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Router Design (Nick Feamster) February 11, 2008. 2 Today’s Lecture The design of big, fast routers Partridge et al., A 50 Gb/s IP Router Design constraints.

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Presentation on theme: "Router Design (Nick Feamster) February 11, 2008. 2 Today’s Lecture The design of big, fast routers Partridge et al., A 50 Gb/s IP Router Design constraints."— Presentation transcript:

1 Router Design (Nick Feamster) February 11, 2008

2 2 Today’s Lecture The design of big, fast routers Partridge et al., A 50 Gb/s IP Router Design constraints –Speed –Size –Power consumption Components Algorithms –Lookups and packet processing (classification, etc.) –Packet queuing –Switch arbitration

3 3 What’s In A Router Interfaces –Input/output of packets Switching fabric –Moving packets from input to output Software –Routing –Packet processing –Scheduling –Etc.

4 4 What a Router Chassis Looks Like Cisco CRS-1Juniper M320 6ft 19 ” 2ft Capacity: 1.2Tb/s Power: 10.4kW Weight: 0.5 Ton Cost: $500k 3ft 2ft 17 ” Capacity: 320 Gb/s Power: 3.1kW

5 5 What a Router Line Card Looks Like 1-Port OC48 (2.5 Gb/s) (for Juniper M40) 4-Port 10 GigE (for Cisco CRS-1) Power: about 150 Watts 21in 2in 10in

6 6 Big, Fast Routers: Why Bother? Faster link bandwidths Increasing demands Larger network size (hosts, routers, users)

7 7 Summary of Routing Functionality Router gets packet Looks at packet header for destination Looks up routing table for output interface Modifies header (TTL, IP header checksum) Passes packet to output interface

8 8 Generic Router Architecture Lookup IP Address Update Header Header Processing DataHdrDataHdr 1M prefixes Off-chip DRAM Address Table Address Table IP AddressNext Hop Queue Packet Buffer Memory Buffer Memory 1M packets Off-chip DRAM Question: What is the difference between this architecture and that in today’s paper?

9 9 Innovation #1: Each Line Card Has the Routing Tables Prevents central table from becoming a bottleneck at high speeds Complication: Must update forwarding tables on the fly. –How does the BBN router update tables without slowing the forwarding engines?

10 10 Generic Router Architecture Lookup IP Address Update Header Header Processing Address Table Address Table Lookup IP Address Update Header Header Processing Address Table Address Table Lookup IP Address Update Header Header Processing Address Table Address Table DataHdrDataHdrDataHdr Buffer Manager Buffer Memory Buffer Memory Buffer Manager Buffer Memory Buffer Memory Buffer Manager Buffer Memory Buffer Memory DataHdrDataHdrDataHdr Interconnection Fabric

11 11 Route Table CPU Buffer Memory Line Interface MAC Line Interface MAC Line Interface MAC Typically <0.5Gb/s aggregate capacity Shared Bus Line Interface CPU Memory First Generation Routers Off-chip Buffer

12 12 Route Table CPU Line Card Buffer Memory Line Card MAC Buffer Memory Line Card MAC Buffer Memory Fwding Cache Fwding Cache Fwding Cache MAC Buffer Memory Typically <5Gb/s aggregate capacity Second Generation Routers

13 13 Third Generation Routers Line Card MAC Local Buffer Memory CPU Card Line Card MAC Local Buffer Memory “Crossbar”: Switched Backplane Line Interface CPU Memory Fwding Table Routing Table Fwding Table Typically <50Gb/s aggregate capacity

14 14 Innovation #2: Switched Backplane Every input port has a connection to every output port During each timeslot, each input connected to zero or one outputs Advantage: Exploits parallelism Disadvantage: Need scheduling algorithm

15 15 Head-of-Line Blocking Output 1 Output 2 Output 3 Input 1 Input 2 Input 3 Problem: The packet at the front of the queue experiences contention for the output queue, blocking all packets behind it. Maximum throughput in such a switch: 2 – sqrt(2) M.J. Karol, M. G. Hluchyj, and S. P. Morgan, “Input Versus Output Queuing on a Space-Division Packet Switch,” IEEE Transactions On Communications, Vol. Com-35, No. 12, December 1987, pp. 1347-1356.

16 16 Speedup What if the crossbar could have a “speedup”? Key result: Given a crossbar with 2x speedup, any maximal matching can achieve 100% throughput. S.-T. Chuang, A. Goel, N. McKeown, and B. Prabhakarm, “Matching Output Queueing with a Combined Input Output Queued Switch”, Proceedings of INFOCOM,1998. I.e., does as well as a switch with Nx speedup.

17 17 Combined Input-Output Queuing Advantages –Easy to build 100% can be achieved with limited speedup Disadvantages –Harder to design algorithms Two congestion points Flow control at destination input interfacesoutput interfaces Crossbar

18 18 Solution: Virtual Output Queues Maintain N virtual queues at each input – one per output Output 1 Output 2 Output 3 Input 1 Input 2 Input 3 N. McKeown, A. Mekkittikul, V. Anantharam, and J. Walrand, “Achieving 100% Throughput in an Input-Queued Switch,” IEEE Transactions on Communications, Vol. 47, No. 8, August 1999, pp. 1260-1267.

19 19 Router Components and Functions Route processor –Routing –Installing forwarding tables –Management Line cards –Packet processing and classification –Packet forwarding Switched bus (“Crossbar”) –Scheduling

20 20 Crossbar Switching Conceptually: N inputs, N outputs –Actually, inputs are also outputs In each timeslot, one-to-one mapping between inputs and outputs. Goal: Maximal matching L 11 (n) L N1 (n) Traffic DemandsBipartite Match Maximum Weight Match

21 21 Early Crossbar Scheduling Algorithm Wavefront algorithm Problems: Fairness, speed, …

22 22 Alternatives to the Wavefront Scheduler PIM: Parallel Iterative Matching –Request: Each input sends requests to all outputs for which it has packets –Grant: Output selects an input at random and grants –Accept: Input selects from its received grants Problem: Matching may not be maximal Solution: Run several times Problem: Matching may not be “fair” Solution: Grant/accept in round robin instead of random

23 23 Processing: Fast Path vs. Slow Path Optimize for common case –BBN router: 85 instructions for fast-path code –Fits entirely in L1 cache Non-common cases handled on slow path –Route cache misses –Errors (e.g., ICMP time exceeded) –IP options –Fragmented packets –Mullticast packets

24 24 Recent Trends: Programmability NetFPGA: 4-port interface card, plugs into PCI bus (Stanford) –Customizable forwarding –Appearance of many virtual interfaces (with VLAN tags) Programmability with Network processors (Washington U.) Line Cards PEs Switch

25 25 Scheduling and Fairness What is an appropriate definition of fairness? –One notion: Max-min fairness –Disadvantage: Compromises throughput Max-min fairness gives priority to low data rates/small values Is it guaranteed to exist? Is it unique?

26 26 Max-Min Fairness A flow rate x is max-min fair if any rate x cannot be increased without decreasing some y which is smaller than or equal to x. How to share equally with different resource demands –small users will get all they want –large users will evenly split the rest More formally, perform this procedure: –resource allocated to customers in order of increasing demand –no customer receives more than requested –customers with unsatisfied demands split the remaining resource

27 27 Example Demands: 2, 2.6, 4, 5; capacity: 10 –10/4 = 2.5 –Problem: 1st user needs only 2; excess of 0.5, Distribute among 3, so 0.5/3=0.167 –now we have allocs of [2, 2.67, 2.67, 2.67], –leaving an excess of 0.07 for cust #2 –divide that in two, gets [2, 2.6, 2.7, 2.7] Maximizes the minimum share to each customer whose demand is not fully serviced

28 28 How to Achieve Max-Min Fairness Take 1: Round-Robin –Problem: Packets may have different sizes Take 2: Bit-by-Bit Round Robin –Problem: Feasibility Take 3: Fair Queuing –Service packets according to soonest “finishing time” Adding QoS: Add weights to the queues…

29 29 Why QoS? Internet currently provides one single class of “best-effort” service –No assurances about delivery Existing applications are elastic –Tolerate delays and losses –Can adapt to congestion Future “real-time” applications may be inelastic

30 30 IP Address Lookup Challenges: 1.Longest-prefix match (not exact). 2.Tables are large and growing. 3.Lookups must be fast.

31 31 IP Lookups find Longest Prefixes 128.9.16.0/21128.9.172.0/21 128.9.176.0/24 0 2 32 -1 128.9.0.0/16 142.12.0.0/19 65.0.0.0/8 128.9.16.14 Routing lookup: Find the longest matching prefix (aka the most specific route) among all prefixes that match the destination address.

32 32 IP Address Lookup Challenges: 1.Longest-prefix match (not exact). 2.Tables are large and growing. 3.Lookups must be fast.

33 33 Address Tables are Large

34 34 IP Address Lookup Challenges: 1.Longest-prefix match (not exact). 2.Tables are large and growing. 3.Lookups must be fast.

35 35 Lookups Must be Fast 12540Gb/s2003 31.2510Gb/s2001 7.812.5Gb/s1999 1.94622Mb/s1997 40B packets (Mpkt/s) LineYear OC-12 OC-48 OC-192 OC-768 Still pretty rare outside of research networks Cisco CRS-1 1-Port OC-768C (Line rate: 42.1 Gb/s)

36 36 IP Address Lookup: Binary Tries Example Prefixes: a) 00001 b) 00010 c) 00011 d) 001 e) 0101 f) 011 g) 100 h) 1010 i) 1100 j) 11110000 e f g h i j 01 a bc d

37 37 Example Prefixes a) 00001 b) 00010 c) 00011 d) 001 e) 0101 f) 011 g) 100 h) 1010 i) 1100 j) 11110000 e f g h i j Skip 5 1000 01 a bc d IP Address Lookup: Patricia Trie Problem: Lots of (slow) memory lookups

38 38 Address Lookup: Direct Trie When pipelined, one lookup per memory access Inefficient use of memory 0000……00001111……1111 02 24 -1 24 bits 8 bits 0 2 8 -1

39 39 Faster LPM: Alternatives Content addressable memory (CAM) –Hardware-based route lookup –Input = tag, output = value –Requires exact match with tag Multiple cycles (1 per prefix) with single CAM Multiple CAMs (1 per prefix) searched in parallel –Ternary CAM (0,1,don’t care) values in tag match Priority (i.e., longest prefix) by order of entries Historically, this approach has not been very economical.

40 40 Faster Lookup: Alternatives Caching –Packet trains exhibit temporal locality –Many packets to same destination Cisco Express Forwarding

41 41 IP Address Lookup: Summary Lookup limited by memory bandwidth. Lookup uses high-degree trie. State of the art: 10Gb/s line rate. Scales to: 40Gb/s line rate.

42 42 Fourth-Generation: Collapse the POP High Reliability and Scalability enable “vertical” POP simplification Reduces CapEx, Operational cost Increases network stability

43 43 Fourth-Generation Routers Switch Linecards Limit today ~2.5Tb/s  Electronics  Scheduler scales <2x every 18 months  Opto-electronic conversion

44 44 In Out WAN Linecard In WAN Multi-rack routers Out Switch fabric

45 45 Future: 100Tb/s Optical Router Arbitration 40Gb/s OpticalSwitch Line termination IP packet processing Packet buffering Line termination IP packet processing Packet buffering Electronic Linecard #1 Electronic Linecard #1 Electronic Linecard #625 Electronic Linecard #625 Request Grant 160- 320Gb/s 160Gb/s 160- 320Gb/s (100Tb/s = 625 * 160Gb/s) McKeown et al., Scaling Internet Routers Using Optics, ACM SIGCOMM 2003

46 46 Challenges with Optical Switching Mis-sequenced packets Pathological traffic patterns Rapidly configuring switch fabric Failing components

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