming the role of the DF or when re-
asserting in response to worse offers.
Backoff (DF-ID, DF-Metric, OfferingID, OfferMetric,
BackoffInterval)
Used by the DF to acknowledge better offers. It instructs
other routers with equal or worse offers to wait until the DF
passes responsibility to the sender of the offer.
Pass (Old-DF-ID, Old-DF-Metric, New-DF-ID, New-DF-Metric)
Used by the old DF to pass forwarding responsibility to a
router that has previously made an offer. The Old-DF-Metric is
the current metric of the DF at the time the pass is sent.
Note that when a router is participating in a DF election for an RPA
on the interface that its MRIB indicates as the RPF Interface, then
that router MUST always advertise an infinite metric in its election
messages. When a router is participating in a DF election on an
interface other than the MRIB-indicated RPF Interface, then it MUST
advertise the MRIB-provided metrics in its election messages.
3.5.3.3. Election Events
During protocol operation, the following events can take place:
Control message reception
Reception of one of the four control DF election messages
(Offer, Winner, Backoff, and Pass). When a control message is
received and actions are specified on a condition that metrics
are Better or Worse, the comparison must be performed as
follows:
o On receipt of an Offer or Winner message, compare the current
metrics for the RPA with the metrics advertised for the
sender of the message.
o On receipt of a Backoff or Pass message, compare the current
metrics for the RPA with the metrics advertised for the
target of the message.
Path to RPA lost
Losing the path to the RPA can happen in two ways. The first
happens when the route learned through the MRIB is withdrawn
and the MRIB no longer reports an available route to reach the
RPA. The second case happens when the next-hop information
reported by the MRIB changes to indicate a next-hop that is
reachable through the router interface under consideration.
Clearly, as the router is using the interface as its RPF
Interface, it cannot offer forwarding services towards the RPL
to other routers on that link.
Metric reported by the MRIB to reach the RPA changes
This event is triggered when the MRIB supplied information for
the RPA changes and the new information provides a path to the
RPA. If the new MRIB information either reports no route or
reports a next-hop interface through the interface for which
the DF election is taking place, then the "Path to RPA lost"
event triggers instead. In specific states, the event may be
further filtered by specifying whether it is expected of the
metric to become better or worse and which of the stored
metrics the new MRIB information must be compared against. The
new information must be compared with either the router's old
metric, the stored DF metric, or the stored Best Offer metric.
Election-Timer (DFT) expiration
Expiration of the DFT election timer can cause message
transmission and state transitions. The event might be further
qualified by specifying the value of the Message Count (MC) as
well as the current existence of a path to the RPA (as defined
above).
Detection of DF failure
Detection of DF failure can occur through the timeout of PIM
neighbor state.
3.5.3.4. Election Actions
The DF election state machine action descriptions use the following
notation in addition to the pseudocode notation described earlier in
this specification:
?= denotes the operation of lowering a timer to a new value. If
the timer is not running, then it is started using the new
value. If the timer is running with an expiration lower than
the new value, then the timer is not altered.
When an action of "set DF to Sender or Target" is encountered during
receipt of a Winner, Pass, or Backoff message, it means the
following:
o On receipt of a Winner message, set the DF to be the originator
of the message and record its metrics.
o On receipt of a Pass message, set the DF to be the target of the
message and record its metrics.
o On receipt of a Backoff message, set the DF to be the originator
of the message and record its metrics.
3.5.3.5. Election State Transitions
When a Designated Forwarder election is initiated, the starting state
is the Offer state, the message counter (MC) is set to zero, and the
DF election Timer (DFT) is set to OPlow (see Section 3.6 for a
definition of timer values).
Figure 3: Designated Forwarder election state machine in tabular form
+-------------+------------------------------------------------------+
| | Event |
| Prev State +-----------------+------------------+-----------------+
| | Recv better | Recv better | Recv better |
| | Pass / Win | Backoff | Offer |
+-------------+-----------------+------------------+-----------------+
| | -> Lose | - | - |
| Offer | DF = Sender or | DFT = BOperiod | DFT = OPhigh; |
| | Target; Stop | + OPlow; MC = | MC = 0 |
| | DFT | 0 | |
+-------------+-----------------+------------------+-----------------+
| | - | - | -> Offer |
| Lose | DF = Sender or | DF = Sender | DFT = OPhigh; |
| | Target | | MC = 0 |
+-------------+-----------------+------------------+-----------------+
| | -> Lose | -> Lose | -> Backoff |
| | DF = Sender or | DF = Sender; | Set Best to |
| Win | Target; Stop | Stop DFT | Sender; Send |
| | DFT | | Backoff; DFT = |
| | | | BOperiod |
+-------------+-----------------+------------------+-----------------+
| | -> Lose | -> Lose | - |
| | DF = Sender or | DF = Sender; | Set Best to |
| Backoff | Target; Stop | Stop DFT | Sender; Send |
| | DFT | | Backoff; DFT = |
| | | | BOperiod |
+-------------+-----------------+------------------+-----------------+
+-----------+-------------------------------------------------------+
| | Event |
| +-------------+-------------+--------------+------------+
|Prev State |Recv Backoff |Recv Pass |Recv Worse |Recv worse |
| |for us |for us |Pass / Win / |Offer |
| | | |Backoff | |
+-----------+-------------+-------------+--------------+------------+
| |- |-> Win |- |- |
| |DFT = |Stop DFT |Set DF to |DFT ?= |
|Offer |BOperiod + | |Sender or |OPlow; MC = |
| |OPlow; MC = | |Target; DFT |0 |
| |0 | |?= OPlow; MC | |
| | | |= 0 | |
+-----------+-------------+-------------+--------------+------------+
| |-> Offer |-> Offer |-> Offer |-> Offer |
| |DF = Sender; |DF = Sender; |DF = Sender |DFT = OPlow;|
|Lose |DFT = OPlow; |DFT = OPlow; |or Target; |MC = 0 |
| |MC = 0 |MC = 0 |DFT = OPlow; | |
| | | |MC = 0 | |
+-----------+-------------+-------------+--------------+------------+
| |-> Offer |-> Offer |-> Offer |- |
| |DF = Sender; |DF = Sender; |DF = Sender |Send Winner |
|Win |DFT = OPlow; |DFT = OPlow; |or Target; | |
| |MC = 0 |MC = 0 |DFT = OPlow; | |
| | | |MC = 0 | |
+-----------+-------------+-------------+--------------+------------+
| |-> Offer |-> Offer |-> Offer |-> Win |
| |DF = Sender; |DF = Sender; |DF = Sender |Send Winner;|
|Backoff |DFT = OPlow; |DFT = OPlow; |or Target; |Stop DFT |
| |MC = 0 |MC = 0 |DFT = OPlow; | |
| | | |MC = 0 | |
+-----------+-------------+-------------+--------------+------------+
+--------------------------------------------------------------------+
| In Offer State |
+----------------------+----------------------+----------------------+
| DFT Expires and MC | DFT Expires and MC | DFT Expires and MC |
| is less than | is equal to | is equal to |
| Robustness | Robustness and we | Robustness and |
| | have path to RPA | there is no path |
| | | to RPA |
+----------------------+----------------------+----------------------+
| - | -> Win | -> Lose |
| Send Offer; DFT = | Send Winner | Set DF to None |
| OPlow; MC = MC + 1 | | |
+----------------------+----------------------+----------------------+
+--------------------------------------------------------------------+
| In Offer State |
+--------------------------------------------------------------------+
| Metric changes and is now worse |
+--------------------------------------------------------------------+
| DFT ?= OPlow |
| MC = 0 |
+--------------------------------------------------------------------+
+--------------------------------------------------------------------+
| In Lose State |
+------------------------------+-------------------------------------+
| Detect DF Failure | Metric changes and now |
| | is better than DF |
+------------------------------+-------------------------------------+
| -> Offer | -> Offer |
| DF = None; DFT = | DFT = OPlow_int; MC = 0 |
| OPlow_int; MC = 0 | |
+------------------------------+-------------------------------------+
+--------------------------------------------------------------------+
| In Win State |
+----------------------+-----------------------+---------------------+
| Metric changes and | Timer Expires and | Path to RPA lost |
| is now worse | MC is less than | |
| | Robustness | |
+----------------------+-----------------------+---------------------+
| - | - | -> Offer |
| DFT = OPlow; MC = | Send Winner; DFT = | Set DF to None; |
| 0 | OPlow; MC = MC + 1 | DFT = OPlow; MC = |
| | | 0 |
+----------------------+-----------------------+---------------------+
+--------------------------------------------------------------------+
| In Backoff State |
+----------------------+-----------------------+---------------------+
| Metric changes and | Timer Expires | Path to RPA lost |
| is now better than | | |
| Best | | |
+----------------------+-----------------------+---------------------+
| -> Win | -> Lose | -> Offer |
| Stop Timer | Send Pass; Set DF | Set DF to None; |
| | to stored Best | DFT = OPlow; MC = |
| | | 0 |
+----------------------+-----------------------+---------------------+
3.5.4. Election Reliability Enhancements
For the correct operation of BIDIR-PIM, it is very important to avoid
situations where two routers consider themselves to be Designated
Forwarders for the same link. The two precautions below are not
required for correct operation but can help diagnose and correct
anomalies.
3.5.5. Missing Pass
After a DF has been elected, a router whose metrics change to become
better than the DF will attempt to take over. If during the re-
election the acting DF has a condition that causes it to lose all of
the election messages (like a CPU overload), the new candidate will
transmit three offers and assume the role of the forwarder resulting
in two DFs on the link. This situation is pathological and should be
corrected by fixing the overloaded router. It is desirable that such
an event can be detected by a network administrator.
When a router becomes the DF for a link without receiving a Pass
message from the known old DF, the PIM neighbor information for the
old DF can be marked to this effect. Upon receiving the next PIM
Hello message from the old DF, the router can retransmit Winner
messages for all the RPAs for which it is acting as the DF. The
anomaly may also be logged by the router in a rate-limited manner to
alert the operator.
3.5.6. Periodic Winner Announcement
An additional degree of safety can be achieved by having the DF for
each RPA periodically announce its status in a Winner message.
Transmission of the periodic Winner message can be restricted to
occur only for RPAs that have active groups, thus avoiding the
periodic control traffic in areas of the network without senders or
receivers for a particular RPA.
3.6. Timers, Counters, and Constants
BIDIR-PIM maintains the following timers, as discussed in Section
3.1. All timers are countdown timers - they are set to a value and
count down to zero, at which point they typically trigger an action.
Of course they can just as easily be implemented as count-up timers,
where the absolute expiry time is stored and compared against a real-
time clock, but the language in this specification assumes that they
count downwards to zero.
Per Rendezvous-Point Address (RPA):
Per interface (I):
DF Election Timer: DFT(RPA,I)
Per Group (G):
Upstream Join Timer: JT(G)
Per interface (I):
Join Expiry Timer: ET(G,I)
PrunePendingTimer: PPT(G,I)
When timers are started or restarted, they are set to default values.
This section summarizes those default values.
Timer Name: DF Election Timer (DFT)
+-------------------+------------------------+-----------------------+
| Value Name | Value | Explanation |
+-------------------+------------------------+-----------------------+
| Offer_Period | 100 ms | Interval to wait |
| | | between repeated |
| | | Offer and Winner |
| | | messages. |
+-------------------+------------------------+-----------------------+
| Backoff_Period | 1 sec | Period that acting |
| | | DF waits between |
| | | receiving a better |
| | | Offer and sending |
| | | the Pass message |
| | | to transfer DF |
| | | responsibility. |
+-------------------+------------------------+-----------------------+
| OPlow | rand(0.5, 1) * | Range of actual |
| | Offer_Period | randomised value |
| | | used between |
| | | repeated messages. |
+-------------------+------------------------+-----------------------+
| OPhigh | Election_Robustness | Interval to wait |
| | * Offer_Period | in order to give a |
| | | chance to a router |
| | | with a better |
| | | Offer to become |
| | | the DF. |
+-------------------+------------------------+-----------------------+
Timer Names: Join Expiry Timer (ET(G,I))
+---------------+---------------+------------------------------------+
|Value Name | Value | Explanation |
+---------------+---------------+------------------------------------+
|J/P HoldTime | from message | Hold Time from Join/Prune Message |
+---------------+---------------+------------------------------------+
Timer Names: PrunePendingTimer (PPT(G,I))
+-------------------------+-------------------+----------------------+
| Value Name | Value | Explanation |
+-------------------------+-------------------+----------------------+
| J/P Override Interval | Default: 3 secs | Short period after |
| | | a Join or Prune to |
| | | allow other |
| | | routers on the LAN |
| | | to override the |
| | | Join or Prune |
+-------------------------+-------------------+----------------------+
Note that the value of the J/P Override Interval is interface specific
and depends on both the Propagation_Delay and the Override_Interval
values that may change when Hello messages are received [4].
Timer Names: Upstream Join Timer (JT(G))
+------------+-------------------+-----------------------------------+
Value Name |Value Explanation |
+------------+-------------------+-----------------------------------+
t_periodic |Default: 60 secs Period between Join/Prune Messages |
+------------+-------------------+-----------------------------------+
t_suppressed |rand(1.1 * Suppression period when someone |
| |t_periodic, 1.4 * else sends a J/P message so we |
| |t_periodic) don't need to do so. |
+------------+-------------------+-----------------------------------+
t_override |rand(0, 0.9 * J/P Randomized delay to prevent |
| |Override Interval) response implosion when sending a |
| | Join message to override someone |
| | else's Prune message. |
+------------+-------------------+-----------------------------------+
For more information about these values, refer to the PIM-SM [4]
documentation.
Constant Name: DF Election Robustness
+-------------------------+------------------+-----------------------+
| Constant Name | Value | Explanation |
+-------------------------+------------------+-----------------------+
| Election_Robustness | Default: 3 | Minimum number of |
| | | election messages |
| | | that must be lost |
| | | in order for |
| | | election to fail. |
+-------------------------+------------------+-----------------------+
3.7. BIDIR-PIM Packet Formats
This section describes the details of the packet formats for BIDIR-
PIM control messages. BIDIR-PIM shares a number of control messages
in common with PIM-SM [4]. These include the Hello and Join/Prune
messages as well as the format for the Encoded-Unicast address. For
details on the format of these packets, please refer to the PIM-SM
documentation. Here we will only define the additional packets that
are introduced by BIDIR-PIM. These are the packets used in the DF
election process as well as the Bidirectional Capable PIM-Hello
option.
3.7.1. DF Election Packet Formats
All PIM control messages have IP protocol number 103.
BIDIR-PIM messages are multicast with TTL 1 to the `ALL-PIM-ROUTERS'
group. The IPv4 `ALL-PIM-ROUTERS' group is `224.0.0.13'. The IPv6
`ALL-PIM-ROUTERS' group is `ff02::d'.
All DF election BIDIR-PIM control messages share the common header
below:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|PIM Ver| Type |Subtype| Rsvd | Checksum |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| RP Address (Encoded-Unicast format) ...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sender Metric Preference |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sender Metric |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
PIM Ver
PIM Version number is 2.
Type
All DF-Election PIM control messages share the PIM message Type of
10.
Subtype
Subtypes for DF election messages are:
1 = Offer
2 = Winner
3 = Backoff
4 = Pass
Rsvd
Set to zero on transmission. Ignored on receipt.
Checksum
A standard checksum IP checksum is used, i.e., the 16-bit one's
complement of the one's complement sum of the entire PIM message.
For computing the checksum, the checksum field is zeroed.
RP Address
The bidirectional RPA for which the election is taking place. The
format is described in [4], Section 4.9.1.
Sender Metric Preference
Preference value assigned to the unicast routing protocol that the
message sender used to obtain the route to the RPA.
Sender Metric
The unicast routing table metric used by the message sender to
reach the RPA. The metric is in units applicable to the unicast
routing protocol used.
In addition to the fields defined above, the Backoff and Pass
messages have the extra fields described below.
3.7.2. Backoff Message
The Backoff message uses the following fields in addition to the
common election message format described above.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Offering Address (Encoded-Unicast format) ...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Offering Metric Preference |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Offering Metric |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Interval |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Offering Address
The address of the router that made the last (best) Offer. The
format is described in [4], Section 4.9.1.
Offering Metric Preference
Preference value assigned to the unicast routing protocol that the
offering router used to obtain the route to the RPA.
Offering Metric
The unicast routing table metric used by the offering router to
reach the RPA. The metric is in units applicable to the unicast
routing protocol used.
Interval
The backoff interval in milliseconds to be used by routers with
worse metrics than the offering router.
3.7.3. Pass Message
The Pass message uses the following fields in addition to the common
election fields described above.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| New Winner Address (Encoded-Unicast format) ...
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| New Winner Metric Preference |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| New Winner Metric |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
New Winner Address
The address of the router that made the last (best) Offer. The
format is described in [4], Section 4.9.1.
New Winner Metric Preference
Preference value assigned to the unicast routing protocol that the
offering router used to obtain the route to the RPA.
New Winner Metric
The unicast routing table metric used by the offering router to
reach the RPA. The metric is in units applicable to the unicast
routing protocol used.
3.7.4. Bidirectional Capable PIM-Hello Option
BIDIR-PIM introduces one new PIM-Hello option.
o OptionType 22: Bidirectional Capable
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 = 22 | Length = 0 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
4. RP Discovery
Routers discover that a range of multicast group addresses operates
in bidirectional mode, and that the address of the Rendezvous-Point
address (RPA) is serving the group range either through static
configuration or using an automatic RP discovery mechanism like the
PIM Bootstrap mechanism (BSR) [7] or Auto-RP.
5. Security Considerations
The IPsec [5] authentication header MAY be used to provide data
integrity protection and group-wise data origin authentication of
BIDIR-PIM protocol messages. Authentication of BIDIR-PIM messages
can protect against unwanted behaviour caused by unauthorized or
altered BIDIR-PIM messages.
5.1. Attacks Based on Forged Messages
As in PIM Sparse-Mode, the extent of possible damage depends on the
type of counterfeit messages accepted. BIDIR-PIM only uses link-
local multicast messages sent to the ALL_PIM_ROUTERS address, hence
attacks can only be carried out by directly connected nodes, or with
the complicity of directly connected routers.
Some of the BIDIR-PIM protocol messages (Join/Prune and Hello) are
identical, both in format and functionality, to the respective
messages used in PIM-SM. Security considerations for these messages
are to be found in [4]. Other messages (DF-election messages) are
specific to BIDIR-PIM and will be discussed in the following
paragraphs.
By forging DF-election messages, an attacker can disrupt the election
of the Designated Forwarder on a link in two different ways:
5.1.1. Election of an Incorrect DF
An attacker can force its election as DF by participating in a
regular election and advertising the best metric to reach the RPA.
An attacker can also try to force the election of another router as
DF by sending an Offer, Winner, or Pass message and impersonating
another router. In some cases (e.g., the Offer), multiple messages
might be needed to carry out an attack.
In the case of Offer or Winner messages, the attacker will have to
impersonate the node that it wants to have become the DF. In the
case of the Pass, it will have to impersonate the current DF. This
type of attack causes the wrong DF to be recorded in all nodes apart
from the one that is being impersonated. This node typically will be
able to detect the anomaly and, possibly, restart a new election.
A more sophisticated attacker might carry out a concurrent DoS attack
on the node being impersonated, so that it will not be able to detect
the forged packets and/or take countermeasures.
All attacks based on impersonation can be detected by all routers and
avoided if the source of DF-election messages can be authenticated.
When authentication is available, spoofed messages MUST be discarded
and a rate-limited warning message SHOULD be logged.
A more subtle attacker could use MAC-level addresses to partition the
set of recipients of DF-election messages and create an inconsistent
DF view on the link. For example, the attacker could use unicast MAC
addresses for its forged DF-election messages. To prevent this type
of attack, BIDIR-PIM routers SHOULD check the destination MAC address
of received DF-election messages. This however is ineffective on
links that do not support layer-2 multicast delivery.
Source authentication is also sufficient to prevent this kind of
attack.
5.1.2. Preventing Election Convergence
By forging DF election messages, an attacker can prevent the election
from converging, thus disrupting the establishment of multicast
forwarding trees. There are many ways to achieve this. The simplest
is by sending an infinite sequence of Offer messages (the metric used
in the messages is not important).
5.2. Non-Cryptographic Authentication Mechanisms
A BIDIR-PIM router SHOULD provide an option to limit the set of
neighbors from which it will accept Join/Prune, Assert, and DF-
election messages. Either static configuration of IP addresses or an
IPsec security association may be used. Furthermore, a PIM router
SHOULD NOT accept protocol messages from a router from which it has
not yet received a valid Hello message.
5.2.1. Basic Access Control
In a PIM-SM domain, when all routers are trusted, it is possible to
implement a basic form of access control for both sources and
receivers: Receivers can be validated by the last-hop DR and sources
can be validated by the first-hop DR and/or the RP.
In BIDIR-PIM, this is generally feasible only for receivers, as
sources can send to the multicast group without the need for routers
to detect their activity and create source-specific state. However,
it is possible to modify the standard BIDIR-PIM behaviour, in a
backward compatible way, to allow per-source access control. The
tradeoff would be protocol simplicity, memory, and processing
requirements.
5.3. Authentication Using IPsec
Just as with PIM-SM, the IPsec [5] transport mode using the
Authentication Header (AH) is the recommended method to prevent the
above attacks against BIDIR-PIM.
It is recommended that IPsec authentication be applied to all BIDIR-
PIM protocol messages. The specification on how this is done is
found in [4]. Specifically, the authentication of PIM-SM link-local
messages, described in [4], applies to all BIDIR-PIM messages as
well.
5.4. Denial-of-Service Attacks
The denial-of-service attack based on forged Join messages, described
in [4], also applies to BIDIR-PIM.
6. IANA Considerations
IANA has assigned OptionType 22 to the "Bidirectional Capable"
option.
7. Acknowledgments
The bidirectional proposal in this document is heavily based on the
ideas and text presented by Estrin and Farinacci in [6]. The main
difference between the two proposals is in the method chosen for
upstream forwarding.
We would also like to thank John Zwiebel at Cisco, Deborah Estrin at
ISI/USC, Bill Fenner at AT&T Research, as well as Nidhi Bhaskar,
Yiqun Cai, Toerless Eckert, Apoorva Karan, Rajitha Sumanasekera, and
Beau Williamson at Cisco for their contributions and comments to this
document.
8. Normative References
[1] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997.
[2] Cain, B., Deering, S., Kouvelas, I., Fenner, B., and A.
Thyagarajan, "Internet Group Management Protocol, Version 3", RFC
3376, October 2002.
[3] Deering, S., Fenner, W., and B. Haberman, "Multicast Listener
Discovery (MLD) for IPv6", RFC 2710, October 1999.
[4] Fenner, B., Handley, M., Holbrook, H., and I. Kouvelas, "Protocol
Independent Multicast - Sparse Mode (PIM-SM): Protocol
Specification (Revised)", RFC 4601, August 2006.
[5] Kent, S. and R. Atkinson, "Security Architecture for the Internet
Protocol", RFC 2401, November 1998.
9. Informative References
[6] Estrin, D. and D. Farinacci, "Bi-directional Shared Trees in
PIM-SM", Work in Progress, May 1999.
[7] Bhaskar, N., Gall, A., Lingard, J., and S. Venaas, "Bootstrap
Router (BSR) Mechanism for PIM", Work in Progress, February 2007.
[8] Bates, T., Chandra, R., Katz, D., and Y. Rekhter, "Multiprotocol
Extensions for BGP-4", RFC 4760, January 2007.
Index
DF. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5,18
Downstream. . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
DownstreamJPState(G,I). . . . . . . . . . . . . . . . . . . . . . 10
ET(G,I) . . . . . . . . . . . . . . . . . . . . . . . . . . . 9,14,33
ET(RPA,I) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
I_am_DF(RPA,I). . . . . . . . . . . . . . . . . . . . . . . .10,12,14
J/P_HoldTime. . . . . . . . . . . . . . . . . . . . . . . . . . . 33
J/P_Override_Interval . . . . . . . . . . . . . . . . . . . . . 16,33
JoinDesired(G). . . . . . . . . . . . . . . . . . . . . . . . . . 18
joins(G). . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
JT(*,G) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
JT(G) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9,33
local_receiver_include(G,I) . . . . . . . . . . . . . . . . . . . 10
MFIB. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
NLT(N,I). . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Offer_Period. . . . . . . . . . . . . . . . . . . . . . . . . . . 32
olist(G). . . . . . . . . . . . . . . . . . . . . . . . . . .10,12,18
Bidirectional Capable OptionType . . . . . . . . . . . . . . . . 37
pim_include(G). . . . . . . . . . . . . . . . . . . . . . . . . . 10
PPT(G,I). . . . . . . . . . . . . . . . . . . . . . . . . . . 9,14,33
RPA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
RPF_interface(RPA). . . . . . . . . . . . . . . . . . . . . . . 10,12
RPL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
TIB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
t_override. . . . . . . . . . . . . . . . . . . . . . . . . . . 17,33
t_periodic. . . . . . . . . . . . . . . . . . . . . . . . . . . 17,33
t_suppressed. . . . . . . . . . . . . . . . . . . . . . . . . . 17,33
Upstream. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Authors' Addresses
Mark Handley
Computer Science Department
University College London
EMail: M.Handley@cs.ucl.ac.uk
Isidor Kouvelas
Cisco Systems
EMail: kouvelas@cisco.com
Tony Speakman
Cisco Systems
EMail: speakman@cisco.com
Lorenzo Vicisano
Digital Fountain
EMail: lorenzo@digitalfountain.com
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