rfc9288.original   rfc9288.txt 
opsec F. Gont Internet Engineering Task Force (IETF) F. Gont
Internet-Draft EdgeUno Request for Comments: 9288 SI6 Networks
Intended status: Informational W. Liu Category: Informational W. Liu
Expires: 4 November 2022 Huawei Technologies ISSN: 2070-1721 Huawei Technologies
3 May 2022 August 2022
Recommendations on the Filtering of IPv6 Packets Containing IPv6 Recommendations on the Filtering of IPv6 Packets Containing IPv6
Extension Headers at Transit Routers Extension Headers at Transit Routers
draft-ietf-opsec-ipv6-eh-filtering-10
Abstract Abstract
This document analyzes the security implications of IPv6 Extension This document analyzes the security implications of IPv6 Extension
Headers and associated IPv6 options. Additionally, it discusses the Headers and associated IPv6 options. Additionally, it discusses the
operational and interoperability implications of discarding packets operational and interoperability implications of discarding packets
based on the IPv6 Extension Headers and IPv6 options they contain. based on the IPv6 Extension Headers and IPv6 options they contain.
Finally, it provides advice on the filtering of such IPv6 packets at Finally, it provides advice on the filtering of such IPv6 packets at
transit routers for traffic not directed to them, for those cases transit routers for traffic not directed to them, for those cases
where such filtering is deemed as necessary. where such filtering is deemed as necessary.
Status of This Memo Status of This Memo
This Internet-Draft is submitted in full conformance with the This document is not an Internet Standards Track specification; it is
provisions of BCP 78 and BCP 79. published for informational purposes.
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 https://datatracker.ietf.org/drafts/current/.
Internet-Drafts are draft documents valid for a maximum of six months This document is a product of the Internet Engineering Task Force
and may be updated, replaced, or obsoleted by other documents at any (IETF). It represents the consensus of the IETF community. It has
time. It is inappropriate to use Internet-Drafts as reference received public review and has been approved for publication by the
material or to cite them other than as "work in progress." Internet Engineering Steering Group (IESG). Not all documents
approved by the IESG are candidates for any level of Internet
Standard; see Section 2 of RFC 7841.
This Internet-Draft will expire on 4 November 2022. 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/rfc9288.
Copyright Notice Copyright Notice
Copyright (c) 2022 IETF Trust and the persons identified as the Copyright (c) 2022 IETF Trust and the persons identified as the
document authors. All rights reserved. document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents (https://trustee.ietf.org/ Provisions Relating to IETF Documents
license-info) in effect on the date of publication of this document. (https://trustee.ietf.org/license-info) in effect on the date of
Please review these documents carefully, as they describe your rights publication of this document. Please review these documents
and restrictions with respect to this document. Code Components carefully, as they describe your rights and restrictions with respect
extracted from this document must include Revised BSD License text as to this document. Code Components extracted from this document must
described in Section 4.e of the Trust Legal Provisions and are include Revised BSD License text as described in Section 4.e of the
provided without warranty as described in the Revised BSD License. Trust Legal Provisions and are provided without warranty as described
in the Revised BSD License.
Table of Contents Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2 1. Introduction
2. Terminology and Assumptions Employed in This Document . . . . 4 2. Terminology and Assumptions Employed in This Document
2.1. Terminology . . . . . . . . . . . . . . . . . . . . . . . 4 2.1. Terminology
2.2. Applicability Statement . . . . . . . . . . . . . . . . . 4 2.2. Applicability Statement
2.3. Router Default Behavior and Features . . . . . . . . . . 4 2.3. Router Default Behavior and Features
3. IPv6 Extension Headers . . . . . . . . . . . . . . . . . . . 5 3. IPv6 Extension Headers
3.1. General Discussion . . . . . . . . . . . . . . . . . . . 5 3.1. General Discussion
3.2. General Security Implications . . . . . . . . . . . . . . 6 3.2. General Security Implications
3.3. Rationale for Our Advice on the Handling of IPv6 Packets 3.3. Rationale for Our Advice on the Handling of IPv6 Packets
with Specific IPv6 Extension Headers . . . . . . . . . . 6 with Specific IPv6 Extension Headers
3.4. Summary of Advice on the Handling of IPv6 Packets with 3.4. Summary of Advice on the Handling of IPv6 Packets with
Specific IPv6 Extension Headers . . . . . . . . . . . . . 6 Specific IPv6 Extension Headers
3.5. Advice on the Handling of IPv6 Packets with Specific IPv6 3.5. Advice on the Handling of IPv6 Packets with Specific IPv6
Extension Headers . . . . . . . . . . . . . . . . . . . . 7 Extension Headers
3.6. Advice on the Handling of Packets with Unknown IPv6 3.6. Advice on the Handling of Packets with Unknown IPv6
Extension Headers . . . . . . . . . . . . . . . . . . . . 16 Extension Headers
4. IPv6 Options . . . . . . . . . . . . . . . . . . . . . . . . 17 4. IPv6 Options
4.1. General Discussion . . . . . . . . . . . . . . . . . . . 17 4.1. General Discussion
4.2. General Security Implications of IPv6 Options . . . . . . 17 4.2. General Security Implications of IPv6 Options
4.3. Summary of Advice on the Handling of IPv6 Packets with 4.3. Summary of Advice on the Handling of IPv6 Packets with
Specific IPv6 Extension Headers . . . . . . . . . . . . . 18 Specific IPv6 Options
4.4. Advice on the Handling of Packets with Specific IPv6 4.4. Advice on the Handling of Packets with Specific IPv6
Options . . . . . . . . . . . . . . . . . . . . . . . . . 19 Options
4.5. Advice on the handling of Packets with Unknown IPv6 4.5. Advice on the Handling of Packets with Unknown IPv6 Options
Options . . . . . . . . . . . . . . . . . . . . . . . . . 32 5. IANA Considerations
5. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 32 6. Privacy Considerations
6. Privacy Considerations . . . . . . . . . . . . . . . . . . . 32 7. Security Considerations
7. Security Considerations . . . . . . . . . . . . . . . . . . . 32 8. References
8. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 33 8.1. Normative References
9. References . . . . . . . . . . . . . . . . . . . . . . . . . 33 8.2. Informative References
9.1. Normative References . . . . . . . . . . . . . . . . . . 33 Acknowledgements
9.2. Informative References . . . . . . . . . . . . . . . . . 37 Authors' Addresses
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 39
1. Introduction 1. Introduction
IPv6 Extension Headers (EHs) allow for the extension of the IPv6 IPv6 Extension Headers (EHs) allow for the extension of the IPv6
protocol, and provide support for core functionality such as IPv6 protocol and provide support for core functionality, such as IPv6
fragmentation. However, common implementation limitations suggest fragmentation. However, common implementation limitations suggest
that EHs present a challenge for IPv6 packet routing equipment, that EHs present a challenge for IPv6 packet routing equipment,
particularly when the IPv6 header chain needs to be processed for particularly when the IPv6 header chain needs to be processed for, as
e.g. enforcing ACLs or implementing other functions [RFC9098]. an example, enforcing Access Control Lists (ACLs) or implementing
other functions [RFC9098].
Several studies (e.g. [Huston-2022], [I-D.vyncke-v6ops-james], and Several studies (e.g., [Huston-2022], [JAMES], and [RFC7872]) suggest
[RFC7872]) suggest that there is widespread dropping of IPv6 packets that there is widespread dropping of IPv6 packets that contain IPv6
that contain IPv6 Extension Headers (EHs). In some cases, such EHs. In some cases, such packet drops occur at transit routers.
packet drops occur at transit routers. While some operators are While some operators are known to intentionally drop packets that
known to intentionally drop packets that contain IPv6 EHs, it is contain IPv6 EHs, it is possible that some of the measured packet
possible that some of the measured packet drops are the result of drops are the result of inappropriate advice in this area.
inappropriate advice in this area.
This document analyzes both the general security implications of IPv6 This document analyzes both the general security implications of IPv6
EHs, as well as the security implications of specific EH and Option EHs, as well as the security implications of specific EH and option
types. It also provides advice on the filtering of IPv6 packets types. It also provides advice on the filtering of IPv6 packets
based on the IPv6 EHs and the IPv6 options they contain. Since based on the IPv6 EHs and the IPv6 options they contain. Since
various protocols may use IPv6 EHs (possibly with IPv6 options), various protocols may use IPv6 EHs (possibly with IPv6 options),
discarding packets based on the IPv6 EHs or IPv6 options they contain discarding packets based on the IPv6 EHs or IPv6 options they contain
can have implications on the proper functioning of such protocols. can have implications on the proper functioning of such protocols.
Thus, this document also attempts to discuss the operational and Thus, this document also attempts to discuss the operational and
interoperability implications of such filtering policies. interoperability implications of such filtering policies.
The resulting packet filtering policy typically depends on where in The resulting packet filtering policy typically depends on where in
the network such policy is enforced: when the policy is enforced in a the network such policy is enforced. When the policy is enforced in
transit network, the policy typically follows a "deny-list" approach, a transit network, the policy typically follows a "deny-list"
where only packets with clear negative implications are dropped. On approach, where only packets with clear negative implications are
the other hand, when the policy is enforced closer to the destination dropped. On the other hand, when the policy is enforced closer to
systems, the policy typically follows an "accept-list" approach, the destination systems, the policy typically follows an "accept-
where only traffic that is expected to be received is allowed. The list" approach, where only traffic that is expected to be received is
advice in this document is aimed only at transit routers that may allowed. The advice in this document is aimed only at transit
need to enforce a filtering policy based on the EHs and IPv6 options routers that may need to enforce a filtering policy based on the IPv6
a packet may contain, following a "deny-list" approach, and hence is EHs and IPv6 options a packet may contain, following a "deny-list"
likely to be much more permissive than a filtering policy to be approach; hence, it is likely to be much more permissive than a
employed at e.g. the edge of an enterprise network. The advice in filtering policy to be employed at, for example, the edge of an
this document is meant to improve the current situation of the enterprise network. The advice in this document is meant to improve
dropping of packets with IPv6 EHs in the Internet [RFC7872] in such the current situation of the dropping of packets with IPv6 EHs in the
cases where packets are being dropped due to inappropriate or missing Internet [RFC7872] in such cases where packets are being dropped due
guidelines. to inappropriate or missing guidelines.
This document is similar in nature to [RFC7126], which addresses the This document is similar in nature to [RFC7126], which addresses the
same problem for the IPv4 case. However, in IPv6, the problem space same problem for the IPv4 case. However, in IPv6, the problem space
is compounded by the fact that IPv6 specifies a number of IPv6 EHs, is compounded by the fact that IPv6 specifies a number of IPv6 EHs
and a number of IPv6 options which may be valid only when included in and a number of IPv6 options that may be valid only when included in
specific EH types. specific EH types.
This document completes and complements the considerations for This document completes and complements the considerations for
protecting the control plane from packets containing IP options that protecting the control plane from packets containing IP options that
can be found in [RFC6192]. can be found in [RFC6192].
Section 2 specifies the terminology and conventions employed Section 2 specifies the terminology and conventions employed
throughout this document. Section 3 discusses IPv6 EHs and provides throughout this document. Section 3 discusses IPv6 EHs and provides
advice in the area of filtering IPv6 packets that contain such IPv6 advice in the area of filtering IPv6 packets that contain such IPv6
EHs. Section 4 discusses IPv6 options and provides advice in the EHs. Section 4 discusses IPv6 options and provides advice in the
area of filtering IPv6 packets that contain such options. area of filtering IPv6 packets that contain such options.
2. Terminology and Assumptions Employed in This Document 2. Terminology and Assumptions Employed in This Document
2.1. Terminology 2.1. Terminology
The terms "permit" (allow the traffic), "drop" (drop with no The terms "permit" (allow the traffic), "drop" (drop with no
notification to sender), and "reject" (drop with appropriate notification to sender), and "reject" (drop with appropriate
notification to sender) are employed as defined in [RFC3871]. notification to sender) are employed as defined in [RFC3871].
Throughout this document we also employ the term "discard" as a Throughout this document, we also employ the term "discard" as a
generic term to indicate the act of discarding a packet, irrespective generic term to indicate the act of discarding a packet, irrespective
of whether the sender is notified of such drops, and irrespective of of whether the sender is notified of such a drop and whether the
whether the specific filtering action is logged. specific filtering action is logged.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in BCP "OPTIONAL" in this document are to be interpreted as described in
14 [RFC2119] [RFC8174] when, and only when, they appear in all BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all
capitals, as shown here. capitals, as shown here.
2.2. Applicability Statement 2.2. Applicability Statement
This document provides advice on the filtering of IPv6 packets with This document provides advice on the filtering of IPv6 packets with
EHs at transit routers for traffic not explicitly destined to them, EHs at transit routers for traffic not explicitly destined to them,
for cases in which such filtering is deemed as necessary. for cases in which such filtering is deemed as necessary.
2.3. Router Default Behavior and Features 2.3. Router Default Behavior and Features
This document assumes that nodes comply with the requirements in This document assumes that nodes comply with the requirements in
[RFC7045]. Namely, [RFC7045]. Namely,
"If a forwarding node discards a packet containing a standard IPv6 | If a forwarding node discards a packet containing a standard IPv6
extension header, it MUST be the result of a configurable policy | extension header, it MUST be the result of a configurable policy
and not just the result of a failure to recognise such a header. | and not just the result of a failure to recognise such a header.
This means that the discard policy for each standard type of | This means that the discard policy for each standard type of
extension header MUST be individually configurable. The default | extension header MUST be individually configurable. The default
configuration SHOULD allow all standard extension headers." | configuration SHOULD allow all standard extension headers.
The advice provided in this document is only meant to guide an The advice provided in this document is only meant to guide an
operator in configuring forwarding devices, and is not to be operator in configuring forwarding devices and is not to be
interpreted as advice regarding default configuration settings for interpreted as advice regarding default configuration settings for
network devices. That is, this document provides advice with respect network devices. That is, this document provides advice with respect
to operational policies, but does not change the implementation to operational policies but does not change the implementation
defaults required by [RFC7045]. defaults required by [RFC7045].
We recommend that configuration options are made available to govern We recommend that configuration options be made available to govern
the processing of each IPv6 EH type and each IPv6 option type. Such the processing of each IPv6 EH type and each IPv6 Option Type. Such
configuration options should include the following possible settings: configuration options should include the following possible settings:
* Permit this IPv6 EH or IPv6 Option type. * Permit this IPv6 EH or IPv6 Option Type.
* Drop packets containing this IPv6 EH or option type. * Drop packets containing this IPv6 EH or IPv6 Option Type.
* Reject packets containing this IPv6 EH or option type (where the * Reject packets containing this IPv6 EH or IPv6 Option Type (where
packet drop is signaled with an ICMPv6 error message). the packet drop is signaled with an ICMPv6 error message).
* Rate-limit traffic containing this IPv6 EH or option type. * Rate-limit traffic containing this IPv6 EH or IPv6 Option Type.
* Ignore this IPv6 EH or option type (as if it was not present) and * Ignore this IPv6 EH or IPv6 Option Type (as if it was not
process the packet according the rules for the remaining headers. present), and process the packet according the rules for the
We note that if a packet carries forwarding information (e.g., in remaining headers. We note that if a packet carries forwarding
an IPv6 Routing Header) this might be an inappropriate or information (e.g., in an IPv6 Routing Header (RH)), this might be
undesirable action. an inappropriate or undesirable action.
We note that special care needs to be taken when devices log packet We note that special care needs to be taken when devices log packet
drops/rejects. Devices should count the number of packets dropped/ drops/rejects. Devices should count the number of packets dropped/
rejected, but the logging of drop/reject events should be limited so rejected, but the logging of drop/reject events should be limited so
as to not overburden device resources. as to not overburden device resources.
Finally, we note that when discarding packets, it is generally Finally, we note that when discarding packets, it is generally
desirable that the sender be signaled of the packet drop, since this desirable that the sender be signaled of the packet drop, since this
is of use for trouble-shooting purposes. However, throughout this is of use for trouble-shooting purposes. However, throughout this
document (when recommending that packets be discarded) we generically document (when recommending that packets be discarded), we
refer to the action as "discard" without specifying whether the generically refer to the action as "discard" without specifying
sender is signaled of the packet drop. whether the sender is signaled of the packet drop.
3. IPv6 Extension Headers 3. IPv6 Extension Headers
3.1. General Discussion 3.1. General Discussion
IPv6 [RFC8200] EHs allow for the extension of the IPv6 protocol. IPv6 EHs [RFC8200] allow for the extension of the IPv6 protocol.
Since both IPv6 EHs and upper-layer protocols share the same Since both IPv6 EHs and upper-layer protocols share the same
namespace ("Next Header" registry/namespace), [RFC7045] identifies namespace ("Next Header" registry/namespace), [RFC7045] identifies
which of the currently assigned Internet Protocol numbers identify which of the currently assigned Internet Protocol numbers identify
IPv6 EHs vs. upper-layer protocols. This document discusses the IPv6 EHs vs. upper-layer protocols. This document discusses the
filtering of packets based on the IPv6 EHs (as specified by filtering of packets based on the IPv6 EHs (as specified by
[RFC7045]) they contain. [RFC7045]) they contain.
NOTE: [RFC8200] specifies that non-fragmented IPv6 datagrams and [RFC8200] specifies that non-fragmented IPv6 datagrams and IPv6
IPv6 First-Fragments must contain the entire IPv6 header chain First-Fragments must contain the entire IPv6 header chain [RFC7112].
[RFC7112]. Therefore, intermediate systems can enforce the Therefore, intermediate systems can enforce the filtering policies
filtering policies discussed in this document, or resort to simply discussed in this document or resort to simply discarding the
discarding the offending packets when they fail to comply with the offending packets when they fail to include the entire IPv6 header
requirements in [RFC8200]. We note that, in order to implement chain [RFC8200].
filtering rules on the fast path, it may be necessary for the
filtering device to limit the depth into the packet that can be We note that in order to implement filtering rules on the fast path,
inspected before giving up. In circumstances where such a it may be necessary for the filtering device to limit the depth into
limitation exists, it is recommended that implementations provide the packet that can be inspected before giving up. In circumstances
a configuration option that specifies whether to discard packets where such a limitation exists, it is recommended that
if the aforementioned limit is encountered. Operators may then implementations provide a configuration option that specifies whether
determine according to their own circumstances how such packets to discard packets if the aforementioned limit is encountered.
will be handled. Operators may then determine, according to their own circumstances,
how such packets will be handled.
3.2. General Security Implications 3.2. General Security Implications
In some device architectures, IPv6 packets that contain IPv6 EHs can In some device architectures, IPv6 packets that contain IPv6 EHs can
cause the corresponding packets to be processed on the slow path, and cause the corresponding packets to be processed on the slow path and,
hence may be leveraged for the purpose of Denial of Service (DoS) hence, may be leveraged for the purpose of Denial-of-Service (DoS)
attacks [RFC9098] [Cisco-EH] [FW-Benchmark]. attacks [RFC9098] [Cisco-EH] [FW-Benchmark].
Operators are urged to consider the IPv6 EH and IPv6 options handling Operators are urged to consider the IPv6 EH and IPv6 options handling
capabilities of their devices as they make deployment decisions in capabilities of their devices as they make deployment decisions in
the future. the future.
3.3. Rationale for Our Advice on the Handling of IPv6 Packets with 3.3. Rationale for Our Advice on the Handling of IPv6 Packets with
Specific IPv6 Extension Headers Specific IPv6 Extension Headers
* IPv6 Packets with IPv6 Extension Headers (or options) that are not * IPv6 packets with IPv6 Extension Headers (or options) that are not
expected to traverse transit routers should be dropped. expected to traverse transit routers should be dropped.
* IPv6 Packets with IPv6 Extension Headers (or options) that are * IPv6 packets with IPv6 Extension Headers (or options) that are
only expected to traverse transit routers when a specific only expected to traverse transit routers when a specific
technology is employed, should be permitted (or dropped) based on technology is employed should be permitted (or dropped) based on
the knowledge regarding the use of such technology in transit the knowledge regarding the use of such technology in the transit
provider in question (i.e. permit the packets if the technology is provider in question (i.e., permit the packets if the technology
employed, or drop them) is employed, or drop them).
* IPv6 Packets with IPv6 Extension Headers (or options) that * IPv6 packets with IPv6 Extension Headers (or options) that
represent a concrete attack vector to network infrastructure represent a concrete attack vector to network infrastructure
devices should be dropped. devices should be dropped.
* IPv6 packets with any other IPv6 Extension headers (or options) * IPv6 packets with any other IPv6 Extension Headers (or options)
should be permitted. This is an intentional trade-off made to should be permitted. This is an intentional trade-off made to
minimize ossification. minimize ossification.
3.4. Summary of Advice on the Handling of IPv6 Packets with Specific 3.4. Summary of Advice on the Handling of IPv6 Packets with Specific
IPv6 Extension Headers IPv6 Extension Headers
This section summarizes the advice provided in Section 3.5, providing This section summarizes the advice provided in Section 3.5, providing
references to the specific sections in which a detailed analysis can references to the specific sections in which a detailed analysis can
be found. be found.
+=========================+==========================+===========+ +=====================+=========================+===========+
| EH type | Filtering policy | Reference | | EH Type | Filtering Policy | Reference |
+=========================+==========================+===========+ +=====================+=========================+===========+
| IPv6 Hop-by-Hop Options | Drop or Ignore | Section | | Hop-by-Hop Options | Drop or Ignore | Section |
| (Proto=0) | | 3.5.1 | | Header (Proto=0) | | 3.5.1 |
+-------------------------+--------------------------+-----------+ +---------------------+-------------------------+-----------+
| Routing Header for IPv6 | Drop only RHT0 and RHT1. | Section | | Routing Header | Drop only Routing Type | Section |
| (Proto=43) | Permit other RH Types | 3.5.2 | | (Proto=43) | 0, Routing Type 1, and | 3.5.2 |
+-------------------------+--------------------------+-----------+ | | Routing Type 3. Permit | |
| Fragment Header for | Permit | Section | | | other Routing Types | |
| IPv6 (Proto=44) | | 3.5.3 | +---------------------+-------------------------+-----------+
+-------------------------+--------------------------+-----------+ | Fragment Header | Permit | Section |
| Encapsulating Security | Permit | Section | | (Proto=44) | | 3.5.3 |
| Payload (Proto=50) | | 3.5.4 | +---------------------+-------------------------+-----------+
+-------------------------+--------------------------+-----------+ | Encapsulating | Permit | Section |
| Authentication Header | Permit | Section | | Security Payload | | 3.5.4 |
| (Proto=51) | | 3.5.5 | | (Proto=50) | | |
+-------------------------+--------------------------+-----------+ +---------------------+-------------------------+-----------+
| Destination Options for | Permit | Section | | Authentication | Permit | Section |
| IPv6 (Proto=60) | | 3.5.6 | | Header (Proto=51) | | 3.5.5 |
+-------------------------+--------------------------+-----------+ +---------------------+-------------------------+-----------+
| Mobility Header | Permit | Section | | Destination Options | Permit | Section |
| (Proto=135) | | 3.5.7 | | Header(Proto=60) | | 3.5.6 |
+-------------------------+--------------------------+-----------+ +---------------------+-------------------------+-----------+
| Host Identity Protocol | Permit | Section | | Mobility Header | Permit | Section |
| (Proto=139) | | 3.5.8 | | (Proto=135) | | 3.5.7 |
+-------------------------+--------------------------+-----------+ +---------------------+-------------------------+-----------+
| Shim6 Protocol | Permit | Section | | Host Identity | Permit | Section |
| (Proto=140) | | 3.5.9 | | Protocol | | 3.5.8 |
+-------------------------+--------------------------+-----------+ | (Proto=139) | | |
| Use for experimentation | Drop | Section | +---------------------+-------------------------+-----------+
| and testing (Proto=253 | | 3.5.10 | | Shim6 Protocol | Permit | Section |
| and 254) | | | | (Proto=140) | | 3.5.9 |
+-------------------------+--------------------------+-----------+ +---------------------+-------------------------+-----------+
| Use for | Drop | Section |
| experimentation and | | 3.5.10 |
| testing (Proto=253 | | |
| and 254) | | |
+---------------------+-------------------------+-----------+
Table 1: Summary of Advice on the Handling of IPv6 Packets Table 1: Summary of Advice on the Handling of IPv6
with Specific IPv6 Extension Headers Packets with Specific IPv6 Extension Headers
3.5. Advice on the Handling of IPv6 Packets with Specific IPv6 3.5. Advice on the Handling of IPv6 Packets with Specific IPv6
Extension Headers Extension Headers
3.5.1. IPv6 Hop-by-Hop Options (Protocol Number=0) 3.5.1. IPv6 Hop-by-Hop Options (Protocol Number=0)
3.5.1.1. Uses 3.5.1.1. Uses
The Hop-by-Hop Options header is used to carry optional information The Hop-by-Hop (HBH) Options header is used to carry optional
that may be examined by every node along a packet's delivery path. information that may be examined by every node along a packet's
It is expected that nodes will examine the Hop-by-Hop Options header delivery path. It is expected that nodes will examine the Hop-by-Hop
if explicitly configured to do so. Options header if explicitly configured to do so.
NOTE: A previous revision of the IPv6 core specification, [RFC2460], | NOTE: A previous revision of the IPv6 core specification
originally required that all nodes examined and processed the Hop-by- | [RFC2460] originally required all nodes to examine and process
Hop Options header. However, even before the publication of | the Hop-by-Hop Options header. However, even before the
[RFC8200] a number of implementations already provided the option of | publication of [RFC8200], a number of implementations already
ignoring this header unless explicitly configured to examine it. | provided the option of ignoring this header unless explicitly
| configured to examine it.
3.5.1.2. Specification 3.5.1.2. Specification
This EH is specified in [RFC8200]. As of May 2022, the following This EH is specified in [RFC8200]. As of May 2022, the following
options have been specified for the Hop-by-Hop Options EH: options have been specified for the Hop-by-Hop Options header:
* Type 0x00: Pad1 [RFC8200] * Type 0x00: Pad1 [RFC8200]
* Type 0x01: PadN [RFC8200] * Type 0x01: PadN [RFC8200]
* Type 0x05: Router Alert [RFC2711] * Type 0x05: Router Alert [RFC2711]
* Type 0x07: CALIPSO [RFC5570] * Type 0x07: CALIPSO [RFC5570]
* Type 0x08: SMF_DPD [RFC6621] * Type 0x08: SMF_DPD [RFC6621]
skipping to change at page 8, line 42 skipping to change at line 375
* Type 0x23: RPL Option [RFC9008] * Type 0x23: RPL Option [RFC9008]
* Type 0x26: Quick-Start [RFC4782] * Type 0x26: Quick-Start [RFC4782]
* Type 0x4D: (Deprecated) * Type 0x4D: (Deprecated)
* Type 0x63: RPL Option [RFC6553] * Type 0x63: RPL Option [RFC6553]
* Type 0x6D: MPL Option [RFC7731] * Type 0x6D: MPL Option [RFC7731]
* Type 0x8A: Endpoint Identification (Deprecated) * Type 0x8A: Endpoint Identification (Deprecated) [NIMROD-EID]
[draft-ietf-nimrod-eid]
* Type 0xC2: Jumbo Payload [RFC2675] * Type 0xC2: Jumbo Payload [RFC2675]
* Type 0xEE: IPv6 DFF Header [RFC6971] * Type 0xEE: IPv6 DFF Header [RFC6971]
* Type 0x1E: RFC3692-style Experiment [RFC4727] * Type 0x1E: RFC3692-style Experiment [RFC4727]
* Type 0x3E: RFC3692-style Experiment [RFC4727] * Type 0x3E: RFC3692-style Experiment [RFC4727]
* Type 0x5E: RFC3692-style Experiment [RFC4727] * Type 0x5E: RFC3692-style Experiment [RFC4727]
* Type 0x7E: RFC3692-style Experiment [RFC4727] * Type 0x7E: RFC3692-style Experiment [RFC4727]
* Type 0x9E: RFC3692-style Experiment [RFC4727] * Type 0x9E: RFC3692-style Experiment [RFC4727]
* Type 0xBE: RFC3692-style Experiment [RFC4727] * Type 0xBE: RFC3692-style Experiment [RFC4727]
* Type 0xDE: RFC3692-style Experiment [RFC4727] * Type 0xDE: RFC3692-style Experiment [RFC4727]
* Type 0xFE: RFC3692-style Experiment [RFC4727] * Type 0xFE: RFC3692-style Experiment [RFC4727]
3.5.1.3. Specific Security Implications 3.5.1.3. Specific Security Implications
Legacy nodes that process this extension header might be subject to Legacy nodes that process this extension header might be subject to
Denial of Service attacks. DoS attacks.
NOTE: While [RFC8200] has removed this requirement, the deployed base | NOTE: While [RFC8200] has removed the requirement for all nodes
may still reflect the classical behavior for a while, and hence the | to examine and process the Hop-by-Hop Options header, the
potential security problems of this EH are still of concern. | deployed base may still reflect the legacy [RFC2460] behavior
| for a while; hence, the potential security problems of this EH
| are still of concern.
3.5.1.4. Operational and Interoperability Impact if Blocked 3.5.1.4. Operational and Interoperability Impact If Blocked
Discarding packets containing a Hop-by-Hop Options EH would break any Discarding packets containing a Hop-by-Hop Options header would break
of the protocols that rely on it for proper functioning. For any of the protocols that rely on it for proper functioning. For
example, it would break RSVP [RFC2205] and multicast deployments, and example, it would break RSVP [RFC2205] and multicast deployments and
would cause IPv6 jumbograms to be discarded. would cause IPv6 jumbograms to be discarded.
3.5.1.5. Advice 3.5.1.5. Advice
Nodes implementing [RFC8200] would already ignore this extension Nodes implementing [RFC8200] would already ignore this extension
header unless explicitly required to process it. For legacy header unless explicitly required to process it. For legacy nodes
([RFC2460]) nodes, the recommended configuration for the processing [RFC2460], the recommended configuration for the processing of these
of these packets depends on the features and capabilities of the packets depends on the features and capabilities of the underlying
underlying platform, the configuration of the platform, and also the platform, the configuration of the platform, and also the deployment
deployment environment of the platform. On platforms that allow environment of the platform. On platforms that allow the forwarding
forwarding of packets with HBH Options on the fast path, we recommend of packets with IPv6 HBH Options headers on the fast path, we
that packets with a HBH Options EH be forwarded as normal. recommend that packets with IPv6 HBH Options headers be forwarded as
Otherwise, on platforms in which processing of packets with a IPv6 normal. Otherwise, on platforms in which the processing of packets
HBH Options EH is carried out in the slow path, and an option is with IPv6 HBH Options headers is carried out in the slow path and an
provided to rate-limit these packets, we recommend that this option option is provided to rate-limit these packets, we recommend that
be selected. Finally, when packets containing a HBH Options EH are this option be selected. Finally, when packets containing IPv6 HBH
processed in the slow-path, and the underlying platform does not have Options headers are processed in the slow path and the underlying
any mitigation options available for attacks based on these packets, platform does not have any mitigation options available for attacks
we recommend that such platforms discard packets containing IPv6 HBH based on these packets, we recommend that such platforms discard
Options EHs. packets containing IPv6 HBH Options headers.
Finally, we note that RPL (Routing Protocol for Low-Power and Lossy Finally, we note that the Routing Protocol for Low-Power and Lossy
Networks) routers [RFC6550] must not discard packets based on the Networks (RPL) routers [RFC6550] must not discard packets based on
presence of an IPv6 Hop-by-Hop Options EH, as this would break RPL. the presence of an IPv6 Hop-by-Hop Options header, as this would
break the RPL.
3.5.2. Routing Header for IPv6 (Protocol Number=43) 3.5.2. Routing Header (Protocol Number=43)
3.5.2.1. Uses 3.5.2.1. Uses
The Routing header is used by an IPv6 source to list one or more The Routing Header is used by an IPv6 source to list one or more
intermediate nodes to be "visited" on the way to a packet's intermediate nodes to be "visited" on the way to a packet's
destination. destination.
3.5.2.2. Specification 3.5.2.2. Specification
This EH is specified in [RFC8200]. [RFC2460] had originally This EH is specified in [RFC8200]. The Routing Type 0 had originally
specified the Routing Header Type 0, which was later obsoleted by been specified in [RFC2460] and was later obsoleted by [RFC5095];
[RFC5095], and thus removed from [RFC8200]. thus, it was removed from [RFC8200].
At of May 2022, the following Routing Types have been specified: As of May 2022, the following Routing Types have been specified:
* Type 0: Source Route (DEPRECATED) [RFC2460] [RFC5095] * Type 0: Source Route (DEPRECATED) [RFC2460] [RFC5095]
* Type 1: Nimrod (DEPRECATED) * Type 1: Nimrod (DEPRECATED)
* Type 2: Type 2 Routing Header [RFC6275] * Type 2: Type 2 Routing Header [RFC6275]
* Type 3: RPL Source Route Header [RFC6554] * Type 3: RPL Source Route Header [RFC6554]
* Type 4: Segment Routing Header (SRH) [RFC8754] * Type 4: Segment Routing Header (SRH) [RFC8754]
skipping to change at page 10, line 45 skipping to change at line 475
* Types 5-252: Unassigned * Types 5-252: Unassigned
* Type 253: RFC3692-style Experiment 1 [RFC4727] * Type 253: RFC3692-style Experiment 1 [RFC4727]
* Type 254: RFC3692-style Experiment 2 [RFC4727] * Type 254: RFC3692-style Experiment 2 [RFC4727]
* Type 255: Reserved * Type 255: Reserved
3.5.2.3. Specific Security Implications 3.5.2.3. Specific Security Implications
The security implications of RHT0 have been discussed in detail in The security implications of Routing Headers of Routing Type 0 have
[Biondi2007] and [RFC5095]. RHT1 was never widely implemented. The been discussed in detail in [Biondi-2007] and [RFC5095]. Routing
security implications of RHT2, RHT3, and RHT4 (SRH) are discussed in Type 1 was never widely implemented. The security implications of
[RFC6275], [RFC6554], and [RFC8754], respectively. Routing Headers of Routing Type 2, Routing Type 3, and Routing Type 4
(SRH) are discussed in [RFC6275], [RFC6554], and [RFC8754],
respectively.
3.5.2.4. Operational and Interoperability Impact if Blocked 3.5.2.4. Operational and Interoperability Impact If Blocked
Blocking packets containing a RHT0 or RHT1 has no operational Blocking packets containing Routing Headers of Routing Type 0 or
implications, since both have been deprecated. Blocking packets with Routing Type 1 has no operational implications, since both have been
a RHT2 would break Mobile IPv6. Packets with a RHT3 may be safely deprecated. Blocking packets containing Routing Headers of Routing
blocked at RPL domain boundaries, since RHT3 headers are employed Type 2 would break Mobile IPv6. Packets containing Routing Headers
within a single RPL domain. Blocking packets with a RHT4 (SRH) will of Routing Type 3 may be safely blocked at RPL domain boundaries,
break Segment Routing (SR) deployments, if the filtering policy is since such headers are employed within a single RPL domain. Blocking
enforced on packets being forwarded within an SR domain. packets containing Routing Headers of Routing Type 4 (SRH) will break
Segment Routing (SR) deployments if the filtering policy is enforced
on packets being forwarded within an SR domain.
3.5.2.5. Advice 3.5.2.5. Advice
Intermediate systems should discard packets containing a RHT0, RHT1, Intermediate systems should discard packets containing Routing
or RHT3. Other routing header types should be permitted, as required Headers of Routing Type 0, Routing Type 1, or Routing Type 3. Other
by [RFC7045]. Routing Types should be permitted, as required by [RFC7045].
3.5.3. Fragment Header for IPv6 (Protocol Number=44) 3.5.3. Fragment Header (Protocol Number=44)
3.5.3.1. Uses 3.5.3.1. Uses
This EH provides the fragmentation functionality for IPv6. This EH provides the fragmentation and reassembly functionality for
IPv6.
3.5.3.2. Specification 3.5.3.2. Specification
This EH is specified in [RFC8200]. This EH is specified in [RFC8200].
3.5.3.3. Specific Security Implications 3.5.3.3. Specific Security Implications
The security implications of the Fragment Header range from Denial of The security implications of the Fragment Header range from DoS
Service attacks (e.g. based on flooding a target with IPv6 fragments) attacks (e.g., based on flooding a target with IPv6 fragments) to
to information leakage attacks [RFC7739]. information leakage attacks [RFC7739].
3.5.3.4. Operational and Interoperability Impact if Blocked 3.5.3.4. Operational and Interoperability Impact If Blocked
Blocking packets that contain a Fragment Header will break any Blocking packets that contain a Fragment Header will break any
protocol that may rely on fragmentation (e.g., the DNS [RFC1034]). protocol that may rely on fragmentation (e.g., the DNS [RFC1034]).
However, IP fragmentation is known to introduce fragility to Internet However, IP fragmentation is known to introduce fragility to Internet
communication [RFC8900]. communication [RFC8900].
3.5.3.5. Advice 3.5.3.5. Advice
Intermediate systems should permit packets that contain a Fragment Intermediate systems should permit packets that contain a Fragment
Header. Header.
skipping to change at page 12, line 4 skipping to change at line 530
protocol that may rely on fragmentation (e.g., the DNS [RFC1034]). protocol that may rely on fragmentation (e.g., the DNS [RFC1034]).
However, IP fragmentation is known to introduce fragility to Internet However, IP fragmentation is known to introduce fragility to Internet
communication [RFC8900]. communication [RFC8900].
3.5.3.5. Advice 3.5.3.5. Advice
Intermediate systems should permit packets that contain a Fragment Intermediate systems should permit packets that contain a Fragment
Header. Header.
3.5.4. Encapsulating Security Payload (Protocol Number=50) 3.5.4. Encapsulating Security Payload (Protocol Number=50)
3.5.4.1. Uses 3.5.4.1. Uses
This EH is employed for the IPsec suite [RFC4303]. This EH is employed for the IPsec suite [RFC4303].
3.5.4.2. Specification 3.5.4.2. Specification
This EH is specified in [RFC4303]. This EH is specified in [RFC4303].
3.5.4.3. Specific Security Implications 3.5.4.3. Specific Security Implications
Besides the general implications of IPv6 EHs, this EH could be Besides the general implications of IPv6 EHs, this EH could be
employed to potentially perform a DoS attack at the destination employed to potentially perform a DoS attack at the destination
system by wasting CPU resources in validating the contents of the system by wasting CPU resources in validating the contents of the
packet. packet.
3.5.4.4. Operational and Interoperability Impact if Blocked 3.5.4.4. Operational and Interoperability Impact If Blocked
Discarding packets that employ this EH would break IPsec deployments. Discarding packets that employ this EH would break IPsec deployments.
3.5.4.5. Advice 3.5.4.5. Advice
Intermediate systems should permit packets containing the Intermediate systems should permit packets containing the
Encapsulating Security Payload EH. Encapsulating Security Payload EH.
3.5.5. Authentication Header (Protocol Number=51) 3.5.5. Authentication Header (Protocol Number=51)
3.5.5.1. Uses 3.5.5.1. Uses
The Authentication Header can be employed for provide authentication The Authentication Header can be employed to provide authentication
services in IPv4 and IPv6. services in IPv4 and IPv6.
3.5.5.2. Specification 3.5.5.2. Specification
This EH is specified in [RFC4302]. This EH is specified in [RFC4302].
3.5.5.3. Specific Security Implications 3.5.5.3. Specific Security Implications
Besides the general implications of IPv6 EHs, this EH could be Besides the general implications of IPv6 EHs, this EH could be
employed to potentially perform a DoS attack at the destination employed to potentially perform a DoS attack at the destination
system by wasting CPU resources in validating the contents of the system by wasting CPU resources in validating the contents of the
packet. packet.
3.5.5.4. Operational and Interoperability Impact if Blocked 3.5.5.4. Operational and Interoperability Impact If Blocked
Discarding packets that employ this EH would break IPsec deployments. Discarding packets that employ this EH would break IPsec deployments.
3.5.5.5. Advice 3.5.5.5. Advice
Intermediate systems should permit packets containing an Intermediate systems should permit packets containing an
Authentication Header. Authentication Header.
3.5.6. Destination Options for IPv6 (Protocol Number=60) 3.5.6. Destination Options (Protocol Number=60)
3.5.6.1. Uses 3.5.6.1. Uses
The Destination Options header is used to carry optional information The Destination Options (DO) header is used to carry optional
that needs be examined only by a packet's destination node(s). information that needs be examined only by a packet's destination
node(s).
3.5.6.2. Specification 3.5.6.2. Specification
This EH is specified in [RFC8200]. As of May 2022, the following This EH is specified in [RFC8200]. As of May 2022, the following
options have been specified for this EH: options have been specified for this EH:
* Type 0x00: Pad1 [RFC8200] * Type 0x00: Pad1 [RFC8200]
* Type 0x01: PadN [RFC8200] * Type 0x01: PadN [RFC8200]
* Type 0x04: Tunnel Encapsulation Limit [RFC2473] * Type 0x04: Tunnel Encapsulation Limit [RFC2473]
* Type 0x0F: IPv6 Performance and Diagnostic Metrics (PDM) [RFC8250] * Type 0x0F: IPv6 Performance and Diagnostic Metrics (PDM) [RFC8250]
* Type 0x4D: (Deprecated) * Type 0x4D: (Deprecated)
* Type 0xC9: Home Address [RFC6275] * Type 0xC9: Home Address [RFC6275]
* Type 0x8A: Endpoint Identification (Deprecated) * Type 0x8A: Endpoint Identification (Deprecated) [NIMROD-EID]
[draft-ietf-nimrod-eid]
* Type 0x8B: ILNP Nonce [RFC6744] * Type 0x8B: ILNP Nonce [RFC6744]
* Type 0x8C: Line-Identification Option [RFC6788] * Type 0x8C: Line-Identification Option [RFC6788]
* Type 0x1E: RFC3692-style Experiment [RFC4727] * Type 0x1E: RFC3692-style Experiment [RFC4727]
* Type 0x3E: RFC3692-style Experiment [RFC4727] * Type 0x3E: RFC3692-style Experiment [RFC4727]
* Type 0x5E: RFC3692-style Experiment [RFC4727] * Type 0x5E: RFC3692-style Experiment [RFC4727]
skipping to change at page 14, line 4 skipping to change at line 624
* Type 0x3E: RFC3692-style Experiment [RFC4727] * Type 0x3E: RFC3692-style Experiment [RFC4727]
* Type 0x5E: RFC3692-style Experiment [RFC4727] * Type 0x5E: RFC3692-style Experiment [RFC4727]
* Type 0x7E: RFC3692-style Experiment [RFC4727] * Type 0x7E: RFC3692-style Experiment [RFC4727]
* Type 0x9E: RFC3692-style Experiment [RFC4727] * Type 0x9E: RFC3692-style Experiment [RFC4727]
* Type 0xBE: RFC3692-style Experiment [RFC4727] * Type 0xBE: RFC3692-style Experiment [RFC4727]
* Type 0xDE: RFC3692-style Experiment [RFC4727] * Type 0xDE: RFC3692-style Experiment [RFC4727]
* Type 0xFE: RFC3692-style Experiment [RFC4727] * Type 0xFE: RFC3692-style Experiment [RFC4727]
3.5.6.3. Specific Security Implications 3.5.6.3. Specific Security Implications
No security implications are known, other than the general No security implications are known, other than the general security
implications of IPv6 EHs. For a discussion of possible security implications of IPv6 EHs. For a discussion of possible security
implications of specific options specified for the DO header, please implications of specific options specified for the DO header, please
see the Section 4.4. see Section 4.4.
3.5.6.4. Operational and Interoperability Impact if Blocked 3.5.6.4. Operational and Interoperability Impact If Blocked
Discarding packets that contain a Destination Options header would Discarding packets that contain a Destination Options header would
break protocols that rely on this EH type for conveying information, break protocols that rely on this EH type for conveying information
including protocols such as ILNP [RFC6740] and Mobile IPv6 [RFC6275], (such as the Identifier-Locator Network Protocol (ILNP) [RFC6740] and
and IPv6 tunnels that employ the Tunnel Encapsulation Limit option. Mobile IPv6 [RFC6275]), as well as IPv6 tunnels that employ the
Tunnel Encapsulation Limit option [RFC2473].
3.5.6.5. Advice 3.5.6.5. Advice
Intermediate systems should permit packets that contain a Destination Intermediate systems should permit packets that contain a Destination
Options Header. Options header.
3.5.7. Mobility Header (Protocol Number=135) 3.5.7. Mobility Header (Protocol Number=135)
3.5.7.1. Uses 3.5.7.1. Uses
The Mobility Header is an EH used by mobile nodes, correspondent The Mobility Header is an EH used by mobile nodes, correspondent
nodes, and home agents in all messaging related to the creation and nodes, and home agents in all messaging related to the creation and
management of bindings in Mobile IPv6. management of bindings in Mobile IPv6.
3.5.7.2. Specification 3.5.7.2. Specification
This EH is specified in [RFC6275]. This EH is specified in [RFC6275].
3.5.7.3. Specific Security Implications 3.5.7.3. Specific Security Implications
A thorough security assessment of the security implications of the A thorough security assessment of the security implications of the
Mobility Header and related mechanisms can be found in Section 15 of Mobility Header and related mechanisms can be found in Section 15 of
[RFC6275]. [RFC6275].
3.5.7.4. Operational and Interoperability Impact if Blocked 3.5.7.4. Operational and Interoperability Impact If Blocked
Discarding packets containing this EH would break Mobile IPv6. Discarding packets containing this EH would break Mobile IPv6.
3.5.7.5. Advice 3.5.7.5. Advice
Intermediate systems should permit packets containing this EH. Intermediate systems should permit packets that contain a Mobility
Header.
3.5.8. Host Identity Protocol (Protocol Number=139) 3.5.8. Host Identity Protocol (Protocol Number=139)
3.5.8.1. Uses 3.5.8.1. Uses
This EH is employed with the Host Identity Protocol (HIP), a protocol This EH is employed with the Host Identity Protocol (HIP), which is a
that allows consenting hosts to securely establish and maintain protocol that allows consenting hosts to securely establish and
shared IP-layer state, allowing separation of the identifier and maintain shared IP-layer state, allowing the separation of the
locator roles of IP addresses, thereby enabling continuity of identifier and locator roles of IP addresses, thereby enabling
communications across IP address changes. continuity of communications across IP address changes.
3.5.8.2. Specification 3.5.8.2. Specification
This EH is specified in [RFC7401]. This EH is specified in [RFC7401].
3.5.8.3. Specific Security Implications 3.5.8.3. Specific Security Implications
The security implications of the HIP header are discussed in detail The security implications of the HIP header are discussed in detail
in Section 8 of [RFC6275]. in Section 8 of [RFC7401].
3.5.8.4. Operational and Interoperability Impact if Blocked 3.5.8.4. Operational and Interoperability Impact If Blocked
Discarding packets that contain the Host Identity Protocol would Discarding packets that contain a HIP header would break HIP
break HIP deployments. deployments.
3.5.8.5. Advice 3.5.8.5. Advice
Intermediate systems should permit packets that contain a Host Intermediate systems should permit packets that contain a HIP header.
Identity Protocol EH.
3.5.9. Shim6 Protocol (Protocol Number=140) 3.5.9. Shim6 Protocol (Protocol Number=140)
3.5.9.1. Uses 3.5.9.1. Uses
This EH is employed by the Shim6 [RFC5533] Protocol. This EH is employed by the Shim6 protocol [RFC5533].
3.5.9.2. Specification 3.5.9.2. Specification
This EH is specified in [RFC5533]. This EH is specified in [RFC5533].
3.5.9.3. Specific Security Implications 3.5.9.3. Specific Security Implications
The specific security implications are discussed in detail in The specific security implications are discussed in detail in
Section 16 of [RFC5533]. Section 16 of [RFC5533].
3.5.9.4. Operational and Interoperability Impact if Blocked 3.5.9.4. Operational and Interoperability Impact If Blocked
Discarding packets that contain this EH will break Shim6. Discarding packets that contain this EH will break Shim6.
3.5.9.5. Advice 3.5.9.5. Advice
Intermediate systems should permit packets containing this EH. Intermediate systems should permit packets containing this EH.
3.5.10. Use for experimentation and testing (Protocol Numbers=253 and 3.5.10. Use for Experimentation and Testing (Protocol Numbers=253 and
254) 254)
3.5.10.1. Uses 3.5.10.1. Uses
These IPv6 EHs are employed for performing RFC3692-Style experiments These IPv6 EHs are employed for performing RFC3692-style experiments
(see [RFC3692] for details). (see [RFC3692] for details).
3.5.10.2. Specification 3.5.10.2. Specification
These EHs are specified in [RFC3692] and [RFC4727]. These EHs are specified in [RFC3692] and [RFC4727].
3.5.10.3. Specific Security Implications 3.5.10.3. Specific Security Implications
The security implications of these EHs will depend on their specific The security implications of these EHs will depend on their specific
use. use.
3.5.10.4. Operational and Interoperability Impact if Blocked 3.5.10.4. Operational and Interoperability Impact If Blocked
For obvious reasons, discarding packets that contain these EHs limits For obvious reasons, discarding packets that contain these EHs limits
the ability to perform legitimate experiments across IPv6 routers. the ability to perform legitimate experiments across IPv6 routers.
3.5.10.5. Advice 3.5.10.5. Advice
Operators should determine according to their own circumstances Operators should determine, according to their own circumstances,
whether to discard packets containing these EHs. whether to discard packets containing these EHs.
3.6. Advice on the Handling of Packets with Unknown IPv6 Extension 3.6. Advice on the Handling of Packets with Unknown IPv6 Extension
Headers Headers
We refer to IPv6 EHs that have not been assigned an Internet Protocol We refer to IPv6 EHs that have not been assigned an Internet Protocol
Number by IANA (and marked as such) in [IANA-PROTOCOLS] as "unknown number by IANA (and marked as such) in [IANA-PROTOCOLS] as "unknown
IPv6 extension headers" ("unknown IPv6 EHs"). IPv6 Extension Headers" ("unknown IPv6 EHs").
3.6.1. Uses 3.6.1. Uses
New IPv6 EHs may be specified as part of future extensions to the New IPv6 EHs may be specified as part of future extensions to the
IPv6 protocol. IPv6 protocol.
Since IPv6 EHs and Upper-layer protocols employ the same namespace, Since IPv6 EHs and upper-layer protocols employ the same namespace,
it is impossible to tell whether an unknown "Internet Protocol it is impossible to tell whether an unknown Internet Protocol number
Number" is being employed for an IPv6 EH or an Upper-Layer protocol. is being employed for an IPv6 EH or an upper-layer protocol.
3.6.2. Specification 3.6.2. Specification
The processing of unknown IPv6 EHs is specified in [RFC7045]. The processing of unknown IPv6 EHs is specified in [RFC7045].
3.6.3. Specific Security Implications 3.6.3. Specific Security Implications
For obvious reasons, it is impossible to determine specific security For obvious reasons, it is impossible to determine specific security
implications of unknown IPv6 EHs. implications of unknown IPv6 EHs.
3.6.4. Operational and Interoperability Impact if Blocked 3.6.4. Operational and Interoperability Impact If Blocked
As noted in [RFC7045], discarding unknown IPv6 EHs may slow down the As noted in [RFC7045], discarding unknown IPv6 EHs may slow down the
deployment of new IPv6 EHs and transport protocols. The deployment of new IPv6 EHs and transport protocols. The
corresponding IANA registry ([IANA-PROTOCOLS]) should be monitored corresponding IANA registry, which is [IANA-PROTOCOLS], should be
such that filtering rules are updated as new IPv6 EHs are monitored such that filtering rules are updated as new IPv6 EHs are
standardized. standardized.
We note that since IPv6 EHs and upper-layer protocols share the same We note that since IPv6 EHs and upper-layer protocols share the same
numbering space, discarding unknown IPv6 EHs may result in packets numbering space, discarding unknown IPv6 EHs may result in packets
encapsulating unknown upper-layer protocols being discarded. encapsulating unknown upper-layer protocols being discarded.
3.6.5. Advice 3.6.5. Advice
Operators should determine according to their own circumstances Operators should determine, according to their own circumstances,
whether to discard packets containing unknown IPv6 EHs. whether to discard packets containing unknown IPv6 EHs.
4. IPv6 Options 4. IPv6 Options
4.1. General Discussion 4.1. General Discussion
The following subsections describe specific security implications of The following subsections describe specific security implications of
different IPv6 options, and provide advice regarding filtering different IPv6 options and provide advice regarding filtering packets
packets that contain such options. that contain such options.
4.2. General Security Implications of IPv6 Options 4.2. General Security Implications of IPv6 Options
The general security implications of IPv6 options are closely related The general security implications of IPv6 options are closely related
to those discussed in Section 3.2 for IPv6 EHs. Essentially, packets to those discussed in Section 3.2 for IPv6 EHs. Essentially, packets
that contain IPv6 options might need to be processed by an IPv6 that contain IPv6 options might need to be processed by an IPv6
router's general-purpose CPU,and hence could present a DDoS risk to router's general-purpose CPU and, hence, could present a Distributed
that router's general-purpose CPU (and thus to the router itself). Denial-of-Service (DDoS) risk to that router's general-purpose CPU
For some architectures, a possible mitigation would be to rate-limit (and thus to the router itself). For some architectures, a possible
the packets that are to be processed by the general-purpose CPU (see mitigation would be to rate-limit the packets that are to be
e.g. [Cisco-EH]). processed by the general-purpose CPU (see, e.g., [Cisco-EH]).
4.3. Summary of Advice on the Handling of IPv6 Packets with Specific 4.3. Summary of Advice on the Handling of IPv6 Packets with Specific
IPv6 Extension Headers IPv6 Options
This section summarizes the advice provided in Section 3.5, providing This section summarizes the advice provided in Section 4.4, and it
references to the specific sections in which a detailed analysis can includes references to the specific sections in which a detailed
be found. analysis can be found.
+===============================+======================+===========+ +===============================+======================+===========+
| Option | Filtering policy | Reference | | Option | Filtering Policy | Reference |
+===============================+======================+===========+ +===============================+======================+===========+
| Pad1 (Type=0x00) | Permit | Section | | Pad1 (Type=0x00) | Permit | Section |
| | | 4.4.1 | | | | 4.4.1 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| PadN (Type=0x01) | Permit | Section | | PadN (Type=0x01) | Permit | Section |
| | | 4.4.2 | | | | 4.4.2 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| Tunnel Encapsulation Limit | Permit | Section | | Tunnel Encapsulation Limit | Permit | Section |
| (Type=0x04) | | 4.4.3 | | (Type=0x04) | | 4.4.3 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
skipping to change at page 18, line 48 skipping to change at line 858
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| Quick-Start (Type=0x26) | Permit | Section | | Quick-Start (Type=0x26) | Permit | Section |
| | | 4.4.9 | | | | 4.4.9 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| Deprecated (Type=0x4D) | Drop | Section | | Deprecated (Type=0x4D) | Drop | Section |
| | | 4.4.10 | | | | 4.4.10 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| MPL Option (Type=0x6D) | Permit | Section | | MPL Option (Type=0x6D) | Permit | Section |
| | | 4.4.12 | | | | 4.4.12 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| Jumbo Payload (Type=0C2) | Permit based on | Section | | Jumbo Payload (Type=0xC2) | Permit based on | Section |
| | needed functionality | 4.4.16 | | | needed functionality | 4.4.16 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| RPL Option (Type=0x63) | Drop in non-RPL | Section | | RPL Option (Type=0x63) | Drop | Section |
| | routers | 4.4.11 | | | | 4.4.11 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| Endpoint Identification | Drop | Section | | Endpoint Identification | Drop | Section |
| (Type=0x8A) | | 4.4.13 | | (Type=0x8A) | | 4.4.13 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| ILNP Nonce (Type=0x8B) | Permit | Section | | ILNP Nonce (Type=0x8B) | Permit | Section |
| | | 4.4.14 | | | | 4.4.14 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| Line-Identification Option | Drop | Section | | Line-Identification Option | Drop | Section |
| (Type=0x8C) | | 4.4.15 | | (Type=0x8C) | | 4.4.15 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
skipping to change at page 19, line 26 skipping to change at line 885
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| IP_DFF (Type=0xEE) | Permit based on | Section | | IP_DFF (Type=0xEE) | Permit based on | Section |
| | needed functionality | 4.4.18 | | | needed functionality | 4.4.18 |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
| RFC3692-style Experiment | Permit based on | Section | | RFC3692-style Experiment | Permit based on | Section |
| (Types = 0x1E, 0x3E, 0x5E, | needed functionality | 4.4.19 | | (Types = 0x1E, 0x3E, 0x5E, | needed functionality | 4.4.19 |
| 0x7E, 0x9E, 0xBE, 0xDE, 0xFE) | | | | 0x7E, 0x9E, 0xBE, 0xDE, 0xFE) | | |
+-------------------------------+----------------------+-----------+ +-------------------------------+----------------------+-----------+
Table 2: Summary of Advice on the Handling of IPv6 Packets with Table 2: Summary of Advice on the Handling of IPv6 Packets with
Specific IPv6 options Specific IPv6 Options
4.4. Advice on the Handling of Packets with Specific IPv6 Options 4.4. Advice on the Handling of Packets with Specific IPv6 Options
The following subsections contain a description of each of the IPv6 The following subsections contain a description of each of the IPv6
options that have so far been specified, a summary of the security options that have so far been specified, a summary of the security
implications of each of such options, a discussion of possible implications of each of such options, a discussion of possible
interoperability implications if packets containing such options are interoperability implications if packets containing such options are
discarded, and specific advice regarding whether packets containing discarded, and specific advice regarding whether packets containing
these options should be permitted. these options should be permitted.
skipping to change at page 20, line 5 skipping to change at line 911
pad out the containing header to a multiple of 8 octets in length. pad out the containing header to a multiple of 8 octets in length.
4.4.1.2. Specification 4.4.1.2. Specification
This option is specified in [RFC8200]. This option is specified in [RFC8200].
4.4.1.3. Specific Security Implications 4.4.1.3. Specific Security Implications
None. None.
4.4.1.4. Operational and Interoperability Impact if Blocked 4.4.1.4. Operational and Interoperability Impact If Blocked
Discarding packets that contain this option would potentially break Discarding packets that contain this option would potentially break
any protocol that relies on IPv6 options. any protocol that relies on IPv6 options.
4.4.1.5. Advice 4.4.1.5. Advice
Intermediate systems should not discard packets based on the presence Intermediate systems should not discard packets based on the presence
of this option. of this option.
4.4.2. PadN (Type=0x01) 4.4.2. PadN (Type=0x01)
skipping to change at page 20, line 31 skipping to change at line 937
4.4.2.2. Specification 4.4.2.2. Specification
This option is specified in [RFC8200]. This option is specified in [RFC8200].
4.4.2.3. Specific Security Implications 4.4.2.3. Specific Security Implications
Because of the possible size of this option, it could be leveraged as Because of the possible size of this option, it could be leveraged as
a large-bandwidth covert channel. a large-bandwidth covert channel.
4.4.2.4. Operational and Interoperability Impact if Blocked 4.4.2.4. Operational and Interoperability Impact If Blocked
Discarding packets that contain this option would potentially break Discarding packets that contain this option would potentially break
any protocol that relies on IPv6 options. any protocol that relies on IPv6 options.
4.4.2.5. Advice 4.4.2.5. Advice
Intermediate systems should not discard IPv6 packets based on the Intermediate systems should not discard IPv6 packets based on the
presence of this option. presence of this option.
4.4.3. Tunnel Encapsulation Limit (Type=0x04) 4.4.3. Tunnel Encapsulation Limit (Type=0x04)
skipping to change at page 21, line 7 skipping to change at line 960
The Tunnel Encapsulation Limit option can be employed to specify how The Tunnel Encapsulation Limit option can be employed to specify how
many further levels of nesting the packet is permitted to undergo. many further levels of nesting the packet is permitted to undergo.
4.4.3.2. Specification 4.4.3.2. Specification
This option is specified in [RFC2473]. This option is specified in [RFC2473].
4.4.3.3. Specific Security Implications 4.4.3.3. Specific Security Implications
Those described in [RFC2473]. These are discussed in [RFC2473].
4.4.3.4. Operational and Interoperability Impact if Blocked 4.4.3.4. Operational and Interoperability Impact If Blocked
Discarding packets based on the presence of this option could result Discarding packets based on the presence of this option could result
in tunnel traffic being discarded. in tunnel traffic being discarded.
4.4.3.5. Advice 4.4.3.5. Advice
Intermediate systems should not discard packets based on the presence Intermediate systems should not discard packets based on the presence
of this option. of this option.
4.4.4. Router Alert (Type=0x05) 4.4.4. Router Alert (Type=0x05)
skipping to change at page 21, line 41 skipping to change at line 994
This option is specified in [RFC2711]. This option is specified in [RFC2711].
4.4.4.3. Specific Security Implications 4.4.4.3. Specific Security Implications
Since this option causes the contents of the packet to be inspected Since this option causes the contents of the packet to be inspected
by the handling device, this option could be leveraged for performing by the handling device, this option could be leveraged for performing
DoS attacks. The security implications of the Router Alert option DoS attacks. The security implications of the Router Alert option
are discussed in detail in [RFC6398]. are discussed in detail in [RFC6398].
4.4.4.4. Operational and Interoperability Impact if Blocked 4.4.4.4. Operational and Interoperability Impact If Blocked
Discarding packets that contain this option would break any protocols Discarding packets that contain this option would break any protocols
that rely on them, such as RSVP and multicast deployments. Please that rely on them, such as RSVP and multicast deployments. Please
see Section 4.4.4.3 for further details. see Section 4.4.4.3 for further details.
4.4.4.5. Advice 4.4.4.5. Advice
Packets containing this option should be permitted in environments Packets containing this option should be permitted in environments
where support for RSVP, multicast routing, or similar protocols is where support for RSVP, multicast routing, or similar protocols is
desired. required.
4.4.5. CALIPSO (Type=0x07) 4.4.5. CALIPSO (Type=0x07)
4.4.5.1. Uses 4.4.5.1. Uses
This option is used for encoding explicit packet Sensitivity Labels This option is used for encoding explicit packet Sensitivity Labels
on IPv6 packets. It is intended for use only within Multi-Level on IPv6 packets. It is intended for use only within Multi-Level
Secure (MLS) networking environments that are both trusted and Secure (MLS) networking environments that are both trusted and
trustworthy. trustworthy.
4.4.5.2. Specification 4.4.5.2. Specification
This option is specified in [RFC5570]. This option is specified in [RFC5570].
4.4.5.3. Specific Security Implications 4.4.5.3. Specific Security Implications
Presence of this option in a packet does not by itself create any Presence of this option in a packet does not by itself create any
specific new threat. Packets with this option ought not normally be specific new threat. Packets with this option ought not normally be
seen on the global public Internet. seen on the global public Internet.
4.4.5.4. Operational and Interoperability Impact if Blocked 4.4.5.4. Operational and Interoperability Impact If Blocked
If packets with this option are discarded or if the option is If packets with this option are discarded or if the option is
stripped from the packet during transmission from source to stripped from the packet during transmission from source to
destination, then the packet itself is likely to be discarded by the destination, then the packet itself is likely to be discarded by the
receiver because it is not properly labeled. In some cases, the receiver because it is not properly labeled. In some cases, the
receiver might receive the packet but associate an incorrect receiver might receive the packet but associate an incorrect
sensitivity label with the received data from the packet whose Sensitivity Label with the received data from the packet whose Common
CALIPSO was stripped by a middle-box (such as a packet-scrubber). Architecture Label IPv6 Security Option (CALIPSO) was stripped by a
Associating an incorrect sensitivity label can cause the received middlebox (such as a packet scrubber). Associating an incorrect
information either to be handled as more sensitive than it really is Sensitivity Label can cause the received information to be handled
("upgrading") or as less sensitive than it really is ("downgrading"), either as more sensitive than it really is ("upgrading") or as less
either of which is problematic. As noted in [RFC5570], IPsec sensitive than it really is ("downgrading"), either of which is
[RFC4301] [RFC4302] [RFC4303] can be employed to protect the CALIPSO problematic. As noted in [RFC5570], IPsec [RFC4301] [RFC4302]
option. [RFC4303] can be employed to protect the CALIPSO.
4.4.5.5. Advice 4.4.5.5. Advice
Recommendations for handling the CALIPSO option depend on the Recommendations for handling the CALIPSO depend on the deployment
deployment environment, rather than whether an intermediate system environment rather than on whether an intermediate system happens to
happens to be deployed as a transit device (e.g., IPv6 transit be deployed as a transit device (e.g., IPv6 transit router).
router).
Explicit configuration is the only method via which an intermediate Explicit configuration is the only method via which an intermediate
system can know whether that particular intermediate system has been system can know whether that particular intermediate system has been
deployed within a Multi-Level Secure (MLS) environment. In many deployed within an MLS environment. In many cases, ordinary
cases, ordinary commercial intermediate systems (e.g., IPv6 routers commercial intermediate systems (e.g., IPv6 routers and firewalls)
and firewalls) are the majority of the deployed intermediate systems are the majority of the deployed intermediate systems inside an MLS
inside an MLS network environment. network environment.
For Intermediate systems that DO NOT implement [RFC5570], there For intermediate systems that DO NOT implement [RFC5570], there
should be a configuration option to EITHER (a) drop packets should be a configuration option to either (a) drop packets
containing the CALIPSO option OR (b) to ignore the presence of the containing the CALIPSO or (b) ignore the presence of the CALIPSO and
CALIPSO option and forward the packets normally. In non-MLS forward the packets normally. In non-MLS environments, such
environments, such intermediate systems should have this intermediate systems should have this configuration option set to (a)
configuration option set to (a) above. In MLS environments, such above. In MLS environments, such intermediate systems should have
intermediate systems should have this option set to (b) above. The this option set to (b) above. The default setting for this
default setting for this configuration option should be set to (a) configuration option should be set to (a) above, because MLS
above, because MLS environments are much less common than non-MLS environments are much less common than non-MLS environments.
environments.
For Intermediate systems that DO implement [RFC5570], there should be For intermediate systems that DO implement [RFC5570], there should be
configuration options (a) and (b) from the preceding paragraph and configuration options (a) and (b) from the preceding paragraph and
also a third configuration option (c) to process packets containing a also a third configuration option (c) to process packets containing a
CALIPSO option as per [RFC5570]. When deployed in non-MLS CALIPSO as per [RFC5570]. When deployed in non-MLS environments,
environments, such intermediate systems should have this such intermediate systems should have this configuration option set
configuration option set to (a) above. When deployed in MLS to (a) above. When deployed in MLS environments, such intermediate
environments, such intermediate systems should have this set to (c). systems should have this configuration option set to (c). The
The default setting for this configuration option MAY be set to (a) default setting for this configuration option MAY be set to (a)
above, because MLS environments are much less common than non-MLS above, because MLS environments are much less common than non-MLS
environments. environments.
4.4.6. SMF_DPD (Type=0x08) 4.4.6. SMF_DPD (Type=0x08)
4.4.6.1. Uses 4.4.6.1. Uses
This option is employed in the (experimental) Simplified Multicast This option is employed in the (experimental) Simplified Multicast
Forwarding (SMF) for unique packet identification for IPv6 I-DPD, and Forwarding (SMF) for unique packet identification for IPv6
as a mechanism to guarantee non-collision of hash values for Identification-based DPD (I-DPD) and as a mechanism to guarantee non-
different packets when H-DPD is used. collision of hash values for different packets when Hash-based DPD
(H-DPD) is used.
4.4.6.2. Specification 4.4.6.2. Specification
This option is specified in [RFC6621]. This option is specified in [RFC6621].
4.4.6.3. Specific Security Implications 4.4.6.3. Specific Security Implications
None. The use of transient numeric identifiers is subject to the None. The use of transient numeric identifiers is subject to the
security and privacy considerations discussed in security and privacy considerations discussed in [NUMERIC-IDS].
[I-D.irtf-pearg-numeric-ids-generation].
4.4.6.4. Operational and Interoperability Impact if Blocked 4.4.6.4. Operational and Interoperability Impact If Blocked
Dropping packets containing this option within a MANET domain would Dropping packets containing this option within a Mobile Ad Hoc
break SMF. However, dropping such packets at the border of such Network (MANET) domain would break SMF. However, dropping such
domain would have no negative impact. packets at the border of such domain would have no negative impact.
4.4.6.5. Advice 4.4.6.5. Advice
Intermediate systems that are not within a MANET domain should Intermediate systems that are not within a MANET domain should
discard packets that contain this option. discard packets that contain this option.
4.4.7. PDM (Type=0x0F) 4.4.7. PDM (Type=0x0F)
4.4.7.1. Uses 4.4.7.1. Uses
This option is employed to convey sequence numbers and timing This option is employed to convey sequence numbers and timing
information in IPv6 packets as a basis for measurements. information in IPv6 packets as a basis for measurements.
4.4.7.2. Specification 4.4.7.2. Specification
This option is specified in [RFC8250]. This option is specified in [RFC8250].
4.4.7.3. Specific Security Implications 4.4.7.3. Specific Security Implications
Those specified in [RFC8250]. Additionally, since the options These are discussed in [RFC8250]. Additionally, since this option
employs transient numeric identifiers, implementations may be subject employs transient numeric identifiers, implementations may be subject
to the issues discussed in [I-D.irtf-pearg-numeric-ids-generation]. to the issues discussed in [NUMERIC-IDS].
4.4.7.4. Operational and Interoperability Impact if Blocked 4.4.7.4. Operational and Interoperability Impact If Blocked
Dropping packets containing this option will result in negative Dropping packets containing this option will result in negative
interoperaiblity implications for traffic employing this option as a interoperability implications for traffic employing this option as a
basis for measurements. basis for measurements.
4.4.7.5. Advice 4.4.7.5. Advice
Intermediate systems should not discard packets based on the presence Intermediate systems should not discard packets based on the presence
of this option. of this option.
4.4.8. RPL Option (Type=0x23) 4.4.8. RPL Option (Type=0x23)
4.4.8.1. Uses 4.4.8.1. Uses
The RPL Option provides a mechanism to include routing information The RPL Option provides a mechanism to include routing information in
with each datagram that an RPL router forwards. each datagram that a RPL router forwards.
4.4.8.2. Specification 4.4.8.2. Specification
This option is specified in [RFC9008]. This option is specified in [RFC9008].
4.4.8.3. Specific Security Implications 4.4.8.3. Specific Security Implications
Those described in [RFC9008]. These are discussed in [RFC9008].
4.4.8.4. Operational and Interoperability Impact if Blocked 4.4.8.4. Operational and Interoperability Impact If Blocked
This option can survive outside of an RPL instance. As a result, This option can survive outside of a RPL instance. As a result,
discarding packets based on the presence of this option would break discarding packets based on the presence of this option would break
some use cases for RPL (see [RFC9008]). some use cases for RPL (see [RFC9008]).
4.4.8.5. Advice 4.4.8.5. Advice
Intermediate systems should not discard IPv6 packets based on the Intermediate systems should not discard IPv6 packets based on the
presence of this option. presence of this option.
4.4.9. Quick-Start (Type=0x26) 4.4.9. Quick-Start (Type=0x26)
4.4.9.1. Uses 4.4.9.1. Uses
This IP Option is used in the specification of Quick-Start for TCP This IP option is used in the specification of Quick-Start for TCP
and IP, which is an experimental mechanism that allows transport and IP, which is an experimental mechanism that allows transport
protocols, in cooperation with routers, to determine an allowed protocols, in cooperation with routers, to determine an allowed
sending rate at the start and, at times, in the middle of a data sending rate at the start and, at times, in the middle of a data
transfer (e.g., after an idle period) [RFC4782]. transfer (e.g., after an idle period) [RFC4782].
4.4.9.2. Specification 4.4.9.2. Specification
This option is specified in [RFC4782], on the "Experimental" track. This option is specified in [RFC4782] on the "Experimental" track.
4.4.9.3. Specific Security Implications 4.4.9.3. Specific Security Implications
Section 9.6 of [RFC4782] notes that Quick-Start is vulnerable to two Section 9.6 of [RFC4782] notes that Quick-Start is vulnerable to two
kinds of attacks: kinds of attacks:
* attacks to increase the routers' processing and state load, and, * attacks to increase the routers' processing and state load and
* attacks with bogus Quick-Start Requests to temporarily tie up * attacks with bogus Quick-Start Requests to temporarily tie up
available Quick-Start bandwidth, preventing routers from approving available Quick-Start bandwidth, preventing routers from approving
Quick-Start Requests from other connections. Quick-Start Requests from other connections
We note that if routers in a given environment do not implement and We note that if routers in a given environment do not implement and
enable the Quick-Start mechanism, only the general security enable the Quick-Start mechanism, only the general security
implications of IP options (discussed in Section 4.2) would apply. implications of IP options (discussed in Section 4.2) would apply.
4.4.9.4. Operational and Interoperability Impact if Blocked 4.4.9.4. Operational and Interoperability Impact If Blocked
The Quick-Start functionality would be disabled, and additional If packets with IPv6 Quick Start options are blocked, the host trying
delays in TCP's connection establishment (for example) could be to establish a TCP connection will fall back to not including the
introduced. (Please see Section 4.7.2 of [RFC4782].) We note, Quick Start option -- this means that the feature will be disabled,
however, that Quick-Start has been proposed as a mechanism that could and additional delays in connection establishment will be introduced
be of use in controlled environments, and not as a mechanism that (as discussed in Section 4.7.2 of [RFC4782]). We note, however, that
would be intended or appropriate for ubiquitous deployment in the Quick-Start has been proposed as a mechanism that could be of use in
global Internet [RFC4782]. controlled environments and not as a mechanism that would be intended
or appropriate for ubiquitous deployment in the global Internet
[RFC4782].
4.4.9.5. Advice 4.4.9.5. Advice
Intermediate systems should not discard IPv6 packets based on the Intermediate systems should not discard IPv6 packets based on the
presence of this option. presence of this option.
4.4.10. Deprecated (Type=0x4D) 4.4.10. Deprecated (Type=0x4D)
4.4.10.1. Uses 4.4.10.1. Uses
No information has been found about this option type. No information has been found about this option type.
4.4.10.2. Specification 4.4.10.2. Specification
No information has been found about this option type. No information has been found about this option type.
4.4.10.3. Specific Security Implications 4.4.10.3. Specific Security Implications
No information has been found about this option type, and hence it No information has been found about this option type; hence, it has
has been impossible to perform the corresponding security assessment. been impossible to perform the corresponding security assessment.
4.4.10.4. Operational and Interoperability Impact if Blocked 4.4.10.4. Operational and Interoperability Impact If Blocked
Unknown. Unknown.
4.4.10.5. Advice 4.4.10.5. Advice
Intermediate systems should discard packets that contain this option. Intermediate systems should discard packets that contain this option.
4.4.11. RPL Option (Type=0x63) 4.4.11. RPL Option (Type=0x63)
4.4.11.1. Uses 4.4.11.1. Uses
The RPL Option provides a mechanism to include routing information The RPL Option provides a mechanism to include routing information in
with each datagram that an RPL router forwards. each datagram that a RPL router forwards.
4.4.11.2. Specification 4.4.11.2. Specification
This option was originally specified in [RFC6553]. It has been This option was originally specified in [RFC6553]. It has been
deprecated by [RFC9008]. deprecated by [RFC9008].
4.4.11.3. Specific Security Implications 4.4.11.3. Specific Security Implications
Those described in [RFC9008]. These are discussed in Section 5 of [RFC6553].
4.4.11.4. Operational and Interoperability Impact if Blocked 4.4.11.4. Operational and Interoperability Impact If Blocked
This option is meant to be employed within an RPL instance. As a This option is meant to be employed within a RPL instance. As a
result, discarding packets based on the presence of this option result, discarding packets based on the presence of this option
outside of an RPL instance will not result in interoperability outside of a RPL instance will not result in interoperability
implications. implications.
4.4.11.5. Advice 4.4.11.5. Advice
Non-RPL routers should discard packets that contain an RPL option. Intermediate systems should discard packets that contain a RPL
Option.
4.4.12. MPL Option (Type=0x6D) 4.4.12. MPL Option (Type=0x6D)
4.4.12.1. Uses 4.4.12.1. Uses
This option is used with the Multicast Protocol for Low power and This option is used with the Multicast Protocol for Low power and
Lossy Networks (MPL), that provides IPv6 multicast forwarding in Lossy Networks (MPL), which provides IPv6 multicast forwarding in
constrained networks. constrained networks.
4.4.12.2. Specification 4.4.12.2. Specification
This option is specified in [RFC7731], and is meant to be included This option is specified in [RFC7731] and is meant to be included
only in Hop-by-Hop Option headers. only in Hop-by-Hop Options headers.
4.4.12.3. Specific Security Implications 4.4.12.3. Specific Security Implications
Those described in [RFC7731]. These are discussed in [RFC7731].
4.4.12.4. Operational and Interoperability Impact if Blocked 4.4.12.4. Operational and Interoperability Impact If Blocked
Dropping packets that contain an MPL option within an MPL network Dropping packets that contain an MPL Option within an MPL network
would break the Multicast Protocol for Low power and Lossy Networks would break the MPL. However, dropping such packets at the border of
(MPL). However, dropping such packets at the border of such networks such networks will have no negative impact.
will have no negative impact.
4.4.12.5. Advice 4.4.12.5. Advice
Intermediate systems should not discard packets based on the presence Intermediate systems should not discard packets based on the presence
of this option. However, since this option has been specified for of this option. However, since this option has been specified for
the Hop-by-Hop Options, such systems should consider the discussion the Hop-by-Hop Options header, such systems should consider the
in Section 3.5.1. discussion in Section 3.5.1.
4.4.13. Endpoint Identification (Type=0x8A) 4.4.13. Endpoint Identification (Type=0x8A)
4.4.13.1. Uses 4.4.13.1. Uses
The Endpoint Identification option was meant to be used with the The Endpoint Identification option was meant to be used with the
Nimrod routing architecture [NIMROD-DOC], but has never seen Nimrod routing architecture [NIMROD-DOC] but has never seen
widespread deployment. widespread deployment.
4.4.13.2. Specification 4.4.13.2. Specification
This option is specified in [NIMROD-DOC]. This option is specified in [NIMROD-DOC].
4.4.13.3. Specific Security Implications 4.4.13.3. Specific Security Implications
Undetermined. Undetermined.
4.4.13.4. Operational and Interoperability Impact if Blocked 4.4.13.4. Operational and Interoperability Impact If Blocked
None. None.
4.4.13.5. Advice 4.4.13.5. Advice
Intermediate systems should discard packets that contain this option. Intermediate systems should discard packets that contain this option.
4.4.14. ILNP Nonce (Type=0x8B) 4.4.14. ILNP Nonce (Type=0x8B)
4.4.14.1. Uses 4.4.14.1. Uses
This option is employed by Identifier-Locator Network Protocol for This option is employed by the Identifier-Locator Network Protocol
IPv6 (ILNPv6) for providing protection against off-path attacks for for IPv6 (ILNPv6) to provide protection against off-path attacks for
packets when ILNPv6 is in use, and as a signal during initial packets when ILNPv6 is in use and as a signal during initial network-
network-layer session creation that ILNPv6 is proposed for use with layer session creation that ILNPv6 is proposed for use with this
this network-layer session, rather than classic IPv6. network-layer session, rather than classic IPv6.
4.4.14.2. Specification 4.4.14.2. Specification
This option is specified in [RFC6744]. This option is specified in [RFC6744].
4.4.14.3. Specific Security Implications 4.4.14.3. Specific Security Implications
Those described in [RFC6744]. These are discussed in [RFC6744].
4.4.14.4. Operational and Interoperability Impact if Blocked 4.4.14.4. Operational and Interoperability Impact If Blocked
Discarding packets that contain this option will break INLPv6 Discarding packets that contain this option will break ILNPv6
deployments. deployments.
4.4.14.5. Advice 4.4.14.5. Advice
Intermediate systems should not discard packets based on the presence Intermediate systems should not discard packets based on the presence
of this option. of this option.
4.4.15. Line-Identification Option (Type=0x8C) 4.4.15. Line-Identification Option (Type=0x8C)
4.4.15.1. Uses 4.4.15.1. Uses
skipping to change at page 29, line 24 skipping to change at line 1352
This option is used by an Edge Router to identify the subscriber This option is used by an Edge Router to identify the subscriber
premises in scenarios where several subscriber premises may be premises in scenarios where several subscriber premises may be
logically connected to the same interface of an Edge Router. logically connected to the same interface of an Edge Router.
4.4.15.2. Specification 4.4.15.2. Specification
This option is specified in [RFC6788]. This option is specified in [RFC6788].
4.4.15.3. Specific Security Implications 4.4.15.3. Specific Security Implications
Those described in [RFC6788]. These are discussed in [RFC6788].
4.4.15.4. Operational and Interoperability Impact if Blocked 4.4.15.4. Operational and Interoperability Impact If Blocked
Since this option is meant to be employed in Router Solicitation Since this option is meant to be used when tunneling Neighbor
messages, discarding packets based on the presence of this option at Discovery messages in some broadband network deployment scenarios,
discarding packets based on the presence of this option at
intermediate systems will result in no interoperability implications. intermediate systems will result in no interoperability implications.
4.4.15.5. Advice 4.4.15.5. Advice
Intermediate devices should discard packets that contain this option. Intermediate systems should discard packets that contain this option.
4.4.16. Jumbo Payload (Type=0XC2) 4.4.16. Jumbo Payload (Type=0XC2)
4.4.16.1. Uses 4.4.16.1. Uses
The Jumbo payload option provides the means of specifying payloads The Jumbo Payload option provides the means for supporting payloads
larger than 65535 bytes. larger than 65535 bytes.
4.4.16.2. Specification 4.4.16.2. Specification
This option is specified in [RFC2675]. This option is specified in [RFC2675].
4.4.16.3. Specific Security Implications 4.4.16.3. Specific Security Implications
There are no specific issues arising from this option, except for There are no specific issues arising from this option, except for
improper validity checks of the option and associated packet lengths. improper validity checks of the option and associated packet lengths.
4.4.16.4. Operational and Interoperability Impact if Blocked 4.4.16.4. Operational and Interoperability Impact If Blocked
Discarding packets based on the presence of this option will cause Discarding packets based on the presence of this option will cause
IPv6 jumbograms to be discarded. IPv6 jumbograms to be discarded.
4.4.16.5. Advice 4.4.16.5. Advice
An operator should permit this option only in specific scenarios in An operator should permit this option only in specific scenarios in
which support for IPv6 jumbograms is desired. which support for IPv6 jumbograms is required.
4.4.17. Home Address (Type=0xC9) 4.4.17. Home Address (Type=0xC9)
4.4.17.1. Uses 4.4.17.1. Uses
The Home Address option is used by a Mobile IPv6 node while away from The Home Address option is used by a Mobile IPv6 node while away from
home, to inform the recipient of the mobile node's home address. home to inform the recipient of the mobile node's home address.
4.4.17.2. Specification 4.4.17.2. Specification
This option is specified in [RFC6275]. This option is specified in [RFC6275].
4.4.17.3. Specific Security Implications 4.4.17.3. Specific Security Implications
No (known) additional security implications than those described in There are no (known) additional security implications, other than
[RFC6275]. those discussed in [RFC6275].
4.4.17.4. Operational and Interoperability Impact if Blocked 4.4.17.4. Operational and Interoperability Impact If Blocked
Discarding IPv6 packets based on the presence of this option will Discarding IPv6 packets based on the presence of this option will
break Mobile IPv6. break Mobile IPv6.
4.4.17.5. Advice 4.4.17.5. Advice
Intermediate systems should not discard IPv6 packets based on the Intermediate systems should not discard IPv6 packets based on the
presence of this option. presence of this option.
4.4.18. IP_DFF (Type=0xEE) 4.4.18. IP_DFF (Type=0xEE)
4.4.18.1. Uses 4.4.18.1. Uses
This option is employed with the (Experimental) Depth-First This option is employed with the (experimental) Depth-First
Forwarding (DFF) in Unreliable Networks. Forwarding (DFF) in unreliable networks.
4.4.18.2. Specification 4.4.18.2. Specification
This option is specified in [RFC6971]. This option is specified in [RFC6971].
4.4.18.3. Specific Security Implications 4.4.18.3. Specific Security Implications
Those specified in [RFC6971]. These are specified in [RFC6971].
4.4.18.4. Operational and Interoperability Impact if Blocked 4.4.18.4. Operational and Interoperability Impact If Blocked
Dropping packets containing this option within a routing domain that Dropping packets containing this option within a routing domain that
is running DFF would break DFF. However, dropping such packets at is running DFF would break DFF. However, dropping such packets at
the border of such domains will have no security implications. the border of such domains will have no operational or
interoperability implications.
4.4.18.5. Advice 4.4.18.5. Advice
Intermediate systems that do not operate within a routing domain that Intermediate systems that do not operate within a routing domain that
is running DFF should discard packets containing this option. is running DFF should discard packets containing this option.
4.4.19. RFC3692-style Experiment (Types = 0x1E, 0x3E, 0x5E, 0x7E, 0x9E, 4.4.19. RFC3692-Style Experiment (Types = 0x1E, 0x3E, 0x5E, 0x7E, 0x9E,
0xBE, 0xDE, 0xFE) 0xBE, 0xDE, 0xFE)
4.4.19.1. Uses 4.4.19.1. Uses
These options can be employed for performing RFC3692-style These options can be employed for performing RFC3692-style
experiments. It is only appropriate to use these values in experiments. It is only appropriate to use these values in
explicitly configured experiments; they must not be shipped as explicitly configured experiments; they must not be shipped as
defaults in implementations. defaults in implementations.
4.4.19.2. Specification 4.4.19.2. Specification
Specified in RFC 4727 [RFC4727] in the context of RFC3692-style These options are specified in [RFC4727] in the context of
experiments. RFC3692-style experiments.
4.4.19.3. Specific Security Implications 4.4.19.3. Specific Security Implications
The specific security implications will depend on the specific use of The specific security implications will depend on the specific use of
these options. these options.
4.4.19.4. Operational and Interoperability Impact if Blocked 4.4.19.4. Operational and Interoperability Impact If Blocked
For obvious reasons, discarding packets that contain these options For obvious reasons, discarding packets that contain these options
limits the ability to perform legitimate experiments across IPv6 limits the ability to perform legitimate experiments across IPv6
routers. routers.
4.4.19.5. Advice 4.4.19.5. Advice
Operators should determine according to their own circumstances Operators should determine, according to their own circumstances,
whether to discard packets containing these IPv6 options. whether to discard packets containing these IPv6 options.
4.5. Advice on the handling of Packets with Unknown IPv6 Options 4.5. Advice on the Handling of Packets with Unknown IPv6 Options
We refer to IPv6 options that have not been assigned an IPv6 option We refer to IPv6 options that have not been assigned an IPv6 Option
type in the corresponding registry ([IANA-IPV6-PARAM]) as "unknown Type in the corresponding registry, which is [IANA-IPV6-PARAM], as
IPv6 options". "unknown IPv6 options".
4.5.1. Uses 4.5.1. Uses
New IPv6 options may be specified as part of future protocol work. New IPv6 options may be specified as part of future protocol work.
4.5.2. Specification 4.5.2. Specification
The processing of unknown IPv6 options is specified in [RFC8200]. The processing of unknown IPv6 options is specified in [RFC8200].
4.5.3. Specific Security Implications 4.5.3. Specific Security Implications
For obvious reasons, it is impossible to determine specific security For obvious reasons, it is impossible to determine specific security
implications of unknown IPv6 options. implications of unknown IPv6 options.
4.5.4. Operational and Interoperability Impact if Blocked 4.5.4. Operational and Interoperability Impact If Blocked
Discarding unknown IPv6 options may slow down the deployment of new Discarding unknown IPv6 options may slow down the deployment of new
IPv6 options. As noted in [draft-gont-6man-ipv6-opt-transmit], the IPv6 options. As noted in [IPv6-OPTIONS], the corresponding IANA
corresponding IANA registry ([IANA-IPV6-PARAM] should be monitored registry, which is [IANA-IPV6-PARAM], should be monitored such that
such that IPv6 option filtering rules are updated as new IPv6 options IPv6 option filtering rules are updated as new IPv6 options are
are standardized. standardized.
4.5.5. Advice 4.5.5. Advice
Operators should determine according to their own circumstances Operators should determine, according to their own circumstances,
whether to discard packets containing unknown IPv6 options. whether to discard packets containing unknown IPv6 options.
5. IANA Considerations 5. IANA Considerations
This document has no actions for IANA. This document has no IANA actions.
6. Privacy Considerations 6. Privacy Considerations
There are no privacy considerations associated with this document. There are no privacy considerations associated with this document.
7. Security Considerations 7. Security Considerations
This document provides advice on the filtering of IPv6 packets that This document provides advice on the filtering of IPv6 packets that
contain IPv6 EHs (and possibly IPv6 options) at IPv6 transit routers. contain IPv6 EHs (and possibly IPv6 options) at IPv6 transit routers.
It is meant to improve the current situation of widespread dropping It is meant to improve the current situation of widespread dropping
of such IPv6 packets in those cases where the drops result from of such IPv6 packets in those cases where the drops result from
improper configuration defaults, or inappropriate advice in this improper configuration defaults or inappropriate advice in this area.
area.
As discussed in Section Section 3.3 of this document, one of the As discussed in Section 3.3, one of the underlying principles for the
underlying principles for the advice provided in this document is advice provided in this document is that IPv6 packets with specific
that IPv6 packets with specific EHs or options which may represent an EHs or options that may represent an attack vector for infrastructure
attack vector for infrastructure devices should be dropped. While devices should be dropped. While this policy helps mitigate some
this policy helps mitigate some specific attack vectors, the specific attack vectors, the recommendations in this document will
recommendations in this document will not help to mitigate not help to mitigate vulnerabilities based on implementation errors
vulnerabilities based on implementation errors [RFC9098]. [RFC9098].
We also note that depending on the router architecture, attempts to We also note that depending on the router architecture, attempts to
filter packets ased on the presence of IPv6 EHs or options might filter packets based on the presence of IPv6 EHs or options might
itself represent an attack vector to network infrastructure devices itself represent an attack vector to network infrastructure devices
[RFC9098]. [RFC9098].
8. Acknowledgements 8. References
The authors would like to thank Ron Bonica for his work on earlier
versions of this document.
The authors of this document would like to thank (in alphabetical
order) Mikael Abrahamsson, Brian Carpenter, Tim Chown, Roman Danyliw,
Darren Dukes, Lars Eggert, David Farmer, Mike Heard, Bob Hinden,
Christian Huitema, Benjamin Kaduk, Erik Kline, Murray Kucherawy, Jen
Linkova, Carlos Pignataro, Alvaro Retana, Maria Ines Robles,
Zaheduzzaman Sarker, Donald Smith, Pascal Thubert, Ole Troan, Gunter
Van De Velde, Eric Vyncke, and Robert Wilton, for providing valuable
comments on earlier versions of this document.
This document borrows some text and analysis from [RFC7126], authored
by Fernando Gont, Randall Atkinson, and Carlos Pignataro.
The authors would like to thank Warren Kumari and Eric Vyncke for
their guidance during the publication process of this document.
Fernando would also like to thank Brian Carpenter and Ran Atkinson
who, over the years, have answered many questions and provided
valuable comments that have benefited his protocol-related work
(including the present document).
9. References
9.1. Normative References 8.1. Normative References
[RFC1034] Mockapetris, P., "Domain names - concepts and facilities", [RFC1034] Mockapetris, P V., "Domain names - concepts and
STD 13, RFC 1034, DOI 10.17487/RFC1034, November 1987, facilities", STD 13, RFC 1034, DOI 10.17487/RFC1034,
<https://www.rfc-editor.org/info/rfc1034>. November 1987, <https://www.rfc-editor.org/info/rfc1034>.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997, DOI 10.17487/RFC2119, March 1997,
<https://www.rfc-editor.org/info/rfc2119>. <https://www.rfc-editor.org/info/rfc2119>.
[RFC2205] Braden, R., Ed., Zhang, L., Berson, S., Herzog, S., and S. [RFC2205] Braden, R., Ed., Zhang, L., Berson, S., Herzog, S., and S.
Jamin, "Resource ReSerVation Protocol (RSVP) -- Version 1 Jamin, "Resource ReSerVation Protocol (RSVP) -- Version 1
Functional Specification", RFC 2205, DOI 10.17487/RFC2205, Functional Specification", RFC 2205, DOI 10.17487/RFC2205,
September 1997, <https://www.rfc-editor.org/info/rfc2205>. September 1997, <https://www.rfc-editor.org/info/rfc2205>.
skipping to change at page 37, line 38 skipping to change at line 1718
[RFC8754] Filsfils, C., Ed., Dukes, D., Ed., Previdi, S., Leddy, J., [RFC8754] Filsfils, C., Ed., Dukes, D., Ed., Previdi, S., Leddy, J.,
Matsushima, S., and D. Voyer, "IPv6 Segment Routing Header Matsushima, S., and D. Voyer, "IPv6 Segment Routing Header
(SRH)", RFC 8754, DOI 10.17487/RFC8754, March 2020, (SRH)", RFC 8754, DOI 10.17487/RFC8754, March 2020,
<https://www.rfc-editor.org/info/rfc8754>. <https://www.rfc-editor.org/info/rfc8754>.
[RFC8900] Bonica, R., Baker, F., Huston, G., Hinden, R., Troan, O., [RFC8900] Bonica, R., Baker, F., Huston, G., Hinden, R., Troan, O.,
and F. Gont, "IP Fragmentation Considered Fragile", and F. Gont, "IP Fragmentation Considered Fragile",
BCP 230, RFC 8900, DOI 10.17487/RFC8900, September 2020, BCP 230, RFC 8900, DOI 10.17487/RFC8900, September 2020,
<https://www.rfc-editor.org/info/rfc8900>. <https://www.rfc-editor.org/info/rfc8900>.
[RFC9008] Robles, M.I., Richardson, M., and P. Thubert, "Using RPI [RFC9008] Robles, M I., Richardson, M., and P. Thubert, "Using RPI
Option Type, Routing Header for Source Routes, and IPv6- Option Type, Routing Header for Source Routes, and IPv6-
in-IPv6 Encapsulation in the RPL Data Plane", RFC 9008, in-IPv6 Encapsulation in the RPL Data Plane", RFC 9008,
DOI 10.17487/RFC9008, April 2021, DOI 10.17487/RFC9008, April 2021,
<https://www.rfc-editor.org/info/rfc9008>. <https://www.rfc-editor.org/info/rfc9008>.
9.2. Informative References 8.2. Informative References
[Biondi2007] [Biondi-2007]
Biondi, P. and A. Ebalard, "IPv6 Routing Header Security", Biondi, P. and A. Ebalard, "IPv6 Routing Header Security",
CanSecWest 2007 Security Conference, 2007, CanSecWest Security Conference, April 2007,
<http://www.secdev.org/conf/IPv6_RH_security-csw07.pdf>. <http://www.secdev.org/conf/IPv6_RH_security-csw07.pdf>.
[Cisco-EH] Cisco Systems, "IPv6 Extension Headers Review and [Cisco-EH] Cisco Systems, "IPv6 Extension Headers Review and
Considerations", Whitepaper. October 2006, Considerations", Whitepaper, October 2006,
<https://www.cisco.com/en/US/technologies/tk648/tk872/ <https://www.cisco.com/en/US/technologies/tk648/tk872/
technologies_white_paper0900aecd8054d37d.pdf>. technologies_white_paper0900aecd8054d37d.pdf>.
[draft-gont-6man-ipv6-opt-transmit]
Gont, F., Liu, W., and R. Bonica, "Transmission and
Processing of IPv6 Options", IETF Internet Draft, work in
progress, August 2014.
[draft-ietf-nimrod-eid]
Lynn, C.L., "Endpoint Identifier Destination
Option", IETF Internet Draft, draft-ietf-nimrod-eid-
00.txt, November 1995.
[FW-Benchmark] [FW-Benchmark]
Zack, E., "Firewall Security Assessment and Benchmarking Zack, E., "Firewall Security Assessment and Benchmarking
IPv6 Firewall Load Tests", IPv6 Hackers Meeting #1, IPv6 Firewall Load Tests", IPv6 Hackers Meeting #1,
Berlin, Germany. June 30, 2013, Berlin, Germany, June 2013,
<https://www.ipv6hackers.org/files/meetings/ipv6-hackers- <https://www.ipv6hackers.org/files/meetings/ipv6-hackers-
1/zack-ipv6hackers1-firewall-security-assessment-and- 1/zack-ipv6hackers1-firewall-security-assessment-and-
benchmarking.pdf>. benchmarking.pdf>.
[Huston-2022] [Huston-2022]
Huston, G. and J. Damas, "IPv6 Fragmentation and EH Huston, G. and J. Damas, "IPv6 Fragmentation and EH
Behaviours", IEPG Meeting - March 2022 @ IETF 113, March Behaviours", IEPG Meeting at IETF 113", March 2022,
2022,
<https://iepg.org/2022-03-20-ietf113/huston-v6frag.pdf>. <https://iepg.org/2022-03-20-ietf113/huston-v6frag.pdf>.
[I-D.irtf-pearg-numeric-ids-generation]
Gont, F. and I. Arce, "On the Generation of Transient
Numeric Identifiers", Work in Progress, Internet-Draft,
draft-irtf-pearg-numeric-ids-generation-08, 31 January
2022, <https://www.ietf.org/archive/id/draft-irtf-pearg-
numeric-ids-generation-08.txt>.
[I-D.vyncke-v6ops-james]
Vyncke, É., Léas, R., and J. Iurman, "Just Another
Measurement of Extension header Survivability (JAMES)",
Work in Progress, Internet-Draft, draft-vyncke-v6ops-
james-01, 19 March 2022, <https://www.ietf.org/archive/id/
draft-vyncke-v6ops-james-01.txt>.
[IANA-IPV6-PARAM] [IANA-IPV6-PARAM]
Internet Assigned Numbers Authority, "Internet Protocol IANA, "Internet Protocol Version 6 (IPv6) Parameters",
Version 6 (IPv6) Parameters", December 2013, <https://www.iana.org/assignments/ipv6-parameters>.
<https://www.iana.org/assignments/ipv6-parameters/
ipv6-parameters.xhtml>.
[IANA-PROTOCOLS] [IANA-PROTOCOLS]
Internet Assigned Numbers Authority, "Protocol Numbers", IANA, "Protocol Numbers",
2014, <https://www.iana.org/assignments/protocol-numbers/ <https://www.iana.org/assignments/protocol-numbers>.
protocol-numbers.xhtml>.
[IPv6-OPTIONS]
Gont, F., Liu, W., and R. P. Bonica, "Transmission and
Processing of IPv6 Options", Work in Progress, Internet-
Draft, draft-gont-6man-ipv6-opt-transmit-02, 21 August
2015, <https://datatracker.ietf.org/doc/html/draft-gont-
6man-ipv6-opt-transmit-02>.
[JAMES] Iurman, J., "Just Another Measurement of Extension header
Survivability (JAMES)", Work in Progress, Internet-Draft,
draft-vyncke-v6ops-james-02, 11 July 2022,
<https://datatracker.ietf.org/doc/html/draft-vyncke-v6ops-
james-02>.
[NIMROD-DOC] [NIMROD-DOC]
Nimrod Documentation Page, "Nimrod Documentation",
"http://ana-3.lcs.mit.edu/~jnc/nimrod/". <http://ana-3.lcs.mit.edu/~jnc/nimrod>.
[NIMROD-EID]
Lynn, C., "Endpoint Identifier Destination Option", Work
in Progress, Internet-Draft, draft-ietf-nimrod-eid-00, 2
March 1996, <https://datatracker.ietf.org/doc/html/draft-
ietf-nimrod-eid-00>.
[NUMERIC-IDS]
Gont, F. and I. Arce, "On the Generation of Transient
Numeric Identifiers", Work in Progress, Internet-Draft,
draft-irtf-pearg-numeric-ids-generation-11, 11 July 2022,
<https://datatracker.ietf.org/doc/html/draft-irtf-pearg-
numeric-ids-generation-11>.
[RFC2460] Deering, S. and R. Hinden, "Internet Protocol, Version 6 [RFC2460] Deering, S. and R. Hinden, "Internet Protocol, Version 6
(IPv6) Specification", RFC 2460, DOI 10.17487/RFC2460, (IPv6) Specification", RFC 2460, DOI 10.17487/RFC2460,
December 1998, <https://www.rfc-editor.org/info/rfc2460>. December 1998, <https://www.rfc-editor.org/info/rfc2460>.
[RFC3871] Jones, G., Ed., "Operational Security Requirements for [RFC3871] Jones, G., Ed., "Operational Security Requirements for
Large Internet Service Provider (ISP) IP Network Large Internet Service Provider (ISP) IP Network
Infrastructure", RFC 3871, DOI 10.17487/RFC3871, September Infrastructure", RFC 3871, DOI 10.17487/RFC3871, September
2004, <https://www.rfc-editor.org/info/rfc3871>. 2004, <https://www.rfc-editor.org/info/rfc3871>.
skipping to change at page 39, line 47 skipping to change at line 1820
"Observations on the Dropping of Packets with IPv6 "Observations on the Dropping of Packets with IPv6
Extension Headers in the Real World", RFC 7872, Extension Headers in the Real World", RFC 7872,
DOI 10.17487/RFC7872, June 2016, DOI 10.17487/RFC7872, June 2016,
<https://www.rfc-editor.org/info/rfc7872>. <https://www.rfc-editor.org/info/rfc7872>.
[RFC9098] Gont, F., Hilliard, N., Doering, G., Kumari, W., Huston, [RFC9098] Gont, F., Hilliard, N., Doering, G., Kumari, W., Huston,
G., and W. Liu, "Operational Implications of IPv6 Packets G., and W. Liu, "Operational Implications of IPv6 Packets
with Extension Headers", RFC 9098, DOI 10.17487/RFC9098, with Extension Headers", RFC 9098, DOI 10.17487/RFC9098,
September 2021, <https://www.rfc-editor.org/info/rfc9098>. September 2021, <https://www.rfc-editor.org/info/rfc9098>.
Acknowledgements
The authors would like to thank Ron Bonica for his work on earlier
draft versions of this document.
The authors of this document would like to thank (in alphabetical
order) Mikael Abrahamsson, Brian Carpenter, Tim Chown, Roman Danyliw,
Darren Dukes, Lars Eggert, David Farmer, Mike Heard, Bob Hinden,
Christian Huitema, Benjamin Kaduk, Erik Kline, Murray Kucherawy, Jen
Linkova, Carlos Pignataro, Alvaro Retana, Maria Ines Robles,
Zaheduzzaman Sarker, Donald Smith, Pascal Thubert, Ole Troan, Gunter
Van de Velde, Éric Vyncke, and Robert Wilton for providing valuable
comments on earlier draft versions of this document.
This document borrows some text and analysis from [RFC7126], which is
authored by Fernando Gont, Randall Atkinson, and Carlos Pignataro.
The authors would like to thank Warren Kumari and Éric Vyncke for
their guidance during the publication process for this document.
Fernando would also like to thank Brian Carpenter and Ran Atkinson
who, over the years, have answered many questions and provided
valuable comments that have benefited his protocol-related work
(including the present document).
Authors' Addresses Authors' Addresses
Fernando Gont Fernando Gont
EdgeUno SI6 Networks
Segurola y Habana 4310, 7mo Piso Segurola y Habana 4310 7mo piso
Villa Devoto
Ciudad Autonoma de Buenos Aires Ciudad Autonoma de Buenos Aires
Argentina Argentina
Email: fernando.gont@edgeuno.com Email: fgont@si6networks.com
URI: https://www.edgeuno.com URI: https://www.si6networks.com
Will (Shucheng) Liu Will (Shucheng) Liu
Huawei Technologies Huawei Technologies
Bantian, Longgang District Bantian, Longgang District
Shenzhen Shenzhen
518129 518129
P.R. China China
Email: liushucheng@huawei.com Email: liushucheng@huawei.com
 End of changes. 204 change blocks. 
514 lines changed or deleted 531 lines changed or added

This html diff was produced by rfcdiff 1.48.