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T. S. Eugene Ngeugeneng at cs.rice.edu Rice University1 COMP/ELEC 429 Introduction to Computer Networks Lecture 8: Bridging Slides used with permissions.

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1 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University1 COMP/ELEC 429 Introduction to Computer Networks Lecture 8: Bridging Slides used with permissions from Edward W. Knightly, T. S. Eugene Ng, Ion Stoica, Hui Zhang

2 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University2 Recap Broadcast network is a simple way to connect hosts –Everyone hears everything Need MAC protocol to control medium sharing Problem: Cannot scale up to connect large number of nodes –Too many nodes, too many collisions, goodput (throughput of useful data) goes to zero Broadcast technology host Hub Hub emulates a broadcast channel Easy to add a new host

3 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University3 Need Switching Techniques Switching limits size of collision domains, allows network size to scale up –To how big? Can Internet be one big switched Ethernet? –Will return to this question Switches are more complex than hubs –Intelligence, memory buffers, high performance host Hub Switch host

4 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University4 Switch Switch has memory buffers to queue packets, reduce loss Switch is intelligent: Forward an incoming packet to the correct output interface only High performance: Full N x line rate possible input interfaceoutput interface Switch fabric input interfaceoutput interface SwitchHub N

5 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University5 Taxonomy of Networks Communication Network Circuit-Switched Network Packet-Switched Network Datagram Network Virtual Circuit Network Frequency Division Multiplexing Time Division Multiplexing

6 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University6 Building Large LAN Using Bridges Bridges connect multiple IEEE 802 LANs at layer 2 –Datagram packet switching –Only forward packets to the right port –Reduce collision domain In contrast, hubs rebroadcast packets. host Bridge

7 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University7 Transparent Bridges Overall design goal: Complete transparency “Plug-and-play” Self-configuring without hardware or software changes Bridges should not impact operation of existing LANs Three parts to transparent bridges: (1) Forwarding of Frames (2) Learning of Addresses (3) Spanning Tree Algorithm

8 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University8 Frame Forwarding Each bridge maintains a forwarding database with entries MAC address: host address or group address port: port number of bridge age: aging time of entry interpretation: a machine with MAC address lies in direction of the port number from the bridge. The entry is age time units old.

9 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University9 Assume a frame arrives on port x. Frame Forwarding 2 Search if MAC address of destination is listed for ports A, B, or C. Forward the frame on the appropriate port Flood the frame, i.e., send the frame on all ports except port x. Found? Not found ?

10 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University10 In principle, the forwarding database could be set statically (=static routing) In the 802.1 bridge, the process is made automatic with a simple heuristic: The source field of a frame that arrives on a port tells which hosts are reachable from this port. Address Learning

11 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University11 Algorithm: For each frame received, stores the source address in the forwarding database together with the port where the frame was received. An entry is deleted after some time out (default is 15 seconds). Address Learning 2

12 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University12 Example Consider the following packets:,, What have the bridges learned? X Y

13 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University13 Consider the two LANs that are connected by two bridges. Assume host n is transmitting a frame F with unknown destination. What is happening? Bridges A and B flood the frame to LAN 2. Bridge B sees F on LAN 2 (with unknown destination), and copies the frame back to LAN 1 Bridge A does the same. The copying continues Where’s the problem? What’s the solution ? Danger of Loops

14 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University14 The solution to the loop problem is to not have loops in the topology IEEE 802.1 has an algorithm that builds and maintains a spanning tree in a dynamic environment. Bridges exchange messages (Configuration Bridge Protocol Data Unit (BPDU)) to configure the bridge to build the tree. Spanning Trees

15 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University15 What’s a Spanning Tree? A subset of edges of a graph that spans all the nodes without creating any cycle (i.e. a tree) 4 5 7 12 6 3

16 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University16 802.1 Spanning Tree Approach (Sketch) Elect a bridge to be the root of the tree Every bridge finds shortest path to the root Union of these paths become the spanning tree 4 5 7 Root 2 6 3

17 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University17 What do the BPDU messages do? With the help of the BPDUs, bridges can: Elect a single bridge as the root bridge. Calculate the distance of the shortest path to the root bridge Each LAN can determine a designated bridge, which is the bridge closest to the root. The designated bridge will forward packets towards the root bridge. Each bridge can determine a root port, the port that gives the best path to the root. Select ports to be included in the spanning tree.

18 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University18 Concepts Each bridge as a unique identifier: Bridge ID = Note that a bridge has several MAC addresses (one for each port), but only one ID Each port within a bridge has a unique identifier (port ID). Root Bridge: The bridge with the lowest identifier is the root of the spanning tree. Path Cost: Cost of the least cost path to the root from the port of a transmitting bridge; Assume it is measured in # of hops to the root. Root Port:Each bridge has a root port which identifies the next hop from a bridge to the root.

19 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University19 Concepts Root Path Cost: For each bridge, the cost of the min-cost path to the root Designated Bridge, Designated Port: Single bridge on a LAN that provides the minimal cost path to the root for this LAN: - if two bridges have the same cost, select the one with highest priority (smallest bridge ID) - if the min-cost bridge has two or more ports on the LAN, select the port with the lowest identifier Note: We assume that “cost” of a path is the number of “hops”.

20 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University20 A Bridged Network B3 B5 B2 B7 B1 B4 B6

21 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University21 Steps of Spanning Tree Algorithm 1. Determine the root bridge 2. Determine the root port on all other bridges 3. Determine the designated bridge on each LAN Each bridge is sending out BPDUs that contain the following information: root bridge (what the sender thinks it is) root path cost for sending bridge Identifies sending bridge root ID cost bridge ID/port ID

22 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University22 Ordering of Messages We can order BPDU messages with the following ordering relation “  “ (let’s call it “lower cost”): If (R1 < R2) M1  M2 elseif ((R1 == R2) and (C1 < C2)) M1  M2 elseif ((R1 == R2) and (C1 == C2) and (B1 < B2)) M1  M2 else M2  M1 ID R1 C1 ID B1 ID R2 C2 ID B2  M1 M2

23 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University23 Initially, all bridges assume they are the root bridge. Each bridge B sends BPDUs of this form on its LANs: Each bridge looks at the BPDUs received on all its ports and its own transmitted BPDUs. Root bridge is the smallest received root ID that has been received so far (Whenever a smaller ID arrives, the root is updated) Determine the Root Bridge B B 0 0 B B

24 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University24 At this time: A bridge B has a belief of who the root is, say R. Bridge B determines the Root Path Cost (Cost) as follows: If B = R : Cost = 0. If B ≠ R: Cost = {Smallest Cost in any of BPDUs that were received from R} + 1 B’s root port is the port from which B received the lowest cost path to R (in terms of relation “  “). Knowing R and Cost, B can generate its BPDU (but will not necessarily send it out): Calculate the Root Path Cost Determine the Root Port R R Cost B B

25 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University25 At this time: B has generated its BPDU B will send this BPDU on one of its ports, say port x, only if its BPDU is lower (via relation “  “) than any BPDU that B received from port x. In this case, B also assumes that it is the designated bridge for the LAN to which the port connects. Calculate the Root Path Cost Determine the Root Port R R Cost B B

26 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University26 Selecting the Ports for the Spanning Tree At this time: Bridge B has calculated the root, the root path cost, and the designated bridge for each LAN. Now B can decide which ports are in the spanning tree: –B’s root port is part of the spanning tree –All ports for which B is the designated bridge are part of the spanning tree. B’s ports that are in the spanning tree will forward packets (=forwarding state) B’s ports that are not in the spanning tree will not forward packets (=blocking state)

27 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University27 A Bridged Network (End of Spanning Tree Computation) B3 B5 B2 B7 B1 B4 B6 x x x

28 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University28 Ethernet Switches Bridges make it possible to increase LAN capacity. –Packets are no longer broadcasted - they are only forwarded on selected links –Adds a switching flavor to the broadcast LAN Ethernet switch is a special case of a bridge: each bridge port is connected to a single host. –Can make the link full duplex (really simple protocol!) –Simplifies the protocol and hardware used (only two stations on the link) – no longer full CSMA/CD –Can have different port speeds on the same switch Unlike in a hub, packets can be stored

29 T. S. Eugene Ngeugeneng at cs.rice.edu Rice University29 Can the Internet be One Big Switched Ethernet? Inefficient –Too much flooding Explosion of forwarding table –Need to have one entry for every Ethernet address in the world! Poor performance –Tree topology does not have good load balancing properties –Hot spots Etc…

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