Filename: 110-avoid-infinite-circuits.txt Title: Avoiding infinite length circuits Version: $Revision$ Last-Modified: $Date$ Author: Roger Dingledine Created: 13-Mar-2007 Status: Accepted Target: 0.2.1.x Implemented-In: 0.2.1.3-alpha History: Revised 28 July 2008 by nickm: set K. Revised 3 July 2008 by nickm: rename from relay_extend to relay_early. Revise to current migration plan. Allow K cells over circuit lifetime, not just at start. Overview: Right now, an attacker can add load to the Tor network by extending a circuit an arbitrary number of times. Every cell that goes down the circuit then adds N times that amount of load in overall bandwidth use. This vulnerability arises because servers don't know their position on the path, so they can't tell how many nodes there are before them on the path. We propose a new set of relay cells that are distinguishable by intermediate hops as permitting extend cells. This approach will allow us to put an upper bound on circuit length relative to the number of colluding adversary nodes; but there are some downsides too. Motivation: The above attack can be used to generally increase load all across the network, or it can be used to target specific servers: by building a circuit back and forth between two victim servers, even a low-bandwidth attacker can soak up all the bandwidth offered by the fastest Tor servers. The general attacks could be used as a demonstration that Tor isn't perfect (leading to yet more media articles about "breaking" Tor), and the targetted attacks will come into play once we have a reputation system -- it will be trivial to DoS a server so it can't pass its reputation checks, in turn impacting security. Design: We should split RELAY cells into two types: RELAY and RELAY_EARLY. Only K (say, 10) Relay_early cells can be sent across a circuit, and only relay_early cells are allowed to contain extend requests. We still support obscuring the length of the circuit (if more research shows us what to do), because Alice can choose how many of the K to mark as relay_early. Note that relay_early cells *can* contain any sort of data cell; so in effect it's actually the relay type cells that are restricted. By default, she would just send the first K data cells over the stream as relay_early cells, regardless of their actual type. (Note that a circuit that is out of relay_early cells MUST NOT be cannibalized later, since it can't extend. Note also that it's always okay to use regular RELAY cells when sending non-EXTEND commands targetted at the first hop of a circuit, since there is no intermediate hop to try to learn the relay command type.) Each intermediate server would pass on the same type of cell that it received (either relay or relay_early), and the cell's destination will be able to learn whether it's allowed to contain an Extend request. If an intermediate server receives more than K relay_early cells, or if it sees a relay cell that contains an extend request, then it tears down the circuit (protocol violation). Security implications: The upside is that this limits the bandwidth amplification factor to K: for an individual circuit to become arbitrary-length, the attacker would need an adversary-controlled node every K hops, and at that point the attack is no worse than if the attacker creates N/K separate K-hop circuits. On the other hand, we want to pick a large enough value of K that we don't mind the cap. If we ever want to take steps to hide the number of hops in the circuit or a node's position in the circuit, this design probably makes that more complex. Migration: In 0.2.0, servers speaking v2 or later of the link protocol accept RELAY_EARLY cells, and pass them on. If the next OR in the circuit is not speaking the v2 link protocol, the server relays the cell as a RELAY cell. In 0.2.1.3-alpha, clients begin using RELAY_EARLY cells on v2 connections. This functionality can be safely backported to 0.2.0.x. Clients should pick a random number betweeen (say) K and K-2 to send. In 0.2.1.3-alpha, servers close any circuit in which more than K relay_early cells are sent. Once all versions the do not send RELAY_EARLY cells are obsolete, servers can begin to reject any EXTEND requests not sent in a RELAY_EARLY cell. Parameters: Let K = 8, for no terribly good reason. Spec: [We can formalize this part once we think the design is a good one.] Acknowledgements: This design has been kicking around since Christian Grothoff and I came up with it at PET 2004. (Nathan Evans, Christian Grothoff's student, is working on implementing a fix based on this design in the summer 2007 timeframe.)