| SDNRG | E.H. Haleplidis |
| Internet-Draft | S.D. Denazis |
| Intended status: Informational | University of Patras |
| Expires: June 12, 2014 | K.P. Pentikousis |
| EICT | |
| J.H.S. Hadi Salim | |
| Mojatatu Networks | |
| D.M. Meyer | |
| Brocade | |
| O.K. Koufopavlou | |
| University of Patras | |
| December 09, 2013 |
SDN Layers and Architecture Terminology
draft-haleplidis-sdnrg-layer-terminology-03
Software-Defined Networking (SDN) can in general be defined as a new approach for network programmability. Network programmability refers to the capacity to initialize, control, change, and manage network behavior dynamically via open interfaces as opposed to relying on closed-box solutions and propietary-defined interfaces. SDN emphasizes the role of software in running networks through the introduction of an abstraction for the data forwarding plane and, by doing so, separates it from the control plane. This separation allows faster innovation cycles at both planes as experience has already shown. However, there is increasing confusion as to what exactly SDN is, what is the layer structure in an SDN architecture and how do layers interface with each other. This document aims to answer these questions and provide a concise reference document for SDNRG, in particular, and the SDN community, in general, based on relevant peer-reviewed literature and documents in the RFC series.
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Software-Defined Networking (SDN) is a relevant new term for the programmable networks paradigm [PNSurvey99][OF08]. In short, SDN refers to the ability to use software to program individual network devices dynamically and therefore control the behavior of the network as a whole [NV09]. A key element in SDN is the introduction of an abstraction between the (traditional) Forwarding and the Control planes in order to separate them and provide applications with the means necessary to programmatically control the network. The goal is to leverage on this separation, and the associated programmability, in order to reduce complexity and enable faster innovation at both planes [A4D05].
Current and earlier research in SDN often focuses on varying aspects of programmability, and we are frequently confronted with conflicting points of view regarding what exactly SDN is. For instance, we find that for various reasons (e.g. work focusing on one domain and therefore not necessarily applicable as-is to other domains), certain well-accepted definitions do not correlate well with each other. For example, both OpenFlow [OpenFlow] and NETCONF [RFC6241] have been characterized as SDN interfaces, but they refer to control and management respectively.
This motivates us to consolidate the definitions of SDN in the literature and correlate them with earlier work in IETF and the research community. Of particular interest, for example, is to determine which layers comprise the SDN architecture and which interfaces and their corresponding attributes are best suitable to be used between them. As such, the aim of this document is not to standardize any particular layer or interface but rather to provide a concise reference document which reflects current approaches regarding the SDN layers architecture. We expect that this document would be useful to upcoming work in SDNRG as well as future discussions within the SDN community as a whole.
This document aims to address the potential work item in the SDNRG charter named "Survey of SDN approaches and Taxonomies", fostering better understanding of prominent SDN technologies in an technology-impartial and business-agnostic manner. As such we do not make any value statements nor discuss the applicability of any of the frameworks examined for any particular purpose. Instead, we document their characteristics and attributes and classify them thus providing a taxonomy.
This document does not constitute a new IETF standard nor a new specification, and aims to receive rough consensus within SDNRG to be published in the IRTF Stream as per [RFC5743].
The remainder of this document is organized as follows. Section 1.1 explains the terminology used in this document. Figure 1 introduces a high-level overview of current SDN architecture abstractions. Finally, Section 3 discusses how the SDN Layer Architecture relates with prominent SDN-enabling technologies
This document uses the following terms:
Figure 1 provides a detailed high-level overview of the current SDN architecture abstractions. Note that planes can be collocated with other planes or can be physically separated, as we discuss below.
SDN is based on the concept of separation between a controlled entity and a controller entity. The controller manipulates the controlled entity via an Interface. Interfaces, when local, are mostly API calls through some library or system call. However, such interfaces may be extended via some protocol definition (which may be local IPC or protocol that could also act remotely; the protocol may be defined as an open standard or in proprietary manner).
o--------------------------------o
| |
| +-------------+ +----------+ |
| | Application | | Service | |
| +-------------+ +----------+ |
| Application Plane |
o---------------Y----------------o
|
*-----------------------------Y---------------------------------*
| Service Abstraction Layer (SAL) |
*------Y------------------------------------------------Y-------*
| |
| Service Interface |
| |
o------Y------------------o o---------------------Y------o
| | Control Plane | | Management Plane | |
| +----Y----+ +-----+ | | +-----+ +----Y----+ |
| | Service | | App | | | | App | | Service | |
| +----Y----+ +--Y--+ | | +--Y--+ +----Y----+ |
| | | | | | | |
| *----Y-----------Y----* | | *---Y---------------Y----* |
| | Control Abstraction | | | | Management Abstraction | |
| | Layer (CAL) | | | | Layer (MAL) | |
| *----------Y----------* | | *----------Y-------------* |
| | | | | |
o------------|------------o o------------|---------------o
| |
| CP | MP
| Southbound | Southbound
| Interface | Interface
| |
*------------Y---------------------------------Y----------------*
| Device and resource Abstraction Layer (DAL) |
*------------Y---------------------------------Y----------------*
| | | |
| o-------Y----------o +-----+ o--------Y----------o |
| | Forwarding Plane | | App | | Operational Plane | |
| o------------------o +-----+ o-------------------o |
| Network Device |
+---------------------------------------------------------------+
Figure 1: SDN Layer Architecture
This document follows a network device centric approach: Control refers to the device's packet handling while Management refers to the device's operation. The reader should keep in mind throughout this document that we make no distinction between "physical" and "virtual" network devices, as we do not delve into implementation or performance aspects. In other words, a network device can be implemented fully in hardware, fully in software, or any hybrid combination in between. Similarly, network device software can run on "bare metal" or on a virtualized substrate. Finally, we do not distinguish on whether a device is implemented as an overlay or as a part/component of some other device.
SDN spans multiple planes as illustrated in Figure 1. Starting from the bottom part of the figure and moving towards the upper part, we identify the following planes:
All planes mentioned above are connected via Interfaces (as indicated with "Y" in Figure 1. An Interface may take multiple roles depending on whether the connected planes reside on the same (physical or virtual) device. If the respective planes are designed so that they do not have to reside in the same device, then the Interface can only take the form of a protocol. If the planes are co-located on the same device, then the Interface could either be an open/proprietary protocol, an open/proprietary software inter-process communication API, or operating system kernel system calls.
Applications, i.e. software programs that perform specific computations that consume services without providing access to other applications, can be implemented natively inside a plane or can span multiple planes.
Services, i.e. software programs that provide APIs to other applications or services, can also be natively implemented in specific planes. Services that span multiple planes belong to the application plane as well.
While not shown in Figure 1, services, applications or even planes, can be placed in a recursive manner thus providing overlay semantics to the model.
Additionally, this document considers four abstraction layers:
A Network Device is an entity that receives packets on its ports and performs one or more network functions on them. For example, the network device could forward a received packet, drop it, alter the packet header (or payload) and forward the packet, and so on. NDs can be implemented in hardware or software and can be either a physical or virtual network element. As mentioned above, this document makes no distinction between these. Each network device has both a Forwarding Plane and an Operational Plane.
The Forwarding Plane, commonly referred to as the "data path", is responsible for handling and forwarding packets. The Forwarding Plane provides switching, routing transformation and filtering functions. Resources of the forwarding plane include but are not limited to filters, meters, markers and classifiers.
The Operational Plane is responsible for operational state of the ND, for example, with respect to status of network ports and interfaces. Resources of the operational plane include but are not limited to memory, CPU, ports, interfaces and queues.
The Forwarding and the Operational Planes can be exposed via a Device and resource Abstraction Layer (DAL), which may be comprised of one or more abstraction models. Examples of Forwarding Plane abstraction models are the ForCES model [RFC5812] and the OpenFlow switch model [OpenFlow]. Examples of the Operational Plane abstraction model include the ForCES model [RFC5812], the YANG model [RFC6020] and SNMP MIBs [RFC3418].
Examples of Network Devices include switches and routers. Additional examples include network elements that may operate at a layer above IP, such as firewalls, load balancers and video transcoders.
Note that applications can also reside in a network device. Examples of such applications include event monitoring, and handling (offloading) topology discovery or ARP [RFC0826] in the device itself instead of forwarding such traffic to the control plane.
The Control plane is usually distributed and is responsible mainly for the configuration of the Forwarding Plane using a Control Plane Southbound Interface (CPSI) with DAL as a point of reference. The Control Plane is responsible for instructing the Forwarding Plane about how to handle network packets.
Control Plane functionalities usually include:
The CPSI is usually defined with the following characteristics:
Examples include fast and high frequency of flow or table updates, high throughput and robustness for packet handling and events.
CPSI can be implemented using a protocol, an API or even interprocess communication. If the Control Plane and the Network Device are not collocated, then this interface is certainly a protocol. Examples of CPSIs are ForCES [RFC5810] and the Openflow protocol [OpenFlow].
The Control Abstraction Layer (CAL) provides access to control applications and services to various CPSIs. The Control Plane may support more than one CPSIs.
Control applications can use CAL to control a network device without providing any service to upper layers. Examples include applications that perform control functions, such as OSPF, BGP, etc.
Control Plane Services examples include a virtual private LAN service, service tunnels, topology services, etc.
The Management Plane is usually centralized and aims to ensure that the network, which consists of network devices, is running optimally by communicating with the network devices's Operational Plane using a Management Plane Southbound Interface (MPSI) with DAL as a point of reference.
Management plane functionalities are typically initiated, based on an overall network view, and traditionally have been human-centric. However, lately algorithms are replacing most human intervention. Management plane functionalities [FCAPS] [RFC3535] usually include:
Normally MSPI, in contrast to the CPSI, is not a time-critical interface and does not share the CPSI requirements.
MSPI is [RFC3535] typically closer to human interaction than the control plane and therefore the MSPI usually has the following characteristics:
As an example of usability versus performance, we refer to the consensus of the 2002 IAB Workshop [RFC3535], as mentioned in [RFC6632], where textual configuration files should be able to contain international characters. Human-readable strings should utilize UTF-8, and protocol elements should be in case-insensitive ASCII which require more processing capabilities to parse.
The MPSI can range from a protocol, to an API or even interprocess communication. If the Management Plane is not embedded in the network device, the MSPI is certainly a protocol. Examples of MPSIs are ForCES [RFC5810], NETCONF [RFC6241], OVSDB [I-D.pfaff-ovsdb-proto] and SNMP [RFC3411].
The Management Abstraction Layer (MAL) provides access to management applications and services to various MPSIs. The Management Plane may support more than one MPSI.
Management Applications can use MAL to manage the network device without providing any service to upper layers. Examples of management applications include network monitoring and fault detection and recovery applications.
Management Plane Services provide access to other services or applications above the Management Plane.
The Service Abstraction Layer (SAL) provides access from services of the control, management and application planes to services and applications of the application plane. We note that the term (as well as the acronym) is overloaded, as it is often used in several contexts ranging from system design to service-oriented architectures. We emphasize that this term relates to Figure 1 and we map it accordingly in Section 3 to prominent SDN approaches.
Service Interfaces can take many forms pertaining to their specific requirements. Examples of service interfaces include but are not limited to, RESTful APIs, open or proprietary protocols such as NETCONF, inter-process communications, CORBA interfaces, etc.
Applications and services that use services from the control and/or management plane form the Application Plane.
Additionally, services residing in the Application Plane may provide services to other services and applications that reside in the application plane via the service interface.
Examples of applications include network topology discovery, network provisioning, path reservation, etc.
We advocate that the SDN southbound interface should encompass both CSPI and MSPI.
The SDN northbound interface is implemented in the Service Abstraction Layer of Figure 1.
The above model can be used to describe in a concise manner all prominent SDN-enabling technologies, as we explain in the following subsections.
The Forwarding and Control Element Separation (ForCES [RFC5810]) is an IETF framework consisting of a model and two protocols. ForCES separates the Forwarding from the Control Plane via an open interface, namely the ForCES protocol which operates on entities of the forwarding plane that have been modeled using the ForCES model.
The ForCES model is based on the fact that a network element is composed of numerous logically separate entities that cooperate to provide a given functionality -such as routing or IP switching- and yet appear as a normal integrated network element to external entities and secondly with a protocol to transport information.
ForCES models the Forwarding Plane using Logical Functional Blocks (LFBs) which are connected in a graph, composing the Forwarding Element (FE). LFBs are described in an XML language, based on an XML schema.
LFB definitions include:
The ForCES model can be used to define LFBs from fine- to coarse-grained as needed.
The ForCES protocol is agnostic to the model and can be used to monitor, configure and control any ForCES-modeled element. The protocol has very simple commands: Set, Get and Del. ForCES is a protocol designed for high throughput and fast updates.
ForCES [RFC5810] can be mapped to the framework illustrated in Figure 1 as follows:
The Network Configuration Protocol (NETCONF [RFC6241]), is an IETF-standardized network management protocol [RFC6632]. NETCONF provides mechanisms to install, manipulate, and delete the configuration of network devices.
NETCONF protocol operations are realized as remote procedure calls (RPCs). The NETCONF protocol uses an Extensible Markup Language (XML) based data encoding for the configuration data as well as the protocol messages.
Additionally, the YANG data modeling language has been developed for specifying NETCONF data models and protocol operations. YANG is a data modeling language used to model configuration and state data manipulated by NETCONF, NETCONF remote procedure calls, and NETCONF notifications.
YANG models the hierarchical organization of data as a tree, in which each node has either a value or a set of child nodes. Additionally, YANG structures data models into modules and submodules allowing reusability and augmentation. YANG models can describe constraints to be enforced on the data. Additionally YANG has a set of base datatype and allows custom defined datatypes as well.
YANG allows the definition of NETCONF RPCs allowing the protocol to have an extensible number of commands. For RPC definition, the operations names, input parameters, and output parameters are defined using YANG data definition statements.
NETCONF can be mapped to the framework illustrated in Figure 1 as follows:
OpenFlow is a framework developed by Standford, currently run by the Open Networking Foundation, initially to provide a way for researchers to run experimental protocols in the network. OpenFlow provides a protocol with which a controller may manage a static model of an OpenFlow switch.
An OpenFlow Switch consists of one or more flow tables which perform packet lookups and forwarding, a group table and an OpenFlow channel to an external controller. The switch communicates with the controller which manages the switch via the OpenFlow protocol.
OpenFlow can be mapped to the framework illustrated in Figure 1 as follows:
I2RS, although still work in progress at the IETF, can be mapped to the framework illustrated in Figure 1 as follows:
Bidirectional Forwarding Detection (BFD) [RFC5880], is an IETF network protocol designed for detecting communication failures between two forwarding elements which are directly connected. It is intended to be implemented in some component of the forwarding engine of a system, in cases where the forwarding and control engines are separated.
BFD provides low-overhead detection of faults even on physical media that do not support failure detection of any kind, such as Ethernet, virtual circuits, tunnels and MPLS Label Switched Paths.
BFD could be mapped to the framework illustrated in Figure 1 either as:
The authors would like to acknowledge David Meyer, Salvatore Loreto and Sudhir Modali for the initial discussion on the SDNRG mailing list as well as their draft-specific comments that helped put this document in a better shape.
Additionally the authors would like to acknowledge Russ White, Linda Dunbar, Robert Raszuk, Pedro Martinez-Julia, Lee Young, Yaakov Stein, Shivleela Arlimatti, Gurkan Deniz, Scott Brim, Carlos Pignataro, Ramki Krishnan, Bless Roland, Tim Copley, Francisco Javier Ros Munoz, Sriganesh Kini, Alan Clark, Erik Nordmark for their critical comments and discussions at the IETF 88 meeting (and the SDNRG mailing list), which we took into consideration while revising this document.
This memo makes no requests to IANA.
TBD