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Virtual Links: VLANs and Tunneling

Virtual Links: VLANs and Tunneling. CS 4251: Computer Networking II Nick Feamster Spring 2008. Why VLANs?. Layer 2: devices on one VLAN cannot communicate with users on another VLAN without the use of routers and network layer addresses Advantages

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Virtual Links: VLANs and Tunneling

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  1. Virtual Links: VLANs and Tunneling CS 4251: Computer Networking IINick FeamsterSpring 2008

  2. Why VLANs? • Layer 2: devices on one VLAN cannot communicate with users on another VLAN without the use of routers and network layer addresses • Advantages • Help control broadcasts (primarily MAC-layer broadcasts) • Switch table entry scaling • Improve network security • Help logically group network users • Key feature: Divorced from physical network topology

  3. VLAN basics • VLAN configuration issues: • A switch creates a broadcast domain • VLANs help manage broadcast domains • VLANs can be defined on port groups, users or protocols • LAN switches and network management software provide a mechanism to create VLANs • VLANs help control the size of broadcast domains and localize traffic. • VLANs are associated with individual networks. • Devices in different VLANs cannot directly communicate without the intervention of a Layer 3 routing device.

  4. VLAN Trunking Protocol • VLAN trunking: many VLANs throughout an organization by adding special tags to frames to identify the VLAN to which they belong. • This tagging allows many VLANs to be carried across a common backbone, or trunk. • IEEE 802.1Q trunking protocol is the standard, widely implemented trunking protocol

  5. Trunking: History • An example of this in a communications network is a backbone link between an MDF and an IDF • A backbone is composed of a number of trunks.

  6. VLAN Trunking • Conserve ports when creating a link between two devices implementing VLANs • Trunking will bundle multiple virtual links over one physical link by allowing the traffic for several VLANs to travel over a single cable between the switches.

  7. Trunking Operation • Manages the transfer of frames from different VLANs on a single physical line • Trunking protocols establish agreement for the distribution of frames to the associated ports at both ends of the trunk • Two mechanisms • frame filtering • frame tagging

  8. Frame Filtering

  9. Frame Tagging • A frame tagging mechanism assigns an identifier, VLAN ID, to the frames • Easier management • Faster delivery of frames

  10. Frame Tagging • Each frame sent on the link is tagged to identify which VLAN it belongs to. • Different tagging schemes exist • Two common schemes for Ethernet frames • 802.1Q:IEEE standard • Encapsulates packet in an additional 4-byte header • ISL –Cisco proprietary Inter-Switch Link protocol • Tagging occurs within the frame itself

  11. VLANs and trunking • VLAN frame tagging is an approach that has been specifically developed for switched communications. • Frame tagging places a unique identifier in the header of each frame as it is forwarded throughout the network backbone. • The identifier is understood and examined by each switch before any broadcasts or transmissions are made to other switches, routers, or end-station devices. • When the frame exits the network backbone, the switch removes the identifier before the frame is transmitted to the target end station. • Frame tagging functions at Layer 2 and requires little processing or administrative overhead.

  12. Inter-VLAN Routing • If a VLAN spans across multiple devices a trunk is used to interconnect the devices. • A trunk carries traffic for multiple VLANs. • For example, a trunk can connect a switch to another switch, a switch to the inter-VLAN router, or a switch to a server with a special NIC installed that supports trunking. • Remember that when a host on one VLAN wants to communicate with a host on another, a router must be involved.

  13. Inter-VLAN Issues and Solutions • Hosts on different VLANs must communicate • Logical connectivity: a single connection, or trunk, from the switch to the router • That trunk can support multiple VLANs • This topology is called a router on a stick because there is a single connection to the router

  14. Physical and logical interfaces • The primary advantage of using a trunk link is a reduction in the number of router and switch ports used. • Not only can this save money, it can also reduce configuration complexity. • Consequently, the trunk-connected router approach can scale to a much larger number of VLANs than a one-link-per-VLAN design.

  15. Why Tunnel? • Security • E.g., VPNs • Flexibility • Topology • Protocol • Bypassing local network engineers • Oppressive regimes: China, Pakistan, TS… • Compatibility/Interoperability • Dispersion/Logical grouping/Organization • Reliability • Fast Reroute, Resilient Overlay Networks (Akamai SureRoute) • Stability (“path pinning”) • E.g., for performance guarantees

  16. MPLS Overview • Main idea: Virtual circuit • Packets forwarded based only on circuit identifier Source 1 Destination Source 2 Router can forward traffic to the same destination on different interfaces/paths.

  17. Circuit Abstraction: Label Swapping D • Label-switched paths (LSPs): Paths are “named” by the label at the path’s entry point • At each hop, label determines: • Outgoing interface • New label to attach • Label distribution protocol: responsible for disseminating signalling information 2 A 1 Tag Out New 3 A 2 D

  18. Layer 3 Virtual Private Networks • Private communications over a public network • A set of sites that are allowed to communicate with each other • Defined by a set of administrative policies • determine both connectivity and QoS among sites • established by VPN customers • One way to implement: BGP/MPLS VPN mechanisms (RFC 2547)

  19. Building Private Networks • Separate physical network • Good security properties • Expensive! • Secure VPNs • Encryption of entire network stack between endpoints • Layer 2 Tunneling Protocol (L2TP) • “PPP over IP” • No encryption • Layer 3 VPNs Privacy and interconnectivity (not confidentiality, integrity, etc.)

  20. Layer 2 vs. Layer 3 VPNs • Layer 2 VPNs can carry traffic for many different protocols, whereas Layer 3 is “IP only” • More complicated to provision a Layer 2 VPN • Layer 3 VPNs: potentially more flexibility, fewer configuration headaches

  21. VPN A/Site 2 10.2/16 VPN B/Site 1 10.2/16 CEA2 CE1B1 10.1/16 CEB2 VPN B/Site 2 P1 PE2 CE2B1 P2 PE1 PE3 CEA3 CEA1 P3 10.3/16 CEB3 10.1/16 VPN A/Site 3 10.4/16 VPN A/Site 1 VPN B/Site 3 Layer 3 BGP/MPLS VPNs • Isolation: Multiple logical networks over a single, shared physical infrastructure • Tunneling:Keeping routes out of the core BGP to exchange routes MPLS to forward traffic

  22. High-Level Overview of Operation • IP packets arrive at PE • Destination IP address is looked up in forwarding table • Datagram sent to customer’s network using tunneling (i.e., an MPLS label-switched path)

  23. BGP/MPLS VPN key components • Forwarding in the core:MPLS • Distributing routes between PEs:BGP • Isolation:Keeping different VPNs from routing traffic over one another • Constrained distribution of routing information • Multiple “virtual” forwarding tables • Unique addresses: VPN-IP4 Address extension

  24. Virtual Routing and Forwarding • Separate tables per customer at each router Customer 1 10.0.1.0/24 10.0.1.0/24RD: Green Customer 1 Customer 2 10.0.1.0/24 Customer 2 10.0.1.0/24RD: Blue

  25. Site 2 Site 1 Site 3 Routing: Constraining Distribution • Performed by Service Provider using route filtering based on BGP Extended Community attribute • BGP Community is attached by ingress PE route filtering based on BGP Community is performed by egress PE BGP Static route, RIP, etc. RD:10.0.1.0/24Route target: GreenNext-hop: A A 10.0.1.0/24

  26. Forwarding • PE and P routers have BGP next-hop reachability through the backbone IGP • Labels are distributed through LDP (hop-by-hop) corresponding to BGP Next-Hops • Two-Label Stack is used for packet forwarding • Top label indicates Next-Hop (interior label) • Second level label indicates outgoing interface or VRF (exterior label) Corresponds to VRF/interface at exit Corresponds to LSP ofBGP next-hop (PE) Layer 2 Header Label1 Label2 IP Datagram

  27. Forwarding in BGP/MPLS VPNs • Step 1: Packet arrives at incoming interface • Site VRF determines BGP next-hop and Label #2 Label2 IP Datagram • Step 2: BGP next-hop lookup, add corresponding LSP (also at site VRF) Label1 Label2 IP Datagram

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