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more patches on sec2 and sec3; rewrite threat model
svn:r712
This commit is contained in:
parent
b0c6a5ea2e
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doc/TODO
6
doc/TODO
@ -1,6 +1,10 @@
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mutiny: if none of the ports is defined maybe it shouldn't start.
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mutiny suggests: if none of the ports is defined maybe it shouldn't start.
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aaron got a crash in tor_timegm in tzset on os x, with -l warn but not with -l debug.
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Oct 25 04:29:17.017 [warn] directory_initiate_command(): No running dirservers known. This is really bad.
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rename ACI to CircID
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rotate tls-level connections -- make new ones, expire old ones.
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dirserver shouldn't put you in running-routers list if you haven't
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uploading a descriptor recently
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Legend:
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SPEC!! - Not specified
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@ -39,7 +39,7 @@
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% \pdfpageheight=\the\paperheight
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%\fi
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\title{Tor: Design of a Second-Generation Onion Router}
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\title{Tor: The Second-Generation Onion Router}
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%\author{Roger Dingledine \\ The Free Haven Project \\ arma@freehaven.net \and
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%Nick Mathewson \\ The Free Haven Project \\ nickm@freehaven.net \and
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@ -308,22 +308,20 @@ Concentrating the traffic to a single point increases the anonymity set
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analysis easier: an adversary need only eavesdrop on the proxy to observe
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the entire system.
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More complex are distributed-trust, circuit-based anonymizing systems. In
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these designs, a user establishes one or more medium-term bidirectional
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end-to-end tunnels to exit servers, and uses those tunnels to deliver
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low-latency packets to and from one or more destinations per
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tunnel. %XXX reword
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Establishing tunnels is expensive and typically
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requires public-key cryptography, whereas relaying packets along a tunnel is
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comparatively inexpensive. Because a tunnel crosses several servers, no
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single server can link a user to her communication partners.
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More complex are distributed-trust, circuit-based anonymizing systems.
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In these designs, a user establishes one or more medium-term bidirectional
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end-to-end circuits, and tunnels TCP streams in fixed-size cells.
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Establishing circuits is expensive and typically requires public-key
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cryptography, whereas relaying cells is comparatively inexpensive.
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Because a circuit crosses several servers, no single server can link a
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user to her communication partners.
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In some distributed-trust systems, such as the Java Anon Proxy (also known
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as JAP or Web MIXes), users build their tunnels along a fixed shared route
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or \emph{cascade}. As with a single-hop proxy, this approach aggregates
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The Java Anon Proxy (also known
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as JAP or Web MIXes) uses fixed shared routes known as
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\emph{cascades}. As with a single-hop proxy, this approach aggregates
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users into larger anonymity sets, but again an attacker only needs to
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observe both ends of the cascade to bridge all the system's traffic.
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The Java Anon Proxy's design seeks to prevent this by padding
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The Java Anon Proxy's design provides protection by padding
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between end users and the head of the cascade \cite{web-mix}. However, the
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current implementation does no padding and thus remains vulnerable
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to both active and passive bridging.
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@ -350,10 +348,10 @@ from the data stream.
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Hordes \cite{hordes-jcs} is based on Crowds but also uses multicast
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responses to hide the initiator. Herbivore \cite{herbivore} and P5
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\cite{p5} go even further, requiring broadcast. Each uses broadcast
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in different ways, and trade-offs are made to make broadcast more
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practical. Both Herbivore and P5 are designed primarily for communication
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between peers, although Herbivore permits external connections by
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\cite{p5} go even further, requiring broadcast. They make anonymity
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and efficiency tradeoffs to make broadcast more practical.
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These systems are designed primarily for communication between peers,
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although Herbivore users can make external connections by
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requesting a peer to serve as a proxy. Allowing easy connections to
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nonparticipating responders or recipients is important for usability,
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for example so users can visit nonparticipating Web sites or exchange
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@ -391,273 +389,132 @@ Eternity and Free Haven.
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\SubSection{Goals}
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Like other low-latency anonymity designs, Tor seeks to frustrate
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attackers from linking communication partners, or from linking
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multiple communications to or from a single point. Within this
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multiple communications to or from a single user. Within this
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main goal, however, several design considerations have directed
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Tor's evolution.
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\begin{tightlist}
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\item[Deployability:] The design must be one which can be implemented,
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deployed, and used in the real world. This requirement precludes designs
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that are expensive to run (for example, by requiring more bandwidth than
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volunteers are willing to provide); designs that place a heavy liability
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burden on operators (for example, by allowing attackers to implicate onion
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routers in illegal activities); and designs that are difficult or expensive
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to implement (for example, by requiring kernel patches, or separate proxies
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for every protocol). This requirement also precludes systems in which
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users who do not benefit from anonymity are required to run special
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software in order to communicate with anonymous parties.
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% Our rendezvous points require clients to use our software to get to
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% the location-hidden servers.
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% Or at least, they require somebody near the client-side running our
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% software. We haven't worked out the details of keeping it transparent
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% for Alice if she's using some other http proxy somewhere. I guess the
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% external http proxy should route through a Tor client, which automatically
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% translates the foo.onion address? -RD
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%
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% 1. Such clients do benefit from anonymity: they can reach the server.
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% Recall that our goal for location hidden servers is to continue to
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% provide service to priviliged clients when a DoS is happening or
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% to provide access to a location sensitive service. I see no contradiction.
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% 2. A good idiot check is whether what we require people to download
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% and use is more extreme than downloading the anonymizer toolbar or
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% privacy manager. I don't think so, though I'm not claiming we've already
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% got the installation and running of a client down to that simplicity
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% at this time. -PS
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\item[Usability:] A hard-to-use system has fewer users---and because
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anonymity systems hide users among users, a system with fewer users
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provides less anonymity. Usability is not only a convenience for Tor:
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it is a security requirement \cite{econymics,back01}. Tor
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should work with most of a user's unmodified applications; shouldn't
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introduce prohibitive delays; and should require the user to make as few
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configuration decisions as possible.
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\item[Flexibility:] The protocol must be flexible and
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well-specified, so that it can serve as a test-bed for future research in
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low-latency anonymity systems. Many of the open problems in low-latency
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anonymity networks (such as generating dummy traffic, or preventing
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pseudospoofing attacks) may be solvable independently from the issues
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solved by Tor; it would be beneficial if future systems were not forced to
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reinvent Tor's design decisions. (But note that while a flexible design
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benefits researchers, there is a danger that differing choices of
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extensions will render users distinguishable. Thus, experiments
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on extensions should be limited and should not significantly affect
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the distinguishability of ordinary users.
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% To run an experiment researchers must file an
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% anonymity impact statement -PS
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of implementations should
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not permit different protocol extensions to coexist in a single deployed
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network.)
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\item[Conservative design:] The protocol's design and security parameters
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must be conservative. Because additional features impose implementation
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and complexity costs, Tor should include as few speculative features as
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possible. (We do not oppose speculative designs in general; however, it is
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our goal with Tor to embody a solution to the problems in low-latency
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anonymity that we can solve today before we plunge into the problems of
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tomorrow.)
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% This last bit sounds completely cheesy. Somebody should tone it down. -NM
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\end{tightlist}
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\textbf{Deployability:} The design must be one which can be implemented,
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deployed, and used in the real world. This requirement precludes designs
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that are expensive to run (for example, by requiring more bandwidth
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than volunteers are willing to provide); designs that place a heavy
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liability burden on operators (for example, by allowing attackers to
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implicate onion routers in illegal activities); and designs that are
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difficult or expensive to implement (for example, by requiring kernel
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patches, or separate proxies for every protocol). This requirement also
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precludes systems in which users who do not benefit from anonymity are
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required to run special software in order to communicate with anonymous
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parties. (We do not meet this goal for the current rendezvous design,
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however; see Section~\ref{sec:rendezvous}.)
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\textbf{Usability:} A hard-to-use system has fewer users---and because
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anonymity systems hide users among users, a system with fewer users
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provides less anonymity. Usability is not only a convenience for Tor:
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it is a security requirement \cite{econymics,back01}. Tor should not
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require modifying applications; should not introduce prohibitive delays;
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and should require the user to make as few configuration decisions
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as possible.
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\textbf{Flexibility:} The protocol must be flexible and well-specified,
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so that it can serve as a test-bed for future research in low-latency
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anonymity systems. Many of the open problems in low-latency anonymity
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networks, such as generating dummy traffic or preventing Sybil attacks
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\cite{sybil}, may be solvable independently from the issues solved by
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Tor. Hopefully future systems will not need to reinvent Tor's design
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decisions. (But note that while a flexible design benefits researchers,
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there is a danger that differing choices of extensions will make users
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distinguishable. Experiments should be run on a separate network.)
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\textbf{Conservative design:} The protocol's design and security
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parameters must be conservative. Additional features impose implementation
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and complexity costs; adding unproven techniques to the design threatens
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deployability, readability, and ease of security analysis. Tor aims to
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deploy a simple and stable system that integrates the best well-understood
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approaches to protecting anonymity.
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\SubSection{Non-goals}
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\label{subsec:non-goals}
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In favoring conservative, deployable designs, we have explicitly deferred
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a number of goals. Many of these goals are desirable in anonymity systems,
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but we choose to defer them either because they are solved elsewhere,
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or because they present an area of active research lacking a generally
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accepted solution.
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a number of goals, either because they are solved elsewhere, or because
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they are an open research question.
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\begin{tightlist}
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\item[Not Peer-to-peer:] Tarzan and MorphMix aim to
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scale to completely decentralized peer-to-peer environments with thousands
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of short-lived servers, many of which may be controlled by an adversary.
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Because of the many open problems in this approach, Tor uses a more
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conservative design.
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\item[Not secure against end-to-end attacks:] Tor does not claim to provide a
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definitive solution to end-to-end timing or intersection attacks. Some
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approaches, such as running an onion router, may help; see
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Section~\ref{sec:analysis} for more discussion.
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\item[No protocol normalization:] Tor does not provide \emph{protocol
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normalization} like Privoxy or the Anonymizer. In order to make clients
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indistinguishable when they use complex and variable protocols such as HTTP,
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Tor must be layered with a filtering proxy such as Privoxy to hide
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differences between clients, expunge protocol features that leak identity,
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and so on. Similarly, Tor does not currently integrate tunneling for
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non-stream-based protocols like UDP; this too must be provided by
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an external service.
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\textbf{Not Peer-to-peer:} Tarzan and MorphMix aim to scale to completely
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decentralized peer-to-peer environments with thousands of short-lived
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servers, many of which may be controlled by an adversary. This approach
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is appealing, but still has many open problems.
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\textbf{Not secure against end-to-end attacks:} Tor does not claim
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to provide a definitive solution to end-to-end timing or intersection
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attacks. Some approaches, such as running an onion router, may help;
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see Section~\ref{sec:analysis} for more discussion.
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\textbf{No protocol normalization:} Tor does not provide \emph{protocol
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normalization} like Privoxy or the Anonymizer. For complex and variable
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protocols such as HTTP, Tor must be layered with a filtering proxy such
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as Privoxy to hide differences between clients, and expunge protocol
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features that leak identity. Similarly, Tor does not currently integrate
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tunneling for non-stream-based protocols like UDP; this too must be
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provided by an external service.
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% Actually, tunneling udp over tcp is probably horrible for some apps.
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% Should this get its own non-goal bulletpoint? The motivation for
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% non-goal-ness would be burden on clients / portability.
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\item[Not steganographic:] Tor does not try to conceal which users are
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sending or receiving communications; it only tries to conceal whom they are
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communicating with.
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\end{tightlist}
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% non-goal-ness would be burden on clients / portability. -RD
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% No, leave it as is. -RD
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\textbf{Not steganographic:} Tor does not try to conceal which users are
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sending or receiving communications; it only tries to conceal with whom
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they communicate.
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\SubSection{Threat Model}
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\label{subsec:threat-model}
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A global passive adversary is the most commonly assumed threat when
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analyzing theoretical anonymity designs. But like all practical low-latency
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systems, Tor is not secure against this adversary. Instead, we assume an
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adversary that is weaker than global with respect to distribution, but that
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is not merely passive. Our threat model expands on that from
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\cite{or-pet00}.
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analyzing theoretical anonymity designs. But like all practical
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low-latency systems, Tor does not protect against such a strong
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adversary. Instead, we expect an adversary who can observe some fraction
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of network traffic; who can generate, modify, delete, or delay traffic
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on the network; who can operate onion routers of its own; and who can
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compromise some fraction of the onion routers on the network.
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%%%% This is really keen analytical stuff, but it isn't our threat model:
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%%%% we just go ahead and assume a fraction of hostile nodes for
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%%%% convenience. -NM
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%
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%% The basic adversary components we consider are:
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%% \begin{tightlist}
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%% \item[Observer:] can observe a connection (e.g., a sniffer on an
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%% Internet router), but cannot initiate connections. Observations may
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%% include timing and/or volume of packets as well as appearance of
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%% individual packets (including headers and content).
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%% \item[Disrupter:] can delay (indefinitely) or corrupt traffic on a
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%% link. Can change all those things that an observer can observe up to
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%% the limits of computational ability (e.g., cannot forge signatures
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%% unless a key is compromised).
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%% \item[Hostile initiator:] can initiate (or destroy) connections with
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%% specific routes as well as vary the timing and content of traffic
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%% on the connections it creates. A special case of the disrupter with
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%% additional abilities appropriate to its role in forming connections.
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%% \item[Hostile responder:] can vary the traffic on the connections made
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%% to it including refusing them entirely, intentionally modifying what
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%% it sends and at what rate, and selectively closing them. Also a
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%% special case of the disrupter.
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%% \item[Key breaker:] can break the key used to encrypt connection
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%% initiation requests sent to a Tor-node.
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%% % Er, there are no long-term private decryption keys. They have
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%% % long-term private signing keys, and medium-term onion (decryption)
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%% % keys. Plus short-term link keys. Should we lump them together or
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%% % separate them out? -RD
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%% %
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%% % Hmmm, I was talking about the keys used to encrypt the onion skin
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%% % that contains the public DH key from the initiator. Is that what you
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%% % mean by medium-term onion key? (``Onion key'' used to mean the
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%% % session keys distributed in the onion, back when there were onions.)
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%% % Also, why are link keys short-term? By link keys I assume you mean
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%% % keys that neighbor nodes use to superencrypt all the stuff they send
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%% % to each other on a link. Did you mean the session keys? I had been
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%% % calling session keys short-term and everything else long-term. I
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%% % know I was being sloppy. (I _have_ written papers formalizing
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%% % concepts of relative freshness.) But, there's some questions lurking
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%% % here. First up, I don't see why the onion-skin encryption key should
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%% % be any shorter term than the signature key in terms of threat
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%% % resistance. I understand that how we update onion-skin encryption
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%% % keys makes them depend on the signature keys. But, this is not the
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%% % basis on which we should be deciding about key rotation. Another
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%% % question is whether we want to bother with someone who breaks a
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%% % signature key as a particular adversary. He should be able to do
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%% % nearly the same as a compromised tor-node, although they're not the
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%% % same. I reworded above, I'm thinking we should leave other concerns
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%% % for later. -PS
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%% \item[Hostile Tor node:] can arbitrarily manipulate the
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%% connections under its control, as well as creating new connections
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%% (that pass through itself).
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%% \end{tightlist}
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%
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%% All feasible adversaries can be composed out of these basic
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%% adversaries. This includes combinations such as one or more
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%% compromised Tor-nodes cooperating with disrupters of links on which
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%% those nodes are not adjacent, or such as combinations of hostile
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%% outsiders and link observers (who watch links between adjacent
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%% Tor-nodes). Note that one type of observer might be a Tor-node. This
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%% is sometimes called an honest-but-curious adversary. While an observer
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%% Tor-node will perform only correct protocol interactions, it might
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%% share information about connections and cannot be assumed to destroy
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%% session keys at end of a session. Note that a compromised Tor-node is
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%% stronger than any other adversary component in the sense that
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%% replacing a component of any adversary with a compromised Tor-node
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%% results in a stronger overall adversary (assuming that the compromised
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%% Tor-node retains the same signature keys and other private
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%% state-information as the component it replaces).
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%Large adversaries will be able to compromise a considerable fraction
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%of the network. (In some circumstances---for example, if the Tor
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%network is running on a hardened network where all operators have
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%had background checks---the number of compromised nodes could be quite
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%small.) Compromised nodes can arbitrarily manipulate the connections that
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%pass through them, as well as creating new connections that pass through
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%themselves. They can observe traffic, and record it for later analysis.
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First, we assume that a threshold of directory servers are honest,
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reliable, accurate, and trustworthy.
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%% the rest of this isn't needed, if dirservers do threshold concensus dirs
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% To augment this, users can periodically cross-check
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%directories from each directory server (trust, but verify).
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%, and that they always have access to at least one directory server that they trust.
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In low-latency anonymity systems that use layered encryption, the
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adversary's typical goal is to observe both the initiator and the
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receiver. Passive attackers can confirm a suspicion that Alice is
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talking to Bob if the timing and volume properties of the traffic on the
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connection are unique enough; active attackers are even more effective
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because they can induce timing signatures on the traffic. Tor provides
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some defenses against these \emph{traffic confirmation} attacks, for
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example by encouraging users to run their own onion routers, but it does
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not provide complete protection. Rather, we aim to prevent \emph{traffic
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analysis} attacks, where the adversary uses traffic patterns to learn
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which points in the network he should attack.
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Second, we assume that somewhere between ten percent and twenty
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percent\footnote{In some circumstances---for example, if the Tor network is
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running on a hardened network where all operators have had background
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checks---the number of compromised nodes could be much lower.}
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of the Tor nodes accepted by the directory servers are compromised, hostile,
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and collaborating in an off-line clique. These compromised nodes can
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arbitrarily manipulate the connections that pass through them, as well as
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creating new connections that pass through themselves. They can observe
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traffic, and record it for later analysis. Honest participants do not know
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which servers these are.
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(In reality, many adversaries might have `bad' servers that are not
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fully compromised but simply under observation, or that have had their keys
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compromised. But for the sake of analysis, we ignore, this possibility,
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since the threat model we assume is strictly stronger.)
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% This next paragraph is also more about analysis than it is about our
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% threat model. Perhaps we can say, ``users can connect to the network and
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% use it in any way; we consider abusive attacks separately.'' ? -NM
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Third, we constrain the impact of hostile users. Users are assumed to vary
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widely in both the duration and number of times they are connected to the Tor
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network. They can also be assumed to vary widely in the volume and shape of
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the traffic they send and receive. Hostile users are, by definition, limited
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to creating and varying their own connections into or through a Tor
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network. They may attack their own connections to try to gain identity
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||||
information of the responder in a rendezvous connection. They can also try to
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attack sites through the Onion Routing network; however we will consider this
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abuse rather than an attack per se (see
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||||
Section~\ref{subsec:exitpolicies}). Other than abuse, a hostile user's
|
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motivation to attack his own connections is limited to the network effects of
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such actions, such as denial of service (DoS) attacks. Thus, in this case,
|
||||
we can view user as simply an extreme case of the ordinary user; although
|
||||
ordinary users are not likely to engage in, e.g., IP spoofing, to gain their
|
||||
objectives.
|
||||
|
||||
In general, we are more focused on traffic analysis attacks than
|
||||
traffic confirmation attacks.
|
||||
%A user who runs a Tor proxy on his own
|
||||
%machine, connects to some remote Tor-node and makes a connection to an
|
||||
%open Internet site, such as a public web server, is vulnerable to
|
||||
%traffic confirmation.
|
||||
That is, an active attacker who suspects that
|
||||
a particular client is communicating with a particular server can
|
||||
confirm this if she can modify and observe both the
|
||||
connection between the Tor network and the client and that between the
|
||||
Tor network and the server. Even a purely passive attacker can
|
||||
confirm traffic if the timing and volume properties of the traffic on
|
||||
the connection are unique enough. (This is not to say that Tor offers
|
||||
no resistance to traffic confirmation; it does. We defer discussion
|
||||
of this point and of particular attacks until Section~\ref{sec:attacks},
|
||||
after we have described Tor in more detail.)
|
||||
% XXX We need to say what traffic analysis is: How about...
|
||||
On the other hand, we {\it do} try to prevent an attacker from
|
||||
performing traffic analysis: that is, attempting to learn the communication
|
||||
partners of an arbitrary user.
|
||||
% XXX If that's not right, what is? It would be silly to have a
|
||||
% threat model section without saying what we want to prevent the
|
||||
% attacker from doing. -NM
|
||||
% XXX Also, do we want to mention linkability or building profiles? -NM
|
||||
|
||||
Our assumptions about our adversary's capabilities imply a number of
|
||||
possible attacks against users' anonymity. Our adversary might try to
|
||||
mount passive attacks by observing the edges of the network and
|
||||
correlating traffic entering and leaving the network: either because
|
||||
of relationships in packet timing; relationships in the volume of data
|
||||
sent; [XXX simple observation??]; or relationships in any externally
|
||||
visible user-selected options. The adversary can also mount active
|
||||
attacks by trying to compromise all the servers' keys in a
|
||||
path---either through illegitimate means or through legal coercion in
|
||||
unfriendly jurisdiction; by selectively DoSing trustworthy servers; by
|
||||
introducing patterns into entering traffic that can later be detected;
|
||||
or by modifying data entering the network and hoping that trashed data
|
||||
comes out the other end. The attacker can additionally try to
|
||||
decrease the network's reliability by performing antisocial activities
|
||||
from reliable servers and trying to get them taken down.
|
||||
% XXX Should there be more or less? Should we turn this into a
|
||||
% bulleted list? Should we cut it entirely?
|
||||
|
||||
We consider these attacks and more, and describe our defenses against them
|
||||
in Section~\ref{sec:attacks}.
|
||||
Our adversary might try to link an initiator Alice with any of her
|
||||
communication partners, or he might try to build a profile of Alice's
|
||||
behavior. He might mount passive attacks by observing the edges of the
|
||||
network and correlating traffic entering and leaving the network---either
|
||||
because of relationships in packet timing; relationships in the volume
|
||||
of data sent; or relationships in any externally visible user-selected
|
||||
options. The adversary can also mount active attacks by compromising
|
||||
routers or keys; by replaying traffic; by selectively DoSing trustworthy
|
||||
routers to encourage users to send their traffic through compromised
|
||||
routers, or DoSing users to see if the traffic elsewhere in the
|
||||
network stops; or by introducing patterns into traffic that can later be
|
||||
detected. The adversary might attack the directory servers to give users
|
||||
differing views of network state. Additionally, he can try to decrease
|
||||
the network's reliability by attacking nodes or by performing antisocial
|
||||
activities from reliable servers and trying to get them taken down;
|
||||
making the network unreliable flushes users to other less anonymous
|
||||
systems, where they may be easier to attack.
|
||||
|
||||
We consider each of these attacks in more detail below, and summarize
|
||||
in Section~\ref{sec:attacks} how well the Tor design defends against
|
||||
each of them.
|
||||
|
||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||
|
||||
@ -2004,7 +1861,7 @@ issues remaining to be ironed out. In particular:
|
||||
|
||||
% Many of these (Scalability, cover traffic) are duplicates from open problems.
|
||||
%
|
||||
\begin{itemize}
|
||||
\begin{tightlist}
|
||||
\item \emph{Scalability:} Tor's emphasis on design simplicity and
|
||||
deployability has led us to adopt a clique topology, a
|
||||
semi-centralized model for directories and trusts, and a
|
||||
@ -2049,7 +1906,7 @@ issues remaining to be ironed out. In particular:
|
||||
able to evaluate some of our design decisions, including our
|
||||
robustness/latency tradeoffs, our abuse-prevention mechanisms, and
|
||||
our overall usability.
|
||||
\end{itemize}
|
||||
\end{tightlist}
|
||||
|
||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||
|
||||
|
Loading…
Reference in New Issue
Block a user