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+Internet Engineering Task Force (IETF) D. Eastlake 3rd
+Request for Comments: 7780 M. Zhang
+Obsoletes: 7180 Huawei
+Updates: 6325, 7177, 7179 R. Perlman
+Category: Standards Track EMC
+ISSN: 2070-1721 A. Banerjee
+ Cisco
+ A. Ghanwani
+ Dell
+ S. Gupta
+ IP Infusion
+ February 2016
+
+
+ Transparent Interconnection of Lots of Links (TRILL):
+ Clarifications, Corrections, and Updates
+
+Abstract
+
+ Since the publication of the TRILL (Transparent Interconnection of
+ Lots of Links) base protocol in 2011, active development and
+ deployment of TRILL have revealed errata in RFC 6325 and areas that
+ could use clarifications or updates. RFC 7177, RFC 7357, and an
+ intended replacement of RFC 6439 provide clarifications and updates
+ with respect to adjacency, the TRILL ESADI (End Station Address
+ Distribution Information) protocol, and Appointed Forwarders,
+ respectively. This document provides other known clarifications,
+ corrections, and updates. It obsoletes RFC 7180 (the previous "TRILL
+ clarifications, corrections, and updates" RFC), and it updates RFCs
+ 6325, 7177, and 7179.
+
+Status of This Memo
+
+ This is an Internet Standards Track document.
+
+ This document is a product of the Internet Engineering Task Force
+ (IETF). It represents the consensus of the IETF community. It has
+ received public review and has been approved for publication by the
+ Internet Engineering Steering Group (IESG). Further information on
+ Internet Standards is available in Section 2 of RFC 5741.
+
+ Information about the current status of this document, any errata,
+ and how to provide feedback on it may be obtained at
+ http://www.rfc-editor.org/info/rfc7780.
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 1]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+Copyright Notice
+
+ Copyright (c) 2016 IETF Trust and the persons identified as the
+ document authors. All rights reserved.
+
+ This document is subject to BCP 78 and the IETF Trust's Legal
+ Provisions Relating to IETF Documents
+ (http://trustee.ietf.org/license-info) in effect on the date of
+ publication of this document. Please review these documents
+ carefully, as they describe your rights and restrictions with respect
+ to this document. Code Components extracted from this document must
+ include Simplified BSD License text as described in Section 4.e of
+ the Trust Legal Provisions and are provided without warranty as
+ described in the Simplified BSD License.
+
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+Eastlake, et al. Standards Track [Page 2]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+Table of Contents
+
+ 1. Introduction (Changed) ..........................................5
+ 1.1. Precedence (Changed) .......................................5
+ 1.2. Changes That Are Not Backward Compatible (Unchanged) .......6
+ 1.3. Terminology and Acronyms (Changed) .........................6
+ 2. Overloaded and/or Unreachable RBridges (Unchanged) ..............7
+ 2.1. Reachability ...............................................8
+ 2.2. Distribution Trees .........................................8
+ 2.3. Overloaded Receipt of TRILL Data Packets ...................9
+ 2.3.1. Known Unicast Receipt ...............................9
+ 2.3.2. Multi-Destination Receipt ...........................9
+ 2.4. Overloaded Origination of TRILL Data Packets ...............9
+ 2.4.1. Known Unicast Origination ..........................10
+ 2.4.2. Multi-Destination Origination ......................10
+ 2.4.2.1. An Example Network ........................10
+ 2.4.2.2. Indicating OOMF Support ...................11
+ 2.4.2.3. Using OOMF Service ........................11
+ 3. Distribution Trees and RPF Check (Changed) .....................12
+ 3.1. Number of Distribution Trees (Unchanged) ..................12
+ 3.2. Distribution Tree Update Clarification (Unchanged) ........12
+ 3.3. Multicast Pruning Based on IP Address (Unchanged) .........13
+ 3.4. Numbering of Distribution Trees (Unchanged) ...............13
+ 3.5. Link Cost Directionality (Unchanged) ......................13
+ 3.6. Alternative RPF Check (New) ...............................14
+ 3.6.1. Example of the Potential Problem ...................14
+ 3.6.2. Solution and Discussion ............................15
+ 4. Nickname Selection (Unchanged) .................................17
+ 5. MTU (Maximum Transmission Unit) (Unchanged) ....................18
+ 5.1. MTU-Related Errata in RFC 6325 ............................19
+ 5.1.1. MTU PDU Addressing .................................19
+ 5.1.2. MTU PDU Processing .................................20
+ 5.1.3. MTU Testing ........................................20
+ 5.2. Ethernet MTU Values .......................................20
+ 6. TRILL Port Modes (Unchanged) ...................................21
+ 7. The CFI/DEI Bit (Unchanged) ....................................22
+ 8. Other IS-IS Considerations (Changed) ...........................23
+ 8.1. E-L1FS Support (New) ......................................24
+ 8.1.1. Backward Compatibility .............................24
+ 8.1.2. E-L1FS Use for Existing (Sub-)TLVs .................25
+ 8.2. Control Packet Priorities (New) ...........................26
+ 8.3. Unknown PDUs (New) ........................................27
+ 8.4. Nickname Flags APPsub-TLV (New) ...........................27
+ 8.5. Graceful Restart (Unchanged) ..............................29
+ 8.6. Purge Originator Identification (New) .....................29
+ 9. Updates to RFC 7177 (Adjacency) (Changed) ......................30
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 3]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ 10. TRILL Header Update (New) .....................................31
+ 10.1. Color Bit ................................................32
+ 10.2. Flags Word Changes (Update to RFC 7179) ..................32
+ 10.2.1. Extended Hop Count ................................32
+ 10.2.1.1. Advertising Support ......................33
+ 10.2.1.2. Ingress Behavior .........................33
+ 10.2.1.3. Transit Behavior .........................33
+ 10.2.1.4. Egress Behavior ..........................34
+ 10.2.2. Extended Color Field ..............................34
+ 10.3. Updated Flags Word Summary ...............................35
+ 11. Appointed Forwarder Status Lost Counter (New) .................35
+ 12. IANA Considerations (Changed) .................................37
+ 12.1. Previously Completed IANA Actions (Unchanged) ............37
+ 12.2. New IANA Actions (New) ...................................37
+ 12.2.1. Reference Updated .................................37
+ 12.2.2. The "E" Capability Bit ............................37
+ 12.2.3. NickFlags APPsub-TLV Number and Registry ..........38
+ 12.2.4. Updated TRILL Extended Header Flags ...............38
+ 12.2.5. TRILL-VER Sub-TLV Capability Flags ................39
+ 12.2.6. Example Nicknames .................................39
+ 13. Security Considerations (Changed) .............................39
+ 14. References ....................................................40
+ 14.1. Normative References .....................................40
+ 14.2. Informative References ...................................42
+ Appendix A. Life Cycle of a TRILL Switch Port (New) ...............45
+ Appendix B. Example TRILL PDUs (New) ..............................48
+ B.1. LAN Hello over Ethernet ...................................48
+ B.2. LSP over PPP ..............................................50
+ B.3. TRILL Data over Ethernet ..................................51
+ B.4. TRILL Data over PPP .......................................52
+ Appendix C. Changes to Previous RFCs (New) ........................53
+ C.1. Changes to Obsoleted RFC 7180 .............................53
+ C.1.1. Changes ..............................................53
+ C.1.2. Additions ............................................53
+ C.1.3. Deletions ............................................54
+ C.2. Changes to RFC 6325 .......................................55
+ C.3. Changes to RFC 7177 .......................................55
+ C.4. Changes to RFC 7179 .......................................55
+ Acknowledgments ...................................................56
+ Authors' Addresses ................................................56
+
+
+
+
+
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+
+
+Eastlake, et al. Standards Track [Page 4]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+1. Introduction (Changed)
+
+ Since the TRILL base protocol [RFC6325] was published in 2011, active
+ development and deployment of TRILL have revealed errors in the
+ specification [RFC6325] and several areas that could use
+ clarifications or updates.
+
+ [RFC7177], [RFC7357], and [RFC6439bis] provide clarifications and
+ updates with respect to adjacency, the TRILL ESADI (End Station
+ Address Distribution Information) protocol, and Appointed Forwarders,
+ respectively. This document provides other known clarifications,
+ corrections, and updates to [RFC6325], [RFC7177], and [RFC7179].
+ This document obsoletes [RFC7180] (the previous TRILL
+ "clarifications, corrections, and updates" document), updates
+ [RFC6325], updates [RFC7177] as described in Section 9, and updates
+ [RFC7179] as described in Sections 10.2 and 10.3. The changes to
+ these RFCs are summarized in Appendix C.
+
+ Sections of this document are annotated as to whether they are "New"
+ technical material, material that has been technically "Changed", or
+ material that is technically "Unchanged", by the appearance of one of
+ these three words in parentheses at the end of the section header. A
+ section with only editorial changes is annotated as "(Unchanged)".
+ If no such notation appears, then the first notation encountered on
+ going to successively higher-level section headers (those with
+ shorter section numbers) applies. Appendix C describes changes,
+ summarizes material added, and lists material deleted.
+
+1.1. Precedence (Changed)
+
+ In the event of any conflicts between this document and [RFC6325],
+ [RFC7177], or [RFC7179], this document takes precedence.
+
+ In addition, Section 1.2 of [RFC6325] ("Normative Content and
+ Precedence") is updated to provide a more complete precedence
+ ordering of the sections of [RFC6325], as shown below, where sections
+ to the left take precedence over sections to their right. There are
+ no known conflicts between these sections; however, Sections 1 and 2
+ are less detailed and do not mention every corner case, while
+ subsequent sections of [RFC6325] are more detailed. This precedence
+ is specified as a fallback in case some conflict is found in the
+ future.
+
+ 4 > 3 > 7 > 5 > 2 > 6 > 1
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 5]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+1.2. Changes That Are Not Backward Compatible (Unchanged)
+
+ The change made by Section 3.4 below (unchanged from Section 3.4 of
+ [RFC7180]) is not backward compatible with [RFC6325] but has
+ nevertheless been adopted to reduce distribution tree changes
+ resulting from topology changes.
+
+ Several other changes herein that are fixes to errata for [RFC6325]
+ -- [Err3002], [Err3003], [Err3004], [Err3052], [Err3053], and
+ [Err3508] -- may not be backward compatible with previous
+ implementations that conformed to errors in the specification.
+
+1.3. Terminology and Acronyms (Changed)
+
+ This document uses the acronyms defined in [RFC6325], some of which
+ are repeated below for convenience, along with some additional
+ acronyms and terms, as follows:
+
+ BFD - Bidirectional Forwarding Detection.
+
+ Campus - A TRILL network consisting of TRILL switches, links, and
+ possibly bridges bounded by end stations and IP routers. For
+ TRILL, there is no "academic" implication in the name "campus".
+
+ CFI - Canonical Format Indicator [802].
+
+ CSNP - Complete Sequence Number PDU.
+
+ DEI - Drop Eligibility Indicator [802.1Q-2014].
+
+ FGL - Fine-Grained Labeling [RFC7172].
+
+ FS-LSP - Flooding Scope LSP.
+
+ OOMF - Overload Originated Multi-destination Frame.
+
+ P2P - Point-to-point.
+
+ PDU - Protocol Data Unit.
+
+ PSNP - Partial Sequence Number PDU.
+
+ RBridge - Routing Bridge, an alternative name for a TRILL switch.
+
+ RPFC - Reverse Path Forwarding Check.
+
+ SNPA - Subnetwork Point of Attachment (for example, Media Access
+ Control (MAC) address).
+
+
+
+Eastlake, et al. Standards Track [Page 6]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ ToS - Type of Service.
+
+ TRILL - Transparent Interconnection of Lots of Links or Tunneled
+ Routing in the Link Layer.
+
+ TRILL switch - A device implementing the TRILL protocol. An
+ alternative name for an RBridge.
+
+ The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
+ "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
+ "OPTIONAL" in this document are to be interpreted as described in
+ [RFC2119].
+
+ In this document, a "packet" usually refers to a TRILL Data packet or
+ TRILL IS-IS packet received from or sent to a TRILL switch, while a
+ "frame" usually refers to a native frame being received from or sent
+ to an end station. (The word "frame" also occurs in other contexts,
+ such as the "Frame Check Sequence" that is at the end of Ethernet
+ transmissions.)
+
+2. Overloaded and/or Unreachable RBridges (Unchanged)
+
+ In this section, the term "neighbor" refers only to actual RBridges
+ and ignores pseudonodes.
+
+ RBridges may be in overload, as indicated by the [IS-IS] overload
+ flag in their LSPs (Link State PDUs). This means that either (1)
+ they are incapable of holding the entire link-state database and thus
+ do not have a view of the entire topology or (2) they have been
+ configured to have the overload bit set. Although networks should be
+ engineered to avoid actual link-state overload, it might occur under
+ various circumstances -- for example, if a very large campus included
+ one or more low-end TRILL switches.
+
+ It is a common operational practice to set the overload bit in an
+ [IS-IS] router (such as a TRILL switch) when performing maintenance
+ on that router that might affect its ability to correctly forward
+ packets; this will usually leave the router reachable for maintenance
+ traffic, but transit traffic will not be routed through it. (Also,
+ in some cases, TRILL provides for setting the overload bit in the
+ pseudonode of a link to stop TRILL Data traffic on an access link
+ (see Section 4.9.1 of [RFC6325]).)
+
+ [IS-IS] and TRILL make a reasonable effort to do what they can, even
+ if some TRILL switches/routers are in overload. They can do
+ reasonably well if a few scattered nodes are in overload. However,
+ actual least-cost paths are no longer assured if any TRILL switches
+ are in overload.
+
+
+
+Eastlake, et al. Standards Track [Page 7]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ For the effect of overload on the appointment of forwarders, see
+ [RFC6439bis].
+
+2.1. Reachability
+
+ Packets are not least-cost routed through an overloaded TRILL switch,
+ although they may originate or terminate at an overloaded TRILL
+ switch. In addition, packets will not be least-cost routed over
+ links with cost 2**24 - 1 [RFC5305]; such links are reserved for
+ traffic-engineered packets, the handling of which is beyond the scope
+ of this document.
+
+ As a result, a portion of the campus may be unreachable for
+ least-cost routed TRILL Data because all paths to it would be either
+ through a link with cost 2**24 - 1 or through an overloaded RBridge.
+ For example, an RBridge (TRILL switch) RB1 is not reachable by TRILL
+ Data if all of its neighbors are connected to RB1 by links with cost
+ 2**24 - 1. Such RBridges are called "data unreachable".
+
+ The link-state database at an RBridge -- for example, RB1 -- can also
+ contain information on TRILL switches that are unreachable by IS-IS
+ link-state flooding due to link or RBridge failures. When such
+ failures partition the campus, the TRILL switches adjacent to the
+ failure and on the same side of the failure as RB1 will update their
+ LSPs to show the lack of connectivity, and RB1 will receive those
+ updates. As a result, RB1 will be aware of the partition. Nodes on
+ the far side of the partition are both IS-IS unreachable and data
+ unreachable from RB1. However, LSPs held by RB1 for TRILL switches
+ on the far side of the failure will not be updated and may stay
+ around until they time out, which could be tens of minutes or longer.
+ (The default in [IS-IS] is twenty minutes.)
+
+2.2. Distribution Trees
+
+ An RBridge in overload cannot be trusted to correctly calculate
+ distribution trees or correctly perform the RPFC (Reverse Path
+ Forwarding Check). Therefore, it cannot be trusted to forward
+ multi-destination TRILL Data packets. It can only appear as a leaf
+ node in a TRILL multi-destination distribution tree. Furthermore, if
+ all the immediate neighbors of an RBridge are overloaded, then it is
+ omitted from all trees in the campus and is unreachable by
+ multi-destination packets.
+
+ When an RBridge determines what nicknames to use as the roots of the
+ distribution trees it calculates, it MUST ignore all nicknames held
+ by TRILL switches that are in overload or are data unreachable. When
+ calculating RPFCs for multi-destination packets, an RBridge such as
+ RB1 MAY, to avoid calculating unnecessary RPFC state information,
+
+
+
+Eastlake, et al. Standards Track [Page 8]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ ignore any trees that cannot reach RB1, even if other RBridges list
+ those trees as trees that other TRILL switches might use. (However,
+ see Section 3.)
+
+2.3. Overloaded Receipt of TRILL Data Packets
+
+ The receipt of TRILL Data packets by overloaded RBridge RB2 is
+ discussed in the subsections below. In all cases, the normal
+ Hop Count decrement is performed, and the TRILL Data packets are
+ discarded if the result is less than one or if the Egress Nickname is
+ illegal.
+
+2.3.1. Known Unicast Receipt
+
+ RB2 will not usually receive unicast TRILL Data packets unless it is
+ the egress, in which case it egresses and delivers the data normally.
+ If RB2 receives a unicast TRILL Data packet for which it is not the
+ egress, perhaps because a neighbor does not yet know it is in
+ overload, RB2 MUST NOT discard the packet because the egress is an
+ unknown nickname, as it might not know about all nicknames due to its
+ overloaded condition. If any neighbor other than the neighbor from
+ which it received the packet is not overloaded, it MUST attempt to
+ forward the packet to one of those neighbors selected at random
+ [RFC4086]. If there is no such neighbor, the packet is discarded.
+
+2.3.2. Multi-Destination Receipt
+
+ If RB2 in overload receives a multi-destination TRILL Data packet,
+ RB2 MUST NOT apply an RPFC because, due to overload, it might not do
+ so correctly. RB2 egresses and delivers the frame locally where it
+ is Appointed Forwarder for the frame's VLAN (or, if the packet is
+ FGL, for the VLAN that FGL maps to at the port), subject to any
+ multicast pruning. But because, as stated above, RB2 can only be the
+ leaf of a distribution tree, it MUST NOT forward a multi-destination
+ TRILL Data packet (except as an egressed native frame where RB2 is
+ Appointed Forwarder).
+
+2.4. Overloaded Origination of TRILL Data Packets
+
+ Overloaded origination of unicast TRILL Data packets with known
+ egress and of multi-destination packets is discussed in the
+ subsections below.
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 9]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+2.4.1. Known Unicast Origination
+
+ When RB2, an overloaded RBridge, ingresses or creates a known
+ destination unicast data packet, it delivers it locally if the
+ destination is local. Otherwise, RB2 unicasts it to any neighbor
+ TRILL switch that is not overloaded. It MAY use what routing
+ information it has to help select the neighbor.
+
+2.4.2. Multi-Destination Origination
+
+ Overloaded RBridge RB2 ingressing or creating a multi-destination
+ data packet presents a more complex scenario than that of the known
+ unicast case, as discussed below.
+
+2.4.2.1. An Example Network
+
+ For example, consider the network diagram below in which, for
+ simplicity, end stations and any bridges are not shown. There is one
+ distribution tree of which RB4 is the root, as represented by double
+ lines. Only RBridge RB2 is overloaded.
+
+ +-----+ +-----+ +-----+ +-----+
+ | RB7 +====+ RB5 +=====+ RB3 +=====+ RB1 |
+ +-----+ +--+--+ +-++--+ +--+--+
+ | || |
+ +---+---+ || |
+ +------+RB2(ov)|======++ |
+ | +-------+ || |
+ | || |
+ +--+--+ +-----+ ++==++=++ +--+--+
+ | RB8 +====+ RB6 +===++ RB4 ++=====+ RB9 |
+ +-----+ +-----+ ++=====++ +-----+
+
+ Since RB2 is overloaded, it does not know what the distribution tree
+ or trees are for the network. Thus, there is no way it can provide
+ normal TRILL Data service for multi-destination native frames. So,
+ RB2 tunnels the frame in a TRILL Data packet to a neighbor that is
+ not overloaded if it has such a neighbor that has signaled that it is
+ willing to offer this service. RBridges indicate this in their
+ Hellos as described below. This service is called the OOMF (Overload
+ Originated Multi-destination Frame) service.
+
+ - The multi-destination frame MUST NOT be locally distributed in
+ native form at RB2, because this would cause the frame to be
+ delivered twice. Instead, it is tunneling to a neighbor as
+ described in this section. For example, if RB2 locally distributed
+ a multicast native frame and then tunneled it to RB5, RB2 would get
+ a copy of the frame when RB3 transmitted it as a TRILL Data packet
+
+
+
+Eastlake, et al. Standards Track [Page 10]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ on the multi-access RB2-RB3-RB4 link. Since RB2 would, in general,
+ not be able to tell that this was a frame it had tunneled for
+ distribution, RB2 would decapsulate it and locally distribute it a
+ second time.
+
+ - On the other hand, if there is no neighbor of RB2 offering RB2 the
+ OOMF service, RB2 cannot tunnel the frame to a neighbor. In this
+ case, RB2 MUST locally distribute the frame where it is Appointed
+ Forwarder for the frame's VLAN and optionally subject to multicast
+ pruning.
+
+2.4.2.2. Indicating OOMF Support
+
+ An RBridge RB3 indicates its willingness to offer the OOMF service to
+ RB2 in the TRILL Neighbor TLV in RB3's TRILL Hellos by setting a bit
+ associated with the SNPA (Subnetwork Point of Attachment, also known
+ as MAC address) of RB2 on the link (see the IANA Considerations
+ section). Overloaded RBridge RB2 can only distribute
+ multi-destination TRILL Data packets to the campus if a neighbor of
+ RB2 not in overload offers RB2 the OOMF service. If RB2 does not
+ have OOMF service available to it, RB2 can still receive
+ multi-destination packets from non-overloaded neighbors, and if RB2
+ should originate or ingress such a frame, it distributes it locally
+ in native form.
+
+2.4.2.3. Using OOMF Service
+
+ If RB2 sees this OOMF (Overload Originated Multi-destination Frame)
+ service advertised for it by any of its neighbors on any link to
+ which RB2 connects, it selects one such neighbor by a means that is
+ beyond the scope of this document. Assuming that RB2 selects RB3 to
+ handle multi-destination packets it originates, RB2 MUST advertise in
+ its LSP that it might use any of the distribution trees that RB3
+ advertises so that the RPFC will work in the rest of the campus.
+ Thus, notwithstanding its overloaded state, RB2 MUST retain this
+ information from RB3 LSPs, which it will receive, as it is directly
+ connected to RB3.
+
+ RB2 then encapsulates such frames as TRILL Data packets to RB3 as
+ follows: "M" bit = 0; Hop Count = 2; Ingress Nickname = a nickname
+ held by RB2; and, since RB2 cannot tell what distribution tree RB3
+ will use, Egress Nickname = a special nickname indicating an OOMF
+ packet (see the IANA Considerations section). RB2 then unicasts this
+ TRILL Data packet to RB3. (Implementation of Item 4 in Section 4
+ below provides reasonable assurance that, notwithstanding its
+ overloaded state, the ingress nickname used by RB2 will be unique
+ within at least the portion of the campus that is IS-IS reachable
+ from RB2.)
+
+
+
+Eastlake, et al. Standards Track [Page 11]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ On receipt of such a packet, RB3 does the following:
+
+ - changes the Egress Nickname field to designate a distribution tree
+ that RB3 normally uses,
+
+ - sets the "M" bit to one,
+
+ - changes the Hop Count to the value it would normally use if it were
+ the ingress, and
+
+ - forwards the TRILL Data packet on that tree.
+
+ RB3 MAY rate-limit the number of packets for which it is providing
+ this service by discarding some such packets from RB2. The provision
+ of even limited bandwidth for OOMFs by RB3, perhaps via the slow
+ path, may be important to the bootstrapping of services at RB2 or at
+ end stations connected to RB2, such as supporting DHCP and ARP/ND
+ (Address Resolution Protocol / Neighbor Discovery). (Everyone
+ sometimes needs a little OOMF (pronounced "oomph") to get off the
+ ground.)
+
+3. Distribution Trees and RPF Check (Changed)
+
+ Two corrections, a clarification, and two updates related to
+ distribution trees appear in the subsections below, along with an
+ alternative, stronger RPF (Reverse Path Forwarding) check. See also
+ Section 2.2.
+
+3.1. Number of Distribution Trees (Unchanged)
+
+ In [RFC6325], Section 4.5.2, page 56, point 2, fourth paragraph, the
+ parenthetical "(up to the maximum of {j,k})" is incorrect [Err3052].
+ It should read "(up to k if j is zero or the minimum of (j, k) if j
+ is non-zero)".
+
+3.2. Distribution Tree Update Clarification (Unchanged)
+
+ When a link-state database change causes a change in the distribution
+ tree(s), several possible types of change can occur. If a tree root
+ remains a tree root but the tree changes, then local forwarding and
+ RPFC entries for that tree should be updated as soon as practical.
+ Similarly, if a new nickname becomes a tree root, forwarding and RPFC
+ entries for the new tree should be installed as soon as practical.
+ However, if a nickname ceases to be a tree root and there is
+ sufficient room in local tables, the forwarding and RPFC entries for
+ the former tree MAY be retained so that any multi-destination TRILL
+ Data packets already in flight on that tree have a higher probability
+ of being delivered.
+
+
+
+Eastlake, et al. Standards Track [Page 12]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+3.3. Multicast Pruning Based on IP Address (Unchanged)
+
+ The TRILL base protocol specification [RFC6325] provides for, and
+ recommends the pruning of, multi-destination packet distribution
+ trees based on the location of IP multicast routers and listeners;
+ however, multicast listening is identified by derived MAC addresses
+ as communicated in the Group MAC Address sub-TLV [RFC7176].
+
+ TRILL switches MAY communicate multicast listeners and prune
+ distribution trees based on the actual IPv4 or IPv6 multicast
+ addresses involved. Additional Group Address sub-TLVs are provided
+ in [RFC7176] to carry this information. A TRILL switch that is only
+ capable of pruning based on derived MAC addresses SHOULD calculate
+ and use such derived MAC addresses from the multicast listener IPv4
+ or IPv6 address information it receives.
+
+3.4. Numbering of Distribution Trees (Unchanged)
+
+ Section 4.5.1 of [RFC6325] specifies that, when building distribution
+ tree number j, node (RBridge) N that has multiple possible parents in
+ the tree is attached to possible parent number j mod p. Trees are
+ numbered starting with 1, but possible parents are numbered starting
+ with 0. As a result, if there are two trees and two possible
+ parents, then in tree 1 parent 1 will be selected, and in tree 2
+ parent 0 will be selected.
+
+ This is changed so that the selected parent MUST be (j-1) mod p. As
+ a result, in the case above, tree 1 will select parent 0, and tree 2
+ will select parent 1. This change is not backward compatible with
+ [RFC6325]. If all RBridges in a campus do not determine distribution
+ trees in the same way, then for most topologies, the RPFC will drop
+ many multi-destination packets before they have been properly
+ delivered.
+
+3.5. Link Cost Directionality (Unchanged)
+
+ Distribution tree construction, like other least-cost aspects of
+ TRILL, works even if link costs are asymmetric, so the cost of the
+ hop from RB1 to RB2 is different from the cost of the hop from RB2 to
+ RB1. However, it is essential that all RBridges calculate the same
+ distribution trees, and thus all must use either the cost away from
+ the tree root or the cost towards the tree root. The text in
+ Section 4.5.1 of [RFC6325] is incorrect, as documented in [Err3508].
+ The text says:
+
+ In other words, the set of potential parents for N, for the tree
+ rooted at R, consists of those that give equally minimal cost
+ paths from N to R and ...
+
+
+
+Eastlake, et al. Standards Track [Page 13]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ but the text should say "from R to N":
+
+ In other words, the set of potential parents for N, for the tree
+ rooted at R, consists of those that give equally minimal cost
+ paths from R to N and ...
+
+3.6. Alternative RPF Check (New)
+
+ [RFC6325] mandates a Reverse Path Forwarding (RPF) check on
+ multi-destination TRILL Data packets to avoid possible multiplication
+ and/or looping of multi-destination traffic during TRILL campus
+ topology transients. This check is logically performed at each TRILL
+ switch input port and determines whether it is arriving on the
+ expected port based on where the packet started (the ingress
+ nickname) and the tree on which it is being distributed. If not, the
+ packet is silently discarded. This check is fine for point-to-point
+ links; however, there are rare circumstances involving multi-access
+ ("broadcast") links where a packet can be duplicated despite this
+ RPF check and other checks performed by TRILL.
+
+ Section 3.6.1 gives an example of the potential problem, and
+ Section 3.6.2 specifies a solution. This solution is an alternative,
+ stronger RPF check that TRILL switches can implement in place of the
+ RPF check discussed in [RFC6325].
+
+3.6.1. Example of the Potential Problem
+
+ Consider this network:
+
+ F--A--B--C--o--D
+ |
+ E
+
+ All the links except the link between C, D, and E are point-to-point
+ links. C, D, and E are connected over a broadcast link represented
+ by the pseudonode "o". For example, they could be connected by a
+ bridged LAN. (Bridged LANs are transparent to TRILL.)
+
+ Although the choice of root is unimportant here, assume that D or F
+ is chosen as the root of a distribution tree so that it is obvious
+ that the tree looks just like the diagram above.
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 14]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ Now assume that a link comes up from A to the same bridged LAN. The
+ network then looks like this:
+
+ +--------+
+ | |
+ F--A--B--C--o--D
+ |
+ E
+
+ Let's say the resulting tree in steady state includes all links
+ except the B-C link. After the network has converged, a packet that
+ starts from F will go F->A. Then A will send one copy on the A-B
+ link and another copy into the bridged LAN from which it will be
+ received by C and D.
+
+ Now consider a transition stage where A and D have acted on the new
+ LSPs and programmed their forwarding plane, while B and C have not
+ yet done so. This means that B and C both consider the link between
+ them to still be part of the tree. In this case, a packet that
+ starts out from F and reaches A will be copied by A into the A-B link
+ and to the bridged LAN. D's RPF check says to accept packets on this
+ tree coming from F over its port on the bridged LAN, so it gets
+ accepted. D is also adjacent to A on the tree, so the tree adjacency
+ check, a separate check mandated by [RFC6325], also passes.
+
+ However, the packet that gets to B gets sent out by B to C. C's RPF
+ check still has the old state, and it thinks the packet is OK. C
+ sends the packet along the old tree, which sends the packet into the
+ bridged LAN. D receives one more packet, but the tree adjacency
+ check passes at D because C is adjacent to D in the new tree as well.
+ The RPF check also passes at D because D's port on the bridged LAN is
+ OK for receiving packets from F.
+
+ So, during this transient state, D gets duplicates of every
+ multi-destination packet ingressed at F (unless the packet gets
+ pruned) until B and C act on the new LSPs and program their
+ forwarding tables.
+
+3.6.2. Solution and Discussion
+
+ The problem stems from the RPF check described in [RFC6325] depending
+ only on the port at which a TRILL Data packet is received, the
+ ingress nickname, and the tree being used, that is, a check if
+ {ingress nickname, tree, input port} is a valid combination according
+ to the receiving TRILL switch's view of the campus topology. A
+ multi-access link actually has multiple adjacencies overlaid on one
+ physical link, and to avoid the problem shown in Section 3.6.1, a
+ stronger check is needed that includes the Layer 2 source address of
+
+
+
+Eastlake, et al. Standards Track [Page 15]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ the TRILL Data packet being received. (TRILL is a Layer 3 protocol,
+ and TRILL switches are true routers that logically strip the Layer 2
+ header from any arriving TRILL Data packets and add the appropriate
+ new Layer 2 header to any outgoing TRILL Data packet to get it to the
+ next TRILL switch, so the Layer 2 source address in a TRILL Data
+ packet identifies the immediately previous TRILL switch that
+ forwarded the packet.)
+
+ What is needed, instead of checking the validity of the triplet
+ {ingress nickname, tree, input port}, is to check that the quadruplet
+ {ingress nickname, source SNPA, tree, input port} is valid (where
+ "source SNPA" (Subnetwork Point of Attachment) is the Outer.MacSA for
+ an Ethernet link). Although it is true that [RFC6325] also requires
+ a check to ensure that a multi-destination TRILL Data packet is from
+ a TRILL switch that is adjacent in the distribution tree being used,
+ this check is separate from the RPF check, and these two independent
+ checks are not as powerful as the single unified check for a valid
+ quadruplet.
+
+ _______
+ / \
+ RB1 ------ o ----- RB2
+ \_______/
+
+ However, this stronger RPF check is not without cost. In the simple
+ case of a multi-access link where each TRILL switch has only one port
+ on the link, it merely increases the size of validity entries by
+ adding the source SNPA (Outer.MacSA). However, assume that some
+ TRILL switch RB1 has multiple ports attached to a multi-access link.
+ In the figure above, RB1 is shown with three ports on the
+ multi-access link. RB1 is permitted to load split multi-destination
+ traffic it is sending into the multi-access link across those ports
+ (Section 4.4.4 of [RFC6325]). Assume that RB2 is another TRILL
+ switch on the link and RB2 is adjacent to RB1 in the distribution
+ tree. The number of validity quadruplets at RB2 for ingress
+ nicknames whose multi-destination traffic would arrive through RB1 is
+ multiplied by the number of ports RB1 has on the access link, because
+ RB2 has to accept such traffic from any such ports. Although such
+ instances seem to be very rare in practice, the number of ports an
+ RBridge has on a link could in principle be tens or even a hundred or
+ more ports, vastly increasing the RPF check state at RB2 when this
+ stronger RPF check is used.
+
+ Another potential cost of the stronger RPF check is increased
+ transient loss of multi-destination TRILL Data packets during a
+ topology change. For TRILL switch D, the new stronger RPF check is
+ (tree->A, Outer.MacSA=A, ingress=A, arrival port=if1), while the old
+ one was (tree->A, Outer.MacSA=C, ingress=A, arrival port=if1).
+
+
+
+Eastlake, et al. Standards Track [Page 16]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ Suppose that both A and B have switched to the new tree for multicast
+ forwarding but D has not updated its RPF check yet; the multicast
+ packet will then be dropped at D's input port, because D still
+ expects a packet from "Outer.MacSA=C". But we do not have this
+ packet loss issue if the weaker triplet check (tree->A, ingress=A,
+ arrival port=if1) is used. Thus, the stronger check can increase the
+ RPF check discard of multi-destination packets during topology
+ transients.
+
+ Because of these potential costs, implementation of this stronger
+ RPF check is optional. The TRILL base protocol is updated to provide
+ that TRILL switches MUST, for multi-destination packets, either
+ implement the RPF and other checks as described in [RFC6325] or
+ implement this stronger RPF check as a substitute for the [RFC6325]
+ RPF and tree adjacency checks. There is no problem with a campus
+ having a mixture of TRILL switches, some of which implement one of
+ these RPF checks and some of which implement the other.
+
+4. Nickname Selection (Unchanged)
+
+ Nickname selection is covered by Section 3.7.3 of [RFC6325].
+ However, the following should be noted:
+
+ 1. The second sentence in the second bullet item in Section 3.7.3 of
+ [RFC6325] on page 25 is erroneous [Err3002] and is corrected as
+ follows:
+
+ o The occurrence of "IS-IS ID (LAN ID)" is replaced with
+ "priority".
+
+ o The occurrence of "IS-IS System ID" is replaced with "7-byte
+ IS-IS ID (LAN ID)".
+
+ The resulting corrected sentence in [RFC6325] reads as follows:
+
+ If RB1 chooses nickname x, and RB1 discovers, through receipt
+ of an LSP for RB2 at any later time, that RB2 has also chosen
+ x, then the RBridge or pseudonode with the numerically higher
+ priority keeps the nickname, or if there is a tie in priority,
+ the RBridge with the numerically higher 7-byte IS-IS ID
+ (LAN ID) keeps the nickname, and the other RBridge MUST select
+ a new nickname.
+
+ 2. In examining the link-state database for nickname conflicts,
+ nicknames held by IS-IS unreachable TRILL switches MUST be
+ ignored, but nicknames held by IS-IS reachable TRILL switches
+ MUST NOT be ignored even if they are data unreachable.
+
+
+
+
+Eastlake, et al. Standards Track [Page 17]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ 3. An RBridge may need to select a new nickname, either initially
+ because it has none or because of a conflict. When doing so, the
+ RBridge MUST consider as available all nicknames that do not
+ appear in its link-state database or that appear to be held by
+ IS-IS unreachable TRILL switches; however, it SHOULD give
+ preference to selecting new nicknames that do not appear to be
+ held by any TRILL switch in the campus, reachable or unreachable,
+ so as to minimize conflicts if IS-IS unreachable TRILL switches
+ later become reachable.
+
+ 4. An RBridge, even after it has acquired a nickname for which there
+ appears to be no conflicting claimant, MUST continue to monitor
+ for conflicts with the nickname or nicknames it holds. It does so
+ by monitoring any received LSPs that should update its link-state
+ database for any occurrence of any of its nicknames held with
+ higher priority by some other TRILL switch that is IS-IS reachable
+ from it. If it finds such a conflict, it MUST select a new
+ nickname, even when in overloaded state. (It is possible to
+ receive an LSP that should update the link-state database but does
+ not do so due to overload.)
+
+ 5. In the very unlikely case that an RBridge is unable to obtain a
+ nickname because all valid RBridge nicknames (0x0001 through
+ 0xFFBF inclusive) are in use with higher priority by IS-IS
+ reachable TRILL switches, it will be unable to act as an ingress,
+ egress, or tree root but will still be able to function as a
+ transit TRILL switch. Although it cannot be a tree root, such an
+ RBridge is included in distribution trees computed for the campus
+ unless all its neighbors are overloaded. It would not be possible
+ to send a unicast RBridge Channel message specifically to such a
+ TRILL switch [RFC7178]; however, it will receive unicast RBridge
+ Channel messages sent by a neighbor to the Any-RBridge egress
+ nickname and will receive appropriate multi-destination RBridge
+ Channel messages.
+
+5. MTU (Maximum Transmission Unit) (Unchanged)
+
+ MTU values in TRILL are derived from the originatingL1LSPBufferSize
+ value communicated in the IS-IS originatingLSPBufferSize TLV [IS-IS].
+ The campus-wide value Sz, as described in Section 4.3.1 of [RFC6325],
+ is the minimum value of originatingL1LSPBufferSize for the RBridges
+ in a campus, but not less than 1470. The MTU testing mechanism and
+ limiting LSPs to Sz assure that the LSPs can be flooded by IS-IS and
+ thus that IS-IS can operate properly.
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 18]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ If an RBridge knows nothing about the MTU of the links or the
+ originatingL1LSPBufferSize of other RBridges in a campus, the
+ originatingL1LSPBufferSize for that RBridge should default to the
+ minimum of the LSP size that its TRILL IS-IS software can handle and
+ the minimum MTU of the ports that it might use to receive or transmit
+ LSPs. If an RBridge does have knowledge of link MTUs or other
+ RBridge originatingL1LSPBufferSize, then, to avoid the necessity of
+ regenerating the local LSPs using a different maximum size, the
+ RBridge's originatingL1LSPBufferSize SHOULD be configured to the
+ minimum of (1) the smallest value that other RBridges are, or will
+ be, announcing as their originatingL1LSPBufferSize and (2) a value
+ small enough that the campus will not partition due to a significant
+ number of links with limited MTUs. However, as specified in
+ [RFC6325], in no case can originatingL1LSPBufferSize be less than
+ 1470. In a well-configured campus, to minimize any LSP regeneration
+ due to resizing, all RBridges will be configured with the same
+ originatingL1LSPBufferSize.
+
+ Section 5.1 below corrects errata in [RFC6325], and Section 5.2
+ clarifies the meaning of various MTU limits for TRILL Ethernet links.
+
+5.1. MTU-Related Errata in RFC 6325
+
+ Three MTU-related errata in [RFC6325] are corrected in the
+ subsections below.
+
+5.1.1. MTU PDU Addressing
+
+ Section 4.3.2 of [RFC6325] incorrectly states that multi-destination
+ MTU-probe and MTU-ack TRILL IS-IS PDUs are sent on Ethernet links
+ with the All-RBridges multicast address as the Outer.MacDA [Err3004].
+ As TRILL IS-IS PDUs, when multicast on an Ethernet link, these
+ multi-destination MTU-probe and MTU-ack PDUs MUST be sent to the
+ All-IS-IS-RBridges multicast address.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 19]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+5.1.2. MTU PDU Processing
+
+ As discussed in [RFC6325] and (in more detail) [RFC7177], MTU-probe
+ and MTU-ack PDUs MAY be unicast; however, Section 4.6 of [RFC6325]
+ erroneously does not allow for this possibility [Err3003]. It is
+ corrected by replacing Item 1 in Section 4.6.2 of [RFC6325] with the
+ following text, to which TRILL switches MUST conform:
+
+ 1. If the Ethertype is L2-IS-IS and the Outer.MacDA is either
+ All-IS-IS-RBridges or the unicast MAC address of the receiving
+ RBridge port, the frame is handled as described in
+ Section 4.6.2.1.
+
+ The reference to "Section 4.6.2.1" in the above text is to that
+ section in [RFC6325].
+
+5.1.3. MTU Testing
+
+ The last two sentences of Section 4.3.2 of [RFC6325] contain errors
+ [Err3053]. They currently read as follows:
+
+ If X is not greater than Sz, then RB1 sets the "failed minimum MTU
+ test" flag for RB2 in RB1's Hello. If size X succeeds, and X >
+ Sz, then RB1 advertises the largest tested X for each adjacency in
+ the TRILL Hellos RB1 sends on that link, and RB1 MAY advertise X
+ as an attribute of the link to RB2 in RB1's LSP.
+
+ They should read as follows:
+
+ If X is not greater than or equal to Sz, then RB1 sets the "failed
+ minimum MTU test" flag for RB2 in RB1's Hello. If size X
+ succeeds, and X >= Sz, then RB1 advertises the largest tested X
+ for each adjacency in the TRILL Hellos RB1 sends on that link,
+ and RB1 MAY advertise X as an attribute of the link to RB2 in
+ RB1's LSP.
+
+5.2. Ethernet MTU Values
+
+ originatingL1LSPBufferSize is the maximum permitted size of LSPs
+ starting with and including the IS-IS 0x83 "Intradomain Routeing
+ Protocol Discriminator" byte. In Layer 3 IS-IS,
+ originatingL1LSPBufferSize defaults to 1492 bytes. (This is because,
+ in its previous life as DECnet Phase V, IS-IS was encoded using the
+ SNAP SAP (Subnetwork Access Protocol Service Access Point) [RFC7042]
+ format, which takes 8 bytes of overhead and 1492 + 8 = 1500, the
+ classic Ethernet maximum. When standardized by ISO/IEC [IS-IS] to
+ use Logical Link Control (LLC) encoding, this default could have been
+ increased by a few bytes but was not.)
+
+
+
+Eastlake, et al. Standards Track [Page 20]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ In TRILL, originatingL1LSPBufferSize defaults to 1470 bytes. This
+ allows 27 bytes of headroom or safety margin to accommodate legacy
+ devices with the classic Ethernet maximum MTU, despite headers such
+ as an Outer.VLAN.
+
+ Assuming that the campus-wide minimum link MTU is Sz, RBridges on
+ Ethernet links MUST limit most TRILL IS-IS PDUs so that PDUz (the
+ length of the PDU starting just after the L2-IS-IS Ethertype and
+ ending just before the Ethernet Frame Check Sequence (FCS)) does not
+ exceed Sz. The PDU exceptions are TRILL Hello PDUs, which MUST NOT
+ exceed 1470 bytes, and MTU-probe and MTU-ack PDUs that are padded by
+ an amount that depends on the size being tested (which may
+ exceed Sz).
+
+ Sz does not limit TRILL Data packets. They are only limited by the
+ MTU of the devices and links that they actually pass through;
+ however, links that can accommodate IS-IS PDUs up to Sz would
+ accommodate, with a generous safety margin, TRILL Data packet
+ payloads of (Sz - 24) bytes, starting after the Inner.VLAN and ending
+ just before the FCS.
+
+ Most modern Ethernet equipment has ample headroom for frames with
+ extensive headers and is sometimes engineered to accommodate 9 KB
+ jumbo frames.
+
+6. TRILL Port Modes (Unchanged)
+
+ Section 4.9.1 of [RFC6325] specifies four mode bits for RBridge ports
+ but may not be completely clear on the effects of all combinations of
+ bits in terms of allowed frame types.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 21]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ The table below explicitly indicates the effects of all possible
+ combinations of the TRILL port mode bits. "*" in one of the first
+ four columns indicates that the bit can be either zero or one. The
+ remaining columns indicate allowed frame types. The "disable bit"
+ normally disables all frames; however, as an implementation choice,
+ some or all low-level Layer 2 control messages can still be sent or
+ received. Examples of Layer 2 control messages are those control
+ frames for Ethernet identified in Section 1.4 of [RFC6325] or PPP
+ link negotiation messages [RFC6361].
+
+ +-+-+-+-+--------+-------+-------+-------+-------+
+ |D| | | | | | | | |
+ |i| |A| | | | TRILL | | |
+ |s| |c|T| |Native | Data | | |
+ |a| |c|r| |Ingress| | | |
+ |b|P|e|u| | | LSP | | |
+ |l|2|s|n|Layer 2 |Native | SNP | TRILL | P2P |
+ |e|P|s|k|Control |Egress | MTU | Hello | Hello |
+ +-+-+-+-+--------+-------+-------+-------+-------+
+ |0|0|0|0| Yes | Yes | Yes | Yes | No |
+ +-+-+-+-+--------+-------+-------+-------+-------+
+ |0|0|0|1| Yes | No | Yes | Yes | No |
+ +-+-+-+-+--------+-------+-------+-------+-------+
+ |0|0|1|0| Yes | Yes | No | Yes | No |
+ +-+-+-+-+--------+-------+-------+-------+-------+
+ |0|0|1|1| Yes | No | No | Yes | No |
+ +-+-+-+-+--------+-------+-------+-------+-------+
+ |0|1|0|*| Yes | No | Yes | No | Yes |
+ +-+-+-+-+--------+-------+-------+-------+-------+
+ |0|1|1|*| Yes | No | No | No | Yes |
+ +-+-+-+-+--------+-------+-------+-------+-------+
+ |1|*|*|*|Optional| No | No | No | No |
+ +-+-+-+-+--------+-------+-------+-------+-------+
+
+ The formal name of the "access bit" above is the "TRILL traffic
+ disable bit". The formal name of the "trunk bit" is the "end-station
+ service disable bit" [RFC6325].
+
+7. The CFI/DEI Bit (Unchanged)
+
+ In May 2011, the IEEE promulgated IEEE Std 802.1Q-2011, which changed
+ the meaning of the bit between the priority and VLAN ID bits in the
+ payload of C-VLAN tags. Previously, this bit was called the CFI
+ (Canonical Format Indicator) bit [802] and had a special meaning in
+ connection with IEEE 802.5 (Token Ring) frames. After 802.1Q-2011
+ and in subsequent versions of 802.1Q -- the most current of which is
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 22]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ [802.1Q-2014] -- this bit is now the DEI (Drop Eligibility Indicator)
+ bit. (The corresponding bit in S-VLAN/B-VLAN tags has always been a
+ DEI bit.)
+
+ The TRILL base protocol specification [RFC6325] assumed, in effect,
+ that the link by which end stations are connected to TRILL switches
+ and the restricted virtual link provided by the TRILL Data packet are
+ IEEE 802.3 Ethernet links on which the CFI bit is always zero.
+ Should an end station be attached by some other type of link, such as
+ a Token Ring link, [RFC6325] implicitly assumed that such frames
+ would be canonicalized to 802.3 frames before being ingressed, and
+ similarly, on egress, such frames would be converted from 802.3 to
+ the appropriate frame type for the link. Thus, [RFC6325] required
+ that the CFI bit in the Inner.VLAN, which is shown as the "C" bit in
+ Section 4.1.1 of [RFC6325], always be zero.
+
+ However, for TRILL switches with ports conforming to the change
+ incorporated in the IEEE 802.1Q-2011 standard, the bit in the
+ Inner.VLAN, now a DEI bit, MUST be set to the DEI value provided by
+ the port interface on ingressing a native frame. Similarly, this bit
+ MUST be provided to the port when transiting or egressing a TRILL
+ Data packet. As with the 3-bit Priority field, the DEI bit to use in
+ forwarding a transit packet MUST be taken from the Inner.VLAN. The
+ exact effect on the Outer.VLAN DEI and priority bits, and whether or
+ not an Outer.VLAN appears at all on the wire for output frames, may
+ depend on output port configuration.
+
+ TRILL campuses with a mixture of ports, some compliant with versions
+ of 802.1Q from IEEE Std 802.1Q-2011 onward and some compliant with
+ pre-802.1Q-2011 standards, especially if they have actual Token Ring
+ links, may operate incorrectly and may corrupt data, just as a
+ bridged LAN with such mixed ports and links would.
+
+8. Other IS-IS Considerations (Changed)
+
+ This section covers Extended Level 1 Flooding Scope (E-L1FS) support,
+ control packet priorities, unknown PDUs, the Nickname Flags
+ APPsub-TLV, graceful restart, and the Purge Originator
+ Identification TLV.
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 23]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+8.1. E-L1FS Support (New)
+
+ TRILL switches MUST support E-L1FS PDUs [RFC7356] and MUST include a
+ Scope Flooding Support TLV [RFC7356] in all TRILL Hellos they send
+ indicating support for this scope and any other FS-LSP scopes that
+ they support. This support increases the number of fragments
+ available for link-state information by over two orders of magnitude.
+ (See Section 9 for further information on support of the Scope
+ Flooding Support TLV.)
+
+ In addition, TRILL switches MUST advertise their support of E-L1FS
+ flooding in a TRILL-VER sub-TLV Capability Flag (see [RFC7176] and
+ Section 12.2). This flag is used by a TRILL switch, say RB1, to
+ determine support for E-L1FS by some remote RBx. The alternative of
+ simply looking for an E-L1FS FS-LSP originated by RBx fails because
+ (1) RBx might support E-L1FS flooding but is not originating any
+ E-L1FS FS-LSPs and (2) even if RBx is originating E-L1FS FS-LSPs
+ there might, due to legacy TRILL switches in the campus, be no path
+ between RBx and RB1 through TRILL switches supporting E-L1FS
+ flooding. If that were the case, no E-L1FS FS-LSP originated by RBx
+ could get to RB1.
+
+ E-L1FS will commonly be used to flood TRILL GENINFO TLVs and enclosed
+ TRILL APPsub-TLVs [RFC7357]. For robustness, E-L1FS fragment zero
+ MUST NOT exceed 1470 bytes in length; however, if such a fragment is
+ received that is larger, it is processed normally. It is anticipated
+ that in the future some particularly important TRILL APPsub-TLVs will
+ be specified as being flooded in E-L1FS fragment zero. TRILL GENINFO
+ TLVs MUST NOT be sent in LSPs; however, if one is received in an LSP,
+ it is processed normally.
+
+8.1.1. Backward Compatibility
+
+ A TRILL campus might contain TRILL switches supporting E-L1FS
+ flooding and legacy TRILL switches that do not support E-L1FS or
+ perhaps do not support any [RFC7356] scopes.
+
+ A TRILL switch conformant to this document can always tell which
+ adjacent TRILL switches support E-L1FS flooding from the adjacency
+ table entries on its ports (see Section 9). In addition, such a
+ TRILL switch can tell which remote TRILL switches in a campus support
+ E-L1FS by the presence of a TRILL version sub-TLV in that TRILL
+ switch's LSP with the E-L1FS support bit set in the Capabilities
+ field; this capability bit is ignored for adjacent TRILL switches for
+ which only the adjacency table entry is consulted to determine E-L1FS
+ support.
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 24]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ TRILL specifications making use of E-L1FS MUST specify how situations
+ involving a mixed TRILL campus of TRILL switches will be handled.
+
+8.1.2. E-L1FS Use for Existing (Sub-)TLVs
+
+ In a campus where all TRILL switches support E-L1FS, all TRILL
+ sub-TLVs listed in Section 2.3 of [RFC7176], except the TRILL version
+ sub-TLV, MAY be advertised by inclusion in Router Capability or
+ MT-Capability TLVs in E-L1FS FS-LSPs [RFC7356]. (The TRILL version
+ sub-TLV still MUST appear in an LSP fragment zero.)
+
+ In a mixed campus where some TRILL switches support E-L1FS and some
+ do not, then only the following four sub-TLVs of those listed in
+ Section 2.3 of [RFC7176] can appear in E-L1FS, and then only under
+ the conditions discussed below. In the following list, each sub-TLV
+ is preceded by an abbreviated acronym used only in this section of
+ this document:
+
+ IV: Interested VLANs and Spanning Tree Roots sub-TLV
+ VG: VLAN Group sub-TLV
+ IL: Interested Labels and Spanning Tree Roots sub-TLV
+ LG: Label Group sub-TLV
+
+ An IV or VG sub-TLV MUST NOT be advertised by TRILL switch RB1 in an
+ E-L1FS FS-LSP (and should instead be advertised in an LSP) unless the
+ following conditions are met:
+
+ - E-L1FS is supported by all of the TRILL switches that are data
+ reachable from RB1 and are interested in the VLANs mentioned in the
+ IV or VG sub-TLV, and
+
+ - there is E-L1FS connectivity between all such TRILL switches in the
+ campus interested in the VLANs mentioned in the IV or VG sub-TLV
+ (connectivity involving only intermediate TRILL switches that also
+ support E-L1FS).
+
+ Any IV and VG sub-TLVs MAY still be advertised via core TRILL IS-IS
+ LSPs by any TRILL switch that has enough room in its LSPs.
+
+ The conditions for using E-L1FS for the IL and LG sub-TLVs are the
+ same as for IV and VG, but with Fine-Grained Labels [RFC7172]
+ substituted for VLANs.
+
+ Note, for example, that the above would permit a contiguous subset
+ of the campus that supported Fine-Grained Labels and E-L1FS to use
+ E-L1FS to advertise IL and LG sub-TLVs, even if the remainder of
+ the campus did not support Fine-Grained Labels or E-L1FS.
+
+
+
+
+Eastlake, et al. Standards Track [Page 25]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+8.2. Control Packet Priorities (New)
+
+ When deciding what packet to send out a port, control packets used to
+ establish and maintain adjacency between TRILL switches SHOULD be
+ treated as being in the highest-priority category. This includes
+ TRILL IS-IS Hello and MTU PDUs, and possibly other adjacency
+ [RFC7177] or link-technology-specific packets. Other control and
+ data packets SHOULD be given lower priority so that a flood of such
+ other packets cannot lead to loss of, or inability to establish,
+ adjacency. Loss of adjacency causes a topology transient that can
+ result in reduced throughput; reordering; increased probability of
+ loss of data; and, in the worst case, network partition if the
+ adjacency is a cut point.
+
+ Other important control packets should be given second-highest
+ priority. Lower priorities should be given to data or less important
+ control packets.
+
+ Based on the above, control packets can be ordered into priority
+ categories as shown below, based on the relative criticality of these
+ types of messages, where the most critical control packets relate to
+ the core routing between TRILL switches and the less critical control
+ packets are closer to "application" information. (There may be
+ additional control packets, not specifically listed in any category
+ below, that SHOULD be handled as being in the most nearly analogous
+ category.) Although few implementations will actually treat these
+ four categories with different priority, an implementation MAY choose
+ to prioritize more critical messages over less critical. However, an
+ implementation SHOULD NOT send control packets in a lower-priority
+ category with a priority above those in a higher-priority category
+ because, under sufficiently congested conditions, this could block
+ control packets in a higher-priority category, resulting in network
+ disruption.
+
+ Priority
+ Category Description
+ -------- --------------
+
+ 4. Hello, MTU-probe, MTU-ack, and other packets critical
+ to establishing and maintaining adjacency. (Normally
+ sent with highest priority, which is priority 7.)
+
+ 3. LSPs, CSNPs/PSNPs, and other important control packets.
+
+ 2. Circuit scoped FS-LSPs, FS-CSNPs, and FS-PSNPs.
+
+ 1. Non-circuit scoped FS-LSPs, FS-CSNPs, and FS-PSNPs.
+
+
+
+
+Eastlake, et al. Standards Track [Page 26]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+8.3. Unknown PDUs (New)
+
+ TRILL switches MUST silently discard [IS-IS] PDUs they receive with
+ PDU numbers they do not understand, just as they ignore TLVs and
+ sub-TLVs they receive that have unknown Types and sub-Types; however,
+ they SHOULD maintain a counter of how many such PDUs have been
+ received, on a per-PDU-number basis. (This is not burdensome, as the
+ PDU number is only a 5-bit field.)
+
+ Note: The set of valid [IS-IS] PDUs was stable for so long that
+ some IS-IS implementations may treat PDUs with unknown PDU
+ numbers as a serious error and, for example, an indication that
+ other valid PDUs from the sender are not to be trusted or that
+ they should drop adjacency to the sender if it was adjacent.
+ However, the MTU-probe and MTU-ack PDUs were added by
+ [RFC7176], and now [RFC7356] has added three more new PDUs.
+ Although the authors of this document are not aware of any
+ Internet-Drafts calling for further PDUs, the eventual addition
+ of further new PDUs should not be surprising.
+
+8.4. Nickname Flags APPsub-TLV (New)
+
+ An optional Nickname Flags APPsub-TLV within the TRILL GENINFO TLV
+ [RFC7357] is specified below.
+
+ 1 1 1 1 1 1
+ 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ | Type = NickFlags (6) | (2 bytes)
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ | Length = 4*K | (2 bytes)
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ | NICKFLAG RECORD 1 (4 bytes) |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ ...
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ | NICKFLAG RECORD K (4 bytes) |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+
+ where each NICKFLAG RECORD has the following format:
+
+ 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
+ +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+
+ | Nickname |
+ +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+
+ |IN| RESV |
+ +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+
+
+
+
+
+Eastlake, et al. Standards Track [Page 27]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ o Type: NickFlags TRILL APPsub-TLV, set to 6 (NICKFLAGS).
+
+ o Length: 4 times the number of NICKFLAG RECORDS present.
+
+ o Nickname: A 16-bit TRILL nickname held by the advertising TRILL
+ switch ([RFC6325] and Section 4).
+
+ o IN: Ingress. If this flag is one, it indicates that the
+ advertising TRILL switch may use the nickname in the NICKFLAG
+ RECORD as the Ingress Nickname of TRILL Headers it creates. If
+ the flag is zero, that nickname will not be used for that
+ purpose.
+
+ o RESV: Reserved for additional flags to be specified in the
+ future. MUST be sent as zero and ignored on receipt.
+
+ The entire NickFlags APPsub-TLV is ignored if the Length is not a
+ multiple of 4. A NICKFLAG RECORD is ignored if the nickname it lists
+ is not a nickname owned by the TRILL switch advertising the enclosing
+ NickFlags APPsub-TLV.
+
+ If a TRILL switch intends to use a nickname in the Ingress Nickname
+ field of TRILL Headers it constructs, it can advertise this through
+ E-L1FS FS-LSPs (see Section 8.1) using a NickFlags APPsub-TLV entry
+ with the IN flag set. If it owns only one nickname, there is no
+ reason to do this because, if a TRILL switch advertises no NickFlags
+ APPsub-TLVs with the IN flag set for nicknames it owns, it is assumed
+ that the TRILL switch might use any or all nicknames it owns as the
+ Ingress Nickname in TRILL Headers it constructs. If a TRILL switch
+ advertises any NickFlags APPsub-TLV entries with the IN flag set,
+ then it MUST NOT use any other nickname(s) it owns as the Ingress
+ Nickname in TRILL Headers it constructs.
+
+ Every reasonable effort should be made to be sure that Nickname
+ sub-TLVs [RFC7176] and NickFlags APPsub-TLVs remain in sync. If all
+ TRILL switches in a campus support E-L1FS, so that Nickname sub-TLVs
+ can be advertised in E-L1FS FS-LSPs, then the Nickname sub-TLV and
+ any NickFlags APPsub-TLVs for any particular nickname SHOULD be
+ advertised in the same fragment. If they are not in the same
+ fragment, then, to the extent practical, all fragments involving
+ those sub-TLVs for the same nickname should be propagated as an
+ atomic action. If a TRILL switch sees multiple NickFlags APPsub-TLV
+ entries for the same nickname, it assumes that that nickname might be
+ used as the ingress in a TRILL Header if any of the NickFlags
+ APPsub-TLV entries have the IN bit set.
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 28]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ It is possible that a NickFlags APPsub-TLV would not be propagated
+ throughout the TRILL campus due to legacy TRILL switches not
+ supporting E-L1FS. In that case, Nickname sub-TLVs MUST be
+ advertised in LSPs, and TRILL switches not receiving NickFlags
+ APPsub-TLVs having entries with the IN flag set will simply assume
+ that the source TRILL switch might use any of its nicknames as the
+ ingress in constructing TRILL Headers. Thus, the use of this
+ optional APPsub-TLV is backward compatible with legacy lack of E-L1FS
+ support.
+
+ (Additional flags are assigned from those labeled RESV above and
+ specified in [TRILL-L3-GW] and [Centralized-Replication].)
+
+8.5. Graceful Restart (Unchanged)
+
+ TRILL switches SHOULD support the features specified in [RFC5306],
+ which describes a mechanism for a restarting IS-IS router to signal
+ to its neighbors that it is restarting, allowing them to reestablish
+ their adjacencies without cycling through the down state, while still
+ correctly initiating link-state database synchronization. If this
+ feature is not supported, it may increase the number of topology
+ transients caused by a TRILL switch rebooting due to errors or
+ maintenance.
+
+8.6. Purge Originator Identification (New)
+
+ To ease debugging of any purge-related problems, TRILL switches
+ SHOULD include the Purge Originator Identification TLV [RFC6232] in
+ all purge PDUs in TRILL IS-IS. This includes Flooding Scope LSPs
+ [RFC7356] and ESADI LSPs [RFC7357].
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 29]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+9. Updates to RFC 7177 (Adjacency) (Changed)
+
+ To support the E-L1FS flooding scope [RFC7356] mandated by
+ Section 8.1 and backward compatibility with legacy RBridges not
+ supporting E-L1FS flooding, this document updates [RFC7177] as
+ follows:
+
+ 1. The list in the second paragraph of Section 3.1 of [RFC7177] is
+ updated by adding the following item:
+
+ o The Scope Flooding Support TLV.
+
+ In addition, the sentence immediately after that list is updated
+ by this document to read as follows:
+
+ Of course, (a) the priority, (b) the Desired Designated VLAN,
+ (c) the Scope Flooding Support TLV, and whether or not the
+ (d) PORT-TRILL-VER sub-TLV and/or (e) BFD-Enabled TLV are
+ included, and their value if included, could change on
+ occasion. However, if these change, the new value(s) must
+ similarly be used in all TRILL Hellos on the LAN port,
+ regardless of VLAN.
+
+ 2. This document adds another bullet item to the end of Section 3.2
+ of [RFC7177], as follows:
+
+ o The value from the Scope Flooding Support TLV, or a null string
+ if none was included.
+
+ 3. Near the bottom of Section 3.3 of [RFC7177], this document adds
+ the following bullet item:
+
+ o The variable-length value part of the Scope Flooding Support
+ TLV in the Hello, or a null string if that TLV does not occur
+ in the Hello.
+
+ 4. At the beginning of Section 4 of [RFC7177], this document adds a
+ bullet item to the list, as follows:
+
+ o The variable-length value part of the Scope Flooding Support
+ TLV used in TRILL Hellos sent on the port.
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 30]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ 5. This document adds a line to Table 4 ("TRILL Hello Contents") in
+ Section 8.1 of [RFC7177], as follows:
+
+ LAN P2P Number Content Item
+ --- --- ------ ---------------------------
+
+ M M 1 Scope Flooding Support TLV
+
+10. TRILL Header Update (New)
+
+ The TRILL Header has been updated from its original specification in
+ [RFC6325] by [RFC7455] and [RFC7179] and is further updated by this
+ document. The TRILL Header is now as shown in the figure below
+ (which is followed by references for all of the fields). Those
+ fields for which the reference is only to [RFC6325] are unchanged
+ from that RFC.
+
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ | V |A|C|M| RESV |F| Hop Count |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ | Egress Nickname | Ingress Nickname |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ : Optional Flags Word :
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+
+ In calculating a TRILL Data packet hash as part of equal-cost
+ multipath selection, a TRILL switch MUST ignore the value of the
+ "A" and "C" bits.
+
+ In [RFC6325] and [RFC7179], there is a TRILL Header Extension Length
+ field called "Op-Length", which is hereby changed to consist of the
+ RESV field and "F" bit shown above.
+
+ o V (Version): 2-bit unsigned integer. See Section 3.2
+ of [RFC6325].
+
+ o A (Alert): 1 bit. See [RFC7455].
+
+ o C (Color): 1 bit. See Section 10.1.
+
+ o M (Multi-destination): 1 bit. See Section 3.4 of [RFC6325].
+
+ o RESV: 4 bits. These bits are reserved and MUST be sent as zero.
+ Due to the previous use of these bits as specified in [RFC6325],
+ most TRILL "fast path" hardware implementations trap and do not
+ forward TRILL Data packets with these bits non-zero. A TRILL
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 31]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ switch receiving a TRILL Data packet with any of these bits
+ non-zero MUST discard the packet unless the non-zero bit or bits
+ have some future use specified that the TRILL switch understands.
+
+ o F: 1 bit. If this field is non-zero, then the optional flags word
+ described in Section 10.2 is present. If it is zero, the
+ flags word is not present.
+
+ o Hop Count: 6 bits. See Section 3.6 of [RFC6325] and
+ Section 10.2.1 below.
+
+ o Egress Nickname: See Section 3.7.1 of [RFC6325].
+
+ o Ingress Nickname: See Section 3.7.2 of [RFC6325].
+
+ o Optional Flags Word: See [RFC7179] and Section 10.2.
+
+10.1. Color Bit
+
+ The Color bit provides an optional way by which ingress TRILL
+ switches MAY mark TRILL Data packets for implementation-specific
+ purposes. Transit TRILL switches MUST NOT change this bit. Transit
+ and egress TRILL switches MAY use the Color bit for implementation-
+ dependent traffic labeling, or for statistical analysis or other
+ types of traffic study or analysis.
+
+10.2. Flags Word Changes (Update to RFC 7179)
+
+ When the "F" bit in the TRILL Header is non-zero, the first 32 bits
+ after the Ingress Nickname field provide additional flags. These
+ bits are as specified in [RFC7179], except as changed by the
+ subsections below, in which the Extended Hop Count and Extended Color
+ fields are described. See Section 10.3 for a diagram and summary of
+ these fields.
+
+10.2.1. Extended Hop Count
+
+ The TRILL base protocol [RFC6325] specifies the Hop Count field in
+ the header, to avoid packets persisting in the network due to looping
+ or the like. However, the Hop Count field size (6 bits) limits the
+ maximum hops a TRILL Data packet can traverse to 64. Optionally,
+ TRILL switches can use a field composed of bits 14 through 16 in the
+ flags word, as specified below, to extend this field to 9 bits. This
+ increases the maximum Hop Count to 512. Except in rare
+ circumstances, reliable use of Hop Counts in excess of 64 requires
+ support of this optional capability at all TRILL switches along the
+ path of a TRILL Data packet.
+
+
+
+
+Eastlake, et al. Standards Track [Page 32]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+10.2.1.1. Advertising Support
+
+ It may be that not all the TRILL switches support the Extended Hop
+ Count mechanism in a TRILL campus and in that campus more than
+ 64 hops are required either for the distribution tree calculated path
+ or for the unicast calculated path plus a reasonable allowance for
+ alternate pathing. As such, it is required that TRILL switches
+ advertise their support by setting bit 14 in the TRILL Version
+ Sub-TLV Capabilities and Header Flags Supported field [RFC7176];
+ bits 15 and 16 of that field are now specified as Unassigned (see
+ Section 12.2.5).
+
+10.2.1.2. Ingress Behavior
+
+ If an ingress TRILL switch determines that it should set the
+ Hop Count for a TRILL Data packet to 63 or less, then behavior is as
+ specified in the TRILL base protocol [RFC6325]. If the optional
+ TRILL Header flags word is present, bits 14, 15, and 16 and the
+ critical reserved bit of the critical summary bits are zero.
+
+ If the Hop Count for a TRILL Data packet should be set to some value
+ greater than 63 but less than 512 and all TRILL switches that the
+ packet is reasonably likely to encounter support Extended Hop Count,
+ then the resulting TRILL Header has the flags word extension present,
+ the high-order 3 bits of the desired Hop Count are stored in the
+ Extended Hop Count field in the flags word, the low-order 5 bits are
+ stored in the Hop Count field in the first word of the TRILL Header,
+ and bit two (the critical reserved bit of the critical summary bits)
+ in the flags word is set to one.
+
+ For known unicast traffic (TRILL Header "M" bit zero), an ingress
+ TRILL switch discards the frame if it determines that the least-cost
+ path to the egress is (1) more than 64 hops and not all TRILL
+ switches on that path support the Extended Hop Count feature or
+ (2) more than 512 hops.
+
+ For multi-destination traffic, when a TRILL switch determines that
+ one or more tree paths from the ingress are more than 64 hops and not
+ all TRILL switches in the campus support the Extended Hop Count
+ feature, the encapsulation uses a total Hop Count of 63 to obtain at
+ least partial distribution of the traffic.
+
+10.2.1.3. Transit Behavior
+
+ A transit TRILL switch supporting Extended Hop Count behaves like a
+ base protocol [RFC6325] TRILL switch in decrementing the Hop Count,
+ except that it considers the Hop Count to be a 9-bit field where the
+ Extended Hop Count field constitutes the high-order 3 bits.
+
+
+
+Eastlake, et al. Standards Track [Page 33]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ To be more precise: a TRILL switch supporting Extended Hop Count
+ takes the first of the following actions that is applicable:
+
+ 1. If both the Hop Count and Extended Hop Count fields are zero, the
+ packet is discarded.
+
+ 2. If the Hop Count is non-zero, it is decremented. As long as the
+ Extended Hop Count is non-zero, no special action is taken. If
+ the result of this decrement is zero, the packet is processed
+ normally.
+
+ 3. If the Hop Count is zero, it is set to the maximum value of 63,
+ and the Extended Hop Count is decremented. If this results in the
+ Extended Hop Count being zero, the critical reserved bit in the
+ critical summary bits is set to zero.
+
+10.2.1.4. Egress Behavior
+
+ No special behavior is required when egressing a TRILL Data packet
+ that uses the Extended Hop Count. The flags word, if present, is
+ removed along with the rest of the TRILL Header during decapsulation.
+
+10.2.2. Extended Color Field
+
+ Flags word bits 27 and 28 are specified to be a 2-bit Extended Color
+ field (see Section 10.3). These bits are in the non-critical
+ ingress-to-egress region of the flags word.
+
+ The Extended Color field provides an optional way by which ingress
+ TRILL switches MAY mark TRILL Data packets for implementation-
+ specific purposes. Transit TRILL switches MUST NOT change these
+ bits. Transit and egress TRILL switches MAY use the Extended Color
+ bits for implementation-dependent traffic labeling, or for
+ statistical analysis or other types of traffic study or analysis.
+
+ Per Section 2.3.1 of [RFC7176], support for these bits is indicated
+ by the same bits (27 and 28) in the Capabilities and Header Flags
+ Supported field of the TRILL version sub-TLV. If these bits are zero
+ in those capabilities, Extended Color is not supported. A TRILL
+ switch that does not support Extended Color will ignore the
+ corresponding bits in any TRILL Header flags word it receives as part
+ of a TRILL Data packet and will set those bits to zero in any TRILL
+ Header flags word it creates. A TRILL switch that sets or senses the
+ Extended Color field on transmitting or receiving TRILL Data packets
+ MUST set the corresponding 2-bit field in the TRILL version sub-TLV
+ to a non-zero value. Any difference in the meaning of the three
+ possible non-zero values of this 2-bit capability field (0b01, 0b10,
+ or 0b11) is implementation dependent.
+
+
+
+Eastlake, et al. Standards Track [Page 34]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+10.3. Updated Flags Word Summary
+
+ With the changes above, the 32-bit flags word extension to the TRILL
+ Header [RFC7179], which is detailed in the "TRILL Extended Header
+ Flags" registry on the "Transparent Interconnection of Lots of Links
+ (TRILL) Parameters" IANA web page, is now as follows:
+
+ 0 1 2 3
+ 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+ |Crit.| CHbH | NCHbH |CRSV | NCRSV | CItE | NCItE |
+ |.....|.........|...........|.....|.......|...........|.........|
+ |C|C|C| |C|N| | Ext | | |Ext| |
+ |R|R|R| |R|C| | Hop | | |Clr| |
+ |H|I|R| |C|C| | Cnt | | | | |
+ |b|t|s| |A|A| | | | | | |
+ |H|E|v| |F|F| | | | | | |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+
+ Bits 0, 1, and 2 are the critical summary bits, as specified in
+ [RFC7179], consisting of the critical hop-by-hop, critical
+ ingress-to-egress, and critical reserved bits, respectively. The
+ next two fields are specific critical and non-critical hop-by-hop
+ bits -- CHbH and NCHbH, respectively -- containing the Critical and
+ Non-critical Channel Alert flags as specified in [RFC7179]. The next
+ field is the critical reserved bits (CRSV), which are specified
+ herein to be the Extended Hop Count. The non-critical reserved bits
+ (NCRSV) and the critical ingress-to-egress bits (CItE) as specified
+ in [RFC7179] follow. Finally, there is the non-critical
+ ingress-to-egress field, including bits 27 and 28, which are
+ specified herein as the Extended Color field.
+
+11. Appointed Forwarder Status Lost Counter (New)
+
+ Strict conformance to the provisions of Section 4.8.3 of [RFC6325] on
+ the value of the Appointed Forwarder Status Lost Counter can result
+ in the splitting of Interested VLANs and Spanning Tree Roots sub-TLVs
+ [RFC7176] (or the corresponding Interested Labels and Spanning Tree
+ Roots sub-TLVs where a VLAN is mapped to an FGL) due to differences
+ in this counter value for adjacent VLAN IDs (or 24-bit FGLs). This
+ counter is a mechanism to optimize data-plane learning by trimming
+ the expiration timer for learned addresses on a per-VLAN/FGL basis
+ under some circumstances.
+
+ The requirement to increment this counter by one whenever a TRILL
+ switch loses Appointed Forwarder status on a port is hereby changed
+ from the mandatory provisions of [RFC6325] to the enumerated
+ provisions below. To the extent that this might cause the Appointed
+
+
+
+Eastlake, et al. Standards Track [Page 35]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ Forwarder Status Lost Counter to be increased when [RFC6325]
+ indicates that it should not, this will cause data-plane address
+ learning timeouts at remote TRILL switches to be reduced. To the
+ extent that this might cause the Appointed Forwarder Status Lost
+ Counter to remain unchanged when [RFC6325] indicates that it should
+ be increased, this will defeat a reduction in such timeouts that
+ would otherwise occur.
+
+ (1) If any of the following apply, either data-plane address learning
+ is not in use or Appointed Forwarder status is irrelevant. In
+ these cases, the Appointed Forwarder Status Lost Counter MAY be
+ left at zero or set to any convenient value such as the value of
+ the Appointed Forwarder Status Lost Counter for an adjacent
+ VLAN ID or FGL.
+
+ (1a) The TRILL switch port has been configured with the
+ "end-station service disable" bit (also known as the
+ trunk bit) on.
+
+ (1b) The TRILL switch port has been configured in IS-IS as an
+ IS-IS point-to-point link.
+
+ (1c) The TRILL switch is relying on ESADI [RFC7357] or Directory
+ Assist [RFC7067] and not using data-plane learning.
+
+ (2) In cases other than those enumerated in point 1 above, the
+ Appointed Forwarder Status Lost Counter SHOULD be incremented as
+ described in [RFC6325]. Such incrementing has the advantage of
+ optimizing data-plane learning. Alternatively, the value of the
+ Appointed Forwarder Status Lost Counter can deviate from that
+ value -- for example, to make it match the value for an adjacent
+ VLAN ID (or FGL), so as to permit greater aggregation of
+ Interested VLANs and Spanning Tree Roots sub-TLVs.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 36]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+12. IANA Considerations (Changed)
+
+ This section lists IANA actions previously completed and new IANA
+ actions.
+
+12.1. Previously Completed IANA Actions (Unchanged)
+
+ The following IANA actions were completed as part of [RFC7180] and
+ are included here for completeness, since this document obsoletes
+ [RFC7180].
+
+ 1. The nickname 0xFFC1, which was reserved by [RFC6325], is allocated
+ for use in the TRILL Header Egress Nickname field to indicate an
+ OOMF (Overload Originated Multi-destination Frame).
+
+ 2. Bit 1 from the seven previously reserved (RESV) bits in the
+ per-neighbor "Neighbor RECORD" in the TRILL Neighbor TLV [RFC7176]
+ is allocated to indicate that the RBridge sending the TRILL Hello
+ volunteers to provide the OOMF forwarding service described in
+ Section 2.4.2 to such frames originated by the TRILL switch whose
+ SNPA (MAC address) appears in that Neighbor RECORD. The
+ description of this bit is "Offering OOMF service".
+
+ 3. Bit 0 is allocated from the capability bits in the PORT-TRILL-VER
+ sub-TLV [RFC7176] to indicate support of the VLANs Appointed
+ sub-TLV [RFC7176] and the VLAN inhibition setting mechanisms
+ specified in [RFC6439bis]. The description of this bit is "Hello
+ reduction support".
+
+12.2. New IANA Actions (New)
+
+ The following are new IANA actions for this document.
+
+12.2.1. Reference Updated
+
+ All references to [RFC7180] in the "Transparent Interconnection of
+ Lots of Links (TRILL) Parameters" registry have been replaced with
+ references to this document, except that the Reference for bit 0 in
+ the PORT-TRILL-VER Sub-TLV Capability Flags has been changed to
+ [RFC6439bis].
+
+12.2.2. The "E" Capability Bit
+
+ There is an existing TRILL version sub-TLV, sub-TLV #13, under both
+ TLV #242 and TLV #144 [RFC7176]. This TRILL version sub-TLV contains
+ a capability bits field for which assignments are documented in the
+ "TRILL-VER Sub-TLV Capability Flags" registry on the TRILL Parameters
+ IANA web page. IANA has allocated 4 from the previously reserved
+
+
+
+Eastlake, et al. Standards Track [Page 37]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ bits in this "TRILL-VER Sub-TLV Capability Flags" registry to
+ indicate support of the E-L1FS flooding scope as specified in
+ Section 8.1. This capability bit is referred to as the "E" bit. The
+ following is the addition to the "TRILL-VER Sub-TLV Capability Flags"
+ registry:
+
+ Bit Description References
+ ---- --------------------- ---------------
+ 4 E-L1FS FS-LSP support [RFC7356], RFC 7780
+
+12.2.3. NickFlags APPsub-TLV Number and Registry
+
+ IANA has assigned an APPsub-TLV number, as follows, under the TRILL
+ GENINFO TLV from the range less than 255.
+
+ Type Name References
+ ---- --------- -----------
+ 6 NICKFLAGS RFC 7780
+
+ In addition, IANA has created a registry on its TRILL Parameters web
+ page for NickFlags bit assignments, as follows:
+
+ Name: NickFlags Bits
+ Registration Procedure: IETF Review [RFC5226]
+ Reference: RFC 7780
+
+ Bit Mnemonic Description Reference
+ ----- -------- ----------- ---------
+ 0 IN Used as ingress RFC 7780
+ 1-15 - Unassigned RFC 7780
+
+12.2.4. Updated TRILL Extended Header Flags
+
+ The "TRILL Extended Header Flags" registry has been updated as
+ follows:
+
+ Bits Purpose Reference
+ ----- ---------------------------------------- ------------
+
+ 14-16 Extended Hop Count RFC 7780
+
+ 27-28 Extended Color RFC 7780
+
+ 29-31 Available non-critical ingress-to-egress [RFC7179], RFC 7780
+ flags
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 38]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+12.2.5. TRILL-VER Sub-TLV Capability Flags
+
+ The "TRILL-VER Sub-TLV Capability Flags" registry has been updated as
+ follows:
+
+ Bit Description Reference
+ ----- -------------------------- ----------------
+
+ 14 Extended Hop Count support RFC 7780
+
+ 15-16 Unassigned RFC 7780
+
+ 27-28 Extended Color support RFC 7780
+
+ 29-31 Extended header flag support [RFC7179], RFC 7780
+
+12.2.6. Example Nicknames
+
+ As shown in the table below, IANA has assigned a block of eight
+ nicknames for use as examples in documentation. Appendix B shows a
+ use of some of these nicknames. The "TRILL Nicknames" registry has
+ been updated by changing the previous "0xFFC2-0xFFFE Unassigned" line
+ to the following:
+
+ Name Description Reference
+ ------------- -------------- -----------
+ 0xFFC2-0xFFD7 Unassigned
+ 0xFFD8-0xFFDF For use in documentation examples RFC 7780
+ 0xFFE0-0xFFFE Unassigned
+
+13. Security Considerations (Changed)
+
+ See [RFC6325] for general TRILL security considerations.
+
+ This memo improves the documentation of the TRILL protocol; corrects
+ six errata in [RFC6325]; updates [RFC6325], [RFC7177], and [RFC7179];
+ and obsoletes [RFC7180]. It does not change the security
+ considerations of those RFCs, except as follows:
+
+ o E-L1FS FS-LSPs can be authenticated with IS-IS security [RFC5310],
+ that is, through the inclusion of an IS-IS Authentication TLV in
+ E-L1FS PDUs.
+
+ o As discussed in Section 3.6, when using an allowed weaker RPF
+ check under very rare topologies and transient conditions,
+ multi-destination TRILL Data packets can be duplicated; this could
+ have security consequences for some protocols.
+
+
+
+
+Eastlake, et al. Standards Track [Page 39]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+14. References
+
+14.1. Normative References
+
+ [802.1Q-2014]
+ IEEE, "IEEE Standard for Local and metropolitan area
+ networks -- Bridges and Bridged Networks",
+ DOI 10.1109/IEEESTD.2014.6991462, IEEE Std 802.1Q-2014.
+
+ [IS-IS] International Organization for Standardization,
+ "Information technology -- Telecommunications and
+ information exchange between systems -- Intermediate
+ System to Intermediate System intra-domain routeing
+ information exchange protocol for use in conjunction with
+ the protocol for providing the connectionless-mode network
+ service (ISO 8473)", ISO/IEC 10589:2002, Second Edition,
+ November 2002.
+
+ [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
+ Requirement Levels", BCP 14, RFC 2119,
+ DOI 10.17487/RFC2119, March 1997,
+ <http://www.rfc-editor.org/info/rfc2119>.
+
+ [RFC5305] Li, T. and H. Smit, "IS-IS Extensions for Traffic
+ Engineering", RFC 5305, DOI 10.17487/RFC5305,
+ October 2008, <http://www.rfc-editor.org/info/rfc5305>.
+
+ [RFC5306] Shand, M. and L. Ginsberg, "Restart Signaling for IS-IS",
+ RFC 5306, DOI 10.17487/RFC5306, October 2008,
+ <http://www.rfc-editor.org/info/rfc5306>.
+
+ [RFC5310] Bhatia, M., Manral, V., Li, T., Atkinson, R., White, R.,
+ and M. Fanto, "IS-IS Generic Cryptographic
+ Authentication", RFC 5310, DOI 10.17487/RFC5310,
+ February 2009, <http://www.rfc-editor.org/info/rfc5310>.
+
+ [RFC6232] Wei, F., Qin, Y., Li, Z., Li, T., and J. Dong, "Purge
+ Originator Identification TLV for IS-IS", RFC 6232,
+ DOI 10.17487/RFC6232, May 2011,
+ <http://www.rfc-editor.org/info/rfc6232>.
+
+ [RFC6325] Perlman, R., Eastlake 3rd, D., Dutt, D., Gai, S., and A.
+ Ghanwani, "Routing Bridges (RBridges): Base Protocol
+ Specification", RFC 6325, DOI 10.17487/RFC6325, July 2011,
+ <http://www.rfc-editor.org/info/rfc6325>.
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 40]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ [RFC6361] Carlson, J. and D. Eastlake 3rd, "PPP Transparent
+ Interconnection of Lots of Links (TRILL) Protocol Control
+ Protocol", RFC 6361, DOI 10.17487/RFC6361, August 2011,
+ <http://www.rfc-editor.org/info/rfc6361>.
+
+ [RFC7172] Eastlake 3rd, D., Zhang, M., Agarwal, P., Perlman, R., and
+ D. Dutt, "Transparent Interconnection of Lots of Links
+ (TRILL): Fine-Grained Labeling", RFC 7172,
+ DOI 10.17487/RFC7172, May 2014,
+ <http://www.rfc-editor.org/info/rfc7172>.
+
+ [RFC7176] Eastlake 3rd, D., Senevirathne, T., Ghanwani, A., Dutt,
+ D., and A. Banerjee, "Transparent Interconnection of Lots
+ of Links (TRILL) Use of IS-IS", RFC 7176,
+ DOI 10.17487/RFC7176, May 2014,
+ <http://www.rfc-editor.org/info/rfc7176>.
+
+ [RFC7177] Eastlake 3rd, D., Perlman, R., Ghanwani, A., Yang, H., and
+ V. Manral, "Transparent Interconnection of Lots of Links
+ (TRILL): Adjacency", RFC 7177, DOI 10.17487/RFC7177,
+ May 2014, <http://www.rfc-editor.org/info/rfc7177>.
+
+ [RFC7179] Eastlake 3rd, D., Ghanwani, A., Manral, V., Li, Y., and C.
+ Bestler, "Transparent Interconnection of Lots of Links
+ (TRILL): Header Extension", RFC 7179,
+ DOI 10.17487/RFC7179, May 2014,
+ <http://www.rfc-editor.org/info/rfc7179>.
+
+ [RFC7356] Ginsberg, L., Previdi, S., and Y. Yang, "IS-IS Flooding
+ Scope Link State PDUs (LSPs)", RFC 7356,
+ DOI 10.17487/RFC7356, September 2014,
+ <http://www.rfc-editor.org/info/rfc7356>.
+
+ [RFC7455] Senevirathne, T., Finn, N., Salam, S., Kumar, D., Eastlake
+ 3rd, D., Aldrin, S., and Y. Li, "Transparent
+ Interconnection of Lots of Links (TRILL): Fault
+ Management", RFC 7455, DOI 10.17487/RFC7455, March 2015,
+ <http://www.rfc-editor.org/info/rfc7455>.
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 41]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+14.2. Informative References
+
+ [802] IEEE 802, "IEEE Standard for Local and Metropolitan Area
+ Networks: Overview and Architecture",
+ DOI 10.1109/IEEESTD.2014.6847097, IEEE Std 802-2014.
+
+ [Centralized-Replication]
+ Hao, W., Li, Y., Durrani, M., Gupta, S., Qu, A., and T.
+ Han, "Centralized Replication for BUM traffic in
+ active-active edge connection", Work in Progress,
+ draft-ietf-trill-centralized-replication-03,
+ November 2015.
+
+ [Err3002] RFC Errata, Erratum ID 3002, RFC 6325.
+
+ [Err3003] RFC Errata, Erratum ID 3003, RFC 6325.
+
+ [Err3004] RFC Errata, Erratum ID 3004, RFC 6325.
+
+ [Err3052] RFC Errata, Erratum ID 3052, RFC 6325.
+
+ [Err3053] RFC Errata, Erratum ID 3053, RFC 6325.
+
+ [Err3508] RFC Errata, Erratum ID 3508, RFC 6325.
+
+ [RFC792] Postel, J., "Internet Control Message Protocol", STD 5,
+ RFC 792, DOI 10.17487/RFC0792, September 1981,
+ <http://www.rfc-editor.org/info/rfc792>.
+
+ [RFC826] Plummer, D., "Ethernet Address Resolution Protocol: Or
+ Converting Network Protocol Addresses to 48.bit Ethernet
+ Address for Transmission on Ethernet Hardware", STD 37,
+ RFC 826, DOI 10.17487/RFC0826, November 1982,
+ <http://www.rfc-editor.org/info/rfc826>.
+
+ [RFC4086] Eastlake 3rd, D., Schiller, J., and S. Crocker,
+ "Randomness Requirements for Security", BCP 106, RFC 4086,
+ DOI 10.17487/RFC4086, June 2005,
+ <http://www.rfc-editor.org/info/rfc4086>.
+
+ [RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an
+ IANA Considerations Section in RFCs", BCP 26, RFC 5226,
+ DOI 10.17487/RFC5226, May 2008,
+ <http://www.rfc-editor.org/info/rfc5226>.
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 42]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ [RFC6327] Eastlake 3rd, D., Perlman, R., Ghanwani, A., Dutt, D., and
+ V. Manral, "Routing Bridges (RBridges): Adjacency",
+ RFC 6327, DOI 10.17487/RFC6327, July 2011,
+ <http://www.rfc-editor.org/info/rfc6327>.
+
+ [RFC6439] Perlman, R., Eastlake, D., Li, Y., Banerjee, A., and F.
+ Hu, "Routing Bridges (RBridges): Appointed Forwarders",
+ RFC 6439, DOI 10.17487/RFC6439, November 2011,
+ <http://www.rfc-editor.org/info/rfc6439>.
+
+ [RFC6439bis]
+ Eastlake 3rd, D., Li, Y., Umair, M., Banerjee, A., and H.
+ Fangwei, "TRILL: Appointed Forwarders", Work in Progress,
+ draft-ietf-trill-rfc6439bis-01, January 2016.
+
+ [RFC7042] Eastlake 3rd, D. and J. Abley, "IANA Considerations and
+ IETF Protocol and Documentation Usage for IEEE 802
+ Parameters", BCP 141, RFC 7042, DOI 10.17487/RFC7042,
+ October 2013, <http://www.rfc-editor.org/info/rfc7042>.
+
+ [RFC7067] Dunbar, L., Eastlake 3rd, D., Perlman, R., and I.
+ Gashinsky, "Directory Assistance Problem and High-Level
+ Design Proposal", RFC 7067, DOI 10.17487/RFC7067,
+ November 2013, <http://www.rfc-editor.org/info/rfc7067>.
+
+ [RFC7175] Manral, V., Eastlake 3rd, D., Ward, D., and A. Banerjee,
+ "Transparent Interconnection of Lots of Links (TRILL):
+ Bidirectional Forwarding Detection (BFD) Support",
+ RFC 7175, DOI 10.17487/RFC7175, May 2014,
+ <http://www.rfc-editor.org/info/rfc7175>.
+
+ [RFC7178] Eastlake 3rd, D., Manral, V., Li, Y., Aldrin, S., and D.
+ Ward, "Transparent Interconnection of Lots of Links
+ (TRILL): RBridge Channel Support", RFC 7178,
+ DOI 10.17487/RFC7178, May 2014,
+ <http://www.rfc-editor.org/info/rfc7178>.
+
+ [RFC7180] Eastlake 3rd, D., Zhang, M., Ghanwani, A., Manral, V., and
+ A. Banerjee, "Transparent Interconnection of Lots of Links
+ (TRILL): Clarifications, Corrections, and Updates",
+ RFC 7180, DOI 10.17487/RFC7180, May 2014,
+ <http://www.rfc-editor.org/info/rfc7180>.
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 43]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ [RFC7357] Zhai, H., Hu, F., Perlman, R., Eastlake 3rd, D., and O.
+ Stokes, "Transparent Interconnection of Lots of Links
+ (TRILL): End Station Address Distribution Information
+ (ESADI) Protocol", RFC 7357, DOI 10.17487/RFC7357,
+ September 2014, <http://www.rfc-editor.org/info/rfc7357>.
+
+ [TRILL-L3-GW]
+ Hao, W., Li, Y., Qu, A., Durrani, M., Sivamurugan, P., and
+ L. Xia, "TRILL Distributed Layer 3 Gateway", Work in
+ Progress, draft-ietf-trill-irb-10, January 2016.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 44]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+Appendix A. Life Cycle of a TRILL Switch Port (New)
+
+ Text from <http://www.ietf.org/mail-archive/web/trill/
+ current/msg06355.html> is paraphrased in this informational appendix.
+
+ Question:
+ Suppose we are developing a TRILL implementation to run on
+ different machines. Then what happens first? Is LSP flooding or
+ ESADI started first? -> Link-state database creation ->
+ Designated RBridge election (How to set priority? Any fixed
+ process that depends on user settings?) -> etc.
+
+ Answer:
+ The first thing that happens on a port/link is any link setup that
+ is needed. For example, on a PPP link [RFC6361], you need to
+ negotiate that you will be using TRILL. However, if you have
+ Ethernet links [RFC6325], which are probably the most common type,
+ there isn't any link setup needed.
+
+ As soon as the port is set up, it can ingress or egress native
+ frames if end-station service is being offered on that port.
+ Offering end-station service is the default. However, if the port
+ trunk bit (end-station service disable) is set or the port is
+ configured as an IS-IS point-to-point link port, then end-station
+ service is not offered; therefore, native frames received are
+ ignored, and native frames are not egressed.
+
+ TRILL IS-IS Hellos then get sent out the port to be exchanged with
+ any other TRILL switches on the link [RFC7177]. Only the Hellos
+ are required; optionally, you might also exchange MTU-probe/ack
+ PDUs [RFC7177], BFD PDUs [RFC7175], or other link test packets.
+
+ TRILL doesn't send any TRILL Data or TRILL IS-IS packets out the
+ port to the link, except for Hellos, until the link gets to the
+ 2-Way or Report state [RFC7177].
+
+ If a link is configured as a point-to-point link, there is no
+ Designated RBridge (DRB) election. By default, an Ethernet link
+ is considered a LAN link, and the DRB election occurs when the
+ link is in any state other than Down. You don't have to configure
+ priorities for each TRILL switch (RBridge) to be the DRB. Things
+ will work fine with all the RBridges on a link using default
+ priority. But if the network manager wants to control this, there
+ should be a way for them to configure the priority to be the DRB
+ of the TRILL switch ports on the link.
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 45]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ (To avoid complexity, this appendix generally describes the
+ life cycle for a link that only has two TRILL switches on it. But
+ TRILL works fine as currently specified on a broadcast link with
+ multiple TRILL switches on it -- actually, multiple TRILL switch
+ ports -- since a TRILL switch can have multiple ports connected to
+ the same link. The most likely way to get such a multi-access
+ link with current technology and the existing TRILL standards is
+ to have more than two TRILL switch Ethernet ports connected to a
+ bridged LAN. The TRILL protocol operates above all bridging; in
+ general, the bridged LAN looks like a transparent broadcast link
+ to TRILL.)
+
+ When a link gets to the 2-Way or Report state, LSPs, CSNPs, and
+ PSNPs will start to flow on the link (as well as FS-LSPs,
+ FS-CSNPs, and FS-PSNPs for E-L1FS (see Section 8.1)).
+
+ When a link gets to the Report state, there is adjacency. The
+ existence of that adjacency is flooded (reported) to the campus in
+ LSPs. TRILL Data packets can then start to flow on the link as
+ TRILL switches recalculate the least-cost paths and distribution
+ trees to take the new adjacency into account. Until it gets to
+ the Report state, there is no adjacency, and no TRILL Data packets
+ can flow over that link (with the minor corner case exception that
+ an RBridge Channel message can, for its first hop only, be sent on
+ a port where there is no adjacency (Section 2.4 of [RFC7178]).
+ (Although this paragraph seems to be talking about link state, it
+ is actually port state. It is possible for different TRILL switch
+ ports on the same link to temporarily be in different states. The
+ adjacency state machinery runs independently on each port.)
+
+ ESADI [RFC7357] is built on top of the regular TRILL Data routing.
+ Since ESADI PDUs look, to transit TRILL switches, like regular
+ TRILL Data packets, no ESADI PDUs can flow until adjacencies are
+ established and TRILL Data is flowing. Of course, ESADI is
+ optional and is not used unless configured.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 46]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ Question:
+ Does it require TRILL Full Headers at the time TRILL LSPs start
+ being broadcast on a link? Because at that time it's not defined
+ egress and ingress nicknames.
+
+ Answer:
+ TRILL Headers are only for TRILL Data packets. TRILL IS-IS
+ packets, such as TRILL LSPs, are sent in a different way that does
+ not use a TRILL Header and does not depend on nicknames.
+
+ Probably, in most implementations, a TRILL switch will start up
+ using the same nickname it had when it shut down or last got
+ disconnected from a campus. If you want, you can implement TRILL
+ to come up initially not reporting any nickname (by not including
+ a Nickname sub-TLV in its LSPs) until you get the link-state
+ database or most of the link-state database, and then choose a
+ nickname no other TRILL switch in the campus is using. Of course,
+ if a TRILL switch does not have a nickname, then it cannot ingress
+ data, cannot egress known unicast data, and cannot be a tree root.
+
+ TRILL IS-IS PDUs such as LSPs, and the link-state database, all
+ work based on the 7-byte IS-IS System ID (sometimes called the
+ LAN ID [IS-IS]). Since topology determination uses System IDs,
+ which are always unique across the campus, it is not affected by
+ the nickname assignment state. The nickname system is built on
+ top of that.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 47]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+Appendix B. Example TRILL PDUs (New)
+
+ This appendix shows example TRILL IS-IS PDUs. The primary purpose of
+ these examples is to clarify issues related to bit ordering.
+
+ The examples in this appendix concentrate on the format of the packet
+ header and trailer. There are frequently unspecified optional items
+ or data in the packet that would affect header or trailer fields like
+ the packet length or checksum. Thus, an "Xed out" placeholder is
+ used for such fields, where each X represents one hex nibble.
+
+B.1. LAN Hello over Ethernet
+
+ A TRILL Hello sent from a TRILL switch (RBridge) with 7-byte
+ System ID 0x30033003300300 holding nickname 0xFFDE over Ethernet from
+ a port with MAC address 0x00005E0053DE on VLAN 1 at priority 7.
+ There is one neighbor that is the DRB. The neighbor's port MAC is
+ 0x00005E0053E3, and the neighbor's System ID is 0x44444444444400.
+
+ Ethernet Header
+ Outer.MacDA, Outer.MacSA
+ 0x0180C2000041 All-IS-IS-RBridges Destination MAC Address
+ 0x00005E0053DE Source MAC Address
+ Outer VLAN Tag (optional)
+ 0x8100 C-VLAN Ethertype [802.1Q-2014]
+ 0xE001 Priority 7, Outer.VLAN
+ IS-IS
+ 0x22F4 L2-IS-IS Ethertype
+ IS-IS Payload
+ Common Header
+ 0x83 Intradomain Routeing Protocol Discriminator
+ 0x08 Header Length
+ 0x01 IS-IS Version Number
+ 0x06 ID Length of 6 Bytes
+ 0x0F PDU Type (Level 1 LAN Hello)
+ 0x01 Version
+ 0x00 Reserved
+ 0x01 Maximum Area Addresses
+ Hello PDU Specific Fields
+ 0x01 Circuit Type (Level 1)
+ 0x30033003300300 Source System ID
+ 0x0009 Holding Time
+ 0xXXXX PDU Length
+ 0x40 Priority to be DRB
+ 0x44444444444400 LAN ID
+ TLVs (the following order of TLVs or of sub-TLVs in a TLV
+ is not significant)
+
+
+
+
+Eastlake, et al. Standards Track [Page 48]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ Area Addresses TLV
+ 0x01 Area Addresses Type
+ 0x02 Length of Value
+ 0x01 Length of Address
+ 0x00 The fixed TRILL Area Address
+ MT Port Capabilities TLV
+ 0x8F MT Port Capabilities Type
+ 0x0011 Length of Value
+ 0x0000 Topology
+ Special VLANs and Flags Sub-TLV
+ 0x01 Sub-TLV Type
+ 0x08 Length
+ 0x0123 Port ID
+ 0xFFDE Sender Nickname
+ 0x0001 Outer.VLAN
+ 0x0001 Designated VLAN
+ Enabled VLANs Sub-TLV (optional)
+ 0x02 Sub-TLV Type
+ 0x03 Length
+ 0x0001 Start VLAN 1
+ 0x80 VLAN 1
+ TRILL Neighbor TLV
+ 0x91 Neighbor Type
+ 0x0A Length of Value
+ 0xC0 S Flag = 1, L Flag = 1, SIZE field 0
+ NEIGHBOR RECORD
+ 0x00 Flags
+ 0x2328 MTU = 9 KB
+ 0x00005E0053E3 Neighbor MAC Address
+ Scope Flooding Support TLV
+ 0xF3 Scope Flooding Support Type
+ 0x01 Length of Value
+ 0x40 E-L1FS Flooding Scope
+ More TLVs (optional)
+ ...
+ Ethernet Trailer
+ 0xXXXXXXXX Ethernet Frame Check Sequence (FCS)
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 49]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+B.2. LSP over PPP
+
+ Here is an example of a TRILL LSP sent over a PPP link by the same
+ source TRILL switch as the example in Appendix B.1.
+
+ PPP Header
+ 0x405D PPP TRILL Link State Protocol
+ IS-IS Payload
+ Common Header
+ 0x83 Intradomain Routeing Protocol Discriminator
+ 0x08 Header Length
+ 0x01 IS-IS Version Number
+ 0x06 ID Length of 6 Bytes
+ 0x12 PDU Type (Level 1 LSP)
+ 0x01 Version
+ 0x00 Reserved
+ 0x01 Maximum Area Addresses
+ LSP Specific Fields
+ 0xXXXX PDU Length
+ 0x0123 Remaining Lifetime
+ 0x3003300330030009 LSP ID (fragment 9)
+ 0x00001234 Sequence Number
+ 0xXXXX Checksum
+ 0x01 Flags = Level 1
+ TLVs (the following order of TLVs or of sub-TLVs in a TLV
+ is not significant)
+ Router Capability TLV
+ 0xF2 Router Capability Type
+ 0x0F Length of Value
+ 0x00 Flags
+ Nickname Sub-TLV
+ 0x06 Sub-TLV Type
+ 0x05 Length of Value
+ NICKNAME RECORD
+ 0x33 Nickname Priority
+ 0x1234 Tree Root Priority
+ 0xFFDE Nickname
+ TRILL Version Sub-TLV
+ 0x0D Sub-TLV Type
+ 0x05
+ 0x00 Max Version
+ 0x40000000 Flags = FGL Support
+ More TLVs (optional
+ ...
+ PPP Trailer
+ 0xXXXXXX PPP Frame Check Sequence (FCS)
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 50]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+B.3. TRILL Data over Ethernet
+
+ Below is an IPv4 ICMP Echo [RFC792] sent in a TRILL Data packet from
+ the TRILL switch that sent the Hello in Appendix B.1 to the neighbor
+ TRILL switch on the link used in Appendix B.1.
+
+ Ethernet Header
+ Outer.MacDA, Outer.MacSA
+ 0x00005E0053E3 Destination MAC Address
+ 0x00005E0053DE Source MAC Address
+ Outer VLAN Tag (optional)
+ 0x8100 C-VLAN Ethertype [802.1Q-2014]
+ 0x0001 Priority 0, Outer.VLAN 1
+ TRILL
+ 0x22F3 TRILL Ethertype
+ TRILL Header
+ 0X000E Flags, Hop Count 14
+ 0xFFDF Egress Nickname
+ 0xFFDC Ingress Nickname
+ Inner Ethernet Header
+ Inner.MacDA, Inner.MacSA
+ 0x00005E005322 Destination MAC Address
+ 0x00005E005344 Source MAC Address
+ Inner VLAN Tag
+ 0x8100 C-VLAN Ethertype
+ 0x0022 Priority 0, Inner.VLAN 34
+ Ethertype
+ 0x0800 IPv4 Ethertype
+ IP Header
+ 0x4500 Version 4, Header Length 5, ToS 0
+ 0xXXXX Total Length
+ 0x3579 Identification
+ 0x0000 Flags, Fragment Offset
+ 0x1101 TTL 17, ICMP = Protocol 1
+ 0xXXXX Header Checksum
+ 0xC0000207 Source IP 192.0.2.7
+ 0xC000020D Destination IP 192.0.2.13
+ 0x00000000 Options, Padding
+ ICMP
+ 0x0800 ICMP Echo
+ 0xXXXX Checksum
+ 0x87654321 Identifier, Sequence Number
+ ... Echo Data
+ Ethernet Trailer
+ 0xXXXXXXXX Ethernet Frame Check Sequence (FCS)
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 51]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+B.4. TRILL Data over PPP
+
+ Below is an ARP Request [RFC826] sent in a TRILL Data packet from the
+ TRILL switch that sent the Hello in Appendix B.1 over a PPP link.
+
+ PPP Header
+ 0x005D PPP TRILL Network Protocol
+ TRILL Header
+ 0X080D Flags (M = 1), Hop Count 13
+ 0xFFDD Distribution Tree Root Nickname
+ 0xFFDC Ingress Nickname
+ Inner Ethernet Header
+ Inner.MacDA, Inner.MacSA
+ 0xFFFFFFFFFFFF Destination MAC Address
+ 0x00005E005344 Source MAC Address
+ Inner VLAN Tag
+ 0x8100 C-VLAN Ethertype
+ 0x0022 Priority 0, Inner.VLAN 34
+ Ethertype
+ 0x0806 ARP Ethertype
+ ARP
+ 0x0001 Hardware Address Space = Ethernet
+ 0x0001 Protocol Address Space = IPv4
+ 0x06 Size of Hardware Address
+ 0x04 Size of Protocol Address
+ 0x0001 OpCode = Request
+ 0x00005E005344 Sender Hardware Address
+ 0xC0000207 Sender Protocol Address 192.0.2.7
+ 0x000000000000 Target Hardware Address
+ 0xC000020D Target Protocol Address 192.0.2.13
+ PPP Trailer
+ 0xXXXXXX PPP Frame Check Sequence (FCS)
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 52]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+Appendix C. Changes to Previous RFCs (New)
+
+C.1. Changes to Obsoleted RFC 7180
+
+ This section summarizes the changes, augmentations, and excisions
+ this document specifies for [RFC7180], which it obsoletes and
+ replaces.
+
+C.1.1. Changes
+
+ For each section header in this document ending with "(Changed)",
+ this section summarizes the changes that are made by this document:
+
+ Section 1 ("Introduction"): Numerous changes to reflect the overall
+ changes in contents.
+
+ Section 1.1 ("Precedence"): Changed to add mention of [RFC7179].
+
+ Section 1.3 ("Terminology and Acronyms"): Numerous terms added.
+
+ Section 3 ("Distribution Trees and RPF Check"): Changed by the
+ addition of the new material in Section 3.6. See Appendix C.1.2,
+ Item 1.
+
+ Section 8 ("Other IS-IS Considerations"): Changed by the addition of
+ Sections 8.1, 8.2, 8.3, and 8.4. See Appendix C.1.2 -- Items 2, 3,
+ 4, and 5, respectively.
+
+ Section 9 ("Updates to RFC 7177 (Adjacency)": Changes and additions
+ to [RFC7177] to support E-L1FS. See Appendix C.1.2, Item 2.
+
+ Section 12 ("IANA Considerations"): Changed by the addition of
+ material in Section 12.2. See Appendix C.1.2, Item 7.
+
+ Section 13 ("Security Considerations"): Minor changes in the RFCs
+ listed.
+
+C.1.2. Additions
+
+ This document contains the following material not present in
+ [RFC7180]:
+
+ 1. Support for an alternative Reverse Path Forwarding Check (RPFC),
+ along with considerations for deciding between the original
+ [RFC6325] RPFC and this alternative RPFC. This alternative RPFC
+ was originally discussed on the TRILL WG mailing list in
+ <http://www.ietf.org/mail-archive/web/trill/current/
+ msg01852.html> and subsequent messages (Section 3.6).
+
+
+
+Eastlake, et al. Standards Track [Page 53]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ 2. Mandatory E-L1FS [RFC7356] support (Sections 8.1 and 9).
+
+ 3. Recommendations concerning control packet priorities
+ (Section 8.2).
+
+ 4. Implementation requirements concerning unknown IS-IS PDU types
+ (Section 8.3).
+
+ 5. Specification of an optional Nickname Flags APPsub-TLV and an
+ ingress flag within that APPsub-TLV (Section 8.4).
+
+ 6. Update to the TRILL Header to allocate a Color bit
+ (Section 10.1), and update to the optional TRILL Header Extension
+ flags word to allocate a 2-bit Extended Color field
+ (Section 10.2).
+
+ 7. Some new IANA Considerations in Section 12.2, including
+ reservation of nicknames for use as examples in documentation.
+
+ 8. A new "Appointed Forwarder Status Lost Counter" section
+ (Section 11 of this document) that loosens the mandatory update
+ requirements specified in [RFC6325].
+
+ 9. Informative Appendix A on the life cycle of a TRILL port.
+
+ 10. A new Appendix B containing example TRILL PDUs.
+
+ 11. Recommendation to use the Purge Originator Identification TLV
+ (Section 8.6).
+
+C.1.3. Deletions
+
+ This document omits the following material that was present in
+ [RFC7180]:
+
+ 1. All updates to [RFC6327] that occurred in [RFC7180]. These have
+ been rolled into [RFC7177], which obsoletes [RFC6327]. However,
+ new updates to [RFC7177] are included (see Appendix C.3).
+
+ 2. All updates to [RFC6439]. These have been rolled into
+ [RFC6439bis], which is intended to obsolete [RFC6439].
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 54]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+C.2. Changes to RFC 6325
+
+ This document contains many normative updates to [RFC6325], some of
+ which were also in [RFC7180], which this document replaces. These
+ changes include the following:
+
+ 1. Changing nickname allocation to ignore conflicts with RBridges
+ that are IS-IS unreachable.
+
+ 2. Fixing errors: [Err3002], [Err3003], [Err3004], [Err3052],
+ [Err3053], and [Err3508].
+
+ 3. Changing the requirement to use the RPF check described in
+ [RFC6325] for multi-destination TRILL Data packets by providing
+ an alternative stronger RPF check.
+
+ 4. Adoption of the change of the CFI bit, which was required to be
+ zero in the inner frame, to the DEI bit, which is obtained from
+ inner frame ingress or creation.
+
+ 5. Requiring that all RBridges support E-L1FS FS-LSP flooding.
+
+ 6. Reducing the variable-length TRILL Header extensions area to one
+ optional flags word. The Extension Length field (called
+ "Op-Length" in [RFC6325]) is reduced to 1 bit that indicates
+ whether the flags word is present. The rest of that Length field
+ is now reserved.
+
+ 7. Changing the mandatory Appointed Forwarder Status Lost Counter
+ increment provisions, as specified in Section 11.
+
+C.3. Changes to RFC 7177
+
+ All of the updates to [RFC7177] herein are in Section 9. Basically,
+ this document requires that a Scope Flooding Support TLV [RFC7356]
+ appear in all Hellos and that TRILL switches retain in their
+ adjacency state the information received in that TLV.
+
+C.4. Changes to RFC 7179
+
+ The updates to [RFC7179] herein are in Sections 10.2 and 10.3.
+
+
+
+
+
+
+
+
+
+
+Eastlake, et al. Standards Track [Page 55]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+Acknowledgments
+
+ The contributions of the following individuals to this document are
+ gratefully acknowledged:
+
+ Santosh Rajagopalan and Gayle Noble
+
+ The contributions of the following (listed in alphabetical order) to
+ the preceding version of this document, [RFC7180], are gratefully
+ acknowledged:
+
+ Somnath Chatterjee, Weiguo Hao, Rakesh Kumar, Yizhou Li, Radia
+ Perlman, Varun Shah, Mike Shand, and Meral Shirazipour.
+
+Authors' Addresses
+
+ Donald Eastlake 3rd
+ Huawei Technology
+ 155 Beaver Street
+ Milford, MA 01757
+ United States
+
+ Phone: +1-508-333-2270
+ Email: d3e3e3@gmail.com
+
+
+ Mingui Zhang
+ Huawei Technologies
+ No. 156 Beiqing Rd., Haidian District
+ Beijing 100095
+ China
+
+ Email: zhangmingui@huawei.com
+
+
+ Radia Perlman
+ EMC
+ 2010 256th Avenue NE, #200
+ Bellevue, WA 98007
+ United States
+
+ Email: radia@alum.mit.edu
+
+
+ Ayan Banerjee
+ Cisco
+
+ Email: ayabaner@cisco.com
+
+
+
+Eastlake, et al. Standards Track [Page 56]
+
+RFC 7780 TRILL Clarifications, Corrections, Updates February 2016
+
+
+ Anoop Ghanwani
+ Dell
+ 5450 Great America Parkway
+ Santa Clara, CA 95054
+ United States
+
+ Email: anoop@alumni.duke.edu
+
+
+ Sujay Gupta
+ IP Infusion
+ RMZ Centennial
+ Mahadevapura Post
+ Bangalore 560048
+ India
+
+ Email: sujay.gupta@ipinfusion.com
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
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+
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+
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+
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+
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+
+Eastlake, et al. Standards Track [Page 57]
+