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Transport: TCP Manpreet Singh (Slides borrowed from various sources on the web)

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1 Transport: TCP Manpreet Singh (Slides borrowed from various sources on the web)

2 Announcements (1/2) Everybody needs to join the class mailing list...else I can't communicate class info. Check the class archives to see if someone else has picked the same lecture or TCP application We have a group of machines you can use for simulation (snoopy, linus, etc.). You need CSUG accounts to access these machines. We’ll dig up more machines for those who want to do kernel hacking.

3 Announcements (2/2) Need a volunteer to give the "post- modern" E2E lecture 9/9 (in class...). The non-research track students will have to do an initial demo by 11/9. Most of the functionality should be there Allows us to give feed back You time to do performance measurements.

4 Roadmap Why is TCP fair ? Loss-based congestion schemes Tahoe Reno NewReno Sack Delay-based congestion control (Vegas) Modeling TCP throughput Equation-based congestion control

5 The Desired Properties of a Congestion Control Scheme Efficiency (high utilization) Optimality (high throughput, utility) Fairness (resource sharing) Distributedness (no central knowledge for scalability) Convergence and stability (fast convergence after disturbance, low oscillation)

6 TCP Fairness Fairness goal: if N TCP sessions share same bottleneck link, each should get 1/N of link capacity TCP congestion avoidance: AIMD: additive increase, multiplicative decrease increase window by 1 per RTT decrease window by factor of 2 on loss event AIMD TCP connection 1 bottleneck router capacity R TCP connection 2

7 Why is TCP fair? Two competing sessions: Additive increase gives slope of 1, as throughout increases multiplicative decrease decreases throughput proportionally R R equal bandwidth share Connection 1 throughput Connection 2 throughput congestion avoidance: additive increase loss: decrease window by factor of 2 congestion avoidance: additive increase loss: decrease window by factor of 2

8 Loss vs Delay as signal ??? TCP oscillation Loss is a binary signal Delay is a multi-bit signal

9 Simulation-based Comparisons of Tahoe, Reno, and SACK TCP Kevin Fall Sally Floyd

10 Introduction SACK compared with Tahoe, Reno and New-Reno Simulations designed to highlight performance differences with and without SACK

11 Comparison Tahoe: Slow start, congestion avoidance and fast retransmit Reno: Tahoe + fast recovery New-Reno: Reno with modified fast recovery SACK: Reno + selective ACKs

12 TCP Slowstart exponential increase (per RTT) in window size (not so slow!) loss event: timeout (Tahoe TCP) and/or or three duplicate ACKs (Reno TCP) initialize: Congwin = 1 for (each segment ACKed) Congwin++ until (loss event OR CongWin > threshold) Slowstart algorithm (non-linear phase) Host A one segment RTT Host B time two segments four segments

13 TCP Congestion Avoidance /* slowstart is over */ /* Congwin > threshold */ Until (loss event) { every w segments ACKed: Congwin++ } threshold = Congwin/2 Congwin = 1 perform slowstart Congestion avoidance (linear phase) 1 1: TCP Reno skips slowstart (fast recovery) after three duplicate ACKs

14 Fast Retransmit Receiving small number of duplicate ACKs (3) signals packet loss Lost packet can be retransmitted before timeout This improves channel utilization

15 TCP/Reno Congestion Control Initially: cwnd = 1; ssthresh = infinite (64K); For each newly ACKed segment: if (cwnd < ssthresh) /* slow start*/ cwnd = cwnd + 1; else /* congestion avoidance; cwnd increases (approx.) by 1 per RTT */ cwnd += 1/cwnd; Triple-duplicate ACKs: /* multiplicative decrease */ cwnd = ssthresh = cwnd/2; Timeout: ssthresh = cwnd/2; cwnd = 1; (if already timed out, double timeout value; this is called exponential backoff)

16 TCP/Reno: Big Picture Time cwnd slow start congestion avoidance TD TD: Triple duplicate acknowledgements TO: Timeout TO ssthresh congestion avoidance TD congestion avoidance slow start congestion avoidance TD Tahoe + Fast Recovery

17 Fast Recovery Observation: Each duplicate ACK indicates some packet has left pipe Old cwnd New cwnd = (old cwnd)/2 Left edge fixed till ACK received Usable window increased by 1 for each duplicate ACK Packet lost

18 New-Reno extension New-Reno continues with fast recovery if a partial ACK is received Old cwnd New cwnd = (old cwnd)/2 Usable window increased by 1 for each duplicate ACK until ACK for LP is received Packet 1 lostPacket 2 lostLP: Last Packet sent before loss detection

19 Why use SACK? Without SACK sender has to use one of following retransmission strategies - Retransmit 1 dropped packet / RTT Reno, New-Reno - Retransmit packets that might have been successfully delivered Tahoe

20 SACK option [RFC2018] Ex: 2 nd segment dropped (each segment has 500 bytes) segackSack1 left Sack1 right 50005500 lost 6000550060006500

21 SACK Congestion Control (1/2) Conservative extensions to Reno Fast recovery algorithm modified Uses a variable called “pipe” to estimate outstanding data in the flow Rules for changing “pipe” variable + 1 when packet transmitted - 1 when dup ACK received

22 SACK Congestion Control (2/2) SACK sender tracks successfully sent packets using “scoreboard” structure Missing packets are retransmitted Similar to New-Reno in exiting from fast recovery – exits after all outstanding data at time of loss is ACked

23 Simulation Model used Three flows are setup from S1 to K1, 2 nd and 3 rd flows are used to change packet drop pattern of 1 st flow

24 One Packet Loss (1/2) Packet dropped Packet retransmitted Performs slow start

25 One Packet Loss (2/2) Packet dropped Packet retransmitted Performs fast recovery

26 Two Packet Loss (1/2) Packets dropped Packets retransmitted Performs slow start

27 Two Packet Loss (2/2) Packets dropped Packets retransmitted Performs fast recovery

28 Three Packet Losses (1/3) Packets dropped Packets retransmitted Has to wait for timeout

29 Three Packet Losses (2/3) Packets dropped Packets retransmitted No need for timeout Retransmits 1 pkt/RTT

30 Three Packet Losses (3/3) Packets dropped Packets retransmitted Retransmits more than 1 pkt /RTT

31 Observations Tahoe: Robust, performs slow start Reno: For > 2 losses, timeout is often needed New-Reno: Can avoid timeouts, but still cannot retransmit > 1 pkt/RTT SACK: Can retransmit > 1 pkt/RTT, thus recovers from losses faster

32 Conclusions SACK can improve TCP performance SACK can be used in high loss links too (Ex: Wireless) New-Reno demonstrates that certain problems of Reno can be avoided without SACK

33 Reno vs Vegas (Congestion Avoidance) Reno’s mechanism Characteristics uses the loss of segments as a signal reactive not proactive needs to create losses to find the available bandwidth example Threshold window congestion window send window

34 TCP Vegas Idea: source watches for some sign that router’s queue is building up and congestion will happen too; e.g., RTT grows sending rate flattens Congestion window Avg. source send rate Buffer space at router In shaded region we expect throughput to increase but it cannot increase beyond available bandwidth

35 Vegas’ approach Basic idea Vegas tries not to send at a rate that causes buffers to fill maintain the right amount of extra data based on changes in the estimated amount of extra data window size vs. throughput Keep the actual rate straying too far from the available rate (resulting in smooth congestion avoidance period)

36 Vegas Algorithm define a given connection’s BaseRTT BaseRTT = the minimum of all measured RTT expected throughput = WindowSize / BaseRTT Actual rate = Flight size / RTT Calculate the current Actual sending rate Compare Actual (A) to expected (E) and adjusts the window (linear increase or decrease) If (E-A) > beta, cwnd - - (congestion state) If (E-A) < alpha, cwnd++ (low utilization) When a loss is detected, reduce the window by a half

37 Algorithm (cont) Parameters   = 1 buffer   = 3 buffers Black line = actual rate Green line = expected rate Shaded = region between  and  Note: Linear decrease in Vegas does not violate AIMD since it Happens before packets loss

38 Comparison of Reno and Vegas (Retransmission) o Reno’s retransmission mechanism retransmission timeout based on RTT and variance estimates BSD-based : 500ms Fast Retransmit and Fast Recovery When the sender receives duplicate acks, it reduces the window size by a half and avoids timeout which causes retransmission with slow start If multiple drops occur, timeout and slow start will follow anyway. 19% increase in throughput

39 Vegas’ Retransmission reads and records the system clock each time a segment is sent when an ACK arrives, Vegas reads the clock again RTT calculation using this time and the timestamp recorded for the relevant segment uses this more accurate RTT estimate to decide to retransmit

40 Some fun topics to discuss…

41 Modeling TCP throughput Consider congestion avoidance only Time cwnd congestion avoidance TD ssthresh Assume one packet loss (loss event) per cycle Total packets send per cycle: 3W 2 /8 Thus p = 1/( 3W 2 /8) = 8/(3W 2 ) => bottleneck bandwidth W/2 W

42 Modeling TCP throughput… 1/throughput = c * sqrt(p) * RTT

43 Equation-based Congestion Control Don’t need reliability But still want to be friendly to the network What rate should we send the UDP traffic ? Use detailed TCP analysis to relate throughput to loss and RTT. Measure these values and then calculated appropriate throughput directly. Result is rate-based and equation-driven protocol called TFRC.

44 mulTCP Effect of AIMD parameters on the throughput of TCP

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