tor/doc/spec/proposals/115-two-hop-paths.txt

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Filename: 115-two-hop-paths.txt
Title: Two Hop Paths
Version: $Revision$
Last-Modified: $Date$
Author: Mike Perry
Created:
Status: Dead
Supersedes: 112
Overview:
The idea is that users should be able to choose if they would like
to have either two or three hop paths through the tor network.
Let us be clear: the users who would choose this option should be
those that are concerned with IP obfuscation only: ie they would not be
targets of a resource-intensive multi-node attack. It is sometimes said
that these users should find some other network to use other than Tor.
This is a foolish suggestion: more users improves security of everyone,
and the current small userbase size is a critical hindrance to
anonymity, as is discussed below and in [1].
This value should be modifiable from the controller, and should be
available from Vidalia.
Motivation:
The Tor network is slow and overloaded. Increasingly often I hear
stories about friends and friends of friends who are behind firewalls,
annoying censorware, or under surveillance that interferes with their
productivity and Internet usage, or chills their speech. These people
know about Tor, but they choose to put up with the censorship because
Tor is too slow to be usable for them. In fact, to download a fresh,
complete copy of levine-timing.pdf for the Theoretical Argument
section of this proposal over Tor took me 3 tries.
Furthermore, the biggest current problem with Tor's anonymity for
those who really need it is not someone attacking the network to
discover who they are. It's instead the extreme danger that so few
people use Tor because it's so slow, that those who do use it have
essentially no confusion set.
The recent case where the professor and the rogue Tor user were the
only Tor users on campus, and thus suspected in an incident involving
Tor and that University underscores this point: "That was why the police
had come to see me. They told me that only two people on our campus were
using Tor: me and someone they suspected of engaging in an online scam.
The detectives wanted to know whether the other user was a former
student of mine, and why I was using Tor"[1].
Not only does Tor provide no anonymity if you use it to be anonymous
but are obviously from a certain institution, location or circumstance,
it is also dangerous to use Tor for risk of being accused of having
something significant enough to hide to be willing to put up with
the horrible performance as opposed to using some weaker alternative.
There are many ways to improve the speed problem, and of course we
should and will implement as many as we can. Johannes's GSoC project
and my reputation system are longer term, higher-effort things that
will still provide benefit independent of this proposal.
However, reducing the path length to 2 for those who do not need the
extra anonymity 3 hops provide not only improves their Tor experience
but also reduces their load on the Tor network by 33%, and should
increase adoption of Tor by a good deal. That's not just Win-Win, it's
Win-Win-Win.
Who will enable this option?
This is the crux of the proposal. Admittedly, there is some anonymity
loss and some degree of decreased investment required on the part of
the adversary to attack 2 hop users versus 3 hop users, even if it is
minimal and limited mostly to up-front costs and false positives.
The key questions are:
1. Are these users in a class such that their risk is significantly
less than the amount of this anonymity loss?
2. Are these users able to identify themselves?
Many many users of Tor are not at risk for an adversary capturing c/n
nodes of the network just to see what they do. These users use Tor to
circumvent aggressive content filters, or simply to keep their IP out of
marketing and search engine databases. Most content filters have no
interest in running Tor nodes to catch violators, and marketers
certainly would never consider such a thing, both on a cost basis and a
legal one.
In a sense, this represents an alternate threat model against these
users who are not at risk for Tor's normal threat model.
It should be evident to these users that they fall into this class. All
that should be needed is a radio button
* "I use Tor for local content filter circumvention and/or IP obfuscation,
not anonymity. Speed is more important to me than high anonymity.
No one will make considerable efforts to determine my real IP."
* "I use Tor for anonymity and/or national-level, legally enforced
censorship. It is possible effort will be taken to identify
me, including but not limited to network surveillance. I need more
protection."
and then some explanation in the help for exactly what this means, and
the risks involved with eliminating the adversary's need for timing
attacks with respect to false positives. Ultimately, the decision is a
simple one that can be made without this information, however. The user
does not need Paul Syverson to instruct them on the deep magic of Onion
Routing to make this decision. They just need to know why they use Tor.
If they use it just to stay out of marketing databases and/or bypass a
local content filter, two hops is plenty. This is likely the vast
majority of Tor users, and many non-users we would like to bring on
board.
So, having established this class of users, let us now go on to
examine theoretical and practical risks we place them at, and determine
if these risks violate the users needs, or introduce additional risk
to node operators who may be subject to requests from law enforcement
to track users who need 3 hops, but use 2 because they enjoy the
thrill of russian roulette.
Theoretical Argument:
It has long been established that timing attacks against mixed
and onion networks are extremely effective, and that regardless
of path length, if the adversary has compromised your first and
last hop of your path, you can assume they have compromised your
identity for that connection.
In fact, it was demonstrated that for all but the slowest, lossiest
networks, error rates for false positives and false negatives were
very near zero[2]. Only for constant streams of traffic over slow and
(more importantly) extremely lossy network links did the error rate
hit 20%. For loss rates typical to the Internet, even the error rate
for slow nodes with constant traffic streams was 13%.
When you take into account that most Tor streams are not constant,
but probably much more like their "HomeIP" dataset, which consists
mostly of web traffic that exists over finite intervals at specific
times, error rates drop to fractions of 1%, even for the "worst"
network nodes.
Therefore, the user has little benefit from the extra hop, assuming
the adversary does timing correlation on their nodes. Since timing
correlation is simply an implementation issue and is most likely
a single up-front cost (and one that is like quite a bit cheaper
than the cost of the machines purchased to host the nodes to mount
an attack), the real protection is the low probability of getting
both the first and last hop of a client's stream.
Practical Issues:
Theoretical issues aside, there are several practical issues with the
implementation of Tor that need to be addressed to ensure that
identity information is not leaked by the implementation.
Exit policy issues:
If a client chooses an exit with a very restrictive exit policy
(such as an IP or IP range), the first hop then knows a good deal
about the destination. For this reason, clients should not select
exits that match their destination IP with anything other than "*".
Partitioning:
Partitioning attacks form another concern. Since Tor uses telescoping
to build circuits, it is possible to tell a user is constructing only
two hop paths at the entry node and on the local network. An external
adversary can potentially differentiate 2 and 3 hop users, and decide
that all IP addresses connecting to Tor and using 3 hops have something
to hide, and should be scrutinized more closely or outright apprehended.
One solution to this is to use the "leaky-circuit" method of attaching
streams: The user always creates 3-hop circuits, but if the option
is enabled, they always exit from their 2nd hop. The ideal solution
would be to create a RELAY_SHISHKABOB cell which contains onion
skins for every host along the path, but this requires protocol
changes at the nodes to support.
Guard nodes:
Since guard nodes can rotate due to client relocation, network
failure, node upgrades and other issues, if you amortize the risk a
mobile, dialup, or otherwise intermittently connected user is exposed to
over any reasonable duration of Tor usage (on the order of a year), it
is the same with or without guard nodes. Assuming an adversary has
c%/n% of network bandwidth, and guards rotate on average with period R,
statistically speaking, it's merely a question of if the user wishes
their risk to be concentrated with probability c/n over an expected
period of R*c, and probability 0 over an expected period of R*(n-c),
versus a continuous risk of (c/n)^2. So statistically speaking, guards
only create a time-tradeoff of risk over the long run for normal Tor
usage. Rotating guards do not reduce risk for normal client usage long
term.[3]
On other other hand, assuming a more stable method of guard selection
and preservation is devised, or a more stable client side network than
my own is typical (which rotates guards frequently due to network issues
and moving about), guard nodes provide a tradeoff in the form of c/n% of
the users being "sacrificial users" who are exposed to high risk O(c/n)
of identification, while the rest of the network is exposed to zero
risk.
The nature of Tor makes it likely an adversary will take a "shock and
awe" approach to suppressing Tor by rounding up a few users whose
browsing activity has been observed to be made into examples, in an
attempt to prove that Tor is not perfect.
Since this "shock and awe" attack can be applied with or without guard
nodes, stable guard nodes do offer a measure of accountability of sorts.
If a user was using a small set of guard nodes and knows them well, and
then is suddenly apprehended as a result of Tor usage, having a fixed
set of entry points to suspect is a lot better than suspecting the whole
network. Conversely, it can also give non-apprehended users comfort
that they are likely to remain safe indefinitely with their set of (now
presumably trusted) guards. This is probably the most beneficial
property of reliable guards: they deter the adversary from mounting
"shock and awe" attacks because the surviving users will not
intimidated, but instead made more confident. Of course, guards need to
be made much more stable and users need to be encouraged to know their
guards for this property to really take effect.
This beneficial property of client vigilance also carries over to an
active adversary, except in this case instead of relying on the user
to remember their guard nodes and somehow communicate them after
apprehension, the code can alert them to the presence of an active
adversary before they are apprehended. But only if they use guard nodes.
So lets consider the active adversary: Two hop paths allow malicious
guards to get considerably more benefit from failing circuits if they do
not extend to their colluding peers for the exit hop. Since guards can
detect the number of hops in a path via either timing or by statistical
analysis of the exit policy of the 2nd hop, they can perform this attack
predominantly against 2 hop users.
This can be addressed by completely abandoning an entry guard after a
certain ratio of extend or general circuit failures with respect to
non-failed circuits. The proper value for this ratio can be determined
experimentally with TorFlow. There is the possibility that the local
network can abuse this feature to cause certain guards to be dropped,
but they can do that anyways with the current Tor by just making guards
they don't like unreachable. With this mechanism, Tor will complain
loudly if any guard failure rate exceeds the expected in any failure
case, local or remote.
Eliminating guards entirely would actually not address this issue due
to the time-tradeoff nature of risk. In fact, it would just make it
worse. Without guard nodes, it becomes much more difficult for clients
to become alerted to Tor entry points that are failing circuits to make
sure that they only devote bandwidth to carry traffic for streams which
they observe both ends. Yet the rogue entry points are still able to
significantly increase their success rates by failing circuits.
For this reason, guard nodes should remain enabled for 2 hop users,
at least until an IP-independent, undetectable guard scanner can
be created. TorFlow can scan for failing guards, but after a while,
its unique behavior gives away the fact that its IP is a scanner and
it can be given selective service.
Consideration of risks for node operators:
There is a serious risk for two hop users in the form of guard
profiling. If an adversary running an exit node notices that a
particular site is always visited from a fixed previous hop, it is
likely that this is a two hop user using a certain guard, which could be
monitored to determine their identity. Thus, for the protection of both
2 hop users and node operators, 2 hop users should limit their guard
duration to a sufficient number of days to verify reliability of a node,
but not much more. This duration can be determined experimentally by
TorFlow.
Considering a Tor client builds on average 144 circuits/day (10
minutes per circuit), if the adversary owns c/n% of exits on the
network, they can expect to see 144*c/n circuits from this user, or
about 14 minutes of usage per day per percentage of network penetration.
Since it will take several occurrences of user-linkable exit content
from the same predecessor hop for the adversary to have any confidence
this is a 2 hop user, it is very unlikely that any sort of demands made
upon the predecessor node would guaranteed to be effective (ie it
actually was a guard), let alone be executed in time to apprehend the
user before they rotated guards.
The reverse risk also warrants consideration. If a malicious guard has
orders to surveil Mike Perry, it can determine Mike Perry is using two
hops by observing his tendency to choose a 2nd hop with a viable exit
policy. This can be done relatively quickly, unfortunately, and
indicates Mike Perry should spend some of his time building real 3 hop
circuits through the same guards, to require them to at least wait for
him to actually use Tor to determine his style of operation, rather than
collect this information from his passive building patterns.
However, to actively determine where Mike Perry is going, the guard
will need to require logging ahead of time at multiple exit nodes that
he may use over the course of the few days while he is at that guard,
and correlate the usage times of the exit node with Mike Perry's
activity at that guard for the few days he uses it. At this point, the
adversary is mounting a scale and method of attack (widespread logging,
timing attacks) that works pretty much just as effectively against 3
hops, so exit node operators are exposed to no additional danger than
they otherwise normally are.
Why not fix Pathlen=2?:
The main reason I am not advocating that we always use 2 hops is that
in some situations, timing correlation evidence by itself may not be
considered as solid and convincing as an actual, uninterrupted, fully
traced path. Are these timing attacks as effective on a real network as
they are in simulation? Maybe the circuit multiplexing of Tor can serve
to frustrate them to a degree? Would an extralegal adversary or
authoritarian government even care? In the face of these situation
dependent unknowns, it should be up to the user to decide if this is
a concern for them or not.
It should probably also be noted that even a false positive
rate of 1% for a 200k concurrent-user network could mean that for a
given node, a given stream could be confused with something like 10
users, assuming ~200 nodes carry most of the traffic (ie 1000 users
each). Though of course to really know for sure, someone needs to do
an attack on a real network, unfortunately.
Additionally, at some point cover traffic schemes may be implemented to
frustrate timing attacks on the first hop. It is possible some expert
users may do this ad-hoc already, and may wish to continue using 3 hops
for this reason.
Implementation:
new_route_len() can be modified directly with a check of the
Pathlen option. However, circuit construction logic should be
altered so that both 2 hop and 3 hop users build the same types of
circuits, and the option should ultimately govern circuit selection,
not construction. This improves coverage against guard nodes being
able to passively profile users who aren't even using Tor.
PathlenCoinWeight, anyone? :)
The exit policy hack is a bit more tricky. compare_addr_to_addr_policy
needs to return an alternate ADDR_POLICY_ACCEPTED_WILDCARD or
ADDR_POLICY_ACCEPTED_SPECIFIC return value for use in
circuit_is_acceptable.
The leaky exit is trickier still.. handle_control_attachstream
does allow paths to exit at a given hop. Presumably something similar
can be done in connection_ap_handshake_process_socks, and elsewhere?
Circuit construction would also have to be performed such that the
2nd hop's exit policy is what is considered, not the 3rd's.
The entry_guard_t structure could have num_circ_failed and
num_circ_succeeded members such that if it exceeds F% circuit
extend failure rate to a second hop, it is removed from the entry list.
F should be sufficiently high to avoid churn from normal Tor circuit
failure as determined by TorFlow scans.
The Vidalia option should be presented as a radio button.
Migration:
Phase 1: Adjust exit policy checks if Pathlen is set, implement leaky
circuit ability, and 2-3 hop circuit selection logic governed by
Pathlen.
Phase 2: Experiment to determine the proper ratio of circuit
failures used to expire garbage or malicious guards via TorFlow
(pending Bug #440 backport+adoption).
Phase 3: Implement guard expiration code to kick off failure-prone
guards and warn the user. Cap 2 hop guard duration to a proper number
of days determined sufficient to establish guard reliability (to be
determined by TorFlow).
Phase 4: Make radiobutton in Vidalia, along with help entry
that explains in layman's terms the risks involved.
Phase 5: Allow user to specify path length by HTTP URL suffix.
[1] http://p2pnet.net/story/11279
[2] http://www.cs.umass.edu/~mwright/papers/levine-timing.pdf
[3] Proof available upon request ;)