Re: [spring] Beyond SRv6.

+1

The value in using a commodity protocol like RFC 8200 compliant IPv6
for something like SR is that you're gaining from IPv6 being well
understood, widely implemented, widely deployed, widely interoperable,
widely tested, and the major bugs have very likely already been
discovered. It's cheaper to use something that it is already widely in
use.

However, if you then try to stretch or go beyond expected use and
semantics, and violate protocol definitions, you're decommodifying the
commodity. You've lost significant or all of the value of using the
commodity protocol in the first place.

On Sun, 1 Sep 2019 at 06:34, Ron Bonica
<rbonica=40juniper.net@dmarc.ietf.org> wrote:
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> Rob,
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> The following are arguments for proceeding with SRv6+:
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> Efficient forwarding with deep SID lists
> Operational Simplicity
> SRv6+ work may finish before SRv6
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> Efficient forwarding with deep SID Lists
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> ----------------------------------------------------
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> SR customers have stated a firm requirement to support SR paths that contain 8 to 12 segments. They have also stated a requirement for implementations to forward at line speed  and without consuming excessive overhead bandwidth.
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> SRv6, as defined in draft-ietf-6man-segment-routing-header, cannot satisfy these requirements. In order to support an SR path with 8 segments, SRv6 would require a 128-byte SRH. Even if ASICs could process such a long SRH at line speed, the bandwidth overhead would be prohibitive.
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> Therefore, one of the four solutions  that you mention below is required to make SRv6 deployable. While draft-ietf-6man-segment-routing-header is close to maturity, the four competing solutions mentioned below are equally mature and should be given equal consideration.
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> The four solutions are SRv6+, uSID, draft-li and draft-mirsky.
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> Operational Simplicity
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> -----------------------------
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> Network operators strive for operational simplicity. By loosely interpreting (and sometimes bending) the requirements of RFCs 4291 and RFC 8200, SRv6 introduces architectural quirks that introduce operational complexity. The following are architectural quirks of  draft-ietf-6man-segment-routing-header:
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> The Segment Routing Header (SRH) serves purposes other than routing. Therefore, the SRH is sometimes required for packets that traverse the least-cost path from source to destination
> The SRH and the IPv6 Authentication Header are incompatible.
> The IPv6 destination address determines whether an SRH is valid and how it is processed. For example, if the IPv6 destination address contains one locally instantiated value, the SRH might be processed in one particular way, while if the IPv6 destination address contains another locally instantiated value, the SRH might be totally invalid.
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> Draft-ietf-spring-srv6-network-programming  promises more architectural quirks. For example:
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> Segment endpoints can insert and/or delete IPv6 extension headers
> An IPv6 packet can contain two Segment Routing headers
> IPv6 packets are no longer self-describing. For example, the Next Header Field in the SRH can carry a value of No Next Header, even though the SRH is followed by Ethernet payload.
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> Other emerging drafts promise still more architectural quirks. For example, in draft-ali-6man-spring-srv6-oam, implementations need to examine the SRH even when Segment Left equals zero. This is because the SRH has been overloaded to carry OAM as well as routing information.
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> Furthermore, draft-filsfils-spring-net-pgm-extension-srv6-usid requires network operators to obtain address space and number their networks in a particular way to make routing work.
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> SRv6+ Work May Finish Before SRv6 work
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> --------------------------------------------------------
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> SRv6+  has been implemented on LINUX and is being implemented on JUNOS. Implementation experience demonstrates that specification is fairly complete. For example, there is no need for an SRv6+ OAM document. It’s just IPv6 and IPv6 OAM just works.
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> Furthermore, the SRv6+ specifications adhere to a strict interpretation of RFC 8200. Therefore, as they progress through the working group, they won’t need to overcome the objections that are inevitably encountered when stretching the interpretation of a specification that is so fundamental as RFC 8200.
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>                                                                                                       Thanks,
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>                                                                                                           Ron
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> From: spring <spring-bounces@ietf.org> On Behalf Of Rob Shakir
> Sent: Sunday, August 4, 2019 5:04 PM
> To: SPRING WG List <spring@ietf.org>
> Subject: [spring] Beyond SRv6.
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> Hi SPRING WG,
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> Over the last 5+ years, the IETF has developed Source Packet Routing in NetworkinG (SPRING) aka Segment Routing for both the MPLS (SR-MPLS) and IPv6 (SRv6) data planes. SR-MPLS may also be transported over IP in UDP or GRE.
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> These encapsulations are past WG last call (in IESG or RFC Editor).
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> During the SPRING WG meeting at IETF 105, two presentations were related to the reduction of the size of the SID for IPv6 dataplane:
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> SRv6+ / CRH -- https://tools.ietf.org/html/draft-bonica-spring-srv6-plus-04
> uSID -- https://tools.ietf.org/html/draft-filsfils-spring-net-pgm-extension-srv6-usid-01
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> During the IETF week, two additional drafts have been proposed:
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> https://tools.ietf.org/html/draft-li-spring-compressed-srv6-np-00
> https://tools.ietf.org/html/draft-mirsky-6man-unified-id-sr-03
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> As we expressed during the meeting, it is important for the WG to understand what the aims of additional encapsulations are. Thus, we think it is important that the WG should first get to a common understanding on the requirements for a new IPv6 data plane with a smaller SID - both from the perspective of operators that are looking to deploy these technologies, and from that of the software/hardware implementation.
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> Therefore, we would like to solicit network operators interested in SR over the IPv6 data plane to briefly introduce their:
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> use case (e.g. Fast Reroute, explicit routing/TE)
> forwarding performance and scaling requirements
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> e.g., (number of nodes, network diameter, number of SID required in max and average). For the latter, if possible using both SRv6 128-bit SIDs and shorter (e.g. 32-bit) SIDs as the number would typically be different (*).
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> if the existing SRv6 approach is not deployable in their circumstances, details of the requirement of a different solution is required and whether this solution is needed for the short term only or for the long term.
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> As well as deployment limitations, we would like the SPRING community to briefly describe the platform limitations that they are seeing which limit the deployment of SRv6  In particular limitations related to the number of SIDs which can be pushed and forwarded and how much the use of shorter SIDs would improve the deployments .
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> For both of these sets of feedback if possible, please post this to the SPRING WG. If the information cannot be shared publicly, please send it directly to the chairs & AD (Martin).
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> This call for information will run for four weeks, up to 2019/09/03. As a reminder, you can reach the SPRING chairs via spring-chairs@ietf.org and ADs via spring-ads@ietf.org.
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> Thank you,
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> -- Rob & Bruno
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> (*) As expressed on the mailing list, a 128 bit SID can encode two instructions a node SID and an adjacency SID hence less SID may be required.
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> Juniper Business Use Only
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