Internet-Draft | ACTN and Network Slicing | August 2024 |
King, et al. | Expires 1 March 2025 | [Page] |
Network abstraction is a technique that can be applied to a network domain to obtain a view of potential connectivity across the network by utilizing a set of policies to select network resources.¶
Network slicing is an approach to network operations that builds on the concept of network abstraction to provide programmability, flexibility, and modularity. It may use techniques such as Software Defined Networking (SDN) and Network Function Virtualization (NFV) to create multiple logical or virtual networks, each tailored for a set of services that share the same set of requirements.¶
Abstraction and Control of Traffic Engineered Networks (ACTN) is described in RFC 8453. It defines an SDN-based architecture that relies on the concept of network and service abstraction to detach network and service control from the underlying data plane.¶
This document outlines the applicability of ACTN to network slicing in a Traffic Engineered (TE) network that utilizes IETF technologies. It also identifies the features of network slicing not currently within the scope of ACTN and indicates where ACTN might be extended.¶
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The principles of network resource separation are not new. For years, the concepts of separated overlay and logical (virtual) networking have existed, allowing multiple services to be deployed over a single physical network comprised of a single or multiple layers. However, several key aspects differentiate overlay and virtual networking from network slicing.¶
A network slice is a virtual (that is, logical) network with its own network topology and a set of network resources that are used to provide connectivity that conforms to specific Service Level Agreements (SLAs) or a set of Service Level Objectives (SLOs). The network resources used to realize a network slice belong to the network that is sliced. The resources may be assigned and dedicated to an individual slice, or they may be shared with other slices enabling different degrees of service guarantee and providing different levels of isolation between the traffic in each slice.¶
[RFC9543] provides a definition for network slicing in the context of IETF network technologies. In particular, that document defines the term "IETF Network Slice" as the generic network slice concept applied to a network that uses IETF technologies. An IETF Network Slice could span multiple technologies (such as IP, MPLS, or optical) and multiple administrative domains. The logical network that is an IETF Network Slice may be kept separate from other concurrent logical networks with independent control and management: each can be created or modified on demand. Since this document is focused entirely on IETF technologies, it uses the term "network slice" as a more concise expression. Further discussion on the topic of IETF Network Slices and details of how an IETF Network Slice service may be requested and realized as an IETF Network Slice can be found in [RFC9543].¶
Within this document, the terms "network slice", "network slice service", and "network slice controller" refer to network slicing of networks built using IETF technologies as described in [RFC9543].¶
At one end of the spectrum, a Virtual Private Wire (VPW) or a Virtual Private Network (VPN) may be used to build a network slice. In these cases, the network slices do not require the service provider to isolate network resources for the provision of the service - the service is "virtual".¶
At the other end of the spectrum, there may be a detailed description of a complex network service that will meet the needs of a set of applications with connectivity and service function requirements that may include compute resources, storage capabilities, and access to content. Such a service may be requested dynamically (that is, instantiated when an application needs it, and released when the application no longer needs it), and modified as the needs of the application change. An example of such a type of service can be provided using an enhanced VPN described in [I-D.ietf-teas-enhanced-vpn]. It is often based on Traffic Engineering (TE) constructs in the underlay network.¶
Abstraction and Control of TE Networks (ACTN) [RFC8453] is a framework that facilitates the abstraction of underlying network resources to higher-layer applications and that allows network operators to create and supply virtual networks for their customers through the abstraction of the operators' network resources.¶
ACTN is a toolset capable of delivering network slice functionality. This document outlines the application of ACTN and associated enabling technologies to provide network slicing in a network that utilizes IETF TE-based technologies. It describes how the ACTN functional components can be used to support model-driven partitioning of resources into variable-sized bandwidth units to facilitate network sharing and virtualization. Furthermore, the use of model-based interfaces to dynamically request the instantiation of virtual networks can be extended to encompass requesting and instantiation of specific service functions (which may be both physical or virtual), and to partition network resources such as compute resources, storage capability, and access to content. In Section 3, the document highlights how the ACTN approach might be extended to address the requirements of network slicing where the underlying network is TE-capable.¶
This document re-uses terminology from [RFC8453], [RFC9543] and [I-D.ietf-teas-enhanced-vpn].¶
According to Section 6.2 of [RFC9543] "Expressing Connectivity Intents", the customer expresses requirements for a particular network slice by specifying what is required rather than how the requirement is to be fulfilled. That is, the customer's view of a network slice is an abstract one expressed as a network slice service request.¶
The concept of network slicing is a key capability to serve a customer with a wide variety of different service needs expressed as SLOs/SLEs in terms of, e.g., latency, reliability, capacity, and service function-specific capabilities.¶
This section outlines the key capabilities required to realize network slicing in a TE-enabled IETF technology network.¶
Network resources can be allocated and dedicated for use by a specific network slice service, or they may be shared among multiple slice services. This allows a flexible approach that can deliver a range of services by partitioning (that is, slicing) the available network resources to make them available to meet the customer's SLA.¶
Network virtualization enables the creation of multiple virtual networks that are operationally decoupled from the underlying physical network and are run on top of it. Slicing enables the creation of virtual networks as customer services.¶
A customer may request, through their SLA, that changes to the other services delivered by the service provider do not have any negative impact on the delivery of the service. This quality is referred to as "isolation" in (Section 8 of [RFC9543]).¶
Delivery of service isolation may be achieved in the underlying network by various forms of resource partitioning ranging from dedicated allocation of resources for a specific slice, to sharing of resources with safeguards.¶
Although multiple network slices may utilize resources from a single underlying network, isolation should be understood in terms of the following three categorizations.¶
An orchestrator is used to coordinate disparate processes and resources for creating, managing, and deploying the network slicing service in a network. The following aspects of orchestration should be considered:¶
ACTN is designed to facilitate end-to-end connectivity and provides virtual connectivity services (such as virtual links and virtual networks) to the user. The ACTN framework [RFC8453] introduces three functional components and two interfaces:¶
RFC 8453 also highlights how:¶
The ACTN infrastructure resources include traffic-engineered network capabilities. The concept of traffic engineering is broad: it describes the planning and operation of networks using a method of reserving and partitioning of network resources in order to facilitate traffic delivery across a network (see [RFC9522] for more details).¶
In the context of ACTN, traffic engineered infrastructure resources may include Statistical Packet Bandwidth, which refers to using statistical methods instead of assigning fixed bandwidth. This approach allocates bandwidth based on how data is flowing and statistical multiplexing. ACTN traffic engineered network resources also consider the physical parts of the network, such as optical channels and time slots, which facilitates the best use of the network's resources by matching bandwidth with real-time traffic demands.¶
Therefore, an ACTN network may be "sliced", with each customer being given a different partial and abstracted topology view of the physical underlay network.¶
To support multiple customers, each with its own view and control of a virtual network constructed using an underlay network, a service provider needs to partition the network resources to create network slices assigned to each customer.¶
An ACTN Virtual Network (VN) is a customer view of a slice of the ACTN infrastructure resources. It is a network slice that is presented to the customer by the ACTN provider as a set of abstracted resources. See [I-D.ietf-teas-actn-vn-yang] for a detailed description of ACTN VNs and an overview of how various different types of YANG models are applicable to the ACTN framework.¶
Depending on the agreement between a customer and a provider, various VN operations are possible:¶
Section 3, "Virtual Network Primitives", in [RFC8454] describes a set of functional primitives that support these different ACTN VN operations.¶
If the service provider must manage and maintain state in the core of the network for every network slice, then this will quickly limit the number of customer services that can be supported.¶
The importance of scalability for network slices is discussed in [I-D.ietf-teas-enhanced-vpn] and further in [I-D.ietf-teas-nrp-scalability]. That work notes the importance of collecting network slices or their composite connectivity constructs into groups that require similar treatment in the network before realizing those groups in the network.¶
The same consideration applies to ACTN VNs. But fortunately, ACTN VNs may be arranged hierarchically by recursing the MDSCs so that one VN is realized over another VN. This allows the VNs presented to the customer to be aggregated before they are instantiated in the physical network.¶
The ACTN management components (CNC, MDSC, and PNC) and interfaces (CMI and MPI) are introduced in Section 3 and described in detail in [RFC8453]. The management components for network slicing are described in [RFC9543] and are known as the customer orchestration system, the IETF Network Slice Controller (NSC), and the network controller. The network slicing management components are separated by the Network Slice Service Interface and the Network Configuration Interface, modeling the architecture described in [RFC8309].¶
The mapping between network slicing management components and ACTN management components is presented visually in Figure 1 and provides a reference for understanding the material in Section 3.4 and Section 4.¶
Note 1 - The Service Orchestrator may also contain some MDSC service-related functions, as described in section 4.2 of [RFC8453].¶
Note 2 - The Service Orchestrator-to-MDSC Interface (XMI) is an interface between two MDSC functional elements encompassing different MDSC service-related functions which is not defined in [RFC8453].¶
Note 2 - The Service Orchestrator-to-MDSC Interface (XMI) is an interface between two MDSC functional elements encompassing different MDSC service-related functions which is not defined in [RFC8453]. Depending on the function being delivered, the XMI might be realised by the Layer 2 VPN Network Management YANG model [RFC9291] or the Layer 3 VPN Network Management YANG model [RFC9182].¶
The following examples build on the ACTN framework to provide control, management, and orchestration for the network slice life-cycle. These network slices utilize common physical infrastructure, and meet specific service-level requirements.¶
Three examples are shown. Each uses ACTN to achieve a different network slicing scenario. All three scenarios can be scaled up in capacity or be subject to topology changes as well as changes in customer requirements.¶
In the example shown in Figure 2, ACTN provides virtual connections between multiple customer locations (sites accessed through Customer Edge nodes - CEs). The service is requested by the customer (via CNC-A) and delivered as a Virtual Private Line (VPL) service. The characteristics of this model include the following benefits.¶
In terms of the network slicing concept defined in [RFC9543], in this example the customer requests a single network slice with two pairs of point-to-point connectivity constructs between the service demarcation points CE1 and CE3, and CE2 and CE3 with each pair comprising one connectivity construct in each direction.¶
In the example shown in Figure 3, ACTN provides VPN connectivity between two sites across three physical networks. The users of the two sites express the requirements for the VPN. The request is directed to the CNC, and the CNC interacts with the network provider's MDSC. The main characteristics of this model are as follows.¶
In terms of the network slicing concept defined in [RFC9543], in this example, the customer requests a single network slice with a pair of point-to-point connectivity constructs (one in each direction) between the service demarcation points at site A and site B. The customer is unaware that the service is delivered over multiple physical networks.¶
In the example shown in Figure 4, ACTN provides a virtual network to the customer. This virtual network is managed by the customer. The figure shows two virtual networks (Network Slice 1 and Network Slice 2) each created for different customers under the care of different CNCs. There are two physical networks controlled by separate PNCs. Network Slice 2 is built using resources from just one physical network, while Network Slice 1 is constructed using resources from both physical networks.¶
The characteristics of this model include the following.¶
The TE-service mapping model [I-D.ietf-teas-te-service-mapping-yang] creates a binding relationship across a L3VPN Service Model (L3SM) [RFC8299], L2VPN Service Model (L2SM) [RFC8466], and TE Tunnel model [I-D.ietf-teas-yang-te], via the generic ACTN Virtual Network (VN) model [I-D.ietf-teas-actn-vn-yang].¶
When necessary, it must be possible to map between a slice service request and an ACTN VN model. The ACTN VN model is a generic virtual network service model that allows customers to specify a VN that meets the customer's service objectives with various constraints, which could be included in the initial request, and how the service is delivered. Therefore, a request for a network slice service may be mapped directly to a request for a VN.¶
The TE-service mapping model [I-D.ietf-teas-te-service-mapping-yang] binds the L3SM with TE-specific parameters. This binding facilitates seamless service operation and enables visibility of the underlay TE network. The TE-service model developed in that document can also be extended to support other services, including L2SM, and the Layer 1 Connectivity Service Model (L1CSM) [I-D.ietf-ccamp-l1csm-yang] L1CSM network service models.¶
Figure 5 shows the relationship between the YANG models discussed above.¶
Work is still needed to define YANG models to help map network slice services to Traffic Engineering (TE) models. For example, [I-D.dhody-teas-ietf-network-slice-mapping] shows how the Virtual Network (VN) model and the TE Tunnel model can support network slice services.¶
Figure 6 shows the two ACTN components (MDSC and PNC) and one ACTN interface (MPI), as listed in Section 3. The figure also shows the Device Configuration Interface between the PNC and the devices in the physical network. That interface might be used to install state on every device in the network, or might instruct a "head-end" node when a control plane is used within the physical network. In the context of [RFC8309], the Device Configuration Interface uses one or more device configuration models.¶
Figure 6 also shows the Network Slice Service Interface. This interface allows a customer to make requests for delivery of the service, and it facilitates the customer modifying and monitoring the service. In the context of [RFC8309], this is a customer service interface and uses a service model.¶
When an ACTN system is used to manage the delivery of network slices, a network slice resource model is needed. This model will be used for instantiation, operation, and monitoring of network and function resource slices. The YANG model defined in [I-D.ietf-teas-ietf-network-slice-nbi-yang] provides a suitable basis for requesting, controlling, and deletion, of a Network Slice Service.¶
The ACTN VN telemetry model [I-D.ietf-teas-actn-pm-telemetry-autonomics] provides a way for a customer to define performance monitoring relevant for the VN/network slice via the NETCONF subscription mechanisms [RFC8639], [RFC8640], or using the equivalent mechanisms in RESTCONF [RFC8641], [RFC8650].¶
Key characteristics of [I-D.ietf-teas-actn-pm-telemetry-autonomics] include the following:¶
This document makes no requests for action by IANA.¶
Network slicing involves the control of network resources in order to meet the service requirements of customers. In some deployment models using ACTN, the customer may directly request a modification in the behaviour of resources owned and operated by a service provider. Such changes could significantly affect the service provider's ability to provide services to other customers. Furthermore, the resources allocated for or consumed by a customer will typically be billable by the service provider.¶
Therefore, it is crucial that the mechanisms used in any network slicing system allow for authentication of requests, security of those requests, and tracking of resource allocations.¶
It should also be noted that while the partitioning or slicing of resources is virtual, as mentioned in Section 2.3 the customers expect and require that there is no risk of data leakage from one slice to another, and no transfer of knowledge of the structure or even existence of other slices. Further, in some service requests, there is an expectation that changes to one slice (under the control of one customer) should not have detrimental effects on the operation of other slices (whether under control of different or the same customers) even within limits allowed within the SLA. Thus, slices are assumed to be private and to provide the appearance of genuine physical connectivity.¶
Some service provider's may offer secure network slices as a service. Such services may claim to include edge-to-edge encryption for the customer's traffic. However, a customer should take full responsibility for the privacy and integrity of their traffic and should carefully consider using their own edge-to-edge encryption.¶
Further security considerations and recommendations may be found in Section 9 of [RFC8453] and Section 10 of [RFC9543], with the latter document providing additional privacy considerations in Section 11.¶
ACTN operates using the NETCONF [RFC6241] or RESTCONF [RFC8040] protocols and assumes the security characteristics of those protocols. Deployment models for ACTN should fully explore the authentication and other security aspects before networks start to carry live traffic.¶
Thanks to Italo Busi, Qin Wu, Andy Jones, Ramon Casellas, Gert Grammel, Joe Clarke, Peter Yee, Alvaro Retana, Éric Vyncke, Linda Dunbar and Kiran Makhijani for their reviews, insight, and useful discussions about network slicing.¶
This work is partially supported by the European Commission under Horizon 2020 grant agreement number 101015857 Secured autonomic traffic management for a Tera of SDN flows (Teraflow).¶
The following people contributed text to this document.¶
Young Lee Email: younglee.tx@gmail.com Mohamed Boucadair Email: mohamed.boucadair@orange.com Sergio Belotti Email: sergio.belotti@nokia.com Daniele Ceccarelli Email: dceccare@cisco.com¶