Internet Engineering Task Force D. King Internet-Draft Old Dog Consulting Intended status: Informational A. Farrel Expires: 15 January 2014 Juniper Networks 15 July 2013 A PCE-based Architecture for Application-based Network Operations draft-farrkingel-pce-abno-architecture-05.txt Abstract Services such as content distribution, distributed databases, or inter-data center connectivity place a set of new requirements on the operation of networks. They need on-demand and application-specific reservation of network connectivity, reliability, and resources (such as bandwidth) in a variety of network applications (such as point-to- point connectivity, network virtualization, or mobile back-haul) and in a range of network technologies from packet (IP/MPLS) down to optical. An environment that operates to meet this type of requirement is said to have Application-Based Network Operations (ABNO). ABNO brings together many existing technologies for gathering information about the resources available in a network, for consideration of topologies and how those topologies map to underlying network resources, for requesting path computation, and for provisioning or reserving network resources. Thus, ABNO may be seen as the use of a toolbox of existing components enhanced with a few new elements. The key component within an ABNO is the Path Computation Element (PCE), which can be used for computing paths and is further extended to provide policy enforcement capabilities for ABNO. This document describes an architecture and framework for ABNO showing how these components fit together. It provides a cookbook of existing technologies to satisfy the architecture and meet the needs of the applications. King & Farrel [Page 1]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 Status of this Memo This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet- Drafts is at http://datatracker.ietf.org/drafts/current/. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." Copyright Notice Copyright (c) 2013 IETF Trust and the persons identified as the document authors. All rights reserved. This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License. King & Farrel [Page 2]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 Table of Contents 1. Introduction ................................................ 4 1.1 Scope ..................................................... 5 2. Application-based Network Operations (ABNO) .................. 5 2.1 Assumptions and Requirements .............................. 5 2.2 Implementation of the Architecture ........................ 6 2.3 Generic Architecture ...................................... 8 2.3.1 ABNO Components ........................................ 9 2.3.2 ABNO Functional Interfaces ............................ 14 3. ABNO Use Cases .............................................. 21 3.1 Inter-AS Connectivity ..................................... 21 3.2 Multi-Layer Networking .................................... 27 3.2.1 Data Center (DC) Interconnection across MLNs........... 31 3.3 Make-Before-Break ......................................... 34 3.3.1 Make-Before-Break for Re-optimization ................. 34 3.3.2 Make-Before-Break for Restoration ..................... 35 3.3.3 Make-Before-Break for Path Test and Selection ......... 36 3.4 Global Concurrent Optimization ............................ 38 3.4.1 Use Case: GCO with MPLS LSPs .......................... 39 3.5 Adaptive Network Management (ANM) ......................... 41 3.5.1. ANM Trigger ........................................ 42 3.5.2. Processing request and GCO computation ............. 42 3.5.3. Automated Provisioning Process ..................... 43 3.6 Pseudowire Operations and Management ...................... 44 3.6.1 Multi-Segment Pseudowires ........................... 44 3.6.2 Path-Diverse Pseudowires ............................ 46 3.6.3 Path-Diverse Multi-Segment Pseudowires .............. 47 3.6.4 Pseudowire Segment Protection ....................... 48 3.6.5 Applicability of ABNO to Pseudowires ................ 48 3.7 Other Potential Use Cases ................................. 49 3.7.1 Grooming and Regrooming ............................. 49 3.7.2 Bandwidth Scheduling ................................ 49 3.7.3 ALTO Server ......................................... 49 4. Survivability and Redundancy within the ABNO Architecture ... 49 5. Security Consideration ...................................... 49 6. Manageability Considerations ................................ 49 7. IANA Considerations ......................................... 50 8. Acknowledgements ............................................ 50 9. References .................................................. 50 9.1 Informative References ................................... 50 10. Contributors' Addresses .................................... 54 11. Authors' Addresses ......................................... 54 A. Undefined Interfaces ........................................ 55 King & Farrel [Page 3]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 1. Introduction Networks today integrate multiple technologies allowing network infrastructure to deliver a variety of services to support the different characteristics and demands of applications. There is an increasing demand to make the network responsive to service requests issued directly from the application layer. This differs from the established model where services in the network are delivered in response to management commands driven by a human user. These application-driven requests and the services they establish place a set of new requirements on the operation of networks. They need on-demand and application-specific reservation of network connectivity, reliability, and resources (such as bandwidth) in a variety of network applications (such as point-to-point connectivity, network virtualization, or mobile back-haul) and in a range of network technologies from packet (IP/MPLS) down to optical. An environment that operates to meet this type of application-aware requirement is said to have Application-Based Network Operation (ABNO). The Path Computation Element (PCE) [RFC4655] was developed to provide path computation services for GMPLS and MPLS networks. The applicability of PCE can be extended to provide path computation and policy enforcement capabilities for ABNO platforms and services. ABNO can provide the following types of service to applications by coordinating the components that operate and manage the network: - Optimization of traffic flows between applications to create an overlay network for communication in use cases such as file sharing, data caching or mirroring, media streaming, or real-time communications described as Application Layer Traffic Optimization (ALTO) [RFC5693]. - Remote control of network components allowing coordinated programming of network resources through such techniques as Forwarding and Control Element Separation (ForCES) [RFC3746], OpenFlow [ONF], and the Interface to the Routing System (I2RS) [I-D.atlas-i2rs-architecture]. - Interconnection of Content Delivery Networks (CDNi) [RFC6707] through the establishment and resizing of connections between content distribution networks. - Network resource coordination to facilitate grooming and regrooming, bandwidth scheduling, and global concurrent optimization [RFC5557]. King & Farrel [Page 4]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 - Virtual Private Network (VPN) planning in support of deployment of new VPN customers and to facilitate inter-data center connectivity. This document outlines the architecture and use cases for ABNO, and shows how the ABNO architecture can be used for co-ordinating control system and application requests to compute paths, enforce policies, and manage network resources for the benefit of the applications that use the network. The examination of the use cases shows the ABNO architecture as a toolkit comprising many existing components and protocols and so this document looks like a cookbook. 1.1 Scope This document describes a toolkit. It shows how existing functional components described in a large number of separate documents can be brought together within a single architecture to provide the function necessary for ABNO. In many cases, existing protocols are known to be good enough or almost good enough to satisfy the requirements of interfaces between the components. In these cases the protocols are called out as suitable candidates for use within an implementation of ABNO. In other cases it is clear that further work will be required, and in those cases a pointer to on-going work that may be of use is provided. Where there is no current work that can be identified by the authors, a short description of the missing interface protocol is given in the Appendix. Thus, this document may be seen as providing an applicability statement for existing protocols, and guidance for developers of new protocols or protocol extensions. 2. Application Based Network Operations (ABNO) 2.1 Assumptions The principal assumption underlying this document is that existing technologies should be used where they are adequate for the task. Furthermore, when an existing technology is almost sufficient, it is assumed to be preferable to make minor extensions rather than to invent a whole new technology. Note that this document describes an architecture. Functional components are architectural concepts and have distinct and clear responsibilities. Pairs of functional components interact at functional interfaces that are, themselves, architectural concepts. King & Farrel [Page 5]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 2.2 Implementation of the Architecture It needs to be strongly emphasized that this document describes a functional architecture. It is not a software design. Thus, it is not intended that this architecture constrain implementations. However, the separation of the ABNO functions into separate functional components with clear interfaces between them enables implementations to choose which features to include and allows different functions to be distributed across distinct processes or even processors. An implementation of this architecture may make several important decisions about the functional components: - Multiple functional components may be grouped together into one software component such that all of the functions are bundled and only the external interfaces are exposed. This may have distinct advantages for fast paths within the software, and can reduce inter-process communication overhead. For example, an active, stateful PCE could be implemented as a single server combining the ABNO components of the PCE, the Traffic Engineering Database, and the Provisioning Manager (see Section 2.3). - The functional components could be distributed across separate processes, processors, or servers so that the interfaces are exposed as external protocols. For example, the OAM Handler (see Section 2.3.1.6) could be presented on a dedicated server in the network that consumes all status reports from the network, aggregates them, correlates them, and then dispatches notifications to other servers that need to understand what has happened. - There could be multiple instances of any or each of the components. That is, the function of a functional component could be partitioned across multiple software components with each responsible for handling a specific feature or a partition of the network. For example, there may be multiple Traffic Engineering Databases (see Section 2.3.1.8) in an implementation with each holding the topology information of a separate network domain (such as a network layer or an Autonomous System). Similarly there could be multiple PCE instances each processing on a different Traffic Engineering Database, and potentially distributed on different servers under different management control. As a final example, King & Farrel [Page 6]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 there could be multiple ABNO Controllers each with capability to support different classes of application or application service. The purpose of the description of this architecture is to facilitate different implementations while offering interoperability between implementations of key components and easy interaction with the applications and with the network devices. King & Farrel [Page 7]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 2.3 Generic ABNO Architecture The following diagram illustrates the ABNO architecture. The components and functional interfaces are discussed in Sections 2.3.1 2.3.2 respectively. The use cases described in Section 3 show how different components are used selectively to provide different services. +----------------------------------------------------------------+ | OSS / NMS / Application Service Coordinator | +-+---+---+----+-----------+---------------------------------+---+ | | | | | | ...|...|...|....|...........|.................................|...... : | | | | +----+----------------------+ | : : | | | +--+---+ | | +---+---+ : : | | | |Policy+--+ ABNO Controller +------+ | : : | | | |Agent | | +--+ | OAM | : : | | | +-+--+-+ +-+------------+----------+-+ | |Handler| : : | | | | | | | | | | | : : | | +-+---++ | +----+-+ +-------+-------+ | | +---+---+ : : | | |ALTO | +-+ VNTM |--+ | | | | : : | | |Server| +--+-+-+ | | | +--+---+ | : : | | +--+---+ | | | PCE | | | I2RS | | : : | | | +-------+ | | | | |Client| | : : | | | | | | | | +-+--+-+ | : : | +-+----+--+-+ | | | | | | | : : | | Databases +-------:----+ | | | | | : : | | TED | | +-+---+----+----+ | | | | : : | | LSP-DB + | | | | | | | | : : | +-----+--+--+ +-+---------------+-------+-+ | | | : : | | | | Provisioning Manager | | | | : : | | | +-----------------+---+-----+ | | | : ...|.......|..|.................|...|....|...|.......|..|.....|...... | | | | | | | | | | | +-+--+-----------------+--------+-----------+----+ | +----/ Client Network Layer \--+ | +----------------------------------------------------+ | | | | | | | ++------+-------------------------+--------+----------+-----+-+ / Server Network Layers \ +-----------------------------------------------------------------+ Figure 1: Generic ABNO Architecture King & Farrel [Page 8]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 2.3.1 ABNO Components This section describes the functional components shown as boxes in Figure 1. The interactions between those components, the functional interfaces, are described in Section 2.3.2. 2.3.1.1 NMS and OSS A Network Management Station (NMS) or an Operations Support System (OSS) can be used to control, operate, and manage a network. Within the ABNO architecture, an NMS or OSS may issue high-level service requests to the ABNO Controller. It may also establish policies for the activities of the components within the architecture. The NMS and OSS can be consumers of network events reported through the OAM Handler and can act on these reports as well as displaying them to users and raising alarms. The NMS and OSS can also access the Traffic Engineering Database (TED) and Label Switched Path Database (LSP-DB) to show the users the current state of the network. Lastly, the NMS and OSS may utilize a direct programmatic or configuration interface to interact with the network elements within the network. 2.3.1.2 Application Service Coordinator In addition to the NMS and OSS, services in the ABNO architecture may be requested by or on behalf of applications. In this context the term "application" is very broad. An application may be a program that runs on a host or server and that provides services to a user, such as a video conferencing application. Alternatively, an application may be a software tool with which a user makes requests of the network to set up specific services such as end-to-end connections or scheduled bandwidth reservations. Finally, an application may be a sophisticated control system that is responsible for arranging the provision of a more complex network service such as a virtual private network. For the sake of this architecture, all of these concepts of an application are grouped together and are shown as the Application Service Coordinator since they are all in some way responsible for coordinating the activity of the network to provide services for use by applications. In practice, the function of the Application Service Coordinator may be distributed across multiple applications or servers. The Application Service Coordinator communicates with the ABNO Controller to request operations on the network. King & Farrel [Page 9]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 2.3.1.3 ABNO Controller The ABNO Controller is the main gateway to the network for the NMS, OSS, and Application Service Coordinator for the provision of advanced network coordination and functions. The ABNO Controller governs the behavior of the network in response to changing network conditions and in accordance with application network requirements and policies. It is the point of attachment, and invokes the right components in the right order. The use cases in Section 3 provide a clearer picture of how the ABNO Controller interacts with the other components in the ABNO architecture. 2.3.1.4 Policy Agent Policy plays a very important role in the control and management of the network. It is, therefore, significant in influencing how the key components of the ANBO architecture operate. Figure 1 shows the Policy Agent as a component that is configured by the NMS/OSS with the policies that it applies. The Policy Agent is responsible for propagating those policies into the other components of the system. Simplicity in the figure necessitates leaving out many of the policy interactions that will take place. Although the Policy Agent is only shown interacting with the ABNO Controller, the Alto Server, and the Virtual Network Topology Manager (VNTM), it will also interact with a number of other components and the network elements themselves. For example, the Path Computation Element (PCE) will be a Policy Enforcement Point (PEP) [RFC2753] as described in [RFC5394], and the Interface to the Routing System (I2RS) Client will also be a PEP as noted in [I-D.atlas-i2rs-architecture]. 2.3.1.5 Interface to the Routing System (I2RS) Client The Interface to the Routing System (I2RS) is described in [I-D.atlas-i2rs-architecture]. The interface provides a programmatic way to access (for read and write) the routing state and policy information on routers in the network. The I2RS Client is introduced in [I-D.atlas-i2rs-problem-statement]. Its purpose is to manage information requests across a number of routers (each of which runs an I2RS Agent) and coordinate setting or gathering state to/from those routers. King & Farrel [Page 10]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 2.3.1.6 OAM Handler Operations, Administration, and Maintenance (OAM) plays a critical role in understanding how a network is operating, detecting faults, and taking the necessary action to react to problems in the network. Within the ABNO architecture, the OAM Handler is responsible for receiving notifications (often called alerts) from the network about potential problems, for correlating them, and for triggering other components of the system to take action to preserve or recover the services that were established by the ABNO Controller. The OAM Handler also reports network problems and, in particular, service- affecting problems to the NMS, OSS, and Application Service Coordinator. Additionally, the OAM Handler interacts with the devices in the network to initiate OAM actions within the data plane such as monitoring and testing. 2.3.1.7 Path Computation Element (PCE) The Path Computation Element (PCE) is introduced in [RFC4655]. It is a functional component that services requests to compute paths across a network graph. In particular, it can generate traffic engineered routes for MPLS-TE and GMPLS Label Switched Paths (LSPs). The PCE may receive these requests from the ABNO Controller, from the Virtual Network Topology Manager, or from network elements themselves. The PCE operates on a view of the network topology stored in the Traffic Engineering Database (TED). A more sophisticated computation may be provided by a Stateful PCE that enhances the TED with information about the LSPs that are provisioned and operational within the network as described in [RFC4655] and [I-D.ietf-pce-stateful-pce]. Additional function in an Active PCE allows a functional component that includes a Stateful PCE to make provisioning requests to set up new services or to modify in-place services as described in [I-D.ietf-pce-stateful-pce] and [I-D.crabbe-pce-pce-initiated-lsp]. This function may directly access the network elements, or may be channelled through the Provisioning Manager. Coordination between multiple PCEs operating on different TEDs can prove useful for performing path computation in multi-domain (for example, inter-AS) or multi-layer networks. Since the PCE is a key component of the ABNO architecture, a better King & Farrel [Page 11]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 view of its role can be gained by examining the use cases described in Section 3. 2.3.1.8 Databases The ABNO Architecture includes a number of databases that contain information stores for use by the system. The two main databases are the Traffic Engineering Database (TED) and the LSP Database (LSP-DB), but there may be a number of other databases to contain information about topology (ALTO Server), policy (Policy Agent), services (ABNO Controller), etc. 2.3.1.8.1 Traffic Engineering Database (TED) The Traffic Engineering Database (TED) is a data store of topology information about a network that may be enhanced with capability data (such as metrics or bandwidth capacity) and active status information (such as up/down status or residual unreserved bandwidth). The TED may be built from information supplied by the network or from data (such as inventory details) sourced through the NMS/OSS. The principal use of the TED in the ABNO architecture is to provide the raw data on which the Path Computation Element operates. But the TED may also be inspected by users at the NMS/OSS to view the current status of the network, and may provide information to application services such as Application Layer Traffic Optimization (ALTO) [RFC5693]. 2.3.1.8.2 LSP Database The LSP Database (LSP-DB) is a data store of information about LSPs that have been set up in the network, or that could be established. The information stored includes the paths and resource usage of the LSPs. The LSP-DB may be built from information generated locally . For example, when LSPs are provisioned, the LSP-DB can be updated. The database can also be constructed from information gathered from the network by polling or reading the state of LSPs that have already been set up. The main use of the LSP-DB within the ABNO architecture is to enhance the planning and optimization of LSPs. New LSPs can be established to be path-disjoint from other LSPs in order to offer protected services; LSPs can be rerouted in order to put them on more optimal paths or to make network resources available for other LSPs; LSPs can King & Farrel [Page 12]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 be rapidly repaired when a network failure is reported; LSPs can be moved onto other paths in order to avoid resources that have planned maintenance outages. 2.3.1.8.3 Other Databases There may be other databases that are built within the ABNO system and which are referenced when operating the network. These databases might include information about, for example, traffic flows and demands, predicted or scheduled traffic demands, links and node failure and repair history, network resources such as packet labels and physical labels (i.e., MPLS and GMPLS labels), etc. 2.3.1.9 ALTO Server [Editor's note: The ALTO Server is a component of the architecture. Text needs to be supplied.] 2.3.1.10 Virtual Network Topology Manager (VNTM) A Virtual Network Topology (VNT) is defined in [RFC5212] as a set of one or more LSPs in one or more lower-layer networks that provides information for efficient path handling in an upper-layer network. For instance, a set of LSPs in a wavelength division multiplexed (WDM) network can provide connectivity as virtual links in a higher- layer packet switched network. The VNT enhances the physical/dedicated links that are available in the upper-layer network and is configured by setting up or tearing down the lower-layer LSPs and by advertising the changes into the higher-layer network. The VNT can be adapted to traffic demands so that capacity in the higher-layer network can be created or released as needed. Releasing unwanted VNT resources makes them available in the lower-layer network for other uses. The creation of virtual topology for inclusion in a network is not a simple task. Decisions must be made about which nodes in the upper- layer it is best to connect, in which lower-layer network to provision LSPs to provide the connectivity, and how to route the LSPs in the lower-layer network. Furthermore, some specific actions have to be taken to cause the lower-layer LSPs to be provisioned and the connectivity in the upper-layer network to be advertised. [RFC5623] describes how the VNTM may instantiate connections in the server-layer in support of connectivity in the client-layer. Within the ABNO architecture, the creation of new connections may be delegated to the Provisioning Manager as discussed in Section 2.3.1.11. King & Farrel [Page 13]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 All of these actions and decisions are heavily influenced by policy, so the VNTM component that coordinates them takes input from the Policy Agent. The VNTM is also closely associated with the PCE for the upper-layer network and each of the PCEs for the lower-layer networks. 2.3.1.11 Provisioning Manager The Provisioning Manager is responsible for making or channelling requests for the establishment of LSPs. This may be instructions to the control plane running in the networks, or may involve the programming of individual network devices. In the latter case, the Provisioning Manager may act as an OpenFlow Controller [ONF]. See Section 2.3.2.6 for more details of the interactions between the Provisioning Manager and the network. 2.3.1.12 Client and Server Network Layers The client and server networks are shown in Figure 1 as illustrative examples of the fact that the ABNO architecture may be used to coordinate services across multiple networks where lower-layer networks provide connectivity in upper-layer networks. Section 3.2 describes a set of use cases for multi-layer networking. 2.3.2 Functional Interfaces This section describes the interfaces between functional components that might be externalized in an implementation allowing the components to be distributed across platforms. Where existing protocols might provide all or most of the necessary capabilities they are noted. Appendix A notes the interfaces where more protocol specification may be needed. 2.3.2.1 Configuration and Programmatic Interfaces The network devices may be configured or programmed direct from the NMS/OSS. Many protocols already exist to perform these functions including: - SNMP [RFC3412] - Netconf [RFC6241] - ForCES [RFC5810] - OpenFlow [ONF]. [Editor note: need to add the correct TMF interface with a reference] King & Farrel [Page 14]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 From the ABNO perspective, network configuration is a pass-through function. It can be seen represented on the left hand side of Figure 1. 2.3.2.2 TED Construction from the Networks As described in Section 2.3.1.8, the TED provides details of the capabilities and state of the network for use by the ABNO system and the PCE in particular. The TED can be constructed by participating in the IGP-TE protocols run by the networks (for example, OSPF-TE [RFC3630] and ISIS-TE [RFC5305]). Alternatively, the TED may be fed using link-state distribution extensions to BGP [I-D.ietf-idr-ls-distribution]. The ABNO system may maintain a single TED unified across multiple networks, or may retain a separate TEDs for each network. Additionally, an ALTO Server [RFC5693] may provide an abstracted topology from a network to build an application-level TED that can be used by a PCE to compute paths between servers and application- layer entities for the provision of application services. 2.3.2.3 TED Enhancement The TED may be enhanced by inventory information supplied from the NMS/OSS. This may supplement the data collected as described in Section 2.3.2.2 with information that is not normally distributed within the network such as node types and capabilities, or the characteristics of optical links. No protocol is currently identified for this interface, but the protocol developed or adopted to satisfy the requirements of the Interface to the Routing System (I2RS) [I-D.atlas-i2rs-architecture] may be a suitable candidate because it is required to be able to distribute bulk routing state information in a well-defined encoding language. Another candidate protocol may be Netconf [RFC6241] passing data encoded using YANG [RFC6020]. Note that, in general, any protocol and encoding that is suitable for presenting the TED as described in Section 2.3.2.4 will likely be suitable (or could be made suitable) for enabling write-access to the TED as described in this section. 2.3.2.4 TED Presentation The TED may be presented north-bound from the ABNO system for use by an NMS/OSS or by the Application Service Coordinator. This allows King & Farrel [Page 15]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 users and applications to get a view of the network topology and the status of the network resources. It also allows planning and provisioning of application services. There are several protocols available for exporting the TED north- bound: - The ALTO protocol [I-D.ietf-alto-protocol] is designed to distribute the abstracted topology used by an ALTO Server and may prove useful for exporting the TED. - The same protocol used to export topology information from the network can be used to export the topology from the TED. [I-D.ietf-idr-ls-distribution]. - The Interface to the Routing System (I2RS) [I-D.atlas-i2rs-architecture] will require a protocol that is capable of handling bulk routing information exchanges that would be suitable for exporting the TED. In this case it would make sense to have a standardized representation of the TED in a formal data modelling language such as YANG [RFC6020] so that an existing protocol could be used such as Netconf [RFC6241] or XMPP [RFC6120]. Note that export from the TED can be a full dump of the content (expressed in a suitable abstraction language) as described above, or it could be an aggregated or filtered set of data based on policies or specific requirements. Thus, the relationships shown in Figure 1 may be a little simplistic in that the ABNO Controller may also be involved in preparing and presenting the TED information over a north-bound interface. [Editor's note: This section should include more information about the northbound export of information from the ALTO Server. Text needs to be supplied.] 2.3.2.5 Path Computation Requests from the Network As originally specified in the PCE architecture [RFC4655], network elements can make path computation requests to a PCE using the PCE protocol (PCEP) [RFC5440]. This facilitates the network setting up LSPs in response to simple connectivity requests, and it allows the network to re-optimize or repair LSPs. 2.3.2.6 Provisioning Manager Control of Networks As described in Section 2.3.1.11, the Provisioning Manager makes or channels requests to provision resources in the network. These operations can take place at two levels: there can be requests to King & Farrel [Page 16]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 program/configure specific resources in the data or forwarding planes; and there can be requests to trigger a set of actions to be programmed with the assistance of a control plane. A number of protocols already exist to provision network resources as follows: - Program/configure specific network resources - ForCES [RFC5810] defines a protocol for separation of the control element (the Provisioning Manager) from the forwarding elements in each node in the network. - The Generic Switch Management Protocol (GSMP) [RFC3292] is an asymmetric protocol that allows one or more external switch controllers (such as the Provisioning Manager) to establish and maintain the state of a label switch such as an MPLS switch. - OpenFlow [ONF] is a communications protocol that gives an OpenFlow Controller (such as the Provisioning Manager) access to the forwarding plane of a network switch or router in the network. - Historically, other configuration-based mechanisms have been used to set up the forwarding/switching state at individual nodes within networks. Such mechanisms have ranged from non-standard command line interfaces (CLIs) to various standards-based options such as TL1 [TL1] and SNMP [RFC3412]. These mechanisms are not designed for rapid operation of a network and are not easily programmatic. They are not proposed for use by the Provisioning Manager as part of the ABNO architecture. - Netconf [RFC6241] provides a more active configuration protocol that may be suitable for bulk programming of network resources. Its use in this way is dependent on suitable YANG modules being defined for the necessary options. Early work in the IETF's Netmod working group is focused on a higher level of routing function more comparable with the function discussed in Section 2.3.2.8 [I-D.ietf-netmod-routing-cfg]. - [Editor note: need to add the correct TMF interface with a reference] - Trigger actions through the control plane - LSPs can be requested using a management system interface to the head end of the LSP using tools such as CLIs, TL1 [TL1] or SNMP [RFC3412]. Configuration at this granularity is not as time- King & Farrel [Page 17]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 critical as when individual network resources are programmed because the main task of programming end-to-end connectivity is devolved to the control plane. Nevertheless, these mechanisms remain unsuitable for programmatic control of the network and are not proposed for use by the Provisioning Manager as part of the ABNO architecture. - As noted above, Netconf [RFC6241] provides a more active configuration protocol. This may be particularly suitable for requesting the establishment of LSPs. Work would be needed to complete a suitable YANG module. - The PCE protocol (PCEP) [RFC5440] has been proposed as a suitable protocol for requesting the establishment of LSPs [I-D.crabbe-pce-pce-initiated-lsp]. This works well because the protocol elements necessary are exactly the same as used to respond to a path computation request. The functional element that issues PCEP requests to establish LSPs is known as an "Active PCE", however it should be noted that the ABNO functional components responsible for requesting LSPs is the Provisioning Manager. Other controllers like the the VNTM and the ABNO Controller use the services of the Provisioning Manager to isolate the twin functions of computing and requesting paths from the provisioning mechanisms in place with any given network. Note that I2RS does not provide a mechanism for control of network resources at this level as it is designed to provide control of routing state in routers, not forwarding state in the data plane. 2.3.2.7 Auditing the Network Once resources have been provisioned or connections established in the network, it is important that the ABNO system can determine the state of the network. This function falls into four categories: - Updates to the TED are gathered as described in Section 2.3.2.2. - Explicit notification of the successful establishment and the subsequent state of LSP can be provided through extensions to PCEP as described in [I-D.ietf-pce-stateful-pce] and [I-D.crabbe-pce-pce-initiated-lsp]. - OAM can be commissioned and the results inspected by the OAM Handler as described in Section 2.3.2.13. - A number of ABNO components may make inquiries and inspect network King & Farrel [Page 18]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 state through a variety of techniques including I2RS, Netconf, or SNMP. 2.3.2.8 Controlling The Routing System As discussed in Section 2.3.1.5, the Interface to the Routing System (I2RS) provides a programmatic way to access (for read and write) the routing state and policy information on routers in the network. The I2RS Client issues requests to routers in the network to establish or retrieve routing state. Those requests utilize the I2RS protocol which has yet to be selected/designed by the IETF. 2.3.2.9 ABNO Controller Interface to PCE The ABNO Controller needs to be able to consult the PCE to determine what services can be provisioned in the network. There is no reason why this interface cannot be based on the standard PCE protocol as defined in [RFC5440]. 2.3.2.10 VNTM Interface to and from PCE There are two interactions between the Virtual Network Topology Manager and the PCE. The first interaction is used when VNTM wants to determine what LSPs can be set up in a network: in this case it uses the standard PCEP interface [RFC5440] to make path computation requests. The second interaction arises when a PCE determines that it cannot compute a requested path or notices that (according to some configured policy) a network is short of resources (for example, the capacity on some key link is close to exhausted). In this case, the PCE may notify the VNTM which may (again according to policy) act to construct more virtual topology. This second interface is not currently specified although it may be that the protocol selected or designed to satisfy I2RS will provide suitable features (see Section 2.3.2.8). 2.3.2.11 ABNO Control Interfaces The north-bound interface from the ABNO Controller is used by the NMS, OSS, and Application Service Coordinator to request services in the network in support of applications. The interface will also need to be able to report the asynchronous completion of service requests and convey changes in the status of services. This interface will also need strong capabilities for security, authentication, and policy. King & Farrel [Page 19]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 This interface is not currently specified. It needs to be a transactional interface that supports the specification of abstract services with adequate flexibility to facilitate easy extension and yet be concise and easily parsable. It is possible that the protocol selected or designed to satisfy I2RS will provide suitable features (see Section 2.3.2.8). 2.3.2.12 Policy Interfaces As described in Section 2.3.1.4 and throughout this document, policy forms a critical component of the ABNO architecture. The role of policy will include enforcing the following rules and requirements: - Adding resources on demand should be gated by the authorized capability. - Client microflows should not trigger server-layer setup or allocation. - Accounting capabilities should be supported. - Security mechanisms for authorization of requests and capabilities are required. Other policy-related function in the system might include the policy behavior of the routing and forwarding system such as: - ECMP behavior - Classification of packets onto LSPs. Various policy-capable architectures have been defined including a framework for using policy with a PCE-enabled system [RFC5394]. However, the take-up of the IETF's Common Open Policy Service protocol (COPS) [RFC2748] has been poor. New work will be needed to define all of the policy interfaces within the ABNO architecture and to determine which are internal interfaces and which may be external and so in need of a protocol specification. There is some discussion that the I2RS protocol may support the configuration and manipulation of policies. 2.3.2.13 OAM and Reporting The OAM Handler must interact with the networks to perform several actions: - Enabling OAM function within the network. King & Farrel [Page 20]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 - Performing proactive OAM operations in the network. - Receiving notifications of network events. Any of the configuration and programmatic interfaces described in Section 2.3.2.1 may serve this purpose, although neither Netconf nor OpenFlow currently supports asynchronous notifications. Additionally Syslog [RFC5424] is a protocol for reporting events from the network, and IPFIX [RFC5101] is designed to allow network statistics to be aggregated and reported. The OAM Handler also correlates events reported from the network and reports them onward to the ABNO Controller (which can apply the information to the recovery of services that it has provisioned) and to the NMS, OSS, and Application Service Coordinator. The reporting mechanism used here can be essentially the same as used when events are reported from the network and no new protocol is needed. 3. ABNO Use Cases This section provides a number of examples of how the ABNO architecture can be applied to provide application-driven and NMS/OSS-driven network operations. 3.1 Inter-AS Connectivity The following use case describes how the ABNO framework can be used set up an end-to-end MPLS service across multiple Autonomous Systems (ASes). Consider the simple network topology shown in Figure 2. The three ASes (ASa, ASb, and ASc) are connected at ASBRs a1, a2, b1 through b4, c1, and c2. A source node (s) located in ASa is to be connected to a destination node (d) located in ASc. The optimal path for the LSP from s to d must be computed, and then the network must be triggered to set up the LSP. +--------------+ +-----------------+ +--------------+ |ASa | | ASb | | ASc | | +--+ | | +--+ +--+ | | +--+ | | |a1|-|-|-|b1| |b3|-|-|-|c1| | | +-+ +--+ | | +--+ +--+ | | +--+ +-+ | | |s| | | | | |d| | | +-+ +--+ | | +--+ +--+ | | +--+ +-+ | | |a2|-|-|-|b2| |b4|-|-|-|c2| | | +--+ | | +--+ +--+ | | +--+ | | | | | | | +--------------+ +-----------------+ +--------------+ Figure 2: Inter-AS Domain Topology with H-PCE (Parent PCE) King & Farrel [Page 21]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 The following steps are performed to deliver the service within the ABNO architecture. 1. Request Management As shown in Figure 3, the NMS/OSS issues a request to the ABNO Controller for a path between s and d. The ABNO Controller verifies that the NMS/OSS has sufficient rights to make the service request. +---------------------+ | NMS/OSS | +----------+----------+ | V +--------+ +-----------+-------------+ | Policy +-->-+ ABNO Controller | | Agent | | | +--------+ +-------------------------+ Figure 3: ABNO Request Management 2. Service Path Computation with Hierarchical PCE The ABNO Controller needs to determine an end-to-end path for the LSP. Since the ASes will want to maintain a degree of confidentiality about their internal resources and topology, they will not share a TED and each will have its own PCE. In such a situation, the Hierarchical PCE (H-PCE) architecture described in [RFC6805] is applicable. As shown in Figure 4, the ABNO Controller sends a request to the parent PCE for an end-to-end path. As described in [RFC6805], the parent PCE consults its TED that shows the connectivity between ASes. This helps it understand that the end-to-end path must cross each of ASa, ASb, and ASc, so it is sends individual path computation requests to each of PCE a, b, and c to determine the best options for crossing the ASes. Each child PCE applies policy to the requests it receives to determine whether the request is to be allowed and to select the type of network resources that can be used in the computation result. For confidentiality reasons, each child PCE may supply its computation responses using a path key [RFC5520] to hide the details of the path segment it has computed. King & Farrel [Page 22]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +-----------------+ | ABNO Controller | +----+-------+----+ | A V | +--+-------+--+ +--------+ +--------+ | | | | | Policy +-->-+ Parent PCE +---+ AS TED | | Agent | | | | | +--------+ +-+----+----+-+ +--------+ / | \ / | \ +-----+-+ +---+---+ +-+-----+ | | | | | | | PCE a | | PCE b | | PCE c | | | | | | | +---+---+ +---+---+ +---+---+ | | | +--+--+ +--+--+ +--+--+ | TEDa| | TEDb| | TEDc| +-----+ +-----+ +-----+ Figure 4: Path Computation Request with Hierarchical PCE The parent PCE collates the responses from the children and applies its own policy to stitch them together into the best end- to-end path which it returns as a response to the ABNO Controller. 3. Provisioning the End-to-End LSP There are several options for how the end-to-end LSP gets provisioned in the ABNO architecture. Some of these are described below. 3a. Provisioning from the ABNO Controller With a Control Plane Figure 5 shows how the ABNO Controller makes a request through the Provisioning Manager to establish the end-to-end LSP. As described in Section 2.3.2.6 these interactions can use the Netconf protocol [RFC6241] or the extensions to PCEP described in [I-D.crabbe-pce-pce-initiated-lsp]. In either case, the provisioning request is sent to the head end Label Switching Router (LSR) and it signals in the control plane (using a protocol such as RSVP-TE [RFC3209]) so cause the LSP to be established. King & Farrel [Page 23]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +-----------------+ | ABNO Controller | +--------+--------+ | V +------+-------+ | Provisioning | | Manager | +------+-------+ | V +--------------------+------------------------+ / Network \ +-------------------------------------------------+ Figure 5: Provisioning the End-to-End LSP 3b. Provisioning through Programming Network Resources Another option is that the LSP is provisioned hop by hop from the Provisioning Manager using a mechanism such as ForCES [RFC5810] or OpenFlow [ONF] as described in Section 2.3.2.6. In this case, the picture is the same as shown in Figure 5. The interaction between the ABNO Controller and the Provisioning Manager will be PCEP or Netconf as described in option 3a., and the Provisioning Manager will have the responsibility to fan out the requests to the individual network elements. 3c. Provisioning with an Active PCE The active PCE is described in Section 2.3.1.7 based on the concepts expressed in [I-D.crabbe-pce-pce-initiated-lsp]. In this approach, the process described in 3a is modified such that the PCE issues a PCEP command to the network direct without a response being first returned to the ABNO Controller. This situation is shown in Figure 6, and could be modified so that the Provisioning Manager still programs the individual network elements as described in 3b. King & Farrel [Page 24]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +-----------------+ | ABNO Controller | +----+------------+ | V +--+----------+ +--------------+ +--------+ | | | Provisioning | | Policy +-->-+ Parent PCE +---->----+ Manager | | Agent | | | | | +--------+ +-+----+----+-+ +-----+--------+ / | \ | / | \ | +-----+-+ +---+---+ +-+-----+ V | | | | | | | | PCE a | | PCE b | | PCE c | | | | | | | | | +-------+ +-------+ +-------+ | | +--------------------------------+------------+ / Network \ +-------------------------------------------------+ Figure 6: LSP Provisioning with an Active PCE 3d. Provisioning with Active Child PCEs and Segment Stitching A mixture of the approaches described in 3b and 3c can result in a combination of mechanisms to program the network to provide the end-to-end LSP. Figure 7 shows how each child PCE can be an active PCE responsible for setting up an edge-to- edge LSP segment across one of the ASes. The ABNO Controller then uses the Provisioning Manager to program the inter-AS connections using ForCES or OpenFlow and the LSP segments are stitched together following the ideas described in [RFC5150]. King & Farrel [Page 25]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +-----------------+ | ABNO Controller +-------->--------+ +----+-------+----+ | | A | V | | +--+-------+--+ | +--------+ | | | | Policy +-->-+ Parent PCE | | | Agent | | | | +--------+ ++-----+-----++ | / | \ | / | \ | +---+-+ +--+--+ +-+---+ | | | | | | | | |PCE a| |PCE b| |PCE c| | | | | | | | V +--+--+ +--+--+ +---+-+ | | | | | V V V | +----------+-+ +------------+ +-+----------+ | |Provisioning| |Provisioning| |Provisioning| | |Manager | |Manager | |Manager | | +-+----------+ +-----+------+ +-----+------+ | | | | | V V V | +--+-----+ +----+---+ +--+-----+ | / AS a \=====/ AS b \=====/ AS c \ | +------------+ A +------------+ A +------------+ | | | | +-----+----------------+-----+ | | Provisioning Manager +----<-------+ +----------------------------+ Figure 7: LSP Provisioning With Active Child PCEs and Stitching 4. Verification of Service The ABNO Controller will need to ascertain that the end-to-end LSP has been set up as requested. In the case of a control plane being used to establish the LSP, the head end LSR may send a notification (perhaps using PCEP) to report successful setup, but to be sure that the LSP is up, the ABNO Controller will request the OAM Handler to perform Continuity Check OAM in the Data Plane and report back that the LSP is ready to carry traffic. King & Farrel [Page 26]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 5. Notification of Service Fulfillment Finally, when the ABNO Controller is satisfied that the requested service is ready to carry traffic, it will notify the NMS/OSS. The delivery of the service may be further checked through auditing the network as described in 2.3.2.7. 3.2 Multi-Layer Networking Networks are typically constructed using multiple layers. These layers represent separations of administrative regions or of technologies, and may also represent a distinction between client and server networking roles. It is preferable to coordinate network resource control and utilization (i.e., consideration and control of multiple layers), rather than controlling and optimizing resources at each layer independently. This facilitates network efficiency and network automation, and may be defined as inter-layer traffic engineering. The PCE architecture supports inter-layer traffic engineering [RFC5623] and, in combination with the ABNO architecture, provides a suite of capabilities for network resource coordination across multiple layers. The following use case demonstrates ABNO used to coordinate allocation of server-layer network resources to create virtual topology in a client-layer network in order to satisfy a request for end-to-end client-layer connectivity. Consider the simple multi- layer network in Figure 8. There are six packet layer routers (P1 through P6) and three optical layer lambda switches (L1 through L3). There is connectivity in the packet layer between routers P1, P2, and P3, and also between routers P4, P5, and P6, but there is no packet- layer connectivity between these two islands of routers perhaps because of a network failure or perhaps because all existing bandwidth between the islands has already been used up. However, there is connectivity in the optical layer between switches L1, L2, and L3, and the optical network is connected out to routers P3 and P4 (they have optical line cards). In this example, a packet layer connection (an MPLS LSP) is desired between P1 and P6. King & Farrel [Page 27]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +--+ +--+ +--+ +--+ +--+ +--+ |P1|---|P2|---|P3| |P4|---|P5|---|P6| +--+ +--+ +--+ +--+ +--+ +--+ \ / \ / +--+ +--+ +--+ |L1|--|L2|--|L3| +--+ +--+ +--+ Figure 8: A Multi-Layer Network In the ABNO architecture, the following steps are performed to deliver the service. 1. Request Management As shown in Figure 9, the Application Service Coordinator issues a request for connectivity from P1 to P6 in the packet layer network. That is, the Application Service Coordinator requests an MPLS LSP with a specific bandwidth to carry traffic for its application. The ABNO Controller verifies that the Application Service Coordinator has sufficient rights to make the service request. +---------------------------+ | Application Service | | Coordinator | +-------------+-------------+ | V +------+ +------------+------------+ |Policy+->-+ ABNO Controller | |Agent | | | +------+ +-------------------------+ Figure 9: Application Service Coordinator Request Management 2. Service Path Computation in the Packet Layer The ABNO Controller sends a path computation request to the packet layer PCE to compute a suitable path for the requested LSP as shown in Figure 10. The PCE uses the appropriate policy for the request and consults the TED for the packet layer. It determines that no path is immediately available. King & Farrel [Page 28]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +-----------------+ | ABNO Controller | +----+------------+ | V +--------+ +--+-----------+ +--------+ | Policy +-->--+ Packet Layer +---+ Packet | | Agent | | PCE | | TED | +--------+ +--------------+ +--------+ Figure 10: Path Computation Request 3. Invocation of VNTM and Path Computation in the Optical Layer After the path computation failure in step 2, instead of notifying ABNO Controller of the failure, the PCE invokes the VNTM to see whether it can create the necessary link in the virtual network topology to bridge the gap. As shown in Figure 11, the packet layer PCE reports the connectivity problem to the VNTM, and the VNTM consults policy to determine what it is allowed to do in this case. Assuming that the policy allows it, VNTM asks the optical layer PCE to see whether it can find a path across the optical network that could be provisioned to provide a virtual link for the packet layer. In addressing this request, the optical layer PCE consults a TED for the optical layer network. +------+ +--------+ | | +--------------+ | Policy +-->--+ VNTM +--<--+ Packet Layer | | Agent | | | | PCE | +--------+ +---+--+ +--------------+ | V +---------------+ +---------+ | Optical Layer +---+ Optical | | PCE | | TED | +---------------+ +---------+ Figure 11: Invocation of VNTM and Optical Layer Path Computation 4. Provisioning in the Optical Layer Once a path has been found across the optical layer network it needs to be provisioned. The options follow those in step 3 of King & Farrel [Page 29]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 Section 3.1. That is, provisioning can be initiated by the optical layer PCE or by its user, the VNTM. The command can be sent to the head end of the optical LSP (P3) so that the control plane (for example, GMPLS [RFC3473]) can be used to provision the LSP. Alternatively, the network resources can be provisioned direct using any of the mechanisms described in Section 2.3.2.6. 5. Creation of Virtual Topology in the Packet Layer Once the LSP has been set up in the optical layer it can be made available in the packet layer as a virtual link. If the GMPLS signaling used the mechanisms described in [RFC6107] this process can be automated within the control plane, otherwise it may require a specific instruction to the head end router of the optical LSP (for example, through the Interface to the Routing System). Once the virtual link is created as shown in Figure 12, it is advertised in the IGP for the packet layer network and the link will appear in the TED for the packet layer network. +--------+ | Packet | | TED | +------+-+ A | +--+ +--+ |P3|....................|P4| +--+ +--+ \ / \ / +--+ +--+ +--+ |L1|--|L2|--|L3| +--+ +--+ +--+ Figure 12: Advertisement of a New Virtual Link 6. Path Computation Completion and Provisioning in the Packet Layer Now there are sufficient resources in the packet layer network. The PCE for the packet layer can complete its work and the MPLS LSP can be provisioned as described in Section 3.1. 7. Verification and Notification of Service Fulfillment As discussed in Section 3.1, the ABNO Controller will need to King & Farrel [Page 30]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 verify that the end-to-end LSP has been correctly established before reporting service fulfillment to the Application Service Coordinator. Furthermore, it is highly likely that service verification will be necessary before the optical layer LSP can be put into service as a virtual link. Thus, the VNTM will need to coordinate with the OAM Handler to ensure that the LSP is ready for use. 3.2.1 Data Center (DC) Interconnection across MLNs In order to support new and emerging cloud-based applications, such as real-time data backup, virtual machine migration, server clustering or load reorganization, the dynamic provisioning and allocation of IT resources and the interconnection of multiple, remote Data Centers (DC) is a growing requirement. These operations require traffic being delivered between data centers, and, typically, the connections providing such inter-DC connectivity are provisioned using static circuits or dedicated leased lines, leading to an inefficiency in terms of resource utilization. Moreover, a basic requirement is that such a group of remote DCs an be operated logically as one. In such environments, the data plane technology is operator and provider dependent. Their customers may rent LSC, PSC or TDM services, and the application and usage of the ABNO architecture and Controller enables the required dynamic end to end network service provisioning, regardless of underlying service and transport layers. Consequently, the interconnection of remote DCs may involve the operation, control and management of heterogeneous environments, namely, each DC site and the metro-core network segment used to interconnect them, with regard to not only the underlying data plane technology, but also the control plane. For example, each DC site or domain could be controlled locally in a centralized way (e.g. via OpenFlow [ONF]), whereas the metro-core transport infrastructure is controlled by GMPLS. Although OpenFlow is specially adapted to single domain intra-data center networks (packet level control, lots of routing exceptions), a standardized GMPLS based architecture would enable dynamic optical resources allocation and restoration in multi- domain (e.g., multi-vendor) core networks interconnecting distributed data centers. The application of an ABNO architecture and related procedures would involve the following aspects: King & Farrel [Page 31]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 1. Request Application Service Coordinator or NMS The ABNO Controller receives a request from the Application Service Coordinator or from the NMS, in order to create a new end-to-end connection between two end points. the actual addressing of these end points is discussed in the next section. The ABNO Controller asks the PCE for a path between these two endpoints, after considering any applicable policy as defined by the Policy Agent (see Figure 1). +---------------------------+ | Application Service | | Coordinator or NMS | +-------------+-------------+ | V +------+ +------------+------------+ |Policy+->-+ ABNO Controller | |Agent | | | +------+ +-------------------------+ Figure 14: Application Service Coordinator Request Management 2. Cross-Stratum Addressing Mapping In order to compute an end to end path, the PCE needs to have a unified view of the overall topology, which means that it has to consider and identify the actual endpoints with regard to the client network addresses. The ABNO Controller and/or the PCE may need to translate or map addresses from different address spaces. Depending on how the topological information is disseminated and gathered, there are two possible scenarios: a. The Application Layer knows Client Network Layer. Entities belonging to the application layer may have an interface with the TED or with an ALTO server, allowing the mapping of the high level endpoints to network addresses. Layer may have an interface with TEDs or with ALTO server, it may know which are the client network layer addresses, where DCs are connected. This address correlation can be done via manual configuration or any other mechanism which is out of the scope of this draft. In this scenario, request from NMS or Application layer contains addresses in the client layer network. Therefore, when ABNO request to PCE for a path between these two end points, PCE can compute the path and continue the work-flow talking with the provisioning manager. b. Application Layer knows Server Network Layer. In this case, when ABNO asks PCE for a path, there is no route between two end King & Farrel [Page 32]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 points. Similarly to use case in section X.X, PCE asks to the VNTM to create a new connection between two addresses in the Server Network Layer. As VNT can access to TED information and this mapping have to exist, VNT can determine which are Client Layer addresses and continue with provisioning process. [Victor Comment] Not sure how to solve this easy statement now, I will think about it later. The mechanism to do this is ALTO. 3. Provisioning Process Once the path has been obtained, the provisioning manager receives a high level provisioning request to provision the service. Since, in the considered use case, the network elements are not necessarily configured using the same protocol, the end to end path is split into segments, and the ABNO Controller coordinates or orchestrates the establishment by adapting and/or translating the abstract provisioning request to concrete segment requests, by means of a VNTM or PCE, which issue the corresponding commands or instructions. The provisioning may involve configuring the data plane elements directly or delegating the establishment of the underlying connection to a dedicated control plane instance, responsible for that segment. The provisioning manager needs to know which technology is used for the actual provisioning at each segment, by ether manual configuration or discovery. Once the technology is selected, this configuration process can follow the steps. +-----------------+ | ABNO Controller | +-------+---------+ | | V +------+ +------+-------+ | VNTM +--<--+ PCE | +---+--+ +------+-------+ | | V V +-----+---------------+------------+ | Provisioning Manager | +----------------------------------+ | | | | | V | V | V OpenFlow V ForCes V PCEP NetConf SNMP Figure 15: Provisioning Process King & Farrel [Page 33]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 4. Verification and Notification of Service Fulfillment Once the end-to-end connectivity service has been provisioned, and after the verification of the correct operation of the service, the ABNO Controller needs to notify the Application Service Coordinator or NMS. 3.3 Make-Before-Break A number of different services depend on the establishment of a new LSP so that traffic supported by an existing LSP can be switched without disruption. This section describes those use cases, presents a generic model for make-before-break within the ABNO architecture, and shows how each use case can be supported by using elements of the generic model. 3.3.1 Make-Before-Break for Re-optimization Make-before-break is a mechanism supported in RSVP-TE signaling where a new LSP is set up before the LSP it replaces is torn down [RFC3209]. This process has several benefits in situations such as re-optimization of in-service LSPs. The process is simple, and the example shown in Figure 16 utilizes a stateful PCE [I-D.ietf-pce-stateful-pce]to monitor the network and take re-optimization actions when necessary. In this process a service request is made to the ABNO Controller by a requester such as the OSS. The service request indicates that the LSP should be re- optimized under specific conditions according to policy. This allows the ABNO Controller to manage the sequence and prioritization of re- optimizing multiple LSPs using elements of Global Concurrent Optimization (GCO) as described in Section 3.4, and applying policies across the network so that, for instance, LSPs for delay-sensitive services are re-optimized first. The ABNO Controller commissions the PCE to compute and set up the initial path. Over time, the PCE monitors the changes in the network as reflected in the TED, and according to the configured policy may compute and set up a replacement path, using make-before-break within the network. Once the new path has been set up and the Network reports that it is in use correctly, PCE tears down the old path and may report the re-optimization event to the ABNO Controller. King & Farrel [Page 34]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +---------------------------------------------+ | OSS / NMS / Application Service Coordinator | +----------------------+----------------------+ | +------------+------------+ | ABNO Controller | +------------+------------+ | +------+ +-------+-------+ +-----+ |Policy+-----+ PCE +-----+ TED | |Agent | +-------+-------+ +-----+ +------+ | | +----------------------+----------------------+ / Network \ +-------------------------------------------------+ Figure 16: The Make-Before-Break Process 3.3.2 Make-Before-Break for Restoration Make-before-break may also be used to repair a failed LSP where there is a desire to retain resources along some of the path, and where there is the potential for other LSPs to "steal" the resources if the failed LSP is torn down first. Unlike the example in Section 3.3.1, this case is service-interrupting, but that arises from the break in service introduced by the network failure. Obviously, in the case of a point-to-multipoint LSP, the failure might only affect part of the tree and the disruption will only be to a subset of the destination leafs so that a make-before-break restoration approach will not cause disruption to the leafs that were not affected by the original failure. Figure 17 shows the components that interact for this use case. A service request is made to the ABNO Controller by a requester such as the OSS. The service request indicates that the LSP may be restored after failure and should attempt to reuse as much of the original path as possible. The ABNO Controller commissions the PCE to compute and set up the initial path. The ABNO Controller also requests the OAM Handler to initiate OAM on the LSP and to monitor the results. At some point the network reports a fault to the OAM Handler which notifies the ABNO Controller. King & Farrel [Page 35]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 The ABNO Controller commissions the PCE to compute a new path, re- using as much of the original path as possible, and PCE sets up the new LSP. Once the new path has been set up and the Network reports that it is in use correctly, the ABNO Controller instructs the PCE to tear down the old path. +---------------------------------------------+ | OSS / NMS / Application Service Coordinator | +----------------------+----------------------+ | +------------+------------+ +-------+ | ABNO Controller +---+ OAM | +------------+------------+ |Handler| | +---+---+ +-------+-------+ | | PCE | | +-------+-------+ | | | +----------------------+--------------------+-+ / Network \ +-------------------------------------------------+ Figure 17: The Make-Before-Break Restoration Process 3.3.3 Make-Before-Break for Path Test and Selection In a more complicated use case, an LSP may be monitored for a number of attributes such as delay and jitter. When the LSP falls below a threshold, the traffic may be moved to another LSP that offers the desired (or at least a better) quality of service. To achieve this, it is necessary to establish the new LSP and test it, and because the traffic must not be interrupted, make-before-break must be used. Moreover, it may be the case that no new LSP can provide the desired attributes, and that a number of LSPs need to be tested so that the best can be selected. Furthermore, even when the original LSP is set up, it could be desirable to test a number of LSPs before deciding which should be used to carry the traffic. Figure 18 shows the components that interact for this use case. Because multiple LSPs might exist at once, a distinct action is needed to coordinate which one carries the traffic, and this is the job of the I2RS Client acting under the control of the ABNO King & Farrel [Page 36]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 Controller. The OAM Handler is responsible for initiating tests on the LSPs and for reporting the results back to the ABNO Controller. The OAM Handler can also check end-to-end connectivity test results across a multi-domain network even when each domain runs a different technology. For example, an end-to-end might be achieved by stitching together an MPLS segment, an Ethernet/VLAN segment, and an IP etc. Otherwise, the process is similar to that for re-optimization discussed in Section 3.3.1. +---------------------------------------------+ | OSS / NMS / Application Service Coordinator | +----------------------+----------------------+ | +------+ +------------+------------+ +-------+ |Policy+---+ ABNO Controller +----+ OAM | |Agent | | +--+ |Handler| +------+ +------------+------------+ | +---+---+ | | | +-------+-------+ +--+---+ | | PCE | | I2RS | | +-------+-------+ |Client| | | +--+---+ | | | | +-----------------------+---------------+-----+-+ / Network \ +---------------------------------------------------+ Figure 18: The Make-Before-Break Path Test and Selection Process The pseudo-code that follows gives an indication of the interactions between ABNO components. OSS requests quality-assured service :Label1 DoWhile not enough LSPs (ABNO Controller) Instruct PCE to compute and provision the LSP (ABNO Controller) Create the LSP (PCE) EndDo :Label2 King & Farrel [Page 37]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 DoFor each LSP (ABNO Controller) Test LSP (OAM Handler) Report results to ABNO Controller (OAM Handler) EndDo Evaluate results of all tests (ABNO Controller) Select preferred LSP and instruct I2RS client (ABNO Controller) Put traffic on preferred LSP (I2RS Client) DoWhile too many LSPs (ABNO Controller) Instruct PCE to tear down unwanted LSP (ABNO Controller) Tear down unwanted LSP (PCE) EndDo DoUntil trigger (OAM controller, ABNO Controller, Policy Agent) keep sending traffic (Network) Test LSP (OAM Handler) Endif EndDo If there is already a suitable LSP (ABNO Controller) GoTo Label2 Else GoTo Label1 EndIf 3.4 Global Concurrent Optimization Global Concurrent Optimization (GCO) is defined in [RFC5557] and represents a key technology for maximizing network efficiency by computing a set of traffic engineered paths concurrently. A GCO path computation request will simultaneously consider the entire topology of the network, and the complete set of new LSPs together with their respective constraints. Similarly, GCO may be applied to recompute the paths of a set of existing LSPs. GCO may be requested in a number of scenarios. These include: o Routing of new services where the PCE should consider other services or network topology. o A reoptimization of existing services due to fragmented network resources or sub-optimized placement of sequentially computed services. o Recovery of connectivity for bulk services in the event of a catastrophic network failure. King & Farrel [Page 38]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 A service provider may also want to compute and deploy new bulk services based on a predicted traffic matrix. The GCO functionality and capability to perform concurrent computation provides a significant network optimization advantage, thus utilizing network resources optimally and avoiding blocking. The following use case shows how the ABNO architecture and components are used to achieve concurrent optimization across a set of services. 3.4.1 Use Case: GCO with MPLS LSPs When considering the GCO path computation problem, we can split the GCO objective functions into three optimization categories, these are: o Minimize aggregate Bandwidth Consumption (MBC). o Minimize the load of the Most Loaded Link (MLL). o Minimize Cumulative Cost of a set of paths (MCC). This use case assumes the GCO request will be offline and be initiated from an NMS/OSS, that is it may take significant time to compute the service, and the paths reported in the response may want to be verified by the user before being provisioned within the network. 1. Request Management The NMS/OSS issues a request for new service connectivity for bulk services. The ABNO Controller verifies that the NMS/OSS has sufficient rights to make the service request and apply a GCO attribute with a request to Minimize aggregate Bandwidth Consumption (MBC). +---------------------+ | NMS/OSS | +----------+----------+ | V +--------+ +-----------+-------------+ | Policy +-->-+ ABNO Controller | | Agent | | | +--------+ +-------------------------+ Figure 19: NMS Request to ABNO Controller King & Farrel [Page 39]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 1a. Each service request has a source, destination and bandwidth request. These service requests are sent to the ABNO Controller and categorized as a GCO. The PCE uses the appropriate policy for the request and consults the TED for the packet layer. 2. Service Path Computation in the Packet Layer To compute a set of services for the GCO application, PCEP supports synchronization vector (SVEC) lists for synchronized dependent path computations as defined in [RFC5440] and described in [RFC6007]. 2a. The ABNO Controller sends the bulk service request to the GCO-capable packet layer PCE using PCEP messaging. The PCE uses the appropriate policy for the request and consults the TED for the packet layer. +-----------------+ | ABNO Controller | +----+------------+ | V +--------+ +--+-----------+ +--------+ | | | | | | | Policy +-->--+ GCO-capable +---+ Packet | | Agent | | Packet Layer | | TED | | | | PCE | | | +--------+ +--------------+ +--------+ Figure 20: Path Computation Request from GCO-capable PCE 2b. Upon receipt of the bulk (GCO) service requests, the PCE applies the MBC objective function and computes the services concurrently. 2c. Once the requested GCO service path computation completes, the PCE sends the resulting paths back to the ABNO Controller as a PCEP response. The response includes a fully computed explicit path for each service (TE LSP). King & Farrel [Page 40]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +---------------------+ | NMS/OSS | +----------+----------+ ^ | +----------+----------+ | ABNO Controller | | | +---------------------+ Figure 21: ABNO Sends Solution to the NMS/OSS 3. The concurrently computed solution received from the PCE is sent back to the NMS/OSS by the ABNO Controller. The NMS/OSS user can then check the candidate paths and either provision the new services, or save the solution for deployment in the future. 3.5 Adaptive Network Management (ANM) The ABNO architecture provides the capability for reactive network control of resources based on classification, profiling and prediction based on current demands and resource utilization. Server-layer transport network resources, such as Optical Transport Network (OTN) time-slicing [G.709], or the fine granularity grid of wavelengths with variable spectral bandwidth (flexi-grid) [G.694.1], can be manipulated to meet current and projected demands in a model called Elastic Optical Networks (EON). EON provides spectrum-efficient and scalable transport by introducing flexible granular grooming in the optical frequency domain. This is achieved using arbitrary contiguous concatenation of optical spectrum that allows creation of custom- sized bandwidth. This bandwidth is defined in slots of 12,5GHz. Adaptive Network Management (ANM) with EON allows appropriately- sized optical bandwidth to be allocated to an end-to-end optical path. In flexi-grid, the allocation is performed according to the traffic volume or following user requests, and can be achieved in a highly spectrum-efficient and scalable manner. Similarly, OTN provides an adaptive and elastic provisioning of bandwidth on top of wavelength switched optical networks (WSON). To efficiently use optical resources, a system is required which can monitor network resources, and decide the optimal network configuration based on the status, bandwidth availability and user service. We call this ANM. King & Farrel [Page 41]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 3.5.1. ANM Trigger There are different reasons to trigger an adaptive network management process, these include: o Measurement: traffic measurements can be used in order to cause spectrum allocations that fit the traffic needs as efficiently as possible. This function may be influenced by measuring the IP router traffic flows, by examining traffic engineering or link state databases, by usage thresholds for critical links in the network, or by requests from external entities. Nowadays, network operators have active monitoring probes in the network, which store their results in the OSS. The OSS or OAM Handler components activate this measurement-based trigger, so the ABNO Controller would not be directly involved in this case. o Human: operators may request ABNO to run an adaptive network planning process via a NMS. o Periodic: adaptive network planning process can be run periodically to find an optimum configuration. An ABNO Controller would receive a request from OSS or NMS to run an adaptive network manager process. 3.5.2. Processing request and GCO computation Based on the human of periodic trigger requests described in the previous Section, the OSS or NMS will send a request to the ABNO Controller to perform EON-based GCO. The ABNO Controller will select a set of services to be reoptimized and choose an objective function that will deliver the best use of network resources. In making these choices, the ABNO Controller is guided by network-wide policy on the use of resources, the definition of optimization, and the level of perturbation to existing services that is tolerable. Much as in Section 3.5, this request for GCO is passed to the PCE. The PCE could then consider the end-to-end paths and every channel's optimal spectrum assignment in order to satisfy traffic demands and optimize the optical spectrum consumption within the network. The PCE will operate on the TED, but is likely to also be stateful so that it knows which LSPs correspond to which waveband allocations on which links in the network. Once PCE arrives at an answer, it returns a set of potential paths to the ABNO Controller which passes them on to the NMS or OSS to supervise/select the subsequent path set-up/modification process. King & Farrel [Page 42]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 This exchange is shown in Figure 22. Note that the figure does not show the interactions used by the OSS/NMS for establishing or modifying LSPs in the network. +---------------------------+ | OSS or NMS | +-----------+---+-----------+ | ^ V | +------+ +----------+---+----------+ |Policy+->-+ ABNO Controller | |Agent | | | +------+ +----------+---+----------+ | ^ V | +-----+---+----+ + PCE | +--------------+ Figure 22: Adaptive Network Management with human intervention 3.5.3. Automated Provisioning Process Although most of network operations are supervised by the operator, there are some actions, which may not require supervision, like a simple modification of a modulation format in a Bit rate variable transponder (BVT) (to increase the optical spectrum efficiency or reduce energy consumption). In this processes, where human intervention is not required, PCE sends provisioning manager new configuration to configure the network elements. King & Farrel [Page 43]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 +------------------------+ | OSS or NMS | +-----------+------------+ | V +------+ +----------+------------+ |Policy+->-+ ABNO Controller | |Agent | | | +------+ +----------+------------+ | V +------+------+ + PCE | +------+------+ | V +----------------------------------+ | Provisioning Manager | +----------------------------------+ Figure 23: Adaptive Network Management without human intervention 3.6 Pseudowire Operations and Management Pseudowires in an MPLS network [RFC3985] operate as a form of layered network over the connectivity provided by the MPLS network. The pseudowires are carried by LSPs operating as transport tunnels, and planning is necessary to determine how those tunnels are placed in the network and which tunnels are used by any pseudowire. This section considers four use cases: multi-segment pseudowires, path-diverse pseudowires, path-diverse multi-segment pseudowires, and pseudowire segment protection. Section 3.6.4 describes the applicability of the ABNO architecture to these four use cases. 3.6.1 Multi-Segment Pseudowires [RFC5254] described the architecture for multi-segment pseudowires. An end-to-end service, as shown in Figure 24, can consist of a series of stitched segments shown on the figure as AC, PW1, PW2, PW3, and AC. Each pseudowire segment is stitched at a 'stitching PE' (S- PE): for example, PW1 is stitched to PW2 at S-PE1. Each access circuit (AC) is stitched to a pseudowire segment at a 'terminating PE' (T-PE): for example, PW1 is stitched to the AC at T-PE1. Each pseudowire segment is carried across the MPLS network in an LSP operating as a transport tunnel: for example, PW1 is carried in LSP1. The LSPs between PEs may traverse different MPLS networks with the King & Farrel [Page 44]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 PEs as border nodes, or the PEs may lie within the same network such such that the LSPs each only span part of the network. ----- ----- ----- ----- --- |T-PE1| LSP1 |S-PE1| LSP2 |S-PE3| LSP3 |T-PE2| +---+ | | AC | |=======| |=======| |=======| | AC | | |CE1|----|........PW1........|..PW2........|..PW3........|----|CE2| | | | |=======| |=======| |=======| | | | --- | | | | | | | | +---+ ----- ----- ----- ----- Figure 24 : Multi-Segment Pseudowire While the topology shown in Figure 24 is easy to navigate, the reality of a deployed network can be considerably more complex. The topology in Figure 25 shows a small mesh of PEs. The links between the PEs are not physical links but represent the potential of MPLS LSPs between the PEs. When establishing the end-to-end service between CE1 and CE2, some choice must be made about which PEs to use. In other words, a path computation must be made to determine the pseudowire segment 'hops', and then the necessary LSP tunnels must be established to carry the pseudowire segments that will be stitched together. Of course, each LSP may itself require a path computation decision to route it through the MPLS network between PEs. The choice of path for the multi-segment pseudowire will depend on such issues as: - MPLS connectivity - MPLS bandwidth availability - pseudowire stitching capability and capacity at PEs - policy and confidentiality considerations for use of PEs. ----- |S-PE5| /-----\ --- ----- -----/ \----- ----- --- |CE1|----|T-PE1|-------|S-PE1|-------|S-PE3|-------|T-PE2|----|CE2| --- -----\ -----\ ----- /----- --- \ | ------- | / \ ----- \----- / -----|S-PE2|-------|S-PE4|----- ----- ----- Figure 25 : Multi-Segment Pseudowire Network Topology King & Farrel [Page 45]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 3.6.2 Path-Diverse Pseudowires The connectivity service provided by a pseudowire may need to be resilient to failure. In many cases, this function is provided by provisioning a pair of pseudowires carried by path-diverse LSPs across the network as shown in Figure 26 (the terminology is inherited directly from [RFC3985]). Clearly, in this case, the challenge is to keep the two LSPs (LSP1 and LSP2) disjoint within the MPLS network. This problem is not different from the normal MPLS path-diversity problem. ------- ------- | PE1 | LSP1 | PE2 | AC | |=======================| | AC ----...................PW1...................---- --- - / | |=======================| | \ ----- | |/ | | | | \| | | CE1 + | | MPLS Network | | + CE2 | | |\ | | | | /| | --- - \ | |=======================| | / ----- ----...................PW2...................---- AC | |=======================| | AC | | LSP2 | | ------- ------- Figure 26 : Path-Diverse Pseudowires The path-diverse pseudowire is developed in Figure 27 by the "dual- homing" of each CE through more than one PE. The requirement for LSP path diversity is exactly the same, but it is complicated by the LSPs having distinct end points. In this case, the head-end router (e.g., PE1) cannot be relied upon to maintain the path diversity through the signaling protocol because it is aware of the path of the only one of the LSPs. Thus some form of coordinated path computation approach is needed. King & Farrel [Page 46]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 ------- ------- | PE1 | LSP1 | PE2 | AC | |=======================| | AC ---...................PW1...................--- / | |=======================| | \ ----- / | | | | \ ----- | |/ ------- ------- \| | | CE1 + MPLS Network + CE2 | | |\ ------- ------- /| | ----- \ | PE3 | | PE4 | / ----- \ | |=======================| | / ---...................PW2...................--- AC | |=======================| | AC | | LSP2 | | ------- ------- Figure 27 : Path-Diverse Pseudowires With Disjoint PEs 3.6.3 Path-Diverse Multi-Segment Pseudowires Figure 28 shows how the services in the previous two sections may be combined to offer end-to-end diverse paths in a multi-segment environment. To offer end-to-end resilience to failure, two entirely diverse, end-to-end multi-segment pseudowires may be needed. ----- ----- |S-PE5|--------------|T-PE4| /-----\ ----- \ ----- -----/ \----- ----- \ --- |T-PE1|-------|S-PE1|-------|S-PE3|-------|T-PE2|--|CE2| --- / -----\ -----\ ----- /----- --- |CE1|< ------- | ------- | / --- \ ----- \----- \----- / |T-PE3|-------|S-PE2|-------|S-PE4|----- ----- ----- ----- Figure 28 : Path-Diverse Multi-Segment Pseudowire Network Topology Just as in any diverse-path computation, the selection of the first path needs to be made with awareness of the fact that a second, fully-diverse path is also needed. If a sequential computation was applied to the topology in Figure 28, the first path CE1,T-PE1,S-PE1, S-PE3,T-PE2,CE2 would make it impossible to find a second path that was fully diverse from the first. But the problem is complicated by the multi-layer nature of the network. It is not enough that the PEs are chosen to diverse because the LSP tunnels between them might share links within the MPLS King & Farrel [Page 47]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 network. Thus, a multi-layer planning solution is needed to achieve the desired level of service. 3.6.4 Pseudowire Segment Protection An alternative to the end-to-end pseudowire protection service described in Section 3.6.3 can be achieved by protecting individual pseudowire segments or PEs. For example, in Figure 28, the pseudowire between S-PE1 and S-PE5 may be protected by a pair of stitched segments running between S-PE1 and S-PE5, and between S-PE5 and S-PE3. This is shown in detail in Figure 29. ------- ------- ------- | S-PE1 | LSP1 | S-PE5 | LSP3 | S-PE3 | | |============| |============| | | .........PW1..................PW3.......... | Outgoing Incoming | : |============| |============| : | segment segment | : | ------- | :.......... ...........: | | : | | : | | : | | : |=================================| : | | .........PW2............................... | | |=================================| | | | LSP2 | | ------- ------- Figure 29 : Fragment of a Segment-Protected Multi-Segment Pseudowire The determination of pseudowire protection segments requires coordination and planning, and just as in Section 3.6.5, this planning must be cognizant of the paths taken by LSPs through the underlying MPLS networks. 3.6.5 Applicability of ABNO to Pseudowires The ABNO architecture lends itself well to the planning and control pseudowires in the use cases described above. The user or application needs a single point at which it requests services: the ABNO Controller. The ANBO Controller can ask a PCE to draw on the topology of pseudowire stiching-capable PEs as well as additional information regarding PE capabilities, such as load on PEs and administrative policies, and the PCE can use a series of TEDs or other PCEs for the underlying MPLS networks to determine the paths of the LSP tunnels. Then a number of different provisioning systems can be used to instantiate the LSPs and provision the pseudowires under the control of the Provisioning Manager. The ABNO Controller will use the I2RS Client to instruct the network devices about what King & Farrel [Page 48]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 traffic should be placed on which pseudowires, and in conjunction with the OAM Handler can ensure that failure events are handled correctly, that service quality levels are appropriate, and that service protection levels are maintained. 3.7 Other Potential Use Cases This section serves as a place-holder for other potential use cases that might get documented in a future revision of this document. 3.7.1 Grooming and Regrooming This use case could cover the following scenarios: - Nested LSPs - Packet Classification (IP flows into LSPs at edge routers) - Bucket Stuffing - IP Flows into ECMP Hash Bucket 3.7.2 Bandwidth Scheduling Bandwidth Scheduling consist of configuring LSPs based on a given time schedule. This can be used to support maintenance or operational schedules or to adjust network capacity based on traffic pattern detection. The ABNO framework provides the components to enable bandwidth scheduling solutions. 3.7.3 ALTO Server A use case describing the ALTO server is needed.] 4. Survivability and Redundancy within the ABNO Architecture [Editor's note: this section to be written with consideration of how the ABNO system survives the failure of individual components.] 5. Security Consideration [Editor's note: this section to be written.] 6. Manageability Considerations [Editor's note: this section to be written.] King & Farrel [Page 49]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 7. IANA Considerations This document makes no requests for IANA action. 8. Acknowledgements Thanks for discussions and review are due to Ken Gray, Jan Medved, Nitin Bahadur, Diego Caviglia, Joel Halpern, Brian Field, Ori Gerstel, Daniele Ceccarelli, Diego Caviglia Cyril Margaria, and Jonathan Hardwick. This work was supported in part by the FP-7 IDEALIST project under grant agreement number 317999. 9. References 9.1. Informative References [I-D.atlas-i2rs-architecture] Ward, D., Halpern, J., and S. Hares, An Architecture for the Interface to the Routing System", draft-atlas-i2rs-architecture, work in progress. [I-D.atlas-i2rs-problem-statement] Atlas, A., Nadeau, T., and D. Ward, "Interface to the Routing System Problem Statement", draft-atlas-i2rs-problem-statement, work in progress. [I-D.boucadair-connectivity-provisioning-profile] Boucadair, M., Jacquenet, c., and N. Wang, "IP/MPLS Connectivity Provisioning Profile", draft-boucadair-connectivity-provisioning-profile, work in progress. [I-D.crabbe-pce-pce-initiated-lsp] Crabbe, E., Minei, I., Sivabalan, S., and Varga, R., "PCEP Extensions for PCE-initiated LSP Setup in a Stateful PCE Model", draft-crabbe-pce-pce-initiated-lsp, work in progress. [I-D.ietf-alto-protocol] Alimi, R., Penno, R., and Yang, Y., "ALTO Protocol", draft-ietf-alto-protocol, work in progress. King & Farrel [Page 50]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 [I-D.ietf-idr-ls-distribution] Gredler, H., Medved, J., Previdi, S., Farrel, A., and Ray, S., "North-Bound Distribution of Link-State and TE Information using BGP", draft-ietf-idr-ls-distribution, work in progress. [I-D.ietf-netmod-routing-cfg] Lhotka, L., "A YANG Data Model for Routing Management", draft-ietf-netmod-routing-cfg, work in progress. [I-D.ietf-pce-stateful-pce] Crabbe, E., Medved, J., Minei, I., and R. Varga, "PCEP Extensions for Stateful PCE", draft-ietf-pce-stateful-pce, work in progress. [ONF] Open Networking Foundation, "OpenFlow Switch Specification Version 1.1.0 Implemented (Wire Protocol 0x02)", February 2011. [RFC2748] Durham, D., Ed., Boyle, J., Cohen, R., Herzog, S., Rajan, R., and A. Sastry, "The COPS (Common Open Policy Service) Protocol", RFC 2748, January 2000. [RFC2753] Yavatkar, R., Pendarakis, D. and R. Guerin, "A Framework for Policy-based Admission Control", RFC2753, January 2000. [RFC3209] D. Awduche et al., "RSVP-TE: Extensions to RSVP for LSP Tunnels", RFC 3209, December 2001. [RFC3292] Doria, A., Hellstrand, F., Sundell, K., and Worster, T., "General Switch Management Protocol (GSMP) V3", RFC 3292, June 2002. [RFC3412] Case, J., Harrington, D., Preshun, R., and Wijnen, B., "Message Processing and Dispatching for the Simple Network Management Protocol (SNMP)", RFC 3412, December 2002. [RFC3473] L. Berger et al., "Generalized Multi-Protocol Label Switching (GMPLS) Signaling Resource ReserVation Protocol- Traffic Engineering (RSVP-TE) Extensions", RFC 3473, January 2003. [RFC3630] Katz, D., Kmpella, K., and Yeung, D., "Traffic Engineering (TE) Extensions to OSPF Version 2", RFC 3630, September 2003. King & Farrel [Page 51]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 [RFC3746] Yang, L., Dantu, R., Anderson, T., and Gopal, R., "Forwarding and Control Element Separation (ForCES) Framework", RFC 3746, April 2004. [RFC3985] Bryant, S., Ed., and P. Pate, Ed., "Pseudo Wire Emulation Edge-to-Edge (PWE3) Architecture", RFC 3985, March 2005. [RFC4655] Farrel, A., Vasseur, J.-P., and Ash, J., "A Path Computation Element (PCE)-Based Architecture", RFC 4655, August 2006. [RFC5101] B. Claise, "Specification of the IP Flow Information Export (IPFIX) Protocol for the Exchange of IP Traffic Flow Information", RFC 5101, January 2008. [RFC5150] Ayyangar, A., Kompella, K., Vasseur, JP. and Farrel, A., "Label Switched Path Stitching with Generalized Multiprotocol Label Switching Traffic Engineering (GMPLS TE)", RFC 5150, February 2008. [RFC5212] Shiomoto, K., Papadimitriou, D., Le Roux, JL., Vigoureux, M., and Brungard, D., "Requirements for GMPLS-Based Multi- Region and Multi-Layer Networks (MRN/MLN)", RFC 5212, July 2008. [RFC5254] Bitar, N., Bocci, M. and L. Martini, "Requirements for Multi-Segment Pseudowire Emulation Edge-to-Edge (PWE3)", RFC 5254, October 2008 [RFC5305] Li, T. and H. Smit, "IS-IS Extensions for Traffic Engineering", RFC 5305, October 2008. [RFC5394] Bryskin, I., Papadimitriou, D., Berger, L. and Ash, J., "Policy-Enabled Path Computation Framework", RFC 5394, December 2008. [RFC5424] R. Gerhards, "The Syslog Protocol", RFC 5424, March 2009. [RFC5440] Vasseur, JP. and Le Roux, JL., "Path Computation Element (PCE) Communication Protocol (PCEP)", RFC 5440, March 2009. [RFC5520] Bradford, R., Vasseur, JP., and Farrel, A., "Preserving Topology Confidentiality in Inter-Domain Path Computation Using a Path-Key-Based Mechanism", RC 5520, April 2009. King & Farrel [Page 52]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 [RFC5557] Lee, Y., Le Roux, JL., King, D., and Oki, E., "Path Computation Element Communication Protocol (PCEP) Requirements and Protocol Extensions in Support of Global Concurrent Optimization", RFC 5557, July 2009. [RFC5623] Oki, E., Takeda, T., Le Roux, JL., and Farrel, A., "Framework for PCE-Based Inter-Layer MPLS and GMPLS Traffic Engineering", RFC 5623, September 2009. [RFC5693] Seedorf, J., and Burger, E., "Application-Layer Traffic Optimization (ALTO) Problem Statement", RFC 5693, October 2009. [RFC5810] A. Doria, et al., "Forwarding and Control Element Separation (ForCES) Protocol Specification", RFC 5810, March 2010. [RFC6007] I. Nishioka. and D. King., "Use of the Synchronization VECtor (SVEC) List for Synchronized Dependent Path Computations", RFC 6007, September 2010. [RFC6020] Bjorklund, M., "YANG - A Data Modeling Language for the Network Configuration Protocol (NETCONF)", RFC 6020, October 2010. [RFC6107] Shiomoto, K. and A. Farrel, "Procedures for Dynamically Signaled Hierarchical Label Switched Paths", RFC 6107, February 2011. [RFC6120] P. Saint-Andre, "Extensible Messaging and Presence Protocol (XMPP): Core", RFC 6120, March 2011. [RFC6241] Enns, R., Bjorklund, M., Schoenwaelder, J., and Bierman, A., "Network Configuration Protocol (NETCONF)", RFC 6241, June 2011. [RFC6707] Niven-Jenkins, B., Le Faucheur, F., and Bitar, N., "Content Distribution Network Interconnection (CDNI) Problem Statement", RFC 6707, September 2012. [RFC6805] King, D. and Farrel, A., "The Application of the Path Computation Element Architecture to the Determination of a Sequence of Domains in MPLS and GMPLS", RFC 6805, November 2012. [TL1] Telcorida, "Operations Application Messages - Language For Operations Application", GR-831, November 1996. King & Farrel [Page 53]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 [G.694.2] ITU-T Recommendation G.694.2, "Spectral grids for WDM applications: CWDM wavelength grid", December 2003. [G.709] ITU-T, "Interface for the Optical Transport Network (OTN)", G.709 Recommendation, October 2009. 10. Contributors' Addresses Quintin Zhao Huawei Technology 125 Nagog Technology Park Acton, MA 01719 US Email: qzhao@huawei.com Victor Lopez Alvarez Telefonica I+D Email: vlopez@tid.es Ramon Casellas CTTC Email: ramon.casellas@cttc.es Yuji Kamite NTT Communications Corporation Email: y.kamite@ntt.com Yosuke Tanaka NTT Communications Corporation Email: yosuke.tanaka@ntt.com Ina Minei Juniper Networks ina@juniper.net 11. Authors' Addresses Daniel King Old Dog Consulting Email: daniel@olddog.co.uk Adrian Farrel Juniper Networks Email: adrian@olddog.co.uk King & Farrel [Page 54]
draft-farrkingel-pce-abno-architecture-05.txt July 2013 Appendix A. Undefined Interfaces This Appendix provides a brief list of interfaces that are not yet defined at the time of writing. Interfaces where there is a choice of existing protocols are not listed. - An interface for adding additional information to the Treaffic Engineering Database is described in Section 2.3.2.3. No protocol is currently identified for this interface, but candidates include: - The protocol developed or adopted to satisfy the requirements of I2RS [I-D.atlas-i2rs-architecture] - Netconf [RFC6241] - The protocol or protocols to be used by the Interface to the Routing System described in Section 2.3.2.8 have yet to be determined. The I2RS working group will make this decision after use cases and protocol requirements have been agreed. Various candidate protocols have been identified although none appears to be suitable without some extensions to the currently-specified protocol elements. The list of protocols supplied here is illustrative and not intended to constrain the work of the I2RS working group. The order of the list is not significant. - OpenFlow [ONF] - Netconf [RFC6241] - ForCES [RFC3746] - As described in Section 2.3.2.10, the Virtual Network Topology Manager needs an interface that can be used by a PCE or the ABNO Controller to inform it that a client layer needs more virtual topology. It is possible that the protocol identified for use with I2RS will satisfy this requirement. - The north-bound interface from the ABNO Controller is used by the NMS, OSS, and Application Service Coordinator to request services in the network in support of applications as described in Section 2.3.2.11. - It is possible that the protocol selected or designed to satisfy I2RS. - A potential approach for this tyoe of interface is described in [I-D.boucadair-connectivity-provisioning-profile] for a simple use case. King & Farrel [Page 55]