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91a6a69070
svn:r13724
896 lines
42 KiB
TeX
896 lines
42 KiB
TeX
\documentclass{article}
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\newcommand{\plan}[1]{ {\bf (#1)}}
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\begin{document}
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\title{Tor Development Roadmap: Wishlist for 2008 and beyond}
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\author{Roger Dingledine \and Nick Mathewson}
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\date{}
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\maketitle
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\pagestyle{plain}
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\section{Introduction}
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Tor (the software) and Tor (the overall software/network/support/document
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suite) are now experiencing all the crises of success. Over the next
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years, we're probably going to grow even more in terms of users, developers,
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and funding than before. This document attempts to lay out all the
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well-understood next steps that Tor needs to take. We should periodically
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reorganize it to reflect current and intended priorities.
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\section{Everybody can be a relay}
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We've made a lot of progress towards letting an ordinary Tor client also
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serve as a Tor relay. But these issues remain.
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\subsection{UPNP}
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We should teach Vidalia how to speak UPNP to automatically open and
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forward ports on common (e.g. Linksys) routers. There are some promising
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Qt-based UPNP libs out there, and in any case there are others (e.g. in
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Perl) that we can base it on.
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\subsection{``ORPort auto'' to look for a reachable port}
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Vidalia defaults to port 443 on Windows and port 8080 elsewhere. But if
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that port is already in use, or the ISP filters incoming connections
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on that port (some cablemodem providers filter 443 inbound), the user
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needs to learn how to notice this, and then pick a new one and type it
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into Vidalia.
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We should add a new option ``auto'' that cycles through a set of preferred
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ports, testing bindability and reachability for each of them, and only
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complains to the user once it's given up on the common choices.
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\subsection{Incentives design}
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Roger has been working with researchers at Rice University to simulate
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and analyze a new design where the directory authorities assign gold
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stars to well-behaving relays, and then all the relays give priority
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to traffic from gold-starred relays. The great feature of the design is
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that not only does it provide the (explicit) incentive to run a relay,
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but it also aims to grow the overall capacity of the network, so even
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non-relays will benefit.
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It needs more analysis, and perhaps more design work, before we try
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deploying it.
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\subsection{Windows libevent}
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Tor relays still don't work well or reliably on Windows XP or Windows
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Vista, because we don't use the Windows-native ``overlapped IO''
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approach. Christian King made a good start at teaching libevent about
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overlapped IO during Google Summer of Code 2007, and next steps are
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to a) finish that, b) teach Tor to do openssl calls on buffers rather
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than directly to the network, and c) teach Tor to use the new libevent
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buffers approach.
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\subsection{Network scaling}
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If we attract many more relays, we will need to handle the growing pains
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in terms of getting all the directory information to all the users.
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The first piece of this issue is a practical question: since the
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directory size scales linearly with more relays, at some point it
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will no longer be practical for every client to learn about every
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relay. We can try to reduce the amount of information each client needs
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to fetch (e.g. based on fetching less information preemptively as in
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Section~\ref{subsec:fewer-descriptor-fetches} below), but eventually
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clients will need to learn about only a subset of the network, and we
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will need to design good ways to divide up the network information.
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The second piece is an anonymity question that arises from this
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partitioning: if Tor's security comes from having all the clients
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behaving in similar ways, yet we are now giving different clients
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different directory information, how can we minimize the new anonymity
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attacks we introduce?
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\subsection{Using fewer sockets}
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Since in the current network every Tor relay can reach every other Tor
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relay, and we have many times more users than relays, pretty much every
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possible link in the network is in use. That is, the current network
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is a clique in practice.
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And since each of these connections requires a TCP socket, it's going
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to be hard for the network to grow much larger: many systems come with
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a default of 1024 file descriptors allowed per process, and raising
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that ulimit is hard for end users. Worse, many low-end gateway/firewall
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routers can't handle this many connections in their routing table.
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One approach is a restricted-route topology~\cite{danezis:pet2003}:
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predefine which relays can reach which other relays, and communicate
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these restrictions to the relays and the clients. We need to compute
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which links are acceptable in a way that's decentralized yet scalable,
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and in a way that achieves a small-worlds property; and we
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need an efficient (compact) way to characterize the topology information
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so all the users could keep up to date.
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Another approach would be to switch to UDP-based transport between
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relays, so we don't need to keep the TCP sockets open at all. Needs more
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investigation too.
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\subsection{Auto bandwidth detection and rate limiting, especially for
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asymmetric connections.}
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\subsection{Better algorithms for giving priority to local traffic}
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Proposal 111 made a lot of progress at separating local traffic from
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relayed traffic, so Tor users can rate limit the relayed traffic at a
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stricter level. But since we want to pass both traffic classes over the
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same TCP connection, we can't keep them entirely separate. The current
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compromise is that we treat all bytes to/from a given connectin as
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local traffic if any of the bytes within the past N seconds were local
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bytes. But a) we could use some more intelligent heuristics, and b)
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this leaks information to an active attacker about when local traffic
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was sent/received.
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\subsection{Tolerate absurdly wrong clocks, even for relays}
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Many of our users are on Windows, running with a clock several days or
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even several years off from reality. Some of them are even intentionally
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in this state so they can run software that will only run in the past.
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Before Tor 0.1.1.x, Tor clients would still function if their clock was
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wildly off --- they simply got a copy of the directory and believed it.
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Starting in Tor 0.1.1.x (and even moreso in Tor 0.2.0.x), the clients
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only use networkstatus documents that they believe to be recent, so
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clients with extremely wrong clocks no longer work. (This bug has been
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an unending source of vague and confusing bug reports.)
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The first step is for clients to recognize when all the directory material
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they're fetching has roughly the same offset from their current time,
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and then automatically correct for it.
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Once that's working well, clients who opt to become bridge relays should
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be able to use the same approach to serve accurate directory information
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to their bridge users.
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\subsection{Risks from being a relay}
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Three different research
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papers~\cite{back01,clog-the-queue,attack-tor-oak05} describe ways to
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identify the nodes in a circuit by running traffic through candidate nodes
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and looking for dips in the traffic while the circuit is active. These
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clogging attacks are not that scary in the Tor context so long as relays
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are never clients too. But if we're trying to encourage more clients to
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turn on relay functionality too (whether as bridge relays or as normal
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relays), then we need to understand this threat better and learn how to
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mitigate it.
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One promising research direction is to investigate the RelayBandwidthRate
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feature that lets Tor rate limit relayed traffic differently from local
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traffic. Since the attacker's ``clogging'' traffic is not in the same
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bandwidth class as the traffic initiated by the user, it may be harder
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to detect interference. Or it may not be.
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\subsection{First a bridge, then a public relay?}
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Once enough of the items in this section are done, I want all clients
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to start out automatically detecting their reachability and opting
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to be bridge relays.
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Then if they realize they have enough consistency and bandwidth, they
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should automatically upgrade to being non-exit relays.
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What metrics should we use for deciding when we're fast enough
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and stable enough to switch? Given that the list of bridge relays needs
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to be kept secret, it doesn't make much sense to switch back.
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\section{Tor on low resources / slow links}
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\subsection{Reducing directory fetches further}
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\label{subsec:fewer-descriptor-fetches}
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\subsection{AvoidDiskWrites}
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\subsection{Using less ram}
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\subsection{Better DoS resistance for tor servers / authorities}
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\section{Blocking resistance}
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\subsection{Better bridge-address-distribution strategies}
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\subsection{Get more volunteers running bridges}
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\subsection{Handle multiple bridge authorities}
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\subsection{Anonymity for bridge users: second layer of entry guards, etc?}
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\subsection{More TLS normalization}
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\subsection{Harder to block Tor software distribution}
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\subsection{Integration with Psiphon}
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\section{Packaging}
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\subsection{Switch Privoxy out for Polipo}
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- Make Vidalia able to launch more programs itself
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\subsection{Continue Torbutton improvements}
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especially better docs
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\subsection{Vidalia and stability (especially wrt ongoing Windows problems)}
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learn how to get useful crash reports (tracebacks) from Windows users
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\subsection{Polipo support on Windows}
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\subsection{Auto update for Tor, Vidalia, others}
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\subsection{Tor browser bundle for USB and standalone use}
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\subsection{LiveCD solution}
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\subsection{VM-based solution}
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\subsection{Tor-on-enclave-firewall configuration}
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\subsection{General tutorials on what common applications are Tor-friendly}
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\subsection{Controller libraries (torctl) plus documentation}
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\subsection{Localization and translation (Vidalia, Torbutton, web pages)}
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\section{Interacting better with Internet sites}
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\subsection{Make tordnsel (tor exitlist) better and more well-known}
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\subsection{Nymble}
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\subsection{Work with Wikipedia, Slashdot, Google(, IRC networks)}
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\subsection{IPv6 support for exit destinations}
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\section{Network health}
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\subsection{torflow / soat to detect bad relays}
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\subsection{make authorities more automated}
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\subsection{torstatus pages and better trend tracking}
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\subsection{better metrics for assessing network health / growth}
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- geoip usage-by-country reporting and aggregation
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(Once that's working, switch to Directory guards)
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\section{Performance research}
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\subsection{Load balance better}
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\subsection{Improve our congestion control algorithms}
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\subsection{Two-hops vs Three-hops}
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\subsection{Transport IP packets end-to-end}
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\section{Outreach and user education}
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\subsection{"Who uses Tor" use cases}
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\subsection{Law enforcement contacts}
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- "Was this IP address a Tor relay recently?" database
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\subsection{Commercial/enterprise outreach. Help them use Tor well and
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not fear it.}
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\subsection{NGO outreach and training.}
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- "How to be a safe blogger"
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\subsection{More activist coordinators, more people to answer user questions}
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\subsection{More people to hold hands of server operators}
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\subsection{Teaching the media about Tor}
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\subsection{The-dangers-of-plaintext awareness}
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\subsection{check.torproject.org and other "privacy checkers"}
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\subsection{Stronger legal FAQ for US}
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\subsection{Legal FAQs for other countries}
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\section{Anonymity research}
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\subsection{estimate relay bandwidth more securely}
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\subsection{website fingerprinting attacks}
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\subsection{safer e2e defenses}
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\subsection{Using Tor when you really need anonymity. Can you compose it
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with other steps, like more trusted guards or separate proxies?}
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\subsection{Topology-aware routing; routing-zones, steven's pet2007 paper.}
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\subsection{Exactly what do guard nodes provide?}
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Entry guards seem to defend against all sorts of attacks. Can we work
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through all the benefits they provide? Papers like Nikita's CCS 2007
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paper make me think their value is not well-understood by the research
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community.
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\section{Organizational growth and stability}
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\subsection{A contingency plan if Roger gets hit by a bus}
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- Get a new executive director
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\subsection{More diversity of funding}
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- Don't rely on any one funder as much
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- Don't rely on any sector or funder category as much
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\subsection{More Tor-funded people who are skilled at peripheral apps like
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Vidalia, Torbutton, Polipo, etc}
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\subsection{More coordinated media handling and strategy}
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\subsection{Clearer and more predictable trademark behavior}
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\subsection{More outside funding for internships, etc e.g. GSoC.}
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\section{Hidden services}
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\subsection{Scaling: how to handle many hidden services}
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\subsection{Performance: how to rendezvous with them quickly}
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\subsection{Authentication/authorization: how to tolerate DoS / load}
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\section{Tor as a general overlay network}
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\subsection{Choose paths / exit by country}
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\subsection{Easier to run your own private servers and have Tor use them
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anywhere in the path}
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\subsection{Easier to run an independent Tor network}
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\section{Code security/correctness}
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\subsection{veracode}
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\subsection{code audit}
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\subsection{more fuzzing tools}
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\subsection{build farm, better testing harness}
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\subsection{Long-overdue code refactoring and cleanup}
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\section{Protocol security}
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\subsection{safer circuit handshake}
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\subsection{protocol versioning for future compatibility}
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\subsection{cell sizes}
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\subsection{adapt to new key sizes, etc}
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\bibliographystyle{plain} \bibliography{tor-design}
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\end{document}
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\section{Code and design infrastructure}
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\subsection{Protocol revision}
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To maintain backward compatibility, we've postponed major protocol
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changes and redesigns for a long time. Because of this, there are a number
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of sensible revisions we've been putting off until we could deploy several of
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them at once. To do each of these, we first need to discuss design
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alternatives with other cryptographers and outside collaborators to
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make sure that our choices are secure.
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First of all, our protocol needs better {\bf versioning support} so that we
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can make backward-incompatible changes to our core protocol. There are
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difficult anonymity issues here, since many naive designs would make it easy
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to tell clients apart (and then track them) based on their supported versions.
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With protocol versioning support would come the ability to {\bf future-proof
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our ciphersuites}. For example, not only our OR protocol, but also our
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directory protocol, is pretty firmly tied to the SHA-1 hash function, which
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though not yet known to be insecure for our purposes, has begun to show
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its age. We should
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remove assumptions throughout our design based on the assumption that public
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keys, secret keys, or digests will remain any particular size indefinitely.
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Our OR {\bf authentication protocol}, though provably
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secure\cite{tap:pet2006}, relies more on particular aspects of RSA and our
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implementation thereof than we had initially believed. To future-proof
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against changes, we should replace it with a less delicate approach.
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\plan{For all the above: 2 person-months to specify, spread over several
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months with time for interaction with external participants. One
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person-month to implement. Start specifying in early 2007.}
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We might design a {\bf stream migration} feature so that streams tunneled
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over Tor could be more resilient to dropped connections and changed IPs.
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\plan{Not in 2007.}
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A new protocol could support {\bf multiple cell sizes}. Right now, all data
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passes through the Tor network divided into 512-byte cells. This is
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efficient for high-bandwidth protocols, but inefficient for protocols
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like SSH or AIM that send information in small chunks. Of course, we need to
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investigate the extent to which multiple sizes could make it easier for an
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adversary to fingerprint a traffic pattern. \plan{Not in 2007.}
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As a part of our design, we should investigate possible {\bf cipher modes}
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other than counter mode. For example, a mode with built-in integrity
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checking, error propagation, and random access could simplify our protocol
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significantly. Sadly, many of these are patented and unavailable for us.
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\plan{Not in 2007.}
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\subsection{Scalability}
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\subsubsection{Improved directory efficiency}
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We should {\bf have routers upload their descriptors even less often}, so
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that clients do not need to download replacements every 18 hours whether any
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information has changed or not. (As of Tor 0.1.2.3-alpha, clients tolerate
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routers that don't upload often, but routers still upload at least every 18
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hours to support older clients.) \plan{Must do, but not until 0.1.1.x is
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deprecated in mid 2007. 1 week.}
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\subsubsection{Non-clique topology}
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Our current network design achieves a certain amount of its anonymity by
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making clients act like each other through the simple expedient of making
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sure that all clients know all servers, and that any server can talk to any
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other server. But as the number of servers increases to serve an
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ever-greater number of clients, these assumptions become impractical.
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At worst, if these scalability issues become troubling before a solution is
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found, we can design and build a solution to {\bf split the network into
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multiple slices} until a better solution comes along. This is not ideal,
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since rather than looking like all other users from a point of view of path
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selection, users would ``only'' look like 200,000--300,000 other
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users.\plan{Not unless needed.}
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We are in the process of designing {\bf improved schemes for network
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scalability}. Some approaches focus on limiting what an adversary can know
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about what a user knows; others focus on reducing the extent to which an
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adversary can exploit this knowledge. These are currently in their infancy,
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and will probably not be needed in 2007, but they must be designed in 2007 if
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they are to be deployed in 2008.\plan{Design in 2007; unknown difficulty.
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Write a paper.}
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\subsubsection{Relay incentives}
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To support more users on the network, we need to get more servers. So far,
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we've relied on volunteerism to attract server operators, and so far it's
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served us well. But in the long run, we need to {\bf design incentives for
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users to run servers} and relay traffic for others. Most obviously, we
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could try to build the network so that servers offered improved service for
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other servers, but we would need to do so without weakening anonymity and
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making it obvious which connections originate from users running servers. We
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have some preliminary designs~\cite{incentives-txt,tor-challenges},
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but need to perform
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some more research to make sure they would be safe and effective.\plan{Write
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a draft paper; 2 person-months.}
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(XXX we did that)
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\subsection{Portability}
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Our {\bf Windows implementation}, though much improved, continues to lag
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behind Unix and Mac OS X, especially when running as a server. We hope to
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merge promising patches from Christian King to address this point, and bring
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Windows performance on par with other platforms.\plan{Do in 2007; 1.5 months
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to integrate not counting Mike's work.}
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We should have {\bf better support for portable devices}, including modes of
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operation that require less RAM, and that write to disk less frequently (to
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avoid wearing out flash RAM).\plan{Optional; 2 weeks.}
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\subsection{Performance: resource usage}
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We've been working on {\bf using less RAM}, especially on servers. This has
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paid off a lot for directory caches in the 0.1.2, which in some cases are
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using 90\% less memory than they used to require. But we can do better,
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especially in the area around our buffer management algorithms, by using an
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approach more like the BSD and Linux kernels use instead of our current ring
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buffer approach. (For OR connections, we can just use queues of cell-sized
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chunks produced with a specialized allocator.) This could potentially save
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around 25 to 50\% of the memory currently allocated for network buffers, and
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make Tor a more attractive proposition for restricted-memory environments
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like old computers, mobile devices, and the like.\plan{Do in 2007; 2-3 weeks
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plus one week measurement.} (XXX We did this, but we need to do something
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more/else.)
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\subsection{Performance: network usage}
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We know too little about how well our current path
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selection algorithms actually spread traffic around the network in practice.
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We should {\bf research the efficacy of our traffic allocation} and either
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assure ourselves that it is close enough to optimal as to need no improvement
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(unlikely) or {\bf identify ways to improve network usage}, and get more
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users' traffic delivered faster. Performing this research will require
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careful thought about anonymity implications.
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We should also {\bf examine the efficacy of our congestion control
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algorithm}, and see whether we can improve client performance in the
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presence of a congested network through dynamic `sendme' window sizes or
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other means. This will have anonymity implications too if we aren't careful.
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\plan{For both of the above: research, design and write
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a measurement tool in 2007: 1 month. See if we can interest a graduate
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student.}
|
|
|
|
We should work on making Tor's cell-based protocol perform better on
|
|
networks with low bandwidth
|
|
and high packet loss.\plan{Do in 2007 if we're funded to do it; 4-6 weeks.}
|
|
|
|
\subsection{Performance scenario: one Tor client, many users}
|
|
We should {\bf improve Tor's performance when a single Tor handles many
|
|
clients}. Many organizations want to manage a single Tor client on their
|
|
firewall for many users, rather than having each user install a separate
|
|
Tor client. We haven't optimized for this scenario, and it is likely that
|
|
there are some code paths in the current implementation that become
|
|
inefficient when a single Tor is servicing hundreds or thousands of client
|
|
connections. (Additionally, it is likely that such clients have interesting
|
|
anonymity requirements the we should investigate.) We should profile Tor
|
|
under appropriate loads, identify bottlenecks, and fix them.\plan{Do in 2007
|
|
if we're funded to do it; 4-8 weeks.}
|
|
|
|
\subsection{Tor servers on asymmetric bandwidth}
|
|
|
|
Tor should work better on servers that have asymmetric connections like cable
|
|
or DSL. Because Tor has separate TCP connections between each
|
|
hop, if the incoming bytes are arriving just fine and the outgoing bytes are
|
|
all getting dropped on the floor, the TCP push-back mechanisms don't really
|
|
transmit this information back to the incoming streams.\plan{Do in 2007 since
|
|
related to bandwidth limiting. 3-4 weeks.}
|
|
|
|
\subsection{Running Tor as both client and server}
|
|
|
|
Many performance tradeoffs and balances that might need more attention.
|
|
We first need to track and fix whatever bottlenecks emerge; but we also
|
|
need to invent good algorithms for prioritizing the client's traffic
|
|
without starving the server's traffic too much.\plan{No idea; try
|
|
profiling and improving things in 2007.}
|
|
|
|
\subsection{Protocol redesign for UDP}
|
|
Tor has relayed only TCP traffic since its first versions, and has used
|
|
TLS-over-TCP to do so. This approach has proved reliable and flexible, but
|
|
in the long term we will need to allow UDP traffic on the network, and switch
|
|
some or all of the network to using a UDP transport. {\bf Supporting UDP
|
|
traffic} will make Tor more suitable for protocols that require UDP, such
|
|
as many VOIP protocols. {\bf Using a UDP transport} could greatly reduce
|
|
resource limitations on servers, and make the network far less interruptible
|
|
by lossy connections. Either of these protocol changes would require a great
|
|
deal of design work, however. We hope to be able to enlist the aid of a few
|
|
talented graduate students to assist with the initial design and
|
|
specification, but the actual implementation will require significant testing
|
|
of different reliable transport approaches.\plan{Maybe do a design in 2007 if
|
|
we find an interested academic. Ian or Ben L might be good partners here.}
|
|
|
|
\section{Blocking resistance}
|
|
|
|
\subsection{Design for blocking resistance}
|
|
We have written a design document explaining our general approach to blocking
|
|
resistance. We should workshop it with other experts in the field to get
|
|
their ideas about how we can improve Tor's efficacy as an anti-censorship
|
|
tool.
|
|
|
|
\subsection{Implementation: client-side and bridges-side}
|
|
|
|
Bridges will want to be able to {\bf listen on multiple addresses and ports}
|
|
if they can, to give the adversary more ports to block.
|
|
|
|
\subsection{Research: anonymity implications from becoming a bridge}
|
|
|
|
see arma's bridge proposal; e.g. should bridge users use a second layer of
|
|
entry guards?
|
|
|
|
\subsection{Implementation: bridge authority}
|
|
|
|
we run some
|
|
directory authorities with a slightly modified protocol that doesn't leak
|
|
the entire list of bridges. Thus users can learn up-to-date information
|
|
for bridges they already know about, but they can't learn about arbitrary
|
|
new bridges.
|
|
|
|
we need a design for distributing the bridge authority over more than one
|
|
server
|
|
|
|
\subsection{Normalizing the Tor protocol on the wire}
|
|
Additionally, we should {\bf resist content-based filters}. Though an
|
|
adversary can't see what users are saying, some aspects of our protocol are
|
|
easy to fingerprint {\em as} Tor. We should correct this where possible.
|
|
|
|
Look like Firefox; or look like nothing?
|
|
Future research: investigate timing similarities with other protocols.
|
|
|
|
\subsection{Research: scanning-resistance}
|
|
|
|
\subsection{Research/Design/Impl: how users discover bridges}
|
|
Our design anticipates an arms race between discovery methods and censors.
|
|
We need to begin the infrastructure on our side quickly, preferably in a
|
|
flexible language like Python, so we can adapt quickly to censorship.
|
|
|
|
phase one: personal bridges
|
|
phase two: families of personal bridges
|
|
phase three: more structured social network
|
|
phase four: bag of tricks
|
|
Research: phase five...
|
|
|
|
Integration with Psiphon, etc?
|
|
|
|
\subsection{Document best practices for users}
|
|
Document best practices for various activities common among
|
|
blocked users (e.g. WordPress use).
|
|
|
|
\subsection{Research: how to know if a bridge has been blocked?}
|
|
|
|
\subsection{GeoIP maintenance, and "private" user statistics}
|
|
How to know if the whole idea is working?
|
|
|
|
\subsection{Research: hiding whether the user is reading or publishing?}
|
|
|
|
\subsection{Research: how many bridges do you need to know to maintain
|
|
reachability?}
|
|
|
|
\subsection{Resisting censorship of the Tor website, docs, and mirrors}
|
|
|
|
We should take some effort to consider {\bf initial distribution of Tor and
|
|
related information} in countries where the Tor website and mirrors are
|
|
censored. (Right now, most countries that block access to Tor block only the
|
|
main website and leave mirrors and the network itself untouched.) Falling
|
|
back on word-of-mouth is always a good last resort, but we should also take
|
|
steps to make sure it's relatively easy for users to get ahold of a copy.
|
|
|
|
\section{Security}
|
|
|
|
\subsection{Security research projects}
|
|
|
|
We should investigate approaches with some promise to help Tor resist
|
|
end-to-end traffic correlation attacks. It's an open research question
|
|
whether (and to what extent) {\bf mixed-latency} networks, {\bf low-volume
|
|
long-distance padding}, or other approaches can resist these attacks, which
|
|
are currently some of the most effective against careful Tor users. We
|
|
should research these questions and perform simulations to identify
|
|
opportunities for strengthening our design without dropping performance to
|
|
unacceptable levels. %Cite something
|
|
\plan{Start doing this in 2007; write a paper. 8-16 weeks.}
|
|
|
|
We've got some preliminary results suggesting that {\bf a topology-aware
|
|
routing algorithm}~\cite{feamster:wpes2004} could reduce Tor users'
|
|
vulnerability against local or ISP-level adversaries, by ensuring that they
|
|
are never in a position to watch both ends of a connection. We need to
|
|
examine the effects of this approach in more detail and consider side-effects
|
|
on anonymity against other kinds of adversaries. If the approach still looks
|
|
promising, we should investigate ways for clients to implement it (or an
|
|
approximation of it) without having to download routing tables for the whole
|
|
Internet. \plan{Not in 2007 unless a graduate student wants to do it.}
|
|
|
|
%\tmp{defenses against end-to-end correlation} We don't expect any to work
|
|
%right now, but it would be useful to learn that one did. Alternatively,
|
|
%proving that one didn't would free up researchers in the field to go work on
|
|
%other things.
|
|
%
|
|
% See above; I think I got this.
|
|
|
|
We should research the efficacy of {\bf website fingerprinting} attacks,
|
|
wherein an adversary tries to match the distinctive traffic and timing
|
|
pattern of the resources constituting a given website to the traffic pattern
|
|
of a user's client. These attacks work great in simulations, but in
|
|
practice we hear they don't work nearly as well. We should get some actual
|
|
numbers to investigate the issue, and figure out what's going on. If we
|
|
resist these attacks, or can improve our design to resist them, we should.
|
|
% add cites
|
|
\plan{Possibly part of end-to-end correlation paper. Otherwise, not in 2007
|
|
unless a graduate student is interested.}
|
|
|
|
\subsection{Implementation security}
|
|
|
|
We should also {\bf mark RAM that holds key material as non-swappable} so
|
|
that there is no risk of recovering key material from a hard disk
|
|
compromise. This would require submitting patches upstream to OpenSSL, where
|
|
support for marking memory as sensitive is currently in a very preliminary
|
|
state.\plan{Nice to do, but not in immediate Tor scope.}
|
|
|
|
There are numerous tools for identifying trouble spots in code (such as
|
|
Coverity or even VS2005's code analysis tool) and we should convince somebody
|
|
to run some of them against the Tor codebase. Ideally, we could figure out a
|
|
way to get our code checked periodically rather than just once.\plan{Almost
|
|
no time once we talk somebody into it.}
|
|
|
|
We should try {\bf protocol fuzzing} to identify errors in our
|
|
implementation.\plan{Not in 2007 unless we find a grad student or
|
|
undergraduate who wants to try.}
|
|
|
|
Our guard nodes help prevent an attacker from being able to become a chosen
|
|
client's entry point by having each client choose a few favorite entry points
|
|
as ``guards'' and stick to them. We should implement a {\bf directory
|
|
guards} feature to keep adversaries from enumerating Tor users by acting as
|
|
a directory cache.\plan{Do in 2007; 2 weeks.}
|
|
|
|
\subsection{Detect corrupt exits and other servers}
|
|
With the success of our network, we've attracted servers in many locations,
|
|
operated by many kinds of people. Unfortunately, some of these locations
|
|
have compromised or defective networks, and some of these people are
|
|
untrustworthy or incompetent. Our current design relies on authority
|
|
administrators to identify bad nodes and mark them as nonfunctioning. We
|
|
should {\bf automate the process of identifying malfunctioning nodes} as
|
|
follows:
|
|
|
|
We should create a generic {\bf feedback mechanism for add-on tools} like
|
|
Mike Perry's ``Snakes on a Tor'' to report failing nodes to authorities.
|
|
\plan{Do in 2006; 1-2 weeks.}
|
|
|
|
We should write tools to {\bf detect more kinds of innocent node failure},
|
|
such as nodes whose network providers intercept SSL, nodes whose network
|
|
providers censor popular websites, and so on. We should also try to detect
|
|
{\bf routers that snoop traffic}; we could do this by launching connections
|
|
to throwaway accounts, and seeing which accounts get used.\plan{Do in 2007;
|
|
ask Mike Perry if he's interested. 4-6 weeks.}
|
|
|
|
We should add {\bf an efficient way for authorities to mark a set of servers
|
|
as probably collaborating} though not necessarily otherwise dishonest.
|
|
This happens when an administrator starts multiple routers, but doesn't mark
|
|
them as belonging to the same family.\plan{Do during v2.1 directory protocol
|
|
redesign; 1-2 weeks to implement.}
|
|
|
|
To avoid attacks where an adversary claims good performance in order to
|
|
attract traffic, we should {\bf have authorities measure node performance}
|
|
(including stability and bandwidth) themselves, and not simply believe what
|
|
they're told. We also measure stability by tracking MTBF. Measuring
|
|
bandwidth will be tricky, since it's hard to distinguish between a server with
|
|
low capacity, and a high-capacity server with most of its capacity in
|
|
use. See also Nikita's NDSS 2008 paper.\plan{Do it if we can interest
|
|
a grad student.}
|
|
|
|
{\bf Operating a directory authority should be easier.} We rely on authority
|
|
operators to keep the network running well, but right now their job involves
|
|
too much busywork and administrative overhead. A better interface for them
|
|
to use could free their time to work on exception cases rather than on
|
|
adding named nodes to the network.\plan{Do in 2007; 4-5 weeks.}
|
|
|
|
\subsection{Protocol security}
|
|
|
|
In addition to other protocol changes discussed above,
|
|
% And should we move some of them down here? -NM
|
|
we should add {\bf hooks for denial-of-service resistance}; we have some
|
|
preliminary designs, but we shouldn't postpone them until we really need them.
|
|
If somebody tries a DDoS attack against the Tor network, we won't want to
|
|
wait for all the servers and clients to upgrade to a new
|
|
version.\plan{Research project; do this in 2007 if funded.}
|
|
|
|
\section{Development infrastructure}
|
|
|
|
\subsection{Build farm}
|
|
We've begun to deploy a cross-platform distributed build farm of hosts
|
|
that build and test the Tor source every time it changes in our development
|
|
repository.
|
|
|
|
We need to {\bf get more participants}, so that we can test a larger variety
|
|
of platforms. (Previously, we've only found out when our code had broken on
|
|
obscure platforms when somebody got around to building it.)
|
|
|
|
We need also to {\bf add our dependencies} to the build farm, so that we can
|
|
ensure that libraries we need (especially libevent) do not stop working on
|
|
any important platform between one release and the next.
|
|
|
|
\plan{This is ongoing as more buildbots arrive.}
|
|
|
|
\subsection{Improved testing harness}
|
|
Currently, our {\bf unit tests} cover only about 20\% of the code base. This
|
|
is uncomfortably low; we should write more and switch to a more flexible
|
|
testing framework.\plan{Ongoing basis, time permitting.}
|
|
|
|
We should also write flexible {\bf automated single-host deployment tests} so
|
|
we can more easily verify that the current codebase works with the
|
|
network.\plan{Worthwhile in 2007; would save lots of time. 2-4 weeks.}
|
|
|
|
We should build automated {\bf stress testing} frameworks so we can see which
|
|
realistic loads cause Tor to perform badly, and regularly profile Tor against
|
|
these loads. This would give us {\it in vitro} performance values to
|
|
supplement our deployment experience.\plan{Worthwhile in 2007; 2-6 weeks.}
|
|
|
|
We should improve our memory profiling code.\plan{...}
|
|
|
|
|
|
\subsection{Centralized build system}
|
|
We currently rely on a separate packager to maintain the packaging system and
|
|
to build Tor on each platform for which we distribute binaries. Separate
|
|
package maintainers is sensible, but separate package builders has meant
|
|
long turnaround times between source releases and package releases. We
|
|
should create the necessary infrastructure for us to produce binaries for all
|
|
major packages within an hour or so of source release.\plan{We should
|
|
brainstorm this at least in 2007.}
|
|
|
|
\subsection{Improved metrics}
|
|
We need a way to {\bf measure the network's health, capacity, and degree of
|
|
utilization}. Our current means for doing this are ad hoc and not
|
|
completely accurate
|
|
|
|
We need better ways to {\bf tell which countries are users are coming from,
|
|
and how many there are}. A good perspective of the network helps us
|
|
allocate resources and identify trouble spots, but our current approaches
|
|
will work less and less well as we make it harder for adversaries to
|
|
enumerate users. We'll probably want to shift to a smarter, statistical
|
|
approach rather than our current ``count and extrapolate'' method.
|
|
|
|
\plan{All of this in 2007 if funded; 4-8 weeks}
|
|
|
|
% \tmp{We'd like to know how much of the network is getting used.}
|
|
% I think this is covered above -NM
|
|
|
|
\subsection{Controller library}
|
|
We've done lots of design and development on our controller interface, which
|
|
allows UI applications and other tools to interact with Tor. We could
|
|
encourage the development of more such tools by releasing a {\bf
|
|
general-purpose controller library}, ideally with API support for several
|
|
popular programming languages.\plan{2006 or 2007; 1-2 weeks.}
|
|
|
|
\section{User experience}
|
|
|
|
\subsection{Get blocked less, get blocked less broadly}
|
|
Right now, some services block connections from the Tor network because
|
|
they don't have a better
|
|
way to keep vandals from abusing them than blocking IP addresses associated
|
|
with vandalism. Our approach so far has been to educate them about better
|
|
solutions that currently exist, but we should also {\bf create better
|
|
solutions for limiting vandalism by anonymous users} like credential and
|
|
blind-signature based implementations, and encourage their use. Other
|
|
promising starting points including writing a patch and explanation for
|
|
Wikipedia, and helping Freenode to document, maintain, and expand its
|
|
current Tor-friendly position.\plan{Do a writeup here in 2007; 1-2 weeks.}
|
|
|
|
Those who do block Tor users also block overbroadly, sometimes blacklisting
|
|
operators of Tor servers that do not permit exit to their services. We could
|
|
obviate innocent reasons for doing so by designing a {\bf narrowly-targeted Tor
|
|
RBL service} so that those who wanted to overblock Tor could no longer
|
|
plead incompetence.\plan{Possibly in 2007 if we decide it's a good idea; 3
|
|
weeks.}
|
|
|
|
\subsection{All-in-one bundle}
|
|
We need a well-tested, well-documented bundle of Tor and supporting
|
|
applications configured to use it correctly. We have an initial
|
|
implementation well under way, but it will need additional work in
|
|
identifying requisite Firefox extensions, identifying security threats,
|
|
improving user experience, and so on. This will need significantly more work
|
|
before it's ready for a general public release.
|
|
|
|
\subsection{LiveCD Tor}
|
|
We need a nice bootable livecd containing a minimal OS and a few applications
|
|
configured to use it correctly. The Anonym.OS project demonstrated that this
|
|
is quite feasible, but their project is not currently maintained.
|
|
|
|
\subsection{A Tor client in a VM}
|
|
\tmp{a.k.a JanusVM} which is quite related to the firewall-level deployment
|
|
section below. JanusVM is a Linux kernel running in VMWare. It gets an IP
|
|
address from the network, and serves as a DHCP server for its host Windows
|
|
machine. It intercepts all outgoing traffic and redirects it into Privoxy,
|
|
Tor, etc. This Linux-in-Windows approach may help us with scalability in
|
|
the short term, and it may also be a good long-term solution rather than
|
|
accepting all security risks in Windows.
|
|
|
|
%\subsection{Interface improvements}
|
|
%\tmp{Allow controllers to manipulate server status.}
|
|
% (Why is this in the User Experience section?) -RD
|
|
% I think it's better left to a generic ``make controller iface better'' item.
|
|
|
|
\subsection{Firewall-level deployment}
|
|
Another useful deployment mode for some users is using {\bf Tor in a firewall
|
|
configuration}, and directing all their traffic through Tor. This can be a
|
|
little tricky to set up currently, but it's an effective way to make sure no
|
|
traffic leaves the host un-anonymized. To achieve this, we need to {\bf
|
|
improve and port our new TransPort} feature which allows Tor to be used
|
|
without SOCKS support; to {\bf add an anonymizing DNS proxy} feature to Tor;
|
|
and to {\bf construct a recommended set of firewall configurations} to redirect
|
|
traffic to Tor.
|
|
|
|
This is an area where {\bf deployment via a livecd}, or an installation
|
|
targeted at specialized home routing hardware, could be useful.
|
|
|
|
\subsection{Assess software and configurations for anonymity risks}
|
|
Right now, users and packagers are more or less on their own when selecting
|
|
Firefox extensions. We should {\bf assemble a recommended list of browser
|
|
extensions} through experiment, and include this in the application bundles
|
|
we distribute.
|
|
|
|
We should also describe {\bf best practices for using Tor with each class of
|
|
application}. For example, Ethan Zuckerman has written a detailed
|
|
tutorial on how to use Tor, Firefox, GMail, and Wordpress to blog with
|
|
improved safety. There are many other cases on the Internet where anonymity
|
|
would be helpful, and there are a lot of ways to screw up using Tor.
|
|
|
|
The Foxtor and Torbutton extensions serve similar purposes; we should pick a
|
|
favorite, and merge in the useful features of the other.
|
|
|
|
%\tmp{clean up our own bundled software:
|
|
%E.g. Merge the good features of Foxtor into Torbutton}
|
|
%
|
|
% What else did you have in mind? -NM
|
|
|
|
\subsection{Localization}
|
|
Right now, most of our user-facing code is internationalized. We need to
|
|
internationalize the last few hold-outs (like the Tor expert installer), and get
|
|
more translations for the parts that are already internationalized.
|
|
|
|
Also, we should look into a {\bf unified translator's solution}. Currently,
|
|
since different tools have been internationalized using the
|
|
framework-appropriate method, different tools require translators to localize
|
|
them via different interfaces. Inasmuch as possible, we should make
|
|
translators only need to use a single tool to translate the whole Tor suite.
|
|
|
|
\section{Support}
|
|
|
|
It would be nice to set up some {\bf user support infrastructure} and
|
|
{\bf contributor support infrastructure}, especially focusing on server
|
|
operators and on coordinating volunteers.
|
|
|
|
This includes intuitive and easy ticket systems for bug reports and
|
|
feature suggestions (not just mailing lists with a half dozen people
|
|
and no clear roles for who answers what), but it also includes a more
|
|
personalized and efficient framework for interaction so we keep the
|
|
attention and interest of the contributors, and so we make them feel
|
|
helpful and wanted.
|
|
|
|
\section{Documentation}
|
|
|
|
\subsection{Unified documentation scheme}
|
|
|
|
We need to {\bf inventory our documentation.} Our documentation so far has
|
|
been mostly produced on an {\it ad hoc} basis, in response to particular
|
|
needs and requests. We should figure out what documentation we have, which of
|
|
it (if any) should get priority, and whether we can't put it all into a
|
|
single format.
|
|
|
|
We could {\bf unify the docs} into a single book-like thing. This will also
|
|
help us identify what sections of the ``book'' are missing.
|
|
|
|
\subsection{Missing technical documentation}
|
|
|
|
We should {\bf revise our design paper} to reflect the new decisions and
|
|
research we've made since it was published in 2004. This will help other
|
|
researchers evaluate and suggest improvements to Tor's current design.
|
|
|
|
Other projects sometimes implement the client side of our protocol. We
|
|
encourage this, but we should write {\bf a document about how to avoid
|
|
excessive resource use}, so we don't need to worry that they will do so
|
|
without regard to the effect of their choices on server resources.
|
|
|
|
\subsection{Missing user documentation}
|
|
|
|
Our documentation falls into two broad categories: some is `discoursive' and
|
|
explains in detail why users should take certain actions, and other
|
|
documentation is `comprehensive' and describes all of Tor's features. Right
|
|
now, we have no document that is both deep, readable, and thorough. We
|
|
should correct this by identifying missing spots in our design.
|
|
|
|
\bibliographystyle{plain} \bibliography{tor-design}
|
|
|
|
\end{document}
|
|
|