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Tighten, clarify
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@ -48,7 +48,7 @@ Anonymous communication is full of surprises. This paper discusses some
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unexpected challenges arising from our experiences deploying Tor, a
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low-latency general-purpose anonymous communication system. We will discuss
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some of the difficulties we have experienced and how we have met them (or how
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we plan to meet them, if we know). We will also discuss some less
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we plan to meet them, if we know). We also discuss some less
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troublesome open problems that we must nevertheless eventually address.
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%We will describe both those future challenges that we intend to explore and
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%those that we have decided not to explore and why.
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@ -56,15 +56,15 @@ troublesome open problems that we must nevertheless eventually address.
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Tor is an overlay network for anonymizing TCP streams over the
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Internet~\cite{tor-design}. It addresses limitations in earlier Onion
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Routing designs~\cite{or-ih96,or-jsac98,or-discex00,or-pet00} by adding
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perfect forward secrecy, congestion control, directory servers, integrity
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checking, configurable exit policies, and location-hidden services using
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perfect forward secrecy, congestion control, directory servers, data
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integrity, configurable exit policies, and location-hidden services using
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rendezvous points. Tor works on the real-world Internet, requires no special
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privileges or kernel modifications, requires little synchronization or
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coordination between nodes, and provides a reasonable tradeoff between
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anonymity, usability, and efficiency.
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We first publicly deployed a Tor network in October 2003; since then it has
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grown to over a hundred volunteer Tor nodes
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We first deployed a public Tor network in October 2003; since then it has
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grown to over a hundred volunteer-operated nodes
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and as much as 80 megabits of
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average traffic per second. Tor's research strategy has focused on deploying
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a network to as many users as possible; thus, we have resisted designs that
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@ -72,21 +72,19 @@ would compromise deployability by imposing high resource demands on node
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operators, and designs that would compromise usability by imposing
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unacceptable restrictions on which applications we support. Although this
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strategy has
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its drawbacks (including a weakened threat model, as discussed below), it has
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drawbacks (including a weakened threat model, as discussed below), it has
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made it possible for Tor to serve many thousands of users and attract
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funding from diverse sources whose goals range from security on a
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national scale down to the liberties of each individual.
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national scale down to individual liberties.
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While~\cite{tor-design} gives an overall view of Tor's
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design and goals, this paper describes policy, social, and technical
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In~\cite{tor-design} we gave an overall view of Tor's
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design and goals. Here we describe some policy, social, and technical
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issues that we face as we continue deployment.
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Rather than trying to provide complete solutions to every problem here, we
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lay out the assumptions and constraints that we have observed while
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deploying Tor in the wild. In doing so, we aim to create a research agenda
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for others to help in addressing these issues. We believe that the issues
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described here will be of general interest to any and all
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projects attempting to build
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and deploy practical, useable anonymity networks in the wild.
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Rather than providing complete solutions to every problem, we
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instead lay out the challenges and constraints that we have observed while
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deploying Tor in the wild. In doing so, we aim to provide a research agenda
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of general interest to projects attempting to build
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and deploy practical, usable anonymity networks in the wild.
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%While the Tor design paper~\cite{tor-design} gives an overall view its
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%design and goals,
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@ -122,46 +120,48 @@ compare Tor to other low-latency anonymity designs.
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Tor provides \emph{forward privacy}, so that users can connect to
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Internet sites without revealing their logical or physical locations
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to those sites or to observers. It also provides \emph{location-hidden
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services}, so that critical servers can support authorized users without
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giving adversaries an effective vector for physical or online attacks.
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The design provides these protections even when a portion of its own
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infrastructure is controlled by an adversary.
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services}, so that servers can support authorized users without
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giving an effective vector for physical or online attackers.
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Tor provides these protections even when a portion of its
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infrastructure is compromised.
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To create a private network pathway with Tor, the client software
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incrementally builds a \emph{circuit} of encrypted connections through
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Tor nodes on the network. The circuit is extended one hop at a time, and
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each node along the way knows only which node gave it data and which
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node it is giving data to. No individual Tor node ever knows the complete
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path that a data packet has taken. The client negotiates a separate set
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of encryption keys for each hop along the circuit. % to ensure that each
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%hop can't trace these connections as they pass through.
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Because each node sees no more than one hop in the
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circuit, neither an eavesdropper nor a compromised node can use traffic
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analysis to link the connection's source and destination.
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For efficiency, the Tor software uses the same circuit for all the TCP
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connections that happen within the same short period.
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Later requests use a new
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To connect to a remove server via Tor, the client software learns a signed
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list of Tor nodes from one of several central \emph{directory servers}, and
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incrementally creates a private pathway or \emph{circuit} of encrypted
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connections through authenticated Tor nodes on the network, negotiating a
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separate set of encryption keys for each hop along the circuit. The circuit
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is extended one node at a time, and each node along the way knows only the
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immediately previous and following nodes in the circuit, so no individual Tor
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node knows the complete path that each fixed-sized data packet (or
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\emph{cell}) will take.
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%Because each node sees no more than one hop in the
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%circuit,
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Thus, neither an eavesdropper nor a compromised node can
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see both the connection's source and destination. Later requests use a new
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circuit, to complicate long-term linkability between different actions by
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a single user.
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Tor also makes it possible for users to hide their locations while
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offering various kinds of services, such as web publishing or an instant
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messaging server. Using ``rendezvous points'', other Tor users can
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connect to these hidden services, each without knowing the other's network
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identity.
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Tor also helps servers hide their locations while
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providing services such as web publishing or instant
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messaging. Using ``rendezvous points'', other Tor users can
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connect to these authenticated hidden services, neither one learning the
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other's network identity.
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Tor attempts to anonymize the transport layer, not the application layer.
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This is useful for applications such as ssh
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This approach is useful for applications such as SSH
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where authenticated communication is desired. However, when anonymity from
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those with whom we communicate is desired,
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application protocols that include personally identifying information need
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additional application-level scrubbing proxies, such as
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Privoxy~\cite{privoxy} for HTTP\@. Furthermore, Tor does not permit arbitrary
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IP packets; it only anonymizes TCP streams and DNS request, and only supports
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connections via SOCKS (see Section~\ref{subsec:tcp-vs-ip}).
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Privoxy~\cite{privoxy} for HTTP\@. Furthermore, Tor does not relay arbitrary
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IP packets; it only anonymizes TCP streams and DNS requests
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%, and only supports
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%connections via SOCKS
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(but see Section~\ref{subsec:tcp-vs-ip}).
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Most node operators do not want to allow arbitary TCP connections to leave
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their server. To address this, Tor provides \emph{exit policies} so that
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Most node operators do not want to allow arbitary TCP traffic.% to leave
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%their server.
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To address this, Tor provides \emph{exit policies} so
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each exit node can block the IP addresses and ports it is unwilling to allow.
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Tor nodes advertise their exit policies to the directory servers, so that
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client can tell which nodes will support their connections.
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@ -169,18 +169,20 @@ client can tell which nodes will support their connections.
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As of January 2005, the Tor network has grown to around a hundred nodes
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on four continents, with a total capacity exceeding 1Gbit/s. Appendix A
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shows a graph of the number of working nodes over time, as well as a
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graph of the number of bytes being handled by the network over time. At
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this point the network is sufficiently diverse for further development
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and testing; but of course we always encourage and welcome new nodes
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to join the network.
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graph of the number of bytes being handled by the network over time.
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The network is now sufficiently diverse for further development
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and testing; but of course we always encourage new nodes
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to join.
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Tor research and development has been funded by ONR and DARPA
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for use in securing government
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communications, and by the Electronic Frontier Foundation, for use
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in maintaining civil liberties for ordinary citizens online. The Tor
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protocol is one of the leading choices
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to be the anonymizing layer in the European Union's PRIME directive to
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help maintain privacy in Europe. The University of Dresden in Germany
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for anonymizing layer in the European Union's PRIME directive to
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help maintain privacy in Europe.
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% XXXX We should credit the specific group, not the whole university.
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The University of Dresden in Germany
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has integrated an independent implementation of the Tor protocol into
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their popular Java Anon Proxy anonymizing client.
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% This wide variety of
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@ -192,16 +194,16 @@ their popular Java Anon Proxy anonymizing client.
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{\bf Threat models and design philosophy.}
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The ideal Tor network would be practical, useful and and anonymous. When
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trade-offs arise between these properties, Tor's research strategy has been
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to insist on remaining useful enough to attract many users,
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to remain useful enough to attract many users,
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and practical enough to support them. Only subject to these
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constraints do we aim to maximize
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constraints do we try to maximize
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anonymity.\footnote{This is not the only possible
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direction in anonymity research: designs exist that provide more anonymity
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than Tor at the expense of significantly increased resource requirements, or
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decreased flexibility in application support (typically because of increased
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latency). Such research does not typically abandon aspirations towards
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deployability or utility, but instead tries to maximize deployability and
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utility subject to a certain degree of inherent anonymity (inherent because
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utility subject to a certain degree of structural anonymity (structural because
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usability and practicality affect usage which affects the actual anonymity
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provided by the network \cite{econymics,back01}).}
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%{We believe that these
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@ -210,59 +212,25 @@ provided by the network \cite{econymics,back01}).}
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%of what makes a system ``practical'' for volunteer operators and ``useful''
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%for home users, and helps illuminate undernoticed issues which any deployed
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%volunteer anonymity network will need to address.}
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Because of this strategy, Tor has a weaker threat model than many anonymity
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designs in the literature. In particular, because we
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Because of our strategy, Tor has a weaker threat model than many designs in
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the literature. In particular, because we
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support interactive communications without impractically expensive padding,
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we fall prey to a variety
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of intra-network~\cite{back01,attack-tor-oak05,flow-correlation04} and
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end-to-end~\cite{danezis-pet2004,SS03} anonymity-breaking attacks.
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Tor does not attempt to defend against a global observer. In general, an
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attacker who can observe both ends of a connection through the Tor network
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can correlate the timing and volume of data on that connection as it enters
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and leaves the network, and so link a user to her chosen communication
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parties. Known solutions to this attack would seem to require introducing a
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and leaves the network, and so link communication partners.
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Known solutions to this attack would seem to require introducing a
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prohibitive degree of traffic padding between the user and the network, or
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introducing an unacceptable degree of latency (but see Section
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\ref{subsec:mid-latency}). Also, it is not clear that these methods would
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work at all against even a minimally active adversary that can introduce timing
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work at all against even a minimally active adversary who could introduce timing
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patterns or additional traffic. Thus, Tor only attempts to defend against
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external observers who cannot observe both sides of a user's connection.
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external observers who cannot observe both sides of a user's connections.
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The distinction between traffic correlation and traffic analysis is
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not as cut and dried as we might wish. In \cite{hintz-pet02} it was
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shown that if data volumes of various popular
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responder destinations are catalogued, it may not be necessary to
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observe both ends of a stream to learn a source-destination link.
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This should be fairly effective without simultaneously observing both
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ends of the connection. However, it is still essentially confirming
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suspected communicants where the responder suspects are ``stored'' rather
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than observed at the same time as the client.
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Similarly latencies of going through various routes can be
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catalogued~\cite{back01} to connect endpoints.
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This is likely to entail high variability and massive storage since
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% XXX hintz-pet02 just looked at data volumes of the sites. this
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% doesn't require much variability or storage. I think it works
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% quite well actually. Also, \cite{kesdogan:pet2002} takes the
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% attack another level further, to narrow down where you could be
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% based on an intersection attack on subpages in a website. -RD
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%
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% I was trying to be terse and simultaneously referring to both the
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% Hintz stuff and the Back et al. stuff from Info Hiding 01. I've
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% separated the two and added the references. -PFS
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routes through the network to each site will be random even if they
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have relatively unique latency characteristics. So this does not seem
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an immediate practical threat. Further along similar lines, the same
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paper suggested a ``clogging attack''. In \cite{attack-tor-oak05}, a
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version of this was demonstrated to be practical against portions of
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the fifty node Tor network as deployed in mid 2004. There it was shown
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that an outside attacker can trace a stream through the Tor network
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while a stream is still active simply by observing the latency of his
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own traffic sent through various Tor nodes. These attacks do not show
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the client address, only the first node within the Tor network, making
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helper nodes all the more worthy of exploration. (See
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Section~\ref{subsec:helper-nodes}.)
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Against internal attackers who sign up Tor nodes, the situation is more
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complicated. In the simplest case, if an adversary has compromised $c$ of
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@ -274,29 +242,62 @@ complicating factors:
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is pretty certain to see a statistical sample of the user's traffic, and
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thereby can build an increasingly accurate profile of her behavior. (See
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Section~\ref{subsec:helper-nodes} for possible solutions.)
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(2)~An adversary who controls a popular service outside of the Tor network
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can be certain of observing all connections to that service; he
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therefore will trace connections to that service with probability
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(2)~An adversary who controls a popular service outside the Tor network
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can be certain to observe all connections to that service; he
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can therefore trace connections to that service with probability
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$\frac{c}{n}$.
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(3)~Users do not in fact choose nodes with uniform probability; they
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favor nodes with high bandwidth or uptime, and exit nodes that
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permit connections to their favorite services.
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(See Section~\ref{subsec:routing-zones} for discussion of how larger
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adversaries affect our dispersal goals.)
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permit connections to their favorite services.
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See Section~\ref{subsec:routing-zones} for discussion of larger
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adversaries and our dispersal goals.
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%\begin{tightlist}
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%\item If the user continues to build random circuits over time, an adversary
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% is pretty certain to see a statistical sample of the user's traffic, and
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% thereby can build an increasingly accurate profile of her behavior. (See
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% \ref{subsec:helper-nodes} for possible solutions.)
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%\item An adversary who controls a popular service outside of the Tor network
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% can be certain of observing all connections to that service; he
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% therefore will trace connections to that service with probability
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% $\frac{c}{n}$.
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%\item Users do not in fact choose nodes with uniform probability; they
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% favor nodes with high bandwidth or uptime, and exit nodes that
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% permit connections to their favorite services.
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%\end{tightlist}
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% I'm trying to make this paragraph work without reference to the
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% analysis/confirmation distinction, which we haven't actually introduced
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% yet, and which we realize isn't very stable anyway. Also, I don't want to
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% deprecate these attacks if we can't demonstrate that they don't work, since
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% in case they *do* turn out to work well against Tor, we'll look pretty
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% foolish. -NM
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More powerful attacks may exist. In \cite{hintz-pet02} it was
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shown that an attacker who can catalog data volumes of popular
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responder destinations (say, websites with consistant data volumes) may not
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need to
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observe both ends of a stream to learn source-destination links for those
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responders.
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%However, it is still essentially confirming
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%suspected communicants where the responder suspects are ``stored'' rather
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%than observed at the same time as the client.
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Similarly latencies of going through various routes can be
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cataloged~\cite{back01} to connect endpoints.
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% XXX hintz-pet02 just looked at data volumes of the sites. this
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% doesn't require much variability or storage. I think it works
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% quite well actually. Also, \cite{kesdogan:pet2002} takes the
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% attack another level further, to narrow down where you could be
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% based on an intersection attack on subpages in a website. -RD
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%
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% I was trying to be terse and simultaneously referring to both the
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% Hintz stuff and the Back et al. stuff from Info Hiding 01. I've
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% separated the two and added the references. -PFS
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It has not yet been shown whether these attacks will succeed or fail
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in the presence of the varaibility and volume quantization introduced by the
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Tor network, but it seems likely that these factors will at best delay
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rather than halt the attacks in the cases where they succeed.
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%likely to entail high variability and massive storage since
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%routes through the network to each site will be random even if they
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%have relatively unique latency characteristics. So this does not seem
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%an immediate practical threat.
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Along similar lines, the same
|
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paper suggested a ``clogging attack''. In \cite{attack-tor-oak05}, a
|
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version of this was demonstrated to be practical against portions of
|
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the fifty node Tor network as deployed in mid 2004. There it was shown
|
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that an outside attacker can trace a stream through the Tor network
|
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while a stream is still active by observing the latency of his
|
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own traffic sent through various Tor nodes. These attacks do not show
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client and server addresses, only the first and last nodes within the Tor
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network, so it is still necessary to observe those nodes to complete the
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attacks. This may make
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helper nodes all the more worthy of exploration (see
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Section~\ref{subsec:helper-nodes}).
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%discuss $\frac{c^2}{n^2}$, except how in practice the chance of owning
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%the last hop is not $c/n$ since that doesn't take the destination (website)
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@ -335,25 +336,19 @@ adversaries affect our dispersal goals.)
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%see Section~\ref{subsec:helper-nodes} for discussion of some ways to
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%address this issue.
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\medskip
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\noindent
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{\bf Distributed trust.}
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In practice Tor's threat model is based entirely on the goal of
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In practice Tor's threat model is based on
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dispersal and diversity.
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Tor's defense lies in having a diverse enough set of nodes
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Our defense lies in having a diverse enough set of nodes
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to prevent most real-world
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adversaries from being in the right places to attack users.
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Tor aims to resist observers and insiders by distributing each transaction
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adversaries from being in the right places to attack users,
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by distributing each transaction
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over several nodes in the network. This ``distributed trust'' approach
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means the Tor network can be safely operated and used by a wide variety
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of mutually distrustful users, providing more sustainability and security
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than some previous attempts at anonymizing networks.
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The Tor network has a broad range of users, including ordinary citizens
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concerned about their privacy, corporations
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who don't want to reveal information to their competitors, and law
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enforcement and government intelligence agencies who need
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to do operations on the Internet without being noticed.
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of mutually distrustful users, providing sustainability and security.
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%than some previous attempts at anonymizing networks.
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No organization can achieve this security on its own. If a single
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corporation or government agency were to build a private network to
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@ -368,6 +363,11 @@ and who is looking for what information. %By bringing more users onto
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%the network, all users become more secure~\cite{econymics}.
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%[XXX I feel uncomfortable saying this last sentence now. -RD]
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%[So, I took it out. I think we can do without it. -PFS]
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The Tor network has a broad range of users, including ordinary citizens
|
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concerned about their privacy, corporations
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who don't want to reveal information to their competitors, and law
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enforcement and government intelligence agencies who need
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to do operations on the Internet without being noticed.
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Naturally, organizations will not want to depend on others for their
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security. If most participating providers are reliable, Tor tolerates
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some hostile infiltration of the network. For maximum protection,
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@ -382,28 +382,28 @@ Tor is not the only anonymity system that aims to be practical and useful.
|
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Commercial single-hop proxies~\cite{anonymizer}, as well as unsecured
|
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open proxies around the Internet, can provide good
|
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performance and some security against a weaker attacker. The Java
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Anon Proxy~\cite{web-mix} provides similar functionality to Tor but only
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handles web browsing rather than arbitrary TCP\@.
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Anon Proxy~\cite{web-mix} provides similar functionality to Tor but
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handles only web browsing rather than arbitrary TCP\@.
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%Some peer-to-peer file-sharing overlay networks such as
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%Freenet~\cite{freenet} and Mute~\cite{mute}
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Zero-Knowledge Systems' commercial Freedom
|
||||
network~\cite{freedom21-security} was even more flexible than Tor in
|
||||
that it could transport arbitrary IP packets, and it also supported
|
||||
pseudonymous access rather than just anonymous access; but it had
|
||||
transporting arbitrary IP packets, and also supported
|
||||
pseudonymous in addition to anonymity; but it has
|
||||
a different approach to sustainability (collecting money from users
|
||||
and paying ISPs to run Tor nodes), and was shut down due to financial
|
||||
and paying ISPs to run Tor nodes), and was eventually shut down due to financial
|
||||
load. Finally, potentially
|
||||
more scalable designs like Tarzan~\cite{tarzan:ccs02} and
|
||||
more scalable peer-to-peer designs like Tarzan~\cite{tarzan:ccs02} and
|
||||
MorphMix~\cite{morphmix:fc04} have been proposed in the literature, but
|
||||
have not yet been fielded. All of these systems differ somewhat
|
||||
have not yet been fielded. These systems differ somewhat
|
||||
in threat model and presumably practical resistance to threats.
|
||||
Morphmix is very close to Tor in circuit setup. And, by separating
|
||||
Morphmix is close to Tor in circuit setup, and, by separating
|
||||
node discovery from route selection from circuit setup, Tor is
|
||||
flexible enough to potentially contain a Morphmix experiment within
|
||||
it. We direct the interested reader to Section
|
||||
2 of~\cite{tor-design} for a more in-depth review of related work.
|
||||
it. We direct the interested reader
|
||||
to~\cite{tor-design} for a more in-depth review of related work.
|
||||
|
||||
Tor differs from other deployed systems for traffic analysis resistance
|
||||
Tor also differs from other deployed systems for traffic analysis resistance
|
||||
in its security and flexibility. Mix networks such as
|
||||
Mixmaster~\cite{mixmaster-spec} or its successor Mixminion~\cite{minion-design}
|
||||
gain the highest degrees of anonymity at the expense of introducing highly
|
||||
@ -440,18 +440,19 @@ Tor's interaction with other services on the Internet.
|
||||
\subsection{Communicating security}
|
||||
|
||||
Usability for anonymity systems
|
||||
contributes directly to their security, because how usable the system
|
||||
is impacts the possible anonymity set~\cite{econymics,back01}. Or
|
||||
conversely, an unusable system attracts few users and thus can't provide
|
||||
contributes directly to their security, because usability
|
||||
effects the possible anonymity set~\cite{econymics,back01}.
|
||||
Conversely, an unusable system attracts few users and thus can't provide
|
||||
much anonymity.
|
||||
|
||||
This phenomenon has a second-order effect: knowing this, users should
|
||||
choose which anonymity system to use based in part on how usable
|
||||
and secure
|
||||
\emph{others} will find it, in order to get the protection of a larger
|
||||
anonymity set. Thus we might replace the adage ``usability is a security
|
||||
anonymity set. Thus we might supplement the adage ``usability is a security
|
||||
parameter''~\cite{back01} with a new one: ``perceived usability is a
|
||||
security parameter.'' From here we can better understand the effects
|
||||
of publicity and advertising on security: the more convincing your
|
||||
of publicity on security: the more convincing your
|
||||
advertising, the more likely people will believe you have users, and thus
|
||||
the more users you will attract. Perversely, over-hyped systems (if they
|
||||
are not too broken) may be a better choice than modestly promoted ones,
|
||||
@ -473,26 +474,26 @@ other, there's an arms race between end-to-end statistical attacks and
|
||||
counter-strategies~\cite{statistical-disclosure,minion-design,e2e-traffic,trickle02}.
|
||||
But for low-latency systems like Tor, end-to-end \emph{traffic
|
||||
correlation} attacks~\cite{danezis-pet2004,defensive-dropping,SS03}
|
||||
allow an attacker who can measure both ends of a communication
|
||||
to match packet timing and volume, quickly linking
|
||||
the initiator to her destination. This is why Tor's threat model is
|
||||
based on preventing the adversary from observing both the initiator and
|
||||
the responder.
|
||||
allow an attacker who can observe both ends of a communication
|
||||
to correlate packet timing and volume, quickly linking
|
||||
the initiator to her destination.% This is why Tor's threat model is
|
||||
%based on preventing the adversary from observing both the initiator and
|
||||
%the responder.
|
||||
|
||||
Like Tor, the current JAP implementation does not pad connections
|
||||
(apart from using small fixed-size cells for transport). In fact,
|
||||
JAP's cascade-based network topology may be even more vulnerable to these
|
||||
apart from using small fixed-size cells for transport. In fact,
|
||||
JAP's cascade-based network topology may be more vulnerable to these
|
||||
attacks, because the network has fewer edges. JAP was born out of
|
||||
the ISDN mix design~\cite{isdn-mixes}, where padding made sense because
|
||||
every user had a fixed bandwidth allocation and altering the timing
|
||||
pattern of packets could be immediately detected, but in its current context
|
||||
as a general Internet web anonymizer, adding sufficient padding to JAP
|
||||
would be prohibitively expensive and probably ineffective against a
|
||||
would probably be prohibitively expensive and ineffective against a
|
||||
minimally active attacker.\footnote{Even if JAP could
|
||||
fund higher-capacity nodes indefinitely, our experience
|
||||
suggests that many users would not accept the increased per-user
|
||||
bandwidth requirements, leading to an overall much smaller user base. But
|
||||
cf.\ Section~\ref{subsec:mid-latency}.} Therefore, since under this threat
|
||||
see Section~\ref{subsec:mid-latency}.} Therefore, since under this threat
|
||||
model the number of concurrent users does not seem to have much impact
|
||||
on the anonymity provided, we suggest that JAP's anonymity meter is not
|
||||
accurately communicating security levels to its users.
|
||||
@ -509,17 +510,17 @@ on the network. We investigate this issue next.
|
||||
Another factor impacting the network's security is its reputability:
|
||||
the perception of its social value based on its current user base. If Alice is
|
||||
the only user who has ever downloaded the software, it might be socially
|
||||
accepted, but she's not getting much anonymity. Add a thousand animal rights
|
||||
activists, and she's anonymous, but everyone thinks she's a Bambi lover (or
|
||||
NRA member if you prefer a contrasting example). Add a thousand
|
||||
accepted, but she's not getting much anonymity. Add a thousand
|
||||
activists, and she's anonymous, but everyone thinks she's an activist too.
|
||||
Add a thousand
|
||||
diverse citizens (cancer survivors, privacy enthusiasts, and so on)
|
||||
and now she's harder to profile.
|
||||
|
||||
Furthermore, the network's reputability affects its node base: more people
|
||||
Furthermore, the network's reputability affects its operator base: more people
|
||||
are willing to run a service if they believe it will be used by human rights
|
||||
workers than if they believe it will be used exclusively for disreputable
|
||||
ends. This effect becomes stronger if node operators themselves think they
|
||||
will be associated with these disreputable ends.
|
||||
will be associated with their users' disreputable ends.
|
||||
|
||||
So the more cancer survivors on Tor, the better for the human rights
|
||||
activists. The more malicious hackers, the worse for the normal users. Thus,
|
||||
@ -532,7 +533,7 @@ political attacks, since it will attract fewer supporters.
|
||||
While people therefore have an incentive for the network to be used for
|
||||
``more reputable'' activities than their own, there are still tradeoffs
|
||||
involved when it comes to anonymity. To follow the above example, a
|
||||
network used entirely by cancer survivors might welcome some NRA members
|
||||
network used entirely by cancer survivors might welcome file sharers
|
||||
onto the network, though of course they'd prefer a wider
|
||||
variety of users.
|
||||
|
||||
@ -592,7 +593,7 @@ hardly likely to tell us specifics if they are.
|
||||
Tor exit node operators do attain a degree of
|
||||
``deniability'' for traffic that originates at that exit node. For
|
||||
example, it is likely in practice that HTTP requests from a Tor node's IP
|
||||
will be assumed to be from the Tor network.
|
||||
will be assumed to be from the Tor network.
|
||||
More significantly, people and organizations who use Tor for
|
||||
anonymity depend on the
|
||||
continued existence of the Tor network to do so; running a node helps to
|
||||
@ -625,20 +626,18 @@ abuse complaints. (See Section~\ref{subsec:tor-and-blacklists}.)
|
||||
%[We can enforce incentives; see Section 6.1. We can rate-limit clients.
|
||||
% We can put "top bandwidth nodes lists" up a la seti@home.]
|
||||
|
||||
|
||||
\subsection{Bandwidth and file-sharing}
|
||||
\label{subsec:bandwidth-and-file-sharing}
|
||||
%One potentially problematical area with deploying Tor has been our response
|
||||
%to file-sharing applications.
|
||||
Once users have configured their applications to work with Tor, the largest
|
||||
remaining usability issue is performance. Users begin to suffer
|
||||
when websites ``feel slow''.
|
||||
when websites ``feel slow.''
|
||||
Clients currently try to build their connections through nodes that they
|
||||
guess will have enough bandwidth. But even if capacity is allocated
|
||||
optimally, it seems unlikely that the current network architecture will have
|
||||
enough capacity to provide every user with as much bandwidth as she would
|
||||
receive if she weren't using Tor, unless far more nodes join the network
|
||||
(see above).
|
||||
receive if she weren't using Tor, unless far more nodes join the network.
|
||||
|
||||
%Limited capacity does not destroy the network, however. Instead, usage tends
|
||||
%towards an equilibrium: when performance suffers, users who value performance
|
||||
@ -650,31 +649,32 @@ Much of Tor's recent bandwidth difficulties have come from file-sharing
|
||||
applications. These applications provide two challenges to
|
||||
any anonymizing network: their intensive bandwidth requirement, and the
|
||||
degree to which they are associated (correctly or not) with copyright
|
||||
violation.
|
||||
infringement.
|
||||
|
||||
As noted above, high-bandwidth protocols can make the network unresponsive,
|
||||
but tend to be somewhat self-correcting. Issues of copyright violation,
|
||||
but tend to be somewhat self-correcting as lack of bandwidth drives away
|
||||
users who need it. Issues of copyright violation,
|
||||
however, are more interesting. Typical exit node operators want to help
|
||||
people achieve private and anonymous speech, not to help people (say) host
|
||||
Vin Diesel movies for download; and typical ISPs would rather not
|
||||
deal with customers who incur them the overhead of getting menacing letters
|
||||
deal with customers who draw menacing letters
|
||||
from the MPAA\@. While it is quite likely that the operators are doing nothing
|
||||
illegal, many ISPs have policies of dropping users who get repeated legal
|
||||
threats regardless of the merits of those threats, and many operators would
|
||||
prefer to avoid receiving legal threats even if those threats have little
|
||||
merit. So when the letters arrive, operators are likely to face
|
||||
prefer to avoid receiving even meritless legal threats.
|
||||
So when letters arrive, operators are likely to face
|
||||
pressure to block file-sharing applications entirely, in order to avoid the
|
||||
hassle.
|
||||
|
||||
But blocking file-sharing would not necessarily be easy; most popular
|
||||
protocols have evolved to run on a variety of non-standard ports in order to
|
||||
get around other port-based bans. Thus, exit node operators who wanted to
|
||||
But blocking file-sharing would not necessarily be easy; many popular
|
||||
protocols have evolved to run on a non-standard ports in order to
|
||||
get around other port-based bans. Thus, exit node operators who want to
|
||||
block file-sharing would have to find some way to integrate Tor with a
|
||||
protocol-aware exit filter. This could be a technically expensive
|
||||
undertaking, and one with poor prospects: it is unlikely that Tor exit nodes
|
||||
would succeed where so many institutional firewalls have failed. Another
|
||||
possibility for sensitive operators is to run a restrictive node that
|
||||
only permits exit connections to a restricted range of ports which are
|
||||
only permits exit connections to a restricted range of ports that are
|
||||
not frequently associated with file sharing. There are increasingly few such
|
||||
ports.
|
||||
|
||||
@ -703,7 +703,7 @@ file-sharing protocols that have separate control and data channels.
|
||||
\subsection{Tor and blacklists}
|
||||
\label{subsec:tor-and-blacklists}
|
||||
|
||||
It was long expected that, alongside Tor's legitimate users, it would also
|
||||
It was long expected that, alongside legitimate users, Tor would also
|
||||
attract troublemakers who exploited Tor in order to abuse services on the
|
||||
Internet with vandalism, rude mail, and so on.
|
||||
%[XXX we're not talking bandwidth abuse here, we're talking vandalism,
|
||||
@ -713,7 +713,7 @@ to allow individual Tor nodes to block access to specific IP/port ranges.
|
||||
This approach aims to make operators more willing to run Tor by allowing
|
||||
them to prevent their nodes from being used for abusing particular
|
||||
services. For example, all Tor nodes currently block SMTP (port 25), in
|
||||
order to avoid being used to send spam.
|
||||
order to avoid being used for spam.
|
||||
|
||||
This approach is useful, but is insufficient for two reasons. First, since
|
||||
it is not possible to force all nodes to block access to any given service,
|
||||
@ -722,18 +722,19 @@ blockable is important to being good netizens, we would like to encourage
|
||||
services to allow anonymous access; services should not need to decide
|
||||
between blocking legitimate anonymous use and allowing unlimited abuse.
|
||||
|
||||
This is potentially a bigger problem than it may appear.
|
||||
On the one hand, if people want to refuse connections from your address to
|
||||
their servers it would seem that they should be allowed. But, it's not just
|
||||
for himself that the individual node administrator is deciding when he decides
|
||||
if he wants to post to Wikipedia from his Tor node address or allow
|
||||
This is potentially a bigger problem than it may appear.
|
||||
On the one hand, people should be allowed to refuse connections to
|
||||
their services. But, it's not just
|
||||
for himself that a node administrator is deciding when he decides
|
||||
whether he prefers to be able to post to Wikipedia from his Tor node address,
|
||||
or to allow
|
||||
people to read Wikipedia anonymously through his Tor node. (Wikipedia
|
||||
has blocked all posting from all Tor nodes based on IP address.) If e.g.,
|
||||
s/he comes through a campus or corporate NAT, then the decision must
|
||||
be to have the entire population behind it able to have a Tor exit
|
||||
node or to have write access to Wikipedia. This is a loss for both Tor
|
||||
and Wikipedia. We don't want to compete for (or divvy up) the NAT
|
||||
protected entities of the world.
|
||||
has blocked all posting from all Tor nodes based on IP addresses.) If
|
||||
the Tor node shares an address with a campus or corporate NAT,
|
||||
then the decision can prevent the entire population from posting.
|
||||
This is a loss for both Tor
|
||||
and Wikipedia: we don't want to compete for (or divvy up) the
|
||||
NAT-protected entities of the world.
|
||||
|
||||
Worse, many IP blacklists are not terribly fine-grained.
|
||||
No current IP blacklist, for example, allows a service provider to blacklist
|
||||
@ -812,35 +813,37 @@ be investigated as the network develops.
|
||||
\label{subsec:tcp-vs-ip}
|
||||
|
||||
Tor transports streams; it does not tunnel packets.
|
||||
Developers of the old Freedom network~\cite{freedom21-security}
|
||||
keep telling us that IP addresses should ``obviously'' be anonymized
|
||||
at the IP layer. These issues need to be resolved before
|
||||
Tor will be ready to carry arbitrary IP traffic:
|
||||
It has often been suggested that like the old Freedom
|
||||
network~\cite{freedom21-security}, Tor should
|
||||
``obviously'' anonymize IP traffic
|
||||
at the IP layer. Before this could be done, many issues need to be resolved:
|
||||
|
||||
\begin{enumerate}
|
||||
\setlength{\itemsep}{0mm}
|
||||
\setlength{\parsep}{0mm}
|
||||
\item \emph{IP packets reveal OS characteristics.} We still need to do
|
||||
IP-level packet normalization, to stop things like IP fingerprinting
|
||||
attacks. There likely exist libraries that can help with this.
|
||||
\item \emph{IP packets reveal OS characteristics.} We would still need to do
|
||||
IP-level packet normalization, to stop things like TCP fingerprinting
|
||||
attacks.%There likely exist libraries that can help with this.
|
||||
This is unlikely to be a trivial task, given the diversity and complexity of
|
||||
various TCP stacks.
|
||||
\item \emph{Application-level streams still need scrubbing.} We still need
|
||||
Tor to be easy to integrate with user-level application-specific proxies
|
||||
such as Privoxy. So it's not just a matter of capturing packets and
|
||||
anonymizing them at the IP layer.
|
||||
\item \emph{Certain protocols will still leak information.} For example,
|
||||
we must rewrite DNS requests so they are
|
||||
delivered to an unlinkable DNS server; so we must
|
||||
understand the protocols we are transporting.
|
||||
\item \emph{Certain protocols will still leak information.} For example, we
|
||||
must rewrite DNS requests so they are delivered to an unlinkable DNS server
|
||||
rather than a DNS server at a user's ISP;thus, we must understand the
|
||||
protocols we are transporting.
|
||||
\item \emph{The crypto is unspecified.} First we need a block-level encryption
|
||||
approach that can provide security despite
|
||||
packet loss and out-of-order delivery. Freedom allegedly had one, but it was
|
||||
never publicly specified.
|
||||
Also, TLS over UDP is not implemented or even
|
||||
Also, TLS over UDP is not yet implemented or
|
||||
specified, though some early work has begun on that~\cite{dtls}.
|
||||
\item \emph{We'll still need to tune network parameters}. Since the above
|
||||
\item \emph{We'll still need to tune network parameters.} Since the above
|
||||
encryption system will likely need sequence numbers (and maybe more) to do
|
||||
replay detection, handle duplicate frames, etc., we will be reimplementing
|
||||
a subset of TCP anyway.
|
||||
replay detection, handle duplicate frames, and so on, we will be reimplementing
|
||||
a subset of TCP anyway---a notoriously tricky path.
|
||||
\item \emph{Exit policies for arbitrary IP packets mean building a secure
|
||||
IDS\@.} Our node operators tell us that exit policies are one of
|
||||
the main reasons they're willing to run Tor.
|
||||
@ -854,9 +857,11 @@ we become able to transport IP packets. We also need to compactly
|
||||
describe exit policies so clients can predict
|
||||
which nodes will allow which packets to exit.
|
||||
\item \emph{The Tor-internal name spaces would need to be redesigned.} We
|
||||
support hidden service {\tt{.onion}} addresses, and other special addresses
|
||||
like {\tt{.exit}} for the user to request a particular exit node,
|
||||
support hidden service {\tt{.onion}} addresses (and other special addresses,
|
||||
like {\tt{.exit}} which lets the user request a particular exit node),
|
||||
by intercepting the addresses when they are passed to the Tor client.
|
||||
Doing so at the IP level would require more complex interface between
|
||||
Tor and local DNS resolver.
|
||||
\end{enumerate}
|
||||
|
||||
This list is discouragingly long, but being able to transport more
|
||||
@ -866,14 +871,14 @@ items are actual roadblocks and which are easier to resolve than we think.
|
||||
To be fair, Tor's stream-based approach has run into
|
||||
stumbling blocks as well. While Tor supports the SOCKS protocol,
|
||||
which provides a standardized interface for generic TCP proxies, many
|
||||
applications do not support SOCKS\@. For them we must
|
||||
applications do not support SOCKS\@. For them we already need to
|
||||
replace the networking system calls with SOCKS-aware
|
||||
versions, or run a SOCKS tunnel locally, neither of which is
|
||||
easy for the average user. %---even with good instructions.
|
||||
Even when applications do use SOCKS, they often make DNS requests
|
||||
themselves before handing the address to Tor, which advertises
|
||||
Even when applications can use SOCKS, they often make DNS requests
|
||||
themselves before handing an IP address to Tor, which advertises
|
||||
where the user is about to connect.
|
||||
We are still working on usable solutions.
|
||||
We are still working on more usable solutions.
|
||||
|
||||
%So in order to actually provide good anonymity, we need to make sure that
|
||||
%users have a practical way to use Tor anonymously. Possibilities include
|
||||
@ -893,14 +898,15 @@ require increasingly more data~\cite{e2e-traffic}. Can we improve Tor's
|
||||
resistance without losing too much usability?
|
||||
|
||||
We need to learn whether we can trade a small increase in latency
|
||||
for a large anonymity increase, or if we'll end up trading a lot of
|
||||
latency for a small security gain. A trade could be worthwhile even if we
|
||||
can only protect certain use cases, such as infrequent short-duration
|
||||
for a large anonymity increase, or if we'd end up trading a lot of
|
||||
latency for only a minimal security gain. A trade-off might be worthwhile
|
||||
even if we
|
||||
could only protect certain use cases, such as infrequent short-duration
|
||||
transactions. % To answer this question
|
||||
We might adapt the techniques of~\cite{e2e-traffic} to a lower-latency mix
|
||||
network, where the messages are batches of cells in temporally clustered
|
||||
connections. These large fixed-size batches can also help resist volume
|
||||
signature attacks~\cite{hintz-pet02}. We can also experiment with traffic
|
||||
signature attacks~\cite{hintz-pet02}. We could also experiment with traffic
|
||||
shaping to get a good balance of throughput and security.
|
||||
%Other padding regimens might supplement the
|
||||
%mid-latency option; however, we should continue the caution with which
|
||||
@ -908,7 +914,7 @@ shaping to get a good balance of throughput and security.
|
||||
%performance or too many volunteers.
|
||||
|
||||
We must keep usability in mind too. How much can latency increase
|
||||
before we drive away our users? We're already being forced to increase
|
||||
before we drive users away? We've already been forced to increase
|
||||
latency slightly, as our growing network incorporates more DSL and
|
||||
cable-modem nodes and more nodes in distant continents. Perhaps we can
|
||||
harness this increased latency to improve anonymity rather than just
|
||||
@ -950,7 +956,8 @@ order). Using randomized path lengths may help some, since the attacker
|
||||
will never be certain he has identified all nodes in the path, but as
|
||||
long as the network remains small this attack will still be feasible.
|
||||
|
||||
Helper nodes also aim to help Tor clients, because choosing entry and exit points
|
||||
Helper nodes also aim to help Tor clients, because choosing entry and exit
|
||||
points
|
||||
randomly and changing them frequently allows an attacker who controls
|
||||
even a few nodes to eventually link some of their destinations. The goal
|
||||
is to take the risk once and for all about choosing a bad entry node,
|
||||
@ -1507,10 +1514,10 @@ minute burst in each 4 hour period.}
|
||||
|
||||
\end{document}
|
||||
|
||||
Making use of nodes with little bandwidth, or high latency/packet loss.
|
||||
%Making use of nodes with little bandwidth, or high latency/packet loss.
|
||||
|
||||
Running Tor nodes behind NATs, behind great-firewalls-of-China, etc.
|
||||
Restricted routes. How to propagate to everybody the topology? BGP
|
||||
style doesn't work because we don't want just *one* path. Point to
|
||||
Geoff's stuff.
|
||||
%Running Tor nodes behind NATs, behind great-firewalls-of-China, etc.
|
||||
%Restricted routes. How to propagate to everybody the topology? BGP
|
||||
%style doesn't work because we don't want just *one* path. Point to
|
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%Geoff's stuff.
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