mirror of
https://gitlab.torproject.org/tpo/core/tor.git
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f3ea6be7e5
svn:r1154
543 lines
23 KiB
Plaintext
543 lines
23 KiB
Plaintext
$Id$
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Tor Spec
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Note: This is an attempt to specify Tor as it exists as implemented in
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early June, 2003. It is not recommended that others implement this
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design as it stands; future versions of Tor will implement improved
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protocols.
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TODO: (very soon)
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- Specify truncate/truncated payloads?
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- Specify RELAY_END payloads. [It's 1 byte of reason, then X bytes of
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data, right? -NM]
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[Right, where X=4 and it's an IP, currently. -RD]
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- Sendme w/stream0 is circuit sendme
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- Integrate -NM and -RD comments
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- EXTEND cells should have hostnames or nicknames, so that OPs never
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resolve OR hostnames. Else DNS servers can give different answers to
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different OPs, and compromise their anonymity.
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EVEN LATER:
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- Do TCP-style sequencing and ACKing of DATA cells so that we can afford
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to lose some data cells. [Actually, we'll probably never do this. -RD]
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0. Notation:
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PK -- a public key.
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SK -- a private key
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K -- a key for a symmetric cypher
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a|b -- concatenation of 'a' with 'b'.
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All numeric values are encoded in network (big-endian) order.
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Unless otherwise specified, all symmetric ciphers are AES in counter
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mode, with an IV of all 0 bytes. Asymmetric ciphers are either RSA
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with 1024-bit keys and exponents of 65537, or DH with the safe prime
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from rfc2409, section 6.2, whose hex representation is:
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"FFFFFFFFFFFFFFFFC90FDAA22168C234C4C6628B80DC1CD129024E08"
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"8A67CC74020BBEA63B139B22514A08798E3404DDEF9519B3CD3A431B"
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"302B0A6DF25F14374FE1356D6D51C245E485B576625E7EC6F44C42E9"
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"A637ED6B0BFF5CB6F406B7EDEE386BFB5A899FA5AE9F24117C4B1FE6"
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"49286651ECE65381FFFFFFFFFFFFFFFF"
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1. System overview
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Onion Routing is a distributed overlay network designed to anonymize
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low-latency TCP-based applications such as web browsing, secure shell,
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and instant messaging. Clients choose a path through the network and
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build a ``circuit'', in which each node (or ``onion router'' or ``OR'')
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in the path knows its predecessor and successor, but no other nodes in
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the circuit. Traffic flowing down the circuit is sent in fixed-size
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``cells'', which are unwrapped by a symmetric key at each node (like
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the layers of an onion) and relayed downstream.
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2. Connections
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There are two ways to connect to an onion router (OR). The first is
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as an onion proxy (OP), which allows the OP to authenticate the OR
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without authenticating itself. The second is as another OR, which
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allows mutual authentication.
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Tor uses TLS for link encryption, using the cipher suite
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"TLS_DHE_RSA_WITH_AES_128_CBC_SHA".
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[That's cool, except it's not what we use currently. We use
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3DES because most people don't have openssl 0.9.7 and thus
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don't have AES. -RD]
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An OR always sends a
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self-signed X.509 certificate whose commonName is the server's
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nickname, and whose public key is in the server directory.
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All parties receiving certificates must confirm that the public
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key is as it appears in the server directory, and close the
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connection if it is not.
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Once a TLS connection is established, the two sides send cells
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(specified below) to one another. Cells are sent serially. All
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cells are 512 bytes long. Cells may be sent embedded in TLS
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records of any size or divided across TLS records, but the framing
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of TLS records must not leak information about the type or
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contents of the cells.
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OR-to-OR connections are never deliberately closed. An OP should
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close a connection to an OR if there are no circuits running over
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the connection, and an amount of time (KeepalivePeriod, defaults to
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5 minutes) has passed.
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3. Cell Packet format
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The basic unit of communication for onion routers and onion
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proxies is a fixed-width "cell". Each cell contains the following
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fields:
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CircID [2 bytes]
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Command [1 byte]
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Payload (padded with 0 bytes) [509 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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The interpretation of 'Payload' depends on the type of the cell.
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PADDING: Unused.
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CREATE: Payload contains the handshake challenge.
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CREATED: Payload contains the handshake response.
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RELAY: Payload contains the relay header and relay body.
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DESTROY: Unused.
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The payload is padded with 0 bytes.
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PADDING cells are currently used to implement connection
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keepalive. ORs and OPs send one another a PADDING cell every few
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minutes.
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CREATE, CREATED, and DESTROY cells are used to manage circuits;
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see section 4 below.
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RELAY cells are used to send commands and data along a circuit; see
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section 5 below.
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4. Circuit management
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4.1. CREATE and CREATED cells
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Users set up circuits incrementally, one hop at a time. To create a
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new circuit, users send a CREATE cell to the first node, with the
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first half of the DH handshake; that node responds with a CREATED
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cell with the second half of the DH handshake plus the first 20 bytes
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of derivative key data (see section 4.2). To extend a circuit past
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the first hop, the user sends an EXTEND relay cell (see section 5)
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which instructs the last node in the circuit to send a CREATE cell
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to extend the circuit.
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The payload for a CREATE cell is an 'onion skin', consisting of:
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RSA-encrypted data [128 bytes]
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Symmetrically-encrypted data [16 bytes]
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The RSA-encrypted portion contains:
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Symmetric key [16 bytes]
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First part of DH data (g^x) [112 bytes]
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The symmetrically encrypted portion contains:
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Second part of DH data (g^x) [16 bytes]
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The two parts of DH data, once decrypted and concatenated, form
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g^x as calculated by the client.
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The relay payload for an EXTEND relay cell consists of:
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Address [4 bytes]
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Port [2 bytes]
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Onion skin [144 bytes]
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The port and address field denote the IPV4 address and port of the
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next onion router in the circuit.
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4.2. Setting circuit keys
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Once the handshake between the OP and an OR is completed, both
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servers can now calculate g^xy with ordinary DH. From the base key
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material g^xy, they compute derivative key material as follows.
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First, the server represents g^xy as a big-endian unsigned integer.
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Next, the server computes 60 bytes of key data as K = SHA1(g^xy |
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[00]) | SHA1(g^xy | [01]) | SHA1(g^xy | [02]) where "00" is a single
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octet whose value is zero, "01" is a single octet whose value is
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one, etc. The first 20 bytes of K form KH, the next 16 bytes of K
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form Kf, and the next 16 bytes of K form Kb.
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KH is used in the handshake response to demonstrate knowledge of the
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computed shared key. Kf is used to encrypt the stream of data going
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from the OP to the OR, and Kb is used to encrypt the stream of data
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going from the OR to the OP.
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4.3. Creating circuits
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When creating a circuit through the network, the circuit creator
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performs the following steps:
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1. Choose a chain of N onion routers (R_1...R_N) to constitute
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the path, such that no router appears in the path twice.
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[this is wrong, now we choose the last hop and then choose
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new hops lazily -RD]
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2. If not already connected to the first router in the chain,
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open a new connection to that router.
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3. Choose a circID not already in use on the connection with the
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first router in the chain. If we are an onion router and our
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nickname is lexicographically greater than the nickname of the
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other side, then let the high bit of the circID be 1, else 0.
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4. Send a CREATE cell along the connection, to be received by
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the first onion router.
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5. Wait until a CREATED cell is received; finish the handshake
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and extract the forward key Kf_1 and the backward key Kb_1.
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6. For each subsequent onion router R (R_2 through R_N), extend
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the circuit to R.
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To extend the circuit by a single onion router R_M, the circuit
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creator performs these steps:
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1. Create an onion skin, encrypting the RSA-encrypted part with
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R's public key.
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2. Encrypt and send the onion skin in a relay EXTEND cell along
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the circuit (see section 5).
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3. When a relay EXTENDED cell is received, calculate the shared
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keys. The circuit is now extended.
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When an onion router receives an EXTEND relay cell, it sends a
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CREATE cell to the next onion router, with the enclosed onion skin
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as its payload. The initiating onion router chooses some circID not
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yet used on the connection between the two onion routers. (But see
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section 4.3. above, concerning choosing circIDs. [What? This
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is 4.3. Maybe we mean to remind about lexicographic order of
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nicknames? -RD])
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As an extension (called router twins), if the desired next onion
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router R in the circuit is down, and some other onion router R'
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has the same key as R, then it's ok to extend to R' rather than R.
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When an onion router receives a CREATE cell, if it already has a
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circuit on the given connection with the given circID, it drops the
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cell. Otherwise, after receiving the CREATE cell, it completes
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the DH handshake, and replies with a CREATED cell, containing g^y
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as its [128 byte] payload. Upon receiving a CREATED cell, an onion
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router packs it payload into an EXTENDED relay cell (see section 5),
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and sends that cell up the circuit. Upon receiving the EXTENDED
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relay cell, the OP can retrieve g^y.
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(As an optimization, OR implementations may delay processing onions
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until a break in traffic allows time to do so without harming
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network latency too greatly.)
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4.4. Tearing down circuits
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Circuits are torn down when an unrecoverable error occurs along
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the circuit, or when all streams on a circuit are closed and the
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circuit's intended lifetime is over. Circuits may be torn down
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either completely or hop-by-hop.
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To tear down a circuit completely, an OR or OP sends a DESTROY
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cell to the adjacent nodes on that circuit, using the appropriate
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direction's circID.
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Upon receiving an outgoing DESTROY cell, an OR frees resources
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associated with the corresponding circuit. If it's not the end of
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the circuit, it sends a DESTROY cell for that circuit to the next OR
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in the circuit. If the node is the end of the circuit, then it tears
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down any associated edge connections (see section 5.1).
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After a DESTROY cell has been processed, an OR ignores all data or
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destroy cells for the corresponding circuit.
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[This next paragraph is never used, and should perhaps go away. -RD]
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To tear down part of a circuit, the OP sends a RELAY_TRUNCATE cell
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signaling a given OR (Stream ID zero). That OR sends a DESTROY
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cell to the next node in the circuit, and replies to the OP with a
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RELAY_TRUNCATED cell.
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When an unrecoverable error occurs along one connection in a
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circuit, the nodes on either side of the connection should, if they
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are able, act as follows: the node closer to the OP should send a
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RELAY_TRUNCATED cell towards the OP; the node farther from the OP
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should send a DESTROY cell down the circuit.
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[We'll have to reevaluate this section once we figure out cleaner
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circuit/connection killing conventions. Possibly the right answer
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is to not use most of the extensions. -RD]
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[Correct. We should specify that OPs must not send truncate cells. -RD]
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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 length
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field and the payload with AES/CTR, as follows:
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'Forward' relay cell (same direction as CREATE):
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Use Kf as key; encrypt.
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'Back' relay cell (opposite direction from CREATE):
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Use Kb as key; decrypt.
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[This part is now wrong. There's a 'recognized' field. If it crypts
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to 0, then check the digest. Speaking of which, there's a digest
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field. We should mention this. -RD]
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If the OR recognizes the stream ID on the cell (it is either the ID
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of an open stream or the signaling (zero) ID), the OR processes the
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contents of the relay cell. Otherwise, it passes the decrypted
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relay cell along the circuit if the circuit continues, or drops the
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cell if it's the end of the circuit. [Getting an unrecognized
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relay cell at the end of the circuit must be allowed for now;
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we can reexamine this once we've designed full tcp-style close
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handshakes. -RD [No longer true, an unrecognized relay cell at
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the end is met with a destroy cell. -RD]]
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Otherwise, if the data cell is coming from the OP edge of the
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circuit, the OP decrypts the length and payload fields with AES/CTR as
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follows:
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OP sends data cell to node R_M:
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For I=1...M, decrypt with Kf_I.
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Otherwise, if the data cell is arriving at the OP edge if the
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circuit, the OP encrypts the length and payload fields with AES/CTR as
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follows:
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OP receives data cell:
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For I=N...1,
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Encrypt with Kb_I. If the stream ID is a recognized
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stream for R_I, or if the stream ID is the signaling
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ID (zero), then stop and process the payload.
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For more information, see section 5 below.
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5. Application connections and stream management
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5.1. Streams
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Within a circuit, the OP and the exit node use the contents of
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RELAY packets to tunnel end-to-end commands and TCP connections
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("Streams") across circuits. End-to-end commands can be initiated
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by either edge; streams are initiated by the OP.
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The first 8 bytes of each relay cell are reserved as follows:
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Relay command [1 byte]
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Stream ID [7 bytes]
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[command 1 byte, recognized 2 bytes, streamid 2 bytes, digest 4 bytes,
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length 2 bytes == 11 bytes of header -RD]
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The relay commands are:
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1 -- RELAY_BEGIN
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2 -- RELAY_DATA
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3 -- RELAY_END
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4 -- RELAY_CONNECTED
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5 -- RELAY_SENDME
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6 -- RELAY_EXTEND
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7 -- RELAY_EXTENDED
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8 -- RELAY_TRUNCATE
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9 -- RELAY_TRUNCATED
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10 -- RELAY_DROP
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All RELAY cells pertaining to the same tunneled stream have the
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same stream ID. Stream ID's are chosen randomly by the OP. A
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stream ID is considered "recognized" on a circuit C by an OP or an
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OR if it already has an existing stream established on that
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circuit, or if the stream ID is equal to the signaling stream ID,
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which is all zero: [00 00 00 00 00 00 00]
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[This next paragraph is wrong: to begin a new stream, it simply
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uses the new streamid. No need to send it separately. -RD]
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To create a new anonymized TCP connection, the OP sends a
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RELAY_BEGIN data cell with a payload encoding the address and port
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of the destination host. The stream ID is zero. The payload format is:
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NEWSTREAMID | ADDRESS | ':' | PORT | '\000'
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where NEWSTREAMID is the newly generated Stream ID to use for
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this stream, ADDRESS may be a DNS hostname, or an IPv4 address in
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dotted-quad format; and where PORT is encoded in decimal.
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Upon receiving this packet, the exit node resolves the address as
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necessary, and opens a new TCP connection to the target port. If
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the address cannot be resolved, or a connection can't be
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established, the exit node replies with a RELAY_END cell.
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Otherwise, the exit node replies with a RELAY_CONNECTED cell.
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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 stream data in RELAY_DATA cells, and upon receiving such
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cells, echo their contents to the corresponding TCP stream.
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Relay RELAY_DROP 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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5.2. Closing streams
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[Note -- TCP streams can only be half-closed for reading. Our
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Bickford's conversation was incorrect. -NM]
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Because TCP connections can be half-open, we follow an equivalent
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to TCP's FIN/FIN-ACK/ACK protocol to close streams.
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An exit connection can have a TCP stream in one of three states:
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'OPEN', 'DONE_PACKAGING', and 'DONE_DELIVERING'. For the purposes
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of modeling transitions, we treat 'CLOSED' as a fourth state,
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although connections in this state are not, in fact, tracked by the
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onion router.
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A stream begins in the 'OPEN' state. Upon receiving a 'FIN' from
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the corresponding TCP connection, the edge node sends a 'RELAY_END'
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cell along the circuit and changes its state to 'DONE_PACKAGING'.
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Upon receiving a 'RELAY_END' cell, an edge node sends a 'FIN' to
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the corresponding TCP connection (e.g., by calling
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shutdown(SHUT_WR)) and changing its state to 'DONE_DELIVERING'.
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When a stream in already in 'DONE_DELIVERING' receives a 'FIN', it
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also sends a 'RELAY_END' along the circuit, and changes its state
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to 'CLOSED'. When a stream already in 'DONE_PACKAGING' receives a
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'RELAY_END' cell, it sends a 'FIN' and changes its state to
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'CLOSED'.
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[Note: Please rename 'RELAY_END2'. :) -NM ]
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If an edge node encounters an error on any stram, it sends a
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'RELAY_END2' cell along the circuit (if possible) and closes the
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TCP connection immediately. If an edge node receives a
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'RELAY_END2' cell for any stream, it closes the TCP connection
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completely, and sends nothing along the circuit.
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6. Flow control
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6.1. Link throttling
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Each node should do appropriate bandwidth throttling to keep its
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user happy.
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Communicants rely on TCP's default flow control to push back when they
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stop reading.
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6.2. Link padding
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Currently nodes are not required to do any sort of link padding or
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dummy traffic. Because strong attacks exist even with link padding,
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and because link padding greatly increases the bandwidth requirements
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for running a node, we plan to leave out link padding until this
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tradeoff is better understood.
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6.3. Circuit-level flow control
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To control a circuit's bandwidth usage, each OR keeps track of
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two 'windows', consisting of how many RELAY_DATA cells it is
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allowed to package for transmission, and how many RELAY_DATA cells
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it is willing to deliver to streams outside the network.
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Each 'window' value is initially set to 1000 data cells
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in each direction (cells that are not data cells do not affect
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the window). When an OR is willing to deliver more cells, it sends a
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RELAY_SENDME cell towards the OP, with Stream ID zero. When an OR
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receives a RELAY_SENDME cell with stream ID zero, it increments its
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packaging window.
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Each of these cells increments the corresponding window by 100.
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The OP behaves identically, except that it must track a packaging
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window and a delivery window for every OR in the circuit.
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An OR or OP sends cells to increment its delivery window when the
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corresponding window value falls under some threshold (900).
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If a packaging window reaches 0, the OR or OP stops reading from
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TCP connections for all streams on the corresponding circuit, and
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sends no more RELAY_DATA cells until receiving a RELAY_SENDME cell.
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[this stuff is badly worded; copy in the tor-design section -RD]
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6.4. Stream-level flow control
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Edge nodes use RELAY_SENDME cells to implement end-to-end flow
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control for individual connections across circuits. Similarly to
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circuit-level flow control, edge nodes begin with a window of cells
|
|
(500) per stream, and increment the window by a fixed value (50)
|
|
upon receiving a RELAY_SENDME cell. Edge nodes initiate RELAY_SENDME
|
|
cells when both a) the window is <= 450, and b) there are less than
|
|
ten cell payloads remaining to be flushed at that edge.
|
|
|
|
|
|
7. Directories and routers
|
|
|
|
7.1. Router descriptor format.
|
|
|
|
(Unless otherwise noted, tokens on the same line are space-separated.)
|
|
|
|
Router ::= Router-Line Date-Line Onion-Key Link-Key Signing-Key Exit-Policy Router-Signature NL
|
|
Router-Line ::= "router" nickname address ORPort SocksPort DirPort bandwidth NL
|
|
Date-Line ::= "published" YYYY-MM-DD HH:MM:SS NL
|
|
Onion-key ::= "onion-key" NL a public key in PEM format NL
|
|
Link-key ::= "link-key" NL a public key in PEM format NL
|
|
Signing-Key ::= "signing-key" NL a public key in PEM format NL
|
|
Exit-Policy ::= Exit-Line*
|
|
Exit-Line ::= ("accept"|"reject") string NL
|
|
Router-Signature ::= "router-signature" NL Signature
|
|
Signature ::= "-----BEGIN SIGNATURE-----" NL
|
|
Base-64-encoded-signature NL "-----END SIGNATURE-----" NL
|
|
|
|
ORport ::= port where the router listens for routers/proxies (speaking cells)
|
|
SocksPort ::= where the router listens for applications (speaking socks)
|
|
DirPort ::= where the router listens for directory download requests
|
|
bandwidth ::= maximum bandwidth, in bytes/s
|
|
|
|
nickname ::= between 1 and 32 alphanumeric characters. case-insensitive.
|
|
|
|
Example:
|
|
router moria1 moria.mit.edu 9001 9021 9031 100000
|
|
published 2003-09-24 19:36:05
|
|
-----BEGIN RSA PUBLIC KEY-----
|
|
MIGJAoGBAMBBuk1sYxEg5jLAJy86U3GGJ7EGMSV7yoA6mmcsEVU3pwTUrpbpCmwS
|
|
7BvovoY3z4zk63NZVBErgKQUDkn3pp8n83xZgEf4GI27gdWIIwaBjEimuJlEY+7K
|
|
nZ7kVMRoiXCbjL6VAtNa4Zy1Af/GOm0iCIDpholeujQ95xew7rQnAgMA//8=
|
|
-----END RSA PUBLIC KEY-----
|
|
signing-key
|
|
-----BEGIN RSA PUBLIC KEY-----
|
|
7BvovoY3z4zk63NZVBErgKQUDkn3pp8n83xZgEf4GI27gdWIIwaBjEimuJlEY+7K
|
|
MIGJAoGBAMBBuk1sYxEg5jLAJy86U3GGJ7EGMSV7yoA6mmcsEVU3pwTUrpbpCmwS
|
|
f/GOm0iCIDpholeujQ95xew7rnZ7kVMRoiXCbjL6VAtNa4Zy1AQnAgMA//8=
|
|
-----END RSA PUBLIC KEY-----
|
|
reject 18.0.0.0/24
|
|
|
|
Note: The extra newline at the end of the router block is intentional.
|
|
|
|
7.2. Directory format
|
|
|
|
Directory ::= Directory-Header Directory-Router Router* Signature
|
|
Directory-Header ::= "signed-directory" NL Software-Line NL
|
|
Software-Line: "recommended-software" comma-separated-version-list
|
|
Directory-Router ::= Router
|
|
Directory-Signature ::= "directory-signature" NL Signature
|
|
Signature ::= "-----BEGIN SIGNATURE-----" NL
|
|
Base-64-encoded-signature NL "-----END SIGNATURE-----" NL
|
|
|
|
Note: The router block for the directory server must appear first.
|
|
The signature is computed by computing the SHA-1 hash of the
|
|
directory, from the characters "signed-directory", through the newline
|
|
after "directory-signature". This digest is then padded with PKCS.1,
|
|
and signed with the directory server's signing key.
|
|
|
|
7.3. Behavior of a directory server
|
|
|
|
lists nodes that are connected currently
|
|
speaks http on a socket, spits out directory on request
|
|
|
|
-----------
|
|
(for emacs)
|
|
Local Variables:
|
|
mode:text
|
|
indent-tabs-mode:nil
|
|
fill-column:77
|
|
End:
|