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011b732436
Also mention rounding step.
179 lines
6.7 KiB
Plaintext
179 lines
6.7 KiB
Plaintext
Title: Computing Bandwidth Adjustments
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Filename: 161-computing-bandwidth-adjustments.txt
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Author: Mike Perry
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Created: 12-May-2009
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Target: 0.2.2.x
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Status: Open
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1. Motivation
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There is high variance in the performance of the Tor network. Despite
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our efforts to balance load evenly across the Tor nodes, some nodes are
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significantly slower and more overloaded than others.
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Proposal 160 describes how we can augment the directory authorities to
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vote on measured bandwidths for routers. This proposal describes what
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goes into the measuring process.
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2. Measurement Selection
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The general idea is to determine a load factor representing the ratio
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of the capacity of measured nodes to the rest of the network. This load
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factor could be computed from three potentially relevant statistics:
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circuit failure rates, circuit extend times, or stream capacity.
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Circuit failure rates and circuit extend times appear to be
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non-linearly proportional to node load. We've observed that the same
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nodes when scanned at US nighttime hours (when load is presumably
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lower) exhibit almost no circuit failure, and significantly faster
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extend times than when scanned during the day.
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Stream capacity, however, is much more uniform, even during US
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nighttime hours. Moreover, it is a more intuitive representation of
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node capacity, and also less dependent upon distance and latency
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if amortized over large stream fetches.
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3. Average Stream Bandwidth Calculation
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The average stream bandwidths are obtained by dividing the network into
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slices of 50 nodes each, grouped according to advertised node bandwidth.
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Two hop circuits are built using nodes from the same slice, and a large
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file is downloaded via these circuits. The file sizes are set based
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on node percentile rank as follows:
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0-10: 4M
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10-20: 2M
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20-30: 1M
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30-50: 512k
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50-75: 256k
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75-100: 128k
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These sizes are based on measurements performed during test scans.
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This process is repeated until each node has been chosen to participate
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in at least 5 circuits.
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4. Ratio Calculation
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The ratios are calculated by dividing each measured value by the
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network-wide average.
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5. Ratio Filtering
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After the base ratios are calculated, a second pass is performed
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to remove any streams with nodes of ratios less than X=0.5 from
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the results of other nodes. In addition, all outlying streams
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with capacity of one standard deviation below a node's average
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are also removed.
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The final ratio result will be the unfiltered ratio if it is
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close to 1.0, otherwise it will be the filtered ratio.
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6. Pseudocode for Ratio Calculation Algorithm
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Here is the complete pseudocode for the ratio algorithm:
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Slices = {S | S is 50 nodes of similar consensus capacity}
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for S in Slices:
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while exists node N in S with circ_chosen(N) < 7:
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fetch_slice_file(build_2hop_circuit(N, (exit in S)))
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for N in S:
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BW_measured(N) = MEAN(b | b is bandwidth of a stream through N)
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Bw_stddev(N) = STDDEV(b | b is bandwidth of a stream through N)
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Bw_avg(S) = MEAN(b | b = BW_measured(N) for all N in S)
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Normal_Routers(S) = {N | Bw_measured(N)/Bw_avg(S) > 0.5 }
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for N in S:
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Normal_Streams(N) =
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{stream via N | all nodes in stream not in {Normal_Routers(S)-N}
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and bandwidth > BW_measured(N)-Bw_stddev(N)}
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BW_Norm_measured(N) = MEAN(b | b is a bandwidth of Normal_Streams(N))
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Bw_net_avg(Slices) = MEAN(BW_measured(N) for all N in Slices)
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Bw_Norm_net_avg(Slices) = MEAN(BW_Norm_measured(N) for all N in Slices)
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for N in all Slices:
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Bw_net_ratio(N) = Bw_measured(N)/Bw_net_avg(Slices)
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Bw_Norm_net_ratio(N) = Bw_measured2(N)/Bw_Norm_net_avg(Slices)
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ResultRatio(N) = ClosestToOne(Bw_net_ratio(N), Bw_Norm_net_ratio(N))
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7. Security implications
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The ratio filtering will deal with cases of sabotage by dropping
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both very slow outliers in stream average calculations, as well
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as dropping streams that used very slow nodes from the calculation
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of other nodes.
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This scheme will not address nodes that try to game the system by
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providing better service to scanners. The scanners can be detected
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at the entry by IP address, and at the exit by the destination fetch
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IP.
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Measures can be taken to obfuscate and separate the scanners' source
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IP address from the directory authority IP address. For instance,
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scans can happen offsite and the results can be rsynced into the
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authorities. The destination server IP can also change.
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Neither of these methods are foolproof, but such nodes can already
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lie about their bandwidth to attract more traffic, so this solution
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does not set us back any in that regard.
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8. Parallelization
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Because each slice takes as long as 6 hours to complete, we will want
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to parallelize as much as possible. This will be done by concurrently
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running multiple scanners from each authority to deal with different
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segments of the network. Each scanner piece will continually loop
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over a portion of the network, outputting files of the form:
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node_id=<idhex> SP strm_bw=<BW_measured(N)> SP
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filt_bw=<BW_Norm_measured(N)> ns_bw=<CurrentConsensusBw(N)> NL
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The most recent file from each scanner will be periodically gathered
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by another script that uses them to produce network-wide averages
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and calculate ratios as per the algorithm in section 6. Because nodes
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may shift in capacity, they may appear in more than one slice and/or
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appear more than once in the file set. The line that yields a ratio
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closest to 1.0 will be chosen in this case.
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9. Integration with Proposal 160
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The final results will be produced for the voting mechanism
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described in Proposal 160 by multiplying the derived ratio by
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the average published consensus bandwidth during the course of the
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scan, and taking the weighted average with the previous consensus
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bandwidth:
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Bw_new = Round((Bw_current * Alpha + Bw_scan_avg*Bw_ratio)/(Alpha + 1))
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The Alpha parameter is a smoothing parameter intended to prevent
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rapid oscillation between loaded and unloaded conditions. It is
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currently fixed at 0.333.
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The Round() step consists of rounding to the 3 most significant figures
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in base10, and then rounding that result to the nearest 1000, with
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a minimum value of 1000.
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This will produce a new bandwidth value that will be output into a
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file consisting of lines of the form:
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node_id=<idhex> SP bw=<Bw_new> NL
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The first line of the file will contain a timestamp in UNIX time()
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seconds. This will be used by the authority to decide if the
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measured values are too old to use.
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This file can be either copied or rsynced into a directory readable
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by the directory authority.
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