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253f60d051
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1610 lines
79 KiB
TeX
1610 lines
79 KiB
TeX
\documentclass[times,10pt,twocolumn]{article}
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% If an URL ends up with '%'s in it, that's because the line *in the .bib/.tex
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% file* is too long, so break it there (it doesn't matter if the next line is
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% indented with spaces). -DH
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\begin{document}
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%% Use dvipdfm instead. --DH
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\title{Tor: Design of a 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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%Paul Syverson \\ Naval Research Lab \\ syverson@itd.nrl.navy.mil}
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\maketitle
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\thispagestyle{empty}
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\begin{abstract}
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We present Tor, a connection-based low-latency anonymous communication
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system. Tor is the successor to Onion Routing
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and addresses many limitations in the original Onion Routing design.
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Tor works in a real-world Internet environment,
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% it's user-space too
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requires little synchronization or coordination between nodes, and
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protects against known anonymity-breaking attacks as well
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as or better than other systems with similar design parameters.
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% and we present a big list of open problems at the end
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% and we present a new practical design for rendezvous points
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\end{abstract}
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%\begin{center}
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%\textbf{Keywords:} anonymity, peer-to-peer, remailer, nymserver, reply block
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%\end{center}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\Section{Overview}
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\label{sec:intro}
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Onion Routing is a distributed overlay network designed to anonymize
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low-latency TCP-based applications such as web browsing, secure shell,
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and instant messaging. Clients choose a path through the network and
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build a \emph{virtual circuit}, in which each node (or ``onion router'')
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in the path knows its
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predecessor and successor, but no others. Traffic flowing down the circuit
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is sent in fixed-size \emph{cells}, which are unwrapped by a symmetric key
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at each node (like the layers of an onion) and relayed downstream. The
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original Onion Routing project published several design and analysis
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papers
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\cite{or-jsac98,or-discex00,or-ih96,or-pet00}. While there was briefly
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a wide area Onion Routing network,
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% how long is briefly? a day, a month? -RD
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the only long-running and publicly accessible
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implementation was a fragile proof-of-concept that ran on a single
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machine (which nonethless processed several tens of thousands of connections
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daily from thousands of global users).
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Many critical design and deployment issues were never resolved,
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and the design has not been updated in several years.
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Here we describe Tor, a protocol for asynchronous, loosely
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federated onion routers that provides the following improvements over
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the old Onion Routing design, and over other low-latency anonymity systems:
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\begin{tightlist}
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\item \textbf{Perfect forward secrecy:} The original Onion Routing
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design was vulnerable to a single hostile node recording traffic and later
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compromising successive nodes in the circuit and forcing them to
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decrypt it.
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Rather than using a single onion to lay each circuit,
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Tor now uses an incremental or \emph{telescoping}
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path-building design, where the initiator negotiates session keys with
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each successive hop in the circuit. Once these keys are deleted,
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subsequently compromised nodes cannot decrypt old traffic.
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As a side benefit, onion replay detection is no longer
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necessary, and the process of building circuits is more reliable, since
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the initiator knows when a hop fails and can then try extending to a new node.
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% Perhaps mention that not all of these are things that we invented. -NM
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\item \textbf{Separation of protocol cleaning from anonymity:}
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The original Onion Routing design required a separate ``application
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proxy'' for each
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supported application protocol --- most
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of which were never written, so many applications were never supported.
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Tor uses the standard and near-ubiquitous SOCKS
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\cite{socks4,socks5} proxy interface, allowing us to support most TCP-based
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programs without modification. This design change allows Tor to
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use the filtering features of privacy-enhancing
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application-level proxies such as Privoxy without having to
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incorporate those features itself.
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\item \textbf{Many TCP streams can share one circuit:} The original
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Onion Routing design built a separate circuit for each application-level
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request.
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This hurt performance by requiring multiple public key operations for
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every request, and also presented
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a threat to anonymity (see Section~\ref{maintaining-anonymity}).
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\footnote{The first Onion Routing design \cite{or-ih96} protected against
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this threat to some
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extent by requiring users to hide network access behind an onion
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router/firewall that was also forwarding traffic from other nodes.
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However, it is desirable for users to
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benefit from Onion Routing even when they can't run their own
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onion routers.
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%Such users, especially if they engage in certain unusual
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%communication behaviors, may be identifiable \cite{wright03}.
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%To
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%complicate the possibility of such attacks Tor multiplexes many
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%stream down each circuit, but still rotates the circuit
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%periodically to avoid too much linkability from requests on a single
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%circuit.
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%
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% [This digression probably belongs in maintaining-anonymity. -NM
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}
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The current Tor design multiplexes multiple TCP streams along each virtual
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circuit, in order to improve efficiency and anonymity.
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\item \textbf{No mixing, padding, or traffic shaping:} The original
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Onion Routing design called for mixing of data from each circuit,
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plus full link padding both between onion routers and between onion
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proxies (that is, users) and onion routers \cite{or-jsac98}. The
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later analysis paper \cite{or-pet00} suggested \emph{traffic shaping}
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to provide similar protection but use less bandwidth, but did not go
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into detail. However, recent research \cite{econymics} and deployment
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experience \cite{freedom21-security} suggest that this level of resource
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use is not practical or economical; and even full link padding is still
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vulnerable \cite{defensive-dropping}. Thus, until we have a proven and
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convenient design for traffic shaping or low-latency mixing that will help
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anonymity against a realistic adversary, we leave these strategies out.
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\item \textbf{Leaky-pipe circuit topology:} Through in-band
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signalling within the
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circuit, Tor initiators can direct traffic to nodes partway down the
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circuit. This not only allows for long-range padding to frustrate traffic
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shape and volume attacks at the initiator \cite{defensive-dropping},
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but because circuits are used by more than one application, it also
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allows traffic to exit the circuit from the middle -- thus
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frustrating traffic shape and volume attacks based on observing exit
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points.
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%Or something like that. hm. Tone this down maybe? Or support it. -RD
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%How's that? -PS
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\item \textbf{Congestion control:} Earlier anonymity designs do not
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address traffic bottlenecks. Unfortunately, typical approaches to load
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balancing and flow control in overlay networks involve inter-node control
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communication and global views of traffic. Tor's decentralized ack-based
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congestion control maintains reasonable anonymity while allowing nodes
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at the edges of the network to detect congestion or flooding attacks
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and send less data until the congestion subsides.
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\item \textbf{Directory servers:} The original Onion Routing design
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planned to flood link-state information through the network --- an
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approach which can be unreliable and
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open to partitioning attacks or outright deception. Tor takes a simplified
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view towards distributing link-state information. Certain more trusted
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onion routers also serve as directory servers; they provide signed
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\emph{directories} describing all routers they know about, and which
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are currently up. Users periodically download these directories via HTTP.
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\item \textbf{End-to-end integrity checking:} Without integrity checking
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on traffic going through the network, any onion router on the path
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can change the contents of cells as they pass by --- for example, to redirect a
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connection on the fly so it connects to a different webserver, or to
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tag encrypted traffic and look for the tagged traffic at the network
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edges \cite{minion-design}. Tor hampers these attacks by checking data
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integrity before it leaves the network.
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\item \textbf{Robustness to failed nodes:} A failed node in a traditional
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mix network means lost messages, but thanks to Tor's step-by-step
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circuit building, users can notice failed
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nodes while building circuits and route around them. Additionally,
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liveness information from directories allows users to avoid
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unreliable nodes in the first place.
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%We further provide a
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%simple mechanism that allows connections to be established despite recent
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%node failure or slightly dated information from a directory server. Tor
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%permits onion routers to have \emph{router twins} --- nodes that share
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%the same private decryption key. Note that because connections now have
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%perfect forward secrecy, an onion router still cannot read the traffic
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%on a connection established through its twin even while that connection
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%is active. Also, which nodes are twins can change dynamically depending
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%on current circumstances, and twins may or may not be under the same
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%administrative authority.
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%
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%[Commented out; Router twins provide no real increase in robustness
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%to failed nodes. If a non-twinned node goes down, the
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%circuit-builder notices this and routes around it. Circuit-building
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%is offline, so there shouldn't even be a latency hit. -NM]
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\item \textbf{Variable exit policies:} Tor provides a consistent
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mechanism for
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each node to specify and advertise a policy describing the hosts and
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ports to which it will connect. These exit policies
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are critical in a volunteer-based distributed infrastructure, because
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each operator is comfortable with allowing different types of traffic
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to exit the Tor network from his node.
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\item \textbf{Implementable in user-space:} Because it only attempts to
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anonymize TCP streams, Tor differs from other anonymity systems like
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Freedom \cite{freedom} in that it does not require patches to an operating
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system's network stack in order to operate. Although this approach is less
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flexible, it has proven valuable to Tor's portability and deployability.
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\item \textbf{Rendezvous points and location-protected servers:} Tor
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provides an integrated mechanism for responder anonymity via
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location-protected servers. Previous Onion Routing designs included
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long-lived ``reply onions'' which could be used to build virtual
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circuits to a hidden server, but this approach is
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brittle because a reply onion becomes useless if any node in the
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path goes down or rotates its keys, and it's also
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%vulnerable to flooding attacks,
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% no it isn't. no more than our rendezvous point approach at least -RD
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incompatible with forward security. In Tor's
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current design, clients use {\it introduction points} to negotiate {\it
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rendezvous points} to connect with hidden servers; and reply onions
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are no longer required.
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\end{tightlist}
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[XXX carefully mention implementation, emphasizing that experience
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deploying isn't there yet, and not all features are implemented.
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Mention that it runs, is kinda alpha, kinda deployed, runs on win32.]
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We review previous work in Section \ref{sec:background}, describe
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our goals and assumptions in Section \ref{sec:assumptions},
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and then address the above list of improvements in Sections
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\ref{sec:design}-\ref{sec:maintaining-anonymity}. We then summarize
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how our design stands up to known attacks, and conclude with a list of
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open problems.
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\Section{Background and threat model}
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\label{sec:background}
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\SubSection{Related work}
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\label{sec:related-work}
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Modern anonymity designs date to Chaum's Mix-Net\cite{chaum-mix} design of
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1981. Chaum proposed hiding sender-recipient connections by wrapping
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messages in several layers of public key cryptography, and relaying them
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through a path composed of Mix servers. Mix servers in turn decrypt, delay,
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and re-order messages, before relay them along the path towards their
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destinations.
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Subsequent relay-based anonymity designs have diverged in two
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principal directions. Some have attempted to maximize anonymity at
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the cost of introducing comparatively large and variable latencies,
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for example, Babel\cite{babel}, Mixmaster\cite{mixmaster-spec}, and
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Mixminion\cite{minion-design}. Because of this
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trade-off, such \emph{high-latency} networks are well-suited for anonymous
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email, but introduce too much lag for interactive tasks such as web browsing,
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internet chat, or SSH connections.
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% Parts of this graf belongs later in expository order. Some of the
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% sentences seem superficially unrelated.
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Tor belongs to the second category: \emph{low-latency} designs that
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attempt to anonymize interactive network traffic. Because such
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traffic tends to involve a relatively large numbers of packets, it is
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difficult to prevent an attacker who can eavesdrop entry and exit
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points from correlating packets entering the anonymity network with
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packets leaving it. Although some work has been done to frustrate
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these attacks, most designs protect primarily against traffic analysis
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rather than traffic confirmation \cite{or-jsac98}. One can pad and
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limit communication to a constant rate or at least to control the
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variation in traffic shape. This can have prohibitive bandwidth costs
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and/or performance limitations. One can also use a cascade (fixed
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shared route) with a relatively fixed set of users. This assumes a
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significant degree of agreement and provides an easier target for an active
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attacker since the endpoints are generally known.
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The simplest low-latency designs are single-hop proxies such as the
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Anonymizer \cite{anonymizer}, wherein a single trusted server removes
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identifying users' data before relaying it. These designs are easy to
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analyze, but require end-users to trust the anonymizing proxy.
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More complex are distributed-trust, channel-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 a
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number of low-latency packets to and from one or more destinations per
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tunnel. Establishing tunnels is comparatively 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 learn the user's communication partners.
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The Java Anon Proxy (aka JAP aka WebMIXes) is based on the cascade
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approach mentioned above. Like a single-hop proxy a single cascade has
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the advantage of concentrating all the concurrent users in one
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communication pipe, making for potentially large anonymity sets.
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Also, like a single-hop proxy, it is easy to know where any
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communication is entering or leaving the network. Thus, though there
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is no single trusted server, it is potentially easy to simply bridge
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the entire cascade, i.e., to obviate its purpose. The design prevents
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this by padding between end users and the head of the cascade
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\cite{web-mix}. However, the current implementation does not do such
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padding and thus remains vulnerable to both active and passive
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bridging.
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%[Ouch: We haven't said what an onion is yet, but we use the word here! -NM]
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Systems such as earlier versions of Freedom and the original Onion Routing
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build the anonymous channel all at once (using an onion of public-key
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encrypted messages, each layer of which provided a session key and pointer
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to the address corresponding to the next layer's key).
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Later designs of Freedom and Tor as described herein build
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the channel in stages, as does AnonNet
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\cite{anonnet}. Amongst other things, this makes perfect forward
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secrecy feasible.
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Some systems, such as Crowds \cite{crowds-tissec}, do not rely on the
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changing appearance of packets to hide the path; rather they employ
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mechanisms so that an intermediary cannot be sure when it is
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receiving from/sending to the ultimate initiator. There is no public-key
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encryption needed for Crowds, but the responder and all data are
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visible to all nodes on the path so that anonymity of connection
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initiator depends on filtering all identifying information from the
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data stream. Crowds is also designed only for HTTP traffic.
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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
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P5 \cite{p5} go even further requiring broadcast.
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They each use broadcast in different ways, and tradeoffs are made to
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make broadcast more practical. Both Herbivore and P5 are designed primarily
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for communication between communicating peers, although Herbivore
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permits external connections by requesting a peer to serve as a proxy.
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Allowing easy connections to nonparticipating responders or recipients
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is a practical requirement for many users, e.g., to visit
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nonparticipating Web sites or to exchange mail with nonparticipating
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recipients.
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Distributed-trust anonymizing systems differ in how they prevent attackers
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from controlling too many servers and thus compromising too many user paths.
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Some protocols rely on a centrally maintained set of well-known anonymizing
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servers. The current Tor design falls into this category.
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Others (such as Tarzan and MorphMix) allow unknown users to run
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servers, while using a limited resource (DHT space for Tarzan; IP space for
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MorphMix) to prevent an attacker from owning too much of the network.
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Crowds uses a centralized ``blender'' to enforce Crowd membership
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policy. For small crowds it is suggested that familiarity with all
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members is adequate. For large diverse crowds, limiting accounts in
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control of any one party is more difficult:
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``(e.g., the blender administrator sets up an account for a user only
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after receiving a written, notarized request from that user) and each
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account to one jondo, and by monitoring and limiting the number of
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jondos on any one net- work (using IP address), the attacker would be
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forced to launch jondos using many different identities and on many
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different networks to succeed'' \cite{crowds-tissec}.
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Another low-latency design that was proposed independently and at
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about the same time as the original Onion Routing was PipeNet
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\cite{pipenet}. It provided anonymity protections that were stronger
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than Onion Routing's, but at the cost of allowing a single user to
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shut down the network simply by not sending. It was also never
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implemented or formally published. Low-latency anonymous communication
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has also been designed for other types of systems, including
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ISDN \cite{isdn-mixes}, and mobile applications such as telephones and
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active badging systems \cite{federrath-ih96,reed-protocols97}.
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Tor is not primarily designed for censorship resistance but rather
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for anonymous communication. However, Tor's rendezvous points, which
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enable connections between mutually anonymous entities, also
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facilitate connections to hidden servers. These building blocks to
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censorship resistance and other capabilities are described in
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Section~\ref{sec:rendezvous}. Location-hidden servers are an
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essential component for anonymous publishing systems such as
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Publius\cite{publius}, Free Haven\cite{freehaven-berk}, and
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Tangler\cite{tangler}.
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[XXX I'm considering the subsection as ended here for now. I'm leaving the
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following notes in case we want to revisit any of them. -PS]
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Channel-based anonymizing systems also differ in their use of dummy traffic.
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[XXX]
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Finally, several systems provide low-latency anonymity without channel-based
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communication. Crowds and [XXX] provide anonymity for HTTP requests; [...]
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[XXX Mention error recovery?]
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STILL NOT MENTIONED:
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real-time mixes\\
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rewebbers\\
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cebolla\\
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Rewebber was mentioned in an earlier version along with Eternity,
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which *must* be mentioned if we cite anything at all
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in censorship resistance.
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[XXX Close by mentioning where Tor fits.]
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\Section{Design goals and assumptions}
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|
\label{sec:assumptions}
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\subsection{Goals}
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% Reformat this section like ``Adversary Model'' is formatted. -NM
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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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main goal, however, several design considerations have directed
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Tor's evolution.
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First, we have tried to build a {\bf deployable} system. [XXX why?]
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This requirement precludes designs that are expensive to run (for
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example, by requiring more bandwidth than volunteers will easily
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provide); designs that place a heavy liability burden on operators
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(for example, by allowing attackers to implicate operators in illegal
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|
activities); and designs that are difficult or expensive to implement
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|
(for example, by requiring kernel patches to many operating systems,
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or ). [Only anon people need to run special software! Look at minion
|
|
reviews]
|
|
|
|
Second, the system must be {\bf usable}. A hard-to-use system has
|
|
fewer users --- and because anonymity systems hide users among users, a
|
|
system with fewer users provides less anonymity. Thus, usability is
|
|
not only a convenience, but is a security requirement for anonymity
|
|
systems. In order to be usable, Tor should with most of a
|
|
user's unmodified aplication; shouldn't introduce prohibitive delays; and
|
|
[XXX what else?].
|
|
|
|
Third, the protocol must be {\bf extensible}, so that it can serve as
|
|
a test-bed for future research in low-latency anonymity systems.
|
|
(Note that while an extensible protocol benefits researchers, there is
|
|
a danger that differing choices of extensions will render users
|
|
distinguishable. Thus, implementations should not permit different
|
|
protocol extensions to coexist in a single deployed network.)
|
|
|
|
% We should mention that there's a specification someplace: the spec makes us
|
|
% easier to extend too. -NM
|
|
|
|
The protocol's design and security parameters must be {\bf
|
|
conservative}. Additional features impose implementation and
|
|
complexity costs. [XXX Say that we don't want to try to come up with
|
|
speculative solutions to problems we don't KNOW how to solve? -NM]
|
|
|
|
\subsection{Non-goals}
|
|
In favoring conservative, deployable designs, we have explicitly
|
|
deferred a number of goals --- not because they are not desirable in
|
|
anonymity systems --- but because they are either solved
|
|
elsewhere, or an area of active research without a generally accepted
|
|
solution.
|
|
|
|
Unlike Tarzan or Morphmix, Tor does not attempt to scale to completely
|
|
decentralized peer-to-peer environments with thousands of short-lived
|
|
servers, many of which may be controlled by an adversary.
|
|
|
|
Tor does not claim to provide a definitive solution to end-to-end
|
|
timing or intersection attacks for users who do not run their own
|
|
Onion Routers.
|
|
% Mention would-be approaches. -NM
|
|
% Does that mean we do claim to solve intersection attack for
|
|
% the enclave-firewall model? -RD
|
|
|
|
Tor does not provide \emph{protocol normalization} like the Anonymizer or
|
|
Privoxy. In order to provide client indistinguishibility for
|
|
complex and variable protocols such as HTTP, Tor must be layered with
|
|
a filtering proxy such as Privoxy. Similarly, Tor does not currently
|
|
integrate tunneling for non-stream-based protocols; this too must be
|
|
provided by an external service.
|
|
|
|
Tor is not steganographic: it doesn't try to conceal which users are
|
|
sending or receiving communications.
|
|
|
|
|
|
\SubSection{Adversary Model}
|
|
\label{subsec:adversary-model}
|
|
|
|
Like all practical low-latency systems, Tor is not secure against a
|
|
global passive adversary, which is the most commonly assumed adversary
|
|
for analysis of theoretical anonymous communication designs. The adversary
|
|
we assume
|
|
is weaker than global with respect to distribution, but it is not
|
|
merely passive.
|
|
We assume a threat model that expands on that from \cite{or-pet00}.
|
|
|
|
|
|
The basic adversary components we consider are:
|
|
\begin{description}
|
|
\item[Observer:] can observe a connection (e.g., a sniffer on an
|
|
Internet router), but cannot initiate connections. Observations may
|
|
include timing and/or volume of packets as well as appearance of
|
|
individual packets (including headers and content).
|
|
\item[Disrupter:] can delay (indefinitely) or corrupt traffic on a
|
|
link. Can change all those things that an observer can observe up to
|
|
the limits of computational ability (e.g., cannot forge signatures
|
|
unless a key is compromised).
|
|
\item[Hostile initiator:] can initiate (or destroy) connections with
|
|
specific routes as well as vary the timing and content of traffic
|
|
on the connections it creates. A special case of the disrupter with
|
|
additional abilities appropriate to its role in forming connections.
|
|
\item[Hostile responder:] can vary the traffic on the connections made
|
|
to it including refusing them entirely, intentionally modifying what
|
|
it sends and at what rate, and selectively closing them. Also a
|
|
special case of the disrupter.
|
|
\item[Key breaker:] can break the key used to encrypt connection
|
|
initiation requests sent to a Tor-node.
|
|
% Er, there are no long-term private decryption keys. They have
|
|
% long-term private signing keys, and medium-term onion (decryption)
|
|
% keys. Plus short-term link keys. Should we lump them together or
|
|
% separate them out? -RD
|
|
%
|
|
% Hmmm, I was talking about the keys used to encrypt the onion skin
|
|
% that contains the public DH key from the initiator. Is that what you
|
|
% mean by medium-term onion key? (``Onion key'' used to mean the
|
|
% session keys distributed in the onion, back when there were onions.)
|
|
% Also, why are link keys short-term? By link keys I assume you mean
|
|
% keys that neighbor nodes use to superencrypt all the stuff they send
|
|
% to each other on a link. Did you mean the session keys? I had been
|
|
% calling session keys short-term and everything else long-term. I
|
|
% know I was being sloppy. (I _have_ written papers formalizing
|
|
% concepts of relative freshness.) But, there's some questions lurking
|
|
% here. First up, I don't see why the onion-skin encryption key should
|
|
% be any shorter term than the signature key in terms of threat
|
|
% resistance. I understand that how we update onion-skin encryption
|
|
% keys makes them depend on the signature keys. But, this is not the
|
|
% basis on which we should be deciding about key rotation. Another
|
|
% question is whether we want to bother with someone who breaks a
|
|
% signature key as a particular adversary. He should be able to do
|
|
% nearly the same as a compromised tor-node, although they're not the
|
|
% same. I reworded above, I'm thinking we should leave other concerns
|
|
% for later. -PS
|
|
|
|
|
|
\item[Hostile Tor node:] can arbitrarily manipulate the
|
|
connections under its control, as well as creating new connections
|
|
(that pass through itself).
|
|
\end{description}
|
|
|
|
|
|
All feasible adversaries can be composed out of these basic
|
|
adversaries. This includes combinations such as one or more
|
|
compromised Tor-nodes cooperating with disrupters of links on which
|
|
those nodes are not adjacent, or such as combinations of hostile
|
|
outsiders and link observers (who watch links between adjacent
|
|
Tor-nodes). Note that one type of observer might be a Tor-node. This
|
|
is sometimes called an honest-but-curious adversary. While an observer
|
|
Tor-node will perform only correct protocol interactions, it might
|
|
share information about connections and cannot be assumed to destroy
|
|
session keys at end of a session. Note that a compromised Tor-node is
|
|
stronger than any other adversary component in the sense that
|
|
replacing a component of any adversary with a compromised Tor-node
|
|
results in a stronger overall adversary (assuming that the compromised
|
|
Tor-node retains the same signature keys and other private
|
|
state-information as the component it replaces).
|
|
|
|
|
|
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
|
|
the particular client is communicating with the particular server will
|
|
be able to confirm this if she can attack 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 will be
|
|
able to confirm if the timing and volume properties of the traffic on
|
|
the connnection 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. However, we note here some
|
|
basic assumptions that affect the threat model.
|
|
|
|
[XXX I think this next subsection should be cut, leaving its points
|
|
for the attacks section. But I'm leaving it here for now. The above
|
|
line refers to the immediately following SubSection.-PS]
|
|
|
|
|
|
\SubSection{Known attacks against low-latency anonymity systems}
|
|
\label{subsec:known-attacks}
|
|
% Should be merged into ``Threat model'' and reiterated in Attacks. -NM
|
|
|
|
We discuss each of these attacks in more detail below, along with the
|
|
aspects of the Tor design that provide defense. We provide a summary
|
|
of the attacks and our defenses against them in Section~\ref{sec:attacks}.
|
|
|
|
Passive attacks:
|
|
simple observation,
|
|
timing correlation,
|
|
size correlation,
|
|
option distinguishability,
|
|
|
|
Active attacks:
|
|
key compromise,
|
|
iterated subpoena,
|
|
run recipient,
|
|
run a hostile node,
|
|
compromise entire path,
|
|
selectively DOS servers,
|
|
introduce timing into messages,
|
|
directory attacks,
|
|
tagging attacks,
|
|
smear attacks,
|
|
entrapment attacks
|
|
|
|
|
|
\SubSection{Assumptions}
|
|
% Should be merged into ``Threat model''.
|
|
|
|
For purposes of this paper, we assume all directory servers are honest
|
|
% No longer true, see subsec:dirservers below -RD
|
|
and trusted. Perhaps more accurately, we assume that all users and
|
|
nodes can perform their own periodic checks on information they have
|
|
from directory servers and that all will always have access to at
|
|
least one directory server that they trust and from which they obtain
|
|
all directory information. Future work may include robustness
|
|
techniques to cope with a minority dishonest servers.
|
|
|
|
Somewhere between ten percent and twenty percent of nodes are assumed
|
|
to be compromised. In some circumstances, e.g., if the Tor network is
|
|
running on a hardened network where all operators have had
|
|
background checks, the percent of compromised nodes might be much
|
|
lower. It may be worthwhile to consider cases where many of the `bad'
|
|
nodes are not fully compromised but simply (passive) observing
|
|
adversaries or that some nodes have only had compromise of the keys
|
|
that decrypt connection initiation requests. But, we assume for
|
|
simplicity that `bad' nodes are compromised in the sense spelled out
|
|
above. We assume that all adversary components, regardless of their
|
|
capabilities are collaborating and are connected in an offline clique.
|
|
|
|
Users are assumed to vary widely in both the duration and number of
|
|
times they are connected to the Tor network. They can also be assumed
|
|
to vary widely in the volume and shape of the traffic they send and
|
|
receive. Hostile users are, by definition, limited to creating and
|
|
varying their own connections into or through a Tor network. They may
|
|
attack their own connections to try to gain identity information of
|
|
the responder in a rendezvous connection. They may also try to attack
|
|
sites through the Onion Routing network; however we will consider
|
|
this abuse rather than an attack per se (see
|
|
Section~\ref{subsec:exitpolicies}). Other than these, a hostile user's
|
|
motivation to attack his own connections is limited to the network
|
|
effects of such actions, e.g., DoS. Thus, in this case, we can view a
|
|
hostile 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.
|
|
|
|
% We do not assume any hostile users, except in the context of
|
|
%
|
|
% This sounds horrible. What do you mean we don't assume any hostile
|
|
% users? Surely we can tolerate some? -RD
|
|
%
|
|
% Better? -PS
|
|
|
|
|
|
[XXX what else?]
|
|
|
|
|
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
|
|
\Section{The Tor Design}
|
|
\label{sec:design}
|
|
|
|
The Tor network is an overlay network; each node is called an onion router
|
|
(OR). Onion routers run on normal computers without needing any special
|
|
privileges. Each OR maintains a long-term TLS connection to every other
|
|
OR (although we look at ways to relax this clique-topology assumption in
|
|
section \ref{subsec:restricted-routes}). A subset of the ORs also act as
|
|
directory servers, tracking which routers are currently in the network;
|
|
see section \ref{subsec:dirservers} for directory server details. Users
|
|
run local software called an onion proxy (OP) that fetches directories,
|
|
establishes paths (called \emph{virtual circuits}) over the network,
|
|
and handles connections from the user applications. Onion proxies accept
|
|
TCP streams and multiplex them across the virtual circuit. The onion
|
|
router on the other side
|
|
% I don't mean other side, I mean wherever it is on the circuit. But
|
|
% don't want to introduce complexity this early? Hm. -RD
|
|
of the circuit connects to the destinations of
|
|
the TCP streams and relays data.
|
|
|
|
Onion routers have three types of keys. The first key is the identity
|
|
(signing) key. An OR uses this key to sign TLS certificates, to sign its
|
|
router descriptor (a summary of its keys, address, bandwidth, exit policy,
|
|
etc), and to sign directories if it is a directory server. Changing the
|
|
identity key of a router is considered equivalent to creating a new
|
|
router. The second key is the onion (decryption) key, which is used
|
|
for decrypting requests from users to set up a circuit and negotiate
|
|
ephemeral keys. Thirdly, each OR shares link keys (generated by TLS)
|
|
with the other ORs it's connected to. We discuss rotating these keys in
|
|
Section \ref{subsec:rotating-keys}.
|
|
|
|
Section \ref{subsec:cells} discusses the structure of the fixed-size
|
|
\emph{cells} that are the unit of communication in Tor. We describe
|
|
in Section \ref{subsec:circuits} how circuits work, and how they are
|
|
built, extended, truncated, and destroyed. Section \ref{subsec:tcp}
|
|
discusses the process of opening TCP streams through Tor, and finally
|
|
Section \ref{subsec:congestion} talks about congestion control and
|
|
fairness issues.
|
|
|
|
\SubSection{Cells}
|
|
\label{subsec:cells}
|
|
|
|
Traffic passes from node to node in fixed-size cells. Each cell is 256
|
|
bytes, and consists of a header and a payload. The header includes the
|
|
circuit identifier (ACI) which specifies which circuit the cell refers to
|
|
(many circuits can be multiplexed over the single TCP connection between
|
|
ORs or between an OP and an OR), and a command to describe what to do
|
|
with the cell's payload. Cells are either control cells, meaning they are
|
|
intended to be interpreted by the node that receives them, or relay cells,
|
|
meaning they carry end-to-end stream data. Controls cells can be one of:
|
|
\emph{padding} (currently used for keepalive, but can be used for link
|
|
padding), \emph{create} or \emph{created} (to set up a new circuit),
|
|
or \emph{destroy} (to tear down a circuit).
|
|
|
|
Relay cells have an additional header (the relay header) after the
|
|
cell header, which specifies the stream identifier (many streams can
|
|
be multiplexed over a circuit), an end-to-end checksum for integrity
|
|
checking, the length of the relay payload, and a relay command. Relay
|
|
commands can be one of: \emph{relay
|
|
data} (for data flowing down the stream), \emph{relay begin} (to open a
|
|
stream), \emph{relay end} (to close a stream), \emph{relay connected}
|
|
(to notify the OP that a relay begin has succeeded), \emph{relay
|
|
extend} and \emph{relay extended} (to extend the circuit by a hop,
|
|
and to acknowledge), \emph{relay truncate} and \emph{relay truncated}
|
|
(to tear down only part of the circuit, and to acknowledge), \emph{relay
|
|
sendme} (used for congestion control), and \emph{relay drop} (used to
|
|
implement long-range dummies).
|
|
|
|
We will talk more about each of these cell types below.
|
|
|
|
% Nick: should there have been a table here? -RD
|
|
|
|
\SubSection{Circuits and streams}
|
|
\label{subsec:circuits}
|
|
|
|
While the original Onion Routing design built one circuit for each stream,
|
|
Tor circuits can be used by many streams. Thus because circuits can
|
|
take several tenths of a second to construct due to crypto and network
|
|
latency, users construct circuits preemptively. Users build a new circuit
|
|
periodically (currently every minute) if the previous one has been used,
|
|
and expire old used circuits that are no longer in use. Thus even very
|
|
active users spend a negligible amount of time and CPU in building
|
|
circuits, but only a limited number of requests can be linked to each
|
|
other by a given exit node.
|
|
|
|
Users set up circuits incrementally, negotiating a symmetric key with
|
|
each hop one at a time. To create a new circuit, the user (call her
|
|
Alice) sends a \emph{create} cell to the first node in her chosen
|
|
path. The payload is the first half of the Diffie-Hellman handshake,
|
|
encrypted to the onion key of the OR (call him Bob). Bob responds with a
|
|
\emph{created} cell with the second half of the DH handshake, along with
|
|
a hash of $K=g^{xy}$. The goal is to get unilateral entity authentication
|
|
(Alice knows she's handshaking with Bob, Bob doesn't care who it is ---
|
|
recall that Alice has no key and is trying to remain anonymous) and
|
|
unilateral key authentication (Alice and Bob agree on a key, and Alice
|
|
knows Bob is the only other person who could know it --- if he is
|
|
honest, etc.). We also want perfect forward secrecy, key freshness, etc.
|
|
|
|
\begin{equation}
|
|
\begin{aligned}
|
|
\mathrm{Alice} \rightarrow \mathrm{Bob}&: E_{PK_{Bob}}(g^x) \\
|
|
\mathrm{Bob} \rightarrow \mathrm{Alice}&: g^y, H(K | \mathrm{``handshake"}) \\
|
|
\end{aligned}
|
|
\end{equation}
|
|
|
|
The second step shows both that it was Bob
|
|
who received $g^x$, and that it was Bob who came up with $y$. We use
|
|
PK encryption in the first step (rather than, e.g., using the first two
|
|
steps of STS, which has a signature in the second step) because we
|
|
don't have enough room in a single cell for a public key and also a
|
|
signature. Preliminary analysis with the NRL protocol analyzer shows
|
|
the above protocol to be secure (including providing PFS) under the
|
|
traditional Dolev-Yao model.
|
|
% cite Cathy? -RD
|
|
% did I use the buzzwords correctly? -RD
|
|
|
|
To extend a circuit past the first hop, Alice sends a \emph{relay extend}
|
|
cell to the last node in the circuit, specifying the address of the new
|
|
OR and an encrypted $g^x$ for it. That node copies the half-handshake
|
|
into a \emph{create} cell, and passes it to the new OR to extend the
|
|
circuit. When it responds with a \emph{created} cell, the penultimate OR
|
|
copies the payload into a \emph{relay extended} cell and passes it back.
|
|
% Nick: please fix my "that OR" pronouns -RD
|
|
|
|
Once Alice has established the circuit (so she shares a key with each
|
|
OR on the circuit), she can send relay cells.
|
|
%The stream ID in the relay header indicates to which stream the cell belongs.
|
|
% Nick: should i include the above line?
|
|
% Paul says yes. -PS
|
|
Alice can address each relay cell to any of the ORs on the circuit. To
|
|
construct a relay cell destined for a given OR, she iteratively
|
|
encrypts the cell payload (that is, the relay header and payload)
|
|
with the symmetric key of each hop up to that node. Then, at each hop
|
|
down the circuit, the OR decrypts the cell payload and checks whether
|
|
it recognizes the stream ID. A stream ID is recognized either if it
|
|
is an already open stream at that OR, or if it is equal to zero. The
|
|
zero stream ID is treated specially, and is used for control messages,
|
|
e.g. starting a new stream. If the stream ID is unrecognized, the OR
|
|
passes the relay cell downstream. This \emph{leaky pipe} circuit design
|
|
allows Alice's streams to exit at different ORs, for example to tolerate
|
|
different exit policies, or to keep the ORs from knowing that two streams
|
|
originate at the same person.
|
|
|
|
To tear down a circuit, Alice sends a destroy control cell. Each OR
|
|
in the circuit receives the destroy cell, closes all open streams on
|
|
that circuit, and passes a new destroy cell forward. But since circuits
|
|
can be built incrementally, they can also be torn down incrementally:
|
|
Alice can send a relay truncate cell to a node along the circuit. That
|
|
node will send a destroy cell forward, and reply with an acknowledgement
|
|
(relay truncated). Alice might truncate her circuit so she can extend it
|
|
to different nodes without signaling to the first few nodes (or somebody
|
|
observing them) that she is changing her circuit. That is, nodes in the
|
|
middle are not even aware that the circuit was truncated, because the
|
|
relay cells are encrypted. Similarly, if a node on the circuit goes down,
|
|
the adjacent node can send a relay truncated back to Alice. Thus the
|
|
``break a node and see which circuits go down'' attack is weakened.
|
|
|
|
\SubSection{Opening and closing streams}
|
|
\label{subsec:tcp}
|
|
|
|
When Alice's application wants to open a TCP connection to a given
|
|
address and port, it asks the OP (via SOCKS) to make the connection. The
|
|
OP chooses the newest open circuit (or creates one if none is available),
|
|
chooses a suitable OR on that circuit to be the exit node (usually the
|
|
last node, but maybe others due to exit policy conflicts; see Section
|
|
\ref{sec:exit-policies}), chooses a new random stream ID for this stream,
|
|
and delivers a relay begin cell to that exit node. It uses a stream ID
|
|
of zero for the begin cell (so the OR will recognize it), and the relay
|
|
payload lists the new stream ID and the destination address and port.
|
|
Once the exit node completes the connection to the remote host, it
|
|
responds with a relay connected cell through the circuit. Upon receipt,
|
|
the OP notifies the application that it can begin talking.
|
|
|
|
There's a catch to using SOCKS, though -- some applications hand the
|
|
alphanumeric address to the proxy, while others resolve it into an IP
|
|
address first and then hand the IP to the proxy. When the application
|
|
does the DNS resolution first, Alice broadcasts her destination. Common
|
|
applications like Mozilla and ssh have this flaw.
|
|
|
|
In the case of Mozilla, we're fine: the filtering web proxy called Privoxy
|
|
does the SOCKS call safely, and Mozilla talks to Privoxy safely. But a
|
|
portable general solution, such as for ssh, is an open problem. We could
|
|
modify the local nameserver, but this approach is invasive, brittle, and
|
|
not portable. We could encourage the resolver library to do resolution
|
|
via TCP rather than UDP, but this approach is hard to do right, and also
|
|
has portability problems. Our current answer is to encourage the use of
|
|
privacy-aware proxies like Privoxy wherever possible, and also provide
|
|
a tool similar to \emph{dig} that can do a private lookup through the
|
|
Tor network.
|
|
|
|
Ending a Tor stream is analogous to ending a TCP stream: it uses a
|
|
two-step handshake for normal operation, or a one-step handshake for
|
|
errors. If one side of the stream closes abnormally, that node simply
|
|
sends a relay teardown cell, and tears down the stream. If one side
|
|
% Nick: mention relay teardown in 'cell' subsec? good enough name? -RD
|
|
of the stream closes the connection normally, that node sends a relay
|
|
end cell down the circuit. When the other side has sent back its own
|
|
relay end, the stream can be torn down. This two-step handshake allows
|
|
for TCP-based applications that, for example, close a socket for writing
|
|
but are still willing to read.
|
|
|
|
\SubSection{Integrity checking on streams}
|
|
|
|
In the old Onion Routing design, traffic was vulnerable to a malleability
|
|
attack: without integrity checking, an adversary could
|
|
guess some of the plaintext of a cell, xor it out, and xor in his own
|
|
plaintext. Even an external adversary could do this despite the link
|
|
encryption!
|
|
|
|
For example, an adversary could change a create cell to a
|
|
destroy cell; change the destination address in a relay begin cell
|
|
to the adversary's webserver; or change a user on an ftp connection
|
|
from typing ``dir'' to typing ``delete *''. Any node or observer along
|
|
the path can introduce such corruption in a stream.
|
|
|
|
Tor solves this malleability attack with respect to external adversaries
|
|
simply by using TLS. Addressing the insider malleability attack is more
|
|
complex.
|
|
|
|
Rather than doing integrity checking of the relay cells at each hop
|
|
(like Mixminion \cite{minion-design}), which would increase packet size
|
|
by a function of path length\footnote{This is also the argument against
|
|
using recent cipher modes like EAX \cite{eax} --- we don't want the added
|
|
message-expansion overhead at each hop, and we don't want to leak the path
|
|
length (or pad to some max path length).}, we choose to accept passive
|
|
timing attacks, and do integrity
|
|
checking only at the edges of the circuit. When Alice negotiates a key
|
|
with that hop, they both start a SHA-1 with some derivative of that key,
|
|
thus starting out with randomness that only the two of them know. From
|
|
then on they each incrementally add all the data bytes flowing across
|
|
the stream to the SHA-1, and each relay cell includes the first 4 bytes
|
|
of the current value of the hash.
|
|
|
|
The attacker must be able to guess all previous bytes between Alice
|
|
and Bob on that circuit (including the pseudorandomness from the key
|
|
negotiation), plus the bytes in the current cell, to remove or modify the
|
|
cell. The computational overhead isn't so bad, compared to doing an AES
|
|
crypt at each hop in the circuit. We use only four bytes per cell to
|
|
minimize overhead; the chance that an adversary will correctly guess a
|
|
valid hash, plus the payload the current cell, is acceptly low, given
|
|
that Alice or Bob tear down the circuit if they receive a bad hash.
|
|
|
|
%% probably don't need to even mention this, because the randomness
|
|
%% covers it:
|
|
%The fun SHA1 attack where the bad guy can incrementally add to a hash
|
|
%to get a new valid hash doesn't apply to us, because we never show any
|
|
%hashes to anybody.
|
|
|
|
\SubSection{Website fingerprinting attacks}
|
|
|
|
% this subsection probably wants to move to analysis -RD
|
|
old onion routing is vulnerable to website fingerprinting attacks like
|
|
david martin's from usenix sec and drew's from pet2002. so is tor. we
|
|
need to send some padding or something, including long-range padding
|
|
(to foil the first hop), to solve this. let's hope somebody writes
|
|
a followup to \cite{defensive-dropping} that tells us what, exactly,
|
|
to do, and why, exactly, it helps.
|
|
|
|
\SubSection{Rate limiting and fairness}
|
|
|
|
Nodes use a token bucket approach \cite{foo} to limit the number of
|
|
bytes they receive. Tokens are added to the bucket each second (when
|
|
the bucket is full, new tokens are discarded.) Each token represents
|
|
permission to receive one byte from the network --- to receive a byte,
|
|
the connection must remove a token from the bucket. Thus if the bucket
|
|
is empty, that connection must wait until more tokens arrive. The number
|
|
of tokens we add enforces a longterm average rate of incoming bytes, yet
|
|
we still permit short-term bursts above the allowed bandwidth. Currently
|
|
bucket sizes are set to ten seconds worth of traffic.
|
|
|
|
Further, we want to avoid starving any Tor streams. Entire circuits
|
|
could starve if we read greedily from connections and one connection
|
|
uses all the remaining bandwidth. We solve this by dividing the number
|
|
of tokens in the bucket by the number of connections that want to read,
|
|
and reading at most that number of bytes from each connection. We iterate
|
|
this procedure until the number of tokens in the bucket is under some
|
|
threshold (eg 10KB), at which point we greedily read from connections.
|
|
|
|
Because the number of bytes going out of a node is roughly the same
|
|
as the number of bytes that have come in, doing rate limiting only on
|
|
incoming bytes should be sufficient.
|
|
|
|
Further, inspired by Rennhard et al's design in \cite{anonnet}, the edges
|
|
of the circuit can automatically distinguish interactive streams compared
|
|
to bulk streams --- interactive streams supply cells only rarely. We can
|
|
get good latency for these streams by giving them preferential service,
|
|
while still getting good overall throughput to the bulk streams. Such
|
|
preferential treatment can have impact on anonymity, but an adversary
|
|
who can observe the stream can already learn this information through
|
|
timing attacks.
|
|
|
|
\SubSection{Congestion control}
|
|
\label{subsec:congestion}
|
|
|
|
Even with bandwidth rate limiting, we still need to worry about
|
|
congestion, either accidental or intentional. If enough users choose
|
|
the same OR-to-OR connection for their circuits, that connection
|
|
will become saturated. For example, an adversary can make a `put'
|
|
request through the onion routing network to a webserver he runs,
|
|
and then refuse to read any of the bytes at the webserver end of the
|
|
circuit. Without some congestion control mechanism, these bottlenecks
|
|
can propagate back through the entire network.
|
|
|
|
\subsubsection{Circuit-level}
|
|
|
|
To control a circuit's bandwidth usage, each OR keeps track of two
|
|
windows. The package window tracks how many relay data cells the OR is
|
|
allowed to package (from outside streams) for transmission back to the OP,
|
|
and the deliver window tracks how many relay data cells it is willing
|
|
to deliver to streams outside the network. Each window is initialized
|
|
(say, to 1000 data cells). When a data cell is packaged or delivered,
|
|
the appropriate window is decremented. When an OR has received enough
|
|
data cells (currently 100), it sends a relay sendme cell towards the OP,
|
|
with stream ID zero. When an OR receives a relay sendme cell with stream
|
|
ID zero, it increments its packaging window. Either of these cells
|
|
increments the corresponding window by 100. If the packaging window
|
|
reaches 0, the OR stops reading from TCP connections for all streams
|
|
on the corresponding circuit, and sends no more relay data cells until
|
|
receiving a relay sendme cell.
|
|
|
|
The OP behaves identically, except that it must track a packaging window
|
|
and a delivery window for every OR in the circuit. If a packaging window
|
|
reaches 0, it stops reading from streams destined for that OR.
|
|
|
|
\subsubsection{Stream-level}
|
|
|
|
The stream-level congestion control mechanism is similar to the
|
|
circuit-level mechanism above. ORs and OPs use relay sendme cells
|
|
to implement end-to-end flow control for individual streams across
|
|
circuits. Each stream begins with a package window (e.g. 500 cells),
|
|
and increments the window by a fixed value (50) upon receiving a relay
|
|
sendme cell. Rather than always returning a relay sendme cell as soon
|
|
as enough cells have arrived, the stream-level congestion control also
|
|
has to check whether data has been successfully flushed onto the TCP
|
|
stream; it sends a relay sendme only when the number of bytes pending
|
|
to be flushed is under some threshold (currently 10 cells worth).
|
|
|
|
Currently, non-data relay cells do not affect the windows. Thus we
|
|
avoid potential deadlock issues, e.g. because a stream can't send a
|
|
relay sendme cell because its packaging window is empty.
|
|
|
|
\subsubsection{Needs more research}
|
|
|
|
We don't need to reimplement full TCP windows (with sequence numbers,
|
|
the ability to drop cells when we're full and retransmit later, etc),
|
|
because the TCP streams already guarantee in-order delivery of each
|
|
cell. But we need to investigate further the effects of the current
|
|
parameters on throughput and latency, while also keeping privacy in mind;
|
|
see Section \ref{sec:maintaining-anonymity} for more discussion.
|
|
|
|
\Section{Other design decisions}
|
|
|
|
\SubSection{Resource management and DoS prevention}
|
|
\label{subsec:dos}
|
|
|
|
Describe DoS prevention. cookies before tls begins, rate limiting of
|
|
create cells, link-to-link rate limiting, etc.
|
|
Mention twins, what the do, what they can't.
|
|
How we should do sequencing and acking like TCP so that we can better
|
|
tolerate lost data cells.
|
|
Mention that designers have to choose what you send across your
|
|
circuit: wrapped IP packets, wrapped stream data, etc. [Disspell
|
|
TCP-over-TCP misconception.]
|
|
Mention that OR-to-OR connections should be highly reliable. If
|
|
they aren't, everything can stall.
|
|
|
|
\SubSection{Exit policies and abuse}
|
|
\label{subsec:exitpolicies}
|
|
|
|
Exit abuse is a serious barrier to wide-scale Tor deployment --- we
|
|
must block or limit attacks and other abuse that users can do through
|
|
the Tor network.
|
|
|
|
Each onion router's \emph{exit policy} describes to which external
|
|
addresses and ports the router will permit stream connections. On one end
|
|
of the spectrum are \emph{open exit} nodes that will connect anywhere;
|
|
on the other end are \emph{middleman} nodes that only relay traffic to
|
|
other Tor nodes, and \emph{private exit} nodes that only connect locally
|
|
or to addresses internal to that node's organization.
|
|
This private exit
|
|
node configuration is more secure for clients --- the adversary cannot
|
|
see plaintext traffic leaving the network (e.g. to a webserver), so he
|
|
is less sure of Alice's destination. More generally, nodes can require
|
|
a variety of forms of traffic authentication \cite{onion-discex00}.
|
|
Most onnion routers will function as \emph{limited exits} that permit
|
|
connections to the world at large, but restrict access to certain abuse-prone
|
|
addresses and services.
|
|
|
|
Tor offers more reliability than the high-latency fire-and-forget
|
|
anonymous email networks, because the sender opens a TCP stream
|
|
with the remote mail server and receives an explicit confirmation of
|
|
acceptance. But ironically, the private exit node model works poorly for
|
|
email, when Tor nodes are run on volunteer machines that also do other
|
|
things, because it's quite hard to configure mail transport agents so
|
|
normal users can send mail normally, but the Tor process can only deliver
|
|
mail locally. Further, most organizations have specific hosts that will
|
|
deliver mail on behalf of certain IP ranges; Tor operators must be aware
|
|
of these hosts and consider putting them in the Tor exit policy.
|
|
|
|
The abuse issues on closed (e.g. military) networks are different
|
|
from the abuse on open networks like the Internet. While these IP-based
|
|
access controls are still commonplace on the Internet, on closed networks,
|
|
nearly all participants will be honest, and end-to-end authentication
|
|
can be assumed for anything important.
|
|
|
|
Tor is harder than minion because tcp doesn't include an abuse
|
|
address. you could reach inside the http stream and change the agent
|
|
or something, but that's a specific case and probably won't help
|
|
much anyway.
|
|
And volunteer nodes don't resolve to anonymizer.mit.edu so it never
|
|
even occurs to people that it wasn't you.
|
|
|
|
Preventing abuse of open exit nodes is an unsolved problem. Princeton's
|
|
CoDeeN project \cite{darkside} gives us a glimpse of what we're in for.
|
|
% This is more speculative than a description of our design.
|
|
|
|
but their solutions, which mainly involve rate limiting and blacklisting
|
|
nodes which do bad things, don't translate directly to Tor. Rate limiting
|
|
still works great, but Tor intentionally separates sender from recipient,
|
|
so it's hard to know which sender was the one who did the bad thing,
|
|
without just making the whole network wide open.
|
|
|
|
even limiting most nodes to allow http, ssh, and aim to exit and reject
|
|
all other stuff is sketchy, because plenty of abuse can happen over
|
|
port 80. but it's a surprisingly good start, because it blocks most things,
|
|
and because people are more used to the concept of port 80 abuse not
|
|
coming from the machine's owner.
|
|
|
|
we could also run intrusion detection system (IDS) modules at each tor
|
|
node, to dynamically monitor traffic streams for attack signatures. it
|
|
can even react when it sees a signature by closing the stream. but IDS's
|
|
don't actually work most of the time, and besides, how do you write a
|
|
signature for "is sending a mean mail"?
|
|
|
|
we should run a squid at each exit node, to provide comparable anonymity
|
|
to private exit nodes for cache hits, to speed everything up, and to
|
|
have a buffer for funny stuff coming out of port 80. we could similarly
|
|
have other exit proxies for other protocols, like mail, to check
|
|
delivered mail for being spam.
|
|
|
|
[XXX Um, I'm uncomfortable with this for several reasons.
|
|
It's not good for keeping honest nodes honest about discarding
|
|
state after it's no longer needed. Granted it keeps an external
|
|
observer from noticing how often sites are visited, but it also
|
|
allows fishing expeditions. ``We noticed you went to this prohibited
|
|
site an hour ago. Kindly turn over your caches to the authorities.''
|
|
I previously elsewhere suggested bulk transfer proxies to carve
|
|
up big things so that they could be downloaded in less noticeable
|
|
pieces over several normal looking connections. We could suggest
|
|
similarly one or a handful of squid nodes that might serve up
|
|
some of the more sensitive but common material, especially if
|
|
the relevant sites didn't want to or couldn't run their own OR.
|
|
This would be better than having everyone run a squid which would
|
|
just help identify after the fact the different history of that
|
|
node's activity. All this kind of speculation needs to move to
|
|
future work section I guess. -PS]
|
|
|
|
A mixture of open and restricted exit nodes will allow the most
|
|
flexibility for volunteers running servers. But while a large number
|
|
of middleman nodes is useful to provide a large and robust network,
|
|
a small number of exit nodes still simplifies traffic analysis because
|
|
there are fewer nodes the adversary needs to monitor, and also puts a
|
|
greater burden on the exit nodes.
|
|
The JAP cascade model is really nice because they only need one node to
|
|
take the heat per cascade. On the other hand, a hydra scheme could work
|
|
better (it's still hard to watch all the clients).
|
|
|
|
Discuss importance of public perception, and how abuse affects it.
|
|
``Usability is a security parameter''. ``Public Perception is also a
|
|
security parameter.''
|
|
|
|
Discuss smear attacks.
|
|
|
|
\SubSection{Directory Servers}
|
|
\label{subsec:dirservers}
|
|
|
|
First-generation Onion Routing designs \cite{or-jsac98,freedom2-arch} did
|
|
% is or-jsac98 the right cite here? what's our stock OR cite? -RD
|
|
in-band network status updates: each router flooded a signed statement
|
|
to its neighbors, which propagated it onward. But anonymizing networks
|
|
have different security goals than typical link-state routing protocols.
|
|
For example, we worry more about delays (accidental or intentional)
|
|
that can cause different parts of the network to have different pictures
|
|
of link-state and topology. We also worry about attacks to deceive a
|
|
client about the router membership list, topology, or current network
|
|
state. Such \emph{partitioning attacks} on client knowledge help an
|
|
adversary with limited resources to efficiently deploy those resources
|
|
when attacking a target.
|
|
|
|
Instead, Tor uses a small group of redundant directory servers to
|
|
track network topology and node state such as current keys and exit
|
|
policies. The directory servers are normal onion routers, but there are
|
|
only a few of them and they are more trusted. They listen on a separate
|
|
port as an HTTP server, both so participants can fetch current network
|
|
state and router lists (a \emph{directory}), and so other onion routers
|
|
can upload their router descriptors.
|
|
|
|
[[mention that descriptors are signed with long-term keys; ORs publish
|
|
regularly to dirservers; policies for generating directories; key
|
|
rotation (link, onion, identity); Everybody already know directory
|
|
keys; how to approve new nodes (advogato, sybil, captcha (RTT));
|
|
policy for handling connections with unknown ORs; diff-based
|
|
retrieval; diff-based consesus; separate liveness from descriptor
|
|
list]]
|
|
|
|
Of course, a variety of attacks remain. An adversary who controls a
|
|
directory server can track certain clients by providing different
|
|
information --- perhaps by listing only nodes under its control
|
|
as working, or by informing only certain clients about a given
|
|
node. Moreover, an adversary without control of a directory server can
|
|
still exploit differences among client knowledge. If Eve knows that
|
|
node $M$ is listed on server $D_1$ but not on $D_2$, she can use this
|
|
knowledge to link traffic through $M$ to clients who have queried $D_1$.
|
|
|
|
Thus these directory servers must be synchronized and redundant. The
|
|
software is distributed with the signature public key of each directory
|
|
server, and directories must be signed by a threshold of these keys.
|
|
|
|
The directory servers in Tor are modeled after those in Mixminion
|
|
\cite{minion-design}, but our situation is easier. Firstly, we make the
|
|
simplifying assumption that all participants agree on who the directory
|
|
servers are. Secondly, Mixminion needs to predict node behavior ---
|
|
that is, build a reputation system for guessing future performance of
|
|
nodes based on past performance, and then figure out a way to build
|
|
a threshold consensus of these predictions. Tor just needs to get a
|
|
threshold consensus of the current state of the network.
|
|
|
|
The threshold consensus can be reached with standard Byzantine agreement
|
|
techniques \cite{castro-liskov}.
|
|
% Should I just stop the section here? Is the rest crap? -RD
|
|
But this library, while more efficient than previous Byzantine agreement
|
|
systems, is still complex and heavyweight for our purposes: we only need
|
|
to compute a single algorithm, and we do not require strict in-order
|
|
computation steps. The Tor directory servers build a consensus directory
|
|
through a simple four-round broadcast protocol. First, each server signs
|
|
and broadcasts its current opinion to the other directory servers; each
|
|
server then rebroadcasts all the signed opinions it has received. At this
|
|
point all directory servers check to see if anybody's cheating. If so,
|
|
directory service stops, the humans are notified, and that directory
|
|
server is permanently removed from the network. Assuming no cheating,
|
|
each directory server then computes a local algorithm on the set of
|
|
opinions, resulting in a uniform shared directory. Then the servers sign
|
|
this directory and broadcast it; and finally all servers rebroadcast
|
|
the directory and all the signatures.
|
|
|
|
The rebroadcast steps ensure that a directory server is heard by either
|
|
all of the other servers or none of them (some of the links between
|
|
directory servers may be down). Broadcasts are feasible because there
|
|
are so few directory servers (currently 3, but we expect to use as many
|
|
as 9 as the network scales). The actual local algorithm for computing
|
|
the shared directory is straightforward, and is described in the Tor
|
|
specification \cite{tor-spec}.
|
|
% we should, uh, add this to the spec. oh, and write it. -RD
|
|
|
|
Using directory servers rather than flooding approaches provides
|
|
simplicity and flexibility. For example, they don't complicate
|
|
the analysis when we start experimenting with non-clique network
|
|
topologies. And because the directories are signed, they can be cached at
|
|
all the other onion routers (or even elsewhere). Thus directory servers
|
|
are not a performance bottleneck when we have many users, and also they
|
|
won't aid traffic analysis by forcing clients to periodically announce
|
|
their existence to any central point.
|
|
% Mention Hydra as an example of non-clique topologies. -NM, from RD
|
|
|
|
\Section{Rendezvous points: location privacy}
|
|
\label{sec:rendezvous}
|
|
|
|
Rendezvous points are a building block for \emph{location-hidden services}
|
|
(aka responder anonymity) in the Tor network. Location-hidden services
|
|
means Bob can offer a TCP service, such as a webserver, without revealing
|
|
the IP of that service. One motivation for location privacy is to provide
|
|
protection against DDoS attacks: attackers are forced to attack the
|
|
onion routing network as a whole rather than just Bob's IP.
|
|
|
|
We provide this censorship resistance for Bob by allowing him to
|
|
advertise several onion routers (his \emph{Introduction Points}) as his
|
|
public location. Alice, the client, chooses a node for her \emph{Meeting
|
|
Point}. She connects to one of Bob's introduction points, informs him
|
|
about her rendezvous point, and then waits for him to connect to the
|
|
rendezvous
|
|
point. This extra level of indirection means Bob's introduction points
|
|
don't open themselves up to abuse by serving files directly, eg if Bob
|
|
chooses a node in France to serve material distateful to the French,
|
|
%
|
|
% We need a more legitimate-sounding reason here.
|
|
%
|
|
or if Bob's service tends to get DDoS'ed by script kiddies.
|
|
The extra level of indirection also allows Bob to respond to some requests
|
|
and ignore others.
|
|
|
|
We provide the necessary glue so that Alice can view webpages from Bob's
|
|
location-hidden webserver with minimal invasive changes. Both Alice and
|
|
Bob must run local onion proxies.
|
|
|
|
The steps of a rendezvous:
|
|
\begin{tightlist}
|
|
\item Bob chooses some Introduction Points, and advertises them on a
|
|
Distributed Hash Table (DHT).
|
|
\item Bob establishes onion routing connections to each of his
|
|
Introduction Points, and waits.
|
|
\item Alice learns about Bob's service out of band (perhaps Bob told her,
|
|
or she found it on a website). She looks up the details of Bob's
|
|
service from the DHT.
|
|
\item Alice chooses and establishes a Rendezvous Point (RP) for this
|
|
transaction.
|
|
\item Alice goes to one of Bob's Introduction Points, and gives it a blob
|
|
(encrypted for Bob) which tells him about herself, the RP
|
|
she chose, and the first half of an ephemeral key handshake. The
|
|
Introduction Point sends the blob to Bob.
|
|
\item Bob chooses whether to ignore the blob, or to onion route to RP.
|
|
Let's assume the latter.
|
|
\item RP plugs together Alice and Bob. Note that RP can't recognize Alice,
|
|
Bob, or the data they transmit (they share a session key).
|
|
\item Alice sends a Begin cell along the circuit. It arrives at Bob's
|
|
onion proxy. Bob's onion proxy connects to Bob's webserver.
|
|
\item Data goes back and forth as usual.
|
|
\end{tightlist}
|
|
|
|
When establishing an introduction point, Bob provides the onion router
|
|
with a public ``introduction'' key. The hash of this public key
|
|
identifies a unique service, and (since Bob is required to sign his
|
|
messages) prevents anybody else from usurping Bob's introduction point
|
|
in the future. Bob uses the same public key when establishing the other
|
|
introduction points for that service.
|
|
|
|
The blob that Alice gives the introduction point includes a hash of Bob's
|
|
public key to identify the service, an optional initial authentication
|
|
token (the introduction point can do prescreening, eg to block replays),
|
|
and (encrypted to Bob's public key) the location of the rendezvous point,
|
|
a rendezvous cookie Bob should tell RP so he gets connected to
|
|
Alice, an optional authentication token so Bob can choose whether to respond,
|
|
and the first half of a DH key exchange. When Bob connects to RP
|
|
and gets connected to Alice's pipe, his first cell contains the
|
|
other half of the DH key exchange.
|
|
|
|
The authentication tokens can be used to provide selective access to users
|
|
proportional to how important it is that they main uninterrupted access
|
|
to the service. During normal situations, Bob's service might simply be
|
|
offered directly from mirrors; Bob also gives out authentication cookies
|
|
to special users. When those mirrors are knocked down by DDoS attacks,
|
|
those special users can switch to accessing Bob's service via the Tor
|
|
rendezvous system.
|
|
|
|
\subsection{Integration with user applications}
|
|
|
|
For each service Bob offers, he configures his local onion proxy to know
|
|
the local IP and port of the server, a strategy for authorizating Alices,
|
|
and a public key. We assume the existence of a robust decentralized
|
|
efficient lookup system which allows authenticated updates, eg
|
|
\cite{cfs:sosp01}. (Each onion router could run a node in this lookup
|
|
system; also note that as a stopgap measure, we can just run a simple
|
|
lookup system on the directory servers.) Bob publishes into the DHT
|
|
(indexed by the hash of the public key) the public key, an expiration
|
|
time (``not valid after''), and the current introduction points for that
|
|
service. Note that Bob's webserver is unmodified, and doesn't even know
|
|
that it's hidden behind the Tor network.
|
|
|
|
As far as Alice's experience goes, we require that her client interface
|
|
remain a SOCKS proxy, and we require that she shouldn't have to modify
|
|
her applications. Thus we encode all of the necessary information into
|
|
the hostname (more correctly, fully qualified domain name) that Alice
|
|
uses, eg when clicking on a url in her browser. Location-hidden services
|
|
use the special top level domain called `.onion': thus hostnames take the
|
|
form x.y.onion where x encodes the hash of PK, and y is the authentication
|
|
cookie. Alice's onion proxy examines hostnames and recognizes when they're
|
|
destined for a hidden server. If so, it decodes the PK and starts the
|
|
rendezvous as described in the table above.
|
|
|
|
\subsection{Previous rendezvous work}
|
|
|
|
Ian Goldberg developed a similar notion of rendezvous points for
|
|
low-latency anonymity systems \cite{ian-thesis}. His ``service tag''
|
|
is the same concept as our ``hash of service's public key''. We make it
|
|
a hash of the public key so it can be self-authenticating, and so the
|
|
client can recognize the same service with confidence later on. His
|
|
design differs from ours in the following ways though. Firstly, Ian
|
|
suggests that the client should manually hunt down a current location of
|
|
the service via Gnutella; whereas our use of the DHT makes lookup faster,
|
|
more robust, and transparent to the user. Secondly, in Tor the client
|
|
and server can share ephemeral DH keys, so at no point in the path is
|
|
the plaintext
|
|
exposed. Thirdly, our design is much more practical for deployment in a
|
|
volunteer network, in terms of getting volunteers to offer introduction
|
|
and rendezvous point services. The introduction points do not output any
|
|
bytes to the clients, and the rendezvous points don't know the client,
|
|
the server, or the stuff being transmitted. The indirection scheme
|
|
is also designed with authentication/authorization in mind -- if the
|
|
client doesn't include the right cookie with its request for service,
|
|
the server doesn't even acknowledge its existence.
|
|
|
|
\Section{Analysis}
|
|
|
|
How well do we resist chosen adversary?
|
|
|
|
How well do we meet stated goals?
|
|
|
|
Mention jurisdictional arbitrage.
|
|
|
|
Pull attacks and defenses into analysis as a subsection
|
|
|
|
\Section{Maintaining anonymity in Tor}
|
|
\label{sec:maintaining-anonymity}
|
|
|
|
I probably should have noted that this means loops will be on at least
|
|
five hop routes, which should be rare given the distribution. I'm
|
|
realizing that this is reproducing some of the thought that led to a
|
|
default of five hops in the original onion routing design. There were
|
|
some different assumptions, which I won't spell out now. Note that
|
|
enclave level protections really change these assumptions. If most
|
|
circuits are just two hops, then just a single link observer will be
|
|
able to tell that two enclaves are communicating with high probability.
|
|
So, it would seem that enclaves should have a four node minimum circuit
|
|
to prevent trivial circuit insider identification of the whole circuit,
|
|
and three hop minimum for circuits from an enclave to some nonclave
|
|
responder. But then... we would have to make everyone obey these rules
|
|
or a node that through timing inferred it was on a four hop circuit
|
|
would know that it was probably carrying enclave to enclave traffic.
|
|
Which... if there were even a moderate number of bad nodes in the
|
|
network would make it advantageous to break the connection to conduct
|
|
a reformation intersection attack. Ahhh! I gotta stop thinking
|
|
about this and work on the paper some before the family wakes up.
|
|
On Sat, Oct 25, 2003 at 06:57:12AM -0400, Paul Syverson wrote:
|
|
> Which... if there were even a moderate number of bad nodes in the
|
|
> network would make it advantageous to break the connection to conduct > a reformation intersection attack. Ahhh! I gotta stop thinking > about this and work on the paper some before the family wakes up.
|
|
This is the sort of issue that should go in the 'maintaining anonymity
|
|
with tor' section towards the end. :)
|
|
Email from between roger and me to beginning of section above. Fix and move.
|
|
|
|
|
|
[Put as much of this as a part of open issues as is possible.]
|
|
|
|
[what's an anonymity set?]
|
|
|
|
packet counting attacks work great against initiators. need to do some
|
|
level of obfuscation for that. standard link padding for passive link
|
|
observers. long-range padding for people who own the first hop. are
|
|
we just screwed against people who insert timing signatures into your
|
|
traffic?
|
|
|
|
Even regardless of link padding from Alice to the cloud, there will be
|
|
times when Alice is simply not online. Link padding, at the edges or
|
|
inside the cloud, does not help for this.
|
|
|
|
how often should we pull down directories? how often send updated
|
|
server descs?
|
|
|
|
when we start up the client, should we build a circuit immediately,
|
|
or should the default be to build a circuit only on demand? should we
|
|
fetch a directory immediately?
|
|
|
|
would we benefit from greater synchronization, to blend with the other
|
|
users? would the reduced speed hurt us more?
|
|
|
|
does the "you can't see when i'm starting or ending a stream because
|
|
you can't tell what sort of relay cell it is" idea work, or is just
|
|
a distraction?
|
|
|
|
does running a server actually get you better protection, because traffic
|
|
coming from your node could plausibly have come from elsewhere? how
|
|
much mixing do you need before this is actually plausible, or is it
|
|
immediately beneficial because many adversary can't see your node?
|
|
|
|
do different exit policies at different exit nodes trash anonymity sets,
|
|
or not mess with them much?
|
|
|
|
do we get better protection against a realistic adversary by having as
|
|
many nodes as possible, so he probably can't see the whole network,
|
|
or by having a small number of nodes that mix traffic well? is a
|
|
cascade topology a more realistic way to get defenses against traffic
|
|
confirmation? does the hydra (many inputs, few outputs) topology work
|
|
better? are we going to get a hydra anyway because most nodes will be
|
|
middleman nodes?
|
|
|
|
using a circuit many times is good because it's less cpu work.
|
|
good because of predecessor attacks with path rebuilding.
|
|
bad because predecessor attacks can be more likely to link you with a
|
|
previous circuit since you're so verbose.
|
|
bad because each thing you do on that circuit is linked to the other
|
|
things you do on that circuit.
|
|
how often to rotate?
|
|
how to decide when to exit from middle?
|
|
when to truncate and re-extend versus when to start new circuit?
|
|
|
|
Because Tor runs over TCP, when one of the servers goes down it seems
|
|
that all the circuits (and thus streams) going over that server must
|
|
break. This reduces anonymity because everybody needs to reconnect
|
|
right then (does it? how much?) and because exit connections all break
|
|
at the same time, and it also reduces usability. It seems the problem
|
|
is even worse in a p2p environment, because so far such systems don't
|
|
really provide an incentive for nodes to stay connected when they're
|
|
done browsing, so we would expect a much higher churn rate than for
|
|
onion routing. Are there ways of allowing streams to survive the loss
|
|
of a node in the path?
|
|
|
|
discuss topologies. Cite George's non-freeroutes paper. Maybe this
|
|
graf goes elsewhere.
|
|
|
|
discuss attracting users; incentives; usability.
|
|
|
|
Choosing paths and path lengths.
|
|
|
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
|
|
\Section{Attacks and Defenses}
|
|
\label{sec:attacks}
|
|
|
|
Below we summarize a variety of attacks and how well our design withstands
|
|
them.
|
|
|
|
\begin{enumerate}
|
|
\item \textbf{Passive attacks}
|
|
\begin{itemize}
|
|
\item \emph{Simple observation.}
|
|
\item \emph{Timing correlation.}
|
|
\item \emph{Size correlation.}
|
|
\item \emph{Option distinguishability.}
|
|
\end{itemize}
|
|
|
|
\item \textbf{Active attacks}
|
|
\begin{itemize}
|
|
\item \emph{Key compromise.}
|
|
\item \emph{Iterated subpoena.}
|
|
\item \emph{Run recipient.}
|
|
\item \emph{Run a hostile node.}
|
|
\item \emph{Compromise entire path.}
|
|
\item \emph{Selectively DoS servers.}
|
|
\item \emph{Introduce timing into messages.}
|
|
\item \emph{Tagging attacks.}
|
|
the exit node can change the content you're getting to try to
|
|
trick you. similarly, when it rejects you due to exit policy,
|
|
it could give you a bad IP that sends you somewhere else.
|
|
\end{itemize}
|
|
|
|
we rely on DNS being globally consistent. if people in africa resolve
|
|
IPs differently, then asking to extend a circuit to a certain IP can
|
|
give away your origin.
|
|
|
|
\item \textbf{Directory attacks}
|
|
\begin{itemize}
|
|
\item knock out a dirserver
|
|
\item knock out half the dirservers
|
|
\item trick user into using different software (with different dirserver
|
|
keys)
|
|
\item OR connects to the dirservers but nowhere else
|
|
\item foo
|
|
\end{itemize}
|
|
|
|
\item \textbf{Attacks against rendezvous points}
|
|
\begin{itemize}
|
|
\item foo
|
|
\end{itemize}
|
|
|
|
\end{enumerate}
|
|
|
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
|
|
\Section{Future Directions and Open Problems}
|
|
\label{sec:conclusion}
|
|
|
|
% Mention that we need to do TCP over tor for reliability.
|
|
|
|
Tor brings together many innovations into
|
|
a unified deployable system. But there are still several attacks that
|
|
work quite well, as well as a number of sustainability and run-time
|
|
issues remaining to be ironed out. In particular:
|
|
|
|
\begin{itemize}
|
|
\item \emph{Scalability:} Since Tor's emphasis currently is on simplicity
|
|
of design and deployment, the current design won't easily handle more
|
|
than a few hundred servers, because of its clique topology. Restricted
|
|
route topologies \cite{danezis-pets03} promise comparable anonymity
|
|
with much better scaling properties, but we must solve problems like
|
|
how to randomly form the network without introducing net attacks.
|
|
% [cascades are a restricted route topology too. we must mention
|
|
% earlier why we're not satisfied with the cascade approach.]-RD
|
|
% [We do. At least
|
|
\item \emph{Cover traffic:} Currently we avoid cover traffic because
|
|
it introduces clear performance and bandwidth costs, but and its
|
|
security properties are not well understood. With more research
|
|
\cite{SS03,defensive-dropping}, the price/value ratio may change, both for
|
|
link-level cover traffic and also long-range cover traffic. In particular,
|
|
we expect restricted route topologies to reduce the cost of cover traffic
|
|
because there are fewer links to cover.
|
|
\item \emph{Better directory distribution:} Even with the threshold
|
|
directory agreement algorithm described in \ref{subsec:dirservers},
|
|
the directory servers are still trust bottlenecks. We must find more
|
|
decentralized yet practical ways to distribute up-to-date snapshots of
|
|
network status without introducing new attacks.
|
|
\item \emph{Implementing location-hidden servers:} While Section
|
|
\ref{sec:rendezvous} provides a design for rendezvous points and
|
|
location-hidden servers, this feature has not yet been implemented.
|
|
We will likely encounter additional issues, both in terms of usability
|
|
and anonymity, that must be resolved.
|
|
\item \emph{Wider-scale deployment:} The original goal of Tor was to
|
|
gain experience in deploying an anonymizing overlay network, and learn
|
|
from having actual users. We are now at the point where we can start
|
|
deploying a wider network. We will see what happens!
|
|
% ok, so that's hokey. fix it. -RD
|
|
\item \emph{Further specification review:} Foo.
|
|
\end{itemize}
|
|
|
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
|
|
%\Section{Acknowledgments}
|
|
%% commented out for anonymous submission
|
|
|
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
|
|
\bibliographystyle{latex8}
|
|
\bibliography{tor-design}
|
|
|
|
\end{document}
|
|
|
|
% Style guide:
|
|
% U.S. spelling
|
|
% avoid contractions (it's, can't, etc.)
|
|
% 'mix', 'mixes' (as noun)
|
|
% 'mix-net'
|
|
% 'mix', 'mixing' (as verb)
|
|
% 'middleman' [Not with a hyphen; the hyphen has been optional
|
|
% since Middle English.]
|
|
% 'nymserver'
|
|
% 'Cypherpunk', 'Cypherpunks', 'Cypherpunk remailer'
|
|
% 'Onion Routing design', 'onion router' [note capitalization]
|
|
% 'SOCKS'
|
|
%
|
|
%
|
|
% 'Substitute ``Damn'' every time you're inclined to write ``very;'' your
|
|
% editor will delete it and the writing will be just as it should be.'
|
|
% -- Mark Twain
|