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847 lines
36 KiB
Plaintext
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Tor Path Specification
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Roger Dingledine
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Nick Mathewson
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Note: This is an attempt to specify Tor as currently implemented. Future
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versions of Tor will implement improved algorithms.
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This document tries to cover how Tor chooses to build circuits and assign
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streams to circuits. Other implementations MAY take other approaches, but
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implementors should be aware of the anonymity and load-balancing implications
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of their choices.
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THIS SPEC ISN'T DONE YET.
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The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL
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NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and
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"OPTIONAL" in this document are to be interpreted as described in
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RFC 2119.
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1. General operation
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Tor begins building circuits as soon as it has enough directory
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information to do so (see section 5 of dir-spec.txt). Some circuits are
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built preemptively because we expect to need them later (for user
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traffic), and some are built because of immediate need (for user traffic
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that no current circuit can handle, for testing the network or our
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reachability, and so on).
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When a client application creates a new stream (by opening a SOCKS
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connection or launching a resolve request), we attach it to an appropriate
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open circuit if one exists, or wait if an appropriate circuit is
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in-progress. We launch a new circuit only
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if no current circuit can handle the request. We rotate circuits over
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time to avoid some profiling attacks.
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To build a circuit, we choose all the nodes we want to use, and then
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construct the circuit. Sometimes, when we want a circuit that ends at a
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given hop, and we have an appropriate unused circuit, we "cannibalize" the
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existing circuit and extend it to the new terminus.
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These processes are described in more detail below.
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This document describes Tor's automatic path selection logic only; path
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selection can be overridden by a controller (with the EXTENDCIRCUIT and
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ATTACHSTREAM commands). Paths constructed through these means may
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violate some constraints given below.
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1.1. Terminology
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A "path" is an ordered sequence of nodes, not yet built as a circuit.
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A "clean" circuit is one that has not yet been used for any traffic.
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A "fast" or "stable" or "valid" node is one that has the 'Fast' or
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'Stable' or 'Valid' flag
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set respectively, based on our current directory information. A "fast"
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or "stable" circuit is one consisting only of "fast" or "stable" nodes.
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In an "exit" circuit, the final node is chosen based on waiting stream
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requests if any, and in any case it avoids nodes with exit policy of
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"reject *:*". An "internal" circuit, on the other hand, is one where
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the final node is chosen just like a middle node (ignoring its exit
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policy).
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A "request" is a client-side stream or DNS resolve that needs to be
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served by a circuit.
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A "pending" circuit is one that we have started to build, but which has
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not yet completed.
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A circuit or path "supports" a request if it is okay to use the
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circuit/path to fulfill the request, according to the rules given below.
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A circuit or path "might support" a request if some aspect of the request
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is unknown (usually its target IP), but we believe the path probably
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supports the request according to the rules given below.
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1.1. A relay's bandwidth
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Old versions of Tor did not report bandwidths in network status
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documents, so clients had to learn them from the routers' advertised
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relay descriptors.
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For versions of Tor prior to 0.2.1.17-rc, everywhere below where we
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refer to a relay's "bandwidth", we mean its clipped advertised
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bandwidth, computed by taking the smaller of the 'rate' and
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'observed' arguments to the "bandwidth" element in the relay's
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descriptor. If a router's advertised bandwidth is greater than
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MAX_BELIEVABLE_BANDWIDTH (currently 10 MB/s), we clipped to that
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value.
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For more recent versions of Tor, we take the bandwidth value declared
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in the consensus, and fall back to the clipped advertised bandwidth
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only if the consensus does not have bandwidths listed.
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2. Building circuits
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2.1. When we build
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2.1.1. Clients build circuits preemptively
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When running as a client, Tor tries to maintain at least a certain
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number of clean circuits, so that new streams can be handled
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quickly. To increase the likelihood of success, Tor tries to
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predict what circuits will be useful by choosing from among nodes
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that support the ports we have used in the recent past (by default
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one hour). Specifically, on startup Tor tries to maintain one clean
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fast exit circuit that allows connections to port 80, and at least
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two fast clean stable internal circuits in case we get a resolve
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request or hidden service request (at least three if we _run_ a
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hidden service).
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After that, Tor will adapt the circuits that it preemptively builds
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based on the requests it sees from the user: it tries to have two fast
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clean exit circuits available for every port seen within the past hour
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(each circuit can be adequate for many predicted ports -- it doesn't
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need two separate circuits for each port), and it tries to have the
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above internal circuits available if we've seen resolves or hidden
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service activity within the past hour. If there are 12 or more clean
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circuits open, it doesn't open more even if it has more predictions.
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Only stable circuits can "cover" a port that is listed in the
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LongLivedPorts config option. Similarly, hidden service requests
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to ports listed in LongLivedPorts make us create stable internal
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circuits.
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Note that if there are no requests from the user for an hour, Tor
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will predict no use and build no preemptive circuits.
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The Tor client SHOULD NOT store its list of predicted requests to a
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persistent medium.
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2.1.2. Clients build circuits on demand
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Additionally, when a client request exists that no circuit (built or
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pending) might support, we create a new circuit to support the request.
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For exit connections, we pick an exit node that will handle the
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most pending requests (choosing arbitrarily among ties), launch a
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circuit to end there, and repeat until every unattached request
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might be supported by a pending or built circuit. For internal
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circuits, we pick an arbitrary acceptable path, repeating as needed.
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In some cases we can reuse an already established circuit if it's
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clean; see Section 2.3 (cannibalizing circuits) for details.
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2.1.3. Relays build circuits for testing reachability and bandwidth
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Tor relays test reachability of their ORPort once they have
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successfully built a circuit (on startup and whenever their IP address
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changes). They build an ordinary fast internal circuit with themselves
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as the last hop. As soon as any testing circuit succeeds, the Tor
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relay decides it's reachable and is willing to publish a descriptor.
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We launch multiple testing circuits (one at a time), until we
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have NUM_PARALLEL_TESTING_CIRC (4) such circuits open. Then we
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do a "bandwidth test" by sending a certain number of relay drop
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cells down each circuit: BandwidthRate * 10 / CELL_NETWORK_SIZE
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total cells divided across the four circuits, but never more than
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CIRCWINDOW_START (1000) cells total. This exercises both outgoing and
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incoming bandwidth, and helps to jumpstart the observed bandwidth
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(see dir-spec.txt).
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Tor relays also test reachability of their DirPort once they have
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established a circuit, but they use an ordinary exit circuit for
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this purpose.
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2.1.4. Hidden-service circuits
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See section 4 below.
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2.1.5. Rate limiting of failed circuits
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If we fail to build a circuit N times in a X second period (see Section
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2.3 for how this works), we stop building circuits until the X seconds
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have elapsed.
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XXXX
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2.1.6. When to tear down circuits
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XXXX
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2.2. Path selection and constraints
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We choose the path for each new circuit before we build it. We choose the
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exit node first, followed by the other nodes in the circuit. All paths
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we generate obey the following constraints:
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- We do not choose the same router twice for the same path.
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- We do not choose any router in the same family as another in the same
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path.
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- We do not choose more than one router in a given /16 subnet
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(unless EnforceDistinctSubnets is 0).
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- We don't choose any non-running or non-valid router unless we have
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been configured to do so. By default, we are configured to allow
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non-valid routers in "middle" and "rendezvous" positions.
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- If we're using Guard nodes, the first node must be a Guard (see 5
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below)
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- XXXX Choosing the length
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For "fast" circuits, we only choose nodes with the Fast flag. For
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non-"fast" circuits, all nodes are eligible.
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For all circuits, we weight node selection according to router bandwidth.
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We also weight the bandwidth of Exit and Guard flagged nodes depending on
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the fraction of total bandwidth that they make up and depending upon the
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position they are being selected for.
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These weights are published in the consensus, and are computed as described
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in Section 3.4.3 of dir-spec.txt. They are:
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Wgg - Weight for Guard-flagged nodes in the guard position
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Wgm - Weight for non-flagged nodes in the guard Position
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Wgd - Weight for Guard+Exit-flagged nodes in the guard Position
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Wmg - Weight for Guard-flagged nodes in the middle Position
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Wmm - Weight for non-flagged nodes in the middle Position
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Wme - Weight for Exit-flagged nodes in the middle Position
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Wmd - Weight for Guard+Exit flagged nodes in the middle Position
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Weg - Weight for Guard flagged nodes in the exit Position
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Wem - Weight for non-flagged nodes in the exit Position
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Wee - Weight for Exit-flagged nodes in the exit Position
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Wed - Weight for Guard+Exit-flagged nodes in the exit Position
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Wgb - Weight for BEGIN_DIR-supporting Guard-flagged nodes
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Wmb - Weight for BEGIN_DIR-supporting non-flagged nodes
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Web - Weight for BEGIN_DIR-supporting Exit-flagged nodes
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Wdb - Weight for BEGIN_DIR-supporting Guard+Exit-flagged nodes
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Wbg - Weight for Guard+Exit-flagged nodes for BEGIN_DIR requests
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Wbm - Weight for Guard+Exit-flagged nodes for BEGIN_DIR requests
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Wbe - Weight for Guard+Exit-flagged nodes for BEGIN_DIR requests
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Wbd - Weight for Guard+Exit-flagged nodes for BEGIN_DIR requests
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Additionally, we may be building circuits with one or more requests in
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mind. Each kind of request puts certain constraints on paths:
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- All service-side introduction circuits and all rendezvous paths
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should be Stable.
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- All connection requests for connections that we think will need to
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stay open a long time require Stable circuits. Currently, Tor decides
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this by examining the request's target port, and comparing it to a
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list of "long-lived" ports. (Default: 21, 22, 706, 1863, 5050,
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5190, 5222, 5223, 6667, 6697, 8300.)
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- DNS resolves require an exit node whose exit policy is not equivalent
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to "reject *:*".
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- Reverse DNS resolves require a version of Tor with advertised eventdns
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support (available in Tor 0.1.2.1-alpha-dev and later).
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- All connection requests require an exit node whose exit policy
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supports their target address and port (if known), or which "might
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support it" (if the address isn't known). See 2.2.1.
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- Rules for Fast? XXXXX
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2.2.1. Choosing an exit
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If we know what IP address we want to connect to or resolve, we can
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trivially tell whether a given router will support it by simulating
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its declared exit policy.
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Because we often connect to addresses of the form hostname:port, we do not
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always know the target IP address when we select an exit node. In these
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cases, we need to pick an exit node that "might support" connections to a
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given address port with an unknown address. An exit node "might support"
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such a connection if any clause that accepts any connections to that port
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precedes all clauses (if any) that reject all connections to that port.
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Unless requested to do so by the user, we never choose an exit node
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flagged as "BadExit" by more than half of the authorities who advertise
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themselves as listing bad exits.
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2.2.2. User configuration
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Users can alter the default behavior for path selection with configuration
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options.
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- If "ExitNodes" is provided, then every request requires an exit node on
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the ExitNodes list. (If a request is supported by no nodes on that list,
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and StrictExitNodes is false, then Tor treats that request as if
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ExitNodes were not provided.)
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- "EntryNodes" and "StrictEntryNodes" behave analogously.
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- If a user tries to connect to or resolve a hostname of the form
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<target>.<servername>.exit, the request is rewritten to a request for
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<target>, and the request is only supported by the exit whose nickname
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or fingerprint is <servername>.
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2.3. Cannibalizing circuits
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If we need a circuit and have a clean one already established, in
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some cases we can adapt the clean circuit for our new
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purpose. Specifically,
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For hidden service interactions, we can "cannibalize" a clean internal
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circuit if one is available, so we don't need to build those circuits
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from scratch on demand.
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We can also cannibalize clean circuits when the client asks to exit
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at a given node -- either via the ".exit" notation or because the
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destination is running at the same location as an exit node.
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2.4. Learning when to give up ("timeout") on circuit construction
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Since version 0.2.2.8-alpha, Tor attempts to learn when to give up on
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circuits based on network conditions.
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2.4.1 Distribution choice and parameter estimation
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Based on studies of build times, we found that the distribution of
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circuit build times 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.
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We calculate the parameters for a Pareto distribution fitting the data
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using the estimators in equation 4 from:
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http://portal.acm.org/citation.cfm?id=1647962.1648139
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This is:
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alpha_m = s/(ln(U(X)/Xm^n))
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where s is the total number of completed circuits we have seen, and
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U(X) = x_max^u * Prod_s{x_i}
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with x_i as our i-th completed circuit time, x_max as the longest
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completed circuit build time we have yet observed, u as the
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number of unobserved timeouts that have no exact value recorded,
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and n as u+s, the total number of circuits that either timeout or
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complete.
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Using log laws, we compute this as the sum of logs to avoid
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overflow and ln(1.0+epsilon) precision issues:
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alpha_m = s/(u*ln(x_max) + Sum_s{ln(x_i)} - n*ln(Xm))
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This estimator is closely related to the parameters present in:
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http://en.wikipedia.org/wiki/Pareto_distribution#Parameter_estimation
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except they are adjusted to handle the fact that our samples are
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right-censored at the timeout cutoff.
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Additionally, because this is not a true Pareto distribution, we alter
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how Xm is computed. The Xm parameter is computed as the midpoint of the most
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frequently occurring 50ms histogram bin, until the point where 1000
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circuits are recorded. After this point, the weighted average of the top
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'cbtnummodes' (default: 3) midpoint modes is used as Xm. All times below
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this value are counted as having the midpoint value of this weighted average
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bin.
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The timeout itself is calculated by using the Pareto Quantile function (the
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inverted CDF) to give us the value on the CDF such that 80% of the mass
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of the distribution is 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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2.4.2. How much data to record
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From our observations, the minimum number of circuit build times for a
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reasonable fit appears to be on the order of 100. However, to keep a
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good fit over the long term, we store 1000 most recent circuit build times
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in a circular array.
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The Tor client should build test circuits at a rate of one per
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minute up until 100 circuits are built. This allows a fresh Tor to have
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a CircuitBuildTimeout estimated within 1.5 hours after install,
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upgrade, or network change (see below).
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Timeouts are stored on disk in a histogram of 50ms bin width, the same
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width used to calculate the Xm value above. This histogram must be shuffled
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after being read from disk, to preserve a proper expiration of old values
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after restart.
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2.4.3. How to record timeouts
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Circuits that pass the timeout threshold should be allowed to continue
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building until a time corresponding to the point 'cbtclosequantile'
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(default 95) on the Pareto curve, or 60 seconds, whichever is greater.
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The actual completion times for these circuits should be recorded.
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Implementations should completely abandon a circuit and record a value
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as an 'unknown' timeout if the total build time exceeds this threshold.
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The reason for this is that right-censored pareto estimators begin to lose
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their accuracy if more than approximately 5% of the values are censored.
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Since we wish to set the cutoff at 20%, we must allow circuits to continue
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building past this cutoff point up to the 95th percentile.
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2.4.4. 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 temporarily set the timeout to 60 seconds
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and stop 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 20 circuits that
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successfully completed at least one hop. If more than 90% of
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these circuits timeout, we discard all buildtimes history, reset
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the timeout to 60, and then begin recomputing the timeout.
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If the timeout was already 60 or higher, we double the timeout.
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2.4.5. Consensus parameters governing behavior
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Clients that implement circuit build timeout learning should obey the
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following consensus parameters that govern behavior, in order to allow
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us to handle bugs or other emergent behaviors due to client circuit
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construction. If these parameters are not present in the consensus,
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the listed default values should be used instead.
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cbtdisabled
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Default: 0
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Min: 0
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Max: 1
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Effect: If 1, all CircuitBuildTime learning code should be
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disabled and history should be discarded. For use in
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emergency situations only.
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cbtnummodes
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Default: 3
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Min: 1
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Max: 20
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Effect: This value governs how many modes to use in the weighted
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average calculation of Pareto parameter Xm. A value of 3 introduces
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some bias (2-5% of CDF) under ideal conditions, but allows for better
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performance in the event that a client chooses guard nodes of radically
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different performance characteristics.
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cbtrecentcount
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Default: 20
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Min: 3
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Max: 1000
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Effect: This is the number of circuit build times to keep track of
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for the following option.
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cbtmaxtimeouts
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Default: 18
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Min: 3
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Max: 10000
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Effect: When this many timeouts happen in the last 'cbtrecentcount'
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circuit attempts, the client should discard all of its
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history and begin learning a fresh timeout value.
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cbtmincircs
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Default: 100
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Min: 1
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Max: 10000
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Effect: This is the minimum number of circuits to build before
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computing a timeout.
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cbtquantile
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Default: 80
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Min: 10
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Max: 99
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Effect: This is the position on the quantile curve to use to set the
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timeout value. It is a percent (10-99).
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cbtclosequantile
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Default: 95
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Min: Value of cbtquantile parameter
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Max: 99
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Effect: This is the position on the quantile curve to use to set the
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timeout value to use to actually close circuits. It is a
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percent (0-99).
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cbttestfreq
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Default: 60
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Min: 1
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Max: 2147483647 (INT32_MAX)
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Effect: Describes how often in seconds to build a test circuit to
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gather timeout values. Only applies if less than 'cbtmincircs'
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have been recorded.
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cbtmintimeout
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Default: 2000
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|
Min: 500
|
|
Max: 2147483647 (INT32_MAX)
|
|
Effect: This is the minimum allowed timeout value in milliseconds.
|
|
The minimum is to prevent rounding to 0 (we only check once
|
|
per second).
|
|
|
|
cbtinitialtimeout
|
|
Default: 60000
|
|
Min: Value of cbtmintimeout
|
|
Max: 2147483647 (INT32_MAX)
|
|
Effect: This is the timeout value to use before computing a timeout,
|
|
in milliseconds.
|
|
|
|
|
|
2.5. Handling failure
|
|
|
|
If an attempt to extend a circuit fails (either because the first create
|
|
failed or a subsequent extend failed) then the circuit is torn down and is
|
|
no longer pending. (XXXX really?) Requests that might have been
|
|
supported by the pending circuit thus become unsupported, and a new
|
|
circuit needs to be constructed.
|
|
|
|
If a stream "begin" attempt fails with an EXITPOLICY error, we
|
|
decide that the exit node's exit policy is not correctly advertised,
|
|
so we treat the exit node as if it were a non-exit until we retrieve
|
|
a fresh descriptor for it.
|
|
|
|
Excessive amounts of either type of failure can indicate an
|
|
attack on anonymity. See section 7 for how excessive failure is handled.
|
|
|
|
3. Attaching streams to circuits
|
|
|
|
When a circuit that might support a request is built, Tor tries to attach
|
|
the request's stream to the circuit and sends a BEGIN, BEGIN_DIR,
|
|
or RESOLVE relay
|
|
cell as appropriate. If the request completes unsuccessfully, Tor
|
|
considers the reason given in the CLOSE relay cell. [XXX yes, and?]
|
|
|
|
|
|
After a request has remained unattached for SocksTimeout (2 minutes
|
|
by default), Tor abandons the attempt and signals an error to the
|
|
client as appropriate (e.g., by closing the SOCKS connection).
|
|
|
|
XXX Timeouts and when Tor auto-retries.
|
|
* What stream-end-reasons are appropriate for retrying.
|
|
|
|
If no reply to BEGIN/RESOLVE, then the stream will timeout and fail.
|
|
|
|
4. Hidden-service related circuits
|
|
|
|
XXX Tracking expected hidden service use (client-side and hidserv-side)
|
|
|
|
5. Guard nodes
|
|
|
|
We use Guard nodes (also called "helper nodes" in the literature) to
|
|
prevent certain profiling attacks. Here's the risk: if we choose entry and
|
|
exit nodes at random, and an attacker controls C out of N relays
|
|
(ignoring bandwidth), then the
|
|
attacker will control the entry and exit node of any given circuit with
|
|
probability (C/N)^2. But as we make many different circuits over time,
|
|
then the probability that the attacker will see a sample of about (C/N)^2
|
|
of our traffic goes to 1. Since statistical sampling works, the attacker
|
|
can be sure of learning a profile of our behavior.
|
|
|
|
If, on the other hand, we picked an entry node and held it fixed, we would
|
|
have probability C/N of choosing a bad entry and being profiled, and
|
|
probability (N-C)/N of choosing a good entry and not being profiled.
|
|
|
|
When guard nodes are enabled, Tor maintains an ordered list of entry nodes
|
|
as our chosen guards, and stores this list persistently to disk. If a Guard
|
|
node becomes unusable, rather than replacing it, Tor adds new guards to the
|
|
end of the list. When choosing the first hop of a circuit, Tor
|
|
chooses at
|
|
random from among the first NumEntryGuards (default 3) usable guards on the
|
|
list. If there are not at least 2 usable guards on the list, Tor adds
|
|
routers until there are, or until there are no more usable routers to add.
|
|
|
|
A guard is unusable if any of the following hold:
|
|
- it is not marked as a Guard by the networkstatuses,
|
|
- it is not marked Valid (and the user hasn't set AllowInvalid entry)
|
|
- it is not marked Running
|
|
- Tor couldn't reach it the last time it tried to connect
|
|
|
|
A guard is unusable for a particular circuit if any of the rules for path
|
|
selection in 2.2 are not met. In particular, if the circuit is "fast"
|
|
and the guard is not Fast, or if the circuit is "stable" and the guard is
|
|
not Stable, or if the guard has already been chosen as the exit node in
|
|
that circuit, Tor can't use it as a guard node for that circuit.
|
|
|
|
If the guard is excluded because of its status in the networkstatuses for
|
|
over 30 days, Tor removes it from the list entirely, preserving order.
|
|
|
|
If Tor fails to connect to an otherwise usable guard, it retries
|
|
periodically: every hour for six hours, every 4 hours for 3 days, every
|
|
18 hours for a week, and every 36 hours thereafter. Additionally, Tor
|
|
retries unreachable guards the first time it adds a new guard to the list,
|
|
since it is possible that the old guards were only marked as unreachable
|
|
because the network was unreachable or down.
|
|
|
|
Tor does not add a guard persistently to the list until the first time we
|
|
have connected to it successfully.
|
|
|
|
6. Router descriptor purposes
|
|
|
|
There are currently three "purposes" supported for router descriptors:
|
|
general, controller, and bridge. Most descriptors are of type general
|
|
-- these are the ones listed in the consensus, and the ones fetched
|
|
and used in normal cases.
|
|
|
|
Controller-purpose descriptors are those delivered by the controller
|
|
and labelled as such: they will be kept around (and expire like
|
|
normal descriptors), and they can be used by the controller in its
|
|
CIRCUITEXTEND commands. Otherwise they are ignored by Tor when it
|
|
chooses paths.
|
|
|
|
Bridge-purpose descriptors are for routers that are used as bridges. See
|
|
doc/design-paper/blocking.pdf for more design explanation, or proposal
|
|
125 for specific details. Currently bridge descriptors are used in place
|
|
of normal entry guards, for Tor clients that have UseBridges enabled.
|
|
|
|
7. Detecting route manipulation by Guard nodes (Path Bias)
|
|
|
|
The Path Bias defense is designed to defend against a type of route
|
|
capture where malicious Guard nodes deliberately fail or choke circuits
|
|
that extend to non-colluding Exit nodes to maximize their network
|
|
utilization in favor of carrying only compromised traffic.
|
|
|
|
In the extreme, the attack allows an adversary that carries c/n
|
|
of the network capacity to deanonymize c/n of the network
|
|
connections, breaking the O((c/n)^2) property of Tor's original
|
|
threat model. It also allows targeted attacks aimed at monitoring
|
|
the activity of specific users, bridges, or Guard nodes.
|
|
|
|
There are two points where path selection can be manipulated:
|
|
during construction, and during usage. Circuit construction
|
|
can be manipulated by inducing circuit failures during circuit
|
|
extend steps, which causes the Tor client to transparently retry
|
|
the circuit construction with a new path. Circuit usage can be
|
|
manipulated by abusing the stream retry features of Tor (for
|
|
example by withholding stream attempt responses from the client
|
|
until the stream timeout has expired), at which point the tor client
|
|
will also transparently retry the stream on a new path.
|
|
|
|
The defense as deployed therefore makes two independent sets of
|
|
measurements of successful path use: one during circuit construction,
|
|
and one during circuit usage.
|
|
|
|
The intended behavior is for clients to ultimately disable the use
|
|
of Guards responsible for excessive circuit failure of either type
|
|
(see section 7.4); however known issues with the Tor network currently
|
|
restrict the defense to being informational only at this stage (see
|
|
section 7.5).
|
|
|
|
7.1. Measuring path construction success rates
|
|
|
|
Clients maintain two counts for each of their guards: a count of the
|
|
number of times a circuit was extended to at least two hops through that
|
|
guard, and a count of the number of circuits that successfully complete
|
|
through that guard. The ratio of these two numbers is used to determine
|
|
a circuit success rate for that Guard.
|
|
|
|
Circuit build timeouts are counted as construction failures if the
|
|
circuit fails to complete before the 95% "right-censored" timeout
|
|
interval, not the 80% timeout condition (see section 2.4).
|
|
|
|
If a circuit closes prematurely after construction but before being
|
|
requested to close by the client, this is counted as a failure.
|
|
|
|
7.2. Measuring path usage success rates
|
|
|
|
Clients maintain two usage counts for each of their guards: a count
|
|
of the number of usage attempts, and a count of the number of
|
|
successful usages.
|
|
|
|
A usage attempt means any attempt to attach a stream to a circuit.
|
|
|
|
Usage success status is temporarily recorded by state flags on circuits.
|
|
Guard usage success counts are not incremented until circuit close. A
|
|
circuit is marked as successfully used if we receive a properly
|
|
recognized RELAY cell on that circuit that was expected for the current
|
|
circuit purpose.
|
|
|
|
If subsequent stream attachments fail or time out, the successfully used
|
|
state of the circuit is cleared, causing it once again to be regarded
|
|
as a usage attempt only.
|
|
|
|
Upon close by the client, all circuits that are still marked as usage
|
|
attempts are probed using a RELAY_BEGIN cell constructed with a
|
|
destination of the form 0.a.b.c:25, where a.b.c is a 24 bit random
|
|
nonce. If we get a RELAY_COMMAND_END in response matching our nonce,
|
|
the circuit is counted as successfully used.
|
|
|
|
If any unrecognized RELAY cells arrive after the probe has been sent,
|
|
the circuit is counted as a usage failure.
|
|
|
|
If the stream failure reason codes DESTROY, TORPROTOCOL, or INTERNAL
|
|
are received in response to any stream attempt, such circuits are not
|
|
probed and are declared usage failures.
|
|
|
|
Prematurely closed circuits are not probed, and are counted as usage
|
|
failures.
|
|
|
|
7.3. Scaling success counts
|
|
|
|
To provide a moving average of recent Guard activity while
|
|
still preserving the ability to verify correctness, we periodically
|
|
"scale" the success counts by multiplying them by a scale factor
|
|
between 0 and 1.0.
|
|
|
|
Scaling is performed when either usage or construction attempt counts
|
|
exceed a parametrized value.
|
|
|
|
To avoid error due to scaling during circuit construction and use,
|
|
currently open circuits are subtracted from the usage counts before
|
|
scaling, and added back after scaling.
|
|
|
|
7.4. Parametrization
|
|
|
|
The following consensus parameters tune various aspects of the
|
|
defense.
|
|
|
|
pb_mincircs
|
|
Default: 150
|
|
Min: 5
|
|
Effect: This is the minimum number of circuits that must complete
|
|
at least 2 hops before we begin evaluating construction rates.
|
|
|
|
|
|
pb_noticepct
|
|
Default: 70
|
|
Min: 0
|
|
Max: 100
|
|
Effect: If the circuit success rate falls below this percentage,
|
|
we emit a notice log message.
|
|
|
|
pb_warnpct
|
|
Default: 50
|
|
Min: 0
|
|
Max: 100
|
|
Effect: If the circuit success rate falls below this percentage,
|
|
we emit a warn log message.
|
|
|
|
pb_extremepct
|
|
Default: 30
|
|
Min: 0
|
|
Max: 100
|
|
Effect: If the circuit success rate falls below this percentage,
|
|
we emit a more alarmist warning log message. If
|
|
pb_dropguard is set to 1, we also disable the use of the
|
|
guard.
|
|
|
|
pb_dropguards
|
|
Default: 0
|
|
Min: 0
|
|
Max: 1
|
|
Effect: If the circuit success rate falls below pb_extremepct,
|
|
when pb_dropguard is set to 1, we disable use of that
|
|
guard.
|
|
|
|
pb_scalecircs
|
|
Default: 300
|
|
Min: 10
|
|
Effect: After this many circuits have completed at least two hops,
|
|
Tor performs the scaling described in Section 7.3.
|
|
|
|
pb_multfactor and pb_scalefactor
|
|
Default: 1/2
|
|
Min: 0.0
|
|
Max: 1.0
|
|
Effect: The double-precision result obtained from
|
|
pb_multfactor/pb_scalefactor is multiplied by our current
|
|
counts to scale them.
|
|
|
|
pb_minuse
|
|
Default: 20
|
|
Min: 3
|
|
Effect: This is the minimum number of circuits that we must attempt to
|
|
use before we begin evaluating construction rates.
|
|
|
|
pb_noticeusepct
|
|
Default: 80
|
|
Min: 3
|
|
Effect: If the circuit usage success rate falls below this percentage,
|
|
we emit a notice log message.
|
|
|
|
pb_extremeusepct
|
|
Default: 60
|
|
Min: 3
|
|
Effect: If the circuit usage success rate falls below this percentage,
|
|
we emit a warning log message. We also disable the use of the
|
|
guard if pb_dropguards is set.
|
|
|
|
pb_scaleuse
|
|
Default: 100
|
|
Min: 10
|
|
Effect: After we have attempted to use this many circuits,
|
|
Tor performs the scaling described in Section 7.3.
|
|
|
|
7.5. Known barriers to enforcement
|
|
|
|
Due to intermittent CPU overload at relays, the normal rate of
|
|
successful circuit completion is highly variable. The Guard-dropping
|
|
version of the defense is unlikely to be deployed until the ntor
|
|
circuit handshake is enabled, or the nature of CPU overload induced
|
|
failure is better understood.
|
|
|
|
|
|
|
|
X. Old notes
|
|
|
|
X.1. Do we actually do this?
|
|
|
|
How to deal with network down.
|
|
- While all helpers are down/unreachable and there are no established
|
|
or on-the-way testing circuits, launch a testing circuit. (Do this
|
|
periodically in the same way we try to establish normal circuits
|
|
when things are working normally.)
|
|
(Testing circuits are a special type of circuit, that streams won't
|
|
attach to by accident.)
|
|
- When a testing circuit succeeds, mark all helpers up and hold
|
|
the testing circuit open.
|
|
- If a connection to a helper succeeds, close all testing circuits.
|
|
Else mark that helper down and try another.
|
|
- If the last helper is marked down and we already have a testing
|
|
circuit established, then add the first hop of that testing circuit
|
|
to the end of our helper node list, close that testing circuit,
|
|
and go back to square one. (Actually, rather than closing the
|
|
testing circuit, can we get away with converting it to a normal
|
|
circuit and beginning to use it immediately?)
|
|
|
|
[Do we actually do any of the above? If so, let's spec it. If not, let's
|
|
remove it. -NM]
|
|
|
|
X.2. A thing we could do to deal with reachability.
|
|
|
|
And as a bonus, it leads to an answer to Nick's attack ("If I pick
|
|
my helper nodes all on 18.0.0.0:*, then I move, you'll know where I
|
|
bootstrapped") -- the answer is to pick your original three helper nodes
|
|
without regard for reachability. Then the above algorithm will add some
|
|
more that are reachable for you, and if you move somewhere, it's more
|
|
likely (though not certain) that some of the originals will become useful.
|
|
Is that smart or just complex?
|
|
|
|
X.3. Some stuff that worries me about entry guards. 2006 Jun, Nickm.
|
|
|
|
It is unlikely for two users to have the same set of entry guards.
|
|
Observing a user is sufficient to learn its entry guards. So, as we move
|
|
around, entry guards make us linkable. If we want to change guards when
|
|
our location (IP? subnet?) changes, we have two bad options. We could
|
|
- Drop the old guards. But if we go back to our old location,
|
|
we'll not use our old guards. For a laptop that sometimes gets used
|
|
from work and sometimes from home, this is pretty fatal.
|
|
- Remember the old guards as associated with the old location, and use
|
|
them again if we ever go back to the old location. This would be
|
|
nasty, since it would force us to record where we've been.
|
|
|
|
[Do we do any of this now? If not, this should move into 099-misc or
|
|
098-todo. -NM]
|
|
|