SPRING
Internet Engineering Task Force (IETF) W. Cheng, Ed.
Internet-Draft
Request for Comments: 9800 China Mobile
Updates: 8754 (if approved) C. Filsfils
Intended status:
Category: Standards Track Cisco Systems, Inc.
Expires: 10 August 2025
ISSN: 2070-1721 Z. Li
Huawei Technologies
B. Decraene
Orange
F. Clad, Ed.
Cisco Systems, Inc.
6 February
June 2025
Compressed SRv6 Segment List Encoding (CSID)
draft-ietf-spring-srv6-srh-compression-23
Abstract
Segment Routing over IPv6 (SRv6) is the instantiation of Segment
Routing (SR) on the IPv6 dataplane. data plane. This document specifies new
flavors for the SRv6 endpoint behaviors defined in RFC 8986, which
enable the compression of an SRv6 segment list. Such compression
significantly reduces the size of the SRv6 encapsulation needed to
steer packets over long segment lists.
This document updates RFC 8754 by allowing a Segment List entry in
the Segment Routing Header (SRH) to be either an IPv6 address, as
specified in RFC 8754, or a REPLACE-CSID container in packed format,
as specified in this document.
Status of This Memo
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This Internet-Draft will expire on 10 August 2025.
https://www.rfc-editor.org/info/rfc9800.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 4
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.1. Requirements Language . . . . . . . . . . . . . . . . . . 6
3. Basic Concepts . . . . . . . . . . . . . . . . . . . . . . . 6
4. SR Segment Endpoint Flavors . . . . . . . . . . . . . . . . . 6
4.1. NEXT-CSID Flavor . . . . . . . . . . . . . . . . . . . . 8
4.1.1. End with NEXT-CSID . . . . . . . . . . . . . . . . . 10
4.1.2. End.X with NEXT-CSID . . . . . . . . . . . . . . . . 11
4.1.3. End.T with NEXT-CSID . . . . . . . . . . . . . . . . 12
4.1.4. End.B6.Encaps with NEXT-CSID . . . . . . . . . . . . 12
4.1.5. End.B6.Encaps.Red with NEXT-CSID . . . . . . . . . . 13
4.1.6. End.BM with NEXT-CSID . . . . . . . . . . . . . . . . 13
4.1.7. Combination with PSP, USP USP, and USD flavors . . . . . . 14 Flavors
4.2. REPLACE-CSID Flavor . . . . . . . . . . . . . . . . . . . 14
4.2.1. End with REPLACE-CSID . . . . . . . . . . . . . . . . 19
4.2.2. End.X with REPLACE-CSID . . . . . . . . . . . . . . . 21
4.2.3. End.T with REPLACE-CSID . . . . . . . . . . . . . . . 21
4.2.4. End.B6.Encaps with REPLACE-CSID . . . . . . . . . . . 22
4.2.5. End.B6.Encaps.Red with REPLACE-CSID . . . . . . . . . 22
4.2.6. End.BM with REPLACE-CSID . . . . . . . . . . . . . . 23
4.2.7. End.DX and End.DT with REPLACE-CSID . . . . . . . . . 23
4.2.8. Combination with PSP, USP, and USD flavors . . . . . 24 Flavors
5. CSID Allocation . . . . . . . . . . . . . . . . . . . . . . . 24
5.1. Global CSID . . . . . . . . . . . . . . . . . . . . . . . 25
5.2. Local CSID . . . . . . . . . . . . . . . . . . . . . . . 25
5.3. Recommended Installation of CSIDs in FIB . . . . . . . . 25
6. SR Source Node . . . . . . . . . . . . . . . . . . . . . . . 27
6.1. SID Validation for Compression . . . . . . . . . . . . . 27
6.2. Segment List Compression . . . . . . . . . . . . . . . . 27
6.3. Rules for segment lists containing Segment Lists Containing NEXT-CSID flavor Flavor SIDs . . . . . . . . . . . . . . . . . . . . . . . . . . 31
6.4. Rules for segment lists containing Segment Lists Containing REPLACE-CSID flavor Flavor SIDs . . . . . . . . . . . . . . . . . . . . . . . . . . 32
6.5. Upper-Layer Checksums . . . . . . . . . . . . . . . . . . 33
7. Inter-Domain Compression . . . . . . . . . . . . . . . . . . 33
7.1. End.LBS: Locator-Block Swap . . . . . . . . . . . . . . . 33
7.1.1. End.LBS with NEXT-CSID . . . . . . . . . . . . . . . 34
7.1.2. End.LBS with REPLACE-CSID . . . . . . . . . . . . . . 34
7.2. End.XLBS: L3 Cross-Connect and Locator-Block Swap . . . . 35
7.2.1. End.XLBS with NEXT-CSID . . . . . . . . . . . . . . . 35
7.2.2. End.XLBS with REPLACE-CSID . . . . . . . . . . . . . 36
8. Control Plane . . . . . . . . . . . . . . . . . . . . . . . . 36
9. Operational Considerations . . . . . . . . . . . . . . . . . 38
9.1. Flavor, Block, and CSID Length . . . . . . . . . . . . . 38
9.2. GIB/LIB Usage . . . . . . . . . . . . . . . . . . . . . . 38
9.3. Pinging a SID . . . . . . . . . . . . . . . . . . . . . . 39
9.4. ICMP Error Processing . . . . . . . . . . . . . . . . . . 40
10. Implementation Status . . . . . . . . . . . . . . . . . . . . 41
10.1. Cisco Systems . . . . . . . . . . . . . . . . . . . . . 41
10.2. Huawei Technologies . . . . . . . . . . . . . . . . . . 42
10.3. Nokia . . . . . . . . . . . . . . . . . . . . . . . . . 43
10.4. Arrcus . . . . . . . . . . . . . . . . . . . . . . . . . 43
10.5. Juniper Networks . . . . . . . . . . . . . . . . . . . . 44
10.6. Marvell . . . . . . . . . . . . . . . . . . . . . . . . 44
10.7. Broadcom . . . . . . . . . . . . . . . . . . . . . . . . 44
10.8. ZTE Corporation . . . . . . . . . . . . . . . . . . . . 45
10.9. New H3C Technologies . . . . . . . . . . . . . . . . . . 45
10.10. Ruijie Network . . . . . . . . . . . . . . . . . . . . . 45
10.11. Ciena . . . . . . . . . . . . . . . . . . . . . . . . . 46
10.12. Centec . . . . . . . . . . . . . . . . . . . . . . . . . 46
10.13. Open-Source . . . . . . . . . . . . . . . . . . . . . . 46
10.14. Interoperability Reports . . . . . . . . . . . . . . . . 47
10.14.1. EANTC 2024 . . . . . . . . . . . . . . . . . . . . 47
10.14.2. Bell Canada / Ciena 2023 . . . . . . . . . . . . . 47
10.14.3. EANTC 2023 . . . . . . . . . . . . . . . . . . . . 47
10.14.4. China Mobile 2020 . . . . . . . . . . . . . . . . . 48
11. Applicability to other Other SRv6 Endpoint Behaviors . . . . . . . 49
12.
11. Security Considerations . . . . . . . . . . . . . . . . . . . 49
13.
12. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 50
13.1.
12.1. SRv6 Endpoint Behaviors . . . . . . . . . . . . . . . . 51
14. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 54
15.
13. References . . . . . . . . . . . . . . . . . . . . . . . . . 54
15.1.
13.1. Normative References . . . . . . . . . . . . . . . . . . 54
15.2.
13.2. Informative References . . . . . . . . . . . . . . . . . 55
Appendix A. Complete pseudocodes . . . . . . . . . . . . . . . . 58 Pseudocodes
A.1. End with NEXT-CSID . . . . . . . . . . . . . . . . . . . 58
A.2. End.X with NEXT-CSID . . . . . . . . . . . . . . . . . . 60
A.3. End.T with NEXT-CSID . . . . . . . . . . . . . . . . . . 62
A.4. End.B6.Encaps with NEXT-CSID . . . . . . . . . . . . . . 64
A.5. End.BM with NEXT-CSID . . . . . . . . . . . . . . . . . . 66
A.6. End with REPLACE-CSID . . . . . . . . . . . . . . . . . . 68
A.7. End.X with REPLACE-CSID . . . . . . . . . . . . . . . . . 70
A.8. End.T with REPLACE-CSID . . . . . . . . . . . . . . . . . 72
A.9. End.B6.Encaps with REPLACE-CSID . . . . . . . . . . . . . 74
A.10. End.BM with REPLACE-CSID . . . . . . . . . . . . . . . . 75
Acknowledgements
Contributors . . . . . . . . . . . . . . . . . . . . . . . . . . 77
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 78
1. Introduction
The Segment Routing (SR) architecture [RFC8402] describes two data
plane instantiations of SR: SR over MPLS (SR-MPLS) and SR over IPv6
(SRv6).
SRv6 Network Programming [RFC8986] builds upon the IPv6 Segment
Routing Header (SRH) [RFC8754] to define a framework for constructing
a network program with topological and service segments.
Some SRv6 applications applications, such as strict path traffic engineering engineering, may
require long segment lists. Compressing the encoding of these long
segment lists in the packet header can significantly reduce the
header size. This document specifies new flavors to the SRv6
endpoint behaviors defined in [RFC8986] that enable a compressed
encoding of the SRv6 segment list. This document also specifies new
SRv6 endpoint behaviors to preserve the compression efficiency in
multi-domain environments.
The SRv6 endpoint behaviors defined in this document leverage the
SRv6 data plane defined in [RFC8754] and [RFC8986], and [RFC8986]; the behaviors are
compatible with the SRv6 control plane extensions for IS-IS
[RFC9352], OSPF [RFC9513], and BGP [RFC9252].
This document updates [RFC8754] by allowing a Segment List entry in
the SRH to be either an IPv6 address, as specified in [RFC8754], or a
REPLACE-CSID container in packed format, as specified in Section 4.2.
2. Terminology
This document leverages the terms defined in [RFC8402], [RFC8754],
and [RFC8986], in particular segment, segment list, Segment
Identifier (SID), SID list, SR policy, prefix segment, adjacency
segment, SRH, SR domain, SR source node, SR segment endpoint node,
transit node, SRv6 endpoint behavior, flavor, SID block, locator,
function, and argument. The reader is assumed to be familiar with
this terminology.
This document introduces the following new terms:
*
Locator-Block: The most significant bits of a SID locator that
represent the SRv6 SID block. The Locator-Block is referred to as
"B" in Section 3.1 of [RFC8986].
*
Locator-Node: The least significant bits of a SID locator that
identify the SR segment endpoint node instantiating the SID. The
Locator-Node is referred to as "N" in Section 3.1 of [RFC8986].
*
Compressed-SID (CSID): A compressed encoding of a SID. The CSID
includes the Locator-Node and Function bits of the SID being
compressed. If either constituent of the SID is empty (zero
length), then the same applies to its CSID encoding.
*
CSID container: A 128-bit IPv6 address that functions as a container
holding a list of one or more CSIDs, CSIDs and the Argument (if any) of
the last CSID.
*
CSID sequence: A group of one or more consecutive SID list entries
encoding the common Locator-Block and at least one CSID container.
*
Compressed SID list: A segment list encoding that reduces the packet
header length thanks to one or more CSID sequences. A compressed
SID list also contains zero, one, or more uncompressed SIDs.
*
Global Identifiers Block (GIB): The pool of CSID values available
for global allocation.
*
Local Identifiers Block (LIB): The pool of CSID values available for
local allocation.
In this document, the length of each constituent part of a SID is
referred to as follows. follows:
* LBL is the Locator-Block length of the SID.
* LNL is the Locator-Node length of the SID.
* FL is the Function length of the SID.
* AL is the Argument length of the SID.
In addition, the Locator-Node and Function length (LNFL) is the sum
of the Locator-Node length and the Function length of the SID. It is
also referred to as the CSID length. "CSID length".
2.1. Requirements Language
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in
BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all
capitals, as shown here.
3. Basic Concepts
In an SR domain, all SRv6 SIDs instantiated from the same Locator-
Block share the same most significant bits. In addition, when the
combined length of the SRv6 SID Locator, Function, and Argument is
smaller than 128 bits, the least significant bits of the SID are
padded with zeros. The compressed segment list encoding seeks to
decrease the packet header length by avoiding the repetition of the
same Locator-Block and reducing the use of padding bits.
Building upon upon, and fully compatible with with, the mechanisms specified in
[RFC8754] and [RFC8986], the compressed segment list encoding
leverages a SID list compression logic at the SR source node (see
Section 6) in combination with new flavors of the SRv6 endpoint
behaviors that process the compressed SID list (see Section 4).
An SR source node constructs and compresses the SID list depending on
the SIDs instantiated on each SR segment endpoint node that the
packet is intended to traverse, as well as its own compression
capabilities. The resulting compressed SID list is a combination of
CSID sequences, for the SIDs that the SR source node was able to
compress, and uncompressed SIDs, which could not be compressed. In
case the SR source node is able to compress all the SIDs in the SID
list, the compressed SID list comprises only CSID sequences (one or
more),
more) and no uncompressed SIDs. Conversely, the compressed SID list
comprises only uncompressed SIDs when the SR source is unable to
compress any of the constituent SIDs.
4. SR Segment Endpoint Flavors
This section defines two SR segment endpoint flavors, flavors: NEXT-CSID and
REPLACE-CSID, for the End, End.X, End.T, End.B6.Encaps,
End.B6.Encaps.Red, and End.BM behaviors of [RFC8986].
This section also defines a REPLACE-CSID flavor for the End.DX6,
End.DX4, End.DT6, End.DT4, End.DT46, End.DX2, End.DX2V, End.DT2U, and
End.DT2M behaviors of [RFC8986]. A counterpart NEXT-CSID flavor is
not defined for these behaviors: since any behaviors. Any SID can be the last element of
a CSID sequence compressed using the NEXT-CSID flavor (see
Section 4.1) and the aforementioned SRv6 endpoint behaviors are
always in the last position in a SID list, list; thus, there is no need for
any modification of the behaviors defined in [RFC8986].
Future documents may extend the applicability of the NEXT-CSID and
REPLACE-CSID flavors to other SRv6 endpoint behaviors (see
Section 11). 10).
The use of these flavors, either individually or in combination,
enables the compressed segment list encoding.
The NEXT-CSID flavor and the REPLACE-CSID flavor both leverage the
SID Argument to determine the next SID to be processed, but employ
different SID list compression schemes. With the NEXT-CSID flavor,
each CSID container is a fully formed SRv6 SID with the common
Locator-Block for all the CSIDs in the CSID container, a Locator-Node Locator-
Node, and Function that are those of the first CSID, and an Argument
carrying the subsequent CSIDs. With the REPLACE-CSID flavor, only
the first element in a CSID sequence is a fully formed SRv6 SID. It
has the common Locator-Block for all the CSIDs in the CSID sequence,
and a Locator-Node and Function that are those of the first CSID.
The remaining elements in the CSID sequence are CSID containers
carrying the subsequent CSIDs without the Locator-Block.
Regardless of which flavor is used, the IPv6 address carried in the
Destination Address field of the IPv6 header is a valid SRv6 SID
conforming to [RFC9602].
In the remainder of this document, the term "a SID of this document"
refers to any End, End.X, End.T, End.B6.Encaps, End.B6.Encaps.Red, or
End.BM SID with the NEXT-CSID or the REPLACE-CSID flavor, flavor and with any
combination of Penultimate Segment Pop (PSP), Ultimate Segment Pop
(USP), and Ultimate Segment Decapsulation (USD) flavor, or any
End.DX6, End.DX4, End.DT6, End.DT4, End.DT46, End.DX2, End.DX2V,
End.DT2U, or End.DT2M with the REPLACE-CSID flavor. All the SRv6
endpoint behaviors introduced in this document are listed in Table 1
at the end of the document. 1.
In the remainder of this document, the terms "NEXT-CSID flavor SID"
and "REPLACE-CSID flavor SID" refer to any SID of this document with
the NEXT-CSID flavor and with the REPLACE-CSID flavor, respectively.
4.1. NEXT-CSID Flavor
A CSID sequence compressed using the mechanism of the NEXT-CSID
flavor comprises one or more CSID containers. Each CSID container is
a fully formed 128-bit SID structured as shown in Figure 1. It
carries a Locator-Block followed by a series of CSIDs. The Locator-
Node and Function of the CSID container are those of the first CSID,
and its Argument is the contiguous series of subsequent CSIDs. The
second CSID is encoded in the most significant bits of the CSID
container Argument, the Argument. The third CSID is encoded in the bits of the
Argument that immediately follow the second CSID, and so on. When
all CSIDs have the same length, a CSID container can carry up to K
CSIDs, where K is computed as floor((128-LBL)/LNFL) (floor(x) is the
greatest integer less than or equal to x [GKP94]). Each CSID
container for NEXT-CSID is independent, such that contiguous CSID
containers in a CSID sequence can be considered as to be separate CSID
sequences.
When a CSID sequence compressed using the NEXT-CSID flavor comprises
at least two CSIDs, the last CSID in the sequence is not required to
have the NEXT-CSID flavor. It can be bound to any SRv6 endpoint
behavior, including [RFC8986] behaviors and REPLACE-CSID flavor, as
long as the updated destination address resulting from the processing
of the previous CSID in the sequence is a valid form for that last
SID. Line S12 of the first pseudocode in Section 6.2 provides
sufficient conditions to ensure this property.
+------------------------------------------------------------------+
| Locator-Block |Loc-Node| Argument |
| |Function| |
+------------------------------------------------------------------+
<----------------------> <------> <------------------------------>
LBL LNFL AL
Figure 1: Structure of a NEXT-CSID flavor Flavor SID (scaled (Scaled for a
48-bit
48-Bit Locator- Block, 16-bit combined 16-Bit Combined Locator-Node and Function,
and 64-bit 64-Bit Argument)
Figure 2 illustrates a compressed SID list as could be produced by an
SR source node steering a packet into an SR policy with a SID list of
eight NEXT-CSID flavor SIDs. All SIDs in this example have a 48-bit
Locator-Block, 16-bit combined Locator-Node and Function, and 64-bit
Argument. The SR source node compresses the SR policy SID list as a
compressed SID list of two CSID containers. The first CSID container
carries a Locator-Block and the first five CSIDs. The second CSID
container carries a Locator-Block and the sixth, seventh, and eighth
CSIDs. Since the SR source node does not use the second CSID
container at full capacity, it sets the 32 least significant bits to
zero. The SR source node sets the IPv6 Destination Address (DA) with
the value of the first CSID container and the first element of the
SRH Segment List with the value of the second CSID container.
Without reduced SRH (Section (see Section 4.1.1 of [RFC8754]), the SR source
node also writes the first CSID container as the second element of
the SRH Segment List.
Note that the CSIDs within a given CSID container appear in forward
order to leverage the longest-prefix match IP forwarding, while the
entries in the SRH Segment List appear in reversed order of their
processing, as specified in Section 4.1 of [RFC8754].
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ Locator-Block +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | 1st CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 2nd CSID | 3rd CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 4th CSID | 5th CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
First CSID container Container
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ Locator-Block +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | 6th CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 7th CSID | 8th CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 0 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Second CSID container Container
Figure 2: Compressed SID list List of eight Eight NEXT-CSID flavor Flavor SIDs with
a 48-bit 48-Bit Locator-Block, 16-bit combined 16-Bit Combined Locator-Node and
Function, and 64-bit 64-Bit Argument
An implementation MUST support a 32-bit Locator-Block length (LBL)
and a 16-bit CSID length (LNFL) for NEXT-CSID flavor SIDs, and it MAY
support any additional Locator-Block and CSID length.
The Argument length (AL) for NEXT-CSID flavor SIDs is equal to 128-
LBL-LNFL.
When processing an IPv6 packet that matches a Forwarding Information
Base (FIB) entry locally instantiated as a SID with the NEXT-CSID
flavor, the SR segment endpoint node applies the procedure specified
in the following subsection that corresponds to the SID behavior. If
the SID also has the PSP, USP, or USD flavor, the procedure is
modified as described in Section 4.1.7.
An SR segment endpoint node instantiating a SID of this document with
the NEXT-CSID flavor MUST accept any Argument value for that SID.
At a high level, for any SID with the NEXT-CSID flavor, the SR
segment endpoint node determines the next SID of the SID list as
follows. If the Argument value of the active SID is non-zero, the SR
segment endpoint node constructs the next SID from the active SID by
copying the entire SID Argument value to the bits that immediately
follow the Locator-Block, thus overwriting the active SID Locator-
Node and Function with those of the next CSID, and filling the least
significant LNFL bits of the Argument with zeros. Otherwise (if the
Argument value is 0), the SR segment endpoint node copies the next
128-bit Segment List entry from the SRH to the Destination Address
field of the IPv6 header.
4.1.1. End with NEXT-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End SID with the NEXT-CSID flavor, the procedure
described in Section 4.1 of [RFC8986] is executed with the following
modifications.
The below pseudocode is inserted between lines S01 and S02 of the SRH
processing in Section 4.1 of [RFC8986]. In addition, this pseudocode
is executed before processing any extension header that is not an
SRH, a Hop-by-Hop header or a Destination Options header, or before
processing the upper-layer header, whichever comes first.
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
N09. }
| Notes:
|
| * DA.Argument identifies the value contained in the bits
| [(LBL+LNFL)..127] in the Destination Address of the IPv6
| header.
|
| * The value in the Segments Left field of the SRH is not
| modified when DA.Argument in the received packet has a
| non-zero value.
A rendering of the complete pseudocode is provided in Appendix A.1.
4.1.2. End.X with NEXT-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.X SID with the NEXT-CSID flavor, the procedure
described in Section 4.2 of [RFC8986] is executed with the following
modifications.
The pseudocode in Section 4.1.1 of this document is modified by
replacing line N08 as shown below.
N08. Submit the packet to the IPv6 module for transmission to the
new destination via a member of J.
| Note: the variable J is defined in Section 4.2 of [RFC8986].
The resulting pseudocode is inserted between lines S01 and S02 of the
SRH processing in Section 4.1 of [RFC8986] after applying the
modification described in Section 4.2 of [RFC8986]. In addition,
this pseudocode is executed before processing any extension header
that is not an SRH, a Hop-by-Hop header or a Destination Options
header, or before processing the upper-layer header, whichever comes
first.
A rendering of the complete pseudocode is provided in Appendix A.2.
4.1.3. End.T with NEXT-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.T SID with the NEXT-CSID flavor, the procedure
described in Section 4.3 of [RFC8986] is executed with the following
modifications.
The pseudocode in Section 4.1.1 of this document is modified by
replacing line N08 as shown below.
N08.1. Set the packet's associated FIB table to T.
N08.2. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
| Note: the variable T is defined in Section 4.3 of [RFC8986].
The resulting pseudocode is inserted between lines S01 and S02 of the
SRH processing in Section 4.1 of [RFC8986] after applying the
modification described in Section 4.3 of [RFC8986]. In addition,
this pseudocode is executed before processing any extension header
that is not an SRH, a Hop-by-Hop header or a Destination Options
header, or before processing the upper-layer header, whichever comes
first.
A rendering of the complete pseudocode is provided in Appendix A.3.
4.1.4. End.B6.Encaps with NEXT-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.B6.Encaps SID with the NEXT-CSID flavor, the
procedure described in Section 4.13 of [RFC8986] is executed with the
following modifications.
The pseudocode in Section 4.1.1 of this document is modified by
replacing line N08 as shown below.
N08.1. Push a new IPv6 header with its own SRH containing B.
N08.2. Set the outer IPv6 SA to A.
N08.3. Set the outer IPv6 DA to the first SID of B.
N08.4. Set the outer Payload Length, Traffic Class, Flow Label,
Hop Limit, and Next Header fields.
N08.5. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
| Note: the variables A and B, as well as the values of the
| Payload Length, Traffic Class, Flow Label, Hop Limit, and Next
| Header are defined in Section 4.13 of [RFC8986].
The resulting pseudocode is inserted between lines S01 and S02 of the
SRH processing in Section 4.13 of [RFC8986]. In addition, this
pseudocode is executed before processing any extension header that is
not an SRH, a Hop-by-Hop header or a Destination Options header, or
before processing the upper-layer header, whichever comes first.
A rendering of the complete pseudocode is provided in Appendix A.4.
Similar to the base End.B6.Encaps SID defined in Section 4.13 of
[RFC8986], the NEXT-CSID flavor variant updates the Destination
Address field of the inner IPv6 header to the next SID in the
original segment list before encapsulating the packet with the
segment list of SR Policy B. At the endpoint of SR Policy B, the
encapsulation is removed and the inner packet is forwarded towards
the exposed destination address, which already contains the next SID
in the original segment list.
4.1.5. End.B6.Encaps.Red with NEXT-CSID
This is an optimization of the End.B6.Encaps with NEXT-CSID behavior.
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.B6.Encaps.Red SID with the NEXT-CSID flavor,
the procedure described in Section 4.1.4 of this document is executed
with the modifications in Section 4.14 of [RFC8986].
4.1.6. End.BM with NEXT-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.BM SID with the NEXT-CSID flavor, the
procedure described in Section 4.15 of [RFC8986] is executed with the
following modifications.
The pseudocode in Section 4.1.1 of this document is modified by
replacing line N08 as shown below.
N08.1. Push the MPLS label stack for B.
N08.2. Submit the packet to the MPLS engine for transmission.
| Note: the variable B is defined in Section 4.15 of [RFC8986].
The resulting pseudocode is inserted between lines S01 and S02 of the
SRH processing in Section 4.15 of [RFC8986]. In addition, this
pseudocode is executed before processing any extension header that is
not an SRH, a Hop-by-Hop header or a Destination Options header, or
before processing the upper-layer header, whichever comes first.
A rendering of the complete pseudocode is provided in Appendix A.5.
4.1.7. Combination with PSP, USP USP, and USD flavors Flavors
PSP: The PSP flavor defined in Section 4.16.1 of [RFC8986] is
unchanged when combined with the NEXT-CSID flavor.
USP: The USP flavor defined in Section 4.16.2 of [RFC8986] is
unchanged when combined with the NEXT-CSID flavor.
USD: The USP flavor defined in Section 4.16.3 of [RFC8986] is
unchanged when combined with the NEXT-CSID flavor.
4.2. REPLACE-CSID Flavor
A CSID sequence compressed using the mechanism of the REPLACE-CSID
flavor starts with a CSID container in fully formed 128-bit SID
format. The Locator-Block of this SID is the common Locator-Block
for all the CSIDs in the CSID sequence, its Locator-Node and Function
are those of the first CSID, and its Argument carries the index of
the current CSID in the current CSID container. The Argument value
is initially 0. When more segments are present in the segment list,
the CSID sequence continues with one or more CSID containers in
packed format carrying the series of subsequent CSIDs. Each
container in packed format is a 128-bit Segment List entry split into
K "positions" of LNFL bits, where K is computed as floor(128/LNFL).
If LNFL does not divide into 128 perfectly, a zero pad is added in
the least significant bits of the CSID container to fill the bits
left over. The second CSID in the CSID sequence is encoded in the
least significant bit position of the first CSID container in packed
format (position K-1), the third CSID is encoded in position K-2, and
so on.
The last CSID in the CSID sequence is not required to have the
REPLACE-CSID flavor. It can be bound to any SRv6 endpoint behavior,
including [RFC8986] the behaviors described in [RFC8986] and NEXT-CSID flavor,
as long as it meets the conditions defined in Section 6.
The structure of a SID with the REPLACE-CSID flavor is shown in
Figure 3. The same structure is also that of the CSID container for
REPLACE-CSID in fully formed 128-bit SID format.
+-------------------------------------------------------------------+
| Locator-Block | Locator-Node | Argument |
| | + Function | |
+-------------------------------------------------------------------+
<----------------------> <--------------> <----------------------->
LBL LNFL AL
Figure 3: Structure of a REPLACE-CSID flavor Flavor SID (scaled (Scaled for a
48-bit
48-Bit Locator- Block, 32-bit combined 32-Bit Combined Locator-Node and Function,
and 48-bit 48-Bit Argument)
The structure of a CSID container for REPLACE-CSID in packed format
is shown in Figure 4.
+-------------------------------------------------------------------+
| Fourth CSID | Third CSID | Second CSID | First CSID |
| (position 0) | (position 1) | (position 2) | (position 3) |
+-------------------------------------------------------------------+
<--------------> <--------------> <--------------> <-------------->
LNFL LNFL LNFL LNFL
Figure 4: Structure of a CSID container Container for REPLACE-CSID using Using a
32-bit
32-Bit CSID length Length (K = 4)
Figure 5 illustrates a compressed SID list as could be produced by an
SR source node steering a packet into an SR policy SID list of seven
REPLACE-CSID flavor SIDs. All SIDs in this example have a 48-bit
Locator-Block, 32-bit combined Locator-Node and Function, and 48-bit
Argument. The SR source node compresses the SR policy SID list as a
compressed SID list of three CSID containers. The first CSID
container is in fully formed 128-bit SID format. It carries a
Locator-Block, the first CSID, and the argument value zero. The
second and third CSID containers are in packed format. The second
CSID container carries the second, third, fourth, and fifth CSIDs.
The third CSID container carries the sixth and seventh CSIDs. Since
the SR source node does not use the third CSID container at full
capacity, it sets the 64 least significant bits to zero. The SR
source node sets the IPv6 DA with the value of the first CSID
container, sets the first element in the SRH Segment List with the
value of the third CSID container, and sets the second element of the
SRH Segment List with the value of the second CSID container (the
elements in the SRH Segment List appear in reversed order of their
processing, as specified in Section 4.1 of [RFC8754]). Without
reduced SRH, the SR source node also writes the first CSID container
as the third element of the SRH Segment List.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ Locator-Block +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | 1st CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 1st CSID continued | |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ 0 +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
First CSID container Container
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 5th CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 4th CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 3rd CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 2nd CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Second CSID container Container
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ 0 +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 7th CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 6th CSID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Third CSID container Container
Figure 5: Compressed SID list List of seven Seven REPLACE-CSID flavor Flavor SIDs
with a 48-bit 48-Bit Locator-Block, 32-bit combined 32-Bit Combined Locator-Node and
Function, and 48-bit 48-Bit Argument
This document updates [RFC8754] by allowing each entry in the SRH
Segment List to be either an IPv6 address or a REPLACE-CSID container
in packed format. The SRv6 endpoint behaviors specified herein
ensure that this entry is never copied as is to the IPv6 header and
that the Destination Address field of the IPv6 header is always a
valid SRv6 SID conforming to [RFC9602].
The REPLACE-CSID flavor SIDs support any Locator-Block length (LBL),
depending on the needs of the operator, as long as it does not exceed
128-LNFL-ceiling(log_2(128/LNFL)) (ceiling(x) is the least integer
greater than or equal to x [GKP94]), so that enough bits remain
available for the CSID and Argument. A Locator-Block length of 48,
56, 64, 72, or 80 bits is recommended for easier reading in
operation.
This document defines the REPLACE-CSID flavor for 16-bit and 32-bit
CSID lengths (LNFL). An implementation MUST support a 32-bit CSID
length for REPLACE-CSID flavor SIDs.
The Argument length (AL) for REPLACE-CSID flavor SIDs is equal to
128-LBL-LNFL. The index value is encoded in the least significant X
bits of the Argument, where X is computed as ceiling(log_2(128/
LNFL)).
When processing an IPv6 packet that matches a FIB entry locally
instantiated as a SID with the REPLACE-CSID flavor, the SR segment
endpoint node applies the procedure specified in the following
subsection that corresponds to the SID behavior. If the SID also has
the PSP, USP, or USD flavor, the procedure is modified as described
in Section 4.2.8.
At a high level, at the start of a CSID sequence using the REPLACE-
CSID flavor, the first CSID container in fully formed 128-bit SID
format is copied to the Destination Address of the IPv6 header.
Then, for any SID with the REPLACE-CSID flavor, the SR segment
endpoint node determines the next SID of the SID list as follows.
When an SRH is present, the SR segment endpoint node decrements the
index value in the Argument of the active SID if the index value is
not 0 or, if it is 0, decrements the Segments Left value in the SRH
and sets the index value in the Argument of the active SID to K-1.
The updated index value indicates the position of the next CSID
within the CSID container in packed format at the "Segment List"
index "Segments Left" in the SRH. The SR segment endpoint node then
constructs the next SID by copying this next CSID to the bits that
immediately follow the Locator-Block in the Destination Address field
of the IPv6 header, thus overwriting the active SID Locator-Node and
Function with those of the next CSID. If no SRH is present, the SR
segment endpoint node ignores the index value in the SID Argument
(except End.DT2M, see Section 4.2.7) and processes the upper-layer
header as per [RFC8986]. The CSID sequence ends with a last CSID in
the last CSID container that does not have the REPLACE-CSID flavor,
or with the special CSID value 0, or when reaching the end of the
segment list, whichever comes first.
4.2.1. End with REPLACE-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End SID with the REPLACE-CSID flavor, the SRH
processing described in Section 4.1 of [RFC8986] is executed with the
following modifications.
Line S02 of SRH processing in Section 4.1 of [RFC8986] is replaced as
follows.
S02. If (Segments Left == 0 and (DA.Arg.Index == 0 or
Segment List[0][DA.Arg.Index-1] == 0)) {
Lines S09 to S15 are replaced by the following pseudo code.
R01. If (DA.Arg.Index != 0) {
R02. If ((Last Entry > max_LE) or (Segments Left > Last Entry)) {
R03. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R04. }
R05. Decrement DA.Arg.Index by 1.
R06. If (Segment List[Segments Left][DA.Arg.Index] == 0) {
R07. Decrement Segments Left by 1.
R08. Decrement IPv6 Hop Limit by 1.
R09. Update IPv6 DA with Segment List[Segments Left]
R10. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
R11. }
R12. } Else {
R13. If((Last Entry > max_LE) or (Segments Left > Last Entry+1)){
R14. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R15. }
R16. Decrement Segments Left by 1.
R17. Set DA.Arg.Index to (floor(128/LNFL) - 1).
R18. }
R19. Decrement IPv6 Hop Limit by 1.
R20. Write Segment List[Segments Left][DA.Arg.Index] into the bits
[LBL..LBL+LNFL-1] of the Destination Address of the IPv6
header.
R21. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
| Notes:
|
| * DA.Arg.Index identifies the value contained in the bits
| [(128-ceiling(log_2(128/LNFL)))..127] in the Destination
| Address of the IPv6 header.
|
| * Segment List[Segments Left][DA.Arg.Index] identifies the
| value contained in the bits
| [DA.Arg.Index*LNFL..(DA.Arg.Index+1)*LNFL-1] in the SRH
| Segment List entry at index Segments Left.
The upper-layer header processing described in Section 4.1.1 of
[RFC8986] is unchanged.
A rendering of the complete pseudocode is provided in Appendix A.6.
4.2.2. End.X with REPLACE-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.X SID with the REPLACE-CSID flavor, the
procedure described in Section 4.2 of [RFC8986] is executed with the
following modifications.
The pseudocode in Section 4.2.1 of this document is modified by
replacing lines R10 and R21 as shown below.
R10. Submit the packet to the IPv6 module for transmission to the
new destination via a member of J.
R21. Submit the packet to the IPv6 module for transmission to the
new destination via a member of J.
| Note: the variable J is defined in Section 4.2 of [RFC8986].
The SRH processing in Section 4.2 of [RFC8986] is replaced with the
resulting pseudocode. The upper-layer header processing is
unchanged.
A rendering of the complete pseudocode is provided in Appendix A.7.
4.2.3. End.T with REPLACE-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.T SID with the REPLACE-CSID flavor, the
procedure described in Section 4.3 of [RFC8986] is executed with the
following modifications.
The pseudocode in Section 4.2.1 of this document is modified by
replacing lines R10 and R21 as shown below.
R10.1. Set the packet's associated FIB table to T.
R10.2. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
R21.1. Set the packet's associated FIB table to T.
R21.2. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
| Note: the variable T is defined in Section 4.3 of [RFC8986].
The SRH processing in Section 4.3 of [RFC8986] is replaced with the
resulting pseudocode. The upper-layer header processing is
unchanged.
A rendering of the complete pseudocode is provided in Appendix A.8.
4.2.4. End.B6.Encaps with REPLACE-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.B6.Encaps SID with the REPLACE-CSID flavor,
the procedure described in Section 4.13 of [RFC8986] is executed with
the following modifications.
The pseudocode in Section 4.2.1 of this document is modified by
replacing lines R10 and R21 as shown below.
R10.1. Push a new IPv6 header with its own SRH containing B.
R10.2. Set the outer IPv6 SA to A.
R10.3. Set the outer IPv6 DA to the first SID of B.
R10.4. Set the outer Payload Length, Traffic Class, Flow Label,
Hop Limit, and Next Header fields.
R10.5. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
R21.1. Push a new IPv6 header with its own SRH containing B.
R21.2. Set the outer IPv6 SA to A.
R21.3. Set the outer IPv6 DA to the first SID of B.
R21.4. Set the outer Payload Length, Traffic Class, Flow Label,
Hop Limit, and Next Header fields.
R21.5. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
| Note: the variables A and B, as well as the values of the
| Payload Length, Traffic Class, Flow Label, Hop Limit, and Next
| Header are defined in Section 4.13 of [RFC8986].
The SRH processing in Section 4.13 of [RFC8986] is replaced with the
resulting pseudocode. The upper-layer header processing is
unchanged.
A rendering of the complete pseudocode is provided in Appendix A.9.
4.2.5. End.B6.Encaps.Red with REPLACE-CSID
This is an optimization of the End.B6.Encaps with REPLACE-CSID
behavior.
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.B6.Encaps.Red SID with the REPLACE-CSID
flavor, the procedure described in Section 4.2.4 of this document is
executed with the modifications in Section 4.14 of [RFC8986].
4.2.6. End.BM with REPLACE-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.BM SID with the REPLACE-CSID flavor, the
procedure described in Section 4.15 of [RFC8986] is executed with the
following modifications.
The pseudocode in Section 4.2.1 of this document is modified by
replacing lines R10 and R21 as shown below.
R10.1. Push the MPLS label stack for B.
R10.2. Submit the packet to the MPLS engine for transmission.
R21.1. Push the MPLS label stack for B.
R21.2. Submit the packet to the MPLS engine for transmission.
| Note: the variable B is defined in Section 4.15 of [RFC8986].
The SRH processing in Section 4.15 of [RFC8986] is replaced with the
resulting pseudocode. The upper-layer header processing is
unchanged.
A rendering of the complete pseudocode is provided in Appendix A.10.
4.2.7. End.DX and End.DT with REPLACE-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.DX6, End.DX4, End.DT6, End.DT4, End.DT46,
End.DX2, End.DX2V, or End.DT2U SID with the REPLACE-CSID flavor, the
corresponding procedure described in Sections 4.4 through 4.11 of
[RFC8986] is executed.
These SIDs differ from those defined in [RFC8986] by the presence of
an Argument as part of the SID structure. The Argument value is
ignored by the SR segment endpoint node.
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.DT2M SID with the REPLACE-CSID flavor, the
procedure described in Section 4.12 of [RFC8986] is executed with the
following modification.
For any End.DT2M SID with the REPLACE-CSID flavor, the value of
Arg.FE2 is 16-bit 16 bits long. The SR segment endpoint node obtains the
value Arg.FE2 from the 16 most significant bits of DA.Argument if
DA.Arg.Index is zero, zero or from the 16 least significant bits of the
next position in the current CSID container (Segment List[Segments
Left][DA.Arg.Index-1]) otherwise (DA.Arg.Index is non-zero).
4.2.8. Combination with PSP, USP, and USD flavors Flavors
PSP: When combined with the REPLACE-CSID flavor, the additional PSP
flavor instructions defined in Section 4.16.1.2 of [RFC8986] are
inserted after lines R09 and R20 of the pseudocode in Section 4.2.1,
and the first line of the inserted instructions after R20 is modified
as follows.
R20.1. If (Segments Left == 0 and (DA.Arg.Index == 0 or
Segment List[0][DA.Arg.Index-1] == 0)) {
| Note: Segment List[Segments Left][DA.Arg.Index-1] identifies
| the value contained in the bits [(DA.Arg.Index-
| 1)*LNFL..DA.Arg.Index*LNFL-1] in the SRH Segment List entry at
| index Segments Left.
USP: When combined with the REPLACE-CSID flavor, the line S03 of the
pseudocode in Section 4.2.1 are substituted by the USP flavor
instructions S03.1 to S03.4 defined in Section 4.16.2 of
[RFC8986]. Note that S03 is shown in the complete pseudocode in
Appendix A.6.
USD: The USD flavor defined in Section 4.16.3 of [RFC8986] is
unchanged when combined with the REPLACE-CSID flavor.
5. CSID Allocation
The CSID value of 0 is reserved. It is used to indicate the end of a
CSID container.
In order to efficiently manage the CSID numbering space, a deployment
may divide it into two non-overlapping sub-spaces: a Global
Identifiers Block (GIB) and a Local Identifiers Block (LIB).
The CSID values that are allocated from the GIB have a global
semantic within the Locator-Block, while those that are allocated
from the LIB have a local semantic on an SR segment endpoint node and
within the scope of the Locator-Block.
The concept of LIB is applicable to SRv6 and specifically to its
NEXT-CSID and REPLACE-CSID flavors. The shorter the CSID, the more
benefit the LIB brings.
The opportunity to use these sub-spaces, their size, and their CSID
allocation policy depends on the CSID length relative to the size of
the network (e.g., number of nodes, links, service routes). Some
guidelines for a typical deployment scenario are provided in the
below subsections.
5.1. Global CSID
A global CSID is a CSID allocated from the GIB.
A global CSID identifies a segment defined at the Locator-Block
level. The tuple (Locator-Block, CSID) identifies the same segment
across all nodes of the SR domain. A typical example is a prefix
segment bound to the End behavior.
A node can have multiple global CSIDs under the same Locator-Block
(e.g., one per IGP flexible algorithm ([RFC9350])). Multiple nodes
may share the same global CSID (e.g., anycast [RFC4786]).
5.2. Local CSID
A local CSID is a CSID allocated from the LIB.
A local CSID identifies a segment defined at the node level and
within the scope of a particular Locator-Block. The tuple (Locator-
Block, CSID) identifies a different segment on each node of the SR
domain. A typical example is a non-routed Adjacency segment bound to
the End.X behavior.
Let N1 and N2 be two different physical nodes of the SR domain and I
a local CSID value, value: N1 may allocate value I to SID S1 and N2 may
allocate the same value I to SID S2.
5.3. Recommended Installation of CSIDs in FIB
Section 4.3 of [RFC8754] defines how an SR segment endpoint node
identifies a locally instantiated SRv6 SID. To ensure that any valid
argument value is accepted, an SR segment endpoint node instantiating
a NEXT-CSID or REPLACE-CSID flavor SID should install a corresponding
FIB entry that matches only the Locator and Function parts of the SID
(i.e., with a prefix length of LBL + LNL + FL).
In addition, an SR segment endpoint node instantiating NEXT-CSID
flavor SIDs from both the GIB and LIB may install combined "Global +
Local" FIB entries to match a sequence of global and local CSIDs in a
single longest prefix longest-prefix match (LPM) lookup.
For example, let us consider an SR segment endpoint node 10
instantiating the following two NEXT-CSID flavor SIDs according to
the CSID length, Locator-Block length, and GIB/LIB recommendations in
this section.
* The SID 2001:db8:b1:10:: bound to the End behavior with the NEXT-
CSID flavor is instantiated from GIB with with:
- Locator-Block length (LBL) = 48 (Locator-Block value
0x20010db800b1),
- Locator-Node length (LNL) = 16 (Locator-Node value 0x0010),
- Function length (FL) = 0, and
- Argument length (AL) = 64.
* The SID 2001:db8:b1:f123:: bound to the End.X behavior for its
local IGP adjacency 123 with the NEXT-CSID flavor is instantiated
from LIB with with:
- Locator-Block length (LBL) = 48 (Locator-Block value
0x20010db800b1),
- Locator-Node length (LNL) = 0,
- Function length (FL) = 16 (Function value 0xf123), and
- Argument length (AL) = 64.
For SID 2001:db8:b1:10::, Node 10 would install the FIB entry
2001:db8:b1:10::/64 bound to the End SID with the NEXT-CSID flavor.
For SID 2001:db8:b1:f123::, Node 10 would install the FIB entry
2001:db8:b1:f123::/64 bound to the End.X SID for adjacency 123 with
the NEXT-CSID flavor.
In addition, Node 10 may also install the combined FIB entry
2001:db8:b1:10:f123::/80 bound to the End.X SID for adjacency 123
with the NEXT-CSID flavor.
As another example, let us consider an SR segment endpoint node 20
instantiating the following two REPLACE-CSID flavor SIDs according to
the CSID length, Locator-Block length, and GIB/LIB recommendations in
this section.
* 2001:db8:b2:20:1:: from GIB with Locator-Block length (LBL) = 48,
Locator-Node length (LNL) = 16, Function length (FL) = 16,
Argument length (AL) = 48, and bound to the End behavior with the
REPLACE-CSID flavor.
* 2001:db8:b2:20:123:: from GIB with Locator-Block length (LBL) =
48, Locator-Node length (LNL) = 16, Function length (FL) = 16,
Argument length (AL) = 48, and bound to the End.X behavior for its
local IGP adjacency 123 with the REPLACE-CSID flavor.
For SID 2001:db8:b2:20:1::, Node 20 would install the FIB entry
2001:db8:b2:20:1::/80 bound to the End SID with the REPLACE-CSID
flavor.
For SID 2001:db8:b2:20:123::, Node 20 would install the FIB entry
2001:db8:b2:20:123::/80 bound to the End.X SID for adjacency 123 with
the REPLACE-CSID flavor.
6. SR Source Node
An SR source node may learn from a control plane protocol (see
Section 8) or local configuration the SIDs that it can use in a
segment list, along with their respective SRv6 endpoint behavior,
structure, and any other relevant attribute (e.g., the set of L3
adjacencies associated with an End.X SID).
6.1. SID Validation for Compression
As part of the compression process or as a preliminary step, the SR
source node MUST validate the SID structure of each SID of this
document in the segment list. The SR source node does so regardless
of whether the segment list is explicitly configured, locally
computed, or advertised by a controller (e.g., via BGP
[I-D.ietf-idr-sr-policy-safi] [SR-BGP] or
PCEP [RFC9603]).
A SID structure is valid for compression if it meets all the
following conditions. conditions:
* The Locator-Block length is not 0.
* The sum of the Locator-Node length and Function length is not 0.
* The Argument length is equal to 128-LBL-LNL-FL.
When compressing a SID list, the SR source node MUST treat an invalid
SID structure as unknown. A SID with an unknown SID structure is
incompressible. not
compressible.
Section 8 discusses how the SIDs of this document and their structure
can be advertised to the SR source node through various control plane
protocols. The SID structure may also be learned through
configuration or other management protocols. The details of such
mechanisms are outside the scope of this document.
6.2. Segment List Compression
An SR source node MAY compress a SID list when it includes NEXT-CSID
and/or REPLACE-CSID flavor SIDs to reduce the packet header length.
It is out of the scope of this document to describe the mechanism
through which an uncompressed SID list is derived, since such a
mechanism may include a wide range of considerations independent of
compression (e.g., minimizing a specific metric, excluding certain
links, or providing a loop-free fast-reroute path). As a general
guidance for implementation or future specification, such a mechanism
should aim to select the combination of SIDs that would result in the
shortest compressed SID list. For example, by selecting a CSID
flavor SID over an equivalent non-CSID flavor SID or by consistently
selecting SIDs of the same CSID flavor within each routing domain.
The SID list that the SR source node pushes onto the packet MUST
comply with the rules in Section Sections 6.3 and Section 6.4 and express the same
list of segments as the original SID list. If these rules are not
followed, the packet may get dropped or misrouted.
If an SR source node chooses to compress the SID list, one method is
described below for illustrative purposes. Any other method
producing a compressed SID list of equal or shorter length than the
uncompressed SID list MAY be used.
This method walks the uncompressed SID list and compresses each
series of consecutive NEXT-CSID flavor SIDs and each series of
consecutive REPLACE-CSID flavor SIDs.
* When the compression method encounters a series of one or more
consecutive compressible NEXT-CSID flavor SIDs, it compresses the
series as follows. A SID with the NEXT-CSID flavor is
compressible if its structure is known to the SR source node and
its Argument value is 0.
S01. Initialize a NEXT-CSID container equal to the first SID in the
series,
series and initialize the remaining capacity of the CSID
container to the AL of that SID
S02. For each subsequent SID in the series {
S03. If the current SID Locator-Block matches that of the CSID
container and the current SID LNFL is lower than or equal to
the remaining capacity of the NEXT-CSID container {
S04. Copy the current SID Locator-Node and Function to the most
significant remaining Argument bits of the NEXT-CSID
container and decrement the remaining capacity by LNFL
S05. } Else {
S06. Push the NEXT-CSID container onto the compressed SID list
S07. Initialize a new NEXT-CSID container equal to the current
SID in the series, series and initialize the remaining capacity
of the NEXT-CSID container to the AL of that SID
S08. } // End If
S09. } // End For
S10. If at least one SID remains in the uncompressed SID list
(following the series of compressible NEXT-CSID flavor SIDs){
S11. Set S to the next SID in the uncompressed SID list
S12. If S is advertised with a SID structure, and the Locator-Block
of S matches that of the NEXT-CSID container, and the sum of
the Locator-Node, Function, and Argument length of S is
lower than or equal to the remaining capacity of the CSID
container {
S13. Copy the Locator-Node, Function, and Argument of S to the
most significant remaining Argument bits of the CSID
container
S14. } // End If
S15. } // End If
S16. Push the NEXT-CSID container onto the compressed SID list
* When the compression method encounters a series of REPLACE-CSID
flavor SIDs of the same CSID length in the uncompressed SID list,
it compresses the series as per the following high-level pseudo
code. A compression checking function ComCheck(F, S) is defined
to check if two SIDs F and S share the same SID structure and
Locator-Block value, and if S has either no Argument or an
Argument with value 0. If the check passes, then ComCheck(F,S)
returns true.
S01. Initialize a REPLACE-CSID container in full SID format equal to
the first SID in the series
S02. Push the REPLACE-CSID container onto the compressed SID list
S03. Initialize a new REPLACE-CSID container in packed format if
there are more than one SIDs, SIDs and initialize the remaining
capacity of the REPLACE-CSID container to 128 bits
S04. For each subsequent SID in the uncompressed SID list {
S05. Set S to the current SID in the uncompressed SID list
S06. If ComCheck(First SID, S) {
S07. If the LNFL of S is lower than or equal to
the remaining capacity of the REPLACE-CSID container {
S08. Copy the Locator-Node and Function of S to the least
significant remaining bits of the REPLACE-CSID container
and decrement the remaining capacity by LNFL // Note
S09. } Else {
S10. Push the REPLACE-CSID container onto the compressed SID
list
S11. Initialize a new REPLACE-CSID container in packed format
with all bits set to 0
S12. Copy the Locator-Node and Function of S to the least
significant remaining bits of the REPLACE-CSID container
and decrement the remaining capacity by LNFL // Note
S13. }
S14. If S is not a REPLACE-CSID flavor SID, then break
S15. } Else {
S16. Break
S17. } // End If
S18. } // End For
S19. Push the REPLACE-CSID container (if it is not empty) onto the
compressed SID list
| Note: When the last CSID is an End.DT2M SID with the REPLACE-
| CSID flavor, if there is are 0 or at least two CSID positions left
| in the current REPLACE-CSID container, the CSID is encoded as
| described above and the value of the Arg.FE2 argument is placed
| in the 16 least significant bits of the next CSID position.
| Otherwise (if there is only one CSID position left in the
| current REPLACE-CSID container), the current REPLACE-CSID
| container is pushed onto the SID list (the value of the CSID
| position 0 remains zero) and the End.DT2M SID with the REPLACE-
| CSID flavor is encoded in full SID format with the value of the
| Arg.FE2 argument in the 16 most significant bits of the SID
| Argument.
*
In all remaining cases (i.e., when the compression method encounters
a SID in the uncompressed SID list that is not handled by any of the
previous subroutines), it pushes this SID as is onto the compressed
SID list.
Regardless of how a compressed SID list is produced, the SR source
node writes it in the IPv6 packet as described in Sections 4.1 and
4.1.1 of [RFC8754]. The text is reproduced below for reference.
| A source node steers a packet into an SR Policy. If the SR Policy
| results in a Segment List containing a single segment, and there
| is no need to add information to the SRH flag or add TLV; the DA
| is set to the single Segment List entry, and the SRH MAY be
| omitted.
|
| When needed, the SRH is created as follows:
|
| The Next Header and Hdr Ext Len fields are set as specified in
| [RFC8200].
|
| The Routing Type field is set to 4.
|
| The DA of the packet is set with the value of the first segment.
|
| The first element of the SRH Segment List is the ultimate segment.
| The second element is the penultimate segment, and so on.
|
| The Segments Left field is set to n-1, where n is the number of
| elements in the SR Policy.
|
| The Last Entry field is set to n-1, where n is the number of
| elements in the SR Policy.
|
| TLVs (including HMAC) may be set according to their specification.
|
| The packet is forwarded toward the packet's Destination Address
| (the first segment).
|
| When a source does not require the entire SID list to be preserved
| in the SRH, a reduced SRH may be used.
|
| A reduced SRH does not contain the first segment of the related SR
| Policy (the first segment is the one already in the DA of the IPv6
| header), and the Last Entry field is set to n-2, where n is the
| number of elements in the SR Policy.
6.3. Rules for segment lists containing Segment Lists Containing NEXT-CSID flavor Flavor SIDs
1. If a Destination Options header would follow an SRH with a
segment list of more than one segment compressed as a single
NEXT-CSID container, the SR source node MUST NOT omit the SRH.
2. When the last Segment List entry (index 0) in the SRH is a NEXT-
CSID container representing more than one segment and the segment
S preceding the first segment of this NEXT-CSID container in the
segment list has the PSP flavor, then the PSP operation is
performed at the SR segment endpoint node of S. If the PSP
behavior should instead be performed at the penultimate segment
along the path, then the SR source node MUST NOT compress the
ultimate SID of the SID list into a NEXT-CSID container.
3. If a Destination Options header would follow an SRH with a last
Segment List entry being a NEXT-CSID container representing more
than one segment, the SR source node MUST ensure that the PSP
operation is not performed before the penultimate SR segment
endpoint node along the path.
4. When the Argument of a NEXT-CSID container is not used to full
capacity, the remaining least significant bits of that Argument
MUST be set to 0.
6.4. Rules for segment lists containing Segment Lists Containing REPLACE-CSID flavor Flavor SIDs
1. All SIDs compressed in a REPLACE-CSID sequence MUST share the
same Locator-Block and the same compression scheme.
2. All SIDs except the last one in a CSID sequence for REPLACE-CSID
MUST have the REPLACE-CSID flavor. If the last REPLACE-CSID
container is fully filled (i.e., the last CSID is at position 0
in the REPLACE-CSID container) and the last SID in the CSID
sequence is not the last segment in the segment list, the last
SID in the CSID sequence MUST NOT have the REPLACE-CSID flavor.
3. When a REPLACE-CSID flavor CSID is present as the last SID in a
container that is not the last Segment List entry (index 0) in
the SRH, the next element in the SID list MUST be a REPLACE-CSID
container in packed format carrying at least one CSID.
The SR source node determines the compression scheme of REPLACE-CSID
flavor SIDs as follows.
When receiving a SID advertisement for a REPLACE-CSID flavor SID with
LNL=16, FL=0, AL=128-LBL-LNFL, and all zeros as the value of the Argument is all
0,
Argument, the SR source node marks both the SID and its locator as
using 16-bit compression. All other SIDs allocated from this locator
with LNL=16, FL=16, AL=128-LBL-LNFL, and all zeros as the value of
the Argument is all
0 are also marked as using 16-bit compression. When
receiving a SID advertisement for a REPLACE-CSID flavor SID with
LNFL=32, AL=128-LBL-
LNFL, AL=128-LBL-LNFL, and all zeros as the value of the Argument is all 0, Argument,
the SR source node marks both the SID and its locator as using 32-bit
compression.
6.5. Upper-Layer Checksums
The Destination Address used in the IPv6 pseudo-header (Section 8.1
of [RFC8200]) is that of the ultimate destination.
At the SR source node, that address will be the Destination Address
as it is expected to be received by the ultimate destination. When
the last element in the compressed SID list is a CSID container, this
address can be obtained from the last element in the uncompressed SID
list or by repeatedly applying the segment behavior as described in
Section 9.4. This applies regardless of whether an SRH is present in
the IPv6 packet or is omitted.
At the ultimate destination(s), that address will be in the
Destination Address field of the IPv6 header.
7. Inter-Domain Compression
Some SRv6 traffic may need to cross multiple routing domains, such as
different Autonomous Systems (ASes) or different routing areas within
an SR domain. Different routing domains may use different addressing
schema and Locator-Blocks.
A property of a CSID sequence is that all CSIDs in the sequence share
the same Locator-Block. Therefore, a segment list that spans
multiple routing domains using different Locator-Blocks may need a
separate CSID sequence for each domain.
This section defines a solution to improve the efficiency of CSID
compression in multi-domain environments by enabling a CSID sequence
to combine CSIDs having different Locator-Blocks.
The solution leverages two new SRv6 endpoint behaviors, "Endpoint
with SRv6 Locator-Block Swap" ("End.LBS" for short) and "Endpoint
with L3 cross-connect and SRv6 Locator-Block Swap" ("End.XLBS" for
short), that enable modifying the Locator-Block for the next CSID in
the CSID sequence at the routing domain boundary.
7.1. End.LBS: Locator-Block Swap
The End.LBS behavior is a variant of the End behavior that modifies
the Locator-Block of the active CSID sequence. This document defines
the End.LBS behavior with the NEXT-CSID flavor and the End.LBS
behavior with the REPLACE-CSID flavor.
An End.LBS SID is used to transition to a new Locator-Block when the
routing domain boundary is on the SR segment endpoint node.
Each instance of an End.LBS SID is associated with a target Locator-
Block B2/m, where B2 is an IPv6 address prefix and m is the
associated prefix length. The original and target Locator-Blocks can
have different prefix lengths as long as the new Destination Address
formed by combining the target Locator-Block with the Locator-Node,
Function, and Argument as described in the pseudocodes pseudocode of
Section Sections
7.1.1 and Section 7.1.2 is a valid IPv6 address. The target Locator-Block is
a local property of the End.LBS SID on the SR segment endpoint node.
| Note: a local SID property is an attribute associated with the
| SID when it is instantiated on the SR segment endpoint node.
| When the SR segment endpoint node identifies the destination
| address of a received packet as a locally instantiated SID, it
| also retrieves any local property associated with this SID.
| Other examples of local SID properties include the set of L3
| adjacencies of an End.X SID (Section 4.2 4.1 of [RFC8986]) and the
| lookup table of an End.DT6 SID (Section 4.6 of [RFC8986]).
The means by which an SR source node learns the target Locator-Block
associated with an End.LBS SID are outside the scope of this
document. As examples, it could be learned via configuration or
signaled by a controller.
7.1.1. End.LBS with NEXT-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.LBS SID with the NEXT-CSID flavor and
associated with the target Locator-Block B2/m, the SR segment
endpoint node applies the procedure specified in Section 4.1.1 with
the lines N05 to N06 replaced as follows.
N05.1. Initialize an IPv6 address A equal to B2.
N05.2. Copy DA.Argument into the bits [m..(m+AL-1)] of A.
N06. Copy A to the Destination Address of the IPv6 header.
7.1.2. End.LBS with REPLACE-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.LBS SID with the REPLACE-CSID flavor and
associated with the target Locator-Block B2/m, the SR segment
endpoint node applies the procedure specified in Section 4.2.1 with
the line R20 replaced as follows.
R20.1. Initialize an IPv6 address A equal to B2.
R20.2. Write Segment List[Segments Left][DA.Arg.Index] into the bits
[m..m+LNFL-1] of A.
R20.3. Write DA.Arg.Index into the bits
[(128-ceiling(log_2(128/LNFL)))..127] of A.
R20.4. Copy A to the Destination Address of the IPv6 header.
7.2. End.XLBS: L3 Cross-Connect and Locator-Block Swap
The End.XLBS behavior is a variant of the End.X behavior that
modifies the Locator-Block of the active CSID sequence. This
document defines the End.XLBS behavior with the NEXT-CSID flavor and
the End.XLBS behavior with the REPLACE-CSID flavor.
An End.XLBS SID is used to transition to a new Locator-Block when the
routing domain boundary is on a link adjacent to the SR segment
endpoint node.
Each instance of an End.XLBS SID is associated with a target Locator-
Block B2/m and a set, J, of one or more L3 adjacencies. The original
and target Locator-Blocks can have different prefix lengths as long
as the new Destination Address formed by combining the target
Locator-Block with the Locator-Node, Function, and Argument as
described in the pseudocodes pseudocode of Section Sections 7.2.1 and Section 7.2.2 is a valid
IPv6 address. The target Locator-Block and set of adjacencies are
local properties of the End.XLBS SID on the SR segment endpoint node.
The means by which an SR source node learns the target Locator-Block
associated with an End.XLBS SID are outside the scope of this
document. As examples, it could be learned via configuration or
signaled by a controller.
7.2.1. End.XLBS with NEXT-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.XLBS SID with the NEXT-CSID flavor and
associated with the target Locator-Block B2/m, the SR segment
endpoint node applies the procedure specified in Section 4.1.2 with
the lines N05 to N06 (of the pseudocode in Section 4.1.1) replaced as
follows.
N05.1. Initialize an IPv6 address A equal to B2.
N05.2. Copy DA.Argument into the bits [m..(m+AL-1)] of A.
N06. Copy A to the Destination Address of the IPv6 header.
7.2.2. End.XLBS with REPLACE-CSID
When processing an IPv6 packet that matches a FIB entry locally
instantiated as an End.XLBS SID with the REPLACE-CSID flavor and
associated with the target Locator-Block B2/m, the SR segment
endpoint node applies the procedure specified in Section 4.2.2 with
the line R20 (of the pseudocode in Section 4.2.1) replaced as
follows.
R20.1. Initialize an IPv6 address A equal to B2.
R20.2. Write Segment List[Segments Left][DA.Arg.Index] into the bits
[m..m+LNFL-1] of A.
R20.3. Write DA.Arg.Index into the bits
[(128-ceiling(log_2(128/LNFL)))..127] of A.
R20.4. Copy A to the Destination Address of the IPv6 header.
8. Control Plane
Section 8 of [RFC8986] provides an overview of the control plane
protocols used for signaling of the SRv6 endpoint behaviors
introduced by that document, including the base SRv6 endpoint
behaviors that are extended in the present document.
The CSID-flavored behaviors introduced by this document are
advertised in the same manner as their base SRv6 endpoint behaviors
using the SRv6 extensions for various routing protocols, such as as:
* IS-IS [RFC9352]
* OSPFv3 [RFC9513]
* BGP [RFC9252], [RFC9514], [I-D.ietf-idr-sr-policy-safi] [SR-BGP]
* BGP-LS [I-D.ietf-idr-bgp-ls-sr-policy] [BGP-LS-SR]
* PCEP [RFC9603]
The SR segment endpoint node MUST set the SID Argument bits to 0 when
advertising a locally instantiated SID of this document in the
routing protocol (e.g., IS-IS [RFC9352], OSPF [RFC9513], or BGP-LS
[RFC9514]).
Signaling the SRv6 SID Structure is REQUIRED for all the SIDs
introduced in this document. It is used by an SR source node to
compress a SID list as described in Section 6. The node initiating
the SID advertisement MUST set the length values in the SRv6 SID
Structure to match the format of the SID on the SR segment endpoint
node. For example, for a SID of this document instantiated from a
/48 SRv6 SID block and a /64 Locator, and having a 16-bit Function,
the SRv6 SID Structure advertisement carries the following values.
* Locator-Block length: 48
* Locator-Node length: 16
* Function length: 16
* Argument length: 48 (= 128-48-16-16)
A local CSID may be advertised in the control plane individually and/
or in combination with a global CSID instantiated on the same SR
segment endpoint node, with the End behavior, and the same Locator-
Block and flavor as the local CSID. A combined global and local CSID
is advertised as follows. follows:
* The SID Locator-Block is that shared by the global and local CSIDs
* The SID Locator-Node is that of global CSID
* The SID Function is that of the local CSID
* The SID Argument length is equal to 128-LBL-LNL-FL and the SID
Argument value is 0
* All other attributes of the SID (e.g., SRv6 endpoint behavior or
algorithm) are those of the local CSID
The local CSID combined CSID-combined advertisement is needed in particular for
control plane protocols mandating that the SID is a subnet of a
locator advertised in the same protocol (e.g., Section 8 of [RFC9352]
and Section 9 of [RFC9513] for advertising Adjacency SIDs in IS-IS
and OSPFv3, respectively).
For a segment list computed by a controller and signaled to an SR
source node (e.g., via BGP [I-D.ietf-idr-sr-policy-safi] [SR-BGP] or PCEP [RFC9603]), the
controller provides the ordered segment list comprising the
uncompressed SIDs, with their respective behavior and structure, to
the SR source node. The SR source node may then compress the SID
list as described in Section 6.
When a node that does not support this specification receives an
advertisement of a SID of this document, it handles it as described
in the corresponding control plane specification (e.g., Sections 7.2,
8.1, and 8.2 of [RFC9352], Sections 8, 9.1, and 9.2 of [RFC9513], and
Section 3.1 of [RFC9252]).
9. Operational Considerations
9.1. Flavor, Block, and CSID Length
SRv6 is intended for use in a variety of networks that require
different prefix lengths and SID numbering spaces. Each of the two
flavors introduced in this document comes with its own
recommendations for Locator-Block and CSID length, as specified in
Section
Sections 4.1 and Section 4.2. These flavors are best suited for different
environments, depending on the requirements of the network. For
instance, larger CSID lengths may be more suitable for networks
requiring ample SID numbering space, while smaller CSID lengths are
better for compression efficiency. The two compression flavors allow
the compressed segment list encoding to adapt to a range of
requirements, with support for multiple compression levels. Network
operators can choose the flavor that best suits their use case,
deployment design, and network scale.
Both CSID flavors can coexist in the same SR domain, on the same SR
segment endpoint node, and even in the same segment list. However,
operators should generally avoid instantiating SIDs of different CSID
flavors within the same routing domain or Locator-Block since these
SIDs have different length and allocation recommendations (see
Section
Sections 4.1, Section 4.2, and Section 9.2). In a multi-domain deployment, different
flavors may be used in different routing domains of the SR domain.
A deployment should use consistent Locator-Block lengths and CSID
lengths for all SIDs within a routing domain. Heterogeneous lengths,
while possible, may impact the compression efficiency.
The compressed segment list encoding works with various Locator-Block
allocations. For example, each routing domain within the SR domain
can be allocated a /48 Locator-Block from a global IPv6 block
available to the operator, operator or from a prefix allocated to SRv6 SIDs as
discussed in Section 5 of [RFC9602].
9.2. GIB/LIB Usage
GIB and LIB usage is a local implementation and/or configuration
decision,
decision; however, some guidelines for determining usage for specific
SRv6 endpoint behaviors and recommendations are provided.
The GIB number space is shared among all SR segment endpoint nodes
using SRv6 locators under a Locator-Block space. The more SIDs
assigned from this space, per node, the faster it is exhausted.
Therefore, its use is prioritized for global segments, such as SIDs
that identify a node.
The LIB number space is unique per node. Each node can fully utilize
the entire LIB number space without consideration of for assignments at
other nodes. Therefore, its use is prioritized for local segments,
such as SIDs that identify services (of which there may be many) at
nodes, cross-connects, or adjacencies.
While a longer CSID length permits more flexibility in which SRv6
endpoint behaviors may be assigned from the GIB; GIB, it also reduces the
compression efficiency.
Given the previous Locator-Block and CSID length recommendations, the
following GIB/LIB usage is recommended:
* NEXT-CSID:
- GIB: End
- LIB: End.X, End.T, End.DT4/6/46/2U/2M, End.DX4/6/2/2V
(including large-scale pseudowire), End.B6.Encaps,
End.B6.Encaps.Red, End.BM, End.LBS, and End.XLBS
* REPLACE-CSID:
- GIB: End, End.X, End.T, End.DT4/6/46/2U/2M, End.DX4/6/2/2V,
End.B6.Encaps, End.B6.Encaps.Red, End.BM, End.LBS, and End.XLBS
- LIB: End.DX2/2V for large-scale pseudowire
Any other allocation is possible but may lead to a suboptimal use of
the CSID numbering space.
9.3. Pinging a SID
An SR source node may ping an SRv6 SID by sending an ICMPv6 echo
request packet destined to the SRv6 SID. The SR source node may ping
the target SID with a SID list comprising only that target SID, SID or
with a longer one that comprises two or more SIDs. In that case, the
target SID is the last element in the SID list. This operation is
illustrated in Appendix A.1.2 of [RFC9259].
When pinging a SID of this document document, the SR source node MUST
construct the IPv6 packet as described in Section 6, including
computing the ICMPv6 checksum as described in Section 6.5.
In particular, when pinging a SID of this document with a SID list
comprising only the target SID, the SR source node places the SID
with Argument value 0 in the destination address of the ICMPv6 echo
request and computes the ICMPv6 checksum using this SID as the
destination address in the IPv6 pseudo-header. The Argument value 0
allows the SID SR segment endpoint node (Section 4) to identify
itself as the ultimate destination of the packet and process the
ICMPv6 payload. Therefore, any existing IPv6 ping implementation can
originate ICMP echo requests to a NEXT-CSID or REPLACE-CSID flavor
SID with a SID list comprising only the target SID, provided that the
user ensures that the SID Argument is 0.
9.4. ICMP Error Processing
When an IPv6 node encounters an error while processing a packet, it
may report that error by sending an IPv6 error message to the packet
source with an enclosed copy of the invoking packet. For the source
of an invoking packet to process the ICMP error message, the ultimate
destination address of the IPv6 header may be required.
Section 5.4 of [RFC8754] defines the logic that an SR source node
follows to determine the ultimate destination of an invoking packet
containing an SRH.
For an SR source node that supports the compressed segment list
encoding defined in this document, the logic to determine the
ultimate destination is generalized as follows.
* If the destination address of the invoking IPv6 packet matches a
known SRv6 SID, modify the invoking IPv6 packet by applying the
SRv6 endpoint behavior associated with the matched SRv6 SID;
* Repeat until the application of the SRv6 endpoint behavior would
result in the processing of the upper-layer header.
The destination address of the resulting IPv6 packet may be used as
the ultimate destination of the invoking IPv6 packet.
Since the SR source node that needs to determine the ultimate
destination is the same node that originally built the SID list in
the invoking packet, it can perform this operation for all the SIDs
in the packet.
10. Implementation Status
This section is to be removed before publishing as an RFC.
RFC-Editor: Please clean up the references cited by this section
before publication.
This section records the status of known implementations of the
protocol defined by this specification at the time of posting of this
Internet-Draft, and is based on a proposal described in [RFC7942].
The description of implementations in this section is intended to
assist the IETF in its decision processes in progressing drafts to
RFCs. Please note that the listing of any individual implementation
here does not imply endorsement by the IETF. Furthermore, no effort
has been spent to verify the information presented here that was
supplied by IETF contributors. This is not intended as, and must not
be construed to be, a catalog of available implementations or their
features. Readers are advised to note that other implementations may
exist.
According to [RFC7942], "this will allow reviewers and working groups
to assign due consideration to documents that have the benefit of
running code, which may serve as evidence of valuable experimentation
and feedback that have made the implemented protocols more mature.
It is up to the individual working groups to use this information as
they see fit".
This section is provided in compliance with the SPRING working group
policies ([SPRING-WG-POLICIES]).
10.1. Cisco Systems
Cisco Systems reported the following implementations of the SR
segment endpoint node NEXT-CSID flavor (Section 4.1) and the SR
source node efficient SID list encoding (Section 6) for NEXT-CSID
flavor SIDs. These are used as part of its SRv6 TI-LFA, micro-loop
avoidance, and traffic engineering functionalities.
* Cisco NCS 540 Series routers running IOS XR 7.3.x or above
[IMPL-CISCO-NCS540]
* Cisco NCS 560 Series routers running IOS XR 7.6.x or above
[IMPL-CISCO-NCS560]
* Cisco NCS 5500 Series routers running IOS XR 7.3.x or above
[IMPL-CISCO-NCS5500]
* Cisco NCS 5700 Series routers running IOS XR 7.5.x or above
[IMPL-CISCO-NCS5700]
* Cisco 8000 Series routers running IOS XR 7.5.x or above
[IMPL-CISCO-8000]
* Cisco ASR 9000 Series routers running IOS XR 7.5.x or above
[IMPL-CISCO-ASR9000]
At the time of this report, all the implementations listed above are
in production and follow the specification in the latest version of
this document, including all the "MUST" and "SHOULD" clauses for the
NEXT-CSID flavor.
This report was last updated on January 11, 2023.
10.2. Huawei Technologies
Huawei Technologies reported the following implementations of the SR
segment endpoint node REPLACE-CSID flavor (Section 4.2). These are
used as part of its SRv6 TI-LFA, micro-loop avoidance, and traffic
engineering functionalities.
* Huawei ATN8XX,ATN910C,ATN980B routers running VRPV800R021C00 or
above.
* Huawei CX600-M2 routers running VRPV800R021C00 or above.
* Huawei NE40E,ME60-X1X2,ME60-X3X8X16 routers running VRPV800R021C00
or above.
* Huawei NE5000E,NE9000 routers running VRPV800R021C00 or above.
* Huawei NCE-IP Controller running V1R21C00 or above.
At the time of this report, all the implementations listed above are
in production and follow the specification in the latest version of
this document, including all the "MUST" and "SHOULD" clauses for the
REPLACE-CSID flavor.
This report was last updated on January 11, 2023.
10.3. Nokia
Nokia reported the following implementations ([IMPL-NOKIA-20.10]) of
the SR segment endpoint node NEXT-CSID flavor (Section 4.1). These
are used as part of its shortest path forwarding (in algorithm 0 and
Flex-Algo), remote and TI-LFA repair tunnel, and Traffic Engineering
functionalities.
* Nokia 7950 XRS 20/20e routers running SROS Release 22.10 or above
* Nokia 7750 SR-12e routers running SROS Release 22.10 or above
* Nokia 7750 SR-7/12 routers running SROS Release 22.10 or above
* Nokia 7750 SR-7s/14s routers running SROS Release 22.10 or above
* Nokia 7750 SR-1/1s/2s routers running SROS Release 22.10 or above
At the time of this report, all the implementations listed above are
in production and follow the specification in the latest version of
this document, including all the "MUST" and "SHOULD" clauses for the
NEXT-CSID flavor.
This report was last updated on February 3, 2023.
10.4. Arrcus
Arrcus reported the following implementations of the SR segment
endpoint node NEXT-CSID flavor (Section 4.1). These are used as part
of its SRv6 shortest path forwarding (in algorithm 0 and Flex-Algo),
TI-LFA, micro-loop avoidance and Traffic Engineering functionalities.
* Arrcus running on Ufi Space routers S9510-28DC, S9710-76D,
S9600-30DX and S9700-23D with ArcOS v5.2.1 or above
* Arrcus running n Ufi Space routers S9600-72XC and S9700-53DX with
ArcOS v5.1.1D or above
* Arrcus running on Quanta router IXA and IXAE with ArcOS v5.1.1D or
above
At the time of this report, all the implementations listed above are
in production and follow the specification in the latest version of
this document, including all the "MUST" and "SHOULD" clauses for the
NEXT-CSID flavor.
This report was last updated on March 11, 2023.
10.5. Juniper Networks
Juniper Networks reported the following implementations of the SR
segment endpoint node NEXT-CSID flavor (Section 4.1). These are used
as part of its SRv6 shortest path forwarding (in algorithm 0 and
Flex-Algo), TI-LFA, micro-loop avoidance, and Traffic Engineering
functionalities.
Juniper release 23.3 onwards supports this functionality.
At the time of this report, all the implementations listed above are
in development and follow the specification in the latest version of
this document, including all the "MUST" and "SHOULD" clauses for the
NEXT-CSID flavor.
This report was last updated on May 30, 2023.
10.6. Marvell
Marvell reported support in the Marvell Prestera Packet Processor for
the SR segment endpoint node NEXT-CSID flavor (Section 4.1) and
REPLACE-CSID flavor (Section 4.2).
This report was last updated on February 15, 2023.
10.7. Broadcom
Broadcom reported the following implementations of the SR segment
endpoint node NEXT-CSID flavor (Section 4.1) and REPLACE-CSID flavor
(Section 4.2). These are used as part of its SRv6 TI-LFA, micro-loop
avoidance, and traffic engineering functionalities. All
implementation of the following list is in general availability for
customers using BCM SDK 6.5.26 or above.
* 88850 (Jericho2c+) series
* 88690 (Jericho2) series
* 88800 (Jericho2c) series
* 88480 (Qunran2a) series
* 88280 (Qunran2u) series
* 88295 (Qunran2n) series
* 88830 (Jericho2x) series
At the time of this report, all the implementations listed above are
in production and follow the specification in the latest version of
this document, including all the "MUST" and "SHOULD" clauses for the
NEXT-CSID and REPLACE-CSID flavors.
For 78900 (Tomahawk) series-related support, please contact the
Broadcom team.
This report was last updated on February 21, 2023.
10.8. ZTE Corporation
ZTE Corporation reported the following implementations of the SR
segment endpoint node REPLACE-CSID flavor (Section 4.2). These are
used as part of its SRv6 TI-LFA, micro-loop avoidance, and traffic
engineering functionalities.
* ZTE M6000-18S(BRAS), M6000-8S Plus(BRAS) routers running
V5.00.10.09 or above.
* ZTE M6000-18S(SR), M6000-8S Plus(SR) routers running V5.00.10.80
or above.
* ZTE T8000-18 routers running V5.00.10.07 or above.
This report was last updated on March 29, 2023.
10.9. New H3C Technologies
New H3C Technologies reported the following implementations of the SR
segment endpoint node REPLACE-CSID flavor (Section 4.2). These are
used as part of its SRv6 TI-LFA, micro-loop avoidance, and traffic
engineering functionalities.
* H3C CR16000-F, SR8800-X routers running Version 7.1.075 or above.
* H3C CR18000, CR19000 routers running Version 7.1.071 or above.
This report was last updated on March 29, 2023.
10.10. Ruijie Network
Ruijie Network reported the following implementations of the SR
segment endpoint node REPLACE-CSID flavor (Section 4.2). These are
used as part of its SRv6 TI-LFA, micro-loop avoidance, and traffic
engineering functionalities.
* RUIJIE RG-N8018-R, RG-N8010-R routers running N8000-R_RGOS
12.8(3)B0801 or above.
This report was last updated on March 29, 2023.
10.11. Ciena
Ciena reported the following implementations of the SR segment
endpoint node NEXT-CSID flavor (Section 4.1). These are used as part
of its shortest path forwarding (in algorithm 0 and Flex-Algo),
remote and TI-LFA repair tunnel, and Traffic Engineering
functionalities.
The following platforms support implementation of the above.
* Ciena 5162, 5164, 5166, 5168 routers running SAOS 10.10 or above
* Ciena 8110, 8112, 8190 routers running SAOS 10.10 or above
At the time of this report, all the implementations listed above are
in production and follow the specification in the latest version of
this document, including all the "MUST" and "SHOULD" clauses for the
NEXT-CSID flavor.
This report was last updated on February 6, 2024.
10.12. Centec
Centec reported the following implementations of the SR segment
endpoint node REPLACE-CSID flavor (Section 4.2). These are used as
part of its SRv6 TI-LFA, micro-loop avoidance, and traffic
engineering functionalities. All implementation of the following
list is in general availability for customers using Centec SDK 5.6.8
or above.
* CTC7132 (TsingMa) Series
* CTC8180 (TsingMa.MX) Series
This report was last updated on February 14, 2024.
10.13. Open-Source
The authors found the following open-source implementations of the SR
segment endpoint node NEXT-CSID flavor (Section 4.1).
* The Linux kernel, version 6.1 [IMPL-OSS-LINUX]
* The Software for Open Networking in the Cloud (SONiC), version
202212 [IMPL-OSS-SONIC], and Switch Abstraction Interface (SAI),
version 1.9.0 [IMPL-OSS-SAI]
* The Vector Packet Processor (VPP), version 20.05 [IMPL-OSS-VPP]
* A generic P4 implementation [IMPL-OSS-P4]
The authors found the following open-source implementations of the SR
segment endpoint node REPLACE-CSID flavor (Section 4.2).
* ONOS and P4 Programmable Switch based [IMPL-OSS-ONOS]
* Open SRv6 Project [IMPL-OSS-OPEN-SRV6]
This section was last updated on January 11, 2023.
10.14. Interoperability Reports
10.14.1. EANTC 2024
In April 2024, the European Advanced Networking Test Center (EANTC)
successfully validated multiple implementations of SRv6 NEXT-CSID
flavor (a.k.a., SRv6 uSID) [EANTC-24].
The participating vendors included Arista, Ciena, Cisco, Ericsson,
H3C, Huawei, Juniper, Keysight, Nokia, and ZTE.
10.14.2. Bell Canada / Ciena 2023
Bell Canada is currently evaluating interoperability between Ciena
and Cisco implementations of the NEXT-CSID flavor defined in this
document. Further information will be added to this section when the
evaluation is complete.
10.14.3. EANTC 2023
In April 2023, the European Advanced Networking Test Center (EANTC)
successfully validated multiple implementations of SRv6 NEXT-CSID
flavor (a.k.a., SRv6 uSID) [EANTC-23].
The participating vendors included Arista, Arrcus, Cisco, Huawei,
Juniper, Keysight, Nokia, and Spirent.
10.14.4. China Mobile 2020
In November 2020, China Mobile successfully validated multiple
interoperable implementations of the NEXT-CSID and REPLACE-CSID
flavors defined in this document.
This testing covered two different implementations of the SRv6
endpoint flavors defined in this document:
* Hardware implementation in Cisco ASR 9000 running IOS XR
* Software implementation in Cisco IOS XRv9000 virtual appliance
* Hardware implementation in Huawei NE40E and NE5000E running VRP
The interoperability testing consisted of a packet flow sent by an SR
source node N0 via an SR traffic engineering policy with a segment
list <S1, S2, S3, S4, S5, S6, S7>, where S1..S7 are SIDs instantiated
on SR segment endpoint nodes N1..N7, respectively.
N0 --- N1 --- N2 --- N3 --- N4 --- N5 --- N6 --- N7
(S1) (S2) (S3) (S4) (S5) (S6) (S7)
* N0 is a generic packet generator.
* N1, N2, and N3 are Huawei routers.
* N4, N5, and N6 are Cisco routers.
* N7 is a generic traffic generator acting as a packet receiver.
The SR source node N0 steers the packets onto the SR policy by
setting the IPv6 destination address and creating an SRH (as
described in Section 4.1 of [RFC8754]) using a compressed segment
list encoding. The length of the compressed segment list encoding
varies for each scenario.
All SR segment endpoint nodes execute a variant of the End behavior:
regular End behavior (as defined in Section 4.1 of [RFC8986]), End
behavior with NEXT-CSID flavor, and End behavior with REPLACE-CSID
flavor. The variant being used at each SR segment endpoint node
varies for each scenario.
The interoperability was validated for the following scenarios:
*Scenario 1:*
* S1 and S2 are associated with the End behavior with the REPLACE-
CSID flavor
* S3 is associated with the regular End behavior (no flavor)
* S4, S5, and S6 are associated with the End behavior with the NEXT-
CSID flavor
* The SR source node imposes a compressed segment list encoding of 3
SIDs.
*Scenario 2:*
* S1, S2..., S6 are associated with the End behavior with the NEXT-
CSID flavor
* The SR source node imposes a compressed segment list encoding of 2
SIDs.
*Scenario 3:*
* S1, S2..., S6 are associated with the End behavior with the
REPLACE-CSID flavor
* The SR source node imposes a compressed segment list encoding of 3
SIDs.
11. Applicability to other Other SRv6 Endpoint Behaviors
Future documents may extend the applicability of the NEXT-CSID and
REPLACE-CSID flavors to other SRv6 endpoint behaviors.
For an SRv6 endpoint behavior that can be used before the last
position of a segment list, a CSID flavor is defined by reproducing
the same logic as described in Section Sections 4.1 and Section 4.2 of this
document to determine the
next SID in the SID list.
12.
11. Security Considerations
Section 8 of [RFC8402] discusses the security considerations for
Segment Routing.
Section 5 of [RFC8754] describes the intra-SR-domain deployment model
and how to secure it. Section 7 of [RFC8754] describes the threats
applicable to SRv6 and how to mitigate them.
Section 9 of [RFC8986] discusses the security considerations
applicable to the SRv6 network programming framework, as well as the
SR source node and SR segment endpoint node behaviors that it
defines.
This document introduces two new flavors flavors, NEXT-CSID and REPLACE-CSID,
for some of the SRv6 endpoint behaviors defined in [RFC8986] and a
method by which an SR source node may leverage the SIDs of these
flavors to produce a compressed segment list encoding.
This document also introduces two new SRv6 endpoint behaviors,
End.LBS and End.XLBS, to preserve the efficiency of CSID compression
in multi-domain environments.
An SR source node constructs an IPv6 packet with a compressed segment
list encoding as defined in Sections 3.1 and 4.1 of [RFC8754] and
Section 5 of [RFC8986]. The paths that an SR source node may enforce
using a compressed segment list encoding are the same, from a
topology and service perspective, as those that an SR source node
could enforce using the SIDs of [RFC8986].
An SR segment endpoint node processes an IPv6 packet matching a
locally instantiated SID as defined in [RFC8986], with the pseudocode
modifications in Section 4 of this document. These modifications
change how the SR segment endpoint node determines the next SID in
the packet, packet but not the semantic of either the active or the next SID.
For example, an adjacency segment instantiated with the End.X
behavior remains an adjacency segment regardless of whether it uses
the base End.X behavior defined in Section 4.2 of [RFC8986] or a CSID
flavor of that behavior. This document does not introduce any new
SID semantic.
Any other transit node processes the packet as described in
Section 4.2 of [RFC8754].
This document defines a new method of encoding the SIDs inside a SID
list at the SR source node (Section 6) and decoding them at the SR
segment endpoint node (Section (see Sections 4 and Section 7), but it does not change
how the SID list itself is encoded in the IPv6 packet nor the
semantic of any segment that it comprises. Therefore, this document
is subject to the same security considerations that are discussed in
[RFC8402], [RFC8754], and [RFC8986].
13.
12. IANA Considerations
13.1.
12.1. SRv6 Endpoint Behaviors
This I-D. requests the
IANA to update has updated the reference of the following registrations from
the "SRv6 Endpoint Behaviors" registry under the
top-level "Segment Routing" registry-group
(https://www.iana.org/assignments/segment-routing/) with the RFC
number of
registry group (<https://www.iana.org/assignments/segment-routing/>)
to point to this document once it is published, and transfer change control to the IETF.
+=======+=========================================+===========+
| Value | Description | Reference |
+=======+=========================================+===========+
| 43 | End with NEXT-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 44 | End with NEXT-CSID & PSP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 45 | End with NEXT-CSID & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 46 | End with NEXT-CSID, PSP & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 47 | End with NEXT-CSID & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 48 | End with NEXT-CSID, PSP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 49 | End with NEXT-CSID, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 50 | End with NEXT-CSID, PSP, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 52 | End.X with NEXT-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 53 | End.X with NEXT-CSID & PSP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 54 | End.X with NEXT-CSID & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 55 | End.X with NEXT-CSID, PSP & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 56 | End.X with NEXT-CSID & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 57 | End.X with NEXT-CSID, PSP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 58 | End.X with NEXT-CSID, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 59 | End.X with NEXT-CSID, PSP, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 85 | End.T with NEXT-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 86 | End.T with NEXT-CSID & PSP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 87 | End.T with NEXT-CSID & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 88 | End.T with NEXT-CSID, PSP & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 89 | End.T with NEXT-CSID & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 90 | End.T with NEXT-CSID, PSP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 91 | End.T with NEXT-CSID, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 92 | End.T with NEXT-CSID, PSP, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 93 | End.B6.Encaps with NEXT-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 94 | End.B6.Encaps.Red with NEXT-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 95 | End.BM with NEXT-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 96 | End.LBS with NEXT-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 97 | End.XLBS with NEXT-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 101 | End with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 102 | End with REPLACE-CSID & PSP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 103 | End with REPLACE-CSID & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 104 | End with REPLACE-CSID, PSP & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 105 | End.X with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 106 | End.X with REPLACE-CSID & PSP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 107 | End.X with REPLACE-CSID & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 108 | End.X with REPLACE-CSID, PSP & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 109 | End.T with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 110 | End.T with REPLACE-CSID & PSP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 111 | End.T with REPLACE-CSID & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 112 | End.T with REPLACE-CSID, PSP & USP | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 114 | End.B6.Encaps with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 115 | End.BM with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 116 | End.DX6 with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 117 | End.DX4 with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 118 | End.DT6 with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 119 | End.DT4 with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 120 | End.DT46 with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 121 | End.DX2 with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 122 | End.DX2V with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 123 | End.DT2U with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 124 | End.DT2M with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 127 | End.B6.Encaps.Red with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 128 | End with REPLACE-CSID & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 129 | End with REPLACE-CSID, PSP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 130 | End with REPLACE-CSID, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 131 | End with REPLACE-CSID, PSP, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 132 | End.X with REPLACE-CSID & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 133 | End.X with REPLACE-CSID, PSP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 134 | End.X with REPLACE-CSID, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 135 | End.X with REPLACE-CSID, PSP, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 136 | End.T with REPLACE-CSID & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 137 | End.T with REPLACE-CSID, PSP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 138 | End.T with REPLACE-CSID, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 139 | End.T with REPLACE-CSID, PSP, USP & USD | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 140 | End.LBS with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
| 141 | End.XLBS with REPLACE-CSID | This I-D. RFC 9800 |
+-------+-----------------------------------------+-----------+
Table 1: SRv6 Endpoint Behaviors Registration List
14. Acknowledgements
The authors would like to thank Kamran Raza, Xing Jiang, YuanChao Su,
Han Li, Yisong Liu, Martin Vigoureux, Joel Halpern, and Tal Mizrahi
for their insightful feedback and suggestions.
The authors would also like to thank Andrew Alston, Linda Dunbar,
Adrian Farrel, Boris Hassanov, Alvaro Retana, and Gunter Van de Velde
for their thorough review of this document.
15.
13. References
15.1.
13.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<https://www.rfc-editor.org/info/rfc2119>.
[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
May 2017, <https://www.rfc-editor.org/info/rfc8174>.
[RFC8200] Deering, S. and R. Hinden, "Internet Protocol, Version 6
(IPv6) Specification", STD 86, RFC 8200,
DOI 10.17487/RFC8200, July 2017,
<https://www.rfc-editor.org/info/rfc8200>.
[RFC8402] Filsfils, C., Ed., Previdi, S., Ed., Ginsberg, L.,
Decraene, B., Litkowski, S., and R. Shakir, "Segment
Routing Architecture", RFC 8402, DOI 10.17487/RFC8402,
July 2018, <https://www.rfc-editor.org/info/rfc8402>.
[RFC8754] Filsfils, C., Ed., Dukes, D., Ed., Previdi, S., Leddy, J.,
Matsushima, S., and D. Voyer, "IPv6 Segment Routing Header
(SRH)", RFC 8754, DOI 10.17487/RFC8754, March 2020,
<https://www.rfc-editor.org/info/rfc8754>.
[RFC8986] Filsfils, C., Ed., Camarillo, P., Ed., Leddy, J., Voyer,
D., Matsushima, S., and Z. Li, "Segment Routing over IPv6
(SRv6) Network Programming", RFC 8986,
DOI 10.17487/RFC8986, February 2021,
<https://www.rfc-editor.org/info/rfc8986>.
15.2.
13.2. Informative References
[EANTC-23] European Advanced Networking Test Center (EANTC), "Multi-
Vendor MPLS SDN Interoperability Test Report 2023", 18
April 2023, <https://eantc.de/wp-content/uploads/2023/04/
EANTC-InteropTest2023-TestReport.pdf>.
[EANTC-24] European Advanced Networking Test Center (EANTC), "Multi-
Vendor MPLS SDN Interoperability Test Report 2024", April
2024, <https://eantc.de/wp-content/uploads/2023/12/EANTC-
MPLSSDNInterop2024-TestReport-v1.3.pdf>.
[GKP94] Graham, R., Knuth, D., and O. Patashnik, "Concrete
Mathematics: A Foundation for Computer Science",
ISBN 9780201558029, 1994.
[I-D.ietf-idr-bgp-ls-sr-policy]
[BGP-LS-SR]
Previdi, S., Talaulikar, K., Ed., Dong, J., Gredler, H.,
and J. Tantsura, "Advertisement of Segment Routing
Policies using BGP Link-State", Work in Progress, Internet-Draft, draft-
ietf-idr-bgp-ls-sr-policy-10, 9 December 2024,
<https://datatracker.ietf.org/doc/html/draft-ietf-idr-bgp-
ls-sr-policy-10>.
[I-D.ietf-idr-sr-policy-safi]
Previdi, S., Filsfils, C., Talaulikar, K., Mattes, P., and
D. Jain, "Advertising Segment Routing Policies in BGP",
Work in Progress, Internet-Draft, draft-ietf-idr-sr-
policy-safi-11, 31 January
March 2025,
<https://datatracker.ietf.org/api/v1/doc/document/draft-
ietf-idr-sr-policy-safi/>.
[IMPL-CISCO-8000]
Cisco Systems, "Segment Routing Configuration Guide for
Cisco 8000 Series Routers", 4 November 2022,
<https://www.cisco.com/c/en/us/td/docs/iosxr/cisco8000/
segment-routing/75x/b-segment-routing-cg-cisco8000-75x/
configuring-segment-routing-over-ipv6-srv6-micro-
sids.html>.
[IMPL-CISCO-ASR9000]
Cisco Systems, "Segment Routing Configuration Guide for
Cisco ASR 9000 Series Routers", 6 November 2022,
<https://www.cisco.com/c/en/us/td/docs/routers/asr9000/
software/asr9k-r7-5/segment-routing/configuration/guide/b-
segment-routing-cg-asr9000-75x/configure-srv6-micro-
sid.html>.
[IMPL-CISCO-NCS540]
Cisco Systems, "Segment Routing Configuration Guide for
Cisco NCS 540 Series Routers", 2 November 2022,
<https://www.cisco.com/c/en/us/td/docs/iosxr/ncs5xx/
segment-routing/73x/b-segment-routing-cg-73x-ncs540/
configure-srv6.html>.
[IMPL-CISCO-NCS5500]
Cisco Systems, "Segment Routing Configuration Guide for
Cisco NCS 5500 Series Routers", 6 November 2022,
<https://www.cisco.com/c/en/us/td/docs/iosxr/ncs5500/
segment-routing/73x/b-segment-routing-cg-ncs5500-73x/
configure-srv6-micro-sid.html>.
[IMPL-CISCO-NCS560]
Cisco Systems, "Segment Routing Configuration Guide for
Cisco NCS 560 Series Routers", 14 October 2022,
<https://www.cisco.com/c/en/us/td/docs/iosxr/ncs560/
segment-routing/76x/b-segment-routing-cg-76x-ncs560/m-
configure-srv6-usid-ncs5xx.html>.
[IMPL-CISCO-NCS5700]
Cisco Systems, "Segment Routing Configuration Guide for
Cisco NCS 5700 Series Routers", 6 November 2022,
<https://www.cisco.com/c/en/us/td/docs/iosxr/ncs5500/
segment-routing/75x/b-segment-routing-cg-ncs5500-75x/
configure-srv6-micro-sid.html>.
[IMPL-NOKIA-20.10]
Nokia, "Segment Routing <https://datatracker.ietf.org/doc/html/draft-
ietf-idr-bgp-ls-sr-policy-17>.
[GKP94] Graham, R., Knuth, D., and PCE User Guide", December
2022, <https://documentation.nokia.com/sr/22-
10/books/Segment%20Routing%20and%20PCE%20User%20Guide/
segment-rout-with-ipv6-data-plane-srv6.html>.
[IMPL-OSS-LINUX]
Abeni, P., "Add NEXT-CSID support O. Patashnik, "Concrete
Mathematics: A Foundation for SRv6 End behavior",
20 September 2022,
<https://git.kernel.org/pub/scm/linux/kernel/git/netdev/
net-next.git/
commit/?id=cec9d59e89362809f17f2d854faf52966216da13>.
[IMPL-OSS-ONOS]
Open Networking Foundation, "Stratum CMCC G-SRv6 Project",
24 March 2021,
<https://wiki.opennetworking.org/display/COM/
Stratum+CMCC+G-SRv6+Project>.
[IMPL-OSS-OPEN-SRV6]
"Open SRv6 Project", n.d.,
<http://opensrv6.org.cn/en/srv6-2/>.
[IMPL-OSS-P4]
Salsano, S. and A. Tulumello, "SRv6 uSID (micro SID)
implementation on P4", 3 January 2021,
<https://github.com/netgroup/p4-srv6-usid>.
[IMPL-OSS-SAI]
Agrawal, A., "Added new behaviors to support uSID
instruction", 8 June 2021,
<https://github.com/opencomputeproject/SAI/pull/1231/
commits/02e58d95ad966ca9efc24eb9e0c0fa10b21de2a4>.
[IMPL-OSS-SONIC]
Shah, S. and R. Sudarshan, "SONiC uSID", 21 August 2022,
<https://github.com/sonic-net/SONiC/blob/master/doc/srv6/
SRv6_uSID.md>.
[IMPL-OSS-VPP]
FD.io, "Srv6 cli reference", n.d., <https://s3-
docs.fd.io/vpp/23.02/cli-reference/clis/
clicmd_src_vnet_srv6.html>. Computer Science",
ISBN 9780201558029, 1994.
[RFC4786] Abley, J. and K. Lindqvist, "Operation of Anycast
Services", BCP 126, RFC 4786, DOI 10.17487/RFC4786,
December 2006, <https://www.rfc-editor.org/info/rfc4786>.
[RFC7942] Sheffer, Y. and A. Farrel, "Improving Awareness of Running
Code: The Implementation Status Section", BCP 205,
RFC 7942, DOI 10.17487/RFC7942, July 2016,
<https://www.rfc-editor.org/info/rfc7942>.
[RFC9252] Dawra, G., Ed., Talaulikar, K., Ed., Raszuk, R., Decraene,
B., Zhuang, S., and J. Rabadan, "BGP Overlay Services
Based on Segment Routing over IPv6 (SRv6)", RFC 9252,
DOI 10.17487/RFC9252, July 2022,
<https://www.rfc-editor.org/info/rfc9252>.
[RFC9259] Ali, Z., Filsfils, C., Matsushima, S., Voyer, D., and M.
Chen, "Operations, Administration, and Maintenance (OAM)
in Segment Routing over IPv6 (SRv6)", RFC 9259,
DOI 10.17487/RFC9259, June 2022,
<https://www.rfc-editor.org/info/rfc9259>.
[RFC9350] Psenak, P., Ed., Hegde, S., Filsfils, C., Talaulikar, K.,
and A. Gulko, "IGP Flexible Algorithm", RFC 9350,
DOI 10.17487/RFC9350, February 2023,
<https://www.rfc-editor.org/info/rfc9350>.
[RFC9352] Psenak, P., Ed., Filsfils, C., Bashandy, A., Decraene, B.,
and Z. Hu, "IS-IS Extensions to Support Segment Routing
over the IPv6 Data Plane", RFC 9352, DOI 10.17487/RFC9352,
February 2023, <https://www.rfc-editor.org/info/rfc9352>.
[RFC9513] Li, Z., Hu, Z., Talaulikar, K., Ed., and P. Psenak,
"OSPFv3 Extensions for Segment Routing over IPv6 (SRv6)",
RFC 9513, DOI 10.17487/RFC9513, December 2023,
<https://www.rfc-editor.org/info/rfc9513>.
[RFC9514] Dawra, G., Filsfils, C., Talaulikar, K., Ed., Chen, M.,
Bernier, D., and B. Decraene, "Border Gateway Protocol -
Link State (BGP-LS) Extensions for Segment Routing over
IPv6 (SRv6)", RFC 9514, DOI 10.17487/RFC9514, December
2023, <https://www.rfc-editor.org/info/rfc9514>.
[RFC9602] Krishnan, S., "Segment Routing over IPv6 (SRv6) Segment
Identifiers in the IPv6 Addressing Architecture",
RFC 9602, DOI 10.17487/RFC9602, October 2024,
<https://www.rfc-editor.org/info/rfc9602>.
[RFC9603] Li, C., Ed., Kaladharan, P., Sivabalan, S., Koldychev, M.,
and Y. Zhu, "Path Computation Element Communication
Protocol (PCEP) Extensions for IPv6 Segment Routing",
RFC 9603, DOI 10.17487/RFC9603, July 2024,
<https://www.rfc-editor.org/info/rfc9603>.
[SPRING-WG-POLICIES]
SPRING Working Group Chairs, "SPRING Working Group
Policies", 14 October 2022,
<https://wiki.ietf.org/en/group/spring/WG_Policies>.
[SR-BGP] Previdi, S., Filsfils, C., Talaulikar, K., Ed., Mattes,
P., and D. Jain, "Advertising Segment Routing Policies in
BGP", Work in Progress, Internet-Draft, draft-ietf-idr-sr-
policy-safi-13, 6 February 2025,
<https://datatracker.ietf.org/doc/html/draft-ietf-idr-sr-
policy-safi-13>.
Appendix A. Complete pseudocodes Pseudocodes
The content of this section is purely informative rendering of the
pseudocodes of [RFC8986] with the modifications in this document.
This rendering may not be used as a reference.
A.1. End with NEXT-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End SID with the NEXT-CSID flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address
with Code 0 (Hop limit exceeded in transit),
interrupt packet processing, and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
N09. }
S02. If (Segments Left == 0) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address
with Code 0 (Hop limit exceeded in transit),
interrupt packet processing, and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
S09. If ((Last Entry > max_LE) or (Segments Left > Last Entry+1)) {
S10. Send an ICMP Parameter Problem to the Source Address
with Code 0 (Erroneous header field encountered)
and Pointer set to the Segments Left field,
interrupt packet processing, and discard the packet.
S11. }
S12. Decrement IPv6 Hop Limit by 1.
S13. Decrement Segments Left by 1.
S14. Update IPv6 DA with Segment List[Segments Left].
S15. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
Before processing the Upper-Layer header or any IPv6 extension header
other than Hop-by-Hop or Destination Options of a packet matching a
FIB entry locally instantiated as an End SID with the NEXT-CSID
flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
N09. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End SID with the NEXT-CSID flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.2. End.X with NEXT-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End.X SID with the NEXT-CSID flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address
with Code 0 (Hop limit exceeded in transit),
interrupt packet processing, and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08. Submit the packet to the IPv6 module for transmission to the
new destination via a member of J.
N09. }
S02. If (Segments Left == 0) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address
with Code 0 (Hop limit exceeded in transit),
interrupt packet processing, and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
S09. If ((Last Entry > max_LE) or (Segments Left > Last Entry+1)) {
S10. Send an ICMP Parameter Problem to the Source Address
with Code 0 (Erroneous header field encountered)
and Pointer set to the Segments Left field,
interrupt packet processing, and discard the packet.
S11. }
S12. Decrement IPv6 Hop Limit by 1.
S13. Decrement Segments Left by 1.
S14. Update IPv6 DA with Segment List[Segments Left].
S15. Submit the packet to the IPv6 module for transmission
to the new destination via a member of J.
Before processing the Upper-Layer header or any IPv6 extension header
other than Hop-by-Hop or Destination Options of a packet matching a
FIB entry locally instantiated as an End.X SID with the NEXT-CSID
flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08. Submit the packet to the IPv6 module for transmission to the
new destination via a member of J.
N09. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End.X SID with the NEXT-CSID flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.3. End.T with NEXT-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End.T SID with the NEXT-CSID flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address
with Code 0 (Hop limit exceeded in transit),
interrupt packet processing, and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08.1. Set the packet's associated FIB table to T.
N08.2. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
N09. }
S02. If (Segments Left == 0) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address
with Code 0 (Hop limit exceeded in transit),
interrupt packet processing, and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
S09. If ((Last Entry > max_LE) or (Segments Left > Last Entry+1)) {
S10. Send an ICMP Parameter Problem to the Source Address
with Code 0 (Erroneous header field encountered)
and Pointer set to the Segments Left field,
interrupt packet processing, and discard the packet.
S11. }
S12. Decrement IPv6 Hop Limit by 1.
S13. Decrement Segments Left by 1.
S14. Update IPv6 DA with Segment List[Segments Left].
S15.1. Set the packet's associated FIB table to T.
S15.2. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
Before processing the Upper-Layer header or any IPv6 extension header
other than Hop-by-Hop or Destination Options of a packet matching a
FIB entry locally instantiated as an End.T SID with the NEXT-CSID
flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08.1. Set the packet's associated FIB table to T.
N08.2. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
N09. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End.T SID with the NEXT-CSID flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.4. End.B6.Encaps with NEXT-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End.B6.Encaps SID with the NEXT-CSID flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08.1. Push a new IPv6 header with its own SRH containing B.
N08.2. Set the outer IPv6 SA to A.
N08.3. Set the outer IPv6 DA to the first SID of B.
N08.4. Set the outer Payload Length, Traffic Class, Flow Label,
Hop Limit, and Next Header fields.
N08.5. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
N09. }
S02. If (Segments Left == 0) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address
with Code 0 (Hop limit exceeded in transit),
interrupt packet processing, and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
S09. If ((Last Entry > max_LE) or (Segments Left > Last Entry+1)) {
S10. Send an ICMP Parameter Problem to the Source Address
with Code 0 (Erroneous header field encountered)
and Pointer set to the Segments Left field,
interrupt packet processing, and discard the packet.
S11. }
S12. Decrement IPv6 Hop Limit by 1.
S13. Decrement Segments Left by 1.
S14. Update IPv6 DA with Segment List[Segments Left].
S15. Push a new IPv6 header with its own SRH containing B.
S16. Set the outer IPv6 SA to A.
S17. Set the outer IPv6 DA to the first SID of B.
S18. Set the outer Payload Length, Traffic Class, Flow Label,
Hop Limit, and Next Header fields.
S19. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
Before processing the Upper-Layer header or any IPv6 extension header
other than Hop-by-Hop or Destination Options of a packet matching a
FIB entry locally instantiated as an End.B6.Encaps SID with the NEXT-
CSID flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08.1. Push a new IPv6 header with its own SRH containing B.
N08.2. Set the outer IPv6 SA to A.
N08.3. Set the outer IPv6 DA to the first SID of B.
N08.4. Set the outer Payload Length, Traffic Class, Flow Label,
Hop Limit, and Next Header fields.
N08.5. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
N09. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End.B6.Encaps SID with the NEXT-CSID
flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.5. End.BM with NEXT-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End.BM SID with the NEXT-CSID flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08.1. Push the MPLS label stack for B.
N08.2. Submit the packet to the MPLS engine for transmission.
N09. }
S02. If (Segments Left == 0) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address
with Code 0 (Hop limit exceeded in transit),
interrupt packet processing, and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
S09. If ((Last Entry > max_LE) or (Segments Left > Last Entry+1)) {
S10. Send an ICMP Parameter Problem to the Source Address
with Code 0 (Erroneous header field encountered)
and Pointer set to the Segments Left field,
interrupt packet processing, and discard the packet.
S11. }
S12. Decrement IPv6 Hop Limit by 1.
S13. Decrement Segments Left by 1.
S14. Update IPv6 DA with Segment List[Segments Left].
S15. Push the MPLS label stack for B.
S16. Submit the packet to the MPLS engine for transmission.
Before processing the Upper-Layer header or any IPv6 extension header
other than Hop-by-Hop or Destination Options of a packet matching a
FIB entry locally instantiated as an End.BM SID with the NEXT-CSID
flavor:
N01. If (DA.Argument != 0) {
N02. If (IPv6 Hop Limit <= 1) {
N03. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
N04. }
N05. Copy DA.Argument into the bits [LBL..(LBL+AL-1)] of the
Destination Address.
N06. Set the bits [(LBL+AL)..127] of the Destination Address to
zero.
N07. Decrement IPv6 Hop Limit by 1.
N08.1. Push the MPLS label stack for B.
N08.2. Submit the packet to the MPLS engine for transmission.
N09. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End.BM SID with the NEXT-CSID
flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.6. End with REPLACE-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End SID with the REPLACE-CSID flavor:
S01. When an SRH is processed {
S02. If (Segments Left == 0 and (DA.Arg.Index == 0 or
Segment List[0][DA.Arg.Index-1] == 0)) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
R01. If (DA.Arg.Index != 0) {
R02. If ((Last Entry > max_LE) or (Segments Left > Last Entry)) {
R03. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R04. }
R05. Decrement DA.Arg.Index by 1.
R06. If (Segment List[Segments Left][DA.Arg.Index] == 0) {
R07. Decrement Segments Left by 1.
R08. Decrement IPv6 Hop Limit by 1.
R09. Update IPv6 DA with Segment List[Segments Left]
R10. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
R11. }
R12. } Else {
R13. If((Last Entry > max_LE) or (Segments Left > Last Entry+1)){
R14. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R15. }
R16. Decrement Segments Left by 1.
R17. Set DA.Arg.Index to (128/LNFL - 1).
R18. }
R19. Decrement IPv6 Hop Limit by 1.
R20. Write Segment List[Segments Left][DA.Arg.Index] into the bits
[LBL..LBL+LNFL-1] of the Destination Address of the IPv6
header.
R21. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
S16. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End SID with the REPLACE-CSID
flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.7. End.X with REPLACE-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End.X SID with the REPLACE-CSID flavor:
S01. When an SRH is processed {
S02. If (Segments Left == 0 and (DA.Arg.Index == 0 or
Segment List[0][DA.Arg.Index-1] == 0)) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
R01. If (DA.Arg.Index != 0) {
R02. If ((Last Entry > max_LE) or (Segments Left > Last Entry)) {
R03. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R04. }
R05. Decrement DA.Arg.Index by 1.
R06. If (Segment List[Segments Left][DA.Arg.Index] == 0) {
R07. Decrement Segments Left by 1.
R08. Decrement IPv6 Hop Limit by 1.
R09. Update IPv6 DA with Segment List[Segments Left]
R10. Submit the packet to the IPv6 module for transmission to
the new destination via a member of J.
R11. }
R12. } Else {
R13. If((Last Entry > max_LE) or (Segments Left > Last Entry+1)){
R14. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R15. }
R16. Decrement Segments Left by 1.
R17. Set DA.Arg.Index to (128/LNFL - 1).
R18. }
R19. Decrement IPv6 Hop Limit by 1.
R20. Write Segment List[Segments Left][DA.Arg.Index] into the bits
[LBL..LBL+LNFL-1] of the Destination Address of the IPv6
header.
R21. Submit the packet to the IPv6 module for transmission to the
new destination via a member of J.
S16. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End.X SID with the REPLACE-CSID
flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.8. End.T with REPLACE-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End.T SID with the REPLACE-CSID flavor:
S01. When an SRH is processed {
S02. If (Segments Left == 0 and (DA.Arg.Index == 0 or
Segment List[0][DA.Arg.Index-1] == 0)) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
R01. If (DA.Arg.Index != 0) {
R02. If ((Last Entry > max_LE) or (Segments Left > Last Entry)) {
R03. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R04. }
R05. Decrement DA.Arg.Index by 1.
R06. If (Segment List[Segments Left][DA.Arg.Index] == 0) {
R07. Decrement Segments Left by 1.
R08. Decrement IPv6 Hop Limit by 1.
R09. Update IPv6 DA with Segment List[Segments Left]
R10.1. Set the packet's associated FIB table to T.
R10.2. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
R11. }
R12. } Else {
R13. If((Last Entry > max_LE) or (Segments Left > Last Entry+1)){
R14. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R15. }
R16. Decrement Segments Left by 1.
R17. Set DA.Arg.Index to (128/LNFL - 1).
R18. }
R19. Decrement IPv6 Hop Limit by 1.
R20. Write Segment List[Segments Left][DA.Arg.Index] into the bits
[LBL..LBL+LNFL-1] of the Destination Address of the IPv6
header.
R21.1. Set the packet's associated FIB table to T.
R21.2. Submit the packet to the egress IPv6 FIB lookup for
transmission to the new destination.
S16. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End.T SID with the REPLACE-CSID
flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.9. End.B6.Encaps with REPLACE-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End.B6.Encaps SID with the REPLACE-CSID flavor:
S01. When an SRH is processed {
S02. If (Segments Left == 0 and (DA.Arg.Index == 0 or
Segment List[0][DA.Arg.Index-1] == 0)) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
R01. If (DA.Arg.Index != 0) {
R02. If ((Last Entry > max_LE) or (Segments Left > Last Entry)) {
R03. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R04. }
R05. Decrement DA.Arg.Index by 1.
R06. If (Segment List[Segments Left][DA.Arg.Index] == 0) {
R07. Decrement Segments Left by 1.
R08. Decrement IPv6 Hop Limit by 1.
R09. Update IPv6 DA with Segment List[Segments Left]
R10.1. Push a new IPv6 header with its own SRH containing B.
R10.2. Set the outer IPv6 SA to A.
R10.3. Set the outer IPv6 DA to the first SID of B.
R10.4. Set the outer Payload Length, Traffic Class, Flow Label,
Hop Limit, and Next Header fields.
R10.5. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
R11. }
R12. } Else {
R13. If((Last Entry > max_LE) or (Segments Left > Last Entry+1)){
R14. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R15. }
R16. Decrement Segments Left by 1.
R17. Set DA.Arg.Index to (128/LNFL - 1).
R18. }
R19. Decrement IPv6 Hop Limit by 1.
R20. Write Segment List[Segments Left][DA.Arg.Index] into the bits
[LBL..LBL+LNFL-1] of the Destination Address of the IPv6
header.
R21.1. Push a new IPv6 header with its own SRH containing B.
R21.2. Set the outer IPv6 SA to A.
R21.3. Set the outer IPv6 DA to the first SID of B.
R21.4. Set the outer Payload Length, Traffic Class, Flow Label,
Hop Limit, and Next Header fields.
R21.5. Submit the packet to the egress IPv6 FIB lookup for
transmission to the next destination.
S16. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End.B6.Encaps SID with the REPLACE-
CSID flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
A.10. End.BM with REPLACE-CSID
When processing the SRH of a packet matching a FIB entry locally
instantiated as an End.BM SID with the REPLACE-CSID flavor:
S01. When an SRH is processed {
S02. If (Segments Left == 0 and (DA.Arg.Index == 0 or
Segment List[0][DA.Arg.Index-1] == 0)) {
S03. Stop processing the SRH, SRH and proceed to process the next
header in the packet, whose type is identified by
the Next Header field in the routing header.
S04. }
S05. If (IPv6 Hop Limit <= 1) {
S06. Send an ICMP Time Exceeded message to the Source Address,
Code 0 (Hop limit exceeded in transit),
interrupt packet processing and discard the packet.
S07. }
S08. max_LE = (Hdr Ext Len / 2) - 1
R01. If (DA.Arg.Index != 0) {
R02. If ((Last Entry > max_LE) or (Segments Left > Last Entry)) {
R03. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R04. }
R05. Decrement DA.Arg.Index by 1.
R06. If (Segment List[Segments Left][DA.Arg.Index] == 0) {
R07. Decrement Segments Left by 1.
R08. Decrement IPv6 Hop Limit by 1.
R09. Update IPv6 DA with Segment List[Segments Left]
R10.1. Push the MPLS label stack for B.
R10.2. Submit the packet to the MPLS engine for transmission.
R11. }
R12. } Else {
R13. If((Last Entry > max_LE) or (Segments Left > Last Entry+1)){
R14. Send an ICMP Parameter Problem to the Source Address,
Code 0 (Erroneous header field encountered),
Pointer set to the Segments Left field,
interrupt packet processing and discard the packet.
R15. }
R16. Decrement Segments Left by 1.
R17. Set DA.Arg.Index to (128/LNFL - 1).
R18. }
R19. Decrement IPv6 Hop Limit by 1.
R20. Write Segment List[Segments Left][DA.Arg.Index] into the bits
[LBL..LBL+LNFL-1] of the Destination Address of the IPv6
header.
R21.1. Push the MPLS label stack for B.
R21.2. Submit the packet to the MPLS engine for transmission.
S16. }
When processing the Upper-Layer header of a packet matching a FIB
entry locally instantiated as an End.BM SID with the REPLACE-CSID
flavor:
S01. If (Upper-Layer header type is allowed by local configuration) {
S02. Proceed to process the Upper-Layer header
S03. } Else {
S04. Send an ICMP Parameter Problem to the Source Address
with Code 4 (SR Upper-layer Header Error)
and Pointer set to the offset of the Upper-Layer header,
interrupt packet processing, and discard the packet.
S05. }
Acknowledgements
The authors would like to thank Kamran Raza, Xing Jiang, YuanChao Su,
Han Li, Yisong Liu, Martin Vigoureux, Joel Halpern, and Tal Mizrahi
for their insightful feedback and suggestions.
The authors would also like to thank Andrew Alston, Linda Dunbar,
Adrian Farrel, Boris Hassanov, Alvaro Retana, and Gunter Van de Velde
for their thorough review of this document.
Contributors
Liu Aihua
ZTE Corporation
China
Email: liu.aihua@zte.com.cn
Dennis Cai
Alibaba
United States of America
Email: d.cai@alibaba-inc.com
Darren Dukes
Cisco Systems, Inc.
Canada
Email: ddukes@cisco.com
James N Guichard
Futurewei Technologies Ltd.
United States of America
Email: james.n.guichard@futurewei.com
Cheng Li
Huawei Technologies
China
Email: c.l@huawei.com
Robert Raszuk
NTT Network Innovations
United States of America
Email: robert@raszuk.net
Ketan Talaulikar
Cisco Systems, Inc.
India
Email: ketant.ietf@gmail.com
Daniel Voyer
Bell Canada
Canada
Email: daniel.voyer@bell.ca
Shay Zadok
Broadcom
Israel
Email: shay.zadok@broadcom.com
Authors' Addresses
Weiqiang Cheng (editor)
China Mobile
China
Email: chengweiqiang@chinamobile.com
Clarence Filsfils
Cisco Systems, Inc.
Belgium
Email: cf@cisco.com
Zhenbin Li
Huawei Technologies
China
Email: lizhenbin@huawei.com
Bruno Decraene
Orange
France
Email: bruno.decraene@orange.com
Francois Clad (editor)
Cisco Systems, Inc.
France
Email: fclad.ietf@gmail.com