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New Packet Sampling Technique for Robust Flow Measurements

New Packet Sampling Technique for Robust Flow Measurements. Shigeo Shioda Department of Architecture and Urban Science Graduate School of Engineering, Chiba University. Objectives of traffic measurements. Short-term monitoring.

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New Packet Sampling Technique for Robust Flow Measurements

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  1. New Packet Sampling Technique for Robust Flow Measurements Shigeo Shioda Department of Architecture and Urban Science Graduate School of Engineering, Chiba University

  2. Objectives of traffic measurements • Short-term monitoring. • Detecting high volume traffic patterns (denial of service attacks). • Detecting unexpected or illegal packets. • Investigating of origins. • Long-term traffic engineering. • Rerouting traffic. • Upgrading selected links.

  3. Per-flow-base traffic measurement (1) • Just counting the number of packets or bytes is not sufficient; per-flow-base traffic measurement is necessary. • What is a flow? • Informally, a set of packets consisting logical communication between application processes running on different hosts. • Flow-level information could tell us who is now using the Internet.

  4. Per-flow-base traffic measurement (2) • Meaning of a flow. Flow 1 Flow 2

  5. Per-flow-base traffic measurement (3) • How we could distinguish flows. • Investigating headers of packets. • Classifying packets based on IP addresses, port numbers, and protocol ID. version HL TOS Total Length Identification Flags Fragment Offset IP Header TTL Protocol-ID Header Checksum Source Address Destination Address Source Port Destination Port TCP Header Sequence Number Acknowledgement Number

  6. Per-flow-base traffic measurement (4) • Flow-measurement procedure. • A Router maintains flow cache containing a flow record. • When a packet is seen, a router updates counters of the corresponding entry in the flow cache. Flow Cache # of packets # of bytes 2 3000 Flow 1: 1 0 1500 0 3 1 2 0 4500 3000 1500 0 Flow 2: Flow 3: 1 0 1500 0 Flow 1 packet Flow 2 packet Flow 3 packet

  7. Problems of flow measurements • Lack of scalability • Due to the rapid increase of the today’s line speed, the number of concurrent flows are increasing yearly. • Updating per-flow counter on a per-packet basis is already impossible with today’s line speed. • The gap between DRAM speeds and link speeds is increasing.

  8. Packet sampling • Updating a flow cache only for sampled packets. • Elephant flows would be detected even under the packet sampling. • Although many tiny (and unimportant) flows would be missed under the packet sampling, it does not matter in terms of network management. • Cisco’s Sampled NetFlow. • How to sample packets?

  9. t 0 Sampling Packets No Sampling Packets Fixed rate sampling • Definition • Choosing sampled packets at a fixed rate. • For example, taking one in every N packets. • Cisco’s Sampled NetFlow uses the fixed rate sampling. N = 5

  10. Shortcomings of the fixed rate sampling • The size of memory holding the flow cache strongly depends on the traffic load. • When DoS attacks are in progress, the memory would be rapidly consumed even if the sampling rate is low. • However, low sampling rate would yield large error in traffic measurement under the normal load. • It’s a hard decision for network operators to set the static sampling rate.

  11. tw 2 tw 3 tw 4 tw 0 Sampling Packets Non-sampled Packets Fixed period sampling • Definition • Choosing at most one packet to sample in every fixed-length period (called sampling window). • For example, taking one in every twsecond. • Our solution. Sampling Window

  12. Properties of fixed period sampling • The number of samplings during a second is bounded by 1/tw. • The number of entries in the flow cache is also bounded. • Sampling interval (tw)is easily determined based on the available memory or CPU for flow measurements.

  13. Fixed period sampling Fixed rate sampling Number of flow entrees Number of Entries Number of Entries Indianapolis-Kansas City U.S.-Japan link Time [s] Time [s] N=1000, tw=10ms

  14. Fixed period sampling Fixed rate sampling Number ofSampled Packets Time [s] Number of sampled packets Number of Sampled Packets Trace 1 Trace 2 Time [s] N=1000, tw=10ms

  15. Second Packet Sampling (1) • An arbitrary packet can be chosen to sample during each sampling window. • Which packets to be sampled? • The simplest (and the most natural) rule: the first packet sampling. • Intuitively the first packet sampling rule seems to work well, but it is not true. • We apply the second packet sampling.

  16. Sampling Packets Sampling Packets Non-sampled Packets Non-sampled Packets First packet sampling and second packet sampling • First packet sampling • Second packet sampling tw 2 tw 3 tw 4 tw 0 tw 2 tw 3 tw 4 tw 0

  17. Second Packet Sampling (2) • For example Flow 1: packets arrive periodically Flow 2: packets arrive according to a Poisson process We theoretically found that ・Under the first packet sampling rule, 63.2% of sampled packets are of flow 1. (strongly biased) ・Under the second packet sampling rule, 49.7% of sampled packets are of flow 1. (almost unbiased)

  18. Flow level traffic estimation • Sampling inevitably misses some information. • Some inference techniques are required to know the statistics of flow level traffic from the sampled packets. • Here, we focus on the flow rate estimation.

  19. Flow rate estimation (1) • Flow rate • Informally, the rate at which a flow sends data. • Formally, the ratio of the total bytes transferred to the flow duration. • Flow rate is an index for identifying vital flows, which often have significant impact on network performance. • Flow rate can be estimated from sampled packet streams.

  20. Flow rate estimation (2) • Real trace on a link between Indianapolis-Kansas City tw=10ms (0.15% packets were sampled) tw=1ms (1.5% packets were sampled) Actual Flow Rate [Mbps] Actual Flow Rate [Mbps] Estimated Flow Rate [Mbps] Estimated Flow Rate [Mbps]

  21. Flow rate estimation (3) • Real trace on a U.S. – Japan link tw=10ms (1.5% packets were sampled) tw=1ms (13.4% packets were sampled) Actual Flow Rate [Mbps] Actual Flow Rate [Mbps] Estimated Flow Rate [Mbps] Estimated Flow Rate [Mbps]

  22. Conclusion • Sampling techniques are indispensable to today’s traffic measurement in the Internet. • Fixed period sampling could bypass problems of the existing sampling technique (fixed rate sampling). • Fixed period sampling should be used together with the second packet sampling. • Flow rate can be estimated well with the fixed period sampling.

  23. Thank you.

  24. Flow rate estimation under first packet sampling Indianapolis-Kansas U.S.-Japan link Actual Flow Rate [Mbps] Actual Flow Rate [Mbps] Estimated Flow Rate [Mbps] Estimated Flow Rate [Mbps] N=1000, tw=10ms

  25. Bayesian Estimates (2) • tw=1ms Naive Estimator Bayesian Estimator Actual Flow Rate [Mbps] Actual Flow Rate [Mbps] Estimated Flow Rate [Mbps] Estimated Flow Rate [Mbps]

  26. Bayesian Estimates (1) • tw=10ms Naive Estimator Bayesian Estimator Actual Flow Rate [Mbps] Actual Flow Rate [Mbps] Estimated Flow Rate [Mbps] Estimated Flow Rate [Mbps]

  27. Objectives of traffic measurements (2) • QoS monitoring. • Measurement of QoS properties. • Validating service-level agreement. • Usage-based accounting. • Input to charge or billing.

  28. Shortcomings of the fixed rate sampling • Is there any sampling strategy which work even under massive DoS attacks? 350 300 250 Traffic 200 150 100 50 0 150 300 450 600 750 900 Time [s]

  29. Existing solutions to the fixed rate sampling • Sampling rate adaptation • First, the sampling rate is initialized to the maximum rate, at which the processor can operate. • Then, the sampling rate is dynamically adjusted based on the amount of consumed memory. • Adaptive NetFlow. • We propose another solution.

  30. Fixed period sampling (2) • Timeout transaction • Under the sampling measurements, one could not exactly know the beginning and end of flows. (SYN or FIN packets may not be sampled.) • Thus, flow entries that have not been seen during last N samplings are deleted from the flow cache. • Due to timeout transaction, the flow cache keeps only flows, whose packets have been detected at least once during last N samplings.

  31. Simulation experiments • The accuracy of the flow-rate estimation was investigated using real traffic data. • Two real traces (traffic data) were used . • Trace1: Traffic data measured by PMA Project on a backbone link between Indianapolis - Kansas City. • Trace 2: Traffic data measured by WIDE Project on a U.S. and Japan link published.

  32. Flow rate estimation (2) • Naïve estimation. • Estimation based on the sampling frequency. • Bayesian estimation. • If we know the probability density function of the flow rate as prior information, we could apply Bayesian estimator to improve the estimation accuracy.

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