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A Software Development Kit to exploit RINA programmability Eduard Grasa (presenter), Vincenzo Maffione, Francesco Salvestrini, Leonardo Bergesio, Miquel Tarzan FP7 PRISTINE ICC 2016, Kuala Lumpur, May 24th 2016 An SDK to exploit RINA programmability 1 WHATISRINA? 2 RINA highlights • 1 Network architecture resulting from a fundamental theory of computer networking • 2 Networking is InterProcess Communication (IPC) and only IPC. Unifies networking and distributed computing: the network is a distributed application that provides IPC • 3 There is a single type of layer with programmable functions, that repeats as many times as needed by the network designers • 4 All layers provide the same service: communication (flows) between two or more application instances, with certain characteristics (delay, loss, in-order-delivery, etc) • 5 There are only 3 types of systems: hosts, interior and border routers. No middleboxes (firewalls, NATs, etc) are needed • 6 Deploy it over, under and next to current networking technologies 3 From the “TCP/IP” protocol suite … (Theory) (Prac.ce) • Functional layers organized for modularity, each layer provides a different service to each other – As the RM is applied to the real world, it proofs to be incomplete. As a consequence, new layers are patched into the reference model as needed (layers 2.5, VLANs, VPNs, virtual network overlays, tunnels, MAC-in-MAC, etc.) 4 … to the RINA architecture Single type of layer, consistent API, programmable policies IPCAPI DataTransfer DataTransfer DataTransfer DataTransfer Relayingand MulNplexing CACEP StateVector StateVector StateVector SDUDelimiNng LayerManagement DataTransferControl Retransmission Retransmission Retransmission Control Control Control RIB Daemon FlowControl FlowControl FlowControl RIB AuthenNcaNon ResourceAllocaNon CDAPParser/ Generator RouNng Enrollment Namespace Management SDUProtecNon FlowAllocaNon Security Management IncreasingNmescale(funcNonsperformedlessoUen)andcomplexity App B App A DIF(DistributedIPCFacility) DIF DIF DIF Host Consistent APIthrough layers Host DIF DIF Borderrouter InteriorRouter Borderrouter 5 Deployment Clean-slate concepts but incremental deployment RINA supported Applications Sockets Applications IP Network RINA Network IP or Ethernet or MPLS, etc RINA Provider • IPv6 brings very small improvements to IPv4, but requires a clean slate deployment (not compatible to IPv4) • RINA can be deployed incrementally where it has the right incentives, and interoperate with current technologies (IP, Ethernet, MPLS, etc.) – Over IP (just like any overlay such as VXLAN, NVGRE, GTP-U, etc.) – Below IP (just like any underlay such as MPLS or MAC-in-MAC) – Next to IP (gateways/protocol translation such as IPv6) Large-scale RINA Experimentation on FIRE+ 6 2 RECURSION,VIRTUALIZATION ANDPROGRAMMABILITY 7 Recursion instead of virtualization (I) • RINA recursive layering structure generalizes the current protocol stack. cleans up and • Example 1: PBB-VPLS (Virtual Private LAN Service) – Uses MAC-in-MAC encapsulation to isolate provider’s core from customers addresses and VLANs 8 Recursion instead of virtualization (I) • RINA recursive layering structure generalizes the current protocol stack. cleans up and • Example 1: PBB-VPLS (Virtual Private LAN Service) – Uses MAC-in-MAC encapsulation to isolate provider’s core from customers addresses and VLANs PtPDIF PtPDIF PtPDIF PtPDIF PtPDIF PtPDIF PtPDIF PtPDIF PtPDIF PtPDIF PtPDIF 9 Recursion instead of virtualization (I) • RINA recursive layering structure generalizes the current protocol stack. cleans up and • Example 1: PBB-VPLS (Virtual Private LAN Service) – Uses MAC-in-MAC encapsulation to isolate provider’s core from customers addresses and VLANs PtPDIF PtPDIF PtPDIF MetroDIF PtPDIF PtPDIF PtPDIF MetroDIF PtPDIF PtPDIF PtPDIF PtPDIF PtPDIF 10 Recursion instead of virtualization (I) • RINA recursive layering structure generalizes the current protocol stack. cleans up and • Example 1: PBB-VPLS (Virtual Private LAN Service) – Uses MAC-in-MAC encapsulation to isolate provider’s core from customers addresses and VLANs PtPDIF PtPDIF PtPDIF MetroDIF PtPDIF PtPDIF CoreDIF PtPDIF PtPDIF PtPDIF MetroDIF PtPDIF PtPDIF PtPDIF 11 Recursion instead of virtualization (I) • RINA recursive layering structure generalizes the current protocol stack. cleans up and • Example 1: PBB-VPLS (Virtual Private LAN Service) – Uses MAC-in-MAC encapsulation to isolate provider’s core from customers addresses and VLANs PtPDIF ProviderVPNServiceDIF PtPDIF MetroDIF PtPDIF PtPDIF CoreDIF PtPDIF PtPDIF PtPDIF PtPDIF MetroDIF PtPDIF PtPDIF PtPDIF 12 Recursion instead of virtualization (I) • RINA recursive layering structure generalizes the current protocol stack. cleans up and • Example 1: PBB-VPLS (Virtual Private LAN Service) – Uses MAC-in-MAC encapsulation to isolate provider’s core from customers addresses and VLANs GreenCustomerVPNDIF PtPDIF ProviderVPNServiceDIF PtPDIF MetroDIF PtPDIF PtPDIF CoreDIF PtPDIF PtPDIF PtPDIF PtPDIF MetroDIF PtPDIF PtPDIF PtPDIF 13 Recursion instead of virtualization (II) • Example 2: LTE (Long Term Evolution) – Uses PDCP, GTP to transport user’s IP payload, and also relies on internal IP network. TCPorUDP IP(e.g.Internet) EPS bearer EPS bearer GTP-U GTP-U RLC UDP UDP MAC IP(LTEtransport) IP(LTEtransport) L1 UE MAC PDCP LTE-Uu Protocol conversion eNodeB L1 MAC . . . MAC MAC . . . MAC L1 . . . L1 L1 . . . L1 S1-U S-GW S5/S8 P-GW SGi 14 Recursion instead of virtualization (II) • Example 2: LTE (Long Term Evolution) – Uses PDCP, GTP to transport user’s IP payload, and also relies on internal IP network. TCPorUDP IP(e.g.Internet) EPS bearer EPS bearer GTP-U RLC UDP UDP MAC IP(LTEtransport) IP(LTEtransport) L1 UE MAC PDCP MAC PtPDIF L1 LTE-Uu Protocol conversion eNodeB GTP-U PtPDIF . . . . . . MAC PtPDIF S1-U L1 MAC PtPDIF L1 S-GW . . . . . . L1 MAC PtPDIF S5/S8 L1 P-GW SGi 15 Recursion instead of virtualization (II) • Example 2: LTE (Long Term Evolution) – Uses PDCP, GTP to transport user’s IP payload, and also relies on internal IP network. TCPorUDP IP(e.g.Internet) EPS bearer EPS bearer PDCP GTP-U RLC UDP L1 UE MAC PtPDIF L1 LTE-Uu Protocol conversion PtPDIF UDP MobileOperator TransportDIF IP(LTEtransport) MAC eNodeB MAC GTP-U . . . . . . MAC PtPDIF S1-U L1 MobileOperator TransportDIF IP(LTEtransport) L1 MAC PtPDIF L1 S-GW . . . . . . MAC PtPDIF S5/S8 L1 P-GW SGi 16 Recursion instead of virtualization (II) • Example 2: LTE (Long Term Evolution) – Uses PDCP, GTP to transport user’s IP payload, and also relies on internal IP network. TCPorUDP IP(e.g.Internet) EPS bearer EPS bearer PDCP GTP-U RLC UDP L1 UE MAC PtPDIF L1 LTE-Uu Protocol conversion PtPDIF UDP MobileOperator TransportDIF IP(LTEtransport) Mul>-accessradio MAC DIF eNodeB MAC GTP-U . . . . . . MAC PtPDIF S1-U L1 MobileOperator TransportDIF IP(LTEtransport) L1 MAC PtPDIF L1 S-GW . . . . . . MAC PtPDIF S5/S8 L1 P-GW SGi 17 Recursion instead of virtualization (II) • Example 2: LTE (Long Term Evolution) – Uses PDCP, GTP to transport user’s IP payload, and also relies on internal IP network. TCPorUDP IP(e.g.Internet) EPS bearer EPS bearer PDCP MobileAccessNetworkTopLevelDIF GTP-U RLC MAC PtPDIF L1 LTE-Uu Protocol conversion UDP MobileOperator TransportDIF IP(LTEtransport) L1 UE PtPDIF UDP Mul>-accessradio MAC DIF eNodeB MAC GTP-U . . . . . . MAC PtPDIF S1-U L1 MobileOperator TransportDIF IP(LTEtransport) L1 MAC PtPDIF L1 S-GW . . . . . . MAC PtPDIF S5/S8 L1 P-GW SGi 18 Recursion instead of virtualization (II) • Example 2: LTE (Long Term Evolution) – Uses PDCP, GTP to transport user’s IP payload, and also relies on internal IP network. TCPorUDP PublicInternetDIF IP(e.g.Internet) EPS bearer EPS bearer PDCP MobileAccessNetworkTopLevelDIF GTP-U RLC MAC PtPDIF L1 LTE-Uu Protocol conversion UDP MobileOperator TransportDIF IP(LTEtransport) L1 UE PtPDIF UDP Mul>-accessradio MAC DIF eNodeB MAC GTP-U . . . . . . MAC PtPDIF S1-U L1 MobileOperator TransportDIF IP(LTEtransport) L1 MAC PtPDIF L1 S-GW . . . . . . MAC PtPDIF S5/S8 L1 P-GW SGi 19 Recursion instead of virtualization (III) • Example 3: Data Center Network with NVO3 – Network Virtualization Over Layer 3, uses overlay virtual networks on top of the DCN’s fabric layer 3 to support multi-tenancy TCPorUDPorSCTP,…(transportlayer) IPv4orIPv6(tenantoverlay) 802.3 VXLAN 802.1Q VM 802.3 802.1Q VM UDP Server Server IPv4orIPv6(Fabriclayer) Protocolconversion, Localbridging ToR Ethernet Ethernet Ethernet Fabric Spine Ethernet Fabric ToR • Recursion provides a cleaner, simpler solution than virtualization – Repeat the same building block, with the same interface. 20 Recursion instead of virtualization (III) • Example 3: Data Center Network with NVO3 – Network Virtualization Over Layer 3, uses overlay virtual networks on top of the DCN’s fabric layer 3 to support multi-tenancy TCPorUDPorSCTP,…(transportlayer) IPv4orIPv6(tenantoverlay) 802.3 PtPDIF VXLAN 802.1Q PtPDIF VM 802.1Q PtPDIF 802.3 PtPDIF VM UDP Server Server IPv4orIPv6(Fabriclayer) Protocolconversion, Localbridging Ethernet PtPDIF ToR Ethernet PtPDIF Fabric Ethernet PtPDIF Spine Ethernet PtPDIF Fabric ToR • Recursion provides a cleaner, simpler solution than virtualization – Repeat the same building block, with the same interface. 21 Recursion instead of virtualization (III) • Example 3: Data Center Network with NVO3 – Network Virtualization Over Layer 3, uses overlay virtual networks on top of the DCN’s fabric layer 3 to support multi-tenancy TCPorUDPorSCTP,…(transportlayer) IPv4orIPv6(tenantoverlay) 802.3 PtPDIF VXLAN 802.1Q PtPDIF VM 802.1Q PtPDIF 802.3 PtPDIF VM UDP DCFabricDIF Server Server IPv4orIPv6(Fabriclayer) Protocolconversion, Localbridging Ethernet PtPDIF ToR Ethernet PtPDIF Fabric Ethernet PtPDIF Spine Ethernet PtPDIF Fabric ToR • Recursion provides a cleaner, simpler solution than virtualization – Repeat the same building block, with the same interface. 22 Recursion instead of virtualization (III) • Example 3: Data Center Network with NVO3 – Network Virtualization Over Layer 3, uses overlay virtual networks on top of the DCN’s fabric layer 3 to support multi-tenancy TCPorUDPorSCTP,…(transportlayer) TenantDIF IPv4orIPv6(tenantoverlay) 802.3 PtPDIF VXLAN 802.1Q PtPDIF VM 802.1Q PtPDIF 802.3 PtPDIF VM UDP DCFabricDIF Server Server IPv4orIPv6(Fabriclayer) Protocolconversion, Localbridging Ethernet PtPDIF ToR Ethernet PtPDIF Fabric Ethernet PtPDIF Spine Ethernet PtPDIF Fabric ToR • Recursion provides a cleaner, simpler solution than virtualization – Repeat the same building block, with the same interface. 23 Network Programmability • Centralized control data forwarding of ONF‘s SDN architecture – GSMPv3 (label switches: ATM, MPLS, optical), OpenFlow (Ethernet, IP, evolving) • APIs for controlling network services & network devices – ONF SDN architecture, IEEE P1520 (P1520 distinguished between virtual devices and hardware) 24 Separation of mechanism from policy IPCAPI DataTransfer DataTransfer DataTransfer DataTransfer Relayingand MulNplexing SDUProtecNon CACEP StateVector StateVector StateVector SDUDelimiNng LayerManagement DataTransferControl Retransmission Retransmission Retransmission Control Control Control RIB Daemon FlowControl FlowControl FlowControl RIB FlowAllocaNon AuthenNcaNon ResourceAllocaNon CDAPParser/ Generator RouNng Enrollment Namespace Management Security Management • All layers have the same mechanisms and 2 protocols (EFCP for data transfer, CDAP for layer management), programmable via policies. – All data transfer and layer management functions are programmable! • Don’t specify/implement protocols, only policies – Re-use common layer structure, re-use policies across layers • This approach greatly simplifies the network structure, minimizing the management overhead and the cost of supporting new requirements, new physical media or new applications 25 3 DESIGNANDIMPLEMENTATION OFANSDKFORIRATI 26 IRATI design: decisions and tradeoffs Decision Pros Cons Linux/OSvsother Opera.ngsystems Adop%on,Community,Stability, Documenta%on,Support Monolithickernel(RINA/ IPCModelmaybebe@er suitedtomicro-kernels) User/kernelsplit vsuser-spaceonly IPCasafundamentalOSservice, accessdevicedrivers,hardware offload,IPoverRINA,performance Morecomplex implementa%onand debugging C/C++ vsJava,Python,… Na%veimplementa%on Portability,Skillstomaster language(users) MulNpleuser-space daemonsvssingleone Reliability,Isola%onbetweenIPCPs andIPCManager Communica%onoverhead, morecompleximpl. SoU-irqs/taskletsvs. workqueues(kernel) Minimizelatencyandcontext switchesofdatagoingthroughthe “stack” Morecomplexkernel lockinganddebugging 27 Overview of IRATI and its SDK RouNng policy SDKsupport SDKsupport Rou%ng Enrollment SDKsupport Namespace Management librina Security Management SDKsupport RIB&RIB Daemon Resource alloca%on Flow alloca%on zoomin ECN policy Txctrl policy RTT policy ErrorandFlowControl Protocol zoomin SDUProtec%on Relayingand Mul%plexingTask SDKsupport SDKsupport Monit policy IRATIRINAimplementaNon NormalIPCP (DataTransfer) NormalIPCProcess (DataTransfer/Control) MaxQ policy Shim IPCP Schedu policy Shim IPCP Forwar policy IPCP ... SDKsupport Encryp policy ShimIPCP SHIM over802.1Q KernelIPCManager CRC policy Kernel Newflow policy librina NormalIPCP (Datatransfer) Userspace SDKsupport Coord policy Auth. policy NormalIPCProcess IPCPDaemon (LayerManagement) (LayerMgmt) TTL policy App IPCManager Daemon Acc.ctrl policy SDKsupport zoomin Pushbak noNfy Manag ement Agent Enroll. sequence PFTgen policy RIB&RIB Daemon Address validat IPCM logic Address assign Network Manager (NMSDAF) Directory replica NormalIPCP (LayerMgmt) IPCManager RINA Plugins Infrastructure (RPI) Kernel RPI (kRPI) ● PluginsareLoadableKernelModules(LKM) ● ● Theypublishasetofpolicysets,becomesavailabletotheRINAstack. Factories, named aXer each policy set, provide opera.ons to create/delete instances of policysetclasses PolicySetlifecycle • Different policy-set class per PolicySetclasses component, since each component has different policies. “OO”approach ● ● ● All policy set classes derive frombaseclass All components derive from baseclass 29 RINA Plugins Infrastructure (RPI) User-space RPI uRPI) ● SameconceptsaskRPI(factories,lifecycle,policyclasses),differentimpl ● PluginsaresharedobjectsdynamicallyloadedbytheIPCPDaemon,loaded throughthelibdllibrary 30 SDK Usage: Experimentation with IRATI Data transfer policies: RMT and EFCP • Programmed data transfer policies to manage congestion in a distributed cloud environment. DECBinaryfeedback(EFCPandRMT) • Two touch points: i) ECNmarking policies for the RMT; ii) flow control policies that react to ECN-marked PDUs in EFCP “TCPTahoe”(EFCP)+RED(RMT) 31 4 ONGOINGRINAINITIATIVES 32 Research, open source, standards • Current research projects 1 – 2 – 3 – – 4 FP7 PRISTINE (2014-2016) http://ict-pristine-eu H2020 ARCFIRE (2016-2017) http://ict-arcfire.eu Norwegian project OCARINA(2016-2021) BU RINA team http://csr.bu.edu/rina • Open source implementations 1 IRATI (Linux OS, C/C++, kernel components, policy framework, RINA – over X) http://github.com/irati/stack 2 – RINASim (RINA simulator, OMNeT++) 3 ProtoRINA (Java, RINA over UDP, quick prototyping) – • Key RINA standardization activities – 1 Pouzin Society (experimental specs) http://pouzinsociety.org – 2 ISO SC6 WG7 (2 new projects: Future Network – Architectures, Future Network- Protocols) 3 ETSI Next Generation Protocols ISG – 33
