RFC 8658 | A+P RADIUS Attributes | October 2019 |
Jiang, et al. | Standards Track | [Page] |
IPv4-over-IPv6 transition mechanisms provide IPv4 connectivity services over IPv6 native networks during the IPv4/IPv6 coexistence period. DHCPv6 options have been defined to configure clients for Lightweight 4over6, Mapping of Address and Port with Encapsulation (MAP-E), Mapping of Address and Port using Translation (MAP-T) unicast softwire mechanisms, and multicast softwires. However, in many networks, configuration information is stored in an Authentication, Authorization, and Accounting (AAA) server, which utilizes the Remote Authentication Dial In User Service (RADIUS) protocol to provide centralized management for users. When a new transition mechanism is developed, new RADIUS attributes need to be defined correspondingly.¶
This document defines new RADIUS attributes to carry softwire configuration parameters based on Address plus Port from a AAA server to a Broadband Network Gateway. Both unicast and multicast attributes are covered.¶
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 7841.¶
Information about the current status of this document, any errata, and how to provide feedback on it may be obtained at https://www.rfc-editor.org/info/rfc8658.¶
Copyright (c) 2019 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 (https://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.¶
Providers have started deploying and transitioning to IPv6. Several IPv4 service continuity mechanisms based on Address plus Port (A+P) [RFC6346] have been proposed for providing unicast IPv4-over-IPv6-only infrastructure, such as Mapping of Address and Port with Encapsulation (MAP-E) [RFC7597], Mapping of Address and Port using Translation (MAP-T) [RFC7599], and Lightweight 4over6 [RFC7596]. Also, [RFC8114] specifies a generic solution for the delivery of IPv4 multicast services to IPv4 clients over an IPv6 multicast network. For each of these mechanisms, DHCPv6 options have been specified for client configuration.¶
In many networks, user configuration information is stored in an Authentication, Authorization, and Accounting (AAA) server. AAA servers generally communicate using the Remote Authentication Dial In User Service (RADIUS) [RFC2865] protocol. In a fixed broadband network, a Broadband Network Gateway (BNG) acts as the access gateway for users. That is, the BNG acts as both a AAA client to the AAA server and a DHCPv6 server for DHCPv6 messages sent by clients. Throughout this document, the term "BNG" describes a device implementing both the AAA client and DHCPv6 server functions.¶
Since IPv4-in-IPv6 softwire configuration information is stored in a AAA server and user configuration information is mainly transmitted through DHCPv6 between the BNGs and Customer Premises Equipment (CEs, a.k.a., CPE), new RADIUS attributes are needed to propagate the information from the AAA servers to BNGs so that they can be provided to CEs using the existing DHCPv6 options.¶
The RADIUS attributes defined in this document provide the configuration to populate the corresponding DHCPv6 options for unicast and multicast softwire configurations, specifically:¶
The contents of the attributes defined in this document have a 1:1 mapping into the fields of the various DHCPv6 options in [RFC7598], [RFC8026], and [RFC8115]. Table 1 shows how the DHCPv6 options map to the corresponding RADIUS attribute. For detailed mappings between each DHCPv6 option field and the corresponding RADIUS attribute or field, see Appendix A.¶
DHCPv6 Option | RADIUS Attribute |
---|---|
OPTION_S46_RULE (89) | Softwire46-Rule |
OPTION_S46_BR (90) | Softwire46-BR |
OPTION_S46_DMR (91) | Softwire46-DMR |
OPTION_S46_V4V6BIND (92) | Softwire46-V4V6Bind |
OPTION_S46_PORTPARAMS (93) | Softwire46-PORTPARAMS |
OPTION_S46_PRIORITY (111) | Softwire46-Priority |
OPTION_V6_PREFIX64 (113) | Softwire46-Multicast |
A RADIUS attribute for Dual-Stack Lite [RFC6333] is defined in [RFC6519].¶
This document targets deployments where a trusted relationship is in place between the RADIUS client and server.¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
The reader should be familiar with the concepts and terms defined in [RFC7596], [RFC7597], [RFC7599], and [RFC8026].¶
The terms "multicast Basic Bridging BroadBand" element (mB4) and "multicast Address Family Transition Router" element (mAFTR) are defined in [RFC8114].¶
Softwire46 (S46) is used throughout to denote any of the IPv4-in-IPv6 softwire mechanisms listed above. Additionally, the following abbreviations are used within the document:¶
This section defines the following attributes:¶
Softwire46-Configuration Attribute (Section 3.1):¶
This attribute carries the configuration information for MAP-E, MAP-T, and Lightweight 4over6. The configuration information for each Softwire46 mechanism is carried in the corresponding Softwire46 attributes. Different attributes are required for each Softwire46 mechanism.¶
Softwire46-Priority Attribute (Section 3.2):¶
Depending on the deployment scenario, a client may support several different Softwire46 mechanisms. Therefore, a client may request configuration for more than one Softwire46 mechanism at a time. The Softwire46-Priority Attribute contains information allowing the client to prioritize which mechanism to use, corresponding to OPTION_S46_PRIORITY defined in [RFC8026].¶
Softwire46-Multicast Attribute (Section 3.3):¶
This attribute conveys the IPv6 prefixes to be used in [RFC8114] to synthesize IPv4-embedded IPv6 addresses. The BNG uses the IPv6 prefixes returned in the RADIUS Softwire46-Multicast Attribute to populate the DHCPv6 PREFIX64 Option [RFC8115].¶
All of these attributes are allocated from the RADIUS "Extended Type" code space per [RFC6929].¶
All of these attribute designs follow [RFC6158] and [RFC6929].¶
This document adheres to the guidance in [RFC8044] for defining new RADIUS attributes.¶
This attribute is of type "tlv", as defined in "Remote Authentication Dial-In User Service (RADIUS) Protocol Extensions" [RFC6929]. It contains some sub-attributes, with the following requirements:¶
The Softwire46-Configuration Attribute is structured as follows:¶
Contains one or more of the following attributes. Each attribute type may appear once at most:¶
The Softwire46-Configuration Attribute is associated with the following identifier: 241.9.¶
The Softwire46 attributes can only be encapsulated in the Softwire46-Configuration Attribute. Depending on the deployment scenario, a client might request more than one transition mechanism at a time. There MUST be at least one Softwire46 attribute encapsulated in one Softwire46-Configuration Attribute. There MUST be at most one instance of each type of Softwire46 attribute encapsulated in one Softwire46-Configuration Attribute.¶
There are three types of Softwire46 attributes, namely:¶
Each type of Softwire46 attribute contains a number of sub-attributes, defined in Section 3.1.3. The hierarchy of the Softwire46 attributes is shown in Figure 1. Section 3.1.2 describes which sub-attributes are mandatory, optional, or not permitted for each defined Softwire46 attribute.¶
The Softwire46-MAP-E attribute is designed to carry the configuration information for MAP-E. The structure of Softwire46-MAP-E is shown below:¶
Contains a set of sub-attributes, with the following requirements:¶
It MUST contain Softwire46-Rule, defined in Section 3.1.3.1.¶
It MUST contain Softwire46-BR, defined in Section 3.1.3.2.¶
It MAY contain Softwire46-PORTPARAMS, defined in Section 3.1.3.5.¶
The Softwire46-MAP-T attribute is designed to carry the configuration information for MAP-T. The structure of Softwire46-MAP-T is shown below:¶
Contains a set of sub-attributes, with the following requirements:¶
It MUST contain Softwire46-Rule, defined in Section 3.1.3.1.¶
It MUST contain Softwire46-DMR, defined in Section 3.1.3.3.¶
It MAY contain Softwire46-PORTPARAMS, defined in Section 3.1.3.5.¶
The Softwire46-Lightweight-4over6 attribute is designed to carry the configuration information for Lightweight 4over6. The structure of Softwire46-Lightweight-4over6 is shown below:¶
Contains a set of sub-attributes as follows:¶
It MUST contain Softwire46-BR, defined in Section 3.1.3.2.¶
It MUST contain Softwire46-V4V6Bind, defined in Section 3.1.3.4.¶
It MAY contain Softwire46-PORTPARAMS, defined in Section 3.1.3.5.¶
Table 2 shows which encapsulated sub-attributes are mandatory, optional, or not permitted for each defined Softwire46 attribute.¶
Sub-attributes | MAP-E | MAP-T | Lightweight 4over6 |
---|---|---|---|
Softwire46-BR | 1+ | 0 | 1+ |
Softwire46-Rule | 1 | 1 | 0 |
Softwire46-DMR | 0 | 1 | 0 |
Softwire46-V4V6Bind | 0 | 0 | 1 |
Softwire46-PORTPARAMS | 0-1 | 0-1 | 0-1 |
The following list defines the meaning of the Table 2 entries.¶
Softwire46-Rule can only be encapsulated in Softwire46-MAP-E (Section 3.1.1.1) or Softwire46-MAP-T (Section 3.1.1.2). Depending on the deployment scenario, one Basic Mapping Rule (BMR) and zero or more Forwarding Mapping Rules (FMRs) MUST be included in Softwire46-MAP-E and Softwire46-MAP-T.¶
Each type of Softwire46-Rule also contains a number of sub-attributes, including Rule-IPv6-Prefix, Rule-IPv4-Prefix, and EA-Length. The structure of the sub-attributes for Softwire46-Rule is defined in Section 3.1.4.¶
Defining multiple TLV types achieves the same design goals as the "Softwire46 Rule Flags" defined in Section 4.1 of [RFC7598]. Using a TLV type set to 5 is equivalent to setting the F flag in the OPTION_S46_RULE S46 Rule Flags field.¶
4 Basic Mapping Rule only (not to be used for forwarding)¶
5 Forwarding Permitted Mapping Rule¶
This field contains a set of attributes as follows:¶
Softwire46-BR can only be encapsulated in Softwire46-MAP-E (Section 3.1.1.1) or Softwire46-Lightweight-4over6 (Section 3.1.1.3).¶
There MUST be at least one Softwire46-BR included in each Softwire46-MAP-E or Softwire46-Lightweight-4over6.¶
The structure of Softwire46-BR is shown below:¶
Softwire46-DMR may only appear in Softwire46-MAP-T (Section 3.1.1.2). There MUST be exactly one Softwire46-DMR included in one Softwire46-MAP-T.¶
The structure of Softwire46-DMR is shown below:¶
Softwire46-V4V6Bind may only be encapsulated in Softwire46-Lightweight-4over6 (Section 3.1.1.3). There MUST be exactly one Softwire46-V4V6Bind included in each Softwire46-Lightweight-4over6.¶
The structure of Softwire46-V4V6Bind is shown below:¶
This field contains a set of attributes as follows:¶
Softwire46-PORTPARAMS is optional. It is used to specify port set information for IPv4 address sharing between clients. Softwire46-PORTPARAMS MAY be included in any of the Softwire46 attributes.¶
The structure of Softwire46-PORTPARAMS is shown below:¶
This field contains a set of attributes as follows:¶
There are two types of Softwire46-Rule: the Basic Mapping Rule and the Forwarding Mapping Rule, indicated by the value in the TLV-Type field of Softwire46-Rule (Section 3.1.3.1).¶
Each type of Softwire46-Rule also contains a number of sub-attributes as detailed in the following subsections.¶
Rule-IPv6-Prefix is REQUIRED for every Softwire46-Rule. There MUST be exactly one Rule-IPv6-Prefix encapsulated in each type of Softwire46-Rule.¶
Rule-IPv6-Prefix follows the framed IPv6 prefix designed in [RFC3162] and [RFC8044].¶
The structure of Rule-IPv6-Prefix is shown below:¶
This attribute is used to convey the MAP Rule IPv4 prefix. The structure of Rule-IPv4-Prefix is shown below:¶
This attribute is used to convey the Embedded Address (EA) bit length. The structure of EA-Length is shown below:¶
The IPv4-Address MAY be used to specify the full or shared IPv4 address of the CE.¶
The structure of IPv4-Address is shown below:¶
The Bind-IPv6-Prefix is used by the CE to identify the correct IPv6 prefix to be used as the tunnel source.¶
The structure of Bind-IPv6-Prefix is shown below:¶
This attribute is used to convey the Port Set Identifier offset as defined in [RFC7597]. This attribute is encoded in 32 bits as per the recommendation in Appendix A.2.1 of [RFC6158].¶
The structure of PSID-Offset is shown below:¶
Contains the PSID-Offset (8 bits) right justified, and the unused bits in this field MUST be set to zero. This field specifies the numeric value for the Softwire46 algorithm's excluded port range/offset bits (a bits), as per Section 5.1 of [RFC7597].¶
Default values for this field are specific to the softwire mechanism being implemented and are defined in the relevant specification document.¶
This attribute is used to convey the PSID length as defined in [RFC7597]. This attribute is encoded in 32 bits as per the recommendation in Appendix A.2.1 of [RFC6158].¶
The structure of PSID-Len is shown below:¶
This attribute is used to convey the PSID as defined in [RFC7597]. This attribute is encoded in 32 bits as per the recommendation in Appendix A.2.1 of [RFC6158].¶
The structure of PSID is shown below:¶
Contains the PSID (16 bits) right justified, and the unused bits in this field MUST be set to zero.¶
The PSID value algorithmically identifies a set of ports assigned to a CE. The first k bits on the left of this 2-octet field are the PSID value. The remaining (16-k) bits on the right are padding zeros.¶
The Softwire46-Priority Attribute includes an ordered list of Softwire46 mechanisms allowing the client to prioritize which mechanism to use, corresponding to OPTION_S46_PRIORITY defined in [RFC8026]. The following requirements apply:¶
The Softwire46-Priority Attribute is structured as follows:¶
The attribute includes one or more Softwire46-Option-Code TLVs: A Softwire46-Priority Attribute MUST contain at least one Softwire46-Option-Code TLV (Section 3.2.1).¶
Softwire46 mechanisms are prioritized in the appearance order in the Softwire46-Priority Attribute. That is, the first-appearing mechanism is most preferred.¶
The Softwire46-Priority Attribute is associated with the following identifier: 241.10.¶
This attribute is used to convey an option code assigned to a Softwire46 mechanism [RFC8026]. This attribute is encoded in 32 bits as per the recommendation in Appendix A.2.1 of [RFC6158].¶
The structure of Softwire46-Option-Code is shown below:¶
The Softwire46-Multicast Attribute conveys the IPv6 prefixes to be used to synthesize multicast and unicast IPv4-embedded IPv6 addresses as per [RFC8114]. This attribute is of type "tlv" and contains additional TLVs. The following requirements apply:¶
The Softwire46-Multicast Attribute is structured as follows:¶
This field contains a set of attributes as follows:¶
The Softwire46-Multicast Attribute is associated with the following identifier: 241.11.¶
The ASM-Prefix64 attribute is structured as follows:¶
The SSM-Prefix64 attribute is structured as follows:¶
The structure of U-Prefix64 is shown below:¶
Figure 2 illustrates how the RADIUS and DHCPv6 protocols interwork to provide CE with softwire configuration information.¶
The authorization operation could be done independently after the authentication process. In this case, steps 1-5 are completed as above, then the following steps are performed:¶
In addition to the above, the following points need to be considered:¶
In some deployments, the DHCP server may use the Accounting-Request to report the softwire configuration returned to a requesting host to a AAA server. It is the responsibility of the DHCP server to ensure the consistency of the configuration provided to the requesting hosts. Reported data to a AAA server may be required for various operational purposes (e.g., regulatory).¶
A configuration change (e.g., BR address) may result in an exchange of CoA-Requests between the BNG and the AAA server, as shown in Figure 3. Concretely, when the BNG receives a CoA-Request message containing Softwire46 attributes, it sends a DHCPv6 Reconfigure message to the appropriate CE to inform that CE that an updated configuration is available. Upon receipt of such a message, the CE sends a DHCPv6 Renew or Information-Request in order to receive the updated Softwire46 configuration. In deployments where the BNG embeds a DHCPv6 relay, CoA-Requests can be used following the procedure specified in [RFC6977].¶
This document specifies three new RADIUS attributes, and their formats are as follows:¶
Table 3 describes which attributes may be found in which kinds of packets and in what quantity.¶
Request | Accept | Reject | Challenge | Acct Req | CoA-Req | # | Attribute |
---|---|---|---|---|---|---|---|
0-1 | 0-1 | 0 | 0 | 0-1 | 0-1 | 241.9 | Softwire46-Configuration |
0-1 | 0-1 | 0 | 0 | 0-1 | 0-1 | 241.10 | Softwire46-Priority |
0-1 | 0-1 | 0 | 0 | 0-1 | 0-1 | 241.11 | Softwire46-Multicast |
Section 9 of [RFC7596] discusses security issues related to Lightweight 4over6; Section 10 of [RFC7597] discusses security issues related to MAP-E; Section 13 of [RFC7599] discusses security issues related to MAP-T; and Section 9 of [RFC8114] discusses security issues related to the delivery of IPv4 multicast services to IPv4 clients over an IPv6 multicast network.¶
This document does not introduce any security issues inherently different from those already identified in Section 8 of [RFC2865] and Section 6 of [RFC5176] for CoA messages. Known security vulnerabilities of the RADIUS protocol discussed in Section 7 of [RFC2607] and Section 7 of [RFC2869] apply to this specification. These well-established properties of the RADIUS protocol place some limitations on how it can safely be used, since there is some inherent requirement to trust the counterparty to not misbehave.¶
Accordingly, this document targets deployments where a trusted relationship is in place between the RADIUS client and server, with communication optionally secured by IPsec or Transport Layer Security (TLS) [RFC6614]. The use of IPsec [RFC4301] for providing security when RADIUS is carried in IPv6 is discussed in [RFC3162].¶
Security considerations for interactions between a Softwire46 CE and the BNG are discussed in Section 9 of [RFC7598] (DHCPv6 options for the configuration of Softwire46 address and port-mapped clients), Section 3 of [RFC8026] (a DHCPv6-based Softwire46 prioritization mechanism), and Section 5 of [RFC8115] (DHCPv6 options for configuration of IPv4-embedded IPv6 prefixes).¶
IANA has made new code point assignments for RADIUS attributes as described in the following subsections. The assignments should use the RADIUS registry available at <https://www.iana.org/assignments/radius-types/>.¶
IANA has assigned the attribute types defined in this document from the RADIUS namespace as described in Section 2 (IANA Considerations) of [RFC3575], in accordance with BCP 26 [RFC8126].¶
IANA has registered three new RADIUS attributes from the "Short Extended Space" section of [RFC6929]. The attributes are the Softwire46-Configuration Attribute, Softwire46-Priority Attribute, and Softwire46-Multicast Attribute:¶
Type | Description | Data Type | Reference |
---|---|---|---|
241.9 | Softwire46-Configuration | tlv | Section 3.1 |
241.10 | Softwire46-Priority | tlv | Section 3.2 |
241.11 | Softwire46-Multicast | tlv | Section 3.3 |
IANA has created a new registry called "RADIUS Softwire46 Configuration and Multicast Attributes".¶
All attributes in this registry have one or more parent RADIUS attributes in nesting (refer to [RFC6929]).¶
This registry has been initially populated with the following values:¶
Value | Description | Data Type | Reference |
---|---|---|---|
0 | Reserved | ||
1 | Softwire46-MAP-E | tlv | Section 3.1.1.1 |
2 | Softwire46-MAP-T | tlv | Section 3.1.1.2 |
3 | Softwire46-Lightweight-4over6 | tlv | Section 3.1.1.3 |
4 | Softwire46-Rule (BMR) | tlv | Section 3.1.3.1 |
5 | Softwire46-Rule (FMR) | tlv | Section 3.1.3.1 |
6 | Softwire46-BR | ipv6addr | Section 3.1.3.2 |
7 | Softwire46-DMR | ipv6prefix | Section 3.1.3.3 |
8 | Softwire46-V4V6Bind | tlv | Section 3.1.3.4 |
9 | Softwire46-PORTPARAMS | tlv | Section 3.1.3.5 |
10 | Rule-IPv6-Prefix | ipv6prefix | Section 3.1.4.1 |
11 | Rule-IPv4-Prefix | ipv4prefix | Section 3.1.4.2 |
12 | EA-Length | integer | Section 3.1.4.3 |
13 | IPv4-Address | ipv4addr | Section 3.1.5.1 |
14 | Bind-IPv6-Prefix | ipv6prefix | Section 3.1.5.2 |
15 | PSID-Offset | integer | Section 3.1.6.1 |
16 | PSID-Len | integer | Section 3.1.6.2 |
17 | PSID | integer | Section 3.1.6.3 |
18 | Softwire46-Option-Code | integer | Section 3.2.1 |
19 | ASM-Prefix64 | ipv6prefix | Section 3.3.1 |
20 | SSM-Prefix64 | ipv6prefix | Section 3.3.2 |
21 | U-Prefix64 | ipv6prefix | Section 3.3.3 |
22-255 | Unassigned |
The registration procedure for this registry is Standards Action as defined in [RFC8126].¶
The Softwire46-Priority Attribute conveys an ordered list of option codes assigned to Softwire46 mechanisms, for which IANA has created and will maintain a new registry titled "Option Codes Permitted in the Softwire46-Priority Attribute".¶
Table 6 shows the initial version of allowed option codes and the Softwire46 mechanisms that they represent. The option code for DS-Lite is derived from the IANA-allocated RADIUS Attribute Type value for DS-Lite [RFC6519]. The option codes for MAP-E, MAP-T, and Lightweight 4over6 are the TLV-Type values for the MAP-E, MAP-T, and Lightweight 4over6 attributes defined in Section 3.1.1.¶
Option Code | Softwire46 Mechanism | Reference |
---|---|---|
1 | MAP-E | [RFC7597] |
2 | MAP-T | [RFC7599] |
3 | Lightweight 4over6 | [RFC7596] |
144 | DS-Lite | [RFC6519] |
Additional option codes may be added to this list in the future using the IETF Review process described in Section 4.8 of [RFC8126].¶
The following sections detail the mappings between the softwire DHCPv6 option fields and the relevant RADIUS attributes as defined in this document.¶
OPTION_S46_RULE Field | Softwire46-Rule Name | TLV Subfield |
---|---|---|
flags | N/A | TLV-type (4, 5) |
ea-len | EA-Length | EA-len |
prefix4-len | Rule-IPv4-Prefix | Prefix-Length |
ipv4-prefix | Rule-IPv4-Prefix | rule-ipv4-prefix |
prefix6-len | Rule-IPv6-Prefix | Prefix-Length |
ipv6-prefix | Rule-IPv6-Prefix | rule-ipv6-prefix |
OPTION_S46_BR Field | Softwire46-BR Subfield |
---|---|
br-ipv6-address | br-ipv6-address |
OPTION_S46_DMR Field | Softwire46-DMR Subfield |
---|---|
dmr-prefix6-len | dmr-prefix6-len |
dmr-ipv6-prefix | dmr-ipv6-prefix |
OPTION_S46_V4V6BIND Field | Softwire46-V4V6Bind Name | TLV Subfield |
---|---|---|
ipv4-address | IPv4-Address | ipv4-address |
bindprefix6-len | Bind-IPv6-Prefix | Prefix-Length |
bind-ipv6-prefix | Bind-IPv6-Prefix | bind-ipv6-prefix |
OPTION_S46_PORTPARAMS Field | Softwire46-PORTPARAMS Name | TLV Subfield |
---|---|---|
offset | PSID-Offset | PSID-Offset |
PSID-len | PSID-Len | PSID-len |
PSID | PSID | PSID |
OPTION_S46_PRIORITY Field | Softwire46-Priority Attribute Subfield |
---|---|
s46-option-code | Softwire46-option-code |
OPTION_V6_PREFIX64 Field | Softwire46-Multicast Attribute TLV Name | TLV Subfield |
---|---|---|
asm-length | ASM-Prefix64 | Prefix-Length |
ASM_mPrefix64 | ASM-Prefix64 | asm-prefix64 |
ssm-length | SSM-Prefix64 | Prefix-Length |
SSM_mPrefix64 | SSM-Prefix64 | ssm-prefix64 |
unicast-length | U-Prefix64 | Prefix-Length |
uPrefix64 | U-Prefix64 | u-prefix64 |
The authors would like to thank Peter Lothberg, Wojciech Dec, Ian Farrer, Suresh Krishnan, Qian Wang, Wei Meng, Cui Wang, Alan Dekok, Stefan Winter, and Yu Tianpeng for their valuable comments regarding this document.¶
This document was merged with [LIGHTWEIGHT-4OVER6] and [RADIUS-EXT]. Thanks to everyone who contributed to this document.¶
Many thanks to Al Morton, Bernie Volz, Joel Halpern, and Donald Eastlake for the review.¶
Bing Liu Huawei Technologies Co., Ltd. China Email: leo.liubing@huawei.com¶
Peter Deacon IEA Software, Inc. United States of America Email: peterd@iea-software.com¶
Qiong Sun China Telecom China Email: sunqiong@ctbri.com.cn¶
Qi Sun Tsinghua University China Email: sunqibupt@gmail.com¶
Cathy Zhou Huawei Technologies China Email: cathy.zhou@huawei.com¶
Tina Tsou Huawei Technologies (USA) United States of America Email: Tina.Tsou.Zouting@huawei.com¶
ZiLong Liu Tsinghua University China Email: liuzilong8266@126.com¶
Yong Cui Tsinghua University China Email: yong@csnet1.cs.tsinghua.edu.cn¶