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[tor-commits] [torspec/master] Add proposal 289: Authenticating sendme cells to mitigate bandwidth attacks
commit 39fde37cfa85149e978620edee9468c58973055e
Author: Nick Mathewson <nickm@xxxxxxxxxxxxxx>
Date: Tue Feb 13 08:39:00 2018 -0500
Add proposal 289: Authenticating sendme cells to mitigate bandwidth attacks
---
proposals/000-index.txt | 2 +
proposals/289-authenticated-sendmes.txt | 397 ++++++++++++++++++++++++++++++++
2 files changed, 399 insertions(+)
diff --git a/proposals/000-index.txt b/proposals/000-index.txt
index 86fab75..503d752 100644
--- a/proposals/000-index.txt
+++ b/proposals/000-index.txt
@@ -209,6 +209,7 @@ Proposals by number:
286 Controller APIs for hibernation access on mobile [OPEN]
287 Reduce circuit lifetime without overloading the network [OPEN]
288 Privacy-Preserving Statistics with Privcount in Tor (Shamir version) [DRAFT]
+289 Authenticating sendme cells to mitigate bandwidth attacks [OPEN]
Proposals by status:
@@ -267,6 +268,7 @@ Proposals by status:
285 Directory documents should be standardized as UTF-8
286 Controller APIs for hibernation access on mobile
287 Reduce circuit lifetime without overloading the network
+ 289 Authenticating sendme cells to mitigate bandwidth attacks
ACCEPTED:
172 GETINFO controller option for circuit information
173 GETINFO Option Expansion
diff --git a/proposals/289-authenticated-sendmes.txt b/proposals/289-authenticated-sendmes.txt
new file mode 100644
index 0000000..316bd75
--- /dev/null
+++ b/proposals/289-authenticated-sendmes.txt
@@ -0,0 +1,397 @@
+Filename: 289-authenticated-sendmes.txt
+Title: Authenticating sendme cells to mitigate bandwidth attacks
+Author: Rob Jansen, Roger Dingledine
+Created: 2016-12-01
+Status: Open
+
+1. Overview and Motivation
+
+ In Rob's "Sniper attack", a malicious Tor client builds a circuit,
+ fetches a large file from some website, and then refuses to read any
+ of the cells from the entry guard, yet sends "sendme" (flow control
+ acknowledgement) cells down the circuit to encourage the exit relay
+ to keep sending more cells. Eventually enough cells queue at the
+ entry guard that it runs out of memory and exits [0, 1].
+
+ We resolved the "runs out of memory and exits" part of the attack with
+ our Out-Of-Memory (OOM) manager introduced in Tor 0.2.4.18-rc. But
+ the earlier part remains unresolved: a malicious client can launch
+ an asymmetric bandwidth attack by creating circuits and streams and
+ sending a small number of sendme cells on each to cause the target
+ relay to receive a large number of data cells.
+
+ This attack could be used for general mischief in the network (e.g.,
+ consume Tor network bandwidth resources or prevent access to relays),
+ and it could probably also be leveraged to harm anonymity a la the
+ "congestion attack" designs [2, 3].
+
+ This proposal describes a way to verify that the client has seen all
+ of the cells that its sendme cell is acknowledging, based on the
+ authenticated sendmes design from [1].
+
+2. Sniper Attack Variations
+
+ There are some variations on the attack involving the number and
+ length of the circuits and the number of Tor clients used. We explain
+ them here to help understand which of them this proposal attempts to
+ defend against.
+
+ We compare the efficiency of these attacks in terms of the number of
+ cells transferred by the adversary and by the network, where receiving
+ and sending a cell counts as two transfers of that cell.
+
+2.1 Single Circuit, without Sendmes
+
+ The simplest attack is where the adversary starts a single Tor client,
+ creates one circuit and two streams to some website, and stops
+ reading from the TCP connection to the entry guard. The adversary
+ gets 1000 "attack" cells "for free" (until the stream and circuit
+ windows close). The attack data cells are both received and sent by the
+ exit and the middle, while being received and queued by the guard.
+
+ Adversary:
+ 6 transfers to create the circuit
+ 2 to begin the two exit connections
+ 2 to send the two GET requests
+ ---
+ 10 total
+
+ Network:
+ 18 transfers to create the circuit
+ 22 to begin the two exit connections (assumes two for the exit TCP connect)
+ 12 to send the two GET requests to the website
+ 5000 for requested data (until the stream and circuit windows close)
+ ---
+ 5052 total
+
+2.2 Single Circuit, with Sendmes
+
+ A slightly more complex version of the attack in 2.1 is where the
+ adversary continues to send sendme cells to the guard (toward the exit),
+ and then gets another 100 attack data cells sent across the network for every
+ three additional exitward sendme cells that it sends (two stream-level
+ sendmes and one circuit-level sendme). The adversary also gets another
+ three clientward sendme cells sent by the exit for every 100 exitward
+ sendme cells it sends.
+
+ If the adversary sends N sendmes, then we have:
+
+ Adversary:
+ 10 for circuit and stream setup
+ N for circuit and stream sendmes
+ ---
+ 10+N
+
+ Network:
+ 5052 for circuit and stream setup and initial depletion of circuit windows
+ N*100/3*5 for transferring additional data cells from the website
+ N*3/100*4 for transferring sendmes from exit to client
+ ---
+ 5052 + N*166.79
+
+ It is important to note that once the adversary stops reading from the
+ guard, it will no longer get feedback on the speed at which the data
+ cells are able to be transferred through the circuit from the exit
+ to the guard. It needs to approximate when it should send sendmes
+ to the exit; if too many sendmes are sent such that the circuit
+ window would open farther than 1000 cells (500 for streams), then the
+ circuit may be closed by the exit. In practice, the adversary could
+ take measurements during the circuit setup process and use them to
+ estimate a conservative sendme sending rate.
+
+2.3 Multiple Circuits
+
+ The adversary could parallelize the above attacks using multiple
+ circuits. Because the adversary needs to stop reading from the TCP
+ connection to the guard, they would need to do a pre-attack setup
+ phase during which they construct the attack circuits. Then, they
+ would stop reading from the guard and send all of the GET requests
+ across all of the circuits they created.
+
+ The number of cells from 2.1 and 2.2 would then be multiplied by the
+ number of circuits C that the adversary is able to build and sustain
+ during the attack.
+
+2.4 Multiple Guards
+
+ The adversary could use the "UseEntryGuards 0" torrc option, or build
+ custom circuits with stem to parallelize the attack across multiple
+ guard nodes. This would slightly increase the bandwidth usage of the
+ adversary, since it would be creating additional TCP connections to
+ guard nodes.
+
+2.5 Multiple Clients
+
+ The adversary could run multiple attack clients, each of which would
+ choose its own guard. This would slightly increase the bandwidth
+ usage of the adversary, since it would be creating additional TCP
+ connections to guard nodes and would also be downloading directory
+ info, creating testing circuits, etc.
+
+2.6 Short Two-hop Circuits
+
+ If the adversary uses two-hop circuits, there is less overhead
+ involved with the circuit setup process.
+
+ Adversary:
+ 4 transfers to create the circuit
+ 2 to begin the two exit connections
+ 2 to send the two GET requests
+ ---
+ 8
+
+ Network:
+ 8 transfers to create the circuit
+ 14 to begin the two exit connections (assumes two for the exit TCP connect)
+ 8 to send the two GET requests to the website
+ 5000 for requested data (until the stream and circuit windows close)
+ ---
+ 5030
+
+2.7 Long >3-hop Circuits
+
+ The adversary could use a circuit longer than three hops to cause more
+ bandwidth usage across the network. Let's use an 8 hop circuit as an
+ example.
+
+ Adversary:
+ 16 transfers to create the circuit
+ 2 to begin the two exit connections
+ 2 to send the two GET requests
+ ---
+ 20
+
+ Network:
+ 128 transfers to create the circuit
+ 62 to begin the two exit connections (assumes two for the exit TCP connect)
+ 32 to send the two GET requests to the website
+ 15000 for requested data (until the stream and circuit windows close)
+ ---
+ 15222
+
+ The adversary could also target a specific relay, and use it multiple
+ times as part of the long circuit, e.g., as hop 1, 4, and 7.
+
+ Target:
+ 54 transfers to create the circuit
+ 22 to begin the two exit connections (assumes two for the exit TCP connect)
+ 12 to send the two GET requests to the website
+ 5000 for requested data (until the stream and circuit windows close)
+ ---
+ 5088
+
+3. Design
+
+ This proposal aims to defend against the versions of the attack that
+ utilize sendme cells without reading. It does not attempt to handle
+ the case of multiple circuits per guard, or try to restrict the number
+ of guards used by a client, or prevent a sybil attack across multiple
+ client instances.
+
+ The proposal involves three components: first, the client needs to add
+ a token to the sendme payload, to prove that it knows the contents
+ of the cells that it has received. Second, the exit relay needs to
+ verify this token. Third, to resolve the case where the client already
+ knows the contents of the file so it only pretends to read the cells,
+ the exit relay needs to be able to add unexpected randomness to the
+ circuit.
+
+ (Note: this proposal talks about clients and exit relays, but since
+ sendmes go in both directions, both sides of the circuit should do
+ these changes.)
+
+3.1. Changing the sendme payload to prove receipt of cells
+
+ In short: clients put the latest received relay cell digest in the
+ payload of their circuit-level sendme cells.
+
+ Each relay cell header includes a 4-byte digest which represents
+ the rolling hash of all bytes received on that circuit. So knowledge
+ of that digest is an indication that you've seen the bytes that go
+ into it.
+
+ We pick circuit-level sendme cells, as opposed to stream-level sendme
+ cells, because we think modifying just circuit-level sendmes is
+ sufficient to accomplish the properties we need, and modifying just
+ stream-level sendmes is not sufficient: a client could send a bunch
+ of begin cells and fake their circuit-level sendmes, but never send
+ any stream-level sendmes, attracting 500*n queued cells to the entry
+ guard for the n streams that it opens.
+
+ Which digest should the client put in the sendme payload? Right now
+ circuit-level sendmes are sent whenever one window worth of relay cells
+ (100) has arrived. So the client should use the digest from the cell
+ that triggers the sendme.
+
+ How shall we version the sendme payload so we can change the format of
+ it later? Right now sendme payloads are empty. Here's a simple design:
+ we use five bytes in the payload, where the first byte indicates the
+ sendme payload version (0 in the original design, and 1 once we've
+ implemented this proposal), and the rest of the payload is formatted
+ based on the payload version number: in this case, it's simply the
+ four bytes of digest.
+
+ Is there a better way to version the payload, e.g. a way that is
+ already standard in other parts of the design, so we aren't adding
+ a new paint color to keep track of on the bike shed?
+
+3.2. Verifying the sendme payload
+
+ In the current Tor, the exit relay keeps no memory of the cells it
+ has sent down the circuit, so it won't be in a position to verify
+ the digest that it gets back.
+
+ But fortunately, the exit relay can count also, so it knows which cell
+ is going to trigger the sendme response. Each circuit can have at most
+ 10 sendmes worth of data outstanding. So the exit relay will keep
+ a per-circuit fifo queue of the digests from the appropriate cells,
+ and when a new sendme arrives, it pulls off the next digest in line,
+ and verifies that it matches.
+
+ If a sendme payload has a payload version of 1 yet its digest
+ doesn't match the expected digest, or if the sendme payload has
+ an unexpected payload version (see below about deployment phases),
+ the exit relay must tear down the circuit. (If we later find that
+ we need to introduce a newer payload version in an incompatible way,
+ we would do that by bumping the circuit protocol version.)
+
+3.3. Making sure there are enough unpredictable bytes in the circuit
+
+ So far, the design as described fails to a very simple attacker:
+ the client fetches a file whose contents it already knows, and it
+ uses that knowledge to calculate the correct digests and fake its
+ sendmes just like in the original attack.
+
+ The fix is that the exit relay needs to be able to add some randomness
+ into its cells. It can add this randomness, in a way that's completely
+ orthogonal to the rest of this design, simply by choosing one relay
+ cell every so often and not using the entire relay cell payload for
+ actual data (i.e. using a Length field of less than 498), and putting
+ some random bytes in the remainder of the payload.
+
+ How many random bytes should the exit relay use, and how often should
+ it use them? There is a tradeoff between security when under attack,
+ and efficiency when not under attack. We think 1 byte of randomness
+ every 1000 cells is a good starting plan, and we can always improve
+ it later without needing to change any of the rest of this design.
+
+ (Note that the spec currently says "The remainder of the payload
+ is padded with NUL bytes." We think "is" doesn't mean MUST, so we
+ should just be sure to update that part of the spec to reflect our
+ new plans here.)
+
+4. Deployment Plan
+
+ In phase one, both sides begin remembering their expected digests,
+ and they learn how to parse sendme payloads. When they receive a
+ sendme with payload version 1, they verify its digest and tear down
+ the circuit if it's wrong. But they continue to send and accept
+ payload version 0 sendmes.
+
+ In phase two, we flip a switch in the consensus, and everybody starts
+ sending payload version 1 sendmes. Payload version 0 sendmes are
+ still accepted.
+
+ In phase three, we flip a different switch in the consensus, and
+ everybody starts refusing payload version 0 sendmes.
+
+ (It has to be two separate switches, not one unified one, because
+ otherwise we'd have a race where relays learn about the update before
+ clients know to start the new behavior.)
+
+ We'll want to do a bunch of testing in chutney before flipping the
+ switches in the real network: I've long suspected we still have bugs
+ in our sendme timing, and this proposal might expose some of them.
+
+ Alas, this deployment plan leaves a pretty large window until relays
+ are protected from attack. It's not all bad news though, since we
+ could flip the switches earlier than intended if we encounter a
+ network-wide attack.
+
+5. Security Discussion
+
+ Does our design enable any new adversarial capabilities?
+
+ An adversarial middle relay could attempt to trick the exit into
+ killing an otherwise valid circuit.
+
+ An adversarial relay can already kill a circuit, but here it could make
+ it appear that the circuit was killed for a legitimate reason (invalid
+ or missing sendme), and make someone else (the exit) do the killing.
+
+ There are two ways it might do this: by trying to make a valid sendme
+ appear invalid; and by blocking the delivery of a valid sendme. Both of
+ these depend on the ability for the adversary to guess which exitward
+ cell is a sendme cell, which it could do by counting clientward cells.
+
+ * Making a valid sendme appear invalid
+
+ A malicious middle could stomp bits in the exitward sendme so
+ that the exit sendme validation fails. However, bit stomping would
+ be detected at the protocol layer orthogonal to this design, and
+ unrecognized exitward cells would currently cause the circuit to be
+ torn down. Therefore, this attack has the same end result as blocking
+ the delivery of a valid sendme.
+
+ (Note that, currently, clientward unrecognized cells are dropped but
+ the circuit is not torn down.)
+
+ * Blocking delivery of a valid sendme
+
+ A malicious middle could simply drop a exitward sendme, so that
+ the exit is unable to verify the digest in the sendme payload. The
+ following exitward sendme cell would then be misaligned with the
+ sendme that the exit is expecting to verify. The exit would kill the
+ circuit because the client failed to prove it has read all of the
+ clientward cells.
+
+ The benefits of such an attack over just directly killing the circuit
+ seem low, and we feel that the added benefits of the defense outweigh
+ the risks.
+
+6. Open problems
+
+ With the proposed defenses in place, an adversary will be unable to
+ successfully use the "continue sending sendmes" part of these attacks.
+
+ But this proposal won't resolve the "build up many circuits over time,
+ and then use them to attack all at once" issue, nor will it stop
+ sybil attacks like if an attacker makes many parallel connections to
+ a single target relay, or reaches out to many guards in parallel.
+
+ We spent a while trying to figure out if we can enforce some
+ upper bound on how many circuits a given connection is allowed
+ to have open at once, to limit every connection's potential for
+ launching a bandwidth attack. But there are plausible situations
+ where well-behaving clients accumulate many circuits over time:
+ Ricochet clients with many friends, popular onion services, or even
+ Tor Browser users with a bunch of tabs open.
+
+ Even though a per-conn circuit limit would produce many false
+ positives, it might still be useful to have it deployed and available
+ as a consensus parameter, as another tool for combatting a wide-scale
+ attack on the network: a parameter to limit the total number of
+ open circuits per conn (viewing each open circuit as a threat) would
+ complement the current work in #24902 to rate limit circuit creates
+ per client address.
+
+ But we think the threat of parallel attacks might be best handled by
+ teaching relays to react to actual attacks, like we've done in #24902:
+ we should teach Tor relays to recognize when somebody is *doing* this
+ attack on them, and to squeeze down or outright block the client IP
+ addresses that have tried it recently.
+
+ An alternative direction would be to await research ideas on how guards
+ might coordinate to defend against attacks while still preserving
+ user privacy.
+
+ In summary, we think authenticating the sendme cells is a useful
+ building block for these future solutions, and it can be (and should
+ be) done orthogonally to whatever sybil defenses we pick later.
+
+7. References
+
+ [0] https://blog.torproject.org/blog/new-tor-denial-service-attacks-and-defenses
+ [1] https://www.freehaven.net/anonbib/#sniper14
+ [2] https://www.freehaven.net/anonbib/#torta05
+ [3] https://www.freehaven.net/anonbib/#congestion-longpaths
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