Internet-Draft SRCOMP Requirements September 2022
Bonica, et al. Expires 31 March 2023 [Page]
Workgroup:
SPRING
Internet-Draft:
draft-ietf-spring-compression-analysis-02
Published:
Intended Status:
Informational
Expires:
Authors:
R. Bonica
Juniper
W. Cheng
China Mobile
D. Dukes, Ed.
Cisco Systems
W. Henderickx
Nokia
C. Li
Huawei
P. Shaofu
ZTE
C. Xie
China Telecom

Compressed SRv6 SID List Analysis

Abstract

Several mechanisms have been proposed to compress the SRv6 SID list. This document analyzes each mechanism with regard to the requirements stated in the companion requirements document.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at https://datatracker.ietf.org/drafts/current/.

Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."

This Internet-Draft will expire on 31 March 2023.

Table of Contents

1. Introduction

The following mechanisms are proposed to compress the SRv6 SID list:

This document analyzes each mechanism against the requirements stated in [I-D.srcompdt-spring-compression-requirement]. Each section of this document corresponds to a similarly named section in [I-D.srcompdt-spring-compression-requirement]. Each section reiterates corresponding requirements and analyzes each proposal against the those requirements.

The terms compression mechanism, compression solution, and compression proposal are used interchangeably within this document.

2. SRv6 Compression Requirements

An SR domain consisting of 3 sub-domains is shown to illustrate the scenarios associated with encapsulation header size, forwarding efficiency and state efficiency.

        + * * * * * * * * * * * * * * * * * * * * * * * * * * +
        *                                                     *
        * - - - - - - - - + - - - - - - - - + - - - - - - - - *
        *                 |                 |                 *
        *   [M1_0]      [B5]  [C_0]       [B7]  [M2_0]        *
[H1]--[E3]                |                 |                [E4]---[H2]
        *        [M1_i] [B6]        [C_j] [B8]       [M2_k]   *
        *                 |                 |                 *
        *     Metro 1     |      Core       |     Metro 2     *
        *- - - - - - - - - - - - - - - - - - - - - - - - - - -*
        *                                                     *
        *                      SR domain                      *
        + * * * * * * * * * * * * * * * * * * * * * * * * * * +
Figure 1: Sample SR Domain

2.1. Encapsulation Header Size

The compression proposal MUST reduce the size of the SRv6 encapsulation header.

Encapsulation header size is evaluated against a set of reference scenarios.

2.1.1. Reference Scenarios

A service provider offers a VPN service with underlay optimization in the SR domain.

  • Hosts H1 and H2 are located in two different sites of a VPN customer.
  • Edge nodes E3 and E4 encapsulate/decapsulate traffic between H1 and H2 to provide the VPN service.
  • The encapsulation consists of a VPN SID (V) (eg END.DT etc) and an SR policy with between 0 and 15 transport segments (T) (eg END or END.X)
  • The SR domain has a block size (B) of 48 bits

  • These independent variables are used to uniquely identify each scenario. For example

    • A scenario with 48bit block size, 3 transport segments and a VPN segment is named 48B.3T.V

Proposals are evaluated against the set of scenarios to calculate the encapsulation in octets (E) and the encapsulation savings (ES) as a fraction of the SRv6 base encapsulation in octets.

E and ES were evaluated for:

  • each proposal in two variants

    • 16-bit SID
    • 32-bit SID
  • 48-bit SRv6 block, 0 to 15 transport segments and a VPN segment (expressed in short form as 48B.0-15T.V)

The average encapsulation savings for each proposal is shown below. The complete analysis is recorded in Appendix:

Table 1: Average ES, 16-bit SIDs, 48B.0-15T.V
16-bit SIDs CSID CRH CRH+TPF VSID UIDSR
Average ES 54.3% 54.2% 50.4% 51.6% 49.2%
Table 2: Average ES, 32-bit SIDs, 48B.0-15T.V
32-bit SIDs CSID CRH CRH+TPF VSID UIDSR
Average ES 42.5% 45.5% 43.2% 45.5% 42.5%

E and ES are also evaluated for 32bit and 64bit SRv6 block sizes. The CSID 16-bit ES averages 57.4% for 32-bit blocks and 49.9% for 64-bit blocks, other proposals are unchanged.

Conclusion: All proposals meet the requirement to reduce the size of the SRv6 encapsulation header. Variances between proposals are negligible.

2.2. Forwarding Efficiency

The compression proposal SHOULD minimize the number of required hardware resources accessed to process a segment.

2.2.1. Headers Parsed

Forwarding efficiency is calculated against the reference scenarios above, recording and summarizing the differences in header parsing for different segment lists.

The following tables indicate the number of headers parsed for each proposal.

Table 3: Headers parsed on non-decapsulating SR segment endpoint nodes, 16-bit SIDs, 48B.0-15T.V
16-bit CSID CRH CRH+TPF VSID UIDSR
PRS(48B.0T).V) IPv6 IPv6 IPv6 IPv6 IPv6
           
PRS(48B.1-4T).V) IPv6 IPv6 IPv6 IPv6 IPv6
    CRH CRH SRH SRH
           
PRS(48B.5-15T).V) IPv6 IPv6 IPv6 IPv6 IPv6
  SRH CRH CRH SRH SRH
           
Table 4: Headers parsed on decapsulating SR segment endpoint nodes, 16-bit SIDs, 48B.0-15T.V
16-bit CSID CRH CRH+TPF VSID UIDSR
PRS(48B.0T).V) IPv6 IPv6 IPv6 IPv6 IPv6
           
PRS(48B.1-4T).V) IPv6 IPv6 IPv6 IPv6 IPv6
    CRH CRH SRH SRH
      TPF    
           
PRS(48B.5-15T).V) IPv6 IPv6 IPv6 IPv6 IPv6
  SRH CRH CRH SRH SRH
      TPF    
Table 5: Headers parsed on non-decapsulating SR segment endpoint nodes, 32-bit SIDs, 48B.0-15T.V
32-bit CSID CRH CRH+TPF VSID UIDSR
PRS(48B.0T.V) IPv6 IPv6 IPv6 IPv6 IPv6
           
PRS(48B.1-15T.V) IPv6 IPv6 IPv6 IPv6 IPv6
  SRH CRH CRH SRH SRH
Table 6: Headers parsed on decapsulating SR segment endpoint nodes, 32-bit SIDs, 48B.0-15T.V
32-bit CSID CRH CRH+TPF VSID UIDSR
PRS(48B.0T.V) IPv6 IPv6 IPv6 IPv6 IPv6
           
PRS(48B.1-15T.V) IPv6 IPv6 IPv6 IPv6 IPv6
  SRH CRH CRH SRH SRH
      TPF    

Conclusion: Overall, the CSID parses the fewest headers. When per packet state is processed per segment, CSID, VSID and UIDSR proposals may include it in the routing header, CRH may include it in a destination option preceding the CRH.

2.2.2. Lookups Performed (LKU)

Some proposals require a different number of lookups per packet, depending on the active segment in a segment list.

An implementation may perform lookups as longest prefix match (LPM) or exact match (EM). CSID, VSID and UIDSR describe SRv6 SID lookup from the IPv6 destination address as an LPM, however an implementation may use either an LPM or EM lookup for SRv6 SIDs. CRH implementations must always uses an exact match for CRH SID lookups.

The following table describes the number of lookups per proposal per segment type.

Table 7: Lookups
  CSID CRH VSID UIDSR
Adjacency and LPM (a) LPM (a) LPM (a) LPM (a)
VPN Segments   EM (b)    
    EM (b,c)    
         
Prefix Segments LPM (a) LPM (a) LPM (a) LPM (a)
  LPM (d) EM (b) LPM (d) LPM (d)
         
  • [a] On active SID, appearing in the IPv6 Destination address
  • [b] On SID in CRH header
  • [c] This lookup is required only when the IPv6 next hop node is not non-CRH aware
  • [d] On next SID, appearing in the IPv6 destination address

Note: [I-D.filsfils-spring-net-pgm-extension-srv6-usid] Section 5 describes an optional local implementation to reduce CSID 16-bit lookups, in some cases, by adding local forwarding state. The analysis of this implementation option is not included in this version of the document.

Conclusion: CSID, VSID, and UIDSR require a single lookup to process an adjacency or VPN segment. CRH always requires 2 lookups for VPN segments, and 2 and sometimes 3 lookups for adjacency segments. All proposals require two lookups to process a prefix segment and the next segment.

2.3. State Efficiency

The compression proposal SHOULD minimize the amount of additional forwarding state stored at a node.

State efficiency is analyzed in a sub-domain of the SR domain, with the following parameters:

  • N: the number of SRv6 nodes in the sub-domain
  • I: the number of IGP algorithms [I-D.ietf-lsr-flex-algo] configured
  • A: the number of local adjacency SIDs at a node
  • D: the number of attached SR sub-domains at a border node
  • V: the number of VPN services at edge nodes

For a sub-domain consisting of:

  • 1000 SRv6 nodes (N=1000) with some number of non-SRv6 nodes
  • 2 IGP algorithms (I=2)
  • 100 adjacencies per SRv6 node (A=100)
  • up to 10 attached sub-domains per border node (D=10)
  • 1000 VPN service segments per edge (V=1000)

The number of forwarding entries at a node is calculated for any node, a border node, and an edge node.

UIDSR, CSID and VSID require the following entries:

  • a FIB entry for the node's prefix segment (1), per algorithm (I=2).
  • a FIB entry per local adjacency SID (A=100) **Note1

  • At border nodes (or any SRv6 nodes) either:

    • A.1) a FIB entry per domain (D=10) to swap the IPv6 destination address prefix.
    • A.2) no additional FIB entries, and the SR source places a 128-bit SID in the segment list of a packet if needed.
  • At edge nodes, a FIB entry per VPN segment (V=1000)

CRH requires:

  • a CFIB entry per CRH node per IGP algorithm for local and remote prefix segments (N*I=2000)

  • a CFIB entry per local adjacency segment (A=100) **Note1

    • When non-CRH adjacent nodes are present, additional state is required for CRH as per [I-D.bonica-6man-comp-rtg-hdr] Appendix B (note, only the second option in the appendix is considered feasible due to state explosion)

      • B.1) Up to one CFIB entry per next endpoint and an additional CFIB entry per adjacency to support non-CRH adjacent endpoints, assuming IP flex algo is not implemented on non-CRH nodes (I=1) ((N+A)*I=1200).

  • At border nodes, assuming two inter-domain links per adjacent domain for redundancy, additional state is required as per [I-D.bonica-6man-comp-rtg-hdr] Appendix B (note, only the second option in the appendix is considered feasible due to state explosion):

    • C.1) In a common CRH network topology, the remote sub-domain borders support CRH: a CFIB entry per CRH node per IGP algorithm for local and remote prefix segments (N*I) plus a CFIB entry per local adjacency segment (A) plus a CFIB entry per connected remote border router (20) (N*I+A+20=2120).
    • C.2) In a poorly designed CRH network topology, the remote sub-domain borders do not support CRH: a CFIB entry per unique endpoint (N*D*I), plus a CFIB entry per local adjacency segment (A), assuming IP flex algo is not implemented on non-CRH border domain (I=1), plus inter-domain adjacency (20) (N*D*I+2=10120).
  • At edge nodes, V=1000 entries for SRv6 based VPN SIDs and another V=1000 entries for CFIB and TPF VPN SIDs.

**Note1: there may be additional adjacency SIDs for protected, unprotected, and per algorithm adjacencies, resulting in some multiple of A. This is common for all compression proposals.

Table 8: Forwarding State Maintained
16-bit and 32-bit CSID CRH VSID UIDSR
S(N1000,I2,A100,D10) 102 2100 102 102
  A.1:112   A.1:112 A.1:112
  A.2:102   A.2:102 A.2:102
    B.1:3300    
    C.1:2120    
    C.2:10120    
         
S(V1000) 1000 2000 1000 1000

Conclusion: CSID, VSID and UIDSR minimize forwarding state stored at a node. CRH moves per segment state from the packet to the FIB.

3. SRv6 Specific Requirements

3.1. SRv6 Based

A solution to compress SRv6 SID Lists SHOULD be based on the SRv6 architecture, control plane and data plane. The compression solution MAY be based on a different data plane and control plane, provided that it derives sufficient benefit.

This section records the use of SRv6 standards for compression.

Table 9: SRv6 Based
  CSID CRH VSID UIDSR
U.RFC8402 Yes Yes - update required for SRv6 data plane Yes Yes
U.RFC8754 Yes No Yes - update required for segments left Yes - update for flags and segments left
U.PGM Yes No Yes - update required for SID behaviors Yes
U.IGP Yes No Yes Yes - additional extensions
U.BGP Yes No Yes Yes
U.POL Yes No Yes Yes
U.BLS Yes No Yes Yes - additional extensions
U.SVC Yes No Yes Yes
U.ALG Yes Yes - Adds IP flex Algo Yes Yes
U.OAM Yes No Yes Yes

Conclusion: CSID is SRv6 based, requiring no updates to existing SRv6 standards, VSID and UIDSR require updates. CRH is not strictly based on SRv6 but is able to provide equivalent functionality.

3.2. Functional Requirements

3.2.1. SRv6 Functionality

A solution to compress an SRv6 SID list MUST support the functionality of SRv6. This requirement ensures no SRv6 functionality is lost. It is particularly important to understand how a proposal, as evaluated in section "SRv6 Based", provides this functionality.

Functional requirements and the drafts defining how a proposal provides the functionality are documented in the table below.

Table 10: Abbreviations
Draft reference Abbreviations
RFC8986: [RFC8986]
SRV6POL: [I-D.ietf-spring-segment-routing-policy]
SRV6EXT: [I-D.ietf-lsr-isis-srv6-extensions]
SRV6BGPSVC: [I-D.ietf-bess-srv6-services]
SRV6BGPLS: [I-D.ietf-idr-bgpls-srv6-ext]
SRV6SVCP: [I-D.ietf-spring-sr-service-programming]
SRV6OAM: [I-D.ietf-6man-spring-srv6-oam]
SRV6FLEXALG: [I-D.ietf-lsr-flex-algo]
SRV6TILFA: [I-D.ietf-rtgwg-segment-routing-ti-lfa]
RFC8402: [RFC8402]
RFC8754: [RFC8754]
CRH: [I-D.bonica-6man-comp-rtg-hdr]
VSID: [I-D.decraene-spring-srv6-vlsid]
UIDSR: [I-D.mirsky-6man-unified-id-sr]
IPFLEXALG: [I-D.ietf-lsr-ip-flexalgo]
CRHEXT: [I-D.bonica-lsr-crh-isis-extensions]
SRM6BGPSVC: [I-D.ssangli-bess-bgp-vpn-srm6]
CSID: [I-D.filsfilscheng-spring-srv6-srh-comp-sl-enc]
Table 11: SRv6 Functionality
  CSID CRH VSID UIDSR
F.SID RFC8402 CRH RFC8402 RFC8402 1
F.Scope RFC8402 CRH RFC8402 RFC8402 1
F.PFX RFC8402, RFC8986, CSID adds an END SID flavor CRH RFC8402, RFC8986, VSID updates the End behavior RFC8402, RFC8986 with new flavor 1
F.ADJ RFC8402, RFC8986, CSID adds an END.X flavor CRH RFC8402, RFC8986, VSID updates the End.X behavior RFC8402, RFC8986 with new flavor 1
F.BIND RFC8402, RFC8986 CRH RFC8402, RFC8986, VSID updates the End.B behaviors RFC8402, RFC8986 with new flavor 1
F.PEER RFC8402, RFC8986, CSID adds an END.X. flavor CRH RFC8402, RFC8986, VSID updates the End.X behaviors RFC8402, RFC8986 with new flavor 1,2
F.SVC RFC8986 CRH RFC8986, VSID updates the service segment behaviors RFC8986 1
F.ALG SRV6FLEXALG IPFLEXALG SRV6FLEXALG SRV6FLEXALG
F.TILFA SRV6TILFA SRV6TILFA SRV6TILFA SRV6TILFA 3
F.SEC RFC8754 CRH RFC8754 RFC8754
F.IGP SRV6EXT CRH-EXT SRV6EXT SRV6EXT 1,4
F.BGP SRV6BGPSVC SRM6BGPSVC SRV6BGPSVC SRV6BGPSVC 1
F.POL SRV6SRPOL SRV6SRPOL update required SRV6SRPOL SRV6SRPOL
F.BLS SRV6BGPLS (specification required) SRV6BGPLS and addition for VSID Length SRV6BGPLS 5
F.SFC SRV6SVCP CRH SRV6SVC SRV6SVCP 1
F.PING SRV6OAM CRH SRV6OAM SRv6OAM
  1. UIDSR with Global Container SID + local index enhancement
  2. draft-peng-spring-truncates-sid-inter-domain
  3. For protections described in section 6.1.2.1, 6.1.2.2, and 6.2, to get next-next SID from SRH with the help of draft-pl-spring-compr-path-recover.
  4. Need more extensions to advertise the capability of U-SID compression (32bits, 16bits, etc.). Note: Global Container SID + local index enhancement.
  5. IGP extensions

Conclusion: CSID supports SRv6 functionality. CRH VSID and UID support SRv6 functionality or equivalent with some new specifications.

3.2.2. Heterogeneous SID Lists

The compression proposal SHOULD support a combination of compressed and non-compressed segments in a single path. As an example, a solution may satisfy this requirement without being SRv6 based by using a binding SID to impose an additional SRv6 header (IPv6 header plus optional SRH) with non-compressed SID.

Table 12: Heterogeneous SID Lists
  CSID CRH VSID UIDSR
Heterogeneous SID Lists Yes Yes Yes Yes

VSID require a binding SID with an additional SRv6 encapsulation to encode non-compressed segments in a single path. VSID changes the interpretation of the SRH Segments Left field, which makes it capable of carrying only compressed segments.

The CRH can include a binding SID that imposes a new IPv6 header with an SRH. This is required when the next segment endpoint in the path can process the SRH, but not the CRH. The next segment endpoint or a subsequent endpoint can execute decapsulation, removing the new IPv6 header and exposing the old one with its CRH. This is required because an IPv6 packet can carry only one routing header.

CSID and UIDSR permit the encoding of, and processing of, any combination of compressed or non-compressed segments in a segment list of an SRH.

CSID makes use of the SRH, without modification, to encode CSIDs as 128 bits, supporting the use of non-compressed segments within the SRH.

UIDSR modifies the interpretation of the SRH Segments Left field at segment endpoint nodes to allow variable segment lengths within a segment list.

Conclusion: All proposals support heterogeneous SID lists. CSID and UIDSR support heterogeneous SID lists in the SRH, while CRH and VSID require installation of binding SIDs at midpoint nodes.

3.2.3. SID List Length

The compression proposal MUST be able to represent SR paths that contain up to 16 segments.

Table 13: SID List Length
  CSID CRH VSID UIDSR
16 Segments Yes Yes Yes Yes

Conclusion: All proposals support segment lists of at least 16 segments.

3.2.4. SID Summarization

The solution MUST be compatible with segment summarization.

In inter sub-domain deployments with summarization:

  • Any node can reach any other node in another sub-domain via a prefix segment.
  • Prefixes are summarized for advertisement between domains.

Without summarization, border router SIDs must be leaked:

  • An additional global prefix segment is required for each domain border to be traversed.
Table 14: SID Summarization
  CSID CRH VSID UIDSR
SID Summarization Yes No Yes Yes

Conclusion: CSID, VSID and UIDSR support segment summarization, CRH does not.

3.3. Operational Requirements

3.3.1. Lossless Compression

A path traversed using a compressed SID list MUST always be the same as the path traversed using the uncompressed SID list if no compression was applied.

Table 15: Lossless Compression
  CSID CRH VSID UIDSR
Lossless Compression Yes Yes Yes Yes

Conclusion: All proposals provide lossless compression.

3.3.2. Preservation of non-routing information

The compression mechanism MUST NOT cause the loss of non-routing information when delivering a packet from the SR ingress node to the egress/penultimate SR node

Table 16: Preservation of non-routing information
  CSID CRH VSID UIDSR
Preserves Non-Routing Information Complies Complies Complies Complies

Conclusion: All proposals preserve non-routing information.

3.3.3. Address Planning

Description: Network operators require addressing plan flexibility, The compression mechanism MUST support flexible IPv6 address planning, it MUST support deployment by using GUA from different address blocks.

Table 17: Address Planning
  CSID CRH VSID UIDSR
Flexible Address Planning Yes Yes Yes Yes

All compression mechanisms provide the encapsulation savings described in Tables 1 and 2. CRH provides these encapsulation savings regardless of the IPv6 addressing scheme. CSID adds a CSID container, or one compressed SID (END.X with XPS behavior), for each change in locator block in a segment list. VSID (via XPS behavior) and UIDSR add one compressed SID for each change in locator block in the segment list.

The XPS behavior draws the new address block from the control plane. At the time of publication, this control plane behavior is undefined. Therefore XPS impact on the control plane is not entirely understood. While it may be possible to define these mechanisms without impacting the control plane, specifications are not yet available.

Conclusion: All proposals support flexible IPv6 planning.

3.4. Scalability Requirements

The compression proposal MUST be capable of representing 65000 adjacency segments per node.

The compression proposal MUST be capable of representing 1 million prefix segments per SID numbering space.

The compression proposal MUST be capable of representing 1 million services per node.

Table 18: Scale Requirements
  CSID CRH VSID UIDSR
Adjacency Segment Scale 65000 Yes Yes Yes Yes
Prefix Segment Scale 1000000 Yes Yes Yes Yes
Service Scale 1000000 Yes Yes Yes Yes

The 32-bit variants of all proposals support this scale of prefix, adjacency and services at a node.

Each proposals 16-bit variant supports a lesser scale. All proposals can encode 2^16 prefix, adjacency and service segments. However, each proposal has various ways of supporting some larger scale per node if required.

CRH 16-bit proposes the encoding of the ultimate segment in a TPF destination option instead of the CRH. This supports 2^32 service segments per node.

VSID proposes the combination of multiple vSIDs, by copying multiple SIDs to a destination address or looking up the next segment in the segment list. This supports more than 2^16 adjacency and service segments per node.

CSID 16-bit variant uses a LIB for adjacency and service segments, the LIB allows local definition of SIDs longer than 16-bits when needed. This supports more than 2^16 adjacency and service segments per node.

UIDSR defines a segment type that modifies the value of SRH segments left field to support variable segment sizes within the segment list. This supports 2^32 adjacency and service segments per node.

Conclusion: All proposals meet scalability requirements.

3.4.1. Compression Levels

The compression proposal SHOULD be able to support multiple levels of compression.

Table 19: Compression Levels
  CSID CRH VSID UIDSR
Multiple compression Levels Yes Yes Yes Yes

Conclusion: All proposals support 16-bit and 32-bit SID variants.

4. Protocol Design Requirements

4.1. SRv6 Base Coexistence

The compression proposal MUST support deployment in SRv6 networks.

Table 20: SRv6 Base Coexistence
  CSID CRH VSID UIDSR
SRv6 Base Coexistence Yes Yes Yes Yes

Conclusion: All proposals can be deployed simultaneously with the SRv6 base solution.

5. Security Requirements

5.1. Security Mechanisms

The compression solution SHOULD be able to address security issues that it introduces, using existing security mechanisms.

Table 21: Security Mechanisms
  CSID CRH VSID UIDSR
Security Mechanisms Yes Yes Yes Yes

Conclusion: All proposals address security issues they may introduce with existing security mechanisms.

5.2. SR Domain Protection

A compression solution must not require nodes outside the SR domain to know SID values within the SR domain, and it must provide the ability to block nodes outside an SR domain from accessing SIDS.

Table 22: SR Domain Protection
  CSID CRH VSID UIDSR
SR Domain Protection Yes Yes Yes Yes

Conclusion: All proposals protect SIDs within the SR domain.

6. Conclusions

Encapsulation Header Size

Forwarding Efficiency

State Efficiency

SRv6 Based

SRv6 Functionality

Heterogeneous SID lists

SID List Length

SID Summarization

Operational Requirements

Scalability Requirements

Protocol Design Requirements

Security Requirements

7. Normative References

[I-D.bonica-6man-comp-rtg-hdr]
Bonica, R., Kamite, Y., Alston, A., Henriques, D., and L. Jalil, "The IPv6 Compact Routing Header (CRH)", Work in Progress, Internet-Draft, draft-bonica-6man-comp-rtg-hdr-28, , <https://www.ietf.org/archive/id/draft-bonica-6man-comp-rtg-hdr-28.txt>.
[I-D.bonica-6man-vpn-dest-opt]
Bonica, R., Kamite, Y., Jalil, L., Zhou, Y., and G. Chen, "The IPv6 Tunnel Payload Forwarding (TPF) Option", Work in Progress, Internet-Draft, draft-bonica-6man-vpn-dest-opt-18, , <https://www.ietf.org/archive/id/draft-bonica-6man-vpn-dest-opt-18.txt>.
[I-D.bonica-lsr-crh-isis-extensions]
Kaneriya, P., Shetty, R., Hegde, S., and R. Bonica, "IS-IS Extensions To Support The IPv6 Compressed Routing Header (CRH)", Work in Progress, Internet-Draft, draft-bonica-lsr-crh-isis-extensions-06, , <https://www.ietf.org/archive/id/draft-bonica-lsr-crh-isis-extensions-06.txt>.
[I-D.cl-spring-generalized-srv6-for-cmpr]
(editor), W. C., Li, Z., (editor), C. L., Clad, F., Liu, A., Xie, C., Liu, Y., and S. Zadok, "Generalized SRv6 Network Programming for SRv6 Compression", Work in Progress, Internet-Draft, draft-cl-spring-generalized-srv6-for-cmpr-05, , <https://www.ietf.org/archive/id/draft-cl-spring-generalized-srv6-for-cmpr-05.txt>.
[I-D.decraene-spring-srv6-vlsid]
Decraene, B., Raszuk, R., Li, Z., and C. Li, "SRv6 vSID: Network Programming extension for variable length SIDs", Work in Progress, Internet-Draft, draft-decraene-spring-srv6-vlsid-07, , <https://www.ietf.org/archive/id/draft-decraene-spring-srv6-vlsid-07.txt>.
[I-D.filsfils-spring-net-pgm-extension-srv6-usid]
Filsfils, C., Garvia, P. C., Cai, D., Voyer, D., Meilik, I., Patel, K., Henderickx, W., Jonnalagadda, P., Melman, D., Liu, Y., and J. Guichard, "Network Programming extension: SRv6 uSID instruction", Work in Progress, Internet-Draft, draft-filsfils-spring-net-pgm-extension-srv6-usid-13, , <https://www.ietf.org/archive/id/draft-filsfils-spring-net-pgm-extension-srv6-usid-13.txt>.
[I-D.filsfilscheng-spring-srv6-srh-comp-sl-enc]
Cheng, W., Filsfils, C., Li, Z., Cai, D., Voyer, D., Clad, F., Zadok, S., Guichard, J. N., and L. Aihua, "Compressed SRv6 Segment List Encoding in SRH", Work in Progress, Internet-Draft, draft-filsfilscheng-spring-srv6-srh-comp-sl-enc-03, , <https://www.ietf.org/archive/id/draft-filsfilscheng-spring-srv6-srh-comp-sl-enc-03.txt>.
[I-D.ietf-6man-spring-srv6-oam]
Ali, Z., Filsfils, C., Matsushima, S., Voyer, D., and M. Chen, "Operations, Administration, and Maintenance (OAM) in Segment Routing Networks with IPv6 Data plane (SRv6)", Work in Progress, Internet-Draft, draft-ietf-6man-spring-srv6-oam-13, , <https://www.ietf.org/archive/id/draft-ietf-6man-spring-srv6-oam-13.txt>.
[I-D.ietf-bess-srv6-services]
Dawra, G., Talaulikar, K., Raszuk, R., Decraene, B., Zhuang, S., and J. Rabadan, "SRv6 BGP based Overlay Services", Work in Progress, Internet-Draft, draft-ietf-bess-srv6-services-15, , <https://www.ietf.org/archive/id/draft-ietf-bess-srv6-services-15.txt>.
[I-D.ietf-idr-bgpls-srv6-ext]
Dawra, G., Filsfils, C., Talaulikar, K., Chen, M., Bernier, D., and B. Decraene, "BGP Link State Extensions for SRv6", Work in Progress, Internet-Draft, draft-ietf-idr-bgpls-srv6-ext-09, , <https://www.ietf.org/archive/id/draft-ietf-idr-bgpls-srv6-ext-09.txt>.
[I-D.ietf-lsr-flex-algo]
Psenak, P., Hegde, S., Filsfils, C., Talaulikar, K., and A. Gulko, "IGP Flexible Algorithm", Work in Progress, Internet-Draft, draft-ietf-lsr-flex-algo-23, , <https://www.ietf.org/archive/id/draft-ietf-lsr-flex-algo-23.txt>.
[I-D.ietf-lsr-ip-flexalgo]
Britto, W., Hegde, S., Kaneriya, P., Shetty, R., Bonica, R., and P. Psenak, "IGP Flexible Algorithms (Flex-Algorithm) In IP Networks", Work in Progress, Internet-Draft, draft-ietf-lsr-ip-flexalgo-06, , <https://www.ietf.org/archive/id/draft-ietf-lsr-ip-flexalgo-06.txt>.
[I-D.ietf-lsr-isis-srv6-extensions]
Psenak, P., Filsfils, C., Bashandy, A., Decraene, B., and Z. Hu, "IS-IS Extensions to Support Segment Routing over IPv6 Dataplane", Work in Progress, Internet-Draft, draft-ietf-lsr-isis-srv6-extensions-18, , <https://www.ietf.org/archive/id/draft-ietf-lsr-isis-srv6-extensions-18.txt>.
[I-D.ietf-rtgwg-segment-routing-ti-lfa]
Litkowski, S., Bashandy, A., Filsfils, C., Francois, P., Decraene, B., and D. Voyer, "Topology Independent Fast Reroute using Segment Routing", Work in Progress, Internet-Draft, draft-ietf-rtgwg-segment-routing-ti-lfa-08, , <https://www.ietf.org/archive/id/draft-ietf-rtgwg-segment-routing-ti-lfa-08.txt>.
[I-D.ietf-spring-segment-routing-policy]
Filsfils, C., Talaulikar, K., Voyer, D., Bogdanov, A., and P. Mattes, "Segment Routing Policy Architecture", Work in Progress, Internet-Draft, draft-ietf-spring-segment-routing-policy-22, , <https://www.ietf.org/archive/id/draft-ietf-spring-segment-routing-policy-22.txt>.
[I-D.ietf-spring-sr-service-programming]
Clad, F., Xu, X., Filsfils, C., Bernier, D., Li, C., Decraene, B., Ma, S., Yadlapalli, C., Henderickx, W., and S. Salsano, "Service Programming with Segment Routing", Work in Progress, Internet-Draft, draft-ietf-spring-sr-service-programming-06, , <https://www.ietf.org/archive/id/draft-ietf-spring-sr-service-programming-06.txt>.
[I-D.mirsky-6man-unified-id-sr]
Weiqiang, C., Mirsky, G., Shaofu, P., Aihua, L., and G. S. Mishra, "Unified Identifier in IPv6 Segment Routing Networks", Work in Progress, Internet-Draft, draft-mirsky-6man-unified-id-sr-10, , <https://www.ietf.org/archive/id/draft-mirsky-6man-unified-id-sr-10.txt>.
[I-D.srcompdt-spring-compression-requirement]
Cheng, W., Xie, C., Bonica, R., Dukes, D., Li, C., Shaofu, P., and W. Henderickx, "Compressed SRv6 SID List Requirements", Work in Progress, Internet-Draft, draft-srcompdt-spring-compression-requirement-07, , <https://www.ietf.org/archive/id/draft-srcompdt-spring-compression-requirement-07.txt>.
[I-D.ssangli-bess-bgp-vpn-srm6]
Sangli, S. and R. Bonica, "BGP based Virtual Private Network (VPN) Services over SRm6 enabled IPv6 networks", Work in Progress, Internet-Draft, draft-ssangli-bess-bgp-vpn-srm6-02, , <https://www.ietf.org/archive/id/draft-ssangli-bess-bgp-vpn-srm6-02.txt>.
[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, , <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, , <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, , <https://www.rfc-editor.org/info/rfc8986>.

Appendix A. Encapsulation analysis

A.1. CRH note

CRH compression efficiency statistics are derived as follows:

If an SR path contains no transport segments and a VPN segment, the SR path is encoded in a single IPv6 header (40 bytes). The destination address in the IPv6 header is a classic SRv6 SID (e.g., END.DT4, END.DT6).

If the SR path contains T transport segments and a VPN segment, and T is greater than 0, the SR path can be encoded:

If the SR path is encoded with a TPF Option, the packet includes a single IPv6 Header (40 bytes), a CRH (variable length), and a Destination Options header (8 bytes). The destination address in the IPv6 header represents the IPv6 address of an interface on the first transport segment endpoint. The CRH must be large enough to contain the subsequent T segments.

If the SR path is encoded without a TPF Option, the packet includes a single IPv6 Header (40 bytes) plus a CRH (variable length). The destination address in the IPv6 header represents the IPv6 address of an interface on the first transport segment endpoin . The CRH must be large enough to contain T+1 segments. In the CRH, SID[1] maps to the IPv6 address of the PE router. SID[0] maps to a classic SRv6 SID (e.g., END.DT4) that is instantiated on the PE router.

In some deployment scenarios, each encoding strategy yields better compression.

A.2. Analysis results

The detailed encapsulation and encapsulation savings per proposal with one VPN segment and "T" transport segments:

Table 23: Encapsulation (E) octets, 16bit SIDS, 48B.0-15T.V
T CSID CRH CRH+TPF VSID UIDSR
0 40 40 40 40 40
1 40 48 56 56 64
2 40 56 56 56 64
3 40 56 64 56 64
4 64 56 64 64 64
5 64 56 64 64 64
6 64 64 64 64 64
7 64 64 72 64 64
8 64 64 72 72 64
9 80 64 72 72 80
10 80 72 72 72 80
11 80 72 80 72 80
12 80 72 80 80 80
13 80 72 80 80 80
14 96 80 80 80 80
15 96 80 88 80 80
Table 24: Encapsulation Savings (ES), 16bit SIDS, 48B.0-15T.V
T CSID CRH CRH+TPF VSID UIDSR
0 0.0% 0.0% 0.0% 0.0% 0.0%
1 37.5% 25.0% 12.5% 12.5% 0.0%
2 50.0% 30.0% 30.0% 30.0% 20.0%
3 58.3% 41.7% 33.3% 41.7% 33.3%
4 42.9% 50.0% 42.9% 42.9% 42.9%
5 50.0% 56.3% 50.0% 50.0% 50.0%
6 55.6% 55.6% 55.6% 55.6% 55.6%
7 60.0% 60.0% 55.0% 60.0% 60.0%
8 63.6% 63.6% 59.1% 59.1% 63.6%
9 58.3% 66.7% 62.5% 62.5% 58.3%
10 61.5% 65.4% 65.4% 65.4% 61.5%
11 64.3% 67.9% 64.3% 67.9% 64.3%
12 66.7% 70.0% 66.7% 66.7% 66.7%
13 68.8% 71.9% 68.8% 68.8% 68.8%
14 64.7% 70.6% 70.6% 70.6% 70.6%
15 66.7% 72.2% 69.4% 72.2% 72.2%
Table 25: Encapsulation (E) octets, 32bit SIDS, 48B.0-15T.V
T CSID CRH CRH+TPF VSID UIDSR
0 40 40 40 40 40
1 64 56 56 56 64
2 64 56 64 56 64
3 64 64 64 64 64
4 64 64 72 64 64
5 80 72 72 72 80
6 80 72 80 72 80
7 80 80 80 80 80
8 80 80 88 80 80
9 96 88 88 88 96
10 96 88 96 88 96
11 96 96 96 96 96
12 96 96 104 96 96
13 112 104 104 104 112
14 112 104 112 104 112
15 112 112 112 112 112
Table 26: Encapsulation Savings (ES), 32bit SIDS, 48B.0-15T.V
T CSID CRH CRH+TPF VSID UIDSR
0 0.0% 0.0% 0.0% 0.0% 0.0%
1 0.0% 12.5% 12.5% 12.5% 0.0%
2 20.0% 30.0% 20.0% 30.0% 20.0%
3 33.3% 33.3% 33.3% 33.3% 33.3%
4 42.9% 42.9% 35.7% 42.9% 42.9%
5 37.5% 43.8% 43.8% 43.8% 37.5%
6 44.4% 50.0% 44.4% 50.0% 44.4%
7 50.0% 50.0% 50.0% 50.0% 50.0%
8 54.5% 54.5% 50.0% 54.5% 54.5%
9 50.0% 54.2% 54.2% 54.2% 50.0%
10 53.8% 57.7% 53.8% 57.7% 53.8%
11 57.1% 57.1% 57.1% 57.1% 57.1%
12 60.0% 60.0% 56.7% 60.0% 60.0%
13 56.3% 59.4% 59.4% 59.4% 56.3%
14 58.8% 61.8% 58.8% 61.8% 58.8%
15 61.1% 61.1% 61.1% 61.1% 61.1%

Authors' Addresses

Ron Bonica
Juniper
Weiqiang Cheng
China Mobile
Darren Dukes (editor)
Cisco Systems
Wim Henderickx
Nokia
Cheng Li
Huawei
Peng Shaofu
ZTE
Chongfeng Xie
China Telecom