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423 lines
19 KiB
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423 lines
19 KiB
Plaintext
Filename: 100-tor-spec-udp.txt
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Title: Tor Unreliable Datagram Extension Proposal
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Author: Marc Liberatore
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Created: 23 Feb 2006
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Status: Dead
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Overview:
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This is a modified version of the Tor specification written by Marc
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Liberatore to add UDP support to Tor. For each TLS link, it adds a
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corresponding DTLS link: control messages and TCP data flow over TLS, and
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UDP data flows over DTLS.
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This proposal is not likely to be accepted as-is; see comments at the end
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of the document.
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Contents
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0. Introduction
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Tor is a distributed overlay network designed to anonymize low-latency
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TCP-based applications. The current tor specification supports only
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TCP-based traffic. This limitation prevents the use of tor to anonymize
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other important applications, notably voice over IP software. This document
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is a proposal to extend the tor specification to support UDP traffic.
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The basic design philosophy of this extension is to add support for
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tunneling unreliable datagrams through tor with as few modifications to the
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protocol as possible. As currently specified, tor cannot directly support
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such tunneling, as connections between nodes are built using transport layer
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security (TLS) atop TCP. The latency incurred by TCP is likely unacceptable
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to the operation of most UDP-based application level protocols.
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Thus, we propose the addition of links between nodes using datagram
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transport layer security (DTLS). These links allow packets to traverse a
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route through tor quickly, but their unreliable nature requires minor
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changes to the tor protocol. This proposal outlines the necessary
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additions and changes to the tor specification to support UDP traffic.
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We note that a separate set of DTLS links between nodes creates a second
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overlay, distinct from the that composed of TLS links. This separation and
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resulting decrease in each anonymity set's size will make certain attacks
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easier. However, it is our belief that VoIP support in tor will
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dramatically increase its appeal, and correspondingly, the size of its user
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base, number of deployed nodes, and total traffic relayed. These increases
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should help offset the loss of anonymity that two distinct networks imply.
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1. Overview of Tor-UDP and its complications
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As described above, this proposal extends the Tor specification to support
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UDP with as few changes as possible. Tor's overlay network is managed
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through TLS based connections; we will re-use this control plane to set up
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and tear down circuits that relay UDP traffic. These circuits be built atop
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DTLS, in a fashion analogous to how Tor currently sends TCP traffic over
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TLS.
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The unreliability of DTLS circuits creates problems for Tor at two levels:
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1. Tor's encryption of the relay layer does not allow independent
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decryption of individual records. If record N is not received, then
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record N+1 will not decrypt correctly, as the counter for AES/CTR is
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maintained implicitly.
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2. Tor's end-to-end integrity checking works under the assumption that
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all RELAY cells are delivered. This assumption is invalid when cells
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are sent over DTLS.
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The fix for the first problem is straightforward: add an explicit sequence
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number to each cell. To fix the second problem, we introduce a
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system of nonces and hashes to RELAY packets.
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In the following sections, we mirror the layout of the Tor Protocol
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Specification, presenting the necessary modifications to the Tor protocol as
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a series of deltas.
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2. Connections
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Tor-UDP uses DTLS for encryption of some links. All DTLS links must have
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corresponding TLS links, as all control messages are sent over TLS. All
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implementations MUST support the DTLS ciphersuite "[TODO]".
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DTLS connections are formed using the same protocol as TLS connections.
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This occurs upon request, following a CREATE_UDP or CREATE_FAST_UDP cell,
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as detailed in section 4.6.
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Once a paired TLS/DTLS connection is established, the two sides send cells
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to one another. All but two types of cells are sent over TLS links. RELAY
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cells containing the commands RELAY_UDP_DATA and RELAY_UDP_DROP, specified
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below, are sent over DTLS links. [Should all cells still be 512 bytes long?
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Perhaps upon completion of a preliminary implementation, we should do a
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performance evaluation for some class of UDP traffic, such as VoIP. - ML]
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Cells may be sent embedded in TLS or DTLS records of any size or divided
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across such records. The framing of these records MUST NOT leak any more
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information than the above differentiation on the basis of cell type. [I am
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uncomfortable with this leakage, but don't see any simple, elegant way
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around it. -ML]
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As with TLS connections, DTLS connections are not permanent.
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3. Cell format
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Each cell contains the following fields:
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CircID [2 bytes]
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Command [1 byte]
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Sequence Number [2 bytes]
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Payload (padded with 0 bytes) [507 bytes]
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[Total size: 512 bytes]
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The 'Command' field holds one of the following values:
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0 -- PADDING (Padding) (See Sec 6.2)
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1 -- CREATE (Create a circuit) (See Sec 4)
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2 -- CREATED (Acknowledge create) (See Sec 4)
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3 -- RELAY (End-to-end data) (See Sec 5)
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4 -- DESTROY (Stop using a circuit) (See Sec 4)
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5 -- CREATE_FAST (Create a circuit, no PK) (See Sec 4)
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6 -- CREATED_FAST (Circuit created, no PK) (See Sec 4)
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7 -- CREATE_UDP (Create a UDP circuit) (See Sec 4)
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8 -- CREATED_UDP (Acknowledge UDP create) (See Sec 4)
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9 -- CREATE_FAST_UDP (Create a UDP circuit, no PK) (See Sec 4)
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10 -- CREATED_FAST_UDP(UDP circuit created, no PK) (See Sec 4)
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The sequence number allows for AES/CTR decryption of RELAY cells
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independently of one another; this functionality is required to support
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cells sent over DTLS. The sequence number is described in more detail in
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section 4.5.
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[Should the sequence number only appear in RELAY packets? The overhead is
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small, and I'm hesitant to force more code paths on the implementor. -ML]
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[There's already a separate relay header that has other material in it,
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so it wouldn't be the end of the world to move it there if it's
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appropriate. -RD]
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[Having separate commands for UDP circuits seems necessary, unless we can
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assume a flag day event for a large number of tor nodes. -ML]
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4. Circuit management
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4.2. Setting circuit keys
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Keys are set up for UDP circuits in the same fashion as for TCP circuits.
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Each UDP circuit shares keys with its corresponding TCP circuit.
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[If the keys are used for both TCP and UDP connections, how does it
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work to mix sequence-number-less cells with sequenced-numbered cells --
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how do you know you have the encryption order right? -RD]
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4.3. Creating circuits
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UDP circuits are created as TCP circuits, using the *_UDP cells as
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appropriate.
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4.4. Tearing down circuits
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UDP circuits are torn down as TCP circuits, using the *_UDP cells as
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appropriate.
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4.5. Routing relay cells
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When an OR receives a RELAY cell, it checks the cell's circID and
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determines whether it has a corresponding circuit along that
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connection. If not, the OR drops the RELAY cell.
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Otherwise, if the OR is not at the OP edge of the circuit (that is,
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either an 'exit node' or a non-edge node), it de/encrypts the payload
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with AES/CTR, as follows:
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'Forward' relay cell (same direction as CREATE):
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Use Kf as key; decrypt, using sequence number to synchronize
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ciphertext and keystream.
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'Back' relay cell (opposite direction from CREATE):
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Use Kb as key; encrypt, using sequence number to synchronize
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ciphertext and keystream.
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Note that in counter mode, decrypt and encrypt are the same operation.
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[Since the sequence number is only 2 bytes, what do you do when it
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rolls over? -RD]
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Each stream encrypted by a Kf or Kb has a corresponding unique state,
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captured by a sequence number; the originator of each such stream chooses
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the initial sequence number randomly, and increments it only with RELAY
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cells. [This counts cells; unlike, say, TCP, tor uses fixed-size cells, so
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there's no need for counting bytes directly. Right? - ML]
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[I believe this is true. You'll find out for sure when you try to
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build it. ;) -RD]
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The OR then decides whether it recognizes the relay cell, by
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inspecting the payload as described in section 5.1 below. If the OR
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recognizes the cell, it processes the contents of the relay cell.
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Otherwise, it passes the decrypted relay cell along the circuit if
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the circuit continues. If the OR at the end of the circuit
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encounters an unrecognized relay cell, an error has occurred: the OR
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sends a DESTROY cell to tear down the circuit.
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When a relay cell arrives at an OP, the OP decrypts the payload
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with AES/CTR as follows:
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OP receives data cell:
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For I=N...1,
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Decrypt with Kb_I, using the sequence number as above. If the
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payload is recognized (see section 5.1), then stop and process
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the payload.
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For more information, see section 5 below.
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4.6. CREATE_UDP and CREATED_UDP cells
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Users set up UDP circuits incrementally. The procedure is similar to that
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for TCP circuits, as described in section 4.1. In addition to the TLS
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connection to the first node, the OP also attempts to open a DTLS
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connection. If this succeeds, the OP sends a CREATE_UDP cell, with a
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payload in the same format as a CREATE cell. To extend a UDP circuit past
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the first hop, the OP sends an EXTEND_UDP relay cell (see section 5) which
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instructs the last node in the circuit to send a CREATE_UDP cell to extend
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the circuit.
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The relay payload for an EXTEND_UDP relay cell consists of:
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Address [4 bytes]
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TCP port [2 bytes]
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UDP port [2 bytes]
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Onion skin [186 bytes]
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Identity fingerprint [20 bytes]
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The address field and ports denote the IPV4 address and ports of the next OR
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in the circuit.
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The payload for a CREATED_UDP cell or the relay payload for an
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RELAY_EXTENDED_UDP cell is identical to that of the corresponding CREATED or
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RELAY_EXTENDED cell. Both circuits are established using the same key.
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Note that the existence of a UDP circuit implies the
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existence of a corresponding TCP circuit, sharing keys, sequence numbers,
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and any other relevant state.
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4.6.1 CREATE_FAST_UDP/CREATED_FAST_UDP cells
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As above, the OP must successfully connect using DTLS before attempting to
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send a CREATE_FAST_UDP cell. Otherwise, the procedure is the same as in
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section 4.1.1.
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5. Application connections and stream management
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5.1. Relay cells
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Within a circuit, the OP and the exit node use the contents of RELAY cells
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to tunnel end-to-end commands, TCP connections ("Streams"), and UDP packets
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across circuits. End-to-end commands and UDP packets can be initiated by
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either edge; streams are initiated by the OP.
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The payload of each unencrypted RELAY cell consists of:
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Relay command [1 byte]
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'Recognized' [2 bytes]
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StreamID [2 bytes]
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Digest [4 bytes]
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Length [2 bytes]
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Data [498 bytes]
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The relay commands are:
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1 -- RELAY_BEGIN [forward]
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2 -- RELAY_DATA [forward or backward]
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3 -- RELAY_END [forward or backward]
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4 -- RELAY_CONNECTED [backward]
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5 -- RELAY_SENDME [forward or backward]
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6 -- RELAY_EXTEND [forward]
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7 -- RELAY_EXTENDED [backward]
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8 -- RELAY_TRUNCATE [forward]
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9 -- RELAY_TRUNCATED [backward]
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10 -- RELAY_DROP [forward or backward]
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11 -- RELAY_RESOLVE [forward]
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12 -- RELAY_RESOLVED [backward]
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13 -- RELAY_BEGIN_UDP [forward]
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14 -- RELAY_DATA_UDP [forward or backward]
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15 -- RELAY_EXTEND_UDP [forward]
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16 -- RELAY_EXTENDED_UDP [backward]
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17 -- RELAY_DROP_UDP [forward or backward]
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Commands labelled as "forward" must only be sent by the originator
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of the circuit. Commands labelled as "backward" must only be sent by
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other nodes in the circuit back to the originator. Commands marked
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as either can be sent either by the originator or other nodes.
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The 'recognized' field in any unencrypted relay payload is always set to
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zero.
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The 'digest' field can have two meanings. For all cells sent over TLS
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connections (that is, all commands and all non-UDP RELAY data), it is
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computed as the first four bytes of the running SHA-1 digest of all the
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bytes that have been sent reliably and have been destined for this hop of
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the circuit or originated from this hop of the circuit, seeded from Df or Db
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respectively (obtained in section 4.2 above), and including this RELAY
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cell's entire payload (taken with the digest field set to zero). Cells sent
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over DTLS connections do not affect this running digest. Each cell sent
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over DTLS (that is, RELAY_DATA_UDP and RELAY_DROP_UDP) has the digest field
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set to the SHA-1 digest of the current RELAY cells' entire payload, with the
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digest field set to zero. Coupled with a randomly-chosen streamID, this
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provides per-cell integrity checking on UDP cells.
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[If you drop malformed UDP relay cells but don't close the circuit,
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then this 8 bytes of digest is not as strong as what we get in the
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TCP-circuit side. Is this a problem? -RD]
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When the 'recognized' field of a RELAY cell is zero, and the digest
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is correct, the cell is considered "recognized" for the purposes of
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decryption (see section 4.5 above).
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(The digest does not include any bytes from relay cells that do
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not start or end at this hop of the circuit. That is, it does not
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include forwarded data. Therefore if 'recognized' is zero but the
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digest does not match, the running digest at that node should
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not be updated, and the cell should be forwarded on.)
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All RELAY cells pertaining to the same tunneled TCP stream have the
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same streamID. Such streamIDs are chosen arbitrarily by the OP. RELAY
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cells that affect the entire circuit rather than a particular
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stream use a StreamID of zero.
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All RELAY cells pertaining to the same UDP tunnel have the same streamID.
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This streamID is chosen randomly by the OP, but cannot be zero.
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The 'Length' field of a relay cell contains the number of bytes in
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the relay payload which contain real payload data. The remainder of
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the payload is padded with NUL bytes.
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If the RELAY cell is recognized but the relay command is not
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understood, the cell must be dropped and ignored. Its contents
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still count with respect to the digests, though. [Before
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0.1.1.10, Tor closed circuits when it received an unknown relay
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command. Perhaps this will be more forward-compatible. -RD]
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5.2.1. Opening UDP tunnels and transferring data
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To open a new anonymized UDP connection, the OP chooses an open
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circuit to an exit that may be able to connect to the destination
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address, selects a random streamID not yet used on that circuit,
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and constructs a RELAY_BEGIN_UDP cell with a payload encoding the address
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and port of the destination host. The payload format is:
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ADDRESS | ':' | PORT | [00]
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where ADDRESS can be a DNS hostname, or an IPv4 address in
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dotted-quad format, or an IPv6 address surrounded by square brackets;
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and where PORT is encoded in decimal.
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[What is the [00] for? -NM]
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[It's so the payload is easy to parse out with string funcs -RD]
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Upon receiving this cell, the exit node resolves the address as necessary.
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If the address cannot be resolved, the exit node replies with a RELAY_END
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cell. (See 5.4 below.) Otherwise, the exit node replies with a
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RELAY_CONNECTED cell, whose payload is in one of the following formats:
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The IPv4 address to which the connection was made [4 octets]
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A number of seconds (TTL) for which the address may be cached [4 octets]
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or
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Four zero-valued octets [4 octets]
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An address type (6) [1 octet]
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The IPv6 address to which the connection was made [16 octets]
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A number of seconds (TTL) for which the address may be cached [4 octets]
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[XXXX Versions of Tor before 0.1.1.6 ignore and do not generate the TTL
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field. No version of Tor currently generates the IPv6 format.]
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The OP waits for a RELAY_CONNECTED cell before sending any data.
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Once a connection has been established, the OP and exit node
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package UDP data in RELAY_DATA_UDP cells, and upon receiving such
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cells, echo their contents to the corresponding socket.
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RELAY_DATA_UDP cells sent to unrecognized streams are dropped.
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Relay RELAY_DROP_UDP cells are long-range dummies; upon receiving such
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a cell, the OR or OP must drop it.
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5.3. Closing streams
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UDP tunnels are closed in a fashion corresponding to TCP connections.
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6. Flow Control
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UDP streams are not subject to flow control.
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7.2. Router descriptor format.
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The items' formats are as follows:
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"router" nickname address ORPort SocksPort DirPort UDPPort
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Indicates the beginning of a router descriptor. "address" must be
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an IPv4 address in dotted-quad format. The last three numbers
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indicate the TCP ports at which this OR exposes
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functionality. ORPort is a port at which this OR accepts TLS
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connections for the main OR protocol; SocksPort is deprecated and
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should always be 0; DirPort is the port at which this OR accepts
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directory-related HTTP connections; and UDPPort is a port at which
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this OR accepts DTLS connections for UDP data. If any port is not
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supported, the value 0 is given instead of a port number.
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Other sections:
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What changes need to happen to each node's exit policy to support this? -RD
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Switching to UDP means managing the queues of incoming packets better,
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so we don't miss packets. How does this interact with doing large public
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key operations (handshakes) in the same thread? -RD
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========================================================================
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COMMENTS
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========================================================================
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[16 May 2006]
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I don't favor this approach; it makes packet traffic partitioned from
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stream traffic end-to-end. The architecture I'd like to see is:
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A *All* Tor-to-Tor traffic is UDP/DTLS, unless we need to fall back on
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TCP/TLS for firewall penetration or something. (This also gives us an
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upgrade path for routing through legacy servers.)
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B Stream traffic is handled with end-to-end per-stream acks/naks and
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retries. On failure, the data is retransmitted in a new RELAY_DATA cell;
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a cell isn't retransmitted.
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We'll need to do A anyway, to fix our behavior on packet-loss. Once we've
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done so, B is more or less inevitable, and we can support end-to-end UDP
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traffic "for free".
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(Also, there are some details that this draft spec doesn't address. For
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example, what happens when a UDP packet doesn't fit in a single cell?)
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-NM
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