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123 lines
4.7 KiB
Plaintext
123 lines
4.7 KiB
Plaintext
Filename: 110-avoid-infinite-circuits.txt
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Title: Avoiding infinite length circuits
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Version: $Revision$
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Last-Modified: $Date$
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Author: Roger Dingledine
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Created: 13-Mar-2007
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Status: Accepted
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Target: 0.2.1.x
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Implemented-In: 0.2.1.3-alpha
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History:
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Revised 28 July 2008 by nickm: set K.
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Revised 3 July 2008 by nickm: rename from relay_extend to
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relay_early. Revise to current migration plan. Allow K cells
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over circuit lifetime, not just at start.
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Overview:
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Right now, an attacker can add load to the Tor network by extending a
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circuit an arbitrary number of times. Every cell that goes down the
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circuit then adds N times that amount of load in overall bandwidth
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use. This vulnerability arises because servers don't know their position
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on the path, so they can't tell how many nodes there are before them
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on the path.
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We propose a new set of relay cells that are distinguishable by
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intermediate hops as permitting extend cells. This approach will allow
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us to put an upper bound on circuit length relative to the number of
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colluding adversary nodes; but there are some downsides too.
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Motivation:
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The above attack can be used to generally increase load all across the
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network, or it can be used to target specific servers: by building a
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circuit back and forth between two victim servers, even a low-bandwidth
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attacker can soak up all the bandwidth offered by the fastest Tor
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servers.
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The general attacks could be used as a demonstration that Tor isn't
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perfect (leading to yet more media articles about "breaking" Tor), and
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the targetted attacks will come into play once we have a reputation
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system -- it will be trivial to DoS a server so it can't pass its
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reputation checks, in turn impacting security.
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Design:
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We should split RELAY cells into two types: RELAY and RELAY_EARLY.
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Only K (say, 10) Relay_early cells can be sent across a circuit, and
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only relay_early cells are allowed to contain extend requests. We
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still support obscuring the length of the circuit (if more research
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shows us what to do), because Alice can choose how many of the K to
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mark as relay_early. Note that relay_early cells *can* contain any
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sort of data cell; so in effect it's actually the relay type cells
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that are restricted. By default, she would just send the first K
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data cells over the stream as relay_early cells, regardless of their
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actual type.
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(Note that a circuit that is out of relay_early cells MUST NOT be
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cannibalized later, since it can't extend. Note also that it's always okay
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to use regular RELAY cells when sending non-EXTEND commands targetted at
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the first hop of a circuit, since there is no intermediate hop to try to
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learn the relay command type.)
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Each intermediate server would pass on the same type of cell that it
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received (either relay or relay_early), and the cell's destination
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will be able to learn whether it's allowed to contain an Extend request.
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If an intermediate server receives more than K relay_early cells, or
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if it sees a relay cell that contains an extend request, then it
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tears down the circuit (protocol violation).
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Security implications:
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The upside is that this limits the bandwidth amplification factor to
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K: for an individual circuit to become arbitrary-length, the attacker
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would need an adversary-controlled node every K hops, and at that
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point the attack is no worse than if the attacker creates N/K separate
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K-hop circuits.
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On the other hand, we want to pick a large enough value of K that we
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don't mind the cap.
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If we ever want to take steps to hide the number of hops in the circuit
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or a node's position in the circuit, this design probably makes that
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more complex.
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Migration:
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In 0.2.0, servers speaking v2 or later of the link protocol accept
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RELAY_EARLY cells, and pass them on. If the next OR in the circuit
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is not speaking the v2 link protocol, the server relays the cell as
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a RELAY cell.
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In 0.2.1.3-alpha, clients begin using RELAY_EARLY cells on v2
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connections. This functionality can be safely backported to
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0.2.0.x. Clients should pick a random number betweeen (say) K and
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K-2 to send.
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In 0.2.1.3-alpha, servers close any circuit in which more than K
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relay_early cells are sent.
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Once all versions the do not send RELAY_EARLY cells are obsolete,
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servers can begin to reject any EXTEND requests not sent in a
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RELAY_EARLY cell.
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Parameters:
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Let K = 8, for no terribly good reason.
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Spec:
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[We can formalize this part once we think the design is a good one.]
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Acknowledgements:
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This design has been kicking around since Christian Grothoff and I came
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up with it at PET 2004. (Nathan Evans, Christian Grothoff's student,
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is working on implementing a fix based on this design in the summer
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2007 timeframe.)
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