RFC6788
Internet Engineering Task Force (IETF) S. Krishnan Request for Comments: 6788 A. Kavanagh Category: Standards Track B. Varga ISSN: 2070-1721 Ericsson
S. Ooghe
Alcatel-Lucent
E. Nordmark
Cisco
November 2012
The Line-Identification Option
Abstract
In Ethernet-based aggregation networks, several subscriber premises may be logically connected to the same interface of an Edge Router. This document proposes a method for the Edge Router to identify the subscriber premises using the contents of the received Router Solicitation messages. The applicability is limited to broadband network deployment scenarios in which multiple user ports are mapped to the same virtual interface on the Edge Router.
Status of This Memo
This is an Internet Standards Track document.
This document is a product of the Internet Engineering Task Force (IETF). It represents the consensus of the IETF community. It has received public review and has been approved for publication by the Internet Engineering Steering Group (IESG). Further information on Internet Standards is available in Section 2 of RFC 5741.
Information about the current status of this document, any errata, and how to provide feedback on it may be obtained at http://www.rfc-editor.org/info/rfc6788.
Copyright Notice
Copyright (c) 2012 IETF Trust and the persons identified as the document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal 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.
3. Issues with Identifying the Subscriber Premises in an
5.3. On Receiving a Router Advertisement from the Edge Router ...9
6.1. On Receiving a Tunneled Router Solicitation from the AN ...10 6.2. On Sending a Router Advertisement Towards the End-Device ..10 6.3. Sending Periodic Unsolicited Router Advertisements
Contents
- 1 Introduction
- 2 Applicability Statement
- 3 Issues with Identifying the Subscriber Premises in an N:1 VLAN Model
- 4 Basic Operation
- 5 AN Behavior
- 6 Edge Router Behavior
- 7 Line-Identification Option (LIO)
- 8 Garbage Collection of Unused Prefixes
- 9 Interactions with Secure Neighbor Discovery
Introduction
Digital Subscriber Line (DSL) is a widely deployed access technology for Broadband Access for Next Generation Networks. While traditional DSL access networks were Point-to-Point Protocol (PPP) RFC1661 based, some networks are migrating from the traditional PPP access model into a pure IP-based Ethernet aggregated access environment. Architectural and topological models of an Ethernet aggregation network in the context of DSL aggregation are described in [TR101].
+----+ +----+ +----------+ |Host|---| RG |----| | +----+ +----+ | |
| AN |\
+----+ +----+ | | \ |Host|---| RG |----| | \ +----+ +----+ +----------+ \ +----------+
\ | |
+-------------+ | |
| Aggregation | | Edge |
| Network |-------| Router |
+-------------+ | |
/ | |
+----------+ / +----------+
| | /
+----+ +----+ | | / |Host|---| RG |----| AN |/ +----+ +----+ | |
| |
+----------+
Figure 1: Broadband Forum Network Architecture
One of the Ethernet and Gigabit-capable Passive Optical Network (GPON) aggregation models specified in this document bridges sessions from multiple user ports behind a DSL Access Node (AN), also referred to as a Digital Subscriber Line Access Multiplexer (DSLAM), into a single VLAN in the aggregation network. This is called the N:1 VLAN allocation model.
+----------+
| |
| |
| AN |\
| | \
| | \ VLANx
+----------+ \ +----------+
\ | |
+-------------+ | |
| Aggregation | VLANx | Edge |
| Network |-------| Router |
+-------------+ | |
/ | |
+----------+ / +----------+
| | / VLANx
| | /
| AN |/
| |
| |
+----------+
Figure 2: n:1 VLAN model
Terminology
1:1 VLAN A broadband network deployment scenario in
which each user port is mapped to a different
VLAN on the Edge Router. The uniqueness of
the mapping is maintained in the Access Node
and across the aggregation network.
N:1 VLAN A broadband network deployment scenario in
which multiple user ports are mapped to the
same VLAN on the Edge Router. The user ports
may be located in the same or different Access
Nodes.
GPON Gigabit-capable Passive Optical Network is an
optical access network that has been
introduced into the Broadband Forum
architecture in [TR156].
AN A DSL or a GPON Access Node. The Access Node
terminates the physical layer (e.g., DSL
termination function or GPON termination
function), may physically aggregate other
nodes implementing such functionality, or may
perform both functions at the same time. This
node contains at least one standard Ethernet
interface that serves as its "northbound"
interface into which it aggregates traffic
from several user ports or Ethernet-based
"southbound" interfaces. It does not
implement an IPv6 stack but performs some
limited inspection/modification of IPv6
packets. The IPv6 functions required on the
Access Node are described in Section 5 of
[TR177].
Aggregation Network The part of the network stretching from the
Access Nodes to the Edge Router. In the
context of this document, the aggregation
network is considered to be Ethernet based,
providing standard Ethernet interfaces at the
edges, for connecting the Access Nodes and the
broadband network. It is comprised of
Ethernet switches that provide very limited IP
functionality (e.g., IGMP snooping, Multicast
Listener Discovery (MLD) snooping, etc.).
RG A residential gateway device. It can be a
Layer-3 (routed) device or a Layer-2 (bridged)
device. The residential gateway for Broadband
Forum networks is defined in [TR124].
Edge Router The Edge Router, also known as the Broadband
Network Gateway (BNG), is the first IPv6 hop
for the user. In cases where the RG is
bridged, the BNG acts as the default router
for the hosts behind the RG. In cases where
the RG is routed, the BNG acts as the default
router for the RG itself. This node
implements IPv6 router functionality.
Host A node that implements IPv6 host
functionality.
End-Device A node that sends Router Solicitations and
processes received Router Advertisements.
When a Layer-3 (L3) RG is used, it is
considered an end-device in the context of
this document. When a Layer-2 (L2) RG is
used, the host behind the RG is considered to
be an end-device in the context of this
document.
Conventions Used in This Document
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 RFC2119.
Applicability Statement
The Line-Identification Option (LIO) is intended to be used only for the N:1 VLAN deployment model. For the other VLAN deployment models, line identification can be achieved differently. The mechanism described in this document allows the connection of hosts that only support IPv6 stateless address auto-configuration to attach to networks that use the N:1 VLAN deployment model.
When the Dynamic Host Configuration Protocol (DHCP) RFC3315 is used for IPv6 address assignment, it has the side-effect of providing end- device-initiated reliability as well as inactivity detection. The reliability is provided by the end-device continuing to retransmit DHCP messages until it receives a response), and inactivity is detected by the end-device not renewing its DHCP lease. The "IPv6 Stateless Address Autoconfiguration" protocol RFC4862 was not designed to satisfy such requirements [RSDA]. While this option improves the reliability of operation in deployments that use Router Solicitations rather than DHCP, there are some limitations as specified below.
The mechanism described in this document deals with the loss of subscriber-originated Router Solicitations (RSes) by initiating RSes at the AN, which improves robustness over solely relying on the end-device's few initial retransmissions of RSes.
However, the AN retransmissions imply that some information (e.g., the subscriber's MAC address) that was obtained by the Edge Router from subscriber-originated RSes may no longer be available. For example, since there is no L2 frame received from the subscriber in case of an RS sent by an AN, the L2-address information of the end-device cannot be determined. One piece of L2-address information currently used in some broadband networks is the MAC address. For
this reason, the solution described in this document is NOT RECOMMENDED for networks that require the MAC address of the endpoint for identification.
There is no indication when a subscriber is no longer active. Thus, this protocol cannot be used to automatically reclaim resources, such as prefixes, that are associated with an active subscriber. See Section 8. Thus, this protocol is NOT RECOMMENDED for networks that require automatic notification when a subscriber is no longer active.
This mechanism by itself provides no protection against the loss of RS-induced state in access routers that would lead to loss of IPv6 connectivity for end-devices. Given that regular IPv6 hosts do not have RS retransmission behavior that would allow automatic recovery from such a failure, this mechanism SHOULD only be used in deployments employing N:1 VLANs.
Issues with Identifying the Subscriber Premises in an N:1 VLAN Model
In a DSL- or GPON-based fixed broadband network, IPv6 end-devices are connected to an AN. Today, these end-devices will typically send a Router Solicitation message to the Edge Router, to which the Edge Router responds with a Router Advertisement message. The Router Advertisement typically contains a prefix that the end-devices will use to automatically configure an IPv6 address. Upon sending the Router Solicitation message, the node connecting the end-device on the access circuit, typically an AN, forwards the RS to the Edge Router upstream over a switched network. In such Ethernet-based aggregation networks, several subscriber premises may be connected to the same interface of an Edge Router (e.g., on the same VLAN). However, the Edge Router requires some information to identify the end-device on the circuit. To accomplish this, the AN needs to add line-identification information to the Router Solicitation message and forward this to the Edge Router. This is analogous to the case where DHCP is being used, and the line-identification information is inserted by a DHCP relay agent RFC3315. This document proposes a method for the Edge Router to identify the subscriber premises using the contents of the received Router Solicitation messages. Note that there might be several end-devices located on the same subscriber premises.
Basic Operation
This document uses a mechanism that tunnels Neighbor Discovery (ND) packets inside another IPv6 packet that uses a destination option (Line-ID option) to convey line-identification information as depicted in Figure 3. The use of the Line-ID option in any other IPv6 datagrams, including untunneled RS and RA messages, is not
defined by this document. The ND packets are left unmodified inside the encapsulating IPv6 packet. In particular, the Hop Limit field of the ND message is not decremented when the packet is being tunneled. This is because an ND message whose Hop Limit is not 255 will be discarded by the receiver of such messages, as described in Sections 6.1.1 and 6.1.2 of RFC4861.
+----+ +----+ +-----------+
|Host| | AN | |Edge Router|
+----+ +----+ +-----------+
| RS | |
|---------->| |
| | |
| |Tunneled RS(LIO)|
| |--------------->|
| | |
| |Tunneled RA(LIO)|
| |<---------------|
| RA | |
|<----------| |
| | |
Figure 3: Basic Message Flow
AN Behavior
On Initialization
On initialization, the AN MUST join the All-BBF-Access-Nodes multicast group on all its upstream interfaces towards the Edge Router.
On Receiving a Router Solicitation from the End-Device
When an end-device sends out a Router Solicitation, it is received by the AN. The AN identifies these messages by looking for ICMPv6 messages (IPv6 Next Header value of 58) with ICMPv6 type 133. The AN intercepts and then tunnels the received Router Solicitation in a newly created IPv6 datagram with the Line-Identification Option (LIO). The AN forms a new IPv6 datagram whose payload is the received Router Solicitation message as described in RFC2473, except that the Hop Limit field of the Router Solicitation message MUST NOT be decremented. If the AN has an IPv6 address, it MUST use this address in the Source Address field of the outer IPv6 datagram. Otherwise, the AN MUST copy the source address from the received Router Solicitation into the Source Address field of the outer IPv6 datagram. The destination address of the outer IPv6 datagram MUST be
copied from the destination address of the tunneled RS. The AN MUST include a destination options header between the outer IPv6 header and the payload. It MUST insert an LIO destination option and set the Line ID field of the option to contain the circuit identifier corresponding to the logical access loop port of the AN from which the RS was initiated.
On Receiving a Router Advertisement from the Edge Router
When the Edge Router sends out a tunneled Router Advertisement in response to the RS, it is received by the AN. If there is an LIO present, the AN MUST use the line-identification data of the LIO to identify the subscriber agent circuit of the AN on which the RA should be sent. The AN MUST then remove the outer IPv6 header of this tunneled RA and multicast the inner packet (the original RA) on this specific subscriber circuit.
Identifying Tunneled Router Advertisements
The AN can identify tunneled RAs by installing filters based on the destination address (All-BBF-Access-Nodes, which is a reserved link-local scoped multicast address) of the outer packets and the presence of a destination option header with an LIO destination option.
On Detecting a Subscriber Circuit Coming Up
RSes initiated by end-devices as described in Section 5.2 may be lost due to lack of connectivity between the AN and the end-device. To ensure that the end-device will receive an RA, the AN needs to trigger the sending of periodic RAs on the Edge Router. For this purpose, the AN needs to inform the Edge Router that a subscriber circuit has come up. Each time the AN detects that a subscriber circuit has come up, it MUST create a Router Solicitation message as described in Section 6.3.7 of RFC4861. It MUST use the unspecified address as the source address of this RS. It MUST then tunnel this RS towards the Edge Router as described in Section 5.2.
In case there are connectivity issues between the AN and the Edge Router, the RSes initiated by the AN can be lost. The AN SHOULD continue retransmitting the Router Solicitations following the algorithm described in Section 5.6 for a given LIO until it receives an RA for that specific LIO.
On Detecting Edge Router Failure
When the Edge Router reboots and loses state or is replaced by a new Edge Router, the AN will detect it using connectivity check mechanisms that are already in place in broadband networks (e.g., Bidirectional Forwarding Detection). When such Edge Router failure is detected, the AN needs to start transmitting RSes for each of its subscriber circuits that have come up, as described in Section 5.4.
RS Retransmission Algorithm
The AN SHOULD use the exponential backoff algorithm for retransmits that is described in Section 14 of RFC3315 in order to continuously retransmit the Router Solicitations for a given LIO until a response is received for that specific LIO. The AN SHOULD use the following variables as input to the retransmission algorithm:
Initial retransmission time (IRT) 1 Second Maximum retransmission time (MRT) 30 Seconds Maximum retransmission count (MRC) 0 Maximum retransmission duration (MRD) 0
Edge Router Behavior
On Receiving a Tunneled Router Solicitation from the AN
When the Edge Router receives a tunneled Router Solicitation forwarded by the AN, it needs to check if there is an LIO destination option present in the outer datagram. The Edge Router can use the contents of the Line ID field to lookup the addressing information and policy that need to be applied to the line from which the Router Solicitation was received. The Edge Router MUST then process the inner RS message as specified in RFC4861.
On Sending a Router Advertisement Towards the End-Device
When the Edge Router sends out a Router Advertisement in response to a tunneled RS that included an LIO, it MUST tunnel the Router Advertisement in a newly created IPv6 datagram with the LIO as described below. First, the Edge Router creates the Router Advertisement message as described in Section 6.2.3 of RFC4861. The Edge Router MUST include a Prefix Information option in this RA that contains the prefix that corresponds to the received LIO. (The LIO from the received tunneled RS is usually passed on from the Edge Router to some form of provisioning system that returns the prefix to be included in the RA. It could e,g., be based on RADIUS.) Then, the Edge Router forms the new IPv6 datagram whose payload is the Router Advertisement message, as described in RFC2473, except that
the Hop Limit field of the Router Advertisement message MUST NOT be decremented. The Edge router MUST use a link-local IPv6 address on the outgoing interface in the Source Address field of the outer IPv6 datagram. The Edge Router MUST include a destination options header between the outer IPv6 header and the payload. It MUST insert an LIO and set the Line ID field of the option to contain the same value as that of the Line-ID option in the received RS. The IPv6 destination address of the inner RA MUST be set to the all-nodes multicast address.
If the Source Address field of the received IPv6 datagram was not the unspecified address, the Edge Router MUST copy this address into the Destination Address field of the outer IPv6 datagram sent back towards the AN. The link-layer destination address of the outer IPv6 datagram containing the outer IPv6 datagram MUST be resolved using regular Neighbor Discovery procedures.
If the Source Address field of the received IPv6 datagram was the unspecified address, the destination address of the outer IPv6 datagram MUST be set to the well-known link-local scope All-BBF-Access-Nodes multicast address (ff02::10). The link-layer destination address of the tunneled RA MUST be set to the unicast link-layer address of the AN that sent the tunneled Router Solicitation that is being responded to.
The Edge Router MUST ensure that it does not transmit tunneled RAs whose size is larger than the MTU of the link between the Edge Router and the AN, which would require that the outer IPv6 datagram undergo fragmentation. This limitation is imposed because the AN may not be capable of handling the reassembly of such fragmented datagrams.
Sending Periodic Unsolicited Router Advertisements Towards the
End-Device
After sending a tunneled Router Advertisement as specified in Section 6.2 in response to a received RS, the Edge Router MUST store the mapping between the LIO and the prefixes contained in the Router Advertisement. It should then initiate periodic sending of unsolicited Router Advertisements as described in Section 6.2.3. of RFC4861 . The Router Advertisements MUST be created and tunneled as described in Section 6.2. The Edge Router MAY stop sending Router Advertisements if it receives a notification from the AN that the subscriber circuit has gone down. This notification can be received out-of-band using a mechanism such as the Access Node Control Protocol (ANCP). Please consult Section 8 for more details.
Line-Identification Option (LIO)
The Line-Identification Option (LIO) is a destination option that can be included in IPv6 datagrams that tunnel Router Solicitation and Router Advertisement messages. The use of the Line-ID option in any other IPv6 datagrams is not defined by this document. Multiple Line- ID destination options MUST NOT be present in the same IPv6 datagram. The LIO has no alignment requirement.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Option Type | Option Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | LineIDLen | Line ID... +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 4: Line-Identification Option Layout
Option Type
8-bit identifier of the type of option. The option identifier for the Line-Identification Option (0x8C) has been allocated by the IANA.
Option Length
8-bit unsigned integer. The length of the option (excluding the Option Type and Option Length fields). The value MUST be greater than 0.
LineIDLen
8-bit unsigned integer. The length of the Line ID field in number of octets.
Line ID
Variable-length data inserted by the AN describing the subscriber-agent circuit identifier corresponding to the logical access loop port of the AN from which the RS was initiated. The line identification MUST be unique across all the ANs that share a link to the Edge Router, e.g., one such line- identification scheme is described in Section 3.9 of [TR101]. The line identification should be encoded as specified in Section 7.1.
Encoding of the Line ID Field Content
This IPv6 Destination option is derived from an existing widely deployed DHCPv6 option RFC4649, which is in turn derived from a widely deployed DHCPv4 option RFC3046. These options derive from and cite the basic DHCP options specification RFC2132. These widely deployed DHCP options use the Network Virtual Terminal (NVT) character set RFC2132 RFC0020. Since the data carried in the Line-ID option is used in the same manner by the provisioning systems as the DHCP options, it is beneficial for it to maintain the same encoding as the DHCP options.
The IPv6 Line ID option contains a description that identifies the line using only character positions (decimal 32 to decimal 126, inclusive) of the US-ASCII character set [X3.4] RFC0020. Consistent with RFC2132, RFC3046, and RFC4649, the Line ID field SHOULD NOT contain the US-ASCII NUL character (decimal 0). However, implementations receiving this option MUST NOT fail merely because an ASCII NUL character is (erroneously) present in the Line ID field.
Some existing widely deployed implementations of Edge Routers and ANs that support the previously mentioned DHCP option only support US-ASCII and strip the high-order bit from any 8-bit characters entered by the device operator. The previously mentioned DHCP options do not support 8-bit character sets either. Therefore, for compatibility with the installed base and to maximize interoperability, the high-order bit of each octet in this field MUST be set to zero by any device inserting this option in an IPv6 packet.
Consistent with RFC3046 and RFC4649, this option always uses binary comparison. Therefore, two Line IDs MUST be equal when they match when compared byte-by-byte. Line-ID A and Line-ID B match byte-by-byte when (1) A and B have the same number of bytes, and (2) for all byte indexes P in A: the value of A at index P has the same binary value as the value of B at index P.
Two Line IDs MUST NOT be equal if they do not match byte-by-byte. For example, an IPv6 Line-ID option containing "f123" is not equal to a Line-ID option "F123".
Intermediate systems MUST NOT alter the contents of the Line ID.
Garbage Collection of Unused Prefixes
Following the mechanism described in this document, the broadband network associates a prefix to a subscriber line based on the LIO. Even when the subscriber line goes down temporarily, this prefix stays allocated to that specific subscriber line, i.e., the prefix is not returned to the unused pool. When a subscriber line no longer needs a prefix, the prefix can be reclaimed by manual action dissociating the prefix from the LIO in the backend systems.
Interactions with Secure Neighbor Discovery
Since the RS/RA packets that are protected by the "SEcure Neighbor Discovery (SEND)" RFC3971 are not modified in any way by the mechanism described in this document, there are no issues with SEND verification.
10. Acknowledgements
The authors would like to thank Margaret Wasserman, Mark Townsley, David Miles, John Kaippallimalil, Eric Levy-Abegnoli, Thomas Narten, Olaf Bonness, Thomas Haag, Wojciech Dec, Brian Haberman, Ole Troan, Hemant Singh, Jari Arkko, Joel Halpern, Bob Hinden, Ran Atkinson, Glen Turner, Kathleen Moriarty, David Sinicrope, Dan Harkins, Stephen Farrell, Barry Leiba, Sean Turner, Ralph Droms, and Mohammed Boucadair for reviewing this document and suggesting changes.
11. Security Considerations
The line identification information inserted by the AN or the Edge Router is not protected. This means that this option may be modified, inserted, or deleted without being detected. In order to ensure validity of the contents of the Line ID field, the network between the AN and the Edge Router needs to be trusted.
12. IANA Considerations
This document defines a new IPv6 destination option for carrying line identification. IANA has assigned the following new destination option type in the "Destination Options and Hop-by-Hop Options" registry maintained at <http://www.iana.org/assignments/ipv6-parameters>:
0x8C Line-Identification Option RFC6788
The act bits for this option are 10 and the chg bit is 0.
Per this document, IANA has also allocated the following well-known link-local scope multicast address from the "IPv6 Multicast Address Space Registry" located at <http://www.iana.org/assignments/ipv6-multicast-addresses/>:
FF02:0:0:0:0:0:0:10 All-BBF-Access-Nodes RFC6788
13. References
13.1. Normative References
RFC1661 Simpson, W., Ed., "The Point-to-Point Protocol (PPP)", STD
51, RFC 1661, July 1994.
RFC2119 Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
RFC2473 Conta, A. and S. Deering, "Generic Packet Tunneling in
IPv6 Specification", RFC 2473, December 1998.
RFC3315 Droms, R., Ed., Bound, J., Volz, B., Lemon, T., Perkins,
C., and M. Carney, "Dynamic Host Configuration Protocol
for IPv6 (DHCPv6)", RFC 3315, July 2003.
RFC3971 Arkko, J., Ed., Kempf, J., Zill, B., and P. Nikander,
"SEcure Neighbor Discovery (SEND)", RFC 3971, March 2005.
RFC4861 Narten, T., Nordmark, E., Simpson, W., and H. Soliman,
"Neighbor Discovery for IP version 6 (IPv6)", RFC 4861, September 2007.
RFC4862 Thomson, S., Narten, T., and T. Jinmei, "IPv6 Stateless
Address Autoconfiguration", RFC 4862, September 2007.
[TR101] Broadband Forum, "Migration to Ethernet-based DSL
aggregation", <http://www.broadband-forum.org/ technical/download/TR-101.pdf>.
[TR124] Broadband Forum, "Functional Requirements for Broadband
Residential Gateway Devices",
<http://www.broadband-forum.org/technical/
download/TR-124_Issue-2.pdf>.
[TR156] Broadband Forum, "Using GPON Access in the context of
TR-101", <http://www.broadband-forum.org/ technical/download/TR-156.pdf>.
[TR177] Broadband Forum, "IPv6 in the context of TR-101",
<www.broadband-forum.org/technical/download/TR-177.pdf>.
[X3.4] American National Standards Institute, "American Standard
Code for Information Interchange (ASCII)", Standard X3.4,
1968.
13.2. Informative References
RFC0020 Cerf, V., "ASCII format for network interchange", RFC 20,
October 1969.
RFC2132 Alexander, S. and R. Droms, "DHCP Options and BOOTP Vendor
Extensions", RFC 2132, March 1997.
RFC3046 Patrick, M., "DHCP Relay Agent Information Option", RFC
3046, January 2001.
RFC4649 Volz, B., "Dynamic Host Configuration Protocol for IPv6
(DHCPv6) Relay Agent Remote-ID Option", RFC 4649, August 2006.
[RSDA] Dec, W., "IPv6 Router Solicitation Driven Access
Considered Harmful", Work in Progress, June 2011.
Authors' Addresses
Suresh Krishnan Ericsson 8400 Blvd Decarie Town of Mount Royal, Quebec Canada
EMail: [email protected]
Alan Kavanagh Ericsson 8400 Blvd Decarie Town of Mount Royal, Quebec Canada
EMail: [email protected]
Balazs Varga Ericsson Konyves Kalman krt. 11. B. 1097 Budapest Hungary
EMail: [email protected]
Sven Ooghe Alcatel-Lucent Copernicuslaan 50 2018 Antwerp, Belgium
Phone: EMail: [email protected]
Erik Nordmark Cisco 510 McCarthy Blvd. Milpitas, CA, 95035 USA
Phone: +1 408 527 6625 EMail: [email protected]
