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Beginnings of a discussion of sparse topology Tor for scaling
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@ -189,7 +189,7 @@ seems overkill (and/or insecure) based on the threat model we've picked.
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\section{Threat model}
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\section{Threat model}
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discuss $\frac{c^2}{n^2}$, except how in practice the chance of owning
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discuss $\frac{c^2}{n^2}$, except how in practice the chance of owning
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the last hop is not c/n since that doesn't take the destination (website)
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the last hop is not $c/n$ since that doesn't take the destination (website)
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into account. so in cases where the adversary does not also control the
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into account. so in cases where the adversary does not also control the
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final destination we're in good shape, but if he *does* then we'd be better
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final destination we're in good shape, but if he *does* then we'd be better
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off with a system that lets each hop choose a path.
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off with a system that lets each hop choose a path.
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@ -703,6 +703,66 @@ adversary.
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\cite{advogato}
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\cite{advogato}
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\cite{berkman}
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\cite{berkman}
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\subsection{Non-clique topologies}
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Because of its threat model that is substantially weaker than high
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latency mixnets, Tor is actually in a potentially better position to
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scale at least initially. The issues for scaling include how many
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neighbors can nodes support and how many users (alternatively how much
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application traffic capacity) can the network handle for each new node
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that comes into the network. This depends on many things, most notably
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the traffic capacity of the new nodes. We can observe, however, that
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adding a tor node of any feasible bandwidth will increase the traffic
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capacity of the network. This means that, as a first step to scaling,
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we can focus on the interconnectivity of the nodes, followed by
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directories, discovery, etc.
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By reducing the connectivity of the network we increase the total
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number of nodes that the network can contain. Anonymity implications
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of restricted routes for mix networks has already been explored by
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Danezis~\cite{danezis-pets03}. That paper explicitly considered only
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traffic analysis resistance provided by the network and sidestepped
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questions of traffic confirmation resistance. But, Tor is designed
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only to resist traffic confirmation. For this and other reasons, we
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cannot simply adopt his mixnet results to onion routing networks. If
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an attacker gains minimal increase in the likelyhood of compromising
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the endpoints of a Tor circuit through a sparse network (vs.\ a clique
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on the same node set), then the restriction will have had minimal
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impact on the anonymity provided by that network.
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As Danezis noted, what is wanted is an expander graph, i.e., a graph
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in which any subgraph of nodes is likely to have lots of nodes as
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neighbors. For Tor we can be a bit more specific. As long as most
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(non-enclave) circuits have three nodes, then ideally any pair of nodes
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should be linked to every node in the network with high probability.
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I need to work out some numbers here: Consider networks of 100,
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200, 500, and 1000 nodes with this property. Figure out the savings
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in connectivity in each case. Consider also reducing the probability.
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Something to do tomorrow.
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Need to tell some story a la the FC02 paper about assigning the
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links in the graph. Also tomorrow or so.
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This approach does not take different node bandwidth into account. We
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could consider a clique of high bandwidth/high reliability nodes that
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is connected to all nodes in the network. All circuits would then go
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through this `backbone'. This simplifies many issues but makes the
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expected minimum path length four. On the other hand, it is not
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likely that there will be substantial increase in network latency
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given that the added hop will always be between high bandwidth nodes.
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Directories need not be too much more of a problem. They can list the
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Top tier nodes, then for each of those, to which nodes they are
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connected. For non-enclave purposes, it is enough to download the top
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tier list and a few of those below it. Lots of threat issues here,
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can address them with witness connections or other means. (E.g., does
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it make sense to favor the nodes that are listed by more than one node
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at the top?)
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\section{The Future}
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\section{The Future}
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\label{sec:conclusion}
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\label{sec:conclusion}
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