\documentclass{llncs} \usepackage{url} \usepackage{amsmath} \usepackage{epsfig} \newenvironment{tightlist}{\begin{list}{$\bullet$}{ \setlength{\itemsep}{0mm} \setlength{\parsep}{0mm} % \setlength{\labelsep}{0mm} % \setlength{\labelwidth}{0mm} % \setlength{\topsep}{0mm} }}{\end{list}} \begin{document} \title{Challenges in practical low-latency stream anonymity (DRAFT)} \author{Roger Dingledine and Nick Mathewson} \institute{The Free Haven Project\\ \email{\{arma,nickm\}@freehaven.net}} \maketitle \pagestyle{empty} \begin{abstract} foo \end{abstract} \section{Introduction} Tor is a low-latency anonymous communication overlay network \cite{tor-design} designed to be practical and usable for securing TCP streams over the Internet. We have been operating a publicly deployed Tor network since October 2003. Tor aims to resist observers and insiders by distributing each transaction over several nodes in the network. This ``distributed trust'' approach means the Tor network can be safely operated and used by a wide variety of mutually distrustful users, providing more sustainability and security than previous attempts at anonymizing networks. The Tor network has a broad range of users, including ordinary citizens who want to avoid being profiled for targeted advertisements, corporations who don't want to reveal information to their competitors, and law enforcement and government intelligence agencies who need to do operations on the Internet without being noticed. Tor has been funded by the U.S. Navy, for use in securing government communications, and also by the Electronic Frontier Foundation, for use in maintaining civil liberties for ordinary citizens online. The Tor protocol is one of the leading choices to be the anonymizing layer in the European Union's PRIME directive to help maintain privacy in Europe. The University of Dresden in Germany has integrated an independent implementation of the Tor protocol into their popular Java Anon Proxy anonymizing client. This wide variety of interests helps maintain both the stability and the security of the network. Tor has a weaker threat model than many anonymity designs in the literature. This is because we our primary requirements are to have a practical and useful network, and from there we aim to provide as much anonymity as we can. %need to discuss how we take the approach of building the thing, and then %assuming that, how much anonymity can we get. we're not here to model or %to simulate or to produce equations and formulae. but those have their %roles too. This paper aims to give the reader enough information to understand the technical and policy issues that Tor faces as we continue deployment, and to lay a research agenda for others to help in addressing some of these issues. Section \ref{sec:what-is-tor} gives an overview of the Tor design and ours goals. We go on in Section \ref{sec:related} to describe Tor's context in the anonymity space. Sections \ref{sec:crossroads-policy} and \ref{sec:crossroads-technical} describe the practical challenges, both policy and technical respectively, that stand in the way of moving from a practical useful network to a practical useful anonymous network. \section{What Is Tor} \label{sec:what-is-tor} \subsection{Distributed trust: safety in numbers} Tor provides \emph{forward privacy}, so that users can connect to Internet sites without revealing their logical or physical locations to those sites or to observers. It also provides \emph{location-hidden services}, so that critical servers can support authorized users without giving adversaries an effective vector for physical or online attacks. Our design provides this protection even when a portion of its own infrastructure is controlled by an adversary. To make private connections in Tor, users incrementally build a path or \emph{circuit} of encrypted connections through servers on the network, extending it one step at a time so that each server in the circuit only learns which server extended to it and which server it has been asked to extend to. The client negotiates a separate set of encryption keys for each step along the circuit. Once a circuit has been established, the client software waits for applications to request TCP connections, and directs these application streams along the circuit. Many streams can be multiplexed along a single circuit, so applications don't need to wait for keys to be negotiated every time they open a connection. Because each server sees no more than one end of the connection, a local eavesdropper or a compromised server cannot use traffic analysis to link the connection's source and destination. The Tor client software rotates circuits periodically to prevent long-term linkability between different actions by a single user. Tor differs from other deployed systems for traffic analysis resistance in its security and flexibility. Mix networks such as Mixmaster or its successor Mixminion \cite{minion-design} gain the highest degrees of anonymity at the expense of introducing highly variable delays, thus making them unsuitable for applications such as web browsing that require quick response times. Commercial single-hop proxies such as {\url{anonymizer.com}} present a single point of failure, where a single compromise can expose all users' traffic, and a single-point eavesdropper can perform traffic analysis on the entire network. Also, their proprietary implementations place any infrastucture that depends on these single-hop solutions at the mercy of their providers' financial health. Tor can handle any TCP-based protocol, such as web browsing, instant messaging and chat, and secure shell login; and it is the only implemented anonymizing design with an integrated system for secure location-hidden services. No organization can achieve this security on its own. If a single corporation or government agency were to build a private network to protect its operations, any connections entering or leaving that network would be obviously linkable to the controlling organization. The members and operations of that agency would be easier, not harder, to distinguish. Instead, to protect our networks from traffic analysis, we must collaboratively blend the traffic from many organizations and private citizens, so that an eavesdropper can't tell which users are which, and who is looking for what information. By bringing more users onto the network, all users become more secure \cite{econymics}. Naturally, organizations will not want to depend on others for their security. If most participating providers are reliable, Tor tolerates some hostile infiltration of the network. For maximum protection, the Tor design includes an enclave approach that lets data be encrypted (and authenticated) end-to-end, so high-sensitivity users can be sure it hasn't been read or modified. This even works for Internet services that don't have built-in encryption and authentication, such as unencrypted HTTP or chat, and it requires no modification of those services to do so. weasel's graph of \# nodes and of bandwidth, ideally from week 0. Tor has the following goals. and we made these assumptions when trying to design the thing. \section{Tor's position in the anonymity field} \label{sec:related} There are many other classes of systems: single-hop proxies, open proxies, jap, mixminion, flash mixes, freenet, i2p, mute/ants/etc, tarzan, morphmix, freedom. Give brief descriptions and brief characterizations of how we differ. This is not the breakthrough stuff and we only have a page or two for it. have a serious discussion of morphmix's assumptions, since they would seem to be the direct competition. in fact tor is a flexible architecture that would encompass morphmix, and they're nearly identical except for path selection and node discovery. and the trust system morphmix has seems overkill (and/or insecure) based on the threat model we've picked. \section{Threat model} discuss $\frac{c^2}{n^2}$, except how in practice the chance of owning the last hop is not c/n since that doesn't take the destination (website) into account. so in cases where the adversary does not also control the final destination we're in good shape, but if he *does* then we'd be better off with a system that lets each hop choose a path. in practice tor's threat model is based entirely on the goal of dispersal and diversity. george and steven describe an attack \cite{draft} that lets them determine the nodes used in a circuit; yet they can't identify alice or bob through this attack. so it's really just the endpoints that remain secure. and the enclave model seems particularly threatened by this, since this attack lets us identify endpoints when they're servers. see \ref{subsec:helper-nodes} for discussion of some ways to address this issue. see \ref{subsec:routing-zones} for discussion of larger adversaries and our dispersal goals. \section{Crossroads: Policy issues} \label{sec:crossroads-policy} Many of the issues the Tor project needs to address are not just a matter of system design or technology development. In particular, the Tor project's \emph{image} with respect to its users and the rest of the Internet impacts the security it can provide. As an example to motivate this section, some U.S.~Department of Enery penetration testing engineers are tasked with compromising DoE computers from the outside. They only have a limited number of ISPs from which to launch their attacks, and they found that the defenders were recognizing attacks because they came from the same IP space. These engineers wanted to use Tor to hide their tracks. First, from a technical standpoint, Tor does not support the variety of IP packets they would like to use in such attacks (see Section \ref{subsec:ip-vs-tcp}). But aside from this, we also decided that it would probably be poor precedent to encourage such use -- even legal use that improves national security -- and managed to dissuade them. With this image issue in mind, here we discuss the Tor user base and Tor's interaction with other services on the Internet. \subsection{Usability} Usability: fc03 paper was great, except the lower latency you are the less useful it seems it is. A Tor gui, how jap's gui is nice but does not reflect the security they provide. Public perception, and thus advertising, is a security parameter. \subsection{Image, usability, and sustainability} Image: substantial non-infringing uses. Image is a security parameter, since it impacts user base and perceived sustainability. Sustainability. Previous attempts have been commercial which we think adds a lot of unnecessary complexity and accountability. Freedom didn't collect enough money to pay its servers; JAP bandwidth is supported by continued money, and they periodically ask what they will do when it dries up. good uses are kept private, bad uses are publicized. not good. \subsection{Reputability} Yet another factor in the safety of a given network is its reputability: the perception of its social value based on its current users. If I'm the only user of a system, it might be socially accepted, but I'm not getting any anonymity. Add a thousand Communists, and I'm anonymous, but everyone thinks I'm a Commie. Add a thousand random citizens (cancer survivors, privacy enthusiasts, and so on) and now I'm hard to profile. The more cancer survivors on Tor, the better for the human rights activists. The more script kiddies, the worse for the normal users. Thus, reputability is an anonymity issue for two reasons. First, it impacts the sustainability of the network: a network that's always about to be shut down has difficulty attracting and keeping users, so its anonymity set suffers. Second, a disreputable network attracts the attention of powerful attackers who may not mind revealing the identities of all the users to uncover the few bad ones. While people therefore have an incentive for the network to be used for ``more reputable'' activities than their own, there are still tradeoffs involved when it comes to anonymity. To follow the above example, a network used entirely by cancer survivors might welcome some Communists onto the network, though of course they'd prefer a wider variety of users. The impact of public perception on security is especially important during the bootstrapping phase of the network, where the first few widely publicized uses of the network can dictate the types of users it attracts next. \subsection{Tor and file-sharing} Bittorrent and dmca. Should we add an IDS to autodetect protocols and snipe them? \subsection{Tor and blacklists} Takedowns and efnet abuse and wikipedia complaints and irc networks. It was long expected that, alongside Tor's legitimate users, it would also attract troublemakers who exploited Tor in order to abuse services on the Internet. Our initial answer to this situation was to use ``exit policies'' to allow individual Tor servers to block access to specific IP/port ranges. This approach was meant to make operators more willing to run Tor by allowing them to prevent their servers from being used for abusing particular services. For example, all Tor servers currently block SMTP (port 25), in order to avoid being used to send spam. This approach is useful, but is insufficient for two reasons. First, since it is not possible to force all ORs to block access to any given service, many of those services try to block Tor instead. More broadly, while being blockable is important to being good netizens, we would like to encourage services to allow anonymous access; services should not need to decide between blocking legitimate anonymous use and allowing unlimited abuse. This is potentially a bigger problem than it may appear. On the one hand, if people want to refuse connections from you on their servers it would seem that they should be allowed to. But, a possible major problem with the blocking of Tor is that it's not just the decision of the individual server administrator whose deciding if he wants to post to wikipedia from his Tor node address or allow people to read wikipedia anonymously through his Tor node. If e.g., s/he comes through a campus or corporate NAT, then the decision must be to have the entire population behind it able to have a Tor exit node or write access to wikipedia. This is a loss for both of us (Tor and wikipedia). We don't want to compete for (or divvy up) the NAT protected entities of the world. (A related problem is that many IP blacklists are not terribly fine-grained. No current IP blacklist, for example, allow a service provider to blacklist only those Tor servers that allow access to a specific IP or port, even though this information is readily available. One IP blacklist even bans every class C network that contains a Tor server, and recommends banning SMTP from these networks even though Tor does not allow SMTP at all.) Problems of abuse occur mainly with services such as IRC networks and Wikipedia, which rely on IP-blocking to ban abusive users. While at first blush this practice might seem to depend on the anachronistic assumption that each IP is an identifier for a single user, it is actually more reasonable in practice: it assumes that non-proxy IPs are a costly resource, and that an abuser can not change IPs at will. By blocking IPs which are used by Tor servers, open proxies, and service abusers, these systems hope to make ongoing abuse difficult. Although the system is imperfect, it works tolerably well for them in practice. But of course, we would prefer that legitimate anonymous users be able to access abuse-prone services. One conceivable approach would be to require would-be IRC users, for instance, to register accounts if they wanted to access the IRC network from Tor. But in practise, this would not significantly impede abuse if creating new accounts were easily automatable; this is why services use IP blocking. In order to deter abuse, pseudonymous identities need to impose a significant switching cost in resources or human time. Once approach, similar to that taken by Freedom, would be to bootstrap some non-anonymous costly identification mechanism to allow access to a blind-signature pseudonym protocol. This would effectively create costly pseudonyms, which services could require in order to allow anonymous access. This approach has difficulties in practise, however: \begin{tightlist} \item Unlike Freedom, Tor is not a commercial service. Therefore, it would be a shame to require payment in order to make Tor useful, or to make non-paying users second-class citizens. \item It is hard to think of an underlying resource that would actually work. We could use IP addresses, but that's the problem, isn't it? \item Managing single sign-on services is not considered a well-solved problem in practice. If Microsoft can't get universal acceptance for passport, why do we think that a Tor-specific solution would do any good? \item Even if we came up with a perfect authentication system for our needs, there's no guarantee that any service would actually start using it. It would require a nonzero effort for them to support it, and it might just be less hassle for them to block tor anyway. \end{tightlist} Squishy IP based ``authentication'' and ``authorization'' is a reality we must contend with. We should say something more about the analogy with SSNs. \subsection{Other} Tor's scope: How much should Tor aim to do? Applications that leak data: we can say they're not our problem, but they're somebody's problem. Also, the more widely deployed Tor becomes, the more people who need a deployed overlay network tell us they'd like to use us if only we added the following more features. For example, Blossom \cite{blossom} and random community wireless projects both want source-routable overlay networks for their own purposes. Fortunately, our modular design separates routing from node discovery; so we could implement Morphmix in Tor just by implementing the Morphmix-specific node discovery and path selection pieces. On the other hand, we could easily get distracted building a general-purpose overlay library, and we're only a few developers. Should we allow revocation of anonymity if a threshold of servers want to? Logging. Making logs not revealing. A happy coincidence that verbose logging is our \#2 performance bottleneck. Is there a way to detect modified servers, or to have them volunteer the information that they're logging verbosely? Would that actually solve any attacks? \section{Crossroads: Scaling and Design choices} \label{sec:crossroads-design} \subsection{Transporting the stream vs transporting the packets} We periodically run into ex ZKS employees who tell us that the process of anonymizing IPs should ``obviously'' be done at the IP layer. Here are the issues that need to be resolved before we'll be ready to switch Tor over to arbitrary IP traffic. \begin{enumerate} \setlength{\itemsep}{0mm} \setlength{\parsep}{0mm} \item [IP packets reveal OS characteristics.] We still need to do IP-level packet normalization, to stop things like IP fingerprinting \cite{ip-fingerprinting}. There exist libraries \cite{ip-normalizing} that can help with this. \item [Application-level streams still need scrubbing.] We still need Tor to be easy to integrate with user-level application-specific proxies such as Privoxy. So it's not just a matter of capturing packets and anonymizing them at the IP layer. \item [Certain protocols will still leak information.] For example, DNS requests destined for my local DNS servers need to be rewritten to be delivered to some other unlinkable DNS server. This requires understanding the protocols we are transporting. \item [The crypto is unspecified.] First we need a block-level encryption approach that can provide security despite packet loss and out-of-order delivery. Freedom allegedly had one, but it was never publicly specified, and we believe it's likely vulnerable to tagging attacks \cite{tor-design}. Also, TLS over UDP is not implemented or even specified, though some early work has begun on that \cite{ben-tls-udp}. \item [We'll still need to tune network parameters]. Since the above encryption system will likely need sequence numbers and maybe more to do replay detection, handle duplicate frames, etc, we will be reimplementing some subset of TCP anyway to manage throughput, congestion control, etc. \item [Exit policies for arbitrary IP packets mean building a secure IDS.] Our server operators tell us that exit policies are one of the main reasons they're willing to run Tor over previous attempts at anonymizing networks. Adding an IDS to handle exit policies would increase the security complexity of Tor, and would likely not work anyway, as evidenced by the entire field of IDS and counter-IDS papers. Many potential abuse issues are resolved by the fact that Tor only transports valid TCP streams (as opposed to arbitrary IP including malformed packets and IP floods), so exit policies become even \emph{more} important as we become able to transport IP packets. We also need a way to compactly characterize the exit policies and let clients parse them to decide which nodes will allow which packets to exit. \item [The Tor-internal name spaces would need to be redesigned.] We support hidden service \tt{.onion} addresses, and other special addresses like \tt{.exit} (see Section \ref{subsec:}), by intercepting the addresses when they are passed to the Tor client. \end{enumerate} This list is discouragingly long right now, but we recognize that it would be good to investigate each of these items in further depth and to understand which are actual roadblocks and which are easier to resolve than we think. We certainly wouldn't mind if Tor one day is able to transport a greater variety of protocols. \subsection{Mid-latency} Mid-latency. Can we do traffic shape to get any defense against George's PET2004 paper? Will padding or long-range dummies do anything then? Will it kill the user base or can we get both approaches to play well together? explain what mid-latency is. propose a single network where users of varying latency goals can combine. Note that in practice as the network is growing and we accept cable modem and dsl nodes, and nodes in other continents, we're *already* looking at many-second delays for some transactions. The engineering required to get this lower is going to be extremely hard. It's worth considering how hard it would be to accept the fixed (higher) latency and improve the protection we get from it. % can somebody besides arma flesh this section out? %\subsection{The DNS problem in practice} \subsection{Measuring performance and capacity} How to measure performance without letting people selectively deny service by distinguishing pings. Heck, just how to measure performance at all. In practice people have funny firewalls that don't match up to their exit policies and Tor doesn't deal. Network investigation: Is all this bandwidth publishing thing a good idea? How can we collect stats better? Note weasel's smokeping, at http://seppia.noreply.org/cgi-bin/smokeping.cgi?target=Tor which probably gives george and steven enough info to break tor? \subsection{Plausible deniability} Does running a server help you or harm you? George's Oakland attack. Plausible deniability -- without even running your traffic through Tor! We have to pick the path length so adversary can't distinguish client from server (how many hops is good?). \subsection{Helper nodes} When does fixing your entry or exit node help you? Helper nodes in the literature don't deal with churn, and especially active attacks to induce churn. Do general DoS attacks have anonymity implications? See e.g. Adam Back's IH paper, but I think there's more to be pointed out here. \subsection{Location-hidden services} Survivable services are new in practice, yes? Hidden services seem less hidden than we'd like, since they stay in one place and get used a lot. They're the epitome of the need for helper nodes. This means that using Tor as a building block for Free Haven is going to be really hard. Also, they're brittle in terms of intersection and observation attacks. Would be nice to have hot-swap services, but hard to design. \subsection{Trust and discovery} The published Tor design adopted a deliberately simplistic design for authorizing new nodes and informing clients about servers and their status. In the early Tor designs, all ORs periodically uploaded a signed description of their locations, keys, and capabilities to each of several well-known {\it directory servers}. These directory servers constructed a signed summary of all known ORs (a ``directory''), and a signed statement of which ORs they believed to be operational at any given time (a ``network status''). Clients periodically downloaded a directory in order to learn the latest ORs and keys, and more frequently downloaded a network status to learn which ORs are likely to be running. ORs also operate as directory caches, in order to lighten the bandwidth on the authoritative directory servers. In order to prevent Sybil attacks (wherein an adversary signs up many purportedly independent servers in order to increase her chances of observing a stream as it enters and leaves the network), the early Tor directory design required the operators of the authoritative directory servers to manually approve new ORs. Unapproved ORs were included in the directory, but clients did not use them at the start or end of their circuits. In practice, directory administrators performed little actual verification, and tended to approve any OR whose operator could compose a coherent email. This procedure may have prevented trivial automated Sybil attacks, but would do little against a clever attacker. There are a number of flaws in this system that need to be addressed as we move forward. They include: \begin{tightlist} \item Each directory server represents an independent point of failure; if any one were compromised, it could immediately compromise all of its users by recommending only compromised ORs. \item The more servers appear join the network, the more unreasonable it becomes to expect clients to know about them all. Directories become unfeasibly large, and downloading the list of servers becomes burdonsome. \item The validation scheme may do as much harm as it does good. It is not only incapable of preventing clever attackers from mounting Sybil attacks, but may deter server operators from joining the network. (For instance, if they expect the validation process to be difficult, or if they do not share any languages in common with the directory server operators.) \end{tightlist} We could try to move the system in several directions, depending on our choice of threat model and requirements. If we did not need to increase network capacity in order to support more users, there would be no reason not to adopt even stricter validation requirements, and reduce the number of servers in the network to a trusted minimum. But since we want Tor to work for as many users as it can, we need XXXXX In order to address the first two issues, it seems wise to move to a system including a number of semi-trusted directory servers, no one of which can compromise a user on its own. Ultimately, of course, we cannot escape the problem of a first introducer: since most users will run Tor in whatever configuration the software ships with, the Tor distribution itself will remain a potential single point of failure so long as it includes the seed keys for directory servers, a list of directory servers, or any other means to learn which servers are on the network. But omitting this information from the Tor distribution would only delegate the trust problem to the individual users, most of whom are presumably less informed about how to make trust decisions than the Tor developers. %Network discovery, sybil, node admission, scaling. It seems that the code %will ship with something and that's our trust root. We could try to get %people to build a web of trust, but no. Where we go from here depends %on what threats we have in mind. Really decentralized if your threat is %RIAA; less so if threat is to application data or individuals or... Game theory for helper nodes: if Alice offers a hidden service on a server (enclave model), and nobody ever uses helper nodes, then against George+Steven's attack she's totally nailed. If only Alice uses a helper node, then she's still identified as the source of the data. If everybody uses a helper node (including Alice), then the attack identifies the helper node and also Alice, and knows which one is which. If everybody uses a helper node (but not Alice), then the attacker figures the real source was a client that is using Alice as a helper node. [How's my logic here?] in practice, sites like bloggers without borders (www.b19s.org) are running tor servers but more important are advertising a hidden-service address on their front page. doing this can provide increased robustness if they used the dual-IP approach we describe in tor-design, but in practice they do it to a) increase visibility of the tor project and their support for privacy, and b) to offer a way for their users, using vanilla software, to get end-to-end encryption and end-to-end authentication to their website. \section{Crossroads: Scaling} %\label{sec:crossroads-scaling} %P2P + anonymity issues: Tor is running today with hundreds of servers and tens of thousands of users, but it will certainly not scale to millions. Scaling Tor involves three main challenges. First is safe server discovery, both bootstrapping -- how a Tor client can robustly find an initial server list -- and ongoing -- how a Tor client can learn about a fair sample of honest servers and not let the adversary control his circuits (see Section x). Second is detecting and handling the speed and reliability of the variety of servers we must use if we want to accept many servers (see Section y). Since the speed and reliability of a circuit is limited by its worst link, we must learn to track and predict performance. Finally, in order to get a large set of servers in the first place, we must address incentives for users to carry traffic for others (see Section incentives). \subsection{Incentives} There are three behaviors we need to encourage for each server: relaying traffic; providing good throughput and reliability while doing it; and allowing traffic to exit the network from that server. We encourage these behaviors through \emph{indirect} incentives, that is, designing the system and educating users in such a way that users with certain goals will choose to relay traffic. In practice, the main incentive for running a Tor server is social benefit: volunteers altruistically donate their bandwidth and time. We also keep public rankings of the throughput and reliability of servers, much like seti@home. We further explain to users that they can get \emph{better security} by operating a server, because they get plausible deniability (indeed, they may not need to route their own traffic through Tor at all -- blending directly with other traffic exiting Tor may be sufficient protection for them), and because they can use their own Tor server as entry or exit point and be confident it's not run by the adversary. Finally, we can improve the usability and feature set of the software: rate limiting support and easy packaging decrease the hassle of maintaining a server, and our configurable exit policies allow each operator to advertise a policy describing the hosts and ports to which he feels comfortable connecting. Beyond these, however, there is also a need for \emph{direct} incentives: providing payment or other resources in return for high-quality service. Paying actual money is problematic: decentralized e-cash systems are not yet practical, and a centralized collection system not only reduces robustness, but also has failed in the past (the history of commercial anonymizing networks is littered with failed attempts). A more promising option is to use a tit-for-tat incentive scheme: provide better service to nodes that have provided good service to you. Unfortunately, such an approach introduces new anonymity problems. Does the incentive system enable the adversary to attract more traffic by performing well? Typically a user who chooses evenly from all options is most resistant to an adversary targetting him, but that approach prevents us from handling heterogeneous servers \cite{casc-rep}. When a server (call him Steve) performs well for Alice, does Steve gain reputation with the entire system, or just with Alice? If the entire system, how does Alice tell everybody about her experience in a way that prevents her from lying about it yet still protects her identity? If Steve's behavior only affects Alice's behavior, does this allow Steve to selectively perform only for Alice, and then break her anonymity later when somebody (presumably Alice) routes through his node? These are difficult and open questions, yet choosing not to scale means leaving most users to a less secure network or no anonymizing network at all. We will start with a simplified approach to the tit-for-tat incentive scheme based on two rules: (1) each node should measure the service it receives from adjacent nodes, and provide service relative to the received service, but (2) when a node is making decisions that affect its own security (e.g. when building a circuit for its own application connections), it should choose evenly from a sufficiently large set of nodes that meet some minimum service threshold. This approach allows us to discourage bad service without opening Alice up as much to attacks. %XXX rewrite the above so it sounds less like a grant proposal and %more like a "if somebody were to try to solve this, maybe this is a %good first step". %We should implement the above incentive scheme in the %deployed Tor network, in conjunction with our plans to add the necessary %associated scalability mechanisms. We will do experiments (simulated %and/or real) to determine how much the incentive system improves %efficiency over baseline, and also to determine how far we are from %optimal efficiency (what we could get if we ignored the anonymity goals). \subsection{Peer-to-peer / practical issues} Making use of servers with little bandwidth. How to handle hammering by certain applications. Handling servers that are far away from the rest of the network, e.g. on the continents that aren't North America and Europe. High latency, often high packet loss. Running Tor servers behind NATs, behind great-firewalls-of-China, etc. Restricted routes. How to propagate to everybody the topology? BGP style doesn't work because we don't want just *one* path. Point to Geoff's stuff. \subsection{ISP-class adversaries} Routing-zones. It seems that our threat model comes down to diversity and dispersal. But hard for Alice to know how to act. Many questions remain. \subsection{The China problem} We have lots of users in Iran and similar (we stopped logging, so it's hard to know now, but many Persian sites on how to use Tor), and they seem to be doing ok. But the China problem is bigger. Cite Stefan's paper, and talk about how we need to route through clients, and we maybe we should start with a time-release IP publishing system + advogato based reputation system, to bound the number of IPs leaked to the adversary. \section{The Future} \label{sec:conclusion} \bibliographystyle{plain} \bibliography{tor-design} \end{document}