rfc9689.original | rfc9689.txt | |||
---|---|---|---|---|
TEAS Working Group Z. Li | Internet Engineering Task Force (IETF) Z. Li | |||
Internet-Draft D. Dhody | Request for Comments: 9689 D. Dhody | |||
Intended status: Informational Huawei Technologies | Category: Informational Huawei Technologies | |||
Expires: 2 December 2024 Q. Zhao | ISSN: 2070-1721 Q. Zhao | |||
Etheric Networks | Etheric Networks | |||
K. He | K. He | |||
Tencent Holdings Ltd. | Tencent Holdings Ltd. | |||
B. Khasanov | B. Khasanov | |||
Yandex LLC | MTS Web Services (MWS) | |||
31 May 2024 | November 2024 | |||
Use Cases for a PCE as a Central Controller (PCECC) | Use Cases for a PCE as a Central Controller (PCECC) | |||
draft-ietf-teas-pcecc-use-cases-18 | ||||
Abstract | Abstract | |||
The PCE is a core component of a Software-Defined Networking (SDN) | The PCE is a core component of a Software-Defined Networking (SDN) | |||
system. It can be used to compute optimal paths for network traffic | system. It can be used to compute optimal paths for network traffic | |||
and update existing paths to reflect changes in the network or | and update existing paths to reflect changes in the network or | |||
traffic demands. PCE was developed to derive traffic-engineered | traffic demands. The PCE was developed to derive Traffic Engineering | |||
paths in MPLS networks, which are supplied to the head end of the | (TE) paths in MPLS networks, which are supplied to the headend of the | |||
paths using the Path Computation Element Communication Protocol | paths using the Path Computation Element Communication Protocol | |||
(PCEP). | (PCEP). | |||
SDN has much broader applicability than signaled MPLS traffic- | SDN has much broader applicability than signalled MPLS TE networks, | |||
engineered (TE) networks, and the PCE may be used to determine paths | and the PCE may be used to determine paths in a range of use cases | |||
in a range of use cases including static LSPs, Segment Routing (SR), | including static Label-Switched Paths (LSPs), Segment Routing (SR), | |||
Service Function Chaining (SFC), and most forms of a routed or | Service Function Chaining (SFC), and most forms of a routed or | |||
switched network. It is, therefore, reasonable to consider PCEP as a | switched network. Therefore, it is reasonable to consider PCEP as a | |||
control protocol for use in these environments to allow the PCE to be | control protocol for use in these environments to allow the PCE to be | |||
fully enabled as a central controller. | fully enabled as a central controller. | |||
A PCE as a Central Controller (PCECC) can simplify the processing of | A PCE as a Central Controller (PCECC) can simplify the processing of | |||
a distributed control plane by blending it with elements of SDN | a distributed control plane by blending it with elements of SDN | |||
without necessarily completely replacing it. This document describes | without necessarily completely replacing it. This document describes | |||
general considerations for PCECC deployment and examines its | general considerations for PCECC deployment and examines its | |||
applicability and benefits, as well as its challenges and | applicability and benefits, as well as its challenges and | |||
limitations, through a number of use cases. PCEP extensions which | limitations, through a number of use cases. PCEP extensions, which | |||
are required for the PCECC use cases are covered in separate | are required for the PCECC use cases, are covered in separate | |||
documents. | documents. | |||
Status of This Memo | Status of This Memo | |||
This Internet-Draft is submitted in full conformance with the | This document is not an Internet Standards Track specification; it is | |||
provisions of BCP 78 and BCP 79. | published for informational purposes. | |||
Internet-Drafts are working documents of the Internet Engineering | ||||
Task Force (IETF). Note that other groups may also distribute | ||||
working documents as Internet-Drafts. The list of current Internet- | ||||
Drafts is at https://datatracker.ietf.org/drafts/current/. | ||||
Internet-Drafts are draft documents valid for a maximum of six months | This document is a product of the Internet Engineering Task Force | |||
and may be updated, replaced, or obsoleted by other documents at any | (IETF). It represents the consensus of the IETF community. It has | |||
time. It is inappropriate to use Internet-Drafts as reference | received public review and has been approved for publication by the | |||
material or to cite them other than as "work in progress." | Internet Engineering Steering Group (IESG). Not all documents | |||
approved by the IESG are candidates for any level of Internet | ||||
Standard; see Section 2 of RFC 7841. | ||||
This Internet-Draft will expire on 2 December 2024. | Information about the current status of this document, any errata, | |||
and how to provide feedback on it may be obtained at | ||||
https://www.rfc-editor.org/info/rfc9689. | ||||
Copyright Notice | Copyright Notice | |||
Copyright (c) 2024 IETF Trust and the persons identified as the | Copyright (c) 2024 IETF Trust and the persons identified as the | |||
document authors. All rights reserved. | document authors. All rights reserved. | |||
This document is subject to BCP 78 and the IETF Trust's Legal | This document is subject to BCP 78 and the IETF Trust's Legal | |||
Provisions Relating to IETF Documents (https://trustee.ietf.org/ | Provisions Relating to IETF Documents | |||
license-info) in effect on the date of publication of this document. | (https://trustee.ietf.org/license-info) in effect on the date of | |||
Please review these documents carefully, as they describe your rights | publication of this document. Please review these documents | |||
and restrictions with respect to this document. Code Components | carefully, as they describe your rights and restrictions with respect | |||
extracted from this document must include Revised BSD License text as | to this document. Code Components extracted from this document must | |||
described in Section 4.e of the Trust Legal Provisions and are | include Revised BSD License text as described in Section 4.e of the | |||
provided without warranty as described in the Revised BSD License. | Trust Legal Provisions and are provided without warranty as described | |||
in the Revised BSD License. | ||||
Table of Contents | Table of Contents | |||
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3 | 1. Introduction | |||
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4 | 2. Terminology | |||
3. Use Cases . . . . . . . . . . . . . . . . . . . . . . . . . . 4 | 3. Use Cases | |||
3.1. PCECC for Label Management . . . . . . . . . . . . . . . 5 | 3.1. PCECC for Label Management | |||
3.2. PCECC and Segment Routing . . . . . . . . . . . . . . . . 7 | 3.2. PCECC and SR | |||
3.2.1. PCECC SID Allocation for SR-MPLS . . . . . . . . . . 8 | 3.2.1. PCECC SID Allocation for SR-MPLS | |||
3.2.2. PCECC for SR-MPLS Best Effort (BE) Path . . . . . . . 9 | 3.2.2. PCECC for SR-MPLS Best Effort (BE) Paths | |||
3.2.3. PCECC for SR-MPLS TE Path . . . . . . . . . . . . . . 9 | 3.2.3. PCECC for SR-MPLS TE Paths | |||
3.2.4. PCECC for SRv6 . . . . . . . . . . . . . . . . . . . 12 | 3.2.4. PCECC for SRv6 | |||
3.3. PCECC for Static TE LSP . . . . . . . . . . . . . . . . . 14 | 3.3. PCECC for Static TE LSPs | |||
3.4. PCECC for Load Balancing (LB) . . . . . . . . . . . . . . 16 | 3.4. PCECC for Load Balancing (LB) | |||
3.5. PCECC and Inter-AS TE . . . . . . . . . . . . . . . . . . 18 | 3.5. PCECC and Inter-AS TE | |||
3.6. PCECC for Multicast LSPs . . . . . . . . . . . . . . . . 21 | 3.6. PCECC for Multicast LSPs | |||
3.6.1. PCECC for P2MP/MP2MP LSPs' Setup . . . . . . . . . . 21 | 3.6.1. PCECC for the Setup of P2MP/MP2MP LSPs | |||
3.6.2. PCECC for the End-to-End Protection of P2MP/MP2MP | 3.6.2. PCECC for the End-to-End Protection of P2MP/MP2MP LSPs | |||
LSPs . . . . . . . . . . . . . . . . . . . . . . . . 24 | 3.6.3. PCECC for the Local Protection of P2MP/MP2MP LSPs | |||
3.6.3. PCECC for the Local Protection of the P2MP/MP2MP | 3.7. PCECC for Traffic Classification | |||
LSPs . . . . . . . . . . . . . . . . . . . . . . . . 25 | 3.8. PCECC for SFC | |||
3.7. PCECC for Traffic Classification . . . . . . . . . . . . 26 | 3.9. PCECC for Native IP | |||
3.8. PCECC for SFC . . . . . . . . . . . . . . . . . . . . . . 27 | 3.10. PCECC for BIER | |||
3.9. PCECC for Native IP . . . . . . . . . . . . . . . . . . . 28 | 4. IANA Considerations | |||
3.10. PCECC for BIER . . . . . . . . . . . . . . . . . . . . . 29 | 5. Security Considerations | |||
4. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 29 | 6. References | |||
5. Security Considerations . . . . . . . . . . . . . . . . . . . 29 | 6.1. Normative References | |||
6. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 30 | 6.2. Informative References | |||
7. References . . . . . . . . . . . . . . . . . . . . . . . . . 30 | Appendix A. Other Use Cases of the PCECC | |||
7.1. Normative References . . . . . . . . . . . . . . . . . . 30 | A.1. PCECC for Network Migration | |||
7.2. Informative References . . . . . . . . . . . . . . . . . 31 | A.2. PCECC for L3VPN and PWE3 | |||
Appendix A. Other Use Cases of PCECC . . . . . . . . . . . . . . 38 | A.3. PCECC for Local Protection (RSVP-TE) | |||
A.1. PCECC for Network Migration . . . . . . . . . . . . . . . 38 | A.4. Using Reliable P2MP TE-Based Multicast Delivery for | |||
A.2. PCECC for L3VPN and PWE3 . . . . . . . . . . . . . . . . 39 | Distributed Computations (MapReduce-Hadoop) | |||
A.3. PCECC for Local Protection (RSVP-TE) . . . . . . . . . . 40 | Acknowledgments | |||
A.4. Using reliable P2MP TE based multicast delivery for | Contributors | |||
distributed computations (MapReduce-Hadoop) . . . . . . . 41 | Authors' Addresses | |||
Appendix B. Contributor Addresses . . . . . . . . . . . . . . . 43 | ||||
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 44 | ||||
1. Introduction | 1. Introduction | |||
The PCE [RFC4655] was developed to offload the path computation | The PCE [RFC4655] was developed to offload the path computation | |||
function from routers in an MPLS traffic-engineered (TE) network. It | function from routers in an MPLS Traffic Engineering (TE) network. | |||
can compute optimal paths for traffic across a network and can also | It can compute optimal paths for traffic across a network and can | |||
update the paths to reflect changes in the network or traffic | also update the paths to reflect changes in the network or traffic | |||
demands. The role and function of PCE have grown to cover several | demands. The role and function of the PCE have grown to cover | |||
other uses (such as GMPLS [RFC7025] or Multicast), and to allow | several other uses (such as GMPLS [RFC7025] or Multicast) and to | |||
delegated stateful control [RFC8231] and PCE-initiated use of network | allow delegated stateful control [RFC8231] and PCE-initiated use of | |||
resources [RFC8281]. | network resources [RFC8281]. | |||
According to [RFC7399], Software-Defined Networking (SDN) refers to a | According to [RFC7399], Software-Defined Networking (SDN) refers to a | |||
separation between the control elements and the forwarding components | separation between the control elements and the forwarding components | |||
so that software running in a centralized system, called a | so that software running in a centralized system, called a | |||
controller, can act to program the devices in the network to behave | "controller", can act to program the devices in the network to behave | |||
in specific ways. A required element in an SDN architecture is a | in specific ways. A required element in an SDN architecture is a | |||
component that plans how the network resources will be used and how | component that plans how the network resources will be used and how | |||
the devices will be programmed. It is possible to view this | the devices will be programmed. It is possible to view this | |||
component as performing specific computations to place traffic flows | component as performing specific computations to place traffic flows | |||
within the network given knowledge of the availability of the network | within the network given knowledge of the availability of the network | |||
resources, how other forwarding devices are programmed, and the way | resources, how other forwarding devices are programmed, and the way | |||
that other flows are routed. This is the function and purpose of a | that other flows are routed. This is the function and purpose of a | |||
PCE, and the way that a PCE integrates into a wider network control | PCE, and the way that a PCE integrates into a wider network control | |||
system (including an SDN system) is presented in [RFC7491]. | system (including an SDN system) is presented in [RFC7491]. | |||
[RFC8283] introduces the architecture for the PCE as a central | [RFC8283] outlines the architecture for the PCE as a central | |||
controller as an extension to the architecture described in [RFC4655] | controller, extending the framework described in [RFC4655], and | |||
and assumes the continued use of PCEP as the protocol used between | demonstrates how PCEP can serve as a general southbound control | |||
the PCE and PCC. [RFC8283] further examines the motivations and | protocol between the PCE and Path Computation Client (PCC). | |||
applicability of PCEP as a Southbound Interface (SBI) and introduces | [RFC8283] further examines the motivations and applicability of PCEP | |||
the implications for the protocol. | as a Southbound Interface (SBI) and introduces the implications for | |||
the protocol. | ||||
[RFC9050] introduces the procedures and extensions for PCEP to | [RFC9050] introduces the procedures and extensions for PCEP to | |||
support the PCECC architecture [RFC8283]. | support the PCECC architecture [RFC8283]. | |||
This document describes the various use cases for the PCECC | This document describes the various use cases for the PCECC | |||
architecture. | architecture. | |||
2. Terminology | 2. Terminology | |||
The following terminology is used in this document. | The following terminology is used in this document. | |||
BGP-LS: Border Gateway Protocol - Link State [RFC9552]. | AS: Autonomous System | |||
LSP: Label Switched Path. | ASBR: Autonomous System Border Router | |||
IGP: Interior Gateway Protocol. In the document, we assume either | BGP-LS: Border Gateway Protocol - Link State [RFC9552] | |||
Open Shortest Path First (OSPF) [RFC2328][RFC5340] or Intermediate | ||||
System to Intermediate System (IS-IS) [RFC1195] as IGP. | ||||
PCC: Path Computation Client. As per [RFC4655], any client | IGP: Interior Gateway Protocol (in this document, we assume IGP as | |||
application requesting a path computation to be performed by a Path | either Open Shortest Path First (OSPF) [RFC2328] [RFC5340] or | |||
Computation Element. | Intermediate System to Intermediate System (IS-IS) [RFC1195]) | |||
PCE: Path Computation Element. As per [RFC4655], an entity | LSP: Label-Switched Path | |||
(component, application, or network node) that is capable of | ||||
computing a network path or route based on a network graph and | ||||
applying computational constraints. | ||||
PCECC: PCE as a Central Controller. Extension of PCE to support SDN | PCC: Path Computation Client (as per [RFC4655], any client | |||
functions as per [RFC8283]. | application requesting a path computation to be performed by a PCE) | |||
PST: Path Setup Type [RFC8408]. | PCE: Path Computation Element (as per [RFC4655], an entity such as a | |||
component, application, or network node that is capable of computing | ||||
a network path or route based on a network graph and applying | ||||
computational constraints) | ||||
RR: Route Reflector [RFC4456]. | PCECC: PCE as a Central Controller (an extension of a PCE to support | |||
SDN functions as per [RFC8283]) | ||||
SID: Segment Identifier [RFC8402]. | PST: Path Setup Type [RFC8408] | |||
SR: Segment Routing [RFC8402]. | RR: Route Reflector [RFC4456] | |||
SRGB: Segment Routing Global Block [RFC8402]. | SID: Segment Identifier [RFC8402] | |||
SRLB: Segment Routing Local Block [RFC8402]. | SR: Segment Routing [RFC8402] | |||
TE: Traffic Engineering [RFC9522]. | SRGB: Segment Routing Global Block [RFC8402] | |||
SRLB: Segment Routing Local Block [RFC8402] | ||||
TE: Traffic Engineering [RFC9522] | ||||
3. Use Cases | 3. Use Cases | |||
[RFC8283] describes various use cases for PCECC such as: | [RFC8283] describes various use cases for a PCECC such as: | |||
* Use of PCECC to set up Static TE LSPs. The PCEP extension for | * use of a PCECC to set up static TE LSPs (the PCEP extension for | |||
this use case is in [RFC9050]. | this use case is in [RFC9050]) | |||
* Use of PCECC in Segment Routing [RFC8402]. | * use of a PCECC in SR [RFC8402] | |||
* Use of PCECC to set up Multicast Point-to-Multipoint (P2MP) LSP. | * use of a PCECC to set up Multicast Point-to-Multipoint (P2MP) LSPs | |||
* Use of PCECC to set up Service Function Chaining (SFC) [RFC7665]. | * use of a PCECC to set up Service Function Chaining (SFC) [RFC7665] | |||
* Use of PCECC in Optical Networks. | * use of a PCECC in optical networks | |||
Section 3.1 describes the general case of PCECC being in charge of | Section 3.1 describes the general case of a PCECC being in charge of | |||
managing MPLS label space which is a prerequisite for further use | managing MPLS label space, which is a prerequisite for further use | |||
cases. Further, various use cases (SR, Multicast etc) are described | cases. Further, various use cases (SR, Multicast, etc.) are | |||
in the following sections to showcase scenarios that can benefit from | described in the following sections to showcase scenarios that can | |||
the use of PCECC. | benefit from the use of a PCECC. | |||
It is interesting to note that some of the use cases listed can also | It is interesting to note that some of the use cases listed can also | |||
be supported via BGP instead of PCEP. However, within the scope of | be supported via BGP instead of PCEP. However, within the scope of | |||
this document, the focus is on the use of PCEP. | this document, the focus is on the use of PCEP. | |||
3.1. PCECC for Label Management | 3.1. PCECC for Label Management | |||
As per [RFC8283], in some cases, the PCE-based controller can take | As per [RFC8283], in some cases, the PCECC can take responsibility | |||
responsibility for managing some part of the MPLS label space for | for managing some part of the MPLS label space for each of the | |||
each of the routers that it controls, and it may take wider | routers that it controls, and it may take wider responsibility for | |||
responsibility for partitioning the label space for each router and | partitioning the label space for each router and allocating different | |||
allocating different parts for different uses, communicating the | parts for different uses, communicating the ranges to the router | |||
ranges to the router using PCEP. | using PCEP. | |||
[RFC9050] describes a mode where LSPs are provisioned as explicit | [RFC9050] describes a mode where LSPs are provisioned as explicit | |||
label instructions at each hop on the end-to-end path. Each router | label instructions at each hop on the end-to-end path. Each router | |||
along the path must be told what label forwarding instructions to | along the path must be told what label forwarding instructions to | |||
program and what resources to reserve. The controller uses PCEP to | program and what resources to reserve. The controller uses PCEP to | |||
communicate with each router along the path of the end-to-end LSP. | communicate with each router along the path of the end-to-end LSP. | |||
For this to work, the PCE-based controller will take responsibility | For this to work, the PCECC will take responsibility for managing | |||
for managing some part of the MPLS label space for each of the | some part of the MPLS label space for each of the routers that it | |||
routers that it controls. An extension to PCEP could be done to | controls. An extension to PCEP could be done to allow a PCC to | |||
allow a PCC to inform the PCE of such a label space to control. (See | inform the PCE of such a label space to control (see [PCE-ID] for a | |||
[I-D.li-pce-controlled-id-space] for a possible PCEP extension to | possible PCEP extension to support the advertisement of the MPLS | |||
support the advertisement of the MPLS label space to the PCE to | label space for the PCE to control). | |||
control.) | ||||
[RFC8664] specifies extensions to PCEP that allow a stateful PCE to | [RFC8664] specifies extensions to PCEP that allow a stateful PCE to | |||
compute, update or initiate SR-TE paths. | compute, update, or initiate SR-TE paths. [PCECC-SR] describes the | |||
[I-D.ietf-pce-pcep-extension-pce-controller-sr] describes the | mechanism for a PCECC to allocate and provision the node/prefix/ | |||
mechanism for PCECC to allocate and provision the node/prefix/ | ||||
adjacency label (Segment Routing Identifier (SID)) via PCEP. To make | adjacency label (Segment Routing Identifier (SID)) via PCEP. To make | |||
such an allocation PCE needs to be aware of the label space from the | such an allocation, the PCE needs to be aware of the label space from | |||
Segment Routing Global Block (SRGB) or Segment Routing Local Block | the Segment Routing Global Block (SRGB) or Segment Routing Local | |||
(SRLB) [RFC8402] of the node that it controls. A mechanism for a PCC | Block (SRLB) [RFC8402] of the node that it controls. A mechanism for | |||
to inform the PCE of such a label space to control is needed within | a PCC to inform the PCE of such a label space to control is needed | |||
the PCEP. The full SRGB/SRLB of a node could be learned via existing | within the PCEP. The full SRGB/SRLB of a node could be learned via | |||
IGP or BGP-LS [RFC9552] mechanisms. | existing IGP or BGP-LS [RFC9552] mechanisms. | |||
Further, there have been proposals for a global label range in MPLS, | Further, there have been proposals for a global label range in MPLS | |||
the PCECC architecture could be used as a means to learn the label | as well as the use of PCECC architecture to learn the label space of | |||
space of nodes, and could also be used to determine and provision the | each node to determine and provision the global label range. | |||
global label range. | ||||
+------------------------------+ +------------------------------+ | +------------------------------+ +------------------------------+ | |||
| PCE DOMAIN 1 | | PCE DOMAIN 2 | | | PCE DOMAIN 1 | | PCE DOMAIN 2 | | |||
| +--------+ | | +--------+ | | | +--------+ | | +--------+ | | |||
| | | | | | | | | | | | | | | | | | |||
| | PCECC1 | ---------PCEP---------- | PCECC2 | | | | | PCECC1 | ---------PCEP---------- | PCECC2 | | | |||
| | | | | | | | | | | | | | | | | | |||
| | | | | | | | | | | | | | | | | | |||
| +--------+ | | +--------+ | | | +--------+ | | +--------+ | | |||
| ^ ^ | | ^ ^ | | | ^ ^ | | ^ ^ | | |||
| / \ PCEP | | PCEP / \ | | | / \ PCEP | | PCEP / \ | | |||
| V V | | V V | | | V V | | V V | | |||
| +--------+ +--------+ | | +--------+ +--------+ | | | +--------+ +--------+ | | +--------+ +--------+ | | |||
| |NODE 11 | | NODE 1n| | | |NODE 21 | | NODE 2n| | | | | Node11 | | Node1n | | | | Node21 | | Node2n | | | |||
| | | ...... | | | | | | ...... | | | | | | | ...... | | | | | | ...... | | | | |||
| | PCECC | | PCECC | | | | PCECC | |PCECC | | | | | PCECC | | PCECC | | | | PCECC | |PCECC | | | |||
| |Enabled | | Enabled| | |Enabled | |Enabled | | | | |Enabled | | Enabled| | | |Enabled | |Enabled | | | |||
| +--------+ +--------+ | | +--------+ +--------+ | | | +--------+ +--------+ | | +--------+ +--------+ | | |||
| | | | | | | | | | |||
+------------------------------+ +------------------------------+ | +------------------------------+ +------------------------------+ | |||
Figure 1: PCECC for MPLS Label Management | Figure 1: PCECC for MPLS Label Management | |||
* As shown in Figure 1, PCC will advertise the PCECC capability to | As shown in Figure 1: | |||
the PCE central controller (PCECC) [RFC9050]. | ||||
* The PCC will advertise the PCECC capability to the PCECC | ||||
[RFC9050]. | ||||
* The PCECC could also learn the label range set aside by the PCC | * The PCECC could also learn the label range set aside by the PCC | |||
(via [I-D.li-pce-controlled-id-space]). | (via [PCE-ID]). | |||
* Optionally, the PCECC could determine the shared MPLS global label | * Optionally, the PCECC could determine the shared MPLS global label | |||
range for the network. | range for the network. | |||
- In the case that the shared global label range needs to be | - In the case that the shared global label range needs to be | |||
negotiated across multiple domains, the central controllers of | negotiated across multiple domains, the central controllers of | |||
these domains will also need to negotiate a common global label | these domains will also need to negotiate a common global label | |||
range across domains. | range across domains. | |||
- The PCECC will need to set the shared global label range to all | - The PCECC will need to set the shared global label range to all | |||
PCC nodes in the network. | PCC nodes in the network. | |||
As per [RFC9050], PCECC could also rely on the PCC to make label | As per [RFC9050], the PCECC could also rely on the PCC to make label | |||
allocations initially and use PCEP to distribute it to where it is | allocations initially and use PCEP to distribute it to where it is | |||
needed. | needed. | |||
3.2. PCECC and Segment Routing | 3.2. PCECC and SR | |||
Segment Routing (SR) [RFC8402] leverages the source routing paradigm. | SR [RFC8402] leverages the source routing paradigm. Using SR, a | |||
Using SR, a source node steers a packet through a path without | source node steers a packet through a path without relying on hop-by- | |||
relying on hop-by-hop signalling protocols such as LDP [RFC5036] or | hop signalling protocols such as LDP [RFC5036] or RSVP-TE [RFC3209]. | |||
RSVP-TE [RFC3209]. Each path is specified as an ordered list of | Each path is specified as an ordered list of instructions called | |||
instructions called "segments". Each segment is an instruction to | "segments". Each segment is an instruction to route the packet to a | |||
route the packet to a specific place in the network, or to perform a | specific place in the network or to perform a specific service on the | |||
specific service on the packet. A database of segments can be | packet. A database of segments can be distributed through the | |||
distributed through the network using a intra-domain routing protocol | network using an intra-domain routing protocol (such as IS-IS or | |||
(such as IS-IS or OSPF) or an inter-domain protocol (BGP), or by any | OSPF), an inter-domain protocol (such as BGP), or by any other means. | |||
other means. PCEP could also be one of other protocols. | PCEP could also be one of other protocols. | |||
[RFC8664] specifies the SR-specific PCEP extension for SR-MPLS. | [RFC8664] specifies the PCEP extension specific to SR for SR over | |||
PCECC may further use PCEP protocol for SR SIDs (Segment Identifiers) | MPLS (SR-MPLS). The PCECC may further use the PCEP for distributing | |||
distribution to the SR nodes (PCC) with some benefits. If the PCECC | SR Segment Identifiers (SIDs) to the SR nodes (PCC) with some | |||
allocates and maintains the SIDs in the network for the nodes and | benefits. If the PCECC allocates and maintains the SIDs in the | |||
adjacencies; and further distributes them to the SR nodes directly | network for the nodes and adjacencies, and further distributes them | |||
via the PCEP session then it is more advantageous over the | to the SR nodes directly via the PCEP session, then it is more | |||
configurations on each SR node and flooding them via IGP, especially | advantageous over the configurations on each SR node and flooding | |||
in an SDN environment. | them via IGP, especially in an SDN environment. | |||
When the PCECC is used for the distribution of the Node-SID and Adj- | When the PCECC is used for the distribution of the Node-SID and Adj- | |||
SID for SR-MPLS, the Node-SID is allocated from the SRGB of the node. | SID for SR-MPLS, the Node-SID is allocated from the SRGB of the node | |||
For the allocation of Adj-SID, the allocation is from the SRLB of the | and the Adj-SID is allocated from the SRLB of the node as described | |||
node as described in [I-D.ietf-pce-pcep-extension-pce-controller-sr]. | in [PCECC-SR]. | |||
[RFC8355] identifies various protection and resiliency usecases for | [RFC8355] identifies various protection and resiliency use cases for | |||
SR. Path protection lets the ingress node be in charge of the | SR. Path protection lets the ingress node be in charge of the | |||
failure recovery (used for SR-TE [RFC8664]). Also, protection can be | failure recovery (used for SR-TE [RFC8664]). Also, protection can be | |||
performed by the node adjacent to the failed component, commonly | performed by the node adjacent to the failed component, commonly | |||
referred to as local protection techniques or fast-reroute (FRR) | referred to as "local protection techniques" or "fast-reroute (FRR) | |||
techniques. In the case of PCECC, the protection paths can be pre- | techniques". In the case of the PCECC, the protection paths can be | |||
computed and set up by the PCE. | precomputed and set up by the PCE. | |||
The Figure 2 illustrates the use case where the Node-SID and Adj-SID | Figure 2 illustrates the use case where the Node-SID and Adj-SID are | |||
are allocated by the PCECC for SR-MPLS. | allocated by the PCECC for SR-MPLS. | |||
192.0.2.1/32 | 192.0.2.1/32 | |||
+----------+ | +----------+ | |||
| R1(1001) | | | R1(1001) | | |||
+----------+ | +----------+ | |||
| | | | |||
+----------+ | +----------+ | |||
| R2(1002) | 192.0.2.2/32 | | R2(1002) | 192.0.2.2/32 | |||
+----------+ | +----------+ | |||
* | * * | * | * * | |||
skipping to change at page 8, line 38 ¶ | skipping to change at line 367 ¶ | |||
| R8(1008) | 192.0.2.8/32 | | R8(1008) | 192.0.2.8/32 | |||
+-----------+ | +-----------+ | |||
Figure 2: SR Topology | Figure 2: SR Topology | |||
3.2.1. PCECC SID Allocation for SR-MPLS | 3.2.1. PCECC SID Allocation for SR-MPLS | |||
Each node (PCC) is allocated a Node-SID by the PCECC. The PCECC | Each node (PCC) is allocated a Node-SID by the PCECC. The PCECC | |||
needs to update the label mapping of each node to all the other nodes | needs to update the label mapping of each node to all the other nodes | |||
in the domain. After receiving the label mapping, each node (PCC) | in the domain. After receiving the label mapping, each node (PCC) | |||
uses the local routing information to determine the nexthop and | uses the local routing information to determine the next hop and | |||
download the label forwarding instructions accordingly. The | download the label forwarding instructions accordingly. The | |||
forwarding behaviour and the end result are the same as IGP shortest- | forwarding behavior and the end result are the same as IGP shortest- | |||
path SR forwarding based on Node-SID. Thus, from anywhere in the | path SR forwarding based on Node-SIDs. Thus, from anywhere in the | |||
domain, it enforces the ECMP-aware shortest-path forwarding of the | domain, it enforces the ECMP-aware shortest-path forwarding of the | |||
packet towards the related node. | packet towards the related node. | |||
For each adjacency in the network, a PCECC can allocate an Adj-SID. | The PCECC can allocate an Adj-SID for each adjacency in the network. | |||
The PCECC sends a PCInitiate message to update the label mapping of | The PCECC sends a PCInitiate message to update the label mapping of | |||
each adjacency to the corresponding nodes in the domain. Each node | each adjacency to the corresponding nodes in the domain. Each node | |||
(PCC) downloads the label forwarding instructions accordingly. The | (PCC) downloads the label forwarding instructions accordingly. The | |||
forwarding behaviour and the end result are similar to IGP-based Adj- | forwarding behavior and the end result are similar to IGP-based Adj- | |||
SID allocation and usage in SR. | SID allocation and usage in SR. | |||
These mechanisms are described in | These mechanisms are described in [PCECC-SR]. | |||
[I-D.ietf-pce-pcep-extension-pce-controller-sr]. | ||||
3.2.2. PCECC for SR-MPLS Best Effort (BE) Path | 3.2.2. PCECC for SR-MPLS Best Effort (BE) Paths | |||
In this use case, the PCECC needs to allocate the Node-SID (without | When using PCECC for SR-MPLS Best Effort (BE) Paths, the PCECC needs | |||
calculating the explicit path for the SR path). The ingress router | to allocate the Node-SID (without calculating the explicit path for | |||
of the forwarding path needs to encapsulate the destination Node-SID | the SR path). The ingress router of the forwarding path needs to | |||
on top of the packet. All the intermediate nodes will forward the | encapsulate the destination Node-SID on top of the packet. All the | |||
packet based on the destination Node-SID. It is similar to the LDP | intermediate nodes will forward the packet based on the destination | |||
LSP. | Node-SID. It is similar to the LDP LSP. | |||
R1 may send a packet to R8 simply by pushing an SR label with segment | R1 may send a packet to R8 simply by pushing an SR label with segment | |||
{1008} (Node-SID for R8). The path will be based on the routing/ | {1008} (Node-SID for R8). The path will be based on the routing / | |||
nexthop calculation on the routers. | next hop calculation on the routers. | |||
3.2.3. PCECC for SR-MPLS TE Path | 3.2.3. PCECC for SR-MPLS TE Paths | |||
SR-TE paths may not follow an IGP shortest path tree (SPT). Such | SR-TE paths may not follow an IGP shortest path tree (SPT). Such | |||
paths may be chosen by a PCECC and provisioned on the ingress node of | paths may be chosen by a PCECC and provisioned on the ingress node of | |||
the SR-TE path. The SR header consists of a list of SIDs (or MPLS | the SR-TE path. The SR header consists of a list of SIDs (or MPLS | |||
labels). The header has all necessary information so that the | labels). The header has all necessary information so that the | |||
packets can be guided from the ingress node to the egress node of the | packets can be guided from the ingress node to the egress node of the | |||
path. Hence, there is no need for any signalling protocol. For the | path. Hence, there is no need for any signalling protocol. For the | |||
case where a strict traffic engineering path is needed, all the Adj- | case where a strict traffic engineering path is needed, all the Adj- | |||
SID are stacked, otherwise, a combination of node-SID or adj-SID can | SIDs are stacked; otherwise, a combination of Node-SIDs or Adj-SIDs | |||
be used for the SR-TE paths. | can be used for the SR-TE paths. | |||
As shown in Figure 3, R1 may send a packet to R8 by pushing an SR | As shown in Figure 3, R1 may send a packet to R8 by pushing an SR | |||
header with segment list {1002, 9001, 1008}. Where 1002 and 1008 are | header with segment list {1002, 9001, 1008}, where 1002 and 1008 are | |||
the Node-SID of R2 and R8 respectively. 9001 is the Adj-SID for | the Node-SIDs of R2 and R8, respectively. 9001 is the Adj-SID for | |||
link1. The path should be: R1-R2-link1-R3-R8. | link1. The path should be: "R1-R2-link1-R3-R8". | |||
To achieve this, the PCECC first allocates and distributes SIDs as | To achieve this, the PCECC first allocates and distributes SIDs as | |||
described in Section 3.2.1. [RFC8664] describes the mechanism for a | described in Section 3.2.1. [RFC8664] describes the mechanism for a | |||
PCE to compute, update, or initiate SR-MPLS TE paths. | PCE to compute, update, or initiate SR-MPLS TE paths. | |||
192.0.2.1/32 | 192.0.2.1/32 | |||
+----------+ | +----------+ | |||
| R1 (1001)| | | R1 (1001)| | |||
+----------+ | +----------+ | |||
| | | | | | |||
skipping to change at page 10, line 37 ¶ | skipping to change at line 449 ¶ | |||
+-----------+ +-----------+ | +-----------+ +-----------+ | |||
| | | | | | |||
|link8 | | |link8 | | |||
| |----------|link9 | | |----------|link9 | |||
+-----------+ | +-----------+ | |||
| R8 (1008) | 192.0.2.8/32 | | R8 (1008) | 192.0.2.8/32 | |||
+-----------+ | +-----------+ | |||
Figure 3: PCECC TE LSP Setup Example | Figure 3: PCECC TE LSP Setup Example | |||
Refer to Figure 3 for an example of TE topology, where, 100x - are | Refer to Figure 3 for an example of TE topology, where 100x are Node- | |||
Node-SIDs and 900xx - are Adj-SIDs. | SIDs and 900xx are Adj-SIDs. | |||
* The SID allocation and distribution are done by the PCECC with all | * The SID allocation and distribution are done by the PCECC with all | |||
Node-SIDs (100x) and all Adj-SIDs (900xx). | Node-SIDs (100x) and all Adj-SIDs (900xx). | |||
* Based on path computation request/delegation or PCE initiation, | * Based on path computation request/delegation or PCE initiation, | |||
the PCECC receives a request with constraints and optimization | the PCECC receives a request with constraints and optimization | |||
criteria from a PCC. | criteria from a PCC. | |||
* PCECC will calculate the optimal path according to the given | * The PCECC will calculate the optimal path according to the given | |||
constraints (e.g. bandwidth). | constraints (e.g., bandwidth (BW)). | |||
* PCECC will provision SR-MPLS TE LSP (path R1-link1-R2-link6-R3-R8) | * The PCECC will provision the SR-MPLS TE LSP path | |||
at the ingress node: {90011,1002,90026,1003,1008} | ("R1-link1-R2-link6-R3-R8") at the ingress node: {90011, 1002, | |||
90026, 1003, 1008} | ||||
* For the end-to-end protection, PCECC can provision the secondary | * For the end-to-end protection, the PCECC can provision the | |||
path (R1-link2-R2-link4-R5-R8): {90012,1002,90024,1005,1008}. | secondary path ("R1-link2-R2-link4-R5-R8"): {90012, 1002, 90024, | |||
1005, 1008}. | ||||
3.2.3.1. PCECC for SR Policy | 3.2.3.1. PCECC for SR Policy | |||
[RFC8402] defines Segment Routing architecture, which uses an SR | [RFC8402] defines SR architecture, which uses an SR Policy to steer | |||
Policy to steer packets from a node through an ordered list of | packets from a node through an ordered list of segments. The SR | |||
segments. The SR Policy could be configured on the headend or | Policy could be configured on the headend or instantiated by an SR | |||
instantiated by an SR controller. The SR architecture does not | controller. The SR architecture does not restrict how the controller | |||
restrict how the controller programs the network. In this case, the | programs the network. In this case, the focus is on PCEP as the | |||
focus is on PCEP as the protocol for SR Policy delivery from PCE to | protocol for SR Policy delivery from the PCE to PCC. | |||
PCC. | ||||
An SR Policy architecture is described in [RFC9256]. An SR Policy is | An SR Policy architecture is described in [RFC9256]. An SR Policy is | |||
a framework that enables the instantiation of an ordered list of | a framework that enables the instantiation of an ordered list of | |||
segments on a node for implementing a source routing policy for the | segments on a node for implementing a source routing policy for the | |||
steering of traffic for a specific purpose (e.g. for a specific SLA) | steering of traffic for a specific purpose (e.g., for a specific | |||
from that node. | Service Level Agreement (SLA)) from that node. | |||
An SR Policy is identified through the tuple <headend, color, | An SR Policy is identified through the tuple <headend, color, | |||
endpoint>. | endpoint>. | |||
Figure 3 is used as an example of PCECC application for SR Policy | Figure 3 is used as an example of PCECC application for SR Policy | |||
instantiation for SR-MPLS, where, 100x - are Node-SIDs and 900xx - | instantiation for SR-MPLS, where the Node-SIDs are 100x and the Adj- | |||
are Adj-SIDs. | SIDs are 900xx. | |||
Let's assume that R1 needs to have two disjoint SR Policies towards | Let's assume that R1 needs to have two disjoint SR Policies towards | |||
R8 based on different bandwidths, the possible paths are: | R8 based on different BWs. This means the possible paths are: | |||
POL1: {Headend R1, color 100, Endpoint R8; Candidate Path1: | * POL1: {Headend R1, color 100, Endpoint R8; Candidate Path1: | |||
Segment List 1: {90011,1002,90023,1004,1003,1008}} | Segment List 1: {90011, 1002, 90023, 1004, 1003, 1008}} | |||
POL2: {Headend R1, color 200, Endpoint R8; Candidate Path1: | * POL2: {Headend R1, color 200, Endpoint R8; Candidate Path1: | |||
Segment List 1: {90012,1002,90024,1005,1006,1008}} | Segment List 1: {90012, 1002, 90024, 1005, 1006, 1008}} | |||
Each SR Policy (including candidate path and segment list) will be | Each SR Policy (including the candidate path and segment list) will | |||
signalled to a headend (R1) via PCEP | be signalled to a headend (R1) via PCEP [PCEP-POLICY] with the | |||
[I-D.ietf-pce-segment-routing-policy-cp] with the addition of an | addition of an ASSOCIATION object. A Binding SID (BSID) [RFC8402] | |||
ASSOCIATION object. Binding SID (BSID) [RFC8402] can be used for | can be used for traffic steering of labelled traffic into an SR | |||
traffic steering of labelled traffic into SR Policy, BSID can be | Policy; a BSID can be provisioned from the PCECC also via PCEP | |||
provisioned from PCECC also via PCEP | [RFC9604]. For non-labelled traffic steering into the SR Policy POL1 | |||
[I-D.ietf-pce-binding-label-sid]. For non-labelled traffic steering | or POL2, a per-destination traffic steering will be used by means of | |||
into the SR Policy POL1 or POL2, a per-destination traffic steering | the BGP Color Extended Community [RFC9012]. | |||
will be used by means of the BGP Color extended community [RFC9012] | ||||
The procedure: | The procedure is as follows: | |||
PCECC allocates Node-SIDs and Adj-SIDs using the mechanism | * The PCECC allocates Node-SIDs and Adj-SIDs using the mechanism | |||
described in Section 3.2.1 for all nodes and links. | described in Section 3.2.1 for all nodes and links. | |||
PCECC will calculate disjoint paths for POL1 and POL2 and create | * The PCECC calculates disjoint paths for POL1 and POL2 and create | |||
Segment Lists for them:{90011,1002,90023,1004,1003,1008};{90012,10 | segment lists for them: {90011, 1002, 90023, 1004, 1003, | |||
02,90024,1005,1006,1008}. | 1008};{90012, 1002, 90024, 1005, 1006, 1008}. | |||
PCECC will form both SR Policies POL1 and POL2. | * The PCECC forms both SR Policies POL1 and POL2. | |||
PCECC will send both POL1 and POl2 to R1 via PCEP. | * The PCECC sends both POL1 and POL2 to R1 via PCEP. | |||
PCECC optionally can allocate BSIDs for the SR Policies. | * The PCECC optionally allocates BSIDs for the SR Policies. | |||
The traffic from R1 to R8 which fits to color 100 will be steered | * The traffic from R1 to R8, which fits to color 100, will be | |||
to POL1 and follows the path: R1-link1-R2-link3-R4-R3-R8. The | steered to POL1 and follows the path: | |||
traffic from R1 to R8 which fits color 200 will be steered to POL2 | "R1-link1-R2-link3-R4-R3-R8". The traffic from R1 to R8, which | |||
and follows the path: R1-link2-R2-link4-R5-R6-R8. Due to the | fits color 200, will be steered to POL2 and follows the path: | |||
possibility of having many Segment Lists in the same Candidate | "R1-link2-R2-link4-R5-R6-R8". Due to the possibility of having | |||
Path of each POL1/POL2, PCECC could provision more paths towards | many segment lists in the same candidate path of each POL1/POL2, | |||
R8 and traffic will be balanced either as ECMP or as w/ECMP. This | the PCECC could provision more paths towards R8 and traffic will | |||
is the advantage of SR Policy architecture. | be balanced either as ECMP or as weighted-ECMP (W-ECMP). This is | |||
the advantage of SR Policy architecture. | ||||
Note that an SR Policy can be associated with multiple candidate | Note that an SR Policy can be associated with multiple candidate | |||
paths. A candidate path is selected when it is valid and it is | paths. A candidate path is selected when it is valid and it is | |||
determined to be the best path of the SR Policy as described in | determined to be the best path of the SR Policy as described in | |||
[RFC9256]. | [RFC9256]. | |||
3.2.4. PCECC for SRv6 | 3.2.4. PCECC for SRv6 | |||
As per [RFC8402], with Segment Routing (SR), a node steers a packet | As per [RFC8402], with SR, a node steers a packet through an ordered | |||
through an ordered list of instructions, called segments. Segment | list of instructions, called segments. SR can be applied to the IPv6 | |||
Routing can be applied to the IPv6 architecture with the Segment | architecture with the Segment Routing Header (SRH) [RFC8754]. A | |||
Routing Header (SRH) [RFC8754]. A segment is encoded as an IPv6 | segment is encoded as an IPv6 address. An ordered list of segments | |||
address. An ordered list of segments is encoded as an ordered list | is encoded as an ordered list of IPv6 addresses in the routing | |||
of IPv6 addresses in the routing header. The active segment is | header. The active segment is indicated by the destination address | |||
indicated by the Destination Address of the packet. Upon completion | of the packet. Upon completion of a segment, a pointer in the new | |||
of a segment, a pointer in the new routing header is incremented and | routing header is incremented and indicates the next segment. | |||
indicates the next segment. | ||||
As per [RFC8754], an SRv6 Segment is a 128-bit value. "SRv6 SID" or | As per [RFC8754], an SR over IPv6 (SRv6) Segment is a 128-bit value. | |||
simply "SID" are often used as a shorter reference for "SRv6 | "SRv6 SID" or simply "SID" are often used as a shorter reference for | |||
Segment". [RFC8986] defines the SRv6 SID as consisting of | "SRv6 Segment". [RFC8986] defines the SRv6 SID as consisting of | |||
LOC:FUNCT:ARG. | LOC:FUNCT:ARG. | |||
[I-D.ietf-pce-segment-routing-ipv6] extends [RFC8664] to support SR | [RFC9603] extends [RFC8664] to support SR for the IPv6 data plane. | |||
for the IPv6 data plane. Further, a PCECC could be extended to | Further, a PCECC could be extended to support SRv6 SID allocation and | |||
support SRv6 SID allocation and distribution. An example of how PCEP | distribution. An example of how PCEP extensions could be extended | |||
extensions could be extended for SRv6 for PCECC is described in | for SRv6 for a PCECC is described in [PCECC-SRv6]. | |||
[I-D.dhody-pce-pcep-extension-pce-controller-srv6]. | ||||
2001:db8::1 | 2001:db8::1 | |||
+----------+ | +----------+ | |||
| R1 | | | R1 | | |||
+----------+ | +----------+ | |||
| | | | |||
+----------+ | +----------+ | |||
| R2 | 2001:db8::2 | | R2 | 2001:db8::2 | |||
+----------+ | +----------+ | |||
* | * * | * | * * | |||
skipping to change at page 13, line 39 ¶ | skipping to change at line 589 ¶ | |||
+-----------+ +-----------+ | +-----------+ +-----------+ | |||
2001:db8::3 | R3 | |R6 |2001:db8::6 | 2001:db8::3 | R3 | |R6 |2001:db8::6 | |||
+-----------+ +-----------+ | +-----------+ +-----------+ | |||
| | | | |||
+-----------+ | +-----------+ | |||
| R8 | 2001:db8::8 | | R8 | 2001:db8::8 | |||
+-----------+ | +-----------+ | |||
Figure 4: PCECC for SRv6 | Figure 4: PCECC for SRv6 | |||
In this case, as shown in Figure 4, PCECC could assign the SRv6 SID | In this case, as shown in Figure 4, the PCECC could assign the SRv6 | |||
(in the form of an IPv6 address) to be used for node and adjacency. | SID (in the form of an IPv6 address) to be used for node and | |||
Later, the SRv6 path in the form of a list of SRv6 SIDs could be used | adjacency. Later, the SRv6 path in the form of a list of SRv6 SIDs | |||
at the ingress. Some examples - | could be used at the ingress. Some examples: | |||
* SRv6 SID-List={2001:db8::8} - The best path towards R8 | * The best path towards R8: SRv6 SID-List={2001:db8::8} | |||
* SRv6 SID-List={2001:db8::5, 2001:db8::8} - The path towards R8 via | * The path towards R8 via R5: SRv6 SID-List={2001:db8::5, | |||
R5 | 2001:db8::8} | |||
The rest of the procedures and mechanisms remain the same as SR-MPLS. | The rest of the procedures and mechanisms remain the same as SR-MPLS. | |||
3.3. PCECC for Static TE LSP | 3.3. PCECC for Static TE LSPs | |||
As described in Section 3.1.2 of [RFC8283], PCECC architecture | As described in Section 3.1.2 of [RFC8283], the PCECC architecture | |||
supports the provisioning of static TE LSP. To achieve this, the | supports the provisioning of static TE LSPs. To achieve this, the | |||
existing PCEP can be used to communicate between the PCECC and nodes | existing PCEP can be used to communicate between the PCECC and nodes | |||
along the path to provision explicit label instructions at each hop | along the path to provision explicit label instructions at each hop | |||
on the end-to-end path. Each router along the path must be told what | on the end-to-end path. Each router along the path must be told what | |||
label-forwarding instructions to program and what resources to | label-forwarding instructions to program and what resources to | |||
reserve. The PCE-based controller keeps a view of the network and | reserve. The PCECC keeps a view of the network and determines the | |||
determines the paths of the end-to-end LSPs, and the controller uses | paths of the end-to-end LSPs, and the controller uses PCEP to | |||
PCEP to communicate with each router along the path of the end-to-end | communicate with each router along the path of the end-to-end LSP. | |||
LSP. | ||||
192.0.2.1/32 | 192.0.2.1/32 | |||
+----------+ | +----------+ | |||
| R1 | | | R1 | | |||
+----------+ | +----------+ | |||
| | | | | | |||
|link1 | | |link1 | | |||
| |link2 | | |link2 | |||
+----------+ | +----------+ | |||
| R2 | 192.0.2.2/32 | | R2 | 192.0.2.2/32 | |||
skipping to change at page 15, line 9 ¶ | skipping to change at line 651 ¶ | |||
+-----------+ | +-----------+ | |||
Figure 5: PCECC TE LSP Setup Example | Figure 5: PCECC TE LSP Setup Example | |||
Refer to Figure 5 for an example TE topology. | Refer to Figure 5 for an example TE topology. | |||
* Based on path computation request/delegation or PCE initiation, | * Based on path computation request/delegation or PCE initiation, | |||
the PCECC receives a request with constraints and optimization | the PCECC receives a request with constraints and optimization | |||
criteria. | criteria. | |||
* PCECC will calculate the optimal path according to the given | * The PCECC will calculate the optimal path according to the given | |||
constraints (e.g. bandwidth). | constraints (e.g., BW). | |||
* PCECC will provision each node along the path and assign incoming | * The PCECC will provision each node along the path and assign | |||
and outgoing labels from R1 to R8 with the path as | incoming and outgoing labels from R1 to R8 with the path as | |||
"R1-link1-R2-link3-R4-link10-R3-link8-R8": | "R1-link1-R2-link3-R4-link10-R3-link8-R8": | |||
- R1: Outgoing label 1001 on link 1 | - R1: Outgoing label 1001 on link 1 | |||
- R2: Incoming label 1001 on link 1 | - R2: Incoming label 1001 on link 1 | |||
- R2: Outgoing label 2003 on link 3 | - R2: Outgoing label 2003 on link 3 | |||
- R4: Incoming label 2003 on link 3 | - R4: Incoming label 2003 on link 3 | |||
- R4: Outgoing label 4010 on link 10 | - R4: Outgoing label 4010 on link 10 | |||
- R3: Incoming label 4010 on link 10 | - R3: Incoming label 4010 on link 10 | |||
- R3: Outgoing label 3008 on link 8 | - R3: Outgoing label 3008 on link 8 | |||
- R8: Incoming label 3008 on link 8 | - R8: Incoming label 3008 on link 8 | |||
* This can also be represented as {R1, link1, 1001}, {1001, R2, | * This can also be represented as: {R1, link1, 1001}, {1001, R2, | |||
link3, 2003], {2003, R4, link10, 4010}, {4010, R3, link8, 3008}, | link3, 2003}, {2003, R4, link10, 4010}, {4010, R3, link8, 3008}, | |||
{3008, R8}. | {3008, R8}. | |||
* For the end-to-end protection, PCECC programs each node along the | * For the end-to-end protection, the PCECC programs each node along | |||
path from R1 to R8 with the secondary path: {R1, link2, 1002}, | the path from R1 to R8 with the secondary path: {R1, link2, 1002}, | |||
{1002, R2, link4, 2004], {2004, R5, link7, 5007}, {5007, R3, | {1002, R2, link4, 2004}, {2004, R5, link7, 5007}, {5007, R3, | |||
link9, 3009}, {3009, R8}. | link9, 3009}, {3009, R8}. | |||
* It is also possible to have a bypass path for the local protection | * It is also possible to have a bypass path for the local protection | |||
set up by the PCECC. For example, the primary path as above, then | set up by the PCECC. For example, use the primary path as above, | |||
to protect the node R4 locally, PCECC can program the bypass path | then to protect the node R4 locally, the PCECC can program the | |||
like this: {R2, link5, 2005}, {2005, R3}. By doing this, the node | bypass path like this: {R2, link5, 2005}, {2005, R3}. By doing | |||
R4 is locally protected at R2. | this, the node R4 is locally protected at R2. | |||
3.4. PCECC for Load Balancing (LB) | 3.4. PCECC for Load Balancing (LB) | |||
Very often many service providers use TE tunnels for solving issues | Very often, many service providers use TE tunnels for solving issues | |||
with non-deterministic paths in their networks. One example of such | with non-deterministic paths in their networks. One example of such | |||
applications is the usage of TEs in the mobile backhaul (MBH). | applications is the usage of TEs in the mobile backhaul (MBH). | |||
Consider the topology as shown in Figure 6 (AGG1...AGGN are | Consider the topology as shown in Figure 6 (where AGG 1...AGG N are | |||
Aggregation Routers, Core 1...Core N are Core routers) - | Aggregation routers, and Core 1...Core N are Core routers). | |||
TE1 --------------> | TE1 -----------> | |||
+---------+ +--------+ +--------+ +--------+ +------+ +---+ | +--------+ +------+ +-----+ +-------+ +------+ +---+ | |||
| Access |----| Access |----| AGG 1 |----| AGG N-1|----|Core 1|--|SR1| | |Access |----|Access|----|AGG 1|----|AGG N-1|----|Core 1|--|SR1| | |||
| SubNode1| | Node 1 | +--------+ +--------+ +------+ +---+ | |SubNode1| |Node1 | +-----+ +-------+ +------+ +---+ | |||
+---------+ +--------+ | | | ^ | | +--------+ +------+ | | | ^ | | |||
| Access | Access | AGG Ring 1 | | | | | Access | Access | AGG Ring 1| | | | |||
| SubRing 1 | Ring 1 | | | | | | | SubRing 1 | Ring 1 | | | | | | |||
+---------+ +--------+ +--------+ | | | | +--------+ +------+ +-----+ | | | | |||
| Access | | Access | | AGG 2 | | | | | |Access | |Access| |AGG 2| | | | | |||
| SubNode2| | Node 2 | +--------+ | | | | |SubNode2| |Node2 | +-----+ | | | | |||
+---------+ +--------+ | | | | | | +--------+ +------+ | | | | | | |||
| | | | | | | | | | | | | | | | |||
| | | +----TE2----|-+ | | | | | +---TE2---|-+ | | |||
+---------+ +--------+ +--------+ +--------+ +------+ +---+ | +--------+ +------+ +-----+ +-------+ +------+ +---+ | |||
| Access | | Access |----| AGG 3 |----| AGG N |----|Core N|--|SRn| | |Access | |Access|----|AGG 3|----| AGG N |----|Core N|--|SRn| | |||
| SubNodeN|----| Node N | +--------+ +--------+ +------+ +---+ | |SubNodeN|----|NodeN | +-----+ +-------+ +------+ +---+ | |||
+---------+ +--------+ | +--------+ +------+ | |||
Figure 6: PCECC Load Balancing (LB) Use Case | Figure 6: PCECC LB Use Case | |||
This MBH architecture uses L2 access rings and sub-rings. L3 starts | This MBH architecture uses L2 access rings and sub-rings. L3 starts | |||
at the aggregation layer. For the sake of simplicity, the figure | at the aggregation layer. For the sake of simplicity, the figure | |||
shows only one access sub-ring. The access ring and aggregation ring | shows only one access sub-ring. The access ring and aggregation ring | |||
are connected by Nx10GE interfaces. The aggregation domain runs its | are connected by Nx10GE interfaces. The aggregation domain runs its | |||
own IGP. There are two Egress routers (AGG N-1, AGG N) that are | own IGP. There are two egress routers (AGG N-1 and AGG N) that are | |||
connected to the Core domain (Core 1...Core N) via L2 interfaces. | connected to the Core domain (Core 1...Core N) via L2 interfaces. | |||
Core also has connections to service routers, RSVP-TE or SR-TE is | The Core also has connections to service routers; RSVP-TE or SR-TE is | |||
used for MPLS transport inside the ring. There could be at least 2 | used for MPLS transport inside the ring. There could be at least two | |||
tunnels (one way) from each AGG router to egress AGG routers. There | tunnels (one way) from each AGG router to egress AGG routers. There | |||
are also many L2 access rings connected to AGG routers. | are also many L2 access rings connected to AGG routers. | |||
Service deployment is made by means of Layer 2 Virtual Private | Service deployment is made by means of Layer 2 Virtual Private | |||
Networks (L2VPNs) (Virtual Private LAN Services (VPLS)), Layer 3 | Networks (L2VPNs), Virtual Private LAN Services (VPLSs), Layer 3 | |||
Virtual Private Networks (L3VPNs) or Ethernet VPNs (EVPNs). Those | Virtual Private Networks (L3VPNs), or Ethernet VPNs (EVPNs). Those | |||
services use MPLS TE (or SR-TE) as transport towards egress AGG | services use MPLS TE (or SR-TE) as transport towards egress AGG | |||
routers. TE tunnels could be used as transport towards service | routers. TE tunnels could be used as transport towards service | |||
routers in case of seamless MPLS ([I-D.ietf-mpls-seamless-mpls]) | routers in case of architecture based on seamless MPLS | |||
based architecture. | [MPLS-SEAMLESS]. | |||
Load balancing between TE tunnels involves distributing network | Load Balancing (LB) between TE tunnels involves distributing network | |||
traffic across multiple TE tunnels to optimize the use of available | traffic across multiple TE tunnels to optimize the use of available | |||
network resources, enhance performance, and ensure reliability. Some | network resources, enhance performance, and ensure reliability. Some | |||
common techniques include Equal-Cost Multi-Path (ECMP) and Unequal- | common techniques include Equal-Cost Multipath (ECMP) and Unequal- | |||
Cost Multi-Path (UCMP) based on the bandwidth of the TE tunnels. | Cost Multipath (UCMP) based on the BW of the TE tunnels. | |||
There is a need to solve the following tasks: | There is a need to solve the following tasks: | |||
* Perform automatic load-balance amongst TE tunnels according to | * Perform automatic LB amongst TE tunnels according to current | |||
current traffic load. | traffic loads. | |||
* TE bandwidth (BW) management: Provide guaranteed BW for specific | * Manage TE BW by guaranteeing BW for specific services (such as | |||
services: High-Speed Data Service (HSI)), IPTV, etc., and provide | High-Speed Internet (HSI), IPTV, etc.) and enabling time-based BW | |||
time-based BW reservation (BW on demand (BoD)) for other services. | reservation (such as Bandwidth on Demand (BoD)). | |||
* Simplify the development of TE tunnels by automation without any | * Simplify the development of TE tunnels by automation without any | |||
manual intervention. | manual intervention. | |||
* Provide flexibility for Service Router placement (anywhere in the | * Provide flexibility for service router placement (anywhere in the | |||
network by the creation of transport LSPs to them). | network by the creation of transport LSPs to them). | |||
In this section, the focus is on load balancing (LB) tasks. LB task | In this section, the focus is on LB tasks. LB tasks could be solved | |||
could be solved by means of PCECC in the following way: | by means of the PCECC in the following ways: | |||
* Application or network service or operator can ask the SDN | * Applications, network services, or operators can ask the SDN | |||
controller (PCECC) for LSP-based load balancing between AGG X and | controller (PCECC) for LSP-based LB between AGG X and AGG N/AGG | |||
AGG N/AGG N-1 (egress AGG routers that have connections to the | N-1 (egress AGG routers that have connections to the core). Each | |||
core). Each of these will have associated constraints (i.e. | of these will have associated constraints (such as BW, inclusion | |||
bandwidth, inclusion or exclusion specific links or nodes, number | or exclusion of specific links or nodes, number of paths, | |||
of paths, objective function (OF), need for disjoint LSP paths | Objective Function (OF), need for disjoint LSP paths, etc.). | |||
etc.); | ||||
* PCECC could calculate multiple (say N) LSPs according to given | * The PCECC could calculate multiple (say N) LSPs according to given | |||
constraints, the calculation is based on results of Objective | constraints. The calculation is based on the results of the OF | |||
Function (OF) [RFC5541], constraints, endpoints, same or different | [RFC5541], constraints, endpoints, same or different BW, different | |||
bandwidth (BW), different links (in case of disjoint paths) and | links (in case of disjoint paths), and other constraints. | |||
other constraints. | ||||
* Depending on the given LSP Path setup type (PST), PCECC will | * Depending on the given LSP PST, the PCECC will download | |||
download instructions to the PCC. At this stage, it is assumed | instructions to the PCC. At this stage, it is assumed the PCECC | |||
the PCECC is aware of the label space it controls and SID | is aware of the label space it controls and SID allocation and | |||
allocation and distribution is already done in the case of SR. | distribution is already done in the case of SR. | |||
* PCECC will send PCInitiate message [RFC8281] towards ingress AGG X | * The PCECC will send a PCInitiate message [RFC8281] towards the | |||
router(PCC) for each of N LSPs and receive PCRpt message [RFC8231] | ingress AGG X router (PCC) for each of N LSPs and receive a PCRpt | |||
back from PCCs. If PST is PCECC-SR, the PCECC will include a SID | message [RFC8231] back from PCCs. If the PST is a PCECC-SR, the | |||
stack as per [RFC8664]. If PST is PCECC (basic), then the PCECC | PCECC will include a SID stack as per [RFC8664]. If the PST is | |||
will assign labels along the calculated path and set up the path | set to "PCECC" type, then the PCECC will assign labels along the | |||
by sending central controller instructions in a PCEP message to | calculated path and set up the path by sending central controller | |||
each node along the path of the LSP as per [RFC9050] and then send | instructions in a PCEP message to each node along the path of the | |||
PCUpd message to the ingress AGG X router with information about | LSP as per [RFC9050]. Then, the PCECC will send a PCUpd message | |||
new LSP. AGG X(PCC) will respond with PCRpt with LSP status. | to the ingress AGG X router with information about the new LSP. | |||
AGG X (PCC) will respond with a PCRpt with LSP status. | ||||
* AGG X as an ingress router now has N LSPs towards AGG N and AGG | * AGG X as an ingress router now has N LSPs towards AGG N and AGG | |||
N-1 which are available for installation to the router's | N-1, which are available for installation to the router's | |||
forwarding table and load-balance traffic between them. Traffic | forwarding table and for LB traffic between them. Traffic | |||
distribution between those LSPs depends on the particular | distribution between those LSPs depends on the particular | |||
realization of the hash-function on that router. | realization of the hash function on that router. | |||
* Since PCECC is aware of TEDB (TE state) and LSP-DB, it can manage | * Since the PCECC is aware of the Traffic Engineering Database (TED) | |||
and prevent possible over-subscriptions and limit the number of | (TE state) and the LSP Database (LSP-DB), it can manage and | |||
available load-balance states. Via PCECC mechanism the control | prevent possible over-subscriptions and limit the number of | |||
available load-balance states. Via a PCECC mechanism, the control | ||||
can take quick actions into the network by directly provisioning | can take quick actions into the network by directly provisioning | |||
the central control instructions. | the central control instructions. | |||
3.5. PCECC and Inter-AS TE | 3.5. PCECC and Inter-AS TE | |||
There are various signalling options for establishing Inter-AS TE | There are various signalling options for establishing Inter-AS TE | |||
LSP: contiguous TE LSP [RFC5151], stitched TE LSP [RFC5150], and | LSPs: contiguous TE LSPs [RFC5151], stitched TE LSPs [RFC5150], and | |||
nested TE LSP [RFC4206]. | nested TE LSPs [RFC4206]. | |||
Requirements for PCE-based Inter-AS setup [RFC5376] describe the | The requirements for PCE-based Inter-AS setup [RFC5376] describe the | |||
approach and PCEP functionality that is needed for establishing | approach and PCEP functionality that is needed for establishing | |||
Inter-AS TE LSPs. | Inter-AS TE LSPs. | |||
[RFC5376] also gives Inter- and Intra-AS PCE Reference Model (as | [RFC5376] also gives an Inter-AS and Intra-AS PCE Reference Model (as | |||
shown in Figure 7) that is provided below in shortened form for the | shown in Figure 7) that is provided below in shortened form for the | |||
sake of simplicity. | sake of simplicity. | |||
Inter-AS Inter-AS | Inter-AS Inter-AS | |||
PCC <-->PCE1<--------->PCE2 | PCC <-->PCE1<--------->PCE2 | |||
:: :: :: | :: :: :: | |||
:: :: :: | :: :: :: | |||
R1----ASBR1====ASBR3---R3---ASBR5 | R1----ASBR1====ASBR3---R3---ASBR5 | |||
| AS1 | | PCC | | | AS1 | | PCC | | |||
| | | AS2 | | | | | AS2 | | |||
R2----ASBR2====ASBR4---R4---ASBR6 | R2----ASBR2====ASBR4---R4---ASBR6 | |||
:: :: | :: :: | |||
:: :: | :: :: | |||
Intra-AS Intra-AS | Intra-AS Intra-AS | |||
PCE3 PCE4 | PCE3 PCE4 | |||
Figure 7: Shortened form of Inter- and Intra-AS PCE Reference Model | Figure 7: Shortened Form of the Inter-AS and Intra-AS PCE | |||
Reference Model | ||||
The PCECC belonging to the different domains can cooperate to set up | The PCECC belonging to the different domains can cooperate to set up | |||
inter-AS TE LSP. The stateful H-PCE [RFC8751] mechanism could also | Inter-AS TE LSPs. The stateful Hierarchical PCE (H-PCE) mechanism | |||
be used to establish a per-domain PCECC LSP first. These could be | [RFC8751] could also be used to establish a per-domain PCECC LSP | |||
stitched together to form inter-AS TE LSP as described in | first. These could be stitched together to form an Inter-AS TE LSP | |||
[I-D.ietf-pce-stateful-interdomain]. | as described in [PCE-INTERDOMAIN]. | |||
For the sake of simplicity, here the focus is on a simplified Inter- | For the sake of simplicity, here the focus is on a simplified Inter- | |||
AS case when both AS1 and AS2 belong to the same service provider | AS case when both AS1 and AS2 belong to the same service provider | |||
administration. In that case, Inter and Intra-AS PCEs could be | administration. In that case, Inter-AS and Intra-AS PCEs could be | |||
combined in one single PCE if such combined PCE performance is enough | combined in one single PCE if such combined PCE performance is enough | |||
to handle the load. The PCE will require interfaces (PCEP and BGP- | to handle the load. The PCE will require interfaces (PCEP and BGP- | |||
LS) to both domains. PCECC redundancy mechanisms are described in | LS) to both domains. PCECC redundancy mechanisms are described in | |||
[RFC8283]. Thus routers (PCCs) in AS1 and AS2 can send PCEP messages | [RFC8283]. Thus, routers (PCCs) in AS1 and AS2 can send PCEP | |||
towards the same PCECC. In Figure 8, PCECC maintains a BGP-LS | messages towards the same PCECC. In Figure 8, the PCECC maintains a | |||
session with route reflectors (RRs) in each AS. This allows the RRs | BGP-LS session with Route Reflectors (RRs) in each AS. This allows | |||
to redistribute routes to other BGP routers (clients) without | the RRs to redistribute routes to other BGP routers (clients) without | |||
requiring a full mesh. The RRs act as BGP-LS Propagator and PCECC | requiring a full mesh. The RRs act as a BGP-LS Propagator, and the | |||
act as a BGP-LS Consumer [RFC9552]. | PCECC acts as a BGP-LS Consumer [RFC9552]. | |||
+----BGP-LS------+ +------BGP-LS-----+ | +----BGP-LS------+ +------BGP-LS-----+ | |||
| | | | | | | | | | |||
+-PCEP-|----++-+-------PCECC-----PCEP--++-+-|-------+ | +-PCEP-|----++-+-------PCECC-----PCEP--++-+-|-------+ | |||
+-:------|----::-:-+ +--::-:-|-------:---+ | +-:------|----::-:-+ +--::-:-|-------:---+ | |||
| : | :: : | | :: : | : | | | : | :: : | | :: : | : | | |||
| : RR1 :: : | | :: : RR2 : | | | : RR1 :: : | | :: : RR2 : | | |||
| v v: : | LSP1 | :: v v | | | v v: : | LSP1 | :: v v | | |||
| R1---------ASBR1=======================ASBR3--------R3 | | | R1---------ASBR1=======================ASBR3--------R3 | | |||
| | v : | | :v | | | | | v : | | :v | | | |||
| +----------ASBR2=======================ASBR4---------+ | | | +----------ASBR2=======================ASBR4---------+ | | |||
| | Region 1 : | | : Region 1 | | | | | Region 1 : | | : Region 1 | | | |||
|----------------:-| |--:-------------|--| | |----------------:-| |--:-------------|--| | |||
| | v | LSP2 | v | | | | | v | LSP2 | v | | | |||
| +----------ASBR5=======================ASBR6---------+ | | | +----------ASBR5=======================ASBR6---------+ | | |||
| Region 2 | | Region 2 | | | Region 2 | | Region 2 | | |||
+------------------+ <--------------> +-------------------+ | +------------------+ <--------------> +-------------------+ | |||
MPLS Domain 1 Inter-AS MPLS Domain 2 | MPLS Domain 1 Inter-AS MPLS Domain 2 | |||
<=======AS1=======> <========AS2=======> | <=======AS1=======> <========AS2=======> | |||
Figure 8: Particular case of Inter-AS PCE | Figure 8: Particular Case of Inter-AS PCE | |||
In the case of the PCECC Inter-AS TE scenario (as shown in Figure 8) | In the case of the PCECC Inter-AS TE scenario (as shown in Figure 8), | |||
where the service provider controls both domains (AS1 and AS2), each | where the service provider controls both domains (AS1 and AS2), each | |||
of them has its own IGP and MPLS transport. There is a need to set | of them has its own IGP and MPLS transport. There is a need to set | |||
up Inter-AS LSPs for transporting different services on top of them | up Inter-AS LSPs for transporting different services on top of them | |||
(Voice, L3VPN etc.). Inter-AS links with different capacities exist | (such as Voice, L3VPN, etc.). Inter-AS links with different | |||
in several regions. The task is not only to provision those Inter-AS | capacities exist in several regions. The task is not only to | |||
LSPs with given constraints but also to calculate the path and pre- | provision those Inter-AS LSPs with given constraints but also to | |||
setup the backup Inter-AS LSPs that will be used if the primary LSP | calculate the path and pre-setup the backup Inter-AS LSPs that will | |||
fails. | be used if the primary LSP fails. | |||
As per Figure 8, LSP1 from R1 to R3 goes via ASBR1 and ASBR3, and it | As per Figure 8, LSP1 from R1 to R3 goes via ASBR1 and ASBR3, and it | |||
is the primary Inter-AS LSP. R1-R3 LSP2 that goes via ASBR5 and | is the primary Inter-AS LSP. LSP2 from R1 to R3 that goes via ASBR5 | |||
ASBR6 are the backup ones. In addition, there could also be a bypass | and ASBR6 is the backup one. In addition, there could also be a | |||
LSP setup to protect against ASBR or inter-AS link failures. | bypass LSP setup to protect against ASBR or Inter-AS link failures. | |||
After the addition of PCECC functionality to PCE (SDN controller), | After the addition of PCECC functionality to the PCE (SDN | |||
the PCECC-based Inter-AS TE model should follow the PCECC use case | controller), the PCECC-based Inter-AS TE model should follow the | |||
for TE LSP including requirements of [RFC5376] with the following | PCECC use case for TE LSP including the requirements described in | |||
details: | [RFC5376] with the following details: | |||
* Since PCECC needs to know the topology of both domains AS1 and | * Since the PCECC needs to know the topology of both domains AS1 and | |||
AS2, PCECC can utilize the BGP-LS peering with BGP routers (or | AS2, the PCECC can utilize the BGP-LS peering with BGP routers (or | |||
RRs) in both domains. | RRs) in both domains. | |||
* PCECC needs to establish PCEP connectivity with all routers in | * The PCECC needs to establish PCEP connectivity with all routers in | |||
both domains (see also section 4 in [RFC5376]). | both domains (see also Section 4 of [RFC5376]). | |||
* After the operator's application or service orchestrator creates a | * After the operator's application or service orchestrator creates a | |||
request for tunnel creation of a specific service, PCECC will | request for tunnel creation of a specific service, the PCECC will | |||
receive that request via NBI (NBI type is implementation | receive that request via the Northbound Interface (NBI) (note that | |||
dependent, it could be NETCONF/Yang, REST etc.). Then PCECC will | the NBI type is implementation-dependent; it could be NETCONF/ | |||
calculate the optimal path based on Objective Function (OF) and | YANG, REST, etc.). Then, the PCECC will calculate the optimal | |||
given constraints (i.e. path setup type, bandwidth etc.), | path based on the OF and given constraints (i.e., PST, BW, etc.). | |||
including those from [RFC5376]: priority, AS sequence, preferred | These constraints include those from [RFC5376], such as priority, | |||
ASBR, disjoint paths, and protection type. In this step, we will | AS sequence, preferred ASBR, disjoint paths, and protection type. | |||
have two paths: R1-ASBR1-ASBR3-R3, R1-ASBR5-ASBR6-R3 | In this step, we will have two paths: "R1-ASBR1-ASBR3-R3, | |||
R1-ASBR5-ASBR6-R3". | ||||
* PCECC will use central control download instructions to the PCC | * The PCECC will use central control download instructions to the | |||
based on the PST. At this stage, it is assumed the PCECC is aware | PCC based on the PST. At this stage, it is assumed the PCECC is | |||
of the label space it controls and in the case of SR the SID | aware of the label space it controls, and in the case of SR, the | |||
allocation and distribution is already done. | SID allocation and distribution is already done. | |||
* PCECC will send PCInitiate message [RFC8281] towards the ingress | * The PCECC will send a PCInitiate message [RFC8281] towards the | |||
router R1 (PCC) in AS1 and receive the PCRpt message [RFC8231] | ingress router R1 (PCC) in AS1 and receive the PCRpt message | |||
back from it. | [RFC8231] back from it. | |||
- If the PST is SR-MPLS, the PCECC will include the SID stack as | - If the PST is SR-MPLS, the PCECC will include the SID stack as | |||
per [RFC8664]. Optionally, a binding SID or BGP Peering-SID | per [RFC8664]. Optionally, a BSID or BGP Peering-SID [RFC9087] | |||
[RFC9087] can also be included on the AS boundary. The backup | can also be included on the AS boundary. The backup SID stack | |||
SID stack can be installed at ingress R1 but more importantly, | can be installed at ingress R1, but more importantly, each node | |||
each node along the SR path could also do the local protection | along the SR path could also do the local protection just based | |||
just based on the top segment. | on the top segment. | |||
- If the PST is PCECC, the PCECC will assign labels along the | - If the PST is a PCECC, the PCECC will assign labels along the | |||
calculated paths (R1-ASBR1-ASBR3-R3, R1-ASBR5-ASBR6-R3) and | calculated paths ("R1-ASBR1-ASBR3-R3", "R1-ASBR5-ASBR6-R3") and | |||
sets up the path by sending central controller instructions in | sets up the path by sending central controller instructions in | |||
PCEP message to each node along the path of the LSPs as per | a PCEP message to each node along the path of the LSPs as per | |||
[RFC9050]. After these steps, the PCECC will send a PCUpd | [RFC9050]. After these steps, the PCECC will send a PCUpd | |||
message to the ingress R1 router with information about new | message to the ingress R1 router with information about new | |||
LSPs and R1 will respond by PCRpt with LSP(s) status. | LSPs and R1 will respond by a PCRpt with LSP(s) status. | |||
* After that step, R1 now have primary and backup TEs (LSP1 and | * After that step, R1 now has primary and backup TEs (LSP1 and LSP2) | |||
LSP2) towards R3. It is up to router implementation how to make | towards R3. It is up to the router implementation for how to | |||
switchover to backup LSP2 if LSP1 fails. | switchover to backup LSP2 if LSP1 fails. | |||
3.6. PCECC for Multicast LSPs | 3.6. PCECC for Multicast LSPs | |||
The multicast LSPs can be set up via the RSVP-TE P2MP or Multipoint | The multicast LSPs can be set up via the RSVP-TE P2MP or Multipoint | |||
LDP (mLDP) protocols. The setup of these LSPs may require manual | LDP (mLDP) protocols. The setup of these LSPs may require manual | |||
configurations and complex signalling when the protection is | configurations and complex signalling when the protection is | |||
considered. By using the PCECC solution, the multicast LSP can be | considered. By using the PCECC solution, the multicast LSP can be | |||
computed and set up through a centralized controller which has the | computed and set up through a centralized controller that has the | |||
full picture of the topology and bandwidth usage for each link. It | full picture of the topology and BW usage for each link. It not only | |||
not only reduces the complex configurations comparing the distributed | reduces the complex configurations comparing the distributed RSVP-TE | |||
RSVP-TE P2MP or mLDP signalling, but also it can compute the disjoint | P2MP or mLDP signalling, but also it can compute the disjoint primary | |||
primary path and secondary P2MP path efficiently. | path and secondary P2MP path efficiently. | |||
3.6.1. PCECC for P2MP/MP2MP LSPs' Setup | 3.6.1. PCECC for the Setup of P2MP/MP2MP LSPs | |||
It is assumed the PCECC is aware of the label space it controls for | It is assumed the PCECC is aware of the label space it controls for | |||
all nodes and makes allocations accordingly. | all nodes and makes allocations accordingly. | |||
+----------+ | +----------+ | |||
| R1 | Root node of the multicast LSP | | R1 | Root Node of the multicast LSP | |||
+----------+ | +----------+ | |||
|9000 (L0) | |9000 (link0) | |||
+----------+ | +----------+ | |||
Transit Node | R2 | | Transit Node | R2 | | |||
branch +----------+ | branch +----------+ | |||
* | * * | * | * * | |||
9001* | * *9002 | 9001* | * *9002 | |||
L1 * | * *L2 | link1 * | * *link2 | |||
+-----------+ | * +-----------+ | +-----------+ | * +-----------+ | |||
| R4 | | * | R5 | Transit Nodes | | R4 | | * | R5 | Transit Nodes | |||
+-----------+ | * +-----------+ | +-----------+ | * +-----------+ | |||
* | * * + | * | * * + | |||
9003* | * * +9004 | 9003* | * * +9004 | |||
L3 * | * * +L4 | link3 * | * * +link4 | |||
+-----------+ +-----------+ | +-----------+ +-----------+ | |||
| R3 | | R6 | Leaf Node | | R3 | | R6 | Leaf Node | |||
+-----------+ +-----------+ | +-----------+ +-----------+ | |||
9005| L5 | 9005| link5 | |||
+-----------+ | +-----------+ | |||
| R8 | Leaf Node | | R8 | Leaf Node | |||
+-----------+ | +-----------+ | |||
Figure 9: Using PCECC for P2MP/MP2MP LSPs' Setup | Figure 9: Using a PCECC for the Setup of P2MP/MP2MP LSPs | |||
The P2MP examples (based on Figure 9) are explained here, where R1 is | The P2MP examples (based on Figure 9) are explained here, where R1 is | |||
the root and the router R8 and R6 are the leaves. | the root and the routers R8 and R6 are the leaves. | |||
* Based on the P2MP path computation request/delegation or PCE | * Based on the P2MP path computation request/delegation or PCE | |||
initiation, the PCECC receives the request with constraints and | initiation, the PCECC receives the request with constraints and | |||
optimization criteria. | optimization criteria. | |||
* PCECC will calculate the optimal P2MP path according to given | * The PCECC will calculate the optimal P2MP path according to given | |||
constraints (i.e.bandwidth). | constraints (i.e., BW). | |||
* PCECC will provision each node along the path and assign incoming | * The PCECC will provision each node along the path and assign | |||
and outgoing labels from R1 to {R6, R8} with the path as | incoming and outgoing labels from R1 to {R6, R8} with the path as | |||
"R1-L0-R2-L2-R5-L4-R6" and "R1-L0-R2-L1-R4-L3-R3-L5-R8": | "R1-link0-R2-link2-R5-link4-R6" and | |||
"R1-link0-R2-link1-R4-link3-R3-link5-R8": | ||||
- R1: Outgoing label 9000 on link L0 | - R1: Outgoing label 9000 on link0 | |||
- R2: Incoming label 9000 on link L0 | - R2: Incoming label 9000 on link0 | |||
- R2: Outgoing label 9001 on link L1 (*) | - R2: Outgoing label 9001 on link1 (*) | |||
- R2: Outgoing label 9002 on link L2 (*) | - R2: Outgoing label 9002 on link2 (*) | |||
- R5: Incoming label 9002 on link L2 | ||||
- R5: Outgoing label 9004 on link L4 | - R5: Incoming label 9002 on link2 | |||
- R6: Incoming label 9004 on link L4 | - R5: Outgoing label 9004 on link4 | |||
- R4: Incoming label 9001 on link L1 | - R6: Incoming label 9004 on link4 | |||
- R4: Outgoing label 9003 on link L3 | - R4: Incoming label 9001 on link1 | |||
- R3: Incoming label 9003 on link L3 | - R4: Outgoing label 9003 on link3 | |||
- R3: Outgoing label 9005 on link L5 | - R3: Incoming label 9003 on link3 | |||
- R8: Incoming label 9005 on link L5 | - R3: Outgoing label 9005 on link5 | |||
* This can also be represented as : {R1, 6000}, {6000, R2, | - R8: Incoming label 9005 on link5 | |||
{9001,9002}}, {9001, R4, 9003}, {9002, R5, 9004} {9003, R3, 9005}, | ||||
* This can also be represented as: {R1, 6000}, {6000, R2, {9001, | ||||
9002}}, {9001, R4, 9003}, {9002, R5, 9004} {9003, R3, 9005}, | ||||
{9004, R6}, {9005, R8}. The main difference (*) is in the branch | {9004, R6}, {9005, R8}. The main difference (*) is in the branch | |||
node instruction at R2 where two copies of a packet are sent | node instruction at R2, where two copies of a packet are sent | |||
towards R4 and R5 with 9001 and 9002 labels respectively. | towards R4 and R5 with 9001 and 9002 labels, respectively. | |||
The packet forwarding involves - | The packet forwarding involves the following: | |||
Step 1: R1 sends a packet to R2 simply by pushing the label of | Step 1. R1 sends a packet to R2 simply by pushing the label of 9000 | |||
9000 to the packet. | to the packet. | |||
Step 2: When R2 receives the packet with label 9000, it will | Step 2. When R2 receives the packet with label 9000, it will forward | |||
forward it to R4 by swapping label 9000 to 9001 and at the same | it to R4 by swapping label 9000 to 9001. At the same time, | |||
time, it will replicate the packet and swap the label 9000 to 9002 | it will replicate the packet and swap the label 9000 to 9002 | |||
and forward it to R5. | and forward it to R5. | |||
Step 3: When R4 receives the packet with label 9001, it will | Step 3. When R4 receives the packet with label 9001, it will forward | |||
forward it to R3 by swapping 9001 to 9003. When R5 receives the | it to R3 by swapping 9001 to 9003. When R5 receives the | |||
packet with the label 9002, it will forward it to R6 by swapping | packet with the label 9002, it will forward it to R6 by | |||
9002 to 9004. | swapping 9002 to 9004. | |||
Step 4: When R3 receives the packet with label 9003, it will | Step 4. When R3 receives the packet with label 9003, it will forward | |||
forward it to R8 by swapping it to 9005 and when R5 receives the | it to R8 by swapping it to 9005. When R5 receives the | |||
packet with label 9002, it will be swapped to 9004 and sent to R6. | packet with label 9002, it will be swapped to 9004 and sent | |||
to R6. | ||||
Step 5: When R8 receives the packet with label 9005, it will pop | Step 5. When R8 receives the packet with label 9005, it will pop the | |||
the label; when R6 receives the packet with label 9004, it will | label. When R6 receives the packet with label 9004, it will | |||
pop the label. | pop the label. | |||
3.6.2. PCECC for the End-to-End Protection of P2MP/MP2MP LSPs | 3.6.2. PCECC for the End-to-End Protection of P2MP/MP2MP LSPs | |||
In this section, the end-to-end managed path protection service as | This section describes the end-to-end managed path protection service | |||
well as the local protection with the operation management in the | as well as the local protection with the operation management in the | |||
PCECC network for the P2MP/MP2MP LSP. | PCECC network for the P2MP/MP2MP LSP. | |||
An end-to-end protection principle can be applied for computing | An end-to-end protection principle can be applied for computing | |||
backup P2MP or MP2MP LSPs. During the computation of the primary | backup P2MP or MP2MP LSPs. During the computation of the primary | |||
multicast trees, PCECC could also take the computation of a secondary | multicast trees, the PCECC could also take the computation of a | |||
tree into consideration. A PCECC could compute the primary and | secondary tree into consideration. A PCECC could compute the primary | |||
backup P2MP (or MP2MP) LSPs together or sequentially. | and backup P2MP (or MP2MP) LSPs together or sequentially. | |||
+----+ +----+ | +----+ +----+ | |||
Root node of LSP | R1 |--| R11| | Root Node of LSP | R1 |--| R11| | |||
+----+ +----+ | +----+ +----+ | |||
/ + | / + | |||
10/ +20 | 10/ +20 | |||
/ + | / + | |||
+----------+ +-----------+ | +----------+ +-----------+ | |||
Transit Node | R2 | | R3 | | Transit Node | R2 | | R3 | | |||
+----------+ +-----------+ | +----------+ +-----------+ | |||
| \ + + | | \ + + | |||
| \ + + | | \ + + | |||
10| 10\ +20 20+ | 10| 10\ +20 20+ | |||
| \ + + | | \ + + | |||
| \ + | | \ + | |||
| + \ + | | + \ + | |||
+-----------+ +-----------+ Leaf Nodes | +-----------+ +-----------+ Leaf Nodes | |||
| R4 | | R5 | (Downstream LSR) | | R4 | | R5 | (Downstream LSR) | |||
+-----------+ +-----------+ | +-----------+ +-----------+ | |||
Figure 10: PCECC for the End-to-End Protection of the P2MP/MP2MP LSPs | Figure 10: PCECC for the End-to-End Protection of P2MP/MP2MP LSPs | |||
In Figure 10, when the PCECC setups the primary multicast tree from | In Figure 10, when the PCECC sets up the primary multicast tree from | |||
the root node R1 to the leaves, which is R1->R2->{R4, R5}, at the | the root node R1 to the leaves, which is R1->R2->{R4, R5}, it can set | |||
same time, it can setup the backup tree, which is R1->R11->R3->{R4, | up the backup tree at the same time, which is R1->R11->R3->{R4, R5}. | |||
R5}. Both of them (primary forwarding tree and secondary forwarding | Both of them (the primary forwarding tree and secondary forwarding | |||
tree) will be downloaded to each router along the primary path and | tree) will be downloaded to each router along the primary path and | |||
the secondary path. The traffic will be forwarded through the | the secondary path. The traffic will be forwarded through the | |||
R1->R2->{R4, R5} path normally, but when a node in the primary tree | R1->R2->{R4, R5} path normally, but when a node in the primary tree | |||
fails (say R2) the root node R1 will switch the flow to the backup | fails (say R2), the root node R1 will switch the flow to the backup | |||
tree, which is R1->R11->R3->{R4, R5}. By using the PCECC a path | tree, which is R1->R11->R3->{R4, R5}. By using the PCECC, path | |||
computation, label downloading and finally forwarding can be done | computation, label downloading, and finally forwarding can be done | |||
without complex signalling used in the P2MP RSVP-TE or mLDP. | without the complex signalling used in the P2MP RSVP-TE or mLDP. | |||
3.6.3. PCECC for the Local Protection of the P2MP/MP2MP LSPs | 3.6.3. PCECC for the Local Protection of P2MP/MP2MP LSPs | |||
In this section, we describe the local protection service in the | In this section, we describe the local protection service in the | |||
PCECC network for the P2MP/MP2MP LSP. | PCECC network for the P2MP/MP2MP LSP. | |||
While the PCECC sets up the primary multicast tree, it can also build | While the PCECC sets up the primary multicast tree, it can also build | |||
the backup LSP between the Point of Local Repair (PLR), the protected | the backup LSP between the Point of Local Repair (PLR), protected | |||
node and Merge Points (MPs) (the downstream nodes of the protected | node, and Merge Points (MPs) (the downstream nodes of the protected | |||
node). In the cases where the amount of downstream nodes is huge, | node). In the cases where the amount of downstream nodes is huge, | |||
this mechanism can avoid unnecessary packet duplication on PLR and | this mechanism can avoid unnecessary packet duplication on the PLR | |||
protect the network from traffic congestion risk. | and protect the network from traffic congestion risks. | |||
+------------+ | +------------+ | |||
| R1 | Root Node | | R1 | Root Node | |||
+------------+ | +------------+ | |||
. | . | |||
. | . | |||
. | . | |||
+------------+ Point of Local Repair/ | +------------+ Point of Local Repair / | |||
| R10 | Switchover Point | | R10 | Switchover Point | |||
+------------+ (Upstream LSR) | +------------+ (Upstream LSR) | |||
/ + | / + | |||
10/ +20 | 10/ +20 | |||
/ + | / + | |||
+----------+ +-----------+ | +----------+ +-----------+ | |||
Protected Node | R20 | | R30 | | Protected Node | R20 | | R30 | | |||
+----------+ +-----------+ | +----------+ +-----------+ | |||
| \ + + | | \ + + | |||
| \ + + | | \ + + | |||
10| 10\ +20 20+ | 10| 10\ +20 20+ | |||
| \ + + | | \ + + | |||
| \ + | | \ + | |||
| + \ + | | + \ + | |||
+-----------+ +-----------+ Merge Point | +-----------+ +-----------+ Merge Point | |||
| R40 | | R50 | (Downstream LSR) | | R40 | | R50 | (Downstream LSR) | |||
+-----------+ +-----------+ | +-----------+ +-----------+ | |||
. . | . . | |||
. . | . . | |||
Figure 11: PCECC for the Local Protection of the P2MP/MP2MP LSPs | Figure 11: PCECC for the Local Protection of P2MP/MP2MP LSPs | |||
In Figure 11, when the PCECC setups the primary multicast path around | In Figure 11, when the PCECC sets up the primary multicast path | |||
the PLR node R10 to protect node R20, which is R10->R20->{R40, R50}, | around the PLR node R10 to protect node R20, which is R10->R20->{R40, | |||
at the same time, it can set up the backup path R10->R30->{R40, R50}. | R50}, it can set up the backup path R10->R30->{R40, R50} at the same | |||
Both the primary forwarding path and secondary bypass forwarding path | time. Both the primary forwarding path and the secondary bypass | |||
will be downloaded to each router along the primary path and the | forwarding path will be downloaded to each router along the primary | |||
secondary bypass path. The traffic will be forwarded through the | path and the secondary bypass path. The traffic will be forwarded | |||
R10->R20->{R40, R50} path normally and when there is a node failure | through the R10->R20->{R40, R50} path normally, and when there is a | |||
for node R20, the PLR node R10 will switch the flow to the backup | node failure for node R20, the PLR node R10 will switch the flow to | |||
path, which is R10->R30->{R40, R50}. By using the PCECC, path | the backup path, which is R10->R30->{R40, R50}. By using the PCECC, | |||
computation, label downloading and finally forwarding can be done | path computation, label downloading, and finally forwarding can be | |||
without complex signalling used in the P2MP RSVP-TE or mLDP. | done without the complex signalling used in the P2MP RSVP-TE or mLDP. | |||
3.7. PCECC for Traffic Classification | 3.7. PCECC for Traffic Classification | |||
As described in [RFC8283], traffic classification is an important | As described in [RFC8283], traffic classification is an important | |||
part of traffic engineering. It is the process of looking into a | part of traffic engineering. It is the process of looking into a | |||
packet to determine how it should be treated while it is forwarded | packet to determine how it should be treated while it is forwarded | |||
through the network. It applies in many scenarios including the | through the network. It applies in many scenarios, including the | |||
following: | following: | |||
MPLS traffic engineering (where it determines what traffic is | * MPLS traffic engineering (where it determines what traffic is | |||
forwarded into which LSPs), | forwarded into which LSPs), | |||
Segment Routing (where it is used to select which set of | * SR (where it is used to select which set of forwarding | |||
forwarding instructions (SIDs) to add to a packet), | instructions (SIDs) to add to a packet), and | |||
SFC (where it indicates how a packet should be forwarded across | * SFC (where it indicates how a packet should be forwarded across | |||
which service function path ). | which service function path). | |||
In conjunction with traffic engineering, traffic classification is an | In conjunction with traffic engineering, traffic classification is an | |||
important enabler for load balancing. Traffic classification is | important enabler for LB. Traffic classification is closely linked | |||
closely linked to the computational elements of planning for the | to the computational elements of planning for the network functions | |||
network functions because it determines how traffic is balanced and | because it determines how traffic is balanced and distributed through | |||
distributed through the network. Therefore, selecting what traffic | the network. Therefore, selecting what traffic classification | |||
classification mechanism should be performed by a router is an | mechanism should be performed by a router is an important part of the | |||
important part of the work done by a PCECC. | work done by a PCECC. | |||
The description of traffic flows by the combination of multiple Flow | The description of traffic flows by the combination of multiple Flow | |||
Specification components and their dissemination as traffic flow | Specification components and their dissemination as traffic Flow | |||
specifications (Flow Specifications) is described for BGP in | Specifications is described for BGP in [RFC8955]. When a PCECC is | |||
[RFC8955]. When a PCECC is used to initiate tunnels (such as TE-LSPs | used to initiate tunnels (such as TE LSPs or SR paths) using PCEP, it | |||
or SR paths) using PCEP, it is important that the head end of the | is important that the headend of the tunnels understands what traffic | |||
tunnels understands what traffic to place on each tunnel. [RFC9168] | to place on each tunnel. [RFC9168] specifies a set of extensions to | |||
specifies a set of extensions to PCEP to support the dissemination of | PCEP to support the dissemination of Flow Specification components | |||
Flow Specification components where the instructions are passed from | where the instructions are passed from the PCECC to the routers using | |||
the PCECC to the routers using PCEP. | PCEP. | |||
Along with traffic classification, there are a few more questions | Along with traffic classification, there are a few more questions | |||
that need to be considered after path setup: | about the tunnels set up by the PCECC that need to be considered: | |||
* how to use it | * how to use it, | |||
* Whether it is a virtual link | * whether it is a virtual link, | |||
* Whether to advertise it in the IGP as a virtual link | * whether to advertise it in the IGP as a virtual link, and | |||
* What bits of this information to signal to the tail end | ||||
* what bits of this information to signal to the tail end. | ||||
These are out of the scope of this document. | These are out of the scope of this document. | |||
3.8. PCECC for SFC | 3.8. PCECC for SFC | |||
Service Function Chaining (SFC) is described in [RFC7665]. It is the | Service Function Chaining (SFC) is described in [RFC7665]. It is the | |||
process of directing traffic in a network such that it passes through | process of directing traffic in a network such that it passes through | |||
specific hardware devices or virtual machines (known as service | specific hardware devices or virtual machines (known as service | |||
function nodes) that can perform particular desired functions on the | function nodes) that can perform particular desired functions on the | |||
traffic. The set of functions to be performed and the order in which | traffic. The set of functions to be performed and the order in which | |||
they are to be performed is known as a service function chain. The | they are to be performed is known as a service function chain. The | |||
chain is enhanced with the locations at which the service functions | chain is enhanced with the locations at which the service functions | |||
are to be performed to derive a Service Function Path (SFP). Each | are to be performed to derive a Service Function Path (SFP). Each | |||
packet is marked as belonging to a specific SFP, and that marking | packet is marked as belonging to a specific SFP, and that marking | |||
lets each successive service function node know which functions to | lets each successive service function node know which functions to | |||
perform and to which service function node to send the packet next. | perform and to which service function node to send the packet next. | |||
To operate an SFC network, the service function nodes must be | To operate an SFC network, the service function nodes must be | |||
configured to understand the packet markings, and the edge nodes must | configured to understand the packet markings, and the edge nodes must | |||
be told how to mark packets entering the network. Additionally, it | be told how to mark packets entering the network. Additionally, it | |||
may be necessary to establish tunnels between service function nodes | may be necessary to establish tunnels between service function nodes | |||
to carry the traffic. Planning an SFC network requires load | to carry the traffic. Planning an SFC network requires LB between | |||
balancing between service function nodes and traffic engineering | service function nodes and traffic engineering across the network | |||
across the network that connects them. As per [RFC8283], these are | that connects them. As per [RFC8283], these are operations that can | |||
operations that can be performed by a PCE-based controller, and that | be performed by a PCECC, and that controller can use PCEP to program | |||
controller can use PCEP to program the network and install the | the network and install the service function chains and any required | |||
service function chains and any required tunnels. | tunnels. | |||
A possible mechanism could add support for SFC-based central control | A possible mechanism could add support for SFC-based central control | |||
instructions. PCECC will be able to instruct each SFF along the SFP. | instructions. The PCECC will be able to instruct each Service | |||
Function Forwarder (SFF) along the SFP. | ||||
* Service Path Identifier (SPI): Uniquely identifies an SFP. | * Service Path Identifier (SPI): Uniquely identifies an SFP. | |||
* Service Index (SI): Provides location within the SFP. | * Service Index (SI): Provides location within the SFP. | |||
* SFC Proxy handling | * Provide SFC Proxy handling instruction. | |||
PCECC can play the role of setting the traffic classification rules | The PCECC can play the role of setting the traffic classification | |||
(as per Section 3.7) at the classifier to impose the Network Service | rules (as per Section 3.7) at the classifier to impose the Network | |||
Header (NSH) [RFC8300] as well as downloading the forwarding | Service Header (NSH) [RFC8300]. It can also download the forwarding | |||
instructions to each SFF along the way so that they could process the | instructions to each SFF along the way so that they could process the | |||
NSH and forward accordingly. Including instructions for the service | NSH and forward accordingly. This includes instructions for the | |||
classifier that handles the context header, metadata etc. This | service classifier that handles the context header, metadata, etc. | |||
metadata/context is shared amongst SFs and classifiers, between SFs, | This metadata/context is shared amongst SFs and classifiers, between | |||
and between external systems (such as PCECC) and SFs. As described | SFs, and between external systems (such as a PCECC) and SFs. As | |||
in [RFC7665], the SFC encapsulation enables the sharing of metadata/ | described in [RFC7665], the SFC encapsulation enables the sharing of | |||
context information along the SFP. | metadata/context information along the SFP. | |||
It is also possible to support SFC with SR in conjunction with or | It is also possible to support SFC with SR in conjunction with or | |||
without NSH such as [RFC9491] and | without an NSH such as described in [RFC9491] and [SR-SERVICE]. | |||
[I-D.ietf-spring-sr-service-programming]. PCECC technique can also | PCECC techniques can also be used for service-function-related | |||
be used for service function-related segments and SR service | segments and SR service policies. | |||
policies. | ||||
3.9. PCECC for Native IP | 3.9. PCECC for Native IP | |||
[RFC8735] describes the scenarios and simulation results for the | [RFC8735] describes the scenarios and simulation results for the | |||
"Centrally Control Dynamic Routing (CCDR)" solution, which integrates | "Centralized Control Dynamic Routing (CCDR)" solution, which | |||
the advantage of using distributed protocols (IGP/BGP) and the power | integrates the advantage of using distributed protocols (IGP/BGP) and | |||
of a centralized control technology (PCE/SDN), providing traffic | the power of a centralized control technology (PCE/SDN), providing | |||
engineering for native IP networks. [RFC8821] defines the framework | traffic engineering for native IP networks. [RFC8821] defines the | |||
for CCDR traffic engineering within a Native IP network, using | framework for CCDR traffic engineering within a native IP network, | |||
multiple BGP sessions and a PCE as the centralized controller. It | using multiple BGP sessions and a PCE as the centralized controller. | |||
requires the PCECC to send the instructions to the PCCs, to build | It requires the PCECC to send the instructions to the PCCs to build | |||
multiple BGP sessions, distribute different prefixes on the | multiple BGP sessions, distribute different prefixes on the | |||
established BGP sessions and assign the different paths to the BGP | established BGP sessions, and assign the different paths to the BGP | |||
next hops. PCEP protocol is used to transfer the key parameters | next hops. The PCEP is used to transfer the key parameters between | |||
between PCE and the underlying network devices (PCC) using the PCECC | the PCE and the underlying network devices (PCC) using the PCECC | |||
technique. The central control instructions from PCECC to PCC will | technique. The central control instructions from the PCECC to PCC | |||
identify which prefix should be advertised on which BGP session. | will identify which prefix should be advertised on which BGP session. | |||
There are PCEP extensions defined in | There are PCEP extensions defined in [PCEP-NATIVE] for it. | |||
[I-D.ietf-pce-pcep-extension-native-ip] for it. | ||||
+------+ | +------+ | |||
+----------+ PCECC+-------+ | +----------+ PCECC+-------+ | |||
| +------+ | | | +------+ | | |||
| | | | | | |||
PCEP | BGP Session 1(lo11/lo21)| PCEP | PCEP | BGP Session 1(lo11/lo21)| PCEP | |||
+-------------------------+ | +-------------------------+ | |||
| | | | | | |||
| BGP Session 2(lo12/lo22)| | | BGP Session 2(lo12/lo22)| | |||
+-------------------------+ | +-------------------------+ | |||
PF12 | | PF22 | PF12 | | PF22 | |||
PF11 | | PF21 | PF11 | | PF21 | |||
+---+ +-----+-----+ +-----+-----+ +---+ | +---+ +-----+-----+ +-----+-----+ +---+ | |||
|SW1+---------+(lo11/lo12)+-------------+(lo21/lo22)+-----------+SW2| | |SW1+---------+(lo11/lo12)+-------------+(lo21/lo22)+-----------+SW2| | |||
+---+ | R1 +-------------+ R2 | +---+ | +---+ | R1 +-------------+ R2 | +---+ | |||
+-----------+ +-----------+ | +-----------+ +-----------+ | |||
Figure 12: PCECC for Native IP | Figure 12: PCECC for Native IP | |||
In the case, as shown in Figure 12, PCECC will instruct both R1 and | In the case as shown in Figure 12, the PCECC will instruct both R1 | |||
R2 via PCEP how to form BGP sessions with each other and which IP | and R2 how to form BGP sessions with each other via PCEP and which IP | |||
prefixes need to be advertised via which BGP session. | prefixes need to be advertised via which BGP session. | |||
3.10. PCECC for BIER | 3.10. PCECC for BIER | |||
Bit Index Explicit Replication (BIER) [RFC8279] defines an | Bit Index Explicit Replication (BIER) [RFC8279] defines an | |||
architecture where all intended multicast receivers are encoded as a | architecture where all intended multicast receivers are encoded as a | |||
bitmask in the multicast packet header within different | BitMask in the multicast packet header within different | |||
encapsulations. A router that receives such a packet will forward | encapsulations. A router that receives such a packet will forward | |||
that packet based on the bit position in the packet header towards | that packet based on the bit position in the packet header towards | |||
the receiver(s) following a precomputed tree for each of the bits in | the receiver(s) following a precomputed tree for each of the bits in | |||
the packet. Each receiver is represented by a unique bit in the | the packet. Each receiver is represented by a unique bit in the | |||
bitmask. | BitMask. | |||
BIER-TE [RFC9262] shares architecture and packet formats with BIER. | BIER-TE [RFC9262] shares architecture and packet formats with BIER. | |||
BIER-TE forwards and replicates packets based on a BitString in the | BIER-TE forwards and replicates packets based on a BitString in the | |||
packet header, but every BitPosition of the BitString of a BIER-TE | packet header, but every BitPosition of the BitString of a BIER-TE | |||
packet indicates one or more adjacencies. BIER-TE paths can be | packet indicates one or more adjacencies. BIER-TE paths can be | |||
derived from a PCE and used at the ingress ( a possible mechanism is | derived from a PCE and used at the ingress (a possible mechanism is | |||
described in [I-D.chen-pce-bier]). | described in [PCEP-BIER]). | |||
PCECC mechanism could be used for the allocation of bits for the BIER | The PCECC mechanism could be used for the allocation of bits for the | |||
router for BIER as well as for the adjacencies for BIER-TE. PCECC- | BIER router for BIER as well as for the adjacencies for BIER-TE. | |||
based controllers can use PCEP to instruct the BIER-capable routers | PCECC-based controllers can use PCEP to instruct the BIER-capable | |||
on the meaning of the bits as well as other fields needed for BIER | routers on the meaning of the bits as well as other fields needed for | |||
encapsulation. The PCECC could be used to program the BIER router | BIER encapsulation. The PCECC could be used to program the BIER | |||
with various parameters used in the BIER encapsulation such as BIER | router with various parameters used in the BIER encapsulation (such | |||
subdomain-ID, BFR-ID, BIER Encapsulation etc. for both node and | as BIER sub-domain-id, BFR-id, etc.) for both node and adjacency. | |||
adjacency. | ||||
A possible way for the PCECC usage and PCEP extension is described in | A possible way to use the PCECC and PCEP extension is described in | |||
[I-D.chen-pce-pcep-extension-pce-controller-bier]. | [PCECC-BIER]. | |||
4. IANA Considerations | 4. IANA Considerations | |||
This document does not require any action from IANA. | This document has no IANA actions. | |||
5. Security Considerations | 5. Security Considerations | |||
[RFC8283] describes how the security considerations for a PCE-based | [RFC8283] describes how the security considerations for a PCECC are a | |||
controller are a little different from those for any other PCE | little different from those for any other PCE system. PCECC | |||
system. PCECC operations rely heavily on the use and security of | operations rely heavily on the use and security of PCEP, so due | |||
PCEP, so due consideration should be given to the security features | consideration should be given to the security features discussed in | |||
discussed in [RFC5440] and the additional mechanisms described in | [RFC5440] and the additional mechanisms described in [RFC8253]. It | |||
[RFC8253]. It further lists the vulnerability of a central | further lists the vulnerability of a central controller architecture, | |||
controller architecture, such as a central point of failure, denial | such as a central point of failure, denial of service, and a focus on | |||
of service, and a focus on interception and modification of messages | interception and modification of messages sent to individual Network | |||
sent to individual Network Elements (NEs). | Elements (NEs). | |||
As per [RFC9050], the use of Transport Layer Security (TLS) in PCEP | As per [RFC9050], the use of Transport Layer Security (TLS) in PCEP | |||
is recommended, as it provides support for peer authentication, | is recommended, as it provides support for peer authentication, | |||
message encryption, and integrity. It further provides mechanisms | message encryption, and integrity. It further provides mechanisms | |||
for associating peer identities with different levels of access and/ | for associating peer identities with different levels of access and/ | |||
or authoritativeness via an attribute in X.509 certificates or a | or authoritativeness via an attribute in X.509 certificates or a | |||
local policy with a specific accept-list of X.509 certificates. This | local policy with a specific accept-list of X.509 certificates. This | |||
can be used to check the authority for the PCECC operations. | can be used to check the authority for the PCECC operations. | |||
It is expected that each new document that is produced for a specific | It is expected that each new document that is produced for a specific | |||
use case will also include considerations of the security impacts of | use case will also include considerations of the security impacts of | |||
the use of a PCE-based central controller on the network type and | the use of a PCECC on the network type and services being managed. | |||
services being managed. | ||||
6. Acknowledgments | ||||
Thanks to Adrian Farrel, Aijun Wang, Robert Tao, Changjiang Yan, | ||||
Tieying Huang, Sergio Belotti, Dieter Beller, Andrey Elperin and | ||||
Evgeniy Brodskiy for their useful comments and suggestions. | ||||
Thanks to Mach Chen and Carlos Pignataro for the RTGDIR review. | ||||
Thanks to Derrell Piper for the SECDIR review. Thanks to Sue Hares | ||||
for GENART review. | ||||
Thanks to Vishnu Pavan Beeram for being the document shepherd and Jim | ||||
Guichard for being the responsible AD. | ||||
Thanks to Roman Danyliw for the IESG review comments. | ||||
7. References | 6. References | |||
7.1. Normative References | 6.1. Normative References | |||
[RFC5440] Vasseur, JP., Ed. and JL. Le Roux, Ed., "Path Computation | [RFC5440] Vasseur, JP., Ed. and JL. Le Roux, Ed., "Path Computation | |||
Element (PCE) Communication Protocol (PCEP)", RFC 5440, | Element (PCE) Communication Protocol (PCEP)", RFC 5440, | |||
DOI 10.17487/RFC5440, March 2009, | DOI 10.17487/RFC5440, March 2009, | |||
<https://www.rfc-editor.org/info/rfc5440>. | <https://www.rfc-editor.org/info/rfc5440>. | |||
[RFC7665] Halpern, J., Ed. and C. Pignataro, Ed., "Service Function | [RFC7665] Halpern, J., Ed. and C. Pignataro, Ed., "Service Function | |||
Chaining (SFC) Architecture", RFC 7665, | Chaining (SFC) Architecture", RFC 7665, | |||
DOI 10.17487/RFC7665, October 2015, | DOI 10.17487/RFC7665, October 2015, | |||
<https://www.rfc-editor.org/info/rfc7665>. | <https://www.rfc-editor.org/info/rfc7665>. | |||
skipping to change at page 31, line 28 ¶ | skipping to change at line 1385 ¶ | |||
Architecture for Use of PCE and the PCE Communication | Architecture for Use of PCE and the PCE Communication | |||
Protocol (PCEP) in a Network with Central Control", | Protocol (PCEP) in a Network with Central Control", | |||
RFC 8283, DOI 10.17487/RFC8283, December 2017, | RFC 8283, DOI 10.17487/RFC8283, December 2017, | |||
<https://www.rfc-editor.org/info/rfc8283>. | <https://www.rfc-editor.org/info/rfc8283>. | |||
[RFC8402] Filsfils, C., Ed., Previdi, S., Ed., Ginsberg, L., | [RFC8402] Filsfils, C., Ed., Previdi, S., Ed., Ginsberg, L., | |||
Decraene, B., Litkowski, S., and R. Shakir, "Segment | Decraene, B., Litkowski, S., and R. Shakir, "Segment | |||
Routing Architecture", RFC 8402, DOI 10.17487/RFC8402, | Routing Architecture", RFC 8402, DOI 10.17487/RFC8402, | |||
July 2018, <https://www.rfc-editor.org/info/rfc8402>. | July 2018, <https://www.rfc-editor.org/info/rfc8402>. | |||
7.2. Informative References | 6.2. Informative References | |||
[I-D.cbrt-pce-stateful-local-protection] | [MAP-REDUCE] | |||
Lee, K., Choi, T., Ganguly, A., Wolinsky, D., Boykin, P., | ||||
and R. Figueiredo, "Parallel Processing Framework on a P2P | ||||
System Using Map and Reduce Primitives", | ||||
DOI 10.1109/IPDPS.2011.315, May 2011, | ||||
<https://leeky.me/publications/mapreduce_p2p.pdf>. | ||||
[MPLS-DC] Afanasiev, D. and D. Ginsburg, "MPLS in DC and inter-DC | ||||
networks: the unified forwarding mechanism for network | ||||
programmability at scale", March 2014, | ||||
<https://www.slideshare.net/DmitryAfanasiev1/yandex- | ||||
nag201320131031>. | ||||
[MPLS-SEAMLESS] | ||||
Leymann, N., Ed., Decraene, B., Filsfils, C., | ||||
Konstantynowicz, M., Ed., and D. Steinberg, "Seamless MPLS | ||||
Architecture", Work in Progress, Internet-Draft, draft- | ||||
ietf-mpls-seamless-mpls-07, 28 June 2014, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-mpls- | ||||
seamless-mpls-07>. | ||||
[PCE-ID] Li, C., Shi, H., Ed., Wang, A., Cheng, W., and C. Zhou, | ||||
"Path Computation Element Communication Protocol (PCEP) | ||||
extension to advertise the PCE Controlled Identifier | ||||
Space", Work in Progress, Internet-Draft, draft-ietf-pce- | ||||
controlled-id-space-00, 4 June 2024, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-pce- | ||||
controlled-id-space-00>. | ||||
[PCE-INTERDOMAIN] | ||||
Dugeon, O., Meuric, J., Lee, Y., and D. Ceccarelli, "PCEP | ||||
Extension for Stateful Inter-Domain Tunnels", Work in | ||||
Progress, Internet-Draft, draft-ietf-pce-stateful- | ||||
interdomain-05, 5 July 2024, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-pce- | ||||
stateful-interdomain-05>. | ||||
[PCE-PROTECTION] | ||||
Barth, C. and R. Torvi, "PCEP Extensions for RSVP-TE | Barth, C. and R. Torvi, "PCEP Extensions for RSVP-TE | |||
Local-Protection with PCE-Stateful", Work in Progress, | Local-Protection with PCE-Stateful", Work in Progress, | |||
Internet-Draft, draft-cbrt-pce-stateful-local-protection- | Internet-Draft, draft-cbrt-pce-stateful-local-protection- | |||
01, 29 June 2018, <https://datatracker.ietf.org/doc/html/ | 01, 29 June 2018, <https://datatracker.ietf.org/doc/html/ | |||
draft-cbrt-pce-stateful-local-protection-01>. | draft-cbrt-pce-stateful-local-protection-01>. | |||
[I-D.chen-pce-bier] | [PCECC-BIER] | |||
Chen, R., Zhang, Z., Chen, H., Dhanaraj, S., Qin, F., and | Chen, R., Zhu, C., Xu, B., Chen, H., and A. Wang, "PCEP | |||
A. Wang, "PCEP Extensions for Tree Engineering for Bit | Procedures and Protocol Extensions for Using PCE as a | |||
Index Explicit Replication (BIER-TE)", Work in Progress, | Central Controller (PCECC) of BIER", Work in Progress, | |||
Internet-Draft, draft-chen-pce-bier-13, 1 October 2023, | Internet-Draft, draft-chen-pce-pcep-extension-pce- | |||
controller-bier-06, 8 July 2024, | ||||
<https://datatracker.ietf.org/doc/html/draft-chen-pce- | <https://datatracker.ietf.org/doc/html/draft-chen-pce- | |||
bier-13>. | pcep-extension-pce-controller-bier-06>. | |||
[I-D.chen-pce-pcep-extension-pce-controller-bier] | [PCECC-SR] Li, Z., Peng, S., Negi, M. S., Zhao, Q., and C. Zhou, "PCE | |||
Chen, R., Xu, B., Chen, H., and A. Wang, "PCEP Procedures | Communication Protocol (PCEP) Extensions for Using PCE as | |||
and Protocol Extensions for Using PCE as a Central | a Central Controller (PCECC) for Segment Routing (SR) MPLS | |||
Controller (PCECC) of BIER", Work in Progress, Internet- | Segment Identifier (SID) Allocation and Distribution.", | |||
Draft, draft-chen-pce-pcep-extension-pce-controller-bier- | Work in Progress, Internet-Draft, draft-ietf-pce-pcep- | |||
05, 19 October 2023, | extension-pce-controller-sr-09, 4 July 2024, | |||
<https://datatracker.ietf.org/doc/html/draft-chen-pce- | <https://datatracker.ietf.org/doc/html/draft-ietf-pce- | |||
pcep-extension-pce-controller-bier-05>. | pcep-extension-pce-controller-sr-09>. | |||
[I-D.dhody-pce-pcep-extension-pce-controller-srv6] | [PCECC-SRv6] | |||
Li, Z., Peng, S., Geng, X., and M. S. Negi, "PCE | Li, Z., Peng, S., Geng, X., and M. S. Negi, "PCE | |||
Communication Protocol (PCEP) Extensions for Using the PCE | Communication Protocol (PCEP) Extensions for Using the PCE | |||
as a Central Controller (PCECC) for Segment Routing over | as a Central Controller (PCECC) for Segment Routing over | |||
IPv6 (SRv6) Segment Identifier (SID) Allocation and | IPv6 (SRv6) Segment Identifier (SID) Allocation and | |||
Distribution.", Work in Progress, Internet-Draft, draft- | Distribution.", Work in Progress, Internet-Draft, draft- | |||
dhody-pce-pcep-extension-pce-controller-srv6-10, 15 | ietf-pce-pcep-extension-pce-controller-srv6-03, 18 August | |||
January 2023, <https://datatracker.ietf.org/doc/html/ | 2024, <https://datatracker.ietf.org/doc/html/draft-ietf- | |||
draft-dhody-pce-pcep-extension-pce-controller-srv6-10>. | pce-pcep-extension-pce-controller-srv6-03>. | |||
[I-D.ietf-mpls-seamless-mpls] | ||||
Leymann, N., Decraene, B., Filsfils, C., Konstantynowicz, | ||||
M., and D. Steinberg, "Seamless MPLS Architecture", Work | ||||
in Progress, Internet-Draft, draft-ietf-mpls-seamless- | ||||
mpls-07, 28 June 2014, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-mpls- | ||||
seamless-mpls-07>. | ||||
[I-D.ietf-pce-binding-label-sid] | [PCEP-BIER] | |||
Sivabalan, S., Filsfils, C., Tantsura, J., Previdi, S., | Chen, R., Zhang, Z., Chen, H., Dhanaraj, S., Qin, F., and | |||
and C. Li, "Carrying Binding Label/Segment Identifier | A. Wang, "PCEP Extensions for BIER-TE", Work in Progress, | |||
(SID) in PCE-based Networks.", Work in Progress, Internet- | Internet-Draft, draft-ietf-pce-bier-te-00, 4 November | |||
Draft, draft-ietf-pce-binding-label-sid-16, 27 March 2023, | 2023, <https://datatracker.ietf.org/doc/html/draft-ietf- | |||
<https://datatracker.ietf.org/doc/html/draft-ietf-pce- | pce-bier-te-00>. | |||
binding-label-sid-16>. | ||||
[I-D.ietf-pce-pcep-extension-native-ip] | [PCEP-NATIVE] | |||
Wang, A., Khasanov, B., Fang, S., Tan, R., and C. Zhu, | Wang, A., Khasanov, B., Fang, S., Tan, R., and C. Zhu, | |||
"Path Computation Element Communication Protocol (PCEP) | "Path Computation Element Communication Protocol (PCEP) | |||
Extensions for Native IP Networks", Work in Progress, | Extensions for Native IP Networks", Work in Progress, | |||
Internet-Draft, draft-ietf-pce-pcep-extension-native-ip- | Internet-Draft, draft-ietf-pce-pcep-extension-native-ip- | |||
30, 1 February 2024, | 40, 10 September 2024, | |||
<https://datatracker.ietf.org/doc/html/draft-ietf-pce- | ||||
pcep-extension-native-ip-30>. | ||||
[I-D.ietf-pce-pcep-extension-pce-controller-sr] | ||||
Li, Z., Peng, S., Negi, M. S., Zhao, Q., and C. Zhou, "PCE | ||||
Communication Protocol (PCEP) Extensions for Using PCE as | ||||
a Central Controller (PCECC) for Segment Routing (SR) MPLS | ||||
Segment Identifier (SID) Allocation and Distribution.", | ||||
Work in Progress, Internet-Draft, draft-ietf-pce-pcep- | ||||
extension-pce-controller-sr-08, 1 January 2024, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-pce- | ||||
pcep-extension-pce-controller-sr-08>. | ||||
[I-D.ietf-pce-segment-routing-ipv6] | ||||
Li, C., Kaladharan, P., Sivabalan, S., Koldychev, M., and | ||||
Y. Zhu, "Path Computation Element Communication Protocol | ||||
(PCEP) Extensions for IPv6 Segment Routing", Work in | ||||
Progress, Internet-Draft, draft-ietf-pce-segment-routing- | ||||
ipv6-25, 4 April 2024, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-pce- | <https://datatracker.ietf.org/doc/html/draft-ietf-pce- | |||
segment-routing-ipv6-25>. | pcep-extension-native-ip-40>. | |||
[I-D.ietf-pce-segment-routing-policy-cp] | [PCEP-POLICY] | |||
Koldychev, M., Sivabalan, S., Barth, C., Peng, S., and H. | Koldychev, M., Sivabalan, S., Barth, C., Peng, S., and H. | |||
Bidgoli, "Path Computation Element Communication Protocol | Bidgoli, "Path Computation Element Communication Protocol | |||
(PCEP) Extensions for Segment Routing (SR) Policy | (PCEP) Extensions for Segment Routing (SR) Policy | |||
Candidate Paths", Work in Progress, Internet-Draft, draft- | Candidate Paths", Work in Progress, Internet-Draft, draft- | |||
ietf-pce-segment-routing-policy-cp-16, 28 May 2024, | ietf-pce-segment-routing-policy-cp-18, 14 October 2024, | |||
<https://datatracker.ietf.org/doc/html/draft-ietf-pce- | ||||
segment-routing-policy-cp-16>. | ||||
[I-D.ietf-pce-stateful-interdomain] | ||||
Dugeon, O., Meuric, J., Lee, Y., and D. Ceccarelli, "PCEP | ||||
Extension for Stateful Inter-Domain Tunnels", Work in | ||||
Progress, Internet-Draft, draft-ietf-pce-stateful- | ||||
interdomain-04, 23 October 2023, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-pce- | <https://datatracker.ietf.org/doc/html/draft-ietf-pce- | |||
stateful-interdomain-04>. | segment-routing-policy-cp-18>. | |||
[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-09, 20 February 2024, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-spring- | ||||
sr-service-programming-09>. | ||||
[I-D.li-pce-controlled-id-space] | ||||
Li, C., Shi, H., Wang, A., Cheng, W., and C. Zhou, "Path | ||||
Computation Element Communication Protocol (PCEP) | ||||
extension to advertise the PCE Controlled Identifier | ||||
Space", Work in Progress, Internet-Draft, draft-li-pce- | ||||
controlled-id-space-16, 25 January 2024, | ||||
<https://datatracker.ietf.org/doc/html/draft-li-pce- | ||||
controlled-id-space-16>. | ||||
[MAP-REDUCE] | ||||
Lee, K., Choi, T., Ganguly, A., Wolinsky, D., Boykin, P., | ||||
and R. Figueiredo, "Parallel Processing Framework on a P2P | ||||
System Using Map and Reduce Primitives", , May 2011, | ||||
<http://leeky.me/publications/mapreduce_p2p.pdf>. | ||||
[MPLS-DC] Afanasiev, D. and D. Ginsburg, "MPLS in DC and inter-DC | ||||
networks: the unified forwarding mechanism for network | ||||
programmability at scale", , March 2014, | ||||
<https://www.slideshare.net/DmitryAfanasiev1/yandex- | ||||
nag201320131031>. | ||||
[RFC1195] Callon, R., "Use of OSI IS-IS for routing in TCP/IP and | [RFC1195] Callon, R., "Use of OSI IS-IS for routing in TCP/IP and | |||
dual environments", RFC 1195, DOI 10.17487/RFC1195, | dual environments", RFC 1195, DOI 10.17487/RFC1195, | |||
December 1990, <https://www.rfc-editor.org/info/rfc1195>. | December 1990, <https://www.rfc-editor.org/info/rfc1195>. | |||
[RFC2328] Moy, J., "OSPF Version 2", STD 54, RFC 2328, | [RFC2328] Moy, J., "OSPF Version 2", STD 54, RFC 2328, | |||
DOI 10.17487/RFC2328, April 1998, | DOI 10.17487/RFC2328, April 1998, | |||
<https://www.rfc-editor.org/info/rfc2328>. | <https://www.rfc-editor.org/info/rfc2328>. | |||
[RFC3209] Awduche, D., Berger, L., Gan, D., Li, T., Srinivasan, V., | [RFC3209] Awduche, D., Berger, L., Gan, D., Li, T., Srinivasan, V., | |||
skipping to change at page 38, line 14 ¶ | skipping to change at line 1680 ¶ | |||
[RFC9522] Farrel, A., Ed., "Overview and Principles of Internet | [RFC9522] Farrel, A., Ed., "Overview and Principles of Internet | |||
Traffic Engineering", RFC 9522, DOI 10.17487/RFC9522, | Traffic Engineering", RFC 9522, DOI 10.17487/RFC9522, | |||
January 2024, <https://www.rfc-editor.org/info/rfc9522>. | January 2024, <https://www.rfc-editor.org/info/rfc9522>. | |||
[RFC9552] Talaulikar, K., Ed., "Distribution of Link-State and | [RFC9552] Talaulikar, K., Ed., "Distribution of Link-State and | |||
Traffic Engineering Information Using BGP", RFC 9552, | Traffic Engineering Information Using BGP", RFC 9552, | |||
DOI 10.17487/RFC9552, December 2023, | DOI 10.17487/RFC9552, December 2023, | |||
<https://www.rfc-editor.org/info/rfc9552>. | <https://www.rfc-editor.org/info/rfc9552>. | |||
Appendix A. Other Use Cases of PCECC | [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>. | ||||
This section lists some more use cases of PCECC that were proposed by | [RFC9604] Sivabalan, S., Filsfils, C., Tantsura, J., Previdi, S., | |||
operators and discussed within the working group, but are not in | and C. Li, Ed., "Carrying Binding Label/SID in PCE-Based | |||
active development at the time of publication. They are listed here | Networks", RFC 9604, DOI 10.17487/RFC9604, August 2024, | |||
for future consideration. | <https://www.rfc-editor.org/info/rfc9604>. | |||
[SR-SERVICE] | ||||
Clad, F., Ed., Xu, X., Ed., 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-10, 23 August 2024, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-spring- | ||||
sr-service-programming-10>. | ||||
Appendix A. Other Use Cases of the PCECC | ||||
This section lists some more use cases of the PCECC that were | ||||
proposed by operators and discussed within the working group but are | ||||
not in active development at the time of publication. They are | ||||
listed here for future consideration. | ||||
A.1. PCECC for Network Migration | A.1. PCECC for Network Migration | |||
One of the main advantages of the PCECC solution is its backward | One of the main advantages of the PCECC solution is its backward | |||
compatibility. The PCE server can function as a proxy node of the | compatibility. The PCE server can function as a proxy node of the | |||
MPLS network for all the new nodes that no longer support the | MPLS network for all the new nodes that no longer support the | |||
signalling protocols. | signalling protocols. | |||
As illustrated in the following example, the current network could | As illustrated in the following example, the current network could | |||
migrate to a total PCECC-controlled network gradually by replacing | migrate to a total PCECC-controlled network gradually by replacing | |||
the legacy nodes. During the migration, the legacy nodes still need | the legacy nodes. During the migration, the legacy nodes still need | |||
to use the existing MPLS protocols signalling such as LDP and RSVP- | to use the existing MPLS signalling protocols such as LDP and RSVP- | |||
TE, and the new nodes will set up their portion of the forwarding | TE, and the new nodes will set up their portion of the forwarding | |||
path through PCECC directly. With the PCECC function as the proxy of | path through the PCECC directly. With the PCECC function as the | |||
these new nodes, MPLS signalling can populate through the network for | proxy of these new nodes, MPLS signalling can populate through the | |||
both: old and new nodes. | network for both old and new nodes. | |||
The example described in this section is based on network | The example described in this section is based on network | |||
configurations illustrated using Figure 13: | configurations illustrated in Figure 13: | |||
+------------------------------------------------------------------+ | +------------------------------------------------------------------+ | |||
| PCE DOMAIN | | | PCE DOMAIN | | |||
| +-----------------------------------------------------+ | | | +-----------------------------------------------------+ | | |||
| | PCECC | | | | | PCECC | | | |||
| +-----------------------------------------------------+ | | | +-----------------------------------------------------+ | | |||
| ^ ^ ^ ^ | | | ^ ^ ^ ^ | | |||
| | PCEP | | PCEP | | | | | PCEP | | PCEP | | | |||
| V V V V | | | V V V V | | |||
| +--------+ +--------+ +--------+ +--------+ +--------+ | | | +--------+ +--------+ +--------+ +--------+ +--------+ | | |||
| | NODE 1 | | NODE 2 | | NODE 3 | | NODE 4 | | NODE 5 | | | | | Node1 | | Node2 | | Node3 | | Node4 | | Node5 | | | |||
| | |...| |...| |...| |...| | | | | | |...| |...| |...| |...| | | | |||
| | Legacy |if1| Legacy |if2|Legacy |if3| PCECC |if4| PCECC | | | | | Legacy |if1| Legacy |if2|Legacy |if3| PCECC |if4| PCECC | | | |||
| | Node | | Node | |Enabled | |Enabled | | Enabled| | | | | Node | | Node | |Enabled | |Enabled | | Enabled| | | |||
| +--------+ +--------+ +--------+ +--------+ +--------+ | | | +--------+ +--------+ +--------+ +--------+ +--------+ | | |||
| | | | | | |||
+------------------------------------------------------------------+ | +------------------------------------------------------------------+ | |||
Figure 13: PCECC Initiated LSP Setup In the Network Migration | Figure 13: PCECC-Initiated LSP Setup in the Network Migration | |||
In this example, there are five nodes for the TE LSP from the head | In this example, there are five nodes for the TE LSP from the headend | |||
end (Node1) to the tail end (Node5). Where Node4 and Node5 are | (Node1) to the tail end (Node5), where Node4 and Node5 are centrally | |||
centrally controlled and other nodes are legacy nodes. | controlled and other nodes are legacy nodes. | |||
* Node1 sends a path request message for the setup of LSP with the | * Node1 sends a path request message for the setup of the LSP with | |||
destination as Node5. | the destination as Node5. | |||
* PCECC sends to Node1 a reply message for LSP setup with the path: | * The PCECC sends a reply message to Node1 for LSP setup with the | |||
(Node1, if1),(Node2, if2), (Node3, if3), (Node4, if4), Node5. | path: (Node1, if1), (Node2, if2), (Node3, if3), (Node4, if4), | |||
Node5. | ||||
* Node1, Node2, and Node3 will set up the LSP to Node5 using the | * Node1, Node2, and Node3 will set up the LSP to Node5 using the | |||
local labels as usual. Node 3 with the help of PCECC could proxy | local labels as usual. With the help of the PCECC, Node3 could | |||
the signalling. | proxy the signalling. | |||
* Then the PCECC will program the out-segment of Node3, the in- | * Then, the PCECC will program the out-segment of Node3, the in- | |||
segment/ out-segment of Node4, and the in-segment for Node5. | segment/out-segment of Node4, and the in-segment for Node5. | |||
A.2. PCECC for L3VPN and PWE3 | A.2. PCECC for L3VPN and PWE3 | |||
As described in [RFC8283], various network services may be offered | As described in [RFC8283], various network services may be offered | |||
over a network. These include protection services (including Virtual | over a network. These include protection services (including Virtual | |||
Private Network (VPN) services (such as Layer 3 VPNs [RFC4364] or | Private Network (VPN) services such as L3VPN [RFC4364] or EVPNs | |||
Ethernet VPNs [RFC7432]); or Pseudowires [RFC3985]. Delivering | [RFC7432]) or pseudowires [RFC3985]. Delivering services over a | |||
services over a network in an optimal way requires coordination in | network in an optimal way requires coordination in the way where | |||
the way where network resources are allocated to support the | network resources are allocated to support the services. A PCECC can | |||
services. A PCE-based central controller can consider the whole | consider the whole network and all components of a service at once | |||
network and all components of a service at once when planning how to | when planning how to deliver the service. It can then use PCEP to | |||
deliver the service. It can then use PCEP to manage the network | manage the network resources and to install the necessary | |||
resources and to install the necessary associations between those | associations between those resources. | |||
resources. | ||||
In the case of L3VPN, VPN labels could also be assigned and | In the case of L3VPN, VPN labels could also be assigned and | |||
distributed through PCEP among the PE router instead of using the BGP | distributed through PCEP among the Provider Edge (PE) router instead | |||
protocols. | of using the BGP protocols. | |||
The example described in this section is based on network | The example described in this section is based on network | |||
configurations illustrated using Figure 14: | configurations illustrated in Figure 14: | |||
+-------------------------------------------+ | +-------------------------------------------+ | |||
| PCE DOMAIN | | | PCE DOMAIN | | |||
| +-----------------------------------+ | | | +-----------------------------------+ | | |||
| | PCECC | | | | | PCECC | | | |||
| +-----------------------------------+ | | | +-----------------------------------+ | | |||
| ^ ^ ^ | | | ^ ^ ^ | | |||
|PWE3/L3VPN | PCEP PCEP|LSP PWE3/L3VPN|PCEP | | | PWE3/L3VPN|PCEP PCEP|LSP PWE3/L3VPN|PCEP | | |||
| V V V | | | V V V | | |||
+--------+ | +--------+ +--------+ +--------+ | +--------+ | +--------+ | +--------+ +--------+ +--------+ | +--------+ | |||
| CE | | | PE1 | | NODE x | | PE2 | | | CE | | | CE | | | PE1 | | Nodex | | PE2 | | | CE | | |||
| |...... | |...| |...| |.....| | | | |...... | |...| |...| |.....| | | |||
| Legacy | |if1 | PCECC |if2|PCCEC |if3| PCECC |if4 | Legacy | | | Legacy | |if1 | PCECC |if2|PCECC |if3| PCECC |if4 | Legacy | | |||
| Node | | | Enabled| |Enabled | |Enabled | | | Node | | | Node | | | Enabled| |Enabled | |Enabled | | | Node | | |||
+--------+ | +--------+ +--------+ +--------+ | +--------+ | +--------+ | +--------+ +--------+ +--------+ | +--------+ | |||
| | | | | | |||
+-------------------------------------------+ | +-------------------------------------------+ | |||
Figure 14: PCECC for L3VPN and PWE3 | Figure 14: PCECC for L3VPN and PWE3 | |||
In the case of PWE3, instead of using the LDP signalling protocols, | In the case of PWE3, instead of using the LDP signalling protocols, | |||
the label and port pairs assigned to each pseudowire can be assigned | the label and port pairs assigned to each pseudowire can be assigned | |||
through PCECC among the PE routers and the corresponding forwarding | through the PCECC among the PE routers and the corresponding | |||
entries will be distributed into each PE router through the extended | forwarding entries will be distributed into each PE router through | |||
PCEP and PCECC mechanism. | the extended PCEP and PCECC mechanism. | |||
A.3. PCECC for Local Protection (RSVP-TE) | A.3. PCECC for Local Protection (RSVP-TE) | |||
[I-D.cbrt-pce-stateful-local-protection] claim that there is a need | [PCE-PROTECTION] claims that there is a need for the PCE to maintain | |||
for the PCE to maintain and associate the local protection paths for | and associate the local protection paths for the RSVP-TE LSP. Local | |||
the RSVP-TE LSP. Local protection requires the setup of a bypass at | protection requires the setup of a bypass at the PLR. This bypass | |||
the PLR. This bypass can be PCC-initiated and delegated, or PCE- | can be PCC-initiated and delegated or PCE-initiated. In either case, | |||
initiated. In either case, the PLR needs to maintain a PCEP session | the PLR needs to maintain a PCEP session with the PCE. The bypass | |||
with the PCE. The Bypass LSPs need to be mapped to the primary LSP. | LSPs need to be mapped to the primary LSP. This could be done | |||
This could be done locally at the PLR based on a local policy but | locally at the PLR based on a local policy, but there is a need for a | |||
there is a need for a PCE to do the mapping as well to exert greater | PCE to do the mapping as well to exert greater control. | |||
control. | ||||
This mapping can be done via PCECC procedures where the PCE could | This mapping can be done via PCECC procedures where the PCE could | |||
instruct the PLR to the mapping and identify the primary LSP for | instruct the PLR to the mapping and identify the primary LSP for | |||
which bypass should be used. | which bypass should be used. | |||
A.4. Using reliable P2MP TE based multicast delivery for distributed | A.4. Using Reliable P2MP TE-Based Multicast Delivery for Distributed | |||
computations (MapReduce-Hadoop) | Computations (MapReduce-Hadoop) | |||
MapReduce model of distributed computations in computing clusters is | The MapReduce model of distributed computations in computing clusters | |||
widely deployed. In Hadoop (https://hadoop.apache.org/) 1.0 | is widely deployed. In Hadoop (https://hadoop.apache.org/) 1.0 | |||
architecture MapReduce operations on big data in the Hadoop | architecture, MapReduce operations occur on big data in the Hadoop | |||
Distributed File System (HDFS), where NameNode knows about resources | Distributed File System (HDFS), where NameNode knows about resources | |||
of the cluster and where actual data (chunks) for a particular task | of the cluster and where actual data (chunks) for a particular task | |||
are located (which DataNode). Each chunk of data (64MB or more) | are located (which DataNode). Each chunk of data (64 MB or more) | |||
should have 3 saved copies in different DataNodes based on their | should have three saved copies in different DataNodes based on their | |||
proximity. | proximity. | |||
The proximity level currently has a semi-manual allocation and is | The proximity level currently has a semi-manual allocation and is | |||
based on Rack IDs (The assumption is that closer data are better | based on Rack IDs (the assumption is that closer data is better | |||
because of access speed/smaller latency). | because of access speed / smaller latency). | |||
JobTracker node is responsible for computation tasks, and scheduling | The JobTracker node is responsible for computation tasks and | |||
across DataNodes and also has Rack-awareness. Currently, transport | scheduling across DataNodes and also has Rack awareness. Currently, | |||
protocols between NameNode/JobTracker and DataNodes are based on IP | transport protocols between NameNode/JobTracker and DataNodes are | |||
unicast. It has simplicity as an advantage but has numerous | based on IP unicast. It has simplicity as an advantage but has | |||
drawbacks related to its flat approach. | numerous drawbacks related to its flat approach. | |||
There is a need to go beyond one data centre (DC) for Hadoop cluster | There is a need to go beyond one data center (DC) for Hadoop cluster | |||
creation and move towards distributed clusters. In that case, one | creation and move towards distributed clusters. In that case, one | |||
needs to handle performance and latency issues. Latency depends on | needs to handle performance and latency issues. Latency depends on | |||
the speed of light in the fibre links and on the latency introduced | the speed of light in the fiber links and on the latency introduced | |||
by intermediate devices in between. The latter is closely correlated | by intermediate devices in between. The latter is closely correlated | |||
with network device architecture and performance. The current | with network device architecture and performance. The current | |||
performance of NPU-based routers should be enough for creating | performance of routers based on Network Processing Unit (NPU) should | |||
distributed Hadoop clusters with predicted latency. The performance | be enough for creating distributed Hadoop clusters with predicted | |||
of software-based routers (mainly virtual network functions (VNF)) | latency. The performance of software-based routers (mainly Virtual | |||
with additional hardware features such as the Data Plane Development | Network Functions (VNFs)) with additional hardware features such as | |||
Kit (DPDK) is promising but requires additional research and testing. | the Data Plane Development Kit (DPDK) is promising but requires | |||
additional research and testing. | ||||
The main question is how to create a simple but effective | The main question is how to create a simple but effective | |||
architecture for a distributed Hadoop cluster. | architecture for a distributed Hadoop cluster. | |||
There is research [MAP-REDUCE] that show how usage of the multicast | There is research [MAP-REDUCE] that shows how usage of the multicast | |||
tree could improve the speed of resource or cluster members' | tree could improve the speed of resource or cluster members' | |||
discovery inside the cluster as well as increased redundancy in | discovery inside the cluster as well as increased redundancy in | |||
communications between cluster nodes. | communications between cluster nodes. | |||
The traditional IP-based multicast may not be appropriate because it | The conventional IP-based multicast may not be appropriate because it | |||
requires an additional control plane (IGMP, PIM) and a lot of | requires an additional control plane (IGMP, PIM) and a lot of | |||
signalling, that is not suitable for high-performance computations, | signalling, which is not suitable for high-performance computations | |||
that are very sensitive to latency. | that are very sensitive to latency. | |||
P2MP TE tunnels are more suitable as a potential solution for the | P2MP TE tunnels are more suitable as a potential solution for the | |||
creation of multicast-based communications between NameNode as root | creation of multicast-based communications between NameNode as the | |||
and DataNodes as leaves inside the cluster. These P2MP tunnels could | root and DataNodes as leaves inside the cluster. These P2MP tunnels | |||
be dynamically created and turned down (with no manual intervention). | could be dynamically created and turned down (with no manual | |||
Here, the PCECC comes into play with the main objective of creating | intervention). Here, the PCECC comes into play with the main | |||
an optimal topology for each particular request for MapReduce | objective of creating an optimal topology for each particular request | |||
computation and creating P2MP tunnels with needed parameters such as | for MapReduce computation and creating P2MP tunnels with needed | |||
bandwidth and delay. | parameters such as BW and delay. | |||
This solution will require the use of MPLS label-based forwarding | This solution will require the use of MPLS label-based forwarding | |||
inside the cluster. The usage of label-based forwarding inside DC | inside the cluster. The usage of label-based forwarding inside DC | |||
was proposed by Yandex [MPLS-DC]. Technically it is already possible | was proposed by Yandex [MPLS-DC]. Technically, it is already | |||
because MPLS on switches is already supported by some vendors, MPLS | possible because MPLS on switches is already supported by some | |||
also exists on Linux and OVS. | vendors, and MPLS also exists on Linux and Open vSwitch (OVS). | |||
A possible framework for this task is shown in Figure 15: | A possible framework for this task is shown in Figure 15: | |||
+--------+ | +--------+ | |||
| APP | | | APP | | |||
+--------+ | +--------+ | |||
| NBI (REST API,...) | | NBI (REST API,...) | |||
| | | | |||
PCEP +----------+ REST API | PCEP +----------+ REST API | |||
+---------+ +---| PCECC |----------+ | +---------+ +---| PCECC |----------+ | |||
skipping to change at page 43, line 4 ¶ | skipping to change at line 1914 ¶ | |||
| Job Tracker | | | | | | NameNode | | | Job Tracker | | | | | | NameNode | | |||
| | | | | | | | | | | | | | | | | | |||
+-------------+ | | | | +----------+ | +-------------+ | | | | +----------+ | |||
+------------------+ | +-----------+ | +------------------+ | +-----------+ | |||
| | | | | | | | | | |||
|---+-----P2MP TE--+-----|-----------| | | |---+-----P2MP TE--+-----|-----------| | | |||
+----------+ +----------+ +----------+ | +----------+ +----------+ +----------+ | |||
| DataNode1| | DataNode2| | DataNodeN| | | DataNode1| | DataNode2| | DataNodeN| | |||
|TaskTraker| |TaskTraker| .... |TaskTraker| | |TaskTraker| |TaskTraker| .... |TaskTraker| | |||
+----------+ +----------+ +----------+ | +----------+ +----------+ +----------+ | |||
Figure 15: Using reliable P2MP TE based multicast delivery for | ||||
distributed computations (MapReduce-Hadoop) | ||||
Communication between JobTracker, NameNode and PCECC can be done via | Figure 15: Using Reliable P2MP TE-Based Multicast Delivery for | |||
REST API directly or via cluster manager such as Mesos. | Distributed Computations (MapReduce-Hadoop) | |||
Phase 1: Distributed cluster resources discovery During this phase, | Communication between the JobTracker, NameNode, and PCECC can be done | |||
JobTracker and NameNode should identify and find available DataNodes | via REST API directly or via a cluster manager such as Mesos. | |||
according to computing requests from the application (APP). NameNode | ||||
should query PCECC about available DataNodes, NameNode may provide | ||||
additional constraints to PCECC such as topological proximity, and | ||||
redundancy level. | ||||
PCECC should analyze the topology of the distributed cluster and | * Phase 1: Distributed cluster resource discovery occurs during this | |||
perform constraint-based path calculation from the client towards the | phase. JobTracker and NameNode should identify and find available | |||
most suitable NameNodes. PCECC should reply to NameNode with the | DataNodes according to computing requests from the application | |||
list of the most suitable DataNodes and their resource capabilities. | (APP). NameNode should query the PCECC about available DataNodes, | |||
The topology discovery mechanism for PCECC will be added later to | and NameNode may provide additional constraints to the PCECC such | |||
that framework. | as topological proximity and redundancy level. | |||
Phase 2: PCECC should create P2MP LSP from the client towards those | The PCECC should analyze the topology of the distributed cluster | |||
DataNodes by means of PCEP messages following the previously | and perform a constraint-based path calculation from the client | |||
calculated path. | towards the most suitable NameNodes. The PCECC should reply to | |||
NameNode with the list of the most suitable DataNodes and their | ||||
resource capabilities. The topology discovery mechanism for the | ||||
PCECC will be added later to that framework. | ||||
Phase 3. NameNode should send this information to the client, and | * Phase 2: The PCECC should create P2MP LSPs from the client towards | |||
PCECC should inform the client about the optimal P2MP path towards | those DataNodes by means of PCEP messages following the previously | |||
DataNodes via PCEP message. | calculated path. | |||
Phase 4. The Client sends data blocks to those DataNodes for writing | * Phase 3: NameNode should send this information to the client, and | |||
via the created P2MP tunnel. | the PCECC should inform the client about the optimal P2MP path | |||
towards DataNodes via a PCEP message. | ||||
* Phase 4: The client sends data blocks to those DataNodes for | ||||
writing via the created P2MP tunnel. | ||||
When this task is finished, the P2MP tunnel could be turned down. | When this task is finished, the P2MP tunnel could be turned down. | |||
Appendix B. Contributor Addresses | Acknowledgments | |||
Luyuan Fang | ||||
United States of America | ||||
Email: luyuanf@gmail.com | Thanks to Adrian Farrel, Aijun Wang, Robert Tao, Changjiang Yan, | |||
Tieying Huang, Sergio Belotti, Dieter Beller, Andrey Elperin, and | ||||
Evgeniy Brodskiy for their useful comments and suggestions. | ||||
Chao Zhou | Thanks to Mach Chen and Carlos Pignataro for the RTGDIR review. | |||
HPE | Thanks to Derrell Piper for the SECDIR review. Thanks to Sue Hares | |||
for GENART review. | ||||
Email: chaozhou_us@yahoo.com | Thanks to Vishnu Pavan Beeram for being the document shepherd and Jim | |||
Guichard for being the responsible AD. | ||||
Boris Zhang | Thanks to Roman Danyliw for the IESG review comments. | |||
Amazon | ||||
Email: zhangyud@amazon.com | Contributors | |||
Artsiom Rachytski | Luyuan Fang | |||
Belarus | United States of America | |||
Email: luyuanf@gmail.com | ||||
Email: arachyts@gmail.com | Chao Zhou | |||
HPE | ||||
Email: chaozhou_us@yahoo.com | ||||
Anton Gulida | Boris Zhang | |||
EPAM Systems, Inc. | Amazon | |||
Belarus | Email: zhangyud@amazon.com | |||
Email: Anton_Hulida@epam.com | Artsiom Rachytski | |||
AWS | ||||
Germany | ||||
Email: arachyts@gmail.com | ||||
Anton Hulida | ||||
AWS | ||||
Australia | ||||
Email: hulidant@amazon.com | ||||
Authors' Addresses | Authors' Addresses | |||
Zhenbin (Robin) Li | Zhenbin (Robin) Li | |||
Huawei Technologies | Huawei Technologies | |||
Huawei Bld., No.156 Beiqing Rd. | Huawei Bld., No.156 Beiqing Rd. | |||
Beijing | Beijing | |||
100095 | 100095 | |||
China | China | |||
Email: lizhenbin@huawei.com | Email: lizhenbin@huawei.com | |||
Dhruv Dhody | Dhruv Dhody | |||
Huawei Technologies | Huawei Technologies | |||
India | India | |||
Email: dhruv.ietf@gmail.com | Email: dhruv.ietf@gmail.com | |||
Quintin Zhao | Quintin Zhao | |||
Etheric Networks | Etheric Networks | |||
1009 S CLAREMONT ST | 1009 S Claremont St. | |||
SAN MATEO, CA 94402 | San Mateo, CA 94402 | |||
United States of America | United States of America | |||
Email: qzhao@ethericnetworks.com | Email: qzhao@ethericnetworks.com | |||
King He | King He | |||
Tencent Holdings Ltd. | Tencent Holdings Ltd. | |||
Shenzhen | Shenzhen | |||
China | China | |||
Email: kinghe@tencent.com | Email: kinghe@tencent.com | |||
Boris Khasanov | Boris Khasanov | |||
Yandex LLC | MTS Web Services (MWS) | |||
Ulitsa Lva Tolstogo 16 | Andropova Ave. 18, building 9 | |||
Moscow | Moscow | |||
Russian Federation | ||||
Email: bhassanov@yahoo.com | Email: bhassanov@yahoo.com | |||
End of changes. 277 change blocks. | ||||
839 lines changed or deleted | 830 lines changed or added | |||
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