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CS 268: Lecture 8 (Router Support for Congestion Control) Ion Stoica February 19, 2002.

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Presentation on theme: "CS 268: Lecture 8 (Router Support for Congestion Control) Ion Stoica February 19, 2002."— Presentation transcript:

1 CS 268: Lecture 8 (Router Support for Congestion Control) Ion Stoica February 19, 2002

2 istoica@cs.berkeley.edu2 Router Support For Congestion Management  Traditional Internet -Congestion control mechanisms at end-systems, mainly implemented in TCP -Routers play little role  Router mechanisms affecting congestion management -Scheduling -Buffer management  Traditional routers -FIFO -Tail drop

3 istoica@cs.berkeley.edu3 Drawbacks of FIFO with Tail-drop  Buffer lock out by misbehaving flows  Synchronizing effect for multiple TCP flows  Burst or multiple consecutive packet drops -Bad for TCP fast recovery

4 istoica@cs.berkeley.edu4 FIFO Router with Two TCP Sessions

5 istoica@cs.berkeley.edu5 Random Early Detection (RED) Routers (Floyd & Fall 93]  Probabilistically discard packets  Probability is computed as a function of average queue length (why average?) -Use exponential averaging Discard Probability Average Queue Length 0 1 min_thmax_th

6 istoica@cs.berkeley.edu6 RED Advantages  Absorb burst better  Avoids synchronization  Signal end systems earlier

7 istoica@cs.berkeley.edu7 RED Router with Two TCP Sessions

8 istoica@cs.berkeley.edu8 Problems with RED  No protection: if a flow misbehaves it will hurt the other flows  Example: 1 UDP (10 Mbps) and 31 TCP’s sharing a 10 Mbps link UDP

9 istoica@cs.berkeley.edu9 Solution?  Round-robin among different flows [Nagle ‘87] -One queue per flow

10 istoica@cs.berkeley.edu10 Round-Robin Discussion  Advantages: protection among flows -Misbehaving flows will not affect the performance of well- behaving flows -FIFO does not have such a property  Disadvantages: -More complex than FIFO: per flow queue/state -Biased toward large packets – a flow receives service proportional to the number of packets (When is this bad?)

11 istoica@cs.berkeley.edu11 Solution?  Bit-by-bit round robin  Can you do this in practice?  No, packets cannot be preempted (why?)  …we can only approximate it

12 istoica@cs.berkeley.edu12 Fair Queueing (FQ) [DKS’89]  Define a fluid flow system: a system in which flows are served bit-by-bit  Then serve packets in the increasing order of their deadlines  Advantages -Each flow will receive exactly its fair rate  Note: -FQ achieves max-min fairness

13 istoica@cs.berkeley.edu13 Max-Min Fairness  Denote -C – link capacity -N – number of flows -r i – arrival rate  Max-min fair rate computation: 1.compute C/N 2.if there are flows i such that r i <= C/N, update C and N 3.if no, f = C/N; terminate 4.go to 1  A flow can receive at most the fair rate, i.e., min(f, r i )

14 istoica@cs.berkeley.edu14 Example  C = 10; r 1 = 8, r 2 = 6, r 3 = 2; N = 3  C/3 = 3.33  C = C – r3 = 8; N = 2  C/2 = 4; f = 4 8 6 2 4 4 2 f = 4 : min(8, 4) = 4 min(6, 4) = 4 min(2, 4) = 2 10

15 istoica@cs.berkeley.edu15 Alternate Way to Compute Fair Rate  If link congested, compute f such that 8 6 2 4 4 2 f = 4 : min(8, 4) = 4 min(6, 4) = 4 min(2, 4) = 2 10

16 istoica@cs.berkeley.edu16 Implementing Fair Queueing  Idea: serve packets in the order in which they would have finished transmission in the fluid flow system

17 istoica@cs.berkeley.edu17 Example 12345 1234 12 3 12 4 34 5 56 12132344 56 5 5 6 Flow 1 (arrival traffic) Flow 2 (arrival traffic) Service in fluid flow system Packet system time

18 istoica@cs.berkeley.edu18 System Virtual Time: V(t)  Measure service, instead of time  V(t) slope – rate at which every active flow receives service -C – link capacity -N(t) – number of active flows in fluid flow system at time t 12 3 12 4 34 5 56 Service in fluid flow system time V(t)

19 istoica@cs.berkeley.edu19 Fair Queueing Implementation  Define - - finishing time of packet k of flow i (in system virtual time reference system) - - arrival time of packet k of flow i - - length of packet k of flow i  The finishing time of packet k+1 of flow i is

20 istoica@cs.berkeley.edu20 “Weighted Fair Queueing” (WFQ)  What if we don't want exact fairness? -ex: file servers  Assign weight w i to each flow i  And change virtual finishing time

21 istoica@cs.berkeley.edu21 FQ Advantages  FQ protect well-behaved flows from ill-behaved flows  Example: 1 UDP (10 Mbps) and 31 TCP’s sharing a 10 Mbps link

22 istoica@cs.berkeley.edu22 Summary  FQ does not eliminate congestion  it just manages the congestion  You need both end-host congestion control and router support for congestion control -End-host congestion control to adapt -Router congestion control to protect/isolate  Don’t forget buffer management: you still need to drop in case of congestion. Which packet’s would you drop in FQ? -One possibility: packet from the longest queue

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