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148 lines
6.1 KiB
Plaintext
148 lines
6.1 KiB
Plaintext
Filename: 151-path-selection-improvements.txt
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Title: Improving Tor Path Selection
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Author: Fallon Chen, Mike Perry
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Created: 5-Jul-2008
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Status: Finished
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Overview
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The performance of paths selected can be improved by adjusting the
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CircuitBuildTimeout and avoiding failing guard nodes. This proposal
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describes a method of tracking buildtime statistics at the client, and
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using those statistics to adjust the CircuitBuildTimeout.
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Motivation
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Tor's performance can be improved by excluding those circuits that
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have long buildtimes (and by extension, high latency). For those Tor
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users who require better performance and have lower requirements for
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anonymity, this would be a very useful option to have.
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Implementation
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Gathering Build Times
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Circuit build times are stored in the circular array
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'circuit_build_times' consisting of uint32_t elements as milliseconds.
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The total size of this array is based on the number of circuits
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it takes to converge on a good fit of the long term distribution of
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the circuit builds for a fixed link. We do not want this value to be
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too large, because it will make it difficult for clients to adapt to
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moving between different links.
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From our observations, the minimum value for a reasonable fit appears
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to be on the order of 500 (MIN_CIRCUITS_TO_OBSERVE). However, to keep
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a good fit over the long term, we store 5000 most recent circuits in
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the array (NCIRCUITS_TO_OBSERVE).
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The Tor client will build test circuits at a rate of one per
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minute (BUILD_TIMES_TEST_FREQUENCY) up to the point of
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MIN_CIRCUITS_TO_OBSERVE. This allows a fresh Tor to have
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a CircuitBuildTimeout estimated within 8 hours after install,
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upgrade, or network change (see below).
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Long Term Storage
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The long-term storage representation is implemented by storing a
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histogram with BUILDTIME_BIN_WIDTH millisecond buckets (default 50) when
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writing out the statistics to disk. The format this takes in the
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state file is 'CircuitBuildTime <bin-ms> <count>', with the total
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specified as 'TotalBuildTimes <total>'
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Example:
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TotalBuildTimes 100
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CircuitBuildTimeBin 25 50
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CircuitBuildTimeBin 75 25
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CircuitBuildTimeBin 125 13
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...
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Reading the histogram in will entail inserting <count> values
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into the circuit_build_times array each with the value of
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<bin-ms> milliseconds. In order to evenly distribute the values
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in the circular array, the Fisher-Yates shuffle will be performed
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after reading values from the bins.
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Learning the CircuitBuildTimeout
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Based on studies of build times, we found that the distribution of
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circuit buildtimes appears to be a Frechet distribution. However,
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estimators and quantile functions of the Frechet distribution are
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difficult to work with and slow to converge. So instead, since we
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are only interested in the accuracy of the tail, we approximate
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the tail of the distribution with a Pareto curve starting at
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the mode of the circuit build time sample set.
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We will calculate the parameters for a Pareto distribution
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fitting the data using the estimators at
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http://en.wikipedia.org/wiki/Pareto_distribution#Parameter_estimation.
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The timeout itself is calculated by using the Quartile function (the
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inverted CDF) to give us the value on the CDF such that
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BUILDTIME_PERCENT_CUTOFF (80%) of the mass of the distribution is
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below the timeout value.
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Thus, we expect that the Tor client will accept the fastest 80% of
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the total number of paths on the network.
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Detecting Changing Network Conditions
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We attempt to detect both network connectivity loss and drastic
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changes in the timeout characteristics.
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We assume that we've had network connectivity loss if 3 circuits
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timeout and we've received no cells or TLS handshakes since those
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circuits began. We then set the timeout to 60 seconds and stop
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counting timeouts.
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If 3 more circuits timeout and the network still has not been
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live within this new 60 second timeout window, we then discard
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the previous timeouts during this period from our history.
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To detect changing network conditions, we keep a history of
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the timeout or non-timeout status of the past RECENT_CIRCUITS (20)
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that successfully completed at least one hop. If more than 75%
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of these circuits timeout, we discard all buildtimes history,
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reset the timeout to 60, and then begin recomputing the timeout.
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Testing
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After circuit build times, storage, and learning are implemented,
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the resulting histogram should be checked for consistency by
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verifying it persists across successive Tor invocations where
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no circuits are built. In addition, we can also use the existing
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buildtime scripts to record build times, and verify that the histogram
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the python produces matches that which is output to the state file in Tor,
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and verify that the Pareto parameters and cutoff points also match.
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We will also verify that there are no unexpected large deviations from
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node selection, such as nodes from distant geographical locations being
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completely excluded.
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Dealing with Timeouts
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Timeouts should be counted as the expectation of the region of
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of the Pareto distribution beyond the cutoff. This is done by
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generating a random sample for each timeout at points on the
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curve beyond the current timeout cutoff.
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Future Work
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At some point, it may be desirable to change the cutoff from a
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single hard cutoff that destroys the circuit to a soft cutoff and
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a hard cutoff, where the soft cutoff merely triggers the building
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of a new circuit, and the hard cutoff triggers destruction of the
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circuit.
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It may also be beneficial to learn separate timeouts for each
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guard node, as they will have slightly different distributions.
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This will take longer to generate initial values though.
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Issues
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Impact on anonymity
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Since this follows a Pareto distribution, large reductions on the
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timeout can be achieved without cutting off a great number of the
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total paths. This will eliminate a great deal of the performance
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variation of Tor usage.
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