Rfc9689
TitleUse Cases for a PCE as a Central Controller (PCECC)
AuthorZ. Li, D. Dhody, Q. Zhao, Z. Ke, B. Khasanov
DateDecember 2024
Format:HTML, TXT, PDF, XML
Status:INFORMATIONAL





Internet Engineering Task Force (IETF)                             Z. Li
Request for Comments: 9689                                      D. Dhody
Category: Informational                              Huawei Technologies
ISSN: 2070-1721                                                  Q. Zhao
                                                        Etheric Networks
                                                                   K. He
                                                   Tencent Holdings Ltd.
                                                             B. Khasanov
                                                  MTS Web Services (MWS)
                                                           December 2024


          Use Cases for a PCE as a Central Controller (PCECC)

Abstract

   The PCE is a core component of a Software-Defined Networking (SDN)
   system.  It can be used to compute optimal paths for network traffic
   and update existing paths to reflect changes in the network or
   traffic demands.  The PCE was developed to derive Traffic Engineering
   (TE) paths in MPLS networks, which are supplied to the headend of the
   paths using the Path Computation Element Communication Protocol
   (PCEP).

   SDN has much broader applicability than signalled MPLS TE networks,
   and the PCE may be used to determine paths in a range of use cases
   including static Label-Switched Paths (LSPs), Segment Routing (SR),
   Service Function Chaining (SFC), and most forms of a routed or
   switched network.  Therefore, it is reasonable to consider PCEP as a
   control protocol for use in these environments to allow the PCE to be
   fully enabled as a central controller.

   A PCE as a Central Controller (PCECC) can simplify the processing of
   a distributed control plane by blending it with elements of SDN
   without necessarily completely replacing it.  This document describes
   general considerations for PCECC deployment and examines its
   applicability and benefits, as well as its challenges and
   limitations, through a number of use cases.  PCEP extensions, which
   are required for the PCECC use cases, are covered in separate
   documents.

Status of This Memo

   This document is not an Internet Standards Track specification; it is
   published for informational purposes.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Not all documents
   approved by the IESG are candidates for any level of Internet
   Standard; see Section 2 of RFC 7841.

   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 (c) 2024 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

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   in the Revised BSD License.

Table of Contents

   1.  Introduction
   2.  Terminology
   3.  Use Cases
     3.1.  PCECC for Label Management
     3.2.  PCECC and SR
       3.2.1.  PCECC SID Allocation for SR-MPLS
       3.2.2.  PCECC for SR-MPLS Best Effort (BE) Paths
       3.2.3.  PCECC for SR-MPLS TE Paths
       3.2.4.  PCECC for SRv6
     3.3.  PCECC for Static TE LSPs
     3.4.  PCECC for Load Balancing (LB)
     3.5.  PCECC and Inter-AS TE
     3.6.  PCECC for Multicast LSPs
       3.6.1.  PCECC for the Setup of P2MP/MP2MP LSPs
       3.6.2.  PCECC for the End-to-End Protection of P2MP/MP2MP LSPs
       3.6.3.  PCECC for the Local Protection of P2MP/MP2MP LSPs
     3.7.  PCECC for Traffic Classification
     3.8.  PCECC for SFC
     3.9.  PCECC for Native IP
     3.10. PCECC for BIER
   4.  IANA Considerations
   5.  Security Considerations
   6.  References
     6.1.  Normative References
     6.2.  Informative References
   Appendix A.  Other Use Cases of the PCECC
     A.1.  PCECC for Network Migration
     A.2.  PCECC for L3VPN and PWE3
     A.3.  PCECC for Local Protection (RSVP-TE)
     A.4.  Using Reliable P2MP TE-Based Multicast Delivery for
           Distributed Computations (MapReduce-Hadoop)
   Acknowledgments
   Contributors
   Authors' Addresses

1.  Introduction

   The PCE [RFC4655] was developed to offload the path computation
   function from routers in an MPLS Traffic Engineering (TE) network.
   It can compute optimal paths for traffic across a network and can
   also update the paths to reflect changes in the network or traffic
   demands.  The role and function of the PCE have grown to cover
   several other uses (such as GMPLS [RFC7025] or Multicast) and to
   allow delegated stateful control [RFC8231] and PCE-initiated use of
   network resources [RFC8281].

   According to [RFC7399], Software-Defined Networking (SDN) refers to a
   separation between the control elements and the forwarding components
   so that software running in a centralized system, called a
   "controller", can act to program the devices in the network to behave
   in specific ways.  A required element in an SDN architecture is a
   component that plans how the network resources will be used and how
   the devices will be programmed.  It is possible to view this
   component as performing specific computations to place traffic flows
   within the network given knowledge of the availability of the network
   resources, how other forwarding devices are programmed, and the way
   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
   system (including an SDN system) is presented in [RFC7491].

   [RFC8283] outlines the architecture for the PCE as a central
   controller, extending the framework described in [RFC4655], and
   demonstrates how PCEP can serve as a general southbound control
   protocol between the PCE and Path Computation Client (PCC).
   [RFC8283] further examines the motivations and applicability of PCEP
   as a Southbound Interface (SBI) and introduces the implications for
   the protocol.

   [RFC9050] introduces the procedures and extensions for PCEP to
   support the PCECC architecture [RFC8283].

   This document describes the various use cases for the PCECC
   architecture.

2.  Terminology

   The following terminology is used in this document.

   AS:  Autonomous System

   ASBR:  Autonomous System Border Router

   BGP-LS:  Border Gateway Protocol - Link State [RFC9552]

   IGP:  Interior Gateway Protocol (in this document, we assume IGP as
   either Open Shortest Path First (OSPF) [RFC2328] [RFC5340] or
   Intermediate System to Intermediate System (IS-IS) [RFC1195])

   LSP:  Label-Switched Path

   PCC:  Path Computation Client (as per [RFC4655], any client
   application requesting a path computation to be performed by a PCE)

   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)

   PCECC:  PCE as a Central Controller (an extension of a PCE to support
   SDN functions as per [RFC8283])

   PST:  Path Setup Type [RFC8408]

   RR:  Route Reflector [RFC4456]

   SID:  Segment Identifier [RFC8402]

   SR:  Segment Routing [RFC8402]

   SRGB:  Segment Routing Global Block [RFC8402]

   SRLB:  Segment Routing Local Block [RFC8402]

   TE:  Traffic Engineering [RFC9522]

3.  Use Cases

   [RFC8283] describes various use cases for a PCECC such as:

   *  use of a PCECC to set up static TE LSPs (the PCEP extension for
      this use case is in [RFC9050])

   *  use of a PCECC in SR [RFC8402]

   *  use of a PCECC to set up Multicast Point-to-Multipoint (P2MP) LSPs

   *  use of a PCECC to set up Service Function Chaining (SFC) [RFC7665]

   *  use of a PCECC in optical networks

   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
   cases.  Further, various use cases (SR, Multicast, etc.) are
   described in the following sections to showcase scenarios that can
   benefit from the use of a PCECC.

   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
   this document, the focus is on the use of PCEP.

3.1.  PCECC for Label Management

   As per [RFC8283], in some cases, the PCECC can take responsibility
   for managing some part of the MPLS label space for each of the
   routers that it controls, and it may take wider responsibility for
   partitioning the label space for each router and allocating different
   parts for different uses, communicating the ranges to the router
   using PCEP.

   [RFC9050] describes a mode where LSPs are provisioned as explicit
   label instructions at each hop on the end-to-end path.  Each router
   along the path must be told what label forwarding instructions 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.
   For this to work, the PCECC will take responsibility for managing
   some part of the MPLS label space for each of the routers that it
   controls.  An extension to PCEP could be done to allow a PCC to
   inform the PCE of such a label space to control (see [PCE-ID] for a
   possible PCEP extension to support the advertisement of the MPLS
   label space for the PCE to control).

   [RFC8664] specifies extensions to PCEP that allow a stateful PCE to
   compute, update, or initiate SR-TE paths.  [PCECC-SR] describes the
   mechanism for a PCECC to allocate and provision the node/prefix/
   adjacency label (Segment Routing Identifier (SID)) via PCEP.  To make
   such an allocation, the PCE needs to be aware of the label space from
   the Segment Routing Global Block (SRGB) or Segment Routing Local
   Block (SRLB) [RFC8402] of the node that it controls.  A mechanism for
   a PCC to inform the PCE of such a label space to control is needed
   within the PCEP.  The full SRGB/SRLB of a node could be learned via
   existing IGP or BGP-LS [RFC9552] mechanisms.

   Further, there have been proposals for a global label range in MPLS
   as well as the use of PCECC architecture to learn the label space of
   each node to determine and provision the global label range.

   +------------------------------+    +------------------------------+
   |         PCE DOMAIN 1         |    |         PCE DOMAIN 2         |
   |          +--------+          |    |          +--------+          |
   |          |        |          |    |          |        |          |
   |          | PCECC1 |  ---------PCEP---------- | PCECC2 |          |
   |          |        |          |    |          |        |          |
   |          |        |          |    |          |        |          |
   |          +--------+          |    |          +--------+          |
   |         ^          ^         |    |         ^          ^         |
   |        /            \  PCEP  |    |  PCEP  /            \        |
   |       V              V       |    |       V              V       |
   | +--------+        +--------+ |    | +--------+        +--------+ |
   | | Node11 |        | Node1n | |    | | Node21 |        | Node2n | |
   | |        | ...... |        | |    | |        | ...... |        | |
   | | PCECC  |        |  PCECC | |    | | PCECC  |        |PCECC   | |
   | |Enabled |        | Enabled| |    | |Enabled |        |Enabled | |
   | +--------+        +--------+ |    | +--------+        +--------+ |
   |                              |    |                              |
   +------------------------------+    +------------------------------+

                 Figure 1: PCECC for MPLS Label Management

   As shown in Figure 1:

   *  The PCC will advertise the PCECC capability to the PCECC
      [RFC9050].

   *  The PCECC could also learn the label range set aside by the PCC
      (via [PCE-ID]).

   *  Optionally, the PCECC could determine the shared MPLS global label
      range for the network.

      -  In the case that the shared global label range needs to be
         negotiated across multiple domains, the central controllers of
         these domains will also need to negotiate a common global label
         range across domains.

      -  The PCECC will need to set the shared global label range to all
         PCC nodes in the network.

   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
   needed.

3.2.  PCECC and SR

   SR [RFC8402] leverages the source routing paradigm.  Using SR, a
   source node steers a packet through a path without relying on hop-by-
   hop signalling protocols such as LDP [RFC5036] or RSVP-TE [RFC3209].
   Each path is specified as an ordered list of instructions called
   "segments".  Each segment is an instruction to route the packet to a
   specific place in the network or to perform a specific service on the
   packet.  A database of segments can be distributed through the
   network using an intra-domain routing protocol (such as IS-IS or
   OSPF), an inter-domain protocol (such as BGP), or by any other means.
   PCEP could also be one of other protocols.

   [RFC8664] specifies the PCEP extension specific to SR for SR over
   MPLS (SR-MPLS).  The PCECC may further use the PCEP for distributing
   SR Segment Identifiers (SIDs) to the SR nodes (PCC) with some
   benefits.  If the PCECC allocates and maintains the SIDs in the
   network for the nodes and adjacencies, and further distributes them
   to the SR nodes directly via the PCEP session, then it is more
   advantageous over the configurations on each SR node and flooding
   them via IGP, especially in an SDN environment.

   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
   and the Adj-SID is allocated from the SRLB of the node as described
   in [PCECC-SR].

   [RFC8355] identifies various protection and resiliency use cases for
   SR.  Path protection lets the ingress node be in charge of the
   failure recovery (used for SR-TE [RFC8664]).  Also, protection can be
   performed by the node adjacent to the failed component, commonly
   referred to as "local protection techniques" or "fast-reroute (FRR)
   techniques".  In the case of the PCECC, the protection paths can be
   precomputed and set up by the PCE.

   Figure 2 illustrates the use case where the Node-SID and Adj-SID are
   allocated by the PCECC for SR-MPLS.

                          192.0.2.1/32
                          +----------+
                          | R1(1001) |
                          +----------+
                               |
                          +----------+
                          | R2(1002) |  192.0.2.2/32
                          +----------+
                         *   |   *    *
                        *    |   *     *
                       *link1|   *      *
        192.0.2.4/32  *      |   *link2  *  192.0.2.5/32
           +-----------+ 9001|   *     +-----------+
           | R4(1004)  |     |   *     | R5(1005)  |
           +-----------+     |   *     +-----------+
                      *      |   *9003  *   +
                       *     |   *     *    +
                        *    |   *    *     +
                        +-----------+   +-----------+
           192.0.2.3/32 | R3(1003)  |   |R6(1006)   |192.0.2.6/32
                        +-----------+   +-----------+
                             |
                        +-----------+
                        | R8(1008)  |  192.0.2.8/32
                        +-----------+

                           Figure 2: SR Topology

3.2.1.  PCECC SID Allocation for SR-MPLS

   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
   in the domain.  After receiving the label mapping, each node (PCC)
   uses the local routing information to determine the next hop and
   download the label forwarding instructions accordingly.  The
   forwarding behavior and the end result are the same as IGP shortest-
   path SR forwarding based on Node-SIDs.  Thus, from anywhere in the
   domain, it enforces the ECMP-aware shortest-path forwarding of the
   packet towards the related node.

   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
   each adjacency to the corresponding nodes in the domain.  Each node
   (PCC) downloads the label forwarding instructions accordingly.  The
   forwarding behavior and the end result are similar to IGP-based Adj-
   SID allocation and usage in SR.

   These mechanisms are described in [PCECC-SR].

3.2.2.  PCECC for SR-MPLS Best Effort (BE) Paths

   When using PCECC for SR-MPLS Best Effort (BE) Paths, the PCECC needs
   to allocate the Node-SID (without calculating the explicit path for
   the SR path).  The ingress router of the forwarding path needs to
   encapsulate the destination Node-SID on top of the packet.  All the
   intermediate nodes will forward the packet based on the destination
   Node-SID.  It is similar to the LDP LSP.

   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 /
   next hop calculation on the routers.

3.2.3.  PCECC for SR-MPLS TE Paths

   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
   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
   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
   case where a strict traffic engineering path is needed, all the Adj-
   SIDs are stacked; otherwise, a combination of Node-SIDs or Adj-SIDs
   can be used for the SR-TE paths.

   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
   the Node-SIDs of R2 and R8, respectively. 9001 is the Adj-SID for
   link1.  The path should be: "R1-R2-link1-R3-R8".

   To achieve this, the PCECC first allocates and distributes SIDs as
   described in Section 3.2.1.  [RFC8664] describes the mechanism for a
   PCE to compute, update, or initiate SR-MPLS TE paths.

                         192.0.2.1/32
                         +----------+
                         | R1 (1001)|
                         +----------+
                           |       |
                    90011  |       |90012
                    link1  |       |link2
                          +----------+
                          | R2 (1002)|  192.0.2.2/32
                          +----------+
                   link3 *   |   *    * link4
                  90023 *    |   *     * 90024
                       *link5|   *      *
        192.0.2.4/32  *90025 |   *link6  *  192.0.2.5/32
           +-----------+     |   *90026+-----------+
           | R4 (1004) |     |   *     | R5 (1005) |
           +-----------+     |   *     +-----------+
                      *      |   *             +
               link10  *     |   *     link7   +
                        *    |   *             +
                        +-----------+   +-----------+
           192.0.2.3/32 | R3 (1003) |   |R6 (1006)  |192.0.2.6/32
                        +-----------+   +-----------+
                         |                   |
                         |link8              |
                         |        |----------|link9
                        +-----------+
                        | R8 (1008) |  192.0.2.8/32
                        +-----------+

                    Figure 3: PCECC TE LSP Setup Example

   Refer to Figure 3 for an example of TE topology, where 100x are Node-
   SIDs and 900xx are Adj-SIDs.

   *  The SID allocation and distribution are done by the PCECC with all
      Node-SIDs (100x) and all Adj-SIDs (900xx).

   *  Based on path computation request/delegation or PCE initiation,
      the PCECC receives a request with constraints and optimization
      criteria from a PCC.

   *  The PCECC will calculate the optimal path according to the given
      constraints (e.g., bandwidth (BW)).

   *  The PCECC will provision the SR-MPLS TE LSP path
      ("R1-link1-R2-link6-R3-R8") at the ingress node: {90011, 1002,
      90026, 1003, 1008}

   *  For the end-to-end protection, the PCECC can provision the
      secondary path ("R1-link2-R2-link4-R5-R8"): {90012, 1002, 90024,
      1005, 1008}.

3.2.3.1.  PCECC for SR Policy

   [RFC8402] defines SR architecture, which uses an SR Policy to steer
   packets from a node through an ordered list of segments.  The SR
   Policy could be configured on the headend or instantiated by an SR
   controller.  The SR architecture does not restrict how the controller
   programs the network.  In this case, the focus is on PCEP as the
   protocol for SR Policy delivery from the PCE to PCC.

   An SR Policy architecture is described in [RFC9256].  An SR Policy is
   a framework that enables the instantiation of an ordered list of
   segments on a node for implementing a source routing policy for the
   steering of traffic for a specific purpose (e.g., for a specific
   Service Level Agreement (SLA)) from that node.

   An SR Policy is identified through the tuple <headend, color,
   endpoint>.

   Figure 3 is used as an example of PCECC application for SR Policy
   instantiation for SR-MPLS, where the Node-SIDs are 100x and the Adj-
   SIDs are 900xx.

   Let's assume that R1 needs to have two disjoint SR Policies towards
   R8 based on different BWs.  This means the possible paths are:

   *  POL1: {Headend R1, color 100, Endpoint R8; Candidate Path1:
      Segment List 1: {90011, 1002, 90023, 1004, 1003, 1008}}

   *  POL2: {Headend R1, color 200, Endpoint R8; Candidate Path1:
      Segment List 1: {90012, 1002, 90024, 1005, 1006, 1008}}

   Each SR Policy (including the candidate path and segment list) will
   be signalled to a headend (R1) via PCEP [PCEP-POLICY] with the
   addition of an ASSOCIATION object.  A Binding SID (BSID) [RFC8402]
   can be used for traffic steering of labelled traffic into an SR
   Policy; a BSID can be provisioned from the PCECC also via PCEP
   [RFC9604].  For non-labelled traffic steering into the SR Policy POL1
   or POL2, a per-destination traffic steering will be used by means of
   the BGP Color Extended Community [RFC9012].

   The procedure is as follows:

   *  The PCECC allocates Node-SIDs and Adj-SIDs using the mechanism
      described in Section 3.2.1 for all nodes and links.

   *  The PCECC calculates disjoint paths for POL1 and POL2 and create
      segment lists for them: {90011, 1002, 90023, 1004, 1003,
      1008};{90012, 1002, 90024, 1005, 1006, 1008}.

   *  The PCECC forms both SR Policies POL1 and POL2.

   *  The PCECC sends both POL1 and POL2 to R1 via PCEP.

   *  The PCECC optionally allocates BSIDs for the SR Policies.

   *  The traffic from R1 to R8, which fits to color 100, will be
      steered to POL1 and follows the path:
      "R1-link1-R2-link3-R4-R3-R8".  The traffic from R1 to R8, which
      fits color 200, will be steered to POL2 and follows the path:
      "R1-link2-R2-link4-R5-R6-R8".  Due to the possibility of having
      many segment lists in the same candidate path of each POL1/POL2,
      the PCECC could provision more paths towards R8 and traffic will
      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
   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
   [RFC9256].

3.2.4.  PCECC for SRv6

   As per [RFC8402], with SR, a node steers a packet through an ordered
   list of instructions, called segments.  SR can be applied to the IPv6
   architecture with the Segment Routing Header (SRH) [RFC8754].  A
   segment is encoded as an IPv6 address.  An ordered list of segments
   is encoded as an ordered list of IPv6 addresses in the routing
   header.  The active segment is indicated by the destination address
   of the packet.  Upon completion of a segment, a pointer in the new
   routing header is incremented and indicates the next segment.

   As per [RFC8754], an SR over IPv6 (SRv6) Segment is a 128-bit value.
   "SRv6 SID" or simply "SID" are often used as a shorter reference for
   "SRv6 Segment".  [RFC8986] defines the SRv6 SID as consisting of
   LOC:FUNCT:ARG.

   [RFC9603] extends [RFC8664] to support SR for the IPv6 data plane.
   Further, a PCECC could be extended to support SRv6 SID allocation and
   distribution.  An example of how PCEP extensions could be extended
   for SRv6 for a PCECC is described in [PCECC-SRv6].

                          2001:db8::1
                          +----------+
                          | R1       |
                          +----------+
                               |
                          +----------+
                          | R2       |  2001:db8::2
                          +----------+
                         *   |   *    *
                        *    |   *     *
                       *link1|   *      *
        2001:db8::4   *      |   *link2  *  2001:db8::5
           +-----------+     |   *     +-----------+
           | R4        |     |   *     | R5        |
           +-----------+     |   *     +-----------+
                      *      |   *      *   +
                       *     |   *     *    +
                        *    |   *    *     +
                        +-----------+   +-----------+
           2001:db8::3  | R3        |   |R6         |2001:db8::6
                        +-----------+   +-----------+
                             |
                        +-----------+
                        | R8        |  2001:db8::8
                        +-----------+

                          Figure 4: PCECC for SRv6

   In this case, as shown in Figure 4, the PCECC could assign the SRv6
   SID (in the form of an IPv6 address) to be used for node and
   adjacency.  Later, the SRv6 path in the form of a list of SRv6 SIDs
   could be used at the ingress.  Some examples:

   *  The best path towards R8: SRv6 SID-List={2001:db8::8}

   *  The path towards R8 via R5: SRv6 SID-List={2001:db8::5,
      2001:db8::8}

   The rest of the procedures and mechanisms remain the same as SR-MPLS.

3.3.  PCECC for Static TE LSPs

   As described in Section 3.1.2 of [RFC8283], the PCECC architecture
   supports the provisioning of static TE LSPs.  To achieve this, the
   existing PCEP can be used to communicate between the PCECC and nodes
   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
   label-forwarding instructions to program and what resources to
   reserve.  The PCECC keeps a view of the network and determines the
   paths of the end-to-end LSPs, and the controller uses PCEP to
   communicate with each router along the path of the end-to-end LSP.

                          192.0.2.1/32
                         +----------+
                         | R1       |
                         +----------+
                           |       |
                           |link1  |
                           |       |link2
                          +----------+
                          | R2       |  192.0.2.2/32
                          +----------+
                   link3 *   |   *    * link4
                        *    |   *     *
                       *link5|   *      *
        192.0.2.4/32  *      |   *link6  *  192.0.2.5/32
           +-----------+     |   *     +-----------+
           | R4        |     |   *     | R5        |
           +-----------+     |   *     +-----------+
                      *      |   *      *       +
               link10  *     |   *     *link7   +
                        *    |   *    *         +
                        +-----------+   +-----------+
           192.0.2.3/32 | R3        |   |R6         |192.0.2.6/32
                        +-----------+   +-----------+
                         |         |
                         |link8    |
                         |         |link9
                        +-----------+
                        | R8        |  192.0.2.8/32
                        +-----------+

                    Figure 5: PCECC TE LSP Setup Example

   Refer to Figure 5 for an example TE topology.

   *  Based on path computation request/delegation or PCE initiation,
      the PCECC receives a request with constraints and optimization
      criteria.

   *  The PCECC will calculate the optimal path according to the given
      constraints (e.g., BW).

   *  The PCECC will provision each node along the path and assign
      incoming and outgoing labels from R1 to R8 with the path as
      "R1-link1-R2-link3-R4-link10-R3-link8-R8":

      -  R1: Outgoing label 1001 on link 1

      -  R2: Incoming label 1001 on link 1

      -  R2: Outgoing label 2003 on link 3

      -  R4: Incoming label 2003 on link 3

      -  R4: Outgoing label 4010 on link 10

      -  R3: Incoming label 4010 on link 10

      -  R3: Outgoing label 3008 on link 8

      -  R8: Incoming label 3008 on link 8

   *  This can also be represented as: {R1, link1, 1001}, {1001, R2,
      link3, 2003}, {2003, R4, link10, 4010}, {4010, R3, link8, 3008},
      {3008, R8}.

   *  For the end-to-end protection, the PCECC programs each node along
      the path from R1 to R8 with the secondary path: {R1, link2, 1002},
      {1002, R2, link4, 2004}, {2004, R5, link7, 5007}, {5007, R3,
      link9, 3009}, {3009, R8}.

   *  It is also possible to have a bypass path for the local protection
      set up by the PCECC.  For example, use the primary path as above,
      then to protect the node R4 locally, the PCECC can program the
      bypass path like this: {R2, link5, 2005}, {2005, R3}. By doing
      this, the node R4 is locally protected at R2.

3.4.  PCECC for Load Balancing (LB)

   Very often, many service providers use TE tunnels for solving issues
   with non-deterministic paths in their networks.  One example of such
   applications is the usage of TEs in the mobile backhaul (MBH).
   Consider the topology as shown in Figure 6 (where AGG 1...AGG N are
   Aggregation routers, and Core 1...Core N are Core routers).

                              TE1 ----------->
   +--------+    +------+    +-----+    +-------+    +------+  +---+
   |Access  |----|Access|----|AGG 1|----|AGG N-1|----|Core 1|--|SR1|
   |SubNode1|    |Node1 |    +-----+    +-------+    +------+  +---+
   +--------+    +------+       | |         | ^          |
       |   Access    |  Access  | AGG Ring 1| |          |
       |  SubRing 1  |  Ring 1  | |         | |          |
   +--------+    +------+    +-----+        | |          |
   |Access  |    |Access|    |AGG 2|        | |          |
   |SubNode2|    |Node2 |    +-----+        | |          |
   +--------+    +------+       | |         | |          |
       |             |          | |         | |          |
       |             |          | +---TE2---|-+          |
   +--------+    +------+    +-----+    +-------+    +------+  +---+
   |Access  |    |Access|----|AGG 3|----| AGG N |----|Core N|--|SRn|
   |SubNodeN|----|NodeN |    +-----+    +-------+    +------+  +---+
   +--------+    +------+

                        Figure 6: PCECC LB Use Case

   This MBH architecture uses L2 access rings and sub-rings.  L3 starts
   at the aggregation layer.  For the sake of simplicity, the figure
   shows only one access sub-ring.  The access ring and aggregation ring
   are connected by Nx10GE interfaces.  The aggregation domain runs its
   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.
   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 two
   tunnels (one way) from each AGG router to egress AGG routers.  There
   are also many L2 access rings connected to AGG routers.

   Service deployment is made by means of Layer 2 Virtual Private
   Networks (L2VPNs), Virtual Private LAN Services (VPLSs), Layer 3
   Virtual Private Networks (L3VPNs), or Ethernet VPNs (EVPNs).  Those
   services use MPLS TE (or SR-TE) as transport towards egress AGG
   routers.  TE tunnels could be used as transport towards service
   routers in case of architecture based on seamless MPLS
   [MPLS-SEAMLESS].

   Load Balancing (LB) between TE tunnels involves distributing network
   traffic across multiple TE tunnels to optimize the use of available
   network resources, enhance performance, and ensure reliability.  Some
   common techniques include Equal-Cost Multipath (ECMP) and Unequal-
   Cost Multipath (UCMP) based on the BW of the TE tunnels.

   There is a need to solve the following tasks:

   *  Perform automatic LB amongst TE tunnels according to current
      traffic loads.

   *  Manage TE BW by guaranteeing BW for specific services (such as
      High-Speed Internet (HSI), IPTV, etc.) and enabling time-based BW
      reservation (such as Bandwidth on Demand (BoD)).

   *  Simplify the development of TE tunnels by automation without any
      manual intervention.

   *  Provide flexibility for service router placement (anywhere in the
      network by the creation of transport LSPs to them).

   In this section, the focus is on LB tasks.  LB tasks could be solved
   by means of the PCECC in the following ways:

   *  Applications, network services, or operators can ask the SDN
      controller (PCECC) for LSP-based LB between AGG X and AGG N/AGG
      N-1 (egress AGG routers that have connections to the core).  Each
      of these will have associated constraints (such as BW, inclusion
      or exclusion of specific links or nodes, number of paths,
      Objective Function (OF), need for disjoint LSP paths, etc.).

   *  The PCECC could calculate multiple (say N) LSPs according to given
      constraints.  The calculation is based on the results of the OF
      [RFC5541], constraints, endpoints, same or different BW, different
      links (in case of disjoint paths), and other constraints.

   *  Depending on the given LSP PST, the PCECC will download
      instructions to the PCC.  At this stage, it is assumed the PCECC
      is aware of the label space it controls and SID allocation and
      distribution is already done in the case of SR.

   *  The PCECC will send a PCInitiate message [RFC8281] towards the
      ingress AGG X router (PCC) for each of N LSPs and receive a PCRpt
      message [RFC8231] back from PCCs.  If the PST is a PCECC-SR, the
      PCECC will include a SID stack as per [RFC8664].  If the PST is
      set to "PCECC" type, then the PCECC will assign labels along the
      calculated path and set up the path by sending central controller
      instructions in a PCEP message to each node along the path of the
      LSP as per [RFC9050].  Then, the PCECC will send a PCUpd message
      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
      N-1, which are available for installation to the router's
      forwarding table and for LB traffic between them.  Traffic
      distribution between those LSPs depends on the particular
      realization of the hash function on that router.

   *  Since the PCECC is aware of the Traffic Engineering Database (TED)
      (TE state) and the LSP Database (LSP-DB), it can manage and
      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
      the central control instructions.

3.5.  PCECC and Inter-AS TE

   There are various signalling options for establishing Inter-AS TE
   LSPs: contiguous TE LSPs [RFC5151], stitched TE LSPs [RFC5150], and
   nested TE LSPs [RFC4206].

   The requirements for PCE-based Inter-AS setup [RFC5376] describe the
   approach and PCEP functionality that is needed for establishing
   Inter-AS TE LSPs.

   [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
   sake of simplicity.

              Inter-AS       Inter-AS
        PCC <-->PCE1<--------->PCE2
         ::      ::             ::
         ::      ::             ::
         R1----ASBR1====ASBR3---R3---ASBR5
         |   AS1 |        |    PCC     |
         |       |        |    AS2     |
         R2----ASBR2====ASBR4---R4---ASBR6
         ::                     ::
         ::                     ::
      Intra-AS               Intra-AS
         PCE3                   PCE4

         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
   Inter-AS TE LSPs.  The stateful Hierarchical PCE (H-PCE) mechanism
   [RFC8751] could also be used to establish a per-domain PCECC LSP
   first.  These could be stitched together to form an Inter-AS TE LSP
   as described in [PCE-INTERDOMAIN].

   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
   administration.  In that case, Inter-AS and Intra-AS PCEs could be
   combined in one single PCE if such combined PCE performance is enough
   to handle the load.  The PCE will require interfaces (PCEP and BGP-
   LS) to both domains.  PCECC redundancy mechanisms are described in
   [RFC8283].  Thus, routers (PCCs) in AS1 and AS2 can send PCEP
   messages towards the same PCECC.  In Figure 8, the PCECC maintains a
   BGP-LS session with Route Reflectors (RRs) in each AS.  This allows
   the RRs to redistribute routes to other BGP routers (clients) without
   requiring a full mesh.  The RRs act as a BGP-LS Propagator, and the
   PCECC acts as a BGP-LS Consumer [RFC9552].

                +----BGP-LS------+ +------BGP-LS-----+
                |                | |                 |
         +-PCEP-|----++-+-------PCECC-----PCEP--++-+-|-------+
       +-:------|----::-:-+                  +--::-:-|-------:---+
       | :      |    :: : |                  |  :: : |       :   |
       | :     RR1   :: : |                  |  :: : RR2     :   |
       | v           v: : |      LSP1        |  :: v         v   |
       | R1---------ASBR1=======================ASBR3--------R3  |
       | |            v : |                  |  :v            |  |
       | +----------ASBR2=======================ASBR4---------+  |
       | |   Region 1   : |                  |  : Region 1    |  |
       |----------------:-|                  |--:-------------|--|
       | |              v |       LSP2       |  v             |  |
       | +----------ASBR5=======================ASBR6---------+  |
       |     Region 2     |                  |       Region 2    |
       +------------------+ <--------------> +-------------------+
           MPLS Domain 1          Inter-AS         MPLS Domain 2
       <=======AS1=======>                    <========AS2=======>

                 Figure 8: Particular Case of Inter-AS PCE

   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
   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
   (such as Voice, L3VPN, etc.).  Inter-AS links with different
   capacities exist in several regions.  The task is not only to
   provision those Inter-AS LSPs with given constraints but also to
   calculate the path and pre-setup the backup Inter-AS LSPs that will
   be used if the primary LSP fails.

   As per Figure 8, LSP1 from R1 to R3 goes via ASBR1 and ASBR3, and it
   is the primary Inter-AS LSP.  LSP2 from R1 to R3 that goes via ASBR5
   and ASBR6 is the backup one.  In addition, there could also be a
   bypass LSP setup to protect against ASBR or Inter-AS link failures.

   After the addition of PCECC functionality to the PCE (SDN
   controller), the PCECC-based Inter-AS TE model should follow the
   PCECC use case for TE LSP including the requirements described in
   [RFC5376] with the following details:

   *  Since the PCECC needs to know the topology of both domains AS1 and
      AS2, the PCECC can utilize the BGP-LS peering with BGP routers (or
      RRs) in both domains.

   *  The PCECC needs to establish PCEP connectivity with all routers in
      both domains (see also Section 4 of [RFC5376]).

   *  After the operator's application or service orchestrator creates a
      request for tunnel creation of a specific service, the PCECC will
      receive that request via the Northbound Interface (NBI) (note that
      the NBI type is implementation-dependent; it could be NETCONF/
      YANG, REST, etc.).  Then, the PCECC will calculate the optimal
      path based on the OF and given constraints (i.e., PST, BW, etc.).
      These constraints include those from [RFC5376], such as priority,
      AS sequence, preferred ASBR, disjoint paths, and protection type.
      In this step, we will have two paths: "R1-ASBR1-ASBR3-R3,
      R1-ASBR5-ASBR6-R3".

   *  The PCECC will use central control download instructions to the
      PCC based on the PST.  At this stage, it is assumed the PCECC is
      aware of the label space it controls, and in the case of SR, the
      SID allocation and distribution is already done.

   *  The PCECC will send a PCInitiate message [RFC8281] towards the
      ingress router R1 (PCC) in AS1 and receive the PCRpt message
      [RFC8231] back from it.

      -  If the PST is SR-MPLS, the PCECC will include the SID stack as
         per [RFC8664].  Optionally, a BSID or BGP Peering-SID [RFC9087]
         can also be included on the AS boundary.  The backup SID stack
         can be installed at ingress R1, but more importantly, each node
         along the SR path could also do the local protection just based
         on the top segment.

      -  If the PST is a PCECC, the PCECC will assign labels along the
         calculated paths ("R1-ASBR1-ASBR3-R3", "R1-ASBR5-ASBR6-R3") and
         sets up the path by sending central controller instructions in
         a PCEP message to each node along the path of the LSPs as per
         [RFC9050].  After these steps, the PCECC will send a PCUpd
         message to the ingress R1 router with information about new
         LSPs and R1 will respond by a PCRpt with LSP(s) status.

   *  After that step, R1 now has primary and backup TEs (LSP1 and LSP2)
      towards R3.  It is up to the router implementation for how to
      switchover to backup LSP2 if LSP1 fails.

3.6.  PCECC for Multicast LSPs

   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
   configurations and complex signalling when the protection is
   considered.  By using the PCECC solution, the multicast LSP can be
   computed and set up through a centralized controller that has the
   full picture of the topology and BW usage for each link.  It not only
   reduces the complex configurations comparing the distributed RSVP-TE
   P2MP or mLDP signalling, but also it can compute the disjoint primary
   path and secondary P2MP path efficiently.

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
   all nodes and makes allocations accordingly.

                          +----------+
                          |    R1    | Root Node of the multicast LSP
                          +----------+
                              |9000 (link0)
                          +----------+
           Transit Node   |    R2    |
           branch         +----------+
                          *  |   *  *
                     9001*   |   *   *9002
                  link1 *    |   *    *link2
           +-----------+     |   *     +-----------+
           |    R4     |     |   *     |    R5     | Transit Nodes
           +-----------+     |   *     +-----------+
                      *      |   *      *     +
                   9003*     |   *     *      +9004
                  link3 *    |   *    *       +link4
                        +-----------+  +-----------+
                        |    R3     |  |    R6     | Leaf Node
                        +-----------+  +-----------+
                         9005| link5
                        +-----------+
                        |    R8     | Leaf Node
                        +-----------+

          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 root and the routers R8 and R6 are the leaves.

   *  Based on the P2MP path computation request/delegation or PCE
      initiation, the PCECC receives the request with constraints and
      optimization criteria.

   *  The PCECC will calculate the optimal P2MP path according to given
      constraints (i.e., BW).

   *  The PCECC will provision each node along the path and assign
      incoming and outgoing labels from R1 to {R6, R8} with the path as
      "R1-link0-R2-link2-R5-link4-R6" and
      "R1-link0-R2-link1-R4-link3-R3-link5-R8":

      -  R1: Outgoing label 9000 on link0

      -  R2: Incoming label 9000 on link0

      -  R2: Outgoing label 9001 on link1 (*)

      -  R2: Outgoing label 9002 on link2 (*)

      -  R5: Incoming label 9002 on link2

      -  R5: Outgoing label 9004 on link4

      -  R6: Incoming label 9004 on link4

      -  R4: Incoming label 9001 on link1

      -  R4: Outgoing label 9003 on link3

      -  R3: Incoming label 9003 on link3

      -  R3: Outgoing label 9005 on link5

      -  R8: Incoming label 9005 on link5

   *  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
      node instruction at R2, where two copies of a packet are sent
      towards R4 and R5 with 9001 and 9002 labels, respectively.

   The packet forwarding involves the following:

   Step 1.  R1 sends a packet to R2 simply by pushing the label of 9000
            to the packet.

   Step 2.  When R2 receives the packet with label 9000, it will forward
            it to R4 by swapping label 9000 to 9001.  At the same time,
            it will replicate the packet and swap the label 9000 to 9002
            and forward it to R5.

   Step 3.  When R4 receives the packet with label 9001, it will forward
            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 9002 to 9004.

   Step 4.  When R3 receives the packet with label 9003, it will forward
            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.

   Step 5.  When R8 receives the packet with label 9005, it will pop the
            label.  When R6 receives the packet with label 9004, it will
            pop the label.

3.6.2.  PCECC for the End-to-End Protection of P2MP/MP2MP LSPs

   This section describes the end-to-end managed path protection service
   as well as the local protection with the operation management in the
   PCECC network for the P2MP/MP2MP LSP.

   An end-to-end protection principle can be applied for computing
   backup P2MP or MP2MP LSPs.  During the computation of the primary
   multicast trees, the PCECC could also take the computation of a
   secondary tree into consideration.  A PCECC could compute the primary
   and backup P2MP (or MP2MP) LSPs together or sequentially.

                               +----+  +----+
              Root Node of LSP | R1 |--| R11|
                               +----+  +----+
                                 /         +
                              10/           +20
                               /             +
                       +----------+        +-----------+
        Transit Node   |    R2    |        |     R3    |
                       +----------+        +-----------+
                         |        \       +         +
                         |         \     +          +
                       10|        10\   +20       20+
                         |           \ +            +
                         |            \             +
                         |           + \            +
                       +-----------+      +-----------+ Leaf Nodes
                       |    R4     |      |    R5     | (Downstream LSR)
                       +-----------+      +-----------+

     Figure 10: PCECC for the End-to-End Protection of P2MP/MP2MP LSPs

   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}, it can set
   up the backup tree at the same time, which is R1->R11->R3->{R4, R5}.
   Both of them (the primary forwarding tree and secondary forwarding
   tree) will be downloaded to each router along the primary path and
   the secondary path.  The traffic will be forwarded through the
   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
   tree, which is R1->R11->R3->{R4, R5}. By using the PCECC, path
   computation, label downloading, and finally forwarding can be done
   without the complex signalling used in the P2MP RSVP-TE or mLDP.

3.6.3.  PCECC for the Local Protection of P2MP/MP2MP LSPs

   In this section, we describe the local protection service in the
   PCECC network for the P2MP/MP2MP LSP.

   While the PCECC sets up the primary multicast tree, it can also build
   the backup LSP between the Point of Local Repair (PLR), protected
   node, and Merge Points (MPs) (the downstream nodes of the protected
   node).  In the cases where the amount of downstream nodes is huge,
   this mechanism can avoid unnecessary packet duplication on the PLR
   and protect the network from traffic congestion risks.

                               +------------+
                               |     R1     | Root Node
                               +------------+
                                      .
                                      .
                                      .
                               +------------+ Point of Local Repair /
                               |     R10     | Switchover Point
                               +------------+ (Upstream LSR)
                                 /         +
                              10/           +20
                               /             +
                       +----------+        +-----------+
        Protected Node |    R20   |        |     R30   |
                       +----------+        +-----------+
                         |        \       +         +
                         |         \     +          +
                       10|        10\   +20       20+
                         |           \ +            +
                         |            \             +
                         |           + \            +
                       +-----------+      +-----------+ Merge Point
                       |    R40    |      |    R50    | (Downstream LSR)
                       +-----------+      +-----------+
                             .                  .
                             .                  .

        Figure 11: PCECC for the Local Protection of P2MP/MP2MP LSPs

   In Figure 11, when the PCECC sets up the primary multicast path
   around the PLR node R10 to protect node R20, which is R10->R20->{R40,
   R50}, it can set up the backup path R10->R30->{R40, R50} at the same
   time.  Both the primary forwarding path and the secondary bypass
   forwarding path will be downloaded to each router along the primary
   path and the secondary bypass path.  The traffic will be forwarded
   through the R10->R20->{R40, R50} path normally, and when there is a
   node failure for node R20, the PLR node R10 will switch the flow to
   the backup path, which is R10->R30->{R40, R50}.  By using the PCECC,
   path computation, label downloading, and finally forwarding can be
   done without the complex signalling used in the P2MP RSVP-TE or mLDP.

3.7.  PCECC for Traffic Classification

   As described in [RFC8283], traffic classification is an important
   part of traffic engineering.  It is the process of looking into a
   packet to determine how it should be treated while it is forwarded
   through the network.  It applies in many scenarios, including the
   following:

   *  MPLS traffic engineering (where it determines what traffic is
      forwarded into which LSPs),

   *  SR (where it is used to select which set of forwarding
      instructions (SIDs) to add to a packet), and

   *  SFC (where it indicates how a packet should be forwarded across
      which service function path).

   In conjunction with traffic engineering, traffic classification is an
   important enabler for LB.  Traffic classification is closely linked
   to the computational elements of planning for the network functions
   because it determines how traffic is balanced and distributed through
   the network.  Therefore, selecting what traffic classification
   mechanism should be performed by a router is an important part of the
   work done by a PCECC.

   The description of traffic flows by the combination of multiple Flow
   Specification components and their dissemination as traffic Flow
   Specifications is described for BGP in [RFC8955].  When a PCECC is
   used to initiate tunnels (such as TE LSPs or SR paths) using PCEP, it
   is important that the headend of the tunnels understands what traffic
   to place on each tunnel.  [RFC9168] specifies a set of extensions to
   PCEP to support the dissemination of Flow Specification components
   where the instructions are passed from the PCECC to the routers using
   PCEP.

   Along with traffic classification, there are a few more questions
   about the tunnels set up by the PCECC that need to be considered:

   *  how to use it,

   *  whether it is 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.

   These are out of the scope of this document.

3.8.  PCECC for SFC

   Service Function Chaining (SFC) is described in [RFC7665].  It is the
   process of directing traffic in a network such that it passes through
   specific hardware devices or virtual machines (known as service
   function nodes) that can perform particular desired functions on the
   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
   chain is enhanced with the locations at which the service functions
   are to be performed to derive a Service Function Path (SFP).  Each
   packet is marked as belonging to a specific SFP, and that marking
   lets each successive service function node know which functions to
   perform and to which service function node to send the packet next.
   To operate an SFC network, the service function nodes must be
   configured to understand the packet markings, and the edge nodes must
   be told how to mark packets entering the network.  Additionally, it
   may be necessary to establish tunnels between service function nodes
   to carry the traffic.  Planning an SFC network requires LB between
   service function nodes and traffic engineering across the network
   that connects them.  As per [RFC8283], these are operations that can
   be performed by a PCECC, and that controller can use PCEP to program
   the network and install the service function chains and any required
   tunnels.

   A possible mechanism could add support for SFC-based central control
   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 Index (SI): Provides location within the SFP.

   *  Provide SFC Proxy handling instruction.

   The PCECC can play the role of setting the traffic classification
   rules (as per Section 3.7) at the classifier to impose the Network
   Service Header (NSH) [RFC8300].  It can also download the forwarding
   instructions to each SFF along the way so that they could process the
   NSH and forward accordingly.  This includes instructions for the
   service classifier that handles the context header, metadata, etc.
   This metadata/context is shared amongst SFs and classifiers, between
   SFs, and between external systems (such as a PCECC) and SFs.  As
   described in [RFC7665], the SFC encapsulation enables the sharing of
   metadata/context information along the SFP.

   It is also possible to support SFC with SR in conjunction with or
   without an NSH such as described in [RFC9491] and [SR-SERVICE].
   PCECC techniques can also be used for service-function-related
   segments and SR service policies.

3.9.  PCECC for Native IP

   [RFC8735] describes the scenarios and simulation results for the
   "Centralized Control Dynamic Routing (CCDR)" solution, which
   integrates the advantage of using distributed protocols (IGP/BGP) and
   the power of a centralized control technology (PCE/SDN), providing
   traffic engineering for native IP networks.  [RFC8821] defines the
   framework for CCDR traffic engineering within a native IP network,
   using multiple BGP sessions and a PCE as the centralized controller.
   It requires the PCECC to send the instructions to the PCCs to build
   multiple BGP sessions, distribute different prefixes on the
   established BGP sessions, and assign the different paths to the BGP
   next hops.  The PCEP is used to transfer the key parameters between
   the PCE and the underlying network devices (PCC) using the PCECC
   technique.  The central control instructions from the PCECC to PCC
   will identify which prefix should be advertised on which BGP session.
   There are PCEP extensions defined in [PCEP-NATIVE] for it.

                                  +------+
                       +----------+ PCECC+-------+
                       |          +------+       |
                       |                         |
                  PCEP | BGP Session 1(lo11/lo21)| PCEP
                       +-------------------------+
                       |                         |
                       | BGP Session 2(lo12/lo22)|
                       +-------------------------+
   PF12                |                         |                 PF22
   PF11                |                         |                 PF21
   +---+         +-----+-----+             +-----+-----+           +---+
   |SW1+---------+(lo11/lo12)+-------------+(lo21/lo22)+-----------+SW2|
   +---+         |    R1     +-------------+    R2     |           +---+
                 +-----------+             +-----------+

                       Figure 12: PCECC for Native IP

   In the case as shown in Figure 12, the PCECC will instruct both R1
   and R2 how to form BGP sessions with each other via PCEP and which IP
   prefixes need to be advertised via which BGP session.

3.10.  PCECC for BIER

   Bit Index Explicit Replication (BIER) [RFC8279] defines an
   architecture where all intended multicast receivers are encoded as a
   BitMask in the multicast packet header within different
   encapsulations.  A router that receives such a packet will forward
   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 packet.  Each receiver is represented by a unique bit in the
   BitMask.

   BIER-TE [RFC9262] shares architecture and packet formats with BIER.
   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 indicates one or more adjacencies.  BIER-TE paths can be
   derived from a PCE and used at the ingress (a possible mechanism is
   described in [PCEP-BIER]).

   The PCECC mechanism could be used for the allocation of bits for the
   BIER router for BIER as well as for the adjacencies for BIER-TE.
   PCECC-based controllers can use PCEP to instruct the BIER-capable
   routers on the meaning of the bits as well as other fields needed for
   BIER encapsulation.  The PCECC could be used to program the BIER
   router with various parameters used in the BIER encapsulation (such
   as BIER sub-domain-id, BFR-id, etc.) for both node and adjacency.

   A possible way to use the PCECC and PCEP extension is described in
   [PCECC-BIER].

4.  IANA Considerations

   This document has no IANA actions.

5.  Security Considerations

   [RFC8283] describes how the security considerations for a PCECC are a
   little different from those for any other PCE system.  PCECC
   operations rely heavily on the use and security of PCEP, so due
   consideration should be given to the security features discussed in
   [RFC5440] and the additional mechanisms described in [RFC8253].  It
   further lists the vulnerability of a central controller architecture,
   such as a central point of failure, denial of service, and a focus on
   interception and modification of messages sent to individual Network
   Elements (NEs).

   As per [RFC9050], the use of Transport Layer Security (TLS) in PCEP
   is recommended, as it provides support for peer authentication,
   message encryption, and integrity.  It further provides mechanisms
   for associating peer identities with different levels of access and/
   or authoritativeness via an attribute in X.509 certificates or a
   local policy with a specific accept-list of X.509 certificates.  This
   can be used to check the authority for the PCECC operations.

   It is expected that each new document that is produced for a specific
   use case will also include considerations of the security impacts of
   the use of a PCECC on the network type and services being managed.

6.  References

6.1.  Normative References

   [RFC5440]  Vasseur, JP., Ed. and JL. Le Roux, Ed., "Path Computation
              Element (PCE) Communication Protocol (PCEP)", RFC 5440,
              DOI 10.17487/RFC5440, March 2009,
              <https://www.rfc-editor.org/info/rfc5440>.

   [RFC7665]  Halpern, J., Ed. and C. Pignataro, Ed., "Service Function
              Chaining (SFC) Architecture", RFC 7665,
              DOI 10.17487/RFC7665, October 2015,
              <https://www.rfc-editor.org/info/rfc7665>.

   [RFC8231]  Crabbe, E., Minei, I., Medved, J., and R. Varga, "Path
              Computation Element Communication Protocol (PCEP)
              Extensions for Stateful PCE", RFC 8231,
              DOI 10.17487/RFC8231, September 2017,
              <https://www.rfc-editor.org/info/rfc8231>.

   [RFC8253]  Lopez, D., Gonzalez de Dios, O., Wu, Q., and D. Dhody,
              "PCEPS: Usage of TLS to Provide a Secure Transport for the
              Path Computation Element Communication Protocol (PCEP)",
              RFC 8253, DOI 10.17487/RFC8253, October 2017,
              <https://www.rfc-editor.org/info/rfc8253>.

   [RFC8281]  Crabbe, E., Minei, I., Sivabalan, S., and R. Varga, "Path
              Computation Element Communication Protocol (PCEP)
              Extensions for PCE-Initiated LSP Setup in a Stateful PCE
              Model", RFC 8281, DOI 10.17487/RFC8281, December 2017,
              <https://www.rfc-editor.org/info/rfc8281>.

   [RFC8283]  Farrel, A., Ed., Zhao, Q., Ed., Li, Z., and C. Zhou, "An
              Architecture for Use of PCE and the PCE Communication
              Protocol (PCEP) in a Network with Central Control",
              RFC 8283, DOI 10.17487/RFC8283, December 2017,
              <https://www.rfc-editor.org/info/rfc8283>.

   [RFC8402]  Filsfils, C., Ed., Previdi, S., Ed., Ginsberg, L.,
              Decraene, B., Litkowski, S., and R. Shakir, "Segment
              Routing Architecture", RFC 8402, DOI 10.17487/RFC8402,
              July 2018, <https://www.rfc-editor.org/info/rfc8402>.

6.2.  Informative References

   [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-01, 21 October 2024,
              <https://datatracker.ietf.org/doc/html/draft-ietf-pce-
              controlled-id-space-01>.

   [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
              Local-Protection with PCE-Stateful", Work in Progress,
              Internet-Draft, draft-cbrt-pce-stateful-local-protection-
              01, 29 June 2018, <https://datatracker.ietf.org/doc/html/
              draft-cbrt-pce-stateful-local-protection-01>.

   [PCECC-BIER]
              Chen, R., Zhu, C., Xu, B., Chen, H., and A. Wang, "PCEP
              Procedures and Protocol Extensions for Using PCE as a
              Central Controller (PCECC) of BIER", Work in Progress,
              Internet-Draft, draft-chen-pce-pcep-extension-pce-
              controller-bier-06, 8 July 2024,
              <https://datatracker.ietf.org/doc/html/draft-chen-pce-
              pcep-extension-pce-controller-bier-06>.

   [PCECC-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-09, 4 July 2024,
              <https://datatracker.ietf.org/doc/html/draft-ietf-pce-
              pcep-extension-pce-controller-sr-09>.

   [PCECC-SRv6]
              Li, Z., Peng, S., Geng, X., and M. S. Negi, "PCE
              Communication Protocol (PCEP) Extensions for Using the PCE
              as a Central Controller (PCECC) for Segment Routing over
              IPv6 (SRv6) Segment Identifier (SID) Allocation and
              Distribution.", Work in Progress, Internet-Draft, draft-
              ietf-pce-pcep-extension-pce-controller-srv6-03, 18 August
              2024, <https://datatracker.ietf.org/doc/html/draft-ietf-
              pce-pcep-extension-pce-controller-srv6-03>.

   [PCEP-BIER]
              Chen, R., Zhang, Z., Chen, H., Dhanaraj, S., Qin, F., and
              A. Wang, "PCEP Extensions for Tree Engineering for Bit
              Index Explicit Replication (BIER-TE)", Work in Progress,
              Internet-Draft, draft-ietf-pce-bier-te-01, 10 October
              2024, <https://datatracker.ietf.org/doc/html/draft-ietf-
              pce-bier-te-01>.

   [PCEP-NATIVE]
              Wang, A., Khasanov, B., Fang, S., Tan, R., and C. Zhu,
              "Path Computation Element Communication Protocol (PCEP)
              Extensions for Native IP Networks", Work in Progress,
              Internet-Draft, draft-ietf-pce-pcep-extension-native-ip-
              40, 10 September 2024,
              <https://datatracker.ietf.org/doc/html/draft-ietf-pce-
              pcep-extension-native-ip-40>.

   [PCEP-POLICY]
              Koldychev, M., Sivabalan, S., Barth, C., Peng, S., and H.
              Bidgoli, "Path Computation Element Communication Protocol
              (PCEP) Extensions for Segment Routing (SR) Policy
              Candidate Paths", Work in Progress, Internet-Draft, draft-
              ietf-pce-segment-routing-policy-cp-18, 14 October 2024,
              <https://datatracker.ietf.org/doc/html/draft-ietf-pce-
              segment-routing-policy-cp-18>.

   [RFC1195]  Callon, R., "Use of OSI IS-IS for routing in TCP/IP and
              dual environments", RFC 1195, DOI 10.17487/RFC1195,
              December 1990, <https://www.rfc-editor.org/info/rfc1195>.

   [RFC2328]  Moy, J., "OSPF Version 2", STD 54, RFC 2328,
              DOI 10.17487/RFC2328, April 1998,
              <https://www.rfc-editor.org/info/rfc2328>.

   [RFC3209]  Awduche, D., Berger, L., Gan, D., Li, T., Srinivasan, V.,
              and G. Swallow, "RSVP-TE: Extensions to RSVP for LSP
              Tunnels", RFC 3209, DOI 10.17487/RFC3209, December 2001,
              <https://www.rfc-editor.org/info/rfc3209>.

   [RFC3985]  Bryant, S., Ed. and P. Pate, Ed., "Pseudo Wire Emulation
              Edge-to-Edge (PWE3) Architecture", RFC 3985,
              DOI 10.17487/RFC3985, March 2005,
              <https://www.rfc-editor.org/info/rfc3985>.

   [RFC4206]  Kompella, K. and Y. Rekhter, "Label Switched Paths (LSP)
              Hierarchy with Generalized Multi-Protocol Label Switching
              (GMPLS) Traffic Engineering (TE)", RFC 4206,
              DOI 10.17487/RFC4206, October 2005,
              <https://www.rfc-editor.org/info/rfc4206>.

   [RFC4364]  Rosen, E. and Y. Rekhter, "BGP/MPLS IP Virtual Private
              Networks (VPNs)", RFC 4364, DOI 10.17487/RFC4364, February
              2006, <https://www.rfc-editor.org/info/rfc4364>.

   [RFC4456]  Bates, T., Chen, E., and R. Chandra, "BGP Route
              Reflection: An Alternative to Full Mesh Internal BGP
              (IBGP)", RFC 4456, DOI 10.17487/RFC4456, April 2006,
              <https://www.rfc-editor.org/info/rfc4456>.

   [RFC4655]  Farrel, A., Vasseur, J.-P., and J. Ash, "A Path
              Computation Element (PCE)-Based Architecture", RFC 4655,
              DOI 10.17487/RFC4655, August 2006,
              <https://www.rfc-editor.org/info/rfc4655>.

   [RFC5036]  Andersson, L., Ed., Minei, I., Ed., and B. Thomas, Ed.,
              "LDP Specification", RFC 5036, DOI 10.17487/RFC5036,
              October 2007, <https://www.rfc-editor.org/info/rfc5036>.

   [RFC5150]  Ayyangar, A., Kompella, K., Vasseur, JP., and A. Farrel,
              "Label Switched Path Stitching with Generalized
              Multiprotocol Label Switching Traffic Engineering (GMPLS
              TE)", RFC 5150, DOI 10.17487/RFC5150, February 2008,
              <https://www.rfc-editor.org/info/rfc5150>.

   [RFC5151]  Farrel, A., Ed., Ayyangar, A., and JP. Vasseur, "Inter-
              Domain MPLS and GMPLS Traffic Engineering -- Resource
              Reservation Protocol-Traffic Engineering (RSVP-TE)
              Extensions", RFC 5151, DOI 10.17487/RFC5151, February
              2008, <https://www.rfc-editor.org/info/rfc5151>.

   [RFC5340]  Coltun, R., Ferguson, D., Moy, J., and A. Lindem, "OSPF
              for IPv6", RFC 5340, DOI 10.17487/RFC5340, July 2008,
              <https://www.rfc-editor.org/info/rfc5340>.

   [RFC5376]  Bitar, N., Zhang, R., and K. Kumaki, "Inter-AS
              Requirements for the Path Computation Element
              Communication Protocol (PCECP)", RFC 5376,
              DOI 10.17487/RFC5376, November 2008,
              <https://www.rfc-editor.org/info/rfc5376>.

   [RFC5541]  Le Roux, JL., Vasseur, JP., and Y. Lee, "Encoding of
              Objective Functions in the Path Computation Element
              Communication Protocol (PCEP)", RFC 5541,
              DOI 10.17487/RFC5541, June 2009,
              <https://www.rfc-editor.org/info/rfc5541>.

   [RFC7025]  Otani, T., Ogaki, K., Caviglia, D., Zhang, F., and C.
              Margaria, "Requirements for GMPLS Applications of PCE",
              RFC 7025, DOI 10.17487/RFC7025, September 2013,
              <https://www.rfc-editor.org/info/rfc7025>.

   [RFC7399]  Farrel, A. and D. King, "Unanswered Questions in the Path
              Computation Element Architecture", RFC 7399,
              DOI 10.17487/RFC7399, October 2014,
              <https://www.rfc-editor.org/info/rfc7399>.

   [RFC7432]  Sajassi, A., Ed., Aggarwal, R., Bitar, N., Isaac, A.,
              Uttaro, J., Drake, J., and W. Henderickx, "BGP MPLS-Based
              Ethernet VPN", RFC 7432, DOI 10.17487/RFC7432, February
              2015, <https://www.rfc-editor.org/info/rfc7432>.

   [RFC7491]  King, D. and A. Farrel, "A PCE-Based Architecture for
              Application-Based Network Operations", RFC 7491,
              DOI 10.17487/RFC7491, March 2015,
              <https://www.rfc-editor.org/info/rfc7491>.

   [RFC8279]  Wijnands, IJ., Ed., Rosen, E., Ed., Dolganow, A.,
              Przygienda, T., and S. Aldrin, "Multicast Using Bit Index
              Explicit Replication (BIER)", RFC 8279,
              DOI 10.17487/RFC8279, November 2017,
              <https://www.rfc-editor.org/info/rfc8279>.

   [RFC8300]  Quinn, P., Ed., Elzur, U., Ed., and C. Pignataro, Ed.,
              "Network Service Header (NSH)", RFC 8300,
              DOI 10.17487/RFC8300, January 2018,
              <https://www.rfc-editor.org/info/rfc8300>.

   [RFC8355]  Filsfils, C., Ed., Previdi, S., Ed., Decraene, B., and R.
              Shakir, "Resiliency Use Cases in Source Packet Routing in
              Networking (SPRING) Networks", RFC 8355,
              DOI 10.17487/RFC8355, March 2018,
              <https://www.rfc-editor.org/info/rfc8355>.

   [RFC8408]  Sivabalan, S., Tantsura, J., Minei, I., Varga, R., and J.
              Hardwick, "Conveying Path Setup Type in PCE Communication
              Protocol (PCEP) Messages", RFC 8408, DOI 10.17487/RFC8408,
              July 2018, <https://www.rfc-editor.org/info/rfc8408>.

   [RFC8664]  Sivabalan, S., Filsfils, C., Tantsura, J., Henderickx, W.,
              and J. Hardwick, "Path Computation Element Communication
              Protocol (PCEP) Extensions for Segment Routing", RFC 8664,
              DOI 10.17487/RFC8664, December 2019,
              <https://www.rfc-editor.org/info/rfc8664>.

   [RFC8735]  Wang, A., Huang, X., Kou, C., Li, Z., and P. Mi,
              "Scenarios and Simulation Results of PCE in a Native IP
              Network", RFC 8735, DOI 10.17487/RFC8735, February 2020,
              <https://www.rfc-editor.org/info/rfc8735>.

   [RFC8751]  Dhody, D., Lee, Y., Ceccarelli, D., Shin, J., and D. King,
              "Hierarchical Stateful Path Computation Element (PCE)",
              RFC 8751, DOI 10.17487/RFC8751, March 2020,
              <https://www.rfc-editor.org/info/rfc8751>.

   [RFC8754]  Filsfils, C., Ed., Dukes, D., Ed., Previdi, S., Leddy, J.,
              Matsushima, S., and D. Voyer, "IPv6 Segment Routing Header
              (SRH)", RFC 8754, DOI 10.17487/RFC8754, March 2020,
              <https://www.rfc-editor.org/info/rfc8754>.

   [RFC8821]  Wang, A., Khasanov, B., Zhao, Q., and H. Chen, "PCE-Based
              Traffic Engineering (TE) in Native IP Networks", RFC 8821,
              DOI 10.17487/RFC8821, April 2021,
              <https://www.rfc-editor.org/info/rfc8821>.

   [RFC8955]  Loibl, C., Hares, S., Raszuk, R., McPherson, D., and M.
              Bacher, "Dissemination of Flow Specification Rules",
              RFC 8955, DOI 10.17487/RFC8955, December 2020,
              <https://www.rfc-editor.org/info/rfc8955>.

   [RFC8986]  Filsfils, C., Ed., Camarillo, P., Ed., Leddy, J., Voyer,
              D., Matsushima, S., and Z. Li, "Segment Routing over IPv6
              (SRv6) Network Programming", RFC 8986,
              DOI 10.17487/RFC8986, February 2021,
              <https://www.rfc-editor.org/info/rfc8986>.

   [RFC9012]  Patel, K., Van de Velde, G., Sangli, S., and J. Scudder,
              "The BGP Tunnel Encapsulation Attribute", RFC 9012,
              DOI 10.17487/RFC9012, April 2021,
              <https://www.rfc-editor.org/info/rfc9012>.

   [RFC9050]  Li, Z., Peng, S., Negi, M., Zhao, Q., and C. Zhou, "Path
              Computation Element Communication Protocol (PCEP)
              Procedures and Extensions for Using the PCE as a Central
              Controller (PCECC) of LSPs", RFC 9050,
              DOI 10.17487/RFC9050, July 2021,
              <https://www.rfc-editor.org/info/rfc9050>.

   [RFC9087]  Filsfils, C., Ed., Previdi, S., Dawra, G., Ed., Aries, E.,
              and D. Afanasiev, "Segment Routing Centralized BGP Egress
              Peer Engineering", RFC 9087, DOI 10.17487/RFC9087, August
              2021, <https://www.rfc-editor.org/info/rfc9087>.

   [RFC9168]  Dhody, D., Farrel, A., and Z. Li, "Path Computation
              Element Communication Protocol (PCEP) Extension for Flow
              Specification", RFC 9168, DOI 10.17487/RFC9168, January
              2022, <https://www.rfc-editor.org/info/rfc9168>.

   [RFC9256]  Filsfils, C., Talaulikar, K., Ed., Voyer, D., Bogdanov,
              A., and P. Mattes, "Segment Routing Policy Architecture",
              RFC 9256, DOI 10.17487/RFC9256, July 2022,
              <https://www.rfc-editor.org/info/rfc9256>.

   [RFC9262]  Eckert, T., Ed., Menth, M., and G. Cauchie, "Tree
              Engineering for Bit Index Explicit Replication (BIER-TE)",
              RFC 9262, DOI 10.17487/RFC9262, October 2022,
              <https://www.rfc-editor.org/info/rfc9262>.

   [RFC9491]  Guichard, J., Ed. and J. Tantsura, Ed., "Integration of
              the Network Service Header (NSH) and Segment Routing for
              Service Function Chaining (SFC)", RFC 9491,
              DOI 10.17487/RFC9491, November 2023,
              <https://www.rfc-editor.org/info/rfc9491>.

   [RFC9522]  Farrel, A., Ed., "Overview and Principles of Internet
              Traffic Engineering", RFC 9522, DOI 10.17487/RFC9522,
              January 2024, <https://www.rfc-editor.org/info/rfc9522>.

   [RFC9552]  Talaulikar, K., Ed., "Distribution of Link-State and
              Traffic Engineering Information Using BGP", RFC 9552,
              DOI 10.17487/RFC9552, December 2023,
              <https://www.rfc-editor.org/info/rfc9552>.

   [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>.

   [RFC9604]  Sivabalan, S., Filsfils, C., Tantsura, J., Previdi, S.,
              and C. Li, Ed., "Carrying Binding Label/SID in PCE-Based
              Networks", RFC 9604, DOI 10.17487/RFC9604, August 2024,
              <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

   One of the main advantages of the PCECC solution is its backward
   compatibility.  The PCE server can function as a proxy node of the
   MPLS network for all the new nodes that no longer support the
   signalling protocols.

   As illustrated in the following example, the current network could
   migrate to a total PCECC-controlled network gradually by replacing
   the legacy nodes.  During the migration, the legacy nodes still need
   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
   path through the PCECC directly.  With the PCECC function as the
   proxy of these new nodes, MPLS signalling can populate through the
   network for both old and new nodes.

   The example described in this section is based on network
   configurations illustrated in Figure 13:

   +------------------------------------------------------------------+
   |                         PCE DOMAIN                               |
   |    +-----------------------------------------------------+       |
   |    |                       PCECC                         |       |
   |    +-----------------------------------------------------+       |
   |     ^              ^                      ^            ^         |
   |     |      PCEP    |                      |   PCEP     |         |
   |     V              V                      V            V         |
   | +--------+   +--------+   +--------+   +--------+   +--------+   |
   | | Node1  |   | Node2  |   | Node3  |   | Node4  |   | Node5  |   |
   | |        |...|        |...|        |...|        |...|        |   |
   | | Legacy |if1| Legacy |if2|Legacy  |if3| PCECC  |if4| PCECC  |   |
   | |  Node  |   |  Node  |   |Enabled |   |Enabled |   | Enabled|   |
   | +--------+   +--------+   +--------+   +--------+   +--------+   |
   |                                                                  |
   +------------------------------------------------------------------+

       Figure 13: PCECC-Initiated LSP Setup in the Network Migration

   In this example, there are five nodes for the TE LSP from the headend
   (Node1) to the tail end (Node5), where Node4 and Node5 are centrally
   controlled and other nodes are legacy nodes.

   *  Node1 sends a path request message for the setup of the LSP with
      the destination as Node5.

   *  The PCECC sends a reply message to Node1 for LSP setup with the
      path: (Node1, if1), (Node2, if2), (Node3, if3), (Node4, if4),
      Node5.

   *  Node1, Node2, and Node3 will set up the LSP to Node5 using the
      local labels as usual.  With the help of the PCECC, Node3 could
      proxy the signalling.

   *  Then, the PCECC will program the out-segment of Node3, the in-
      segment/out-segment of Node4, and the in-segment for Node5.

A.2.  PCECC for L3VPN and PWE3

   As described in [RFC8283], various network services may be offered
   over a network.  These include protection services (including Virtual
   Private Network (VPN) services such as L3VPN [RFC4364] or EVPNs
   [RFC7432]) or pseudowires [RFC3985].  Delivering services over a
   network in an optimal way requires coordination in the way where
   network resources are allocated to support the services.  A PCECC can
   consider the whole network and all components of a service at once
   when planning how to deliver the service.  It can then use PCEP to
   manage the network resources and to install the necessary
   associations between those resources.

   In the case of L3VPN, VPN labels could also be assigned and
   distributed through PCEP among the Provider Edge (PE) router instead
   of using the BGP protocols.

   The example described in this section is based on network
   configurations illustrated in Figure 14:

               +-------------------------------------------+
               |                   PCE DOMAIN              |
               |    +-----------------------------------+  |
               |    |                PCECC              |  |
               |    +-----------------------------------+  |
               |           ^          ^              ^     |
               | PWE3/L3VPN|PCEP  PCEP|LSP PWE3/L3VPN|PCEP |
               |           V          V              V     |
    +--------+ |     +--------+   +--------+   +--------+  |  +--------+
    |  CE    | |     | PE1    |   | Node x |   | PE2    |  |  |   CE   |
    |        |...... |        |...|        |...|        |.....|        |
    | Legacy | |if1  | PCECC  |if2|PCECC   |if3| PCECC  |if4  | Legacy |
    |  Node  | |     | Enabled|   |Enabled |   |Enabled |  |  |  Node  |
    +--------+ |     +--------+   +--------+   +--------+  |  +--------+
               |                                           |
               +-------------------------------------------+

                    Figure 14: PCECC for L3VPN and PWE3

   In the case of PWE3, instead of using the LDP signalling protocols,
   the label and port pairs assigned to each pseudowire can be assigned
   through the PCECC among the PE routers and the corresponding
   forwarding entries will be distributed into each PE router through
   the extended PCEP and PCECC mechanism.

A.3.  PCECC for Local Protection (RSVP-TE)

   [PCE-PROTECTION] claims that there is a need for the PCE to maintain
   and associate the local protection paths for the RSVP-TE LSP.  Local
   protection requires the setup of a bypass at the PLR.  This bypass
   can be PCC-initiated and delegated or PCE-initiated.  In either case,
   the PLR needs to maintain a PCEP session with the PCE.  The bypass
   LSPs need to be mapped to the primary LSP.  This could be done
   locally at the PLR based on a local policy, but there is a need for a
   PCE to do the mapping as well to exert greater control.

   This mapping can be done via PCECC procedures where the PCE could
   instruct the PLR to the mapping and identify the primary LSP for
   which bypass should be used.

A.4.  Using Reliable P2MP TE-Based Multicast Delivery for Distributed
      Computations (MapReduce-Hadoop)

   The MapReduce model of distributed computations in computing clusters
   is widely deployed.  In Hadoop (https://hadoop.apache.org/) 1.0
   architecture, MapReduce operations occur on big data in the Hadoop
   Distributed File System (HDFS), where NameNode knows about resources
   of the cluster and where actual data (chunks) for a particular task
   are located (which DataNode).  Each chunk of data (64 MB or more)
   should have three saved copies in different DataNodes based on their
   proximity.

   The proximity level currently has a semi-manual allocation and is
   based on Rack IDs (the assumption is that closer data is better
   because of access speed / smaller latency).

   The JobTracker node is responsible for computation tasks and
   scheduling across DataNodes and also has Rack awareness.  Currently,
   transport protocols between NameNode/JobTracker and DataNodes are
   based on IP unicast.  It has simplicity as an advantage but has
   numerous drawbacks related to its flat approach.

   There is a need to go beyond one data center (DC) for Hadoop cluster
   creation and move towards distributed clusters.  In that case, one
   needs to handle performance and latency issues.  Latency depends on
   the speed of light in the fiber links and on the latency introduced
   by intermediate devices in between.  The latter is closely correlated
   with network device architecture and performance.  The current
   performance of routers based on Network Processing Unit (NPU) should
   be enough for creating distributed Hadoop clusters with predicted
   latency.  The performance of software-based routers (mainly Virtual
   Network Functions (VNFs)) with additional hardware features such as
   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
   architecture for a distributed Hadoop cluster.

   There is research [MAP-REDUCE] that shows how usage of the multicast
   tree could improve the speed of resource or cluster members'
   discovery inside the cluster as well as increased redundancy in
   communications between cluster nodes.

   The conventional IP-based multicast may not be appropriate because it
   requires an additional control plane (IGMP, PIM) and a lot of
   signalling, which is not suitable for high-performance computations
   that are very sensitive to latency.

   P2MP TE tunnels are more suitable as a potential solution for the
   creation of multicast-based communications between NameNode as the
   root and DataNodes as leaves inside the cluster.  These P2MP tunnels
   could be dynamically created and turned down (with no manual
   intervention).  Here, the PCECC comes into play with the main
   objective of creating an optimal topology for each particular request
   for MapReduce computation and creating P2MP tunnels with needed
   parameters such as BW and delay.

   This solution will require the use of MPLS label-based forwarding
   inside the cluster.  The usage of label-based forwarding inside DC
   was proposed by Yandex [MPLS-DC].  Technically, it is already
   possible because MPLS on switches is already supported by some
   vendors, and MPLS also exists on Linux and Open vSwitch (OVS).

   A possible framework for this task is shown in Figure 15:

                      +--------+
                      |  APP   |
                      +--------+
                           | NBI (REST API,...)
                           |
               PCEP       +----------+  REST API
        +---------+   +---|  PCECC   |----------+
        | Client  |---|---|          |          |
        +---------+   |   +----------+          |
                |     |       | |  |            |
                +-----|---+   |PCEP|            |
             +--------+   |   | |  |            |
             |            |   | |  |            |
             | REST API   |   | |  |            |
             |            |   | |  |            |
   +-------------+        |   | |  |           +----------+
   | Job Tracker |        |   | |  |           | NameNode |
   |             |        |   | |  |           |          |
   +-------------+        |   | |  |           +----------+
           +------------------+ |  +-----------+
           |              |     |              |
       |---+-----P2MP TE--+-----|-----------|  |
   +-----------+       +-----------+      +-----------+
   | DataNode1 |       | DataNode2 |      | DataNodeN |
   |TaskTracker|       |TaskTracker| .... |TaskTracker|
   +-----------+       +-----------+      +-----------+

       Figure 15: Using Reliable P2MP TE-Based Multicast Delivery for
                Distributed Computations (MapReduce-Hadoop)

   Communication between the JobTracker, NameNode, and PCECC can be done
   via REST API directly or via a cluster manager such as Mesos.

   *  Phase 1: Distributed cluster resource discovery occurs during this
      phase.  JobTracker and NameNode should identify and find available
      DataNodes according to computing requests from the application
      (APP).  NameNode should query the PCECC about available DataNodes,
      and NameNode may provide additional constraints to the PCECC such
      as topological proximity and redundancy level.

      The PCECC should analyze the topology of the distributed cluster
      and perform a constraint-based path calculation from the client
      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 2: The PCECC should create P2MP LSPs from the client towards
      those DataNodes by means of PCEP messages following the previously
      calculated path.

   *  Phase 3: NameNode should send this information to the client, and
      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.

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.

Contributors

   Luyuan Fang
   United States of America
   Email: luyuanf@gmail.com


   Chao Zhou
   HPE
   Email: chaozhou_us@yahoo.com


   Boris Zhang
   Amazon
   Email: zhangyud@amazon.com


   Artsiom Rachytski
   AWS
   Germany
   Email: arachyts@gmail.com


   Anton Hulida
   AWS
   Australia
   Email: hulidant@amazon.com


Authors' Addresses

   Zhenbin (Robin) Li
   Huawei Technologies
   Huawei Bld., No.156 Beiqing Rd.
   Beijing
   100095
   China
   Email: lizhenbin@huawei.com


   Dhruv Dhody
   Huawei Technologies
   India
   Email: dhruv.ietf@gmail.com


   Quintin Zhao
   Etheric Networks
   1009 S Claremont St.
   San Mateo, CA 94402
   United States of America
   Email: quintinzhao@gmail.com


   King He
   Tencent Holdings Ltd.
   Shenzhen
   China
   Email: kinghe@tencent.com