SPARC: use-cases and results Requirements and Controller Architecture

1. SPARC: use-cases and resultsRequirements and Controller Architecture Wolfgang John wolfgang.john@ericsson.com November 23th 2012

2. EU FP7 Project • Start date: July 2010; End date: November 2012 (1 week ago …) • 6 Partners: Split Architecture for Carrier-Grade Networks. = ER Budapest ER Kista 23.11.2012 SPARC @ ACREO 2

3. Split Architecture for Carrier-Grade Networks. • Mission: Applying Software Defined Networking (SDN) to operator networks • Results • 23 publications, presentations and demos (GENI engineering conference, World Telecommunication Congress, Globecom, etc.) • Standardization impact in ONF and IRTF • Key Project Deliverables • D2.2: Use cases, requirements, techno-economic study (CAPEX and OPEX), business environment • D3.3: Main technical document, study of architecture and required extensions • D4.2: Documentation of specific OpenFlow extensions • D4.3: Technical documentation of implementation and prototyping activities • D5.2: Results of validation and performance evaluation • Movie: Summarizing the most important demo’s • (Soon) all to find on: http://www.fp7-sparc.eu 23.11.2012 SPARC @ ACREO 3

4. SPARC.Project Team. 23.11.2012 SPARC @ ACREO 4

5. Use Case Areas.Focus on Access/Aggregation. Auto-configuration Network Management Service Management AAA OAM subsystem Other Service Platforms (mobile, business, IPTV, VoIP, ...) BRAS GPON OLT Data Centre RGW Outdoor DSLAM Backbone Access/Aggregation Business AGS1 AGS2 LER LSR DSLAM Optical transport Optical transport Switch / Router Business 23.11.2012 SPARC @ ACREO 5

6. The vision of SPARC is to define, implement & evaluate a scalable carrier class Split Architecture. Seven objectives of SPARC, with the three main objectives highlighted: Definition of typical use cases for Split Architecture (D2.2) Analysis and description of business potential (D2.2) Definition of Split Architecture blueprint (D3.3) Extension of the OpenFlow protocol (D3.3 and D4.2) Development of SPARC prototype (D4.3) Validation of SPARC prototype (D5.2) Exploitation of results (papers, demos, presentations, videos) SPARC.Main Objectives. 23.11.2012 SPARC @ ACREO 6

7. What is carrier-grade? Scalability Support large-scale deployments for carrier-grade networks. E.g. a controller shall be able to control forwarding devices that could count in the order of hundreds. Availability and Reliability The availability of networking services shall be equivalent to that of traditional technologies. Network and service management The ability to monitor, diagnose and centrally manage the network Quality of Service Allowing the assurance of SLAs using QoS guarantees for service attributes (e.g. rate, loss, delay) and service isolation Support for legacy technology allowing deployment of new services in parallel to existing legacy protocol stacks SPARC Objectives.Carrier-grade. 23.11.2012 SPARC @ ACREO 7

8. 1 2 SPARC Requirements and Study Topics.Overview. 23.11.2012 SPARC @ ACREO 8

9. Intro to SplitArchitecture.Evolution of SDN. 23.11.2012 SPARC @ ACREO 9

10. Intro to SplitArchitecture.Software-Defined Networking. business applications SDN control network services software data data data OpenFlow-based SDN model, defined by the ONF 23.11.2012 SPARC @ ACREO 10

11. Intro to SplitArchitecture. Software-Defined Networking. business applications business applications control program hypervisor SDN network operating control network services system software data data data data data data • OpenFlow-based SDN model, including a network hypervisor • Virtualization and abstraction layer • Position of hypervisor (below or above NOS) debatable 23.11.2012 SPARC @ ACREO 11

12. Intro to SplitArchitecture.The SplitArchitecture concept. business applications control program hypervisor network operating system data data data • SPARC SplitArchitecture • Again a split between data and control plane • Forwarding and processing in data plane considered separately 23.11.2012 SPARC @ ACREO 12

13. Intro to SplitArchitecture.The SplitArchitecture concept. hierarchical controller concept OpenFlow forwarding forwarding forwarding processing processing processing • SPARC SplitArchitecture • Again a split between data and control plane • Forwarding and processing in data plane considered separately 23.11.2012 SPARC @ ACREO 13

14. Intro to SplitArchitecture. The SplitArchitecture concept. hierarchical controller concept network management system OpenFlow forwarding forwarding forwarding processing processing processing • SPARC SplitArchitecture • Initial considerations on the role of network management 23.11.2012 SPARC @ ACREO 14

15. Intro to SplitArchitecture. The SplitArchitecture concept. hier . control plane n + 1 app OpenFlow filtered , hierarchical controller abstract hier . control plane n app concept network view OpenFlow hier . control plane n - 1 app OpenFlow forwarding forwarding forwarding processing processing processing network management system • SPARC SplitArchitecture • Recursively stacked control planes • Abstracted network view ot higher planes via OpenFlow Interface 23.11.2012 SPARC @ ACREO 15

16. Intro to SplitArchitecture. The SplitArchitecture concept. hier . control plane n + 1 app OpenFlow filtered , hierarchical controller abstract hier . control plane n app concept network network view OpenFlow management system hier . control plane n - 1 app OpenFlow forwarding forwarding forwarding processing processing processing • SPARC SplitArchitecture • Recursively stacked control planes • Abstracted network view ot higher planes via OpenFlow Interface 23.11.2012 SPARC @ ACREO 16

17. Hierarchical controller.Design goals. • Goals for a carrier-grade control layer: • Increase flexibility • Adapt control architecture to use-cases and business models • Distribute the control layer to adapt to network capabilities • Allowing both cross-layering and strict layering of control logic • Increase scalability • Operator networks are complex -> divide and conquer the problem space • Allow smooth migration • Supporting control protocol operations with legacy domains 23.11.2012 SPARC @ ACREO 17

18. Hierarchical controller. • Current situation: monolithic network elements CP peers talk OSPF, IS-IS, STP, etc. CP CP CP DP DP DP FWD engine (DP) and control logic (CP) sit jointly on a single network element 23.11.2012 SPARC @ ACREO 18

19. Hierarchical controller.Splitting Ccontrol and forwarding. • Step 1 of SDN: Splitting control from data plane But still the old situation  the CP peers control a single network element and use the old protocol for sharing state as before (OSPF, IS-IS, LDP, STP, …) CP CP CP OpenFlow DP DP DP 23.11.2012 SPARC @ ACREO 19

20. Hierarchical controller.Centralizing control. • Step 2 of SDN: Centralize control plane Centralized control logic OpenFlow DP DP DP Benefit: no complex protocols for sharing state among CP peers required any more. 23.11.2012 SPARC @ ACREO 20

21. Hierarchical controller. OpenFlow as northbound interface. • SPARC Idea #1: Exposing services via OpenFlow again! OpenFlow Mgmt API Centralized control logic OpenFlow DP DP DP • Domain acts like a backplane within the emulated data path element. 23.11.2012 SPARC @ ACREO 21

22. Hierarchical controller.Flow space registration. • SPARC Idea #2: Integrate FlowVisor functionality into controller OpenFlow OpenFlow OpenFlow Flowspace Mgmt Mgmt API Centralized control logic OpenFlow DP DP DP Higher layer controllers subscribe to parts of the flowspace (i.e. slices) Replace the pub/sub interface (as in NOX) with flowspace reservation 23.11.2012 SPARC @ ACREO 22

23. Hierarchical controller.Stacked control planes. • Result: Hierarchical structuring of control planes! Requires OpenFlow protocol extensions for management of: * Flowspaces: allow plane (n) to register a slice of the flowspace on (n-1) * Transport endpoints: allow plane (n) to control (CRUD) logical ports on (n-1) 23.11.2012 SPARC @ ACREO 23

24. Hierarchical controller.Example: protocol stack. • Example: Modular layering of a controller SMTP APP-CTL SMTP IPv4 IP-CTL IP IPv4 IPv6 ETH ETH ETH ETH ETH ETH-CTL PHY PHY PHY PHY OpenFlow An IP router  use case: build an IPv4/IPv6 router An SMTP router  use case: build a Mail Transport Agent (MTA) = DP PHY-CTL The northbound interface is OPENFLOW! • IP-CTL  emulates a single IP layer • ETH-CTL  emulates Ethernet host stacks • PHY-CTL  is a data path element 8/20/2014 23.11.2012 SPARC @ ACREO 24

25. Considerations on network management. The SplitArchitecture concept. hier . control plane n + 1 app OpenFlow filtered , hierarchical controller abstract hier . control plane n app concept network network view OpenFlow management system hier . control plane n - 1 app OpenFlow forwarding forwarding forwarding processing processing processing • SPARC SplitArchitecture • Initial considerations on the role of network management 23.11.2012 SPARC @ ACREO 25

26. Considerations on network management.Control vs. management. • Boundary between management and control is blurred • Management functions are important in SplitArchitecture Functionality (Increased control granularity) Today’sNetworkManagement SplitArch/SDN Automation (Program driven, automatic adjustmentof the network) Speed (Beyond human time-scale) 23.11.2012 SPARC @ ACREO 26

27. Which NM functions to embed in a controller? Q1: Already an essential part of SplitArchitecture/SDN control? If not, Q2: Facilitates timely and automated configuration and flow steering? If so, Q3: Possible with open and standardized extensions to the OF / OF-Config protocols? (no bloating with vendor or device specific models) Apply this question to NM function according the TMN/FCAPS definitions of network management Considerations on network management.Assessment of functions. 23.11.2012 SPARC @ ACREO 27

28. Considerations on network management.SPARC assessment example. 23.11.2012 SPARC @ ACREO 28

29. control plane B control plane A hierarchical controller concept network management system OpenFlow e.g. optical devices forwarding forwarding forwarding processing processing processing Control and management architecture.Summary. • Result: A recursive and modular control plane architecture 23.11.2012 SPARC @ ACREO 29

30. SPARC: use-cases and resultsSPARC prototype implementations Wolfgang John wolfgang.john@ericsson.com November 23th 2012

31. Seamless MPLSaka carrier grade packet transport • Seamless MPLS “…architecture which can be used to extend MPLS networks to integrate access and aggregation networks into a single MPLS domain…” draft-leymann-mpls-seamless-mpls-03 Forklifting access/aggregation to MPLS may be too expensive  apply SDN principles for Seamless MPLS 23.11.2012 SPARC @ ACREO 31

32. OpenFlow Service OSPF, LDP,RSVP-TE, BGP … IPMPLS IPMPLS IPMPLS Switch Switch Switch GW Access IP Edge Seamless MPLS implementation.Basic concept. APP (CP) APP (CP) Central element SPARC Controller ProtocolProxy Aggregation IP/MPLS core CP CP CP CP CP CP CP CP 23.11.2012 SPARC @ ACREO 32

33. OFSwitch OFSwitch OFSwitch OFSwitch OF Edge OF Edge CoreMPLS CoreMPLS OFSwitch CoreMPLS Video WEB Client Client Seamless MPLS implementation.Essential Functionalities. NNI OSPF, LDP MPLSCP MPLSCP SPARC Controller MPLSCP OSPF End-to-end MPLS CTRL Protocol Proxy Discovery OpenFlow MPLS CTRL LDP NOX Kernel Clients Services IP/MPLS core OPENFLOW MPLS Aggregation Topology discovery of MPLS aggregation & core Management of MPLS LSPs in aggregation Signal end-to-end MPLS LSPs Provision MPLS transport services (e.g. Pseudowire) 23.11.2012 SPARC @ ACREO 33

34. MPLSCP MPLSCP MPLSCP OFSwitch OFSwitch OFSwitch OFSwitch OFSwitch OF Access OF Access CoreMPLS CoreMPLS CoreMPLS Video WEB Clients Services OPENFLOW MPLS Aggregation IP/MPLS core Client Client Seamless MPLS implementation.1. Topology disovery of MPLS aggegation & core. OSPF Combine OpenFlow and legacy topology discovery information Protocol Proxy Discovery NOX Kernel 23.11.2012 SPARC @ ACREO 34

35. MPLSCP MPLSCP MPLSCP OFSwitch OFSwitch OFSwitch OFSwitch OFSwitch OF Access CoreMPLS OF Access CoreMPLS CoreMPLS Video WEB Services Clients OPENFLOW MPLS Aggregation IP/MPLS core Client Client Seamless MPLS implementation.2. Management of MPLS LSPs in aggregation. SPARC Controller • Installs PtP, MPtP and PtMP tunnels • Reconfigures them upon topology changes Discovery OpenFlow MPLS CTRL NOX Kernel 23.11.2012 SPARC @ ACREO 35

36. MPLSCP MPLSCP MPLSCP OFSwitch OFSwitch OFSwitch OFSwitch OFSwitch OF Access CoreMPLS OF Access CoreMPLS CoreMPLS Video WEB IP/MPLS core OPENFLOW MPLS Aggregation Services Clients Client Client Seamless MPLS implementation.3. Signaling end-to-end MPLS LSPs. • Topology synchronization with OSPF • Spans end-to-end MPLS with LDP • Nests them in MPtP tunnels in aggregation SPARC Controller OSPF MPLS Tunnel End-to-end MPLS CTRL Protocol Proxy Discovery OpenFlow MPLS CTRL LDP NOX Kernel MPLS Tunnel 23.11.2012 SPARC @ ACREO 36

37. Split-BRAS • Split-BRAS BRAS is complex and expensive integrated node since it must handle all subscriber traffic, hence it must cope with continuously increasing capacity need, this means increasing cost Traditional way of deploying BRAS will not scale  apply SDN principles to distribute BRAS functionality 23.11.2012 SPARC @ ACREO 37

38. IP Edge RAWBRAS RAWBRAS BRAS AGS 2 AGS 2 AGS 1 AGS 2 AGS 1 AGS 1 AN AN AN RADIUS RADIUS RADIUS Client(RGW) Client(RGW) Client(RGW) Split BRAS.Basic concept. Common residential model today with PPPoE Split Control and raw forwarding Roll raw BRAS towardAccess Node BRAS CTRL BRAS CTRL Aggregationspecific tunnel Control session Control session PPPoE tunnel PPPoE tunnel Control session PPPoE tunnel 23.11.2012 SPARC @ ACREO 38

39. Split BRAS.Architecture Blueprint. control plane A control plane B Applying a recursive control plane L3 fwd engine IPoE PPP & PPPoE data path element L2 fwd engine (disabled) EoPhy EoPhy 23.11.2012 SPARC @ ACREO 39

40. RAWBRAS GW Access IP Edge Split BRAS.Concept. Central element SPARC Controller BRAS CTRL Relay PPP Request Aggregation IP/MPLS core Ethernet IP/MPLS 23.11.2012 SPARC @ ACREO 40

41. RAWBRAS Switch Switch Switch GW Access IP Edge Split BRAS.Flexible placement. Central element SPARC Controller BRAS CTRL Aggregation IP/MPLS core PPPoE (over PWE) 23.11.2012 SPARC @ ACREO 41

42. RAWBRAS RAWBRAS Switch Switch Switch GW Access IP Edge Split BRAS.Increased scalability. Central element SPARC Controller BRAS CTRL Aggregation IP/MPLS core PPPoE (over PWE) IP/MPLS 23.11.2012 SPARC @ ACREO 42

43. Summary of SPARC OpenFlow Protocol Extensions implemented. • MPLS • Parsing MPLS headers • Basic MPLS actions: push/pop header, change TTL, … • PPP & PPPoE • Terminate PPP & PPPoE tunnels • Connectivity Check • Pro-active monitoring of contuity with probe packets of MPLS-TP BFD format • Used for monitoring adjacency and flow pairs (bidirectional path) • OAM & Protection Notification • About state changes of monitoring entities • About protection events • Pseudo Wire • Support for Ethernet Pseudo Wire over MPLS PSN • Not full implementation (i.e., no sequence numbers) 23.11.2012 SPARC @ ACREO 43