| Softwire WG | M. Boucadair |
| Internet-Draft | Orange |
| Intended status: Standards Track | J. Qin |
| Expires: June 18, 2017 | Cisco |
| C. Jacquenet | |
| Orange | |
| Y. Lee | |
| Comcast | |
| Q. Wang | |
| China Telecom | |
| December 15, 2016 |
Delivery of IPv4 Multicast Services to IPv4 Clients over an IPv6 Multicast Network
draft-ietf-softwire-dslite-multicast-14
This document specifies a solution for the delivery of IPv4 multicast services to IPv4 clients over an IPv6 multicast network. The solution relies upon a stateless IPv4-in-IPv6 encapsulation scheme and uses the IPv6 multicast distribution tree to deliver IPv4 multicast traffic. The solution is particularly useful for the delivery of multicast service offerings to DS-Lite serviced customers.
This Internet-Draft is submitted 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 June 18, 2017.
Copyright (c) 2016 IETF Trust and the persons identified as the document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.
DS-Lite [RFC6333] is a technique that rationalizes the usage of the remaining global IPv4 addresses during the transition period by sharing a single IPv4 address with multiple users. A typical DS-Lite scenario is the delivery of an IPv4 service to an IPv4 user over an IPv6 network (denoted as a 4-6-4 scenario). [RFC6333] covers unicast services exclusively.
This document specifies a generic solution for the delivery of IPv4 multicast services to IPv4 clients over an IPv6 multicast network. The solution was developed with DS-Lite in mind (see more discussion below). The solution is however not limited to DS-Lite; it can be applied in other deployment contexts such as [RFC7596][RFC7597].
If customers have to access IPv4 multicast-based services through a DS-Lite environment, Address Family Transition Router (AFTR) devices will have to process all the Internet Group Management Protocol (IGMP) Report messages [RFC2236] [RFC3376] that have been forwarded by the Customer Premises Equipment (CPE) into the IPv4-in-IPv6 tunnels. From that standpoint, AFTR devices are likely to behave as a replication point for downstream multicast traffic, and the multicast packets will be replicated for each tunnel endpoint that IPv4 receivers are connected to.
This kind of DS-Lite environment raises two major issues:
This document specifies an extension to the DS-Lite model to deliver IPv4 multicast services to IPv4 clients over an IPv6 multicast-enabled network.
This document describes a stateless translation mechanism that supports either Source Specific Multicast (SSM) or Any Source Multicast (ASM) operation. The recommendation in Section 1 of [RFC4607] is that multicast services use SSM where possible; the operation of the translation mechanism is also simplified when SSM is used, e.g., considerations for placement of the IPv6 the Rendezvous Point (RP) are no longer relevant.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC 2119 [RFC2119].
This document makes use of the following terms:
This document focuses only on the subscription to IPv4 multicast groups and the delivery of IPv4-formatted content to IPv4 receivers over an IPv6-only network. In particular, only the following case is covered:
This document does not cover the source/receiver heuristics, where IPv4 receivers can also behave as IPv4 multicast sources. This document assumes that hosts behind the mB4 are IPv4 multicast receivers only. Also, the document covers host built-in mB4 function.
In the DS-Lite specification [RFC6333], an IPv4-in-IPv6 tunnel is used to carry bidirectional IPv4 unicast traffic between a B4 and an AFTR. The solution specified in this document provides an IPv4-in-IPv6 encapsulation scheme to deliver unidirectional IPv4 multicast traffic from an mAFTR to an mB4.
An overview of the solution is provided in this section which is intended as an introduction to how it works, but is not normative. For the normative specifications of the two new functional elements: mB4 and mAFTR (Figure 1), refer to Section 6 and Section 7.
------------
/ \
| IPv4 network |
\ /
------------
IPv4 multicast : | ^ PIMv4 Join
v | :
+-------------+
| mAFTR |
+-------------+
IPv6 multicast |:| | ^ PIMv6 Join (PIMv6
(IPv4 embedded) |:| | : routers in between)
------------
/ \
| IPv6 network |
\ /
------------
|:| | ^ MLD Report
|v| | :
+-----------+
| mB4 |
+-----------+
IPv4 multicast : | ^ IGMP Report
v | :
+-----------+
| IPv4 |
| receiver |
+-----------+
Figure 1: Functional Architecture
In order to map the addresses of IPv4 multicast traffic with IPv6 multicast addresses, an IPv6 multicast prefix (mPrefix64) and an IPv6 unicast prefix (uPrefix64) are provided to the mAFTR and the mB4 elements, both of which contribute to the computation and the maintenance of the IPv6 multicast distribution tree that extends the IPv4 multicast distribution tree into the IPv6 multicast network. The IPv4/IPv6 address mapping is stateless.
The mAFTR and the mB4 use mPrefix64 to convert an IPv4 multicast address (G4) into an IPv4-embedded IPv6 multicast address (G6). The mAFTR and the mB4 use uPrefix64 to convert an IPv4 multicast source address (S4) into an IPv4-embedded IPv6 address (S6). The mAFTR and the mB4 must use the same mPrefix64 and uPrefix64, and also run the same algorithm for building IPv4-embedded IPv6 addresses. Refer to Section 5 for more details about the address mapping.
When an IPv4 receiver connected to the device that embeds the mB4 capability wants to subscribe to an IPv4 multicast group, it sends an IGMP Report message towards the mB4. The mB4 creates the IPv6 multicast group (G6) address using mPrefix64 and the original IPv4 multicast group address. If the receiver sends a source-specific IGMPv3 Report message, the mB4 will create the IPv6 source address (S6) using uPrefix64 and the original IPv4 source address.
The mB4 uses the G6 (and both S6 and G6 in SSM) to create the corresponding MLD Report message. The mB4 sends the Report message towards the MLD Querier in the IPv6 network. The MLD Querier (which usually acts as the PIMv6 Designated Router too) receives the MLD Report message and sends the PIMv6 Join to join the IPv6 multicast distribution tree. The MLD Querier can send either PIMv6 Join (*,G6) in ASM or PIMv6 Join (S6,G6) in SSM to the mAFTR.
The mAFTR acts as the IPv4 DR to which the uPrefix64-derived S6 is connected. The mAFTR will receive the source-specific PIMv6 Join message (S6,G6) from the IPv6 multicast network. If the mAFTR is the Rendezvous Point (RP) of G6, it will receive the any-source PIMv6 Join message (*,G6) from the IPv6 multicast network. If the mAFTR is not the RP of G6, it will send the PIM Register message to the RP of G6 located in the IPv6 multicast network. For the sake of simplicity, it is RECOMMENDED to configure the mAFTR as the RP for the IPv4-embedded IPv6 multicast groups it manages; no registration procedure is required under this configuration.
When the mAFTR receives the PIMv6 Join message (*,G6), it will extract the IPv4 multicast group address (G4). If the mAFTR is the RP of G4 in the IPv4 multicast network, it will create a (*,G4) entry (if such entry does not already exist) in its own IPv4 multicast routing table. If the mAFTR is not the RP of G4, it will send the corresponding PIMv4 Join message (*,G4) towards the RP of G4 in the IPv4 multicast network.
When the mAFTR receives the PIMv6 Join message (S6,G6), it will extract the IPv4 multicast group address (G4) and IPv4 source address (S4) and send the corresponding (S4,G4) PIMv4 Join message directly to the IPv4 source.
A branch of the multicast distribution tree is thus constructed, comprising both an IPv4 part (from the mAFTR upstream) and an IPv6 part (from mAFTR downstream towards the mB4).
The mAFTR advertises the route of uPrefix64 with an IPv6 Interior Gateway Protocol (IGP), so as to represent the IPv4-embedded IPv6 source in the IPv6 multicast network, and to run the Reverse Path Forwarding (RPF) check procedure on incoming multicast traffic. Injecting internal /96 routes is not problematic given the recommendation in [RFC7608] that requires that forwarding processes must be designed to process prefixes of any length up to /128.
When the mAFTR receives an IPv4 multicast packet, it will encapsulate the packet into an IPv6 multicast packet using the IPv4-embedded IPv6 multicast address as the destination address and an IPv4-embedded IPv6 unicast address as the source address. The encapsulated IPv6 multicast packet will be forwarded down the IPv6 multicast distribution tree and the mB4 will eventually receive the packet.
The IPv6 multicast network treats the IPv4-in-IPv6 encapsulated multicast packets as native IPv6 multicast packets. The IPv6 multicast routers use the outer IPv6 header to make their forwarding decisions.
When the mB4 receives the IPv6 multicast packet (to G6) derived by mPrefix64, it decapsulates it and forwards the original IPv4 multicast packet to the receivers subscribing to G4.
Note: At this point, only IPv4-in-IPv6 encapsulation is defined; however, other types of encapsulation could be defined in the future.
A dedicated IPv6 multicast prefix (mPrefix64) is provisioned to the mAFTR and the mB4. The mAFTR and the mB4 use the mPrefix64 to form an IPv6 multicast group address from an IPv4 multicast group address. The mPrefix64 can be of two types: ASM_mPrefix64 (a mPrefix64 used in ASM mode) or SSM_mPrefix64 (a mPrefix64 used in SSM mode). The mPrefix64 MUST be derived from the corresponding IPv6 multicast address space (e.g., the SSM_mPrefix64 must be in the range of multicast address space specified in [RFC4607]).
The IPv6 part of the multicast distribution tree can be seen as an extension of the IPv4 part of the multicast distribution tree. The IPv4 multicast source address MUST be mapped to an IPv6 multicast source address. An IPv6 unicast prefix (uPrefix64) is provisioned to the mAFTR and the mB4. The mAFTR and the mB4 use the uPrefix64 to form an IPv6 multicast source address from an IPv4 multicast source address as specified in [RFC6052]. The uPrefix-formed IPv6 multicast source address will represent the original IPv4 multicast source in the IPv6 multicast network. The uPrefix64 MUST be derived from the IPv6 unicast address space.
The multicast address translation MUST follow the algorithm defined in Section 5.2.
The mPrefix64 and uPrefix64 can be configured in the mB4 using a variety of methods, including an out-of-band mechanism, manual configuration, or a dedicated provisioning protocol (e.g., using DHCPv6 [I-D.ietf-softwire-multicast-prefix-option]).
The stateless translation mechanism described in Section 5 does not preclude use of Embedded-RP [RFC3956].
IPv4-embedded IPv6 multicast addresses are composed according to the following algorithm:
The IPv4 multicast addresses are extracted from the IPv4-embedded IPv6 multicast addresses according to the following algorithm:
An IPv4 source is represented in the IPv6 realm with its IPv4-converted IPv6 address [RFC6052].
The embedded IPv4 address in an IPv6 multicast address is included in the last 32 bits; therefore, dotted decimal notation can be used.
Group address mapping example:
+---------------------+--------------+----------------------------+
| mPrefix64 | IPv4 address | IPv4-Embedded IPv6 address |
+---------------------+--------------+----------------------------+
| ff0x::db8:0:0/96 | 233.252.0.1 | ff0x::db8::233.252.0.1 |
+---------------------+--------------+----------------------------+
Source address mapping example when a /96 is used:
+---------------------+--------------+----------------------------+
| uPrefix64 | IPv4 address | IPv4-Embedded IPv6 address |
+---------------------+--------------+----------------------------+
| 2001:db8::/96 | 192.0.2.33 | 2001:db8::192.0.2.33 |
+---------------------+--------------+----------------------------+
IPv4 and IPv6 addresses used in this example are derived from the IPv4 and IPv6 blocks reserved for documentation, as per [RFC6676]. The unicast IPv4 address of the above example is derived from the documentation address block defined in [RFC6890].
The IGMP-MLD Interworking Function combines the IGMP/MLD Proxying function and the address synthesizing operations. The IGMP/MLD Proxying function is specified in [RFC4605]. The address translation is stateless and MUST follow the address mapping specified in Section 5.
The mB4 performs the host portion of the MLD protocol on the upstream interface. The composition of IPv6 membership in this context is constructed through address synthesizing operations and MUST synchronize with the membership database maintained in the IGMP domain. MLD messages are forwarded natively towards the MLD Querier located upstream in the IPv6 network (i.e., the first hop IPv6 router). The mB4 also performs the router portion of the IGMP protocol on the downstream interface(s). Refer to [RFC4605] for more details.
+----------+ IGMP +-------+ MLD +---------+
| IPv4 |---------| mB4 |---------| MLD |
| Receiver | | | | Querier |
+----------+ +-------+ +---------+
Figure 2: IGMP-MLD Interworking
If SSM is deployed, the mB4 MUST construct the IPv6 source address (or retrieve the IPv4 source address) using the uPrefix64. The mB4 may create a membership database which associates the IPv4-IPv6 multicast groups with the interfaces (e.g., WLAN and Wired Ethernet) facing IPv4 multicast receivers.
When the mB4 receives an IPv6 multicast packet, it MUST check the group address and the source address. If the IPv6 multicast group prefix is mPrefix64 and the IPv6 source prefix is uPrefix64, the mB4 MUST decapsulate the IPv6 header; the decapsulated IPv4 multicast packet will be forwarded through each relevant interface following standard IPv4 multicast forwarding procedure. Otherwise, the mB4 MUST silently drop the packet.
As an illustration, if a packet is received from source 2001:db8::192.0.2.33 and needs to be forwarded to group ff3x:1000::233.252.0.1, the mB4 decapsulates it into an IPv4 multicast packet using 192.0.2.33 as the IPv4 source address and using 233.252.0.1 as the IPv4 destination multicast group.
Encapsulating IPv4 multicast packets into IPv6 multicast packets that will be forwarded by the mAFTR towards the mB4 along the IPv6 multicast distribution tree reduces the effective MTU size by the size of an IPv6 header. In this specification, the data flow is unidirectional from the mAFTR to the mB4. The mAFTR MUST fragment the oversized IPv6 packet after the encapsulation into two IPv6 packets. The mB4 MUST reassemble the IPv6 packets, decapsulate the IPv6 packet, and forward the IPv4 packet to the hosts that have subscribed to the corresponding multicast group. Further considerations about fragmentation issues are documented in [RFC6333].
If the mB4 function is implemented in the host which is directly connected to an IPv6-only network, the host MUST implement Section 6.1, Section 6.2, and Section 6.3. The host MAY optimize the implementation to provide an Application Programming Interface (API) or kernel module to skip the IGMP-MLD Interworking Function. Optimization considerations are out of scope of this specification.
When several mPrefix64s are available, if each enclosed IPv4-embedded IPv6 multicast prefix has a distinct scope, the mB4 MUST select the appropriate IPv4-embedded IPv6 multicast prefix whose scope matches the IPv4 multicast address used to synthesize an IPv4-embedded IPv6 multicast address (Section 8 of [RFC2365]).
The mB4 MAY be configured to not preserve the scope when enforcing the address translation algorithm.
Consider that an mB4 is configured with two mPrefix64s ff0e::db8:0:0/96 (Global scope) and ff08::db8:0:0/96 (Organization scope). If the mB4 receives an IGMP report from an IPv4 receiver to subscribe to 233.252.0.1, it checks which mPrefix64 to use in order to preserve the scope of the requested IPv4 multicast group. In this example, given that 233.252.0.1 is intended for global use, the mB4 creates the IPv6 multicast group (G6) address using ff0e::db8:0:0/96 and the original IPv4 multicast group address (233.252.0.1): ff0e::db8::233.252.0.1.
The mAFTR is responsible for interconnecting the IPv4 multicast distribution tree with the corresponding IPv6 multicast distribution tree. The mAFTR MUST use the uPrefix64 to build the IPv6 source addresses of the multicast group address derived from mPrefix64. In other words, the mAFTR MUST be the multicast source whose address is derived from uPrefix64.
The mAFTR MUST advertise the route towards uPrefix64 with the IPv6 IGP. This is needed by the IPv6 multicast routers so that they acquire the routing information to discover the source.
The mAFTR MUST interwork PIM Join/Prune messages for (*, G6) and (S6, G6) on their corresponding (*, G4) and (S4, G4). The following text specifies the expected behavior of the mAFTR for PIM Join messages.
+---------+
---------| mAFTR |---------
PIMv6 |uPrefix64| PIMv4
|mPreifx64|
+---------+
Figure 3: PIMv6-PIMv4 Interworking Function
The mAFTR contains two separate Tree Information Bases (TIBs): the IPv4 Tree Information Base (TIB4) and the IPv6 Tree Information Base (TIB6), which are bridged by one IPv4-in-IPv6 virtual interface. It should be noted that TIB implementations may vary (e.g., some may rely upon a single integrated TIB without any virtual interface), but they should follow this specification for the sake of global and functional consistency.
When a mAFTR receives a PIMv6 Join message (*,G6) with an IPv6 multicast group address (G6) that is derived from the mPrefix64, it MUST check its IPv6 Tree Information Base (TIB6). If there is an entry for this G6 address, it MUST check whether the interface through which the PIMv6 Join message has been received is in the outgoing interface (oif) list. If not, the mAFTR MUST add the interface to the oif list. If there is no entry in the TIB6, the mAFTR MUST create a new entry (*,G6) for the multicast group. Whether or not the IPv4-in-IPv6 virtual interface is set as the incoming interface of the newly created entry is up to the implementation but it should comply with the mAFTR's multicast data forwarding behavior, see Section 7.4.
The mAFTR MUST extract the IPv4 multicast group address (G4) from the IPv4-embedded IPv6 multicast address (G6) contained in the PIMv6 Join message. The mAFTR MUST check its IPv4 Tree Information Base (TIB4). If there is an entry for G4, it MUST check whether the IPv4-in-IPv6 virtual interface is in the outgoing interface list. If not, the mAFTR MUST add the interface to the oif list. If there is no entry for G4, the mAFTR MUST create a new (*,G4) entry in its TIB4 and initiate the procedure for building the shared tree in the IPv4 multicast network without any additional requirement.
If the mAFTR receives a source-specific Join message, the (S6, G6) is processed rather than (*,G6). The procedures of processing (S6,G6) and (*,G6) are almost the same. Differences have been detailed in [RFC7761].
When the mAFTR receives the first IPv4 multicast packet, it may extract the multicast source address (S4) from the packet and send an Explicit PIMv4 (S4,G4) Join message directly to S4. The mAFTR switches from the shared Rendezvous Point Tree (RPT) to the Shortest Path Tree (SPT) for G4.
For IPv6 multicast routers to switch to the SPT, there is no new requirement. IPv6 multicast routers may send an Explicit PIMv6 Join to the mAFTR once the first (S6,G6) multicast packet arrives from upstream multicast routers.
When the mAFTR receives an IPv4 multicast packet, it checks its TIB4 to find a matching entry and then forwards the packet to the interface(s) listed in the outgoing interface list. If the IPv4-in-IPv6 virtual interface also belongs to this list, the packet is encapsulated with the mPrefix64-derived and uPrefix64-derived IPv4-embedded IPv6 addresses to form an IPv6 multicast packet. Then another lookup is made by the mAFTR to find a matching entry in the TIB6. Whether the RPF check for the second lookup is performed or not is up to the implementation and is out of the scope of this document. The IPv6 multicast packet is then forwarded along the IPv6 multicast distribution tree, based upon the outgoing interface list of the matching entry in the TIB6.
As an illustration, if a packet is received from source 192.0.2.33 and needs to be forwarded to group 233.252.0.1, the mAFTR encapsulates it into an IPv6 multicast packet using ff3x:1000::233.252.0.1 as the IPv6 destination multicast group and using 2001:db8::192.0.2.33 as the IPv6 source address.
The Scope field of IPv4-in-IPv6 multicast addresses should be valued accordingly (e.g, to “E”, Global scope;) in the deployment environment. This specification does not discuss the scope value that should be used.
Nevertheless, when several mPrefix64s are available, if each enclosed IPv4-embedded IPv6 multicast prefix has a distinct scope, the mAFTR MUST select the appropriate IPv4-embedded IPv6 multicast prefix whose scope matches the IPv4 multicast address used to synthesize an IPv4-embedded IPv6 multicast address.
An mAFTR MAY be configured to not preserve the scope when enforcing the address translation algorithm.
The mAFTR can embed the MLD Querier function (as well as the PIMv6 DR) for optimization purposes. When the mB4 sends a MLD Report message to this mAFTR, the mAFTR should process the MLD Report message that contains the IPv4-embedded IPv6 multicast group address and then send the corresponding PIMv4 Join message. (Figure 4)
+---------+
---------| mAFTR |---------
MLD |uPrefix64| PIMv4
|mPreifx64|
+---------+
Figure 4: MLD-PIMv4 Interworking Function
Discussions about the location of the mAFTR capability and related ASM or SSM multicast design considerations are out of the scope of this document.
If the mAFTR is co-located with the DR connected to the original IPv4 source, it may simply use the uPrefix64 and mPrefix64 prefixes to build the IPv4-embedded IPv6 multicast packets, and the sending of PIMv4 Join messages becomes unnecessary.
For robustness and load distribution purposes, several nodes in the network can embed the mAFTR function. In such case, the same IPv6 prefixes (i.e., mPrefix64 and uPrefix64) and algorithm to build IPv4-embedded IPv6 addresses must be configured on those nodes.
The mAFTR may be configured with a list of IPv4 multicast groups and sources. Only multicast flows bound to the configured addresses should be handled by the mAFTR. Otherwise, packets are silently dropped.
To optimize the usage of network resources in current deployments, all multicast streams are conveyed in the core network while only the most popular ones are forwarded in the aggregation/access networks (static mode). Less popular streams are forwarded in the access network upon request (dynamic mode). Depending on the location of the mAFTR in the network, two modes can be envisaged: static and dynamic.
Besides multicast scoping considerations (see Section 6.5 and Section 7.5), this document does not introduce any new security concern in addition to what is discussed in Section 5 of [RFC6052], Section 10 of [RFC3810] and Section 6 of [RFC7761].
An mB4 SHOULD be provided with appropriate configuration information to preserve the scope of a multicast message when mapping an IPv4 multicast address into an IPv4-embedded IPv6 multicast address and vice versa.
The CPE that embeds the mB4 function SHOULD be configured to accept incoming MLD messages and traffic forwarded to multicast groups subscribed by receivers located in the customer premises.
The authors would like to thank Dan Wing for his guidance in the early discussions which initiated this work. We also thank Peng Sun, Jie Hu, Qiong Sun, Lizhong Jin, Alain Durand, Dean Cheng, Behcet Sarikaya, Tina Tsou, Rajiv Asati, Xiaohong Deng, and Stig Venaas for their valuable comments.
Many thanks to Ian Farrer for the review.
Thanks to Zhen Cao and Tim Chown for the INT directorate review.
This document includes no request to IANA.
IPTV generally includes two categories of service offerings:
Two types of provider are involved in the delivery of this service:
Note that some contract agreements prevent a network provider from altering the content as sent by the content provider for various reasons. Depending on these contract agreements, multicast streams should be delivered unaltered to the requesting users.
Many current IPTV contents are likely to remain IPv4-formatted and out of control of the network providers. Additionally, there are numerous legacy receivers (e.g., IPv4-only Set Top Boxes (STB)) that can't be upgraded or be easily replaced to support IPv6. As a consequence, IPv4 service continuity must be guaranteed during the transition period, including the delivery of multicast services such as Live TV Broadcasting to users.
Given the multiple versions of group membership management protocols, mismatch issues may arise at the mB4 (refer to Section 6.1).
If IGMPv2 operates on the IPv4 receivers while MLDv2 operates on the MLD Querier, or if IGMPv3 operates on the IPv4 receivers while MLDv1 operates on the MLD Querier, the version mismatch issue will be encountered. To solve this problem, the mB4 should perform the router portion of IGMP which is similar to the corresponding MLD version (IGMPv2 as of MLDv1, or IGMPv3 as of MLDv2) operating in the IPv6 domain. Then, the protocol interaction approach specified in Section 7 of [RFC3376] can be applied to exchange signaling messages with the IPv4 receivers on which the different version of IGMP is operating.