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- $Id$
- Tor Path Specification
- Roger Dingledine
- Nick Mathewson
- Note: This is an attempt to specify Tor as currently implemented. Future
- versions of Tor will implement improved algorithms.
- This document tries to cover how Tor chooses to build circuits and assign
- streams to circuits. Other implementations MAY take other approaches, but
- implementors should be aware of the anonymity and load-balancing implications
- of their choices.
- THIS SPEC ISN'T DONE OR CORRECT. I'm just copying in relevant info so
- far. The starred points are things we should cover, but not an exhaustive
- list. -NM
- 1. General operation
- Tor begins building circuits as soon as it has enough directory
- information to do so (see section 5.1 of dir-spec.txt). Some circuits are
- built preemptively because we expect to need them later (for user
- traffic), and some are build because of immediate need (for user traffic
- that no current circuit can handle, for testing the network or our
- availability, and so on).
- When a client application creates a new stream (by opening a SOCKS
- connection or launching a resolve request), we attach it to an appropriate
- open (or in-progress) circuit if one exists, and launch a new circuit only
- if no current circuit can handle the request. We rotate circuits over
- time to avoid some profiling attacks.
- These processes are described in more detail below.
- 1b. Types of circuits.
- * Stable / Ordinary
- * Internal / Exit
- 1c. Terminology
- A "path" is an ordered sequence of nodes, not yet built as a circuit.
- A "clean" circuit is one that has not yet been used for any stream or
- rendezvous traffic.
- A "stable" node is one that we believe to have the 'Stable' flag set on
- the basis of our current directory information. A "stable" circuit is one
- that consists entirely of "stable" nodes.
- A "persistent" stream is one that we predict will require a long uptime.
- Currently, Tor does this by examining the stream's target port, and
- comparing it to a list of "long-lived" ports. (Default: 21, 22, 706, 1863,
- 5050, 5190, 5222, 5223, 6667, 8300, 8888.)
- An exit node "supports" a stream if the stream's target IP is known, and
- the stream's IP and target Port are allowed by the exit node's declared
- exit policy. A path "supports" a stream if:
- * The last node in the path "supports" the stream, and
- * If the stream is "persistent," all the nodes in the path are
- "stable".
- An exit node "might support" a stream if the stream's target IP is unknown
- (because we haven't resolved it yet), and the exit node's declared exit
- policy allows some IPs to exit at that port. ???
- 2. Building circuits
- 2.1. When we build.
- When running as a client, Tor tries to maintain at least 3 clean circuits,
- so that new streams can be handled quickly. To increase the likelihood of
- success, Tor tries to predict what exit nodes will be useful by choosing
- from among nodes that support the ports we have used in the recent past.
- If Tor needs to attach a stream that no current exit circuit can support,
- it looks for an existing clean circuit to cannibalize. If we find one,
- we try to extend it another hop to an exit node that might support the
- stream. [Must be internal???]
- If no circuit exists, or is currently being built, along a path that
- might support a stream, we begin building a new circuit that might support
- the stream.
-
- 2.2. Path selection
- We choose the path for each new circuit before we build it. We choose the
- exit node first, followed by the other nodes in the circuit. We do not
- choose the same router twice for the same circuit. We do not choose any
- router in the same family as another in the same circuit. We don't choose
- any non-running or non-valid router unless we have been configured to do
- so. When choosing among multiple candidates for a path element, we choose
- a given router with probability proportional to its advertised bandwidth
- [the smaller of the 'rate' and 'observed' arguments to the "bandwidth"
- element in its descriptor]. If a router's advertised bandwidth is greater
- than MAX_BELIEVEABLE_BANDWIDTH (1.5 MB/sec), we clip to that value.
- Additional restrictions:
- XXX When to use Fast
- XXX When to use Stable
- XXX When to use Named
- If we're building a circuit preemtively, we choose an exit node that might
- support streams to one of our predicted ports; otherwise, we pick an exit
- node that will support a pending stream (if the stream's target is known)
- or that might support a pending stream.
- We pick an entry node from one of our guards; see section 5 below.
- 2.3. Handling failure
- 2.4. Tracking "predicted" ports
- * Choosing the path first, building second.
- * Choosing the length of the circuit.
- * Choosing entries, midpoints, exits.
- * the .exit notation
- * exitnodes, entrynodes, strictexitnodes, strictentrynodes.
- * What to do when an extend fails
- * Keeping track of 'expected' ports
- * And expected hidden service use (client-side and hidserv-side)
- * Backing off from circuit building when a long time has passed
- 3. Attaching streams to circuits
- * Including via the controller.
- * Timeouts and when Tor autoretries.
- * What stream-end-reasons are appropriate for retrying.
- 4. Rendezvous circuits
- 5. Guard nodes
- 6. Testing circuits
- (From some emails by arma)
- Hi folks,
- I've gotten the codebase to the point that I'm going to start trying
- to make helper nodes work well. With luck they will be on by default in
- the final 0.1.1.x release.
- For background on helper nodes, read
- http://wiki.noreply.org/noreply/TheOnionRouter/TorFAQ#RestrictedEntry
- First order of business: the phrase "helper node" sucks. We always have
- to define it after we say it to somebody. Nick likes the phrase "contact
- node", because they are your point-of-contact into the network. That is
- better than phrases like "bridge node". The phrase "fixed entry node"
- doesn't seem to work with non-math people, because they wonder what was
- broken about it. I'm sort of partial to the phrase "entry node" or maybe
- "restricted entry node". In any case, if you have ideas on names, please
- mail me off-list and I'll collate them.
- Right now the code exists to pick helper nodes, store our choices to
- disk, and use them for our entry nodes. But there are three topics
- to tackle before I'm comfortable turning them on by default. First,
- how to handle churn: since Tor nodes are not always up, and sometimes
- disappear forever, we need a plan for replacing missing helpers in a
- safe way. Second, we need a way to distinguish "the network is down"
- from "all my helpers are down", also in a safe way. Lastly, we need to
- examine the situation where a client picks three crummy helper nodes
- and is forever doomed to a lousy Tor experience. Here's my plan:
- How to handle churn.
- - Keep track of whether you have ever actually established a
- connection to each helper. Any helper node in your list that you've
- never used is ok to drop immediately. Also, we don't save that
- one to disk.
- - If all our helpers are down, we need more helper nodes: add a new
- one to the *end*of our list. Only remove dead ones when they have
- been gone for a very long time (months).
- - Pick from the first n (by default 3) helper nodes in your list
- that are up (according to the network-statuses) and reachable
- (according to your local firewall config).
- - This means that order matters when writing/reading them to disk.
- How to deal with network down.
- - While all helpers are down/unreachable and there are no established
- or on-the-way testing circuits, launch a testing circuit. (Do this
- periodically in the same way we try to establish normal circuits
- when things are working normally.)
- (Testing circuits are a special type of circuit, that streams won't
- attach to by accident.)
- - When a testing circuit succeeds, mark all helpers up and hold
- the testing circuit open.
- - If a connection to a helper succeeds, close all testing circuits.
- Else mark that helper down and try another.
- - If the last helper is marked down and we already have a testing
- circuit established, then add the first hop of that testing circuit
- to the end of our helper node list, close that testing circuit,
- and go back to square one. (Actually, rather than closing the
- testing circuit, can we get away with converting it to a normal
- circuit and beginning to use it immediately?)
- How to pick non-sucky helpers.
- - When we're picking a new helper nodes, don't use ones which aren't
- reachable according to our local ReachableAddresses configuration.
- (There's an attack here: if I pick my helper nodes in a very
- restrictive environment, say "ReachableAddresses 18.0.0.0/255.0.0.0:*",
- then somebody watching me use the network from another location will
- guess where I first joined the network. But let's ignore it for now.)
- - Right now we choose new helpers just like we'd choose any entry
- node: they must be "stable" (claim >1day uptime) and "fast" (advertise
- >10kB capacity). In 0.1.1.11-alpha, clients let dirservers define
- "stable" and "fast" however they like, and they just believe them.
- So the next step is to make them a function of the current network:
- e.g. line up all the 'up' nodes in order and declare the top
- three-quarter to be stable, fast, etc, as long as they meet some
- minimum too.
- - If that's not sufficient (it won't be), dirservers should introduce
- a new status flag: in additional to "stable" and "fast", we should
- also describe certain nodes as "entry", meaning they are suitable
- to be chosen as a helper. The first difference would be that we'd
- demand the top half rather than the top three-quarters. Another
- requirement would be to look at "mean time between returning" to
- ensure that these nodes spend most of their time available. (Up for
- two days straight, once a month, is not good enough.)
- - Lastly, we need a function, given our current set of helpers and a
- directory of the rest of the network, that decides when our helper
- set has become "too crummy" and we need to add more. For example,
- this could be based on currently advertised capacity of each of
- our helpers, and it would also be based on the user's preferences
- of speed vs. security.
- ***
- Lasse wrote:
- > I am a bit concerned with performance if we are to have e.g. two out of
- > three helper nodes down or unreachable. How often should Tor check if
- > they are back up and running?
- Right now Tor believes a threshold of directory servers when deciding
- whether each server is up. When Tor observes a server to be down
- (connection failed or building the first hop of the circuit failed),
- it marks it as down and doesn't try it again, until it gets a new
- network-status from somebody, at which point it takes a new concensus
- and marks the appropriate servers as up.
- According to sec 5.1 of dir-spec.txt, the client will try to fetch a new
- network-status at least every 30 minutes, and more often in certain cases.
- With the proposed scheme, we'll also mark all our helpers as up shortly
- after the last one is marked down.
- > When should there be
- > added an extra node to the helper node list? This is kind of an
- > important threshold?
- I agree, this is an important question. I don't have a good answer yet. Is
- it terrible, anonymity-wise, to add a new helper every time only one of
- your helpers is up? Notice that I say add rather than replace -- so you'd
- only use this fourth helper when one of your main three helpers is down,
- and if three of your four are down, you'd add a fifth, but only use it
- when two of the first four are down, etc.
- In fact, this may be smarter than just picking a random node for your
- testing circuit, because if your network goes up and down a lot, then
- eventually you have a chance of using any entry node in the network for
- your testing circuit.
- We have a design choice here. Do we only try to use helpers for the
- connections that will have streams on them (revealing our communication
- partners), or do we also want to restrict the overall set of nodes that
- we'll connect to, to discourage people from enumerating all Tor clients?
- I'm increasingly of the belief that we want to hide our presence too,
- based on the fact that Steven and George and others keep coming up with
- attacks that start with "Assuming we know the set of users".
- If so, then here's a revised "How to deal with network down" section:
- 1) When a helper is marked down or the helper list shrinks, and as
- a result the total number of helpers that are either (up and
- reachable) or (reachable but never connected to) is <= 1, then pick
- a new helper and add it to the end of the list.
- [We count nodes that have never been connected to, since otherwise
- we might keep on adding new nodes before trying any of them. By
- "reachable" I mean "is allowed by ReachableAddresses".]
- 2) When you fail to connect to a helper that has never been connected
- to, you remove him from the list right then (and the above rule
- might kick in).
- 3) When you succeed at connecting to a helper that you've never
- connected to before, mark all reachable helpers earlier in the list
- as up, and close that circuit.
- [We close the circuit, since if the other helpers are now up, we
- prefer to use them for circuits that will reveal communication
- partners.]
- This certainly seems simpler. Are there holes that I'm missing?
- > If running from a laptop you will meet different firewall settings, so
- > how should Helper Nodes settings keep up with moving from an open
- > ReachableAddresses to a FascistFirewall setting after the helper nodes
- > have been selected?
- I added the word "reachable" to three places in the above list, and I
- believe that totally solves this question.
- And as a bonus, it leads to an answer to Nick's attack ("If I pick
- my helper nodes all on 18.0.0.0:*, then I move, you'll know where I
- bootstrapped") -- the answer is to pick your original three helper nodes
- without regard for reachability. Then the above algorithm will add some
- more that are reachable for you, and if you move somewhere, it's more
- likely (though not certain) that some of the originals will become useful.
- Is that smart or just complex?
- > What happens if(when?) performance of the third node is bad?
- My above solution solves this a little bit, in that we always try to
- have two nodes available. But what if they are both up but bad? I'm not
- sure. As my previous mail said, we need some function, given our list
- of helpers and the network directory, that will tell us when we're in a
- bad situation. I can imagine some simple versions of this function --
- for example, when both our working helpers are in the bottom half of
- the nodes, ranked by capacity.
- But the hard part: what's the remedy when we decide there's something
- to fix? Do we add a third, and now we have two crummy ones and a new
- one? Or do we drop one or both of the bad ones?
- Perhaps we believe the latest claim from the network-status concensus,
- and we count a helper the dirservers believe is crummy as "not worth
- trying" (equivalent to "not reachable under our current ReachableAddresses
- config") -- and then the above algorithm would end up adding good ones,
- but we'd go back to the originals if they resume being acceptable? That's
- an appealing design. I wonder if it will cause the typical Tor user to
- have a helper node list that comprises most of the network, though. I'm
- ok with this.
- > Another point you might want to keep in mind, is the possibility to
- > reuse the code in order to add a second layer helper node (meaning node
- > number two) to "protect" the first layer (node number one) helper nodes.
- > These nodes should be tied to each of the first layer nodes. E.g. there
- > is one helper node list, as described in your mail, for each of the
- > first layer nodes, following their create/destroy.
- True. Does that require us to add a fourth hop to our path length,
- since the first hop is from a limited set, the second hop is from a
- limited set, and the third hop might also be constrained because, say,
- we're asking for an unusual exit port?
- > Another of the things might worth adding to the to do list is
- > localization of server (helper) nodes. Making it possible to pick
- > countries/regions where you do (not) want your helper nodes located. (As
- > in "HelperNodesLocated us,!eu" etc.) I know this requires the use of
- > external data and may not be worth it, but it _could_ be integrated at
- > the directory servers only -- adding a list of node IP's and e.g. a
- > country/region code to the directory and thus reduce the overhead. (?)
- > Maybe extending the Family-term?
- I think we are heading towards doing path selection based on geography,
- but I don't have a good sense yet of how that will actually turn out --
- that is, with what mechanism Tor clients will learn the information they
- need. But this seems to be something that is orthogonal to the rest of
- this discussion, so I look forward to having somebody else solve it for
- us, and fitting it in when it's ready. :)
- > And I would like to keep an option to pick the first X helper nodes
- > myself and then let Tor extend this list if these nodes are down (like
- > EntryNodes in current code). Even if this opens up for some new types of
- > "relationship" attacks.
- Good idea. Here's how I'd like to name these:
- The "EntryNodes" config option is a list of seed helper nodes. When we
- read EntryNodes, any node listed in entrynodes but not in the current
- helper node list gets *pre*pended to the helper node list.
- The "NumEntryNodes" config option (currently called NumHelperNodes)
- specifies the number of up, reachable, good-enough helper nodes that
- will make up the pool of possible choices for first hop, counted from
- the front of the helper node list until we have enough.
- The "UseEntryNodes" config option (currently called UseHelperNodes)
- tells us to turn on all this helper node behavior. If you set EntryNodes,
- then this option is implied.
- The "StrictEntryNodes" config option, provided for backward compatibility
- and for debugging, means a) we replace the helper node list with the
- current EntryNodes list, and b) whenever we would do an operation that
- alters the helper node list, we don't. (Yes, this means that if all the
- helper nodes are down, we lose until we mark them up again. But this is
- how it behaves now.)
- > I am sure my next point has been asked before, but what about testing
- > the current speed of the connections when looking for new helper nodes,
- > not only testing the connectivity? I know this might contribute to a lot
- > of overhead in the network, but if this only occur e.g. when using
- > helper nodes as a Hidden Service it might not have that large an impact,
- > but could help availability for the services?
- If we're just going to be testing them when we're first picking them,
- then it seems we can do the same thing by letting the directory servers
- test them. This has the added benefit that all the (behaving) clients
- use the same data, so they don't end up partitioned by a node that
- (for example) performs selectively for his victims.
- Another idea would be to periodically keep track of what speeds you get
- through your helpers, and make decisions from this. The reason we haven't
- done this yet is because there are a lot of variables -- perhaps the
- web site is slow, perhaps some other node in the path is slow, perhaps
- your local network is slow briefly, perhaps you got unlucky, etc. I
- believe that over time (assuming the user has roughly the same browsing
- habits) all of these would average out and you'd get a usable answer,
- but I don't have a good sense of how long it would take to converge,
- so I don't know whether this would be worthwhile.
- > BTW. I feel confortable with all the terms helper/entry/contact nodes,
- > but I think you (the developers) should just pick one and stay with it
- > to avoid confusion.
- I think I'm going to try to co-opt the term 'Entry' node for this
- purpose. We're going to have to keep referring to helper nodes for the
- research community for a while though, so they realize that Tor does
- more than just let users ask for certain entry nodes.
- ============================================================
- Some stuff that worries me about entry guards. 2006 Jun, Nickm.
- 1. It is unlikely for two users to have the same set of entry guards.
- 2. Observing a user is sufficient to learn its entry guards.
- 3. So, as we move around, we leak our
|