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f8c6339979
svn:r252
544 lines
23 KiB
Plaintext
544 lines
23 KiB
Plaintext
$Id$
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TOR (The Onion Router) Spec
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Note: This is an attempt to specify TOR as it exists as implemented in
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early March, 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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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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a[i:j] -- Bytes 'i' through 'j'-1 (inclusive) of the string a.
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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 DES in OFB
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mode, with an IV of all 0 bytes. All asymmetric ciphers are RSA
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with 1024-bit keys, and exponents of 65537.
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[We will move to AES once we can assume everybody will have it. -RD]
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1. System overview
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[Something to start with here. Do feel free to change/expand. -RD]
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Tor is an implementation of version 2 of Onion Routing.
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Onion Routing is a connection-oriented anonymizing communication
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service. Users build a layered block of asymmetric encryptions
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(an "onion") which describes a source-routed path through a set of
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nodes. Those nodes build a "virtual circuit" through the network, in which
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each node knows its predecessor and successor, but no others. Traffic
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flowing down the circuit is unwrapped by a symmetric key at each node,
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which reveals the downstream node.
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2. Connections
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2.1. Establishing OR-to-OR connections
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When one onion router opens a connection to another, the initiating
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OR (called the 'client') and the listening OR (called the 'server')
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perform the following handshake.
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Before the handshake begins, the client and server know one
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another's (1024-bit) public keys, IPV4 addresses, and ports.
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1. Client connects to server:
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The client generates a pair of 8-byte symmetric keys (one
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[K_f] for the 'forward' stream from client to server, and one
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[K_b] for the 'backward' stream from server to client.
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The client then generates a 'Client authentication' message [M]
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containing:
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The client's published IPV4 address [4 bytes]
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The client's published port [2 bytes]
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The server's published IPV4 address [4 bytes]
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The server's published port [2 bytes]
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The forward key (K_f) [16 bytes]
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The backward key (K_f) [16 bytes]
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The maximum bandwidth (bytes/s) [4 bytes]
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[Total: 48 bytes]
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The client then RSA-encrypts the message with the server's
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public key, and PKCS1 padding to given an encrypted message
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[Commentary: 1024 bytes is probably too short, and this protocol can't
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support IPv6. -NM]
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[1024 is too short for a high-latency remailer; but perhaps it's
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fine for us, given our need for speed and also given our greater
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vulnerability to other attacks? Onions are infrequent enough now
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that maybe we could handle it; but I worry it will impact
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scalability, and handling more users is important.-RD]
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The client then opens a TCP connection to the server, sends
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the 128-byte RSA-encrypted data to the server, and waits for a
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reply.
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2. Server authenticates to client:
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Upon receiving a TCP connection, the server waits to receive
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128 bytes from the client. It decrypts the message with its
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private key, and checks the PKCS1 padding. If the padding is
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incorrect, or if the message's length is other than 32 bytes,
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the server closes the TCP connection and stops handshaking.
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The server then checks the list of known ORs for one with the
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address and port given in the client's authentication. If no
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such OR is known, or if the server is already connected to
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that OR, the server closes the current TCP connection and
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stops handshaking.
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For later use, the server sets its keys for this connection,
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setting K_f to the client's K_b, and K_b to the client's K_f.
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The server then creates a server authentication message[M2] as
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follows:
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Modified client authentication [48 bytes]
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A random nonce [N] [8 bytes]
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[Total: 56 bytes]
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The client authentication is generated from M by replacing
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the client's preferred bandwidth [B_c] with the server's
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preferred bandwidth [B_s], if B_s < B_c.
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The server encrypts M2 with the client's public key (found
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from the list of known routers), using PKCS1 padding.
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The server sends the 128-byte encrypted message to the client,
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and waits for a reply.
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3. Client authenticates to server.
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Once the client has received 128 bytes, it decrypts them with
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its public key, and checks the PKCS1 padding. If the padding
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is invalid, or the decrypted message's length is other than 40
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bytes, the client closes the TCP connection.
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The client checks that the addresses and keys in the reply
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message are the same as the ones it originally sent. If not,
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it closes the TCP connection.
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The client updates the connection's bandwidth to that set by
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the server, and generates the following authentication message [M3]:
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The client's published IPV4 address [4 bytes]
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The client's published port [2 bytes]
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The server's published IPV4 address [4 bytes]
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The server's published port [2 bytes]
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The server-generated nonce [N] [8 bytes]
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[Total: 20 bytes]
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Once again, the client encrypts this message using the
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server's public key and PKCS1 padding, and sends the resulting
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128-byte message to the server.
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4. Server checks client authentication
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The server once again waits to receive 128 bytes from the
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client, decrypts the message with its private key, and checks
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the PKCS1 padding. If the padding is incorrect, or if the
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message's length is other than 20 bytes, the server closes the
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TCP connection and stops handshaking.
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If the addresses in the decrypted message M3 match those in M
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and M2, and if the nonce in M3 is the same as in M2, the
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handshake is complete, and the client and server begin sending
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cells to one another. Otherwise, the server closes the TCP
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connection.
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2.2. Establishing OP-to-OR connections
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When an Onion Proxy (OP) needs to establish a connection to an OR,
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the handshake is simpler because the OR does not need to verify the
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OP's identity. The OP and OR establish the following steps:
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1. OP connects to OR:
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First, the OP generates a pair of 8-byte symmetric keys (one
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[K_f] for the 'forward' stream from OP to OR, and one
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[K_b] for the 'backward' stream from OR to OP).
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The OP generates a message [M] in the following format:
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Maximum bandwidth (bytes/s) [4 bytes]
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Forward key [K_f] [16 bytes]
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Backward key [K_b] [16 bytes]
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[Total: 32 bytes]
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The OP encrypts M with the OR's public key and PKCS1 padding,
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opens a TCP connection to the OR's TCP port, and sends the
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resulting 128-byte encrypted message to the OR.
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2. OR receives keys:
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When the OR receives a connection from an OP [This is on a
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different port, right? How does it know the difference? -NM],
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[Correct. The 'or_port' config variable specifies the OR port,
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and the op_port variable specified the OP port. -RD]
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it waits for 128 bytes of data, and decrypts the resulting
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data with its private key, checking the PKCS1 padding. If the
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padding is invalid, or the message is not 20 bytes long, the
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OR closes the connection.
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Otherwise, the connection is established, and the O is ready
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to receive cells.
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The server sets its keys for this connection, setting K_f to
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the client's K_b, and K_b to the client's K_f.
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2.3. Sending cells and link encryption
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Once the handshake is complete, the ORs or OR and OP send cells
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(specified below) to one another. Cells are sent serially,
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encrypted with the 3DES-OFB keystream specified by the handshake
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protocol. Over a connection, communicants encrypt outgoing cells
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with the connection's K_f, and decrypt incoming cells with the
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connection's K_b.
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[Commentary: This means that OR/OP->OR connections are malleable; I
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can flip bits in cells as they go across the wire, and see flipped
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bits coming out the cells as they are decrypted at the next
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server. I need to look more at the data format to see whether
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this is exploitable, but if there's no integrity checking there
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either, I suspect we may have an attack here. -NM]
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[Yes, this protocol is open to tagging attacks. The payloads are
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encrypted inside the network, so it's only at the edge node and beyond
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that it's a worry. But adversaries can already count packets and
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observe/modify timing. It's not worth putting in hashes; indeed, it
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would be quite hard, because one of the sides of the circuit doesn't
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know the keys that are used for de/encrypting at each hop, so couldn't
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craft hashes anyway. See the Bandwidth Throttling (threat model)
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thread on http://archives.seul.org/or/dev/Jul-2002/threads.html. -RD]
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[Even if I don't control both sides of the connection, I can still
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do evil stuff. For instance, if I can guess that a cell is a
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TOPIC_COMMAND_BEGIN cell to www.slashdot.org:80 , I can change the
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address and port to point to a machine I control. -NM]
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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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ACI (anonymous circuit identifier) [2 bytes]
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Command [1 byte]
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Length [1 byte]
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Sequence number (unused, set to 0) [4 bytes]
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Payload (padded with 0 bytes) [248 bytes]
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[Total size: 256 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 -- DATA (End-to-end data) (See Sec 5)
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3 -- DESTROY (Stop using a circuit) (See Sec 4)
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4 -- SENDME (For flow control) (See Sec 6.1)
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The interpretation of 'Length' and 'Payload' depend on the type of
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the cell.
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PADDING: Length is 0; Payload is 248 bytes of 0's.
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CREATE: Length is a value between 1 and 248; the first 'length'
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bytes of payload contain a portion of an onion.
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DATA: Length is a value between 4 and 248; the first 'length'
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bytes of payload contain useful data.
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DESTROY: Neither field is used.
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SENDME: Length encodes a window size, payload is unused.
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Unused fields are filled with 0 bytes. The payload is padded with
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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 and DESTROY cells are used to manage circuits; see section
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4 below.
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DATA cells are used to send commands and data along a circuit; see
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section 5 below.
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SENDME cells are used for flow control; see section 6 below.
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4. Onions and circuit management
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4.1. Setting up circuits
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An onion is a multi-layered structure, with one layer for each node
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in a circuit. Each (unencrypted) layer has the following fields:
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Version [1 byte]
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Port [2 bytes]
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Address [4 bytes]
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Expiration time [4 bytes]
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Key seed material [16 bytes]
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[Total: 27 bytes]
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The value of Version is currently 2.
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The port and address field denote the IPV4 address and port of
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the next onion router in the circuit, or are set to 0 for the
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last hop.
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The expiration time is a number of seconds since the epoch (1
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Jan 1970); by default, it is set to the current time plus one
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day.
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When constructing an onion to create a circuit from OR_1,
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OR_2... OR_N, the onion creator performs the following steps:
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1. Let M = 100 random bytes.
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2. For I=N downto 1:
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A. Create an onion layer L, setting Version=2,
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ExpirationTime=now + 1 day, and Seed=16 random bytes.
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If I=N, set Port=Address=0. Else, set Port and Address to
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the IPV4 port and address of OR_{I+1}.
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B. Let M = L | M.
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C. Let K1_I = SHA1(Seed).
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Let K2_I = SHA1(K1_I).
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Let K3_I = SHA1(K2_I).
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D. Encrypt the first 128 bytes of M with the RSA key of
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OR_I, using no padding. Encrypt the remaining portion of
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M with 3DES/OFB, using K1_I as a key and an all-0 IV.
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3. M is now the onion.
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To create a connection using the onion M, an OP or OR performs the
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following steps:
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1. 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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2. Choose an ACI not already in use on the connection with the
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first router in the chain. If our address/port pair is
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numerically higher than the address/port pair of the other
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side, then let the high bit of the ACI be 1, else 0.
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3. To send M over the wire, prepend a 4-byte integer containing
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Len(M). Call the result M'. Let N=ceil(Len(M')/248).
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Divide M' into N chunks, such that:
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Chunk_I = M'[(I-1)*248:I*248] for 1 <= I <= N-1
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Chunk_N = M'[(N-1)*248:Len(M')]
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4. Send N CREATE cells along the connection, setting the ACI
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on each to the selected ACI, setting the payload on each to
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the corresponding 'Chunk_I', and setting the length on each
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to the length of the payload.
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Upon receiving a CREATE cell along a connection, an OR performs
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the following steps:
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1. If we already have an 'open' circuit along this connection
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with this ACI, drop the cell.
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Otherwise, if we have no circuit along this connection with
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this ACI, let L = the integer value of the first 4 bytes of
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the payload. Create a half-open circuit with this ACI, and
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begin queueing CREATE cells for this circuit.
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Otherwise, we have a half-open circuit. If the total payload
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length of the CREATE cells for this circuit is exactly equal
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to the onion length specified in the first cell (minus 4), then
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process the onion. If it is more, then tear down the circuit.
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2. Once we have a complete onion, decrypt the first 128 bytes
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of the onion with this OR's RSA private key, and extract
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the outmost onion layer. If the version, back cipher, or
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forward cipher is unrecognized, or the expiration time is
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in the past, then tear down the circuit (see section 4.2).
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Compute K1 through K3 as above. Use K1 to decrypt the rest
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of the onion using 3DES/OFB.
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If we are not the exit node, remove the first layer from the
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decrypted onion, and send the remainder to the next OR
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on the circuit, as specified above. (Note that we'll
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choose a different ACI for this circuit on the connection
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with the next OR.)
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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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4.2. 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 topics on a circuit are closed and the
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circuit's intended lifetime is over.
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To tear down a circuit, an OR or OP sends a DESTROY cell with that
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direction's ACI to the adjacent nodes on that circuit.
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Upon receiving a DESTROY cell, an OR frees resources associated
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with the corresponding circuit. If it's not the start or end of the
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circuit, it sends a DESTROY cell for that circuit to the next OR in
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the circuit. If the node is the start or end of the circuit, then
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it tears 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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4.3. Routing data cells
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When an OR receives a DATA cell, it checks the cell's ACI 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 DATA 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 3DES/OFB, as follows:
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'Forward' data cell (same direction as onion):
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Use K2 as key; encrypt.
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'Back' data cell (opposite direction from onion):
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Use K3 as key; decrypt.
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Otherwise, if the data cell has arrived to the OP edge of the circuit,
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the OP de/encrypts the length and payload fields with 3DES/OFB as
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follows:
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OP sends data cell:
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For I=1...N, decrypt with K2_I.
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OP receives data cell:
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For I=N...1, encrypt with K3_I.
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Edge nodes process the length and payload fields of DATA cells as
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described in section 5 below.
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5. Application connections and topic management
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5.1. Topics and TCP streams
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Within a circuit, the OP and the exit node use the contents of DATA
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packets to tunnel TCP connections ("Topics") across circuits.
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These connections are initiated by the OP.
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The first 4 bytes of each data cell are reserved as follows:
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Topic command [1 byte]
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Unused, set to 0. [1 byte]
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Topic ID [2 bytes]
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The recognized topic commands are:
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1 -- TOPIC_BEGIN
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2 -- TOPIC_DATA
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3 -- TOPIC_END
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4 -- TOPIC_CONNECTED
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5 -- TOPIC_SENDME
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All DATA cells pertaining to the same tunneled connection have the
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same topic ID.
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To create a new anonymized TCP connection, the OP sends a
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TOPIC_BEGIN data cell with a payload encoding the address and port
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of the destination host. The payload format is:
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ADDRESS | ':' | PORT | '\000'
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where 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 TOPIC_END cell.
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Otherwise, the exit node replies with a TOPIC_CONNECTED cell.
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The OP waits for a TOPIC_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 TOPIC_DATA cells, and upon receiving such
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cells, echo their contents to the corresponding TCP stream.
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[XXX Mention zlib encoding. -NM]
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When one side of the TCP stream is closed, the corresponding edge
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node sends a TOPIC_END cell along the circuit; upon receiving a
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TOPIC_END cell, the edge node closes the corresponding TCP stream.
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[This should probably become:
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When one side of the TCP stream is closed, the corresponding edge
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node sends a TOPIC_END cell along the circuit; upon receiving a
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TOPIC_END cell, the edge node closes its side of the corresponding
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TCP stream (by sending a FIN packet), but continues to accept and
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package incoming data until both sides of the TCP stream are
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closed. At that point, the edge node sends a second TOPIC_END
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cell, and drops its record of the topic. -NM]
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6. Flow control
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6.1. Link throttling
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As discussed above in section 2.1, ORs and OPs negotiate a maximum
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bandwidth upon startup. The communicants only read up to that
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number of bytes per second on average, though they may use mechanisms
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to handle spikes (eg token buckets).
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Communicants rely on TCP's default flow control to push back when they
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stop reading, so nodes that don't obey this bandwidth limit can't do
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too much damage.
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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
|
|
dummy traffic. Because strong attacks exist even with link padding,
|
|
and because link padding greatly increases the bandwidth requirements
|
|
for running a node, we plan to leave out link padding until this
|
|
tradeoff is better understood.
|
|
|
|
6.3. Circuit flow control
|
|
|
|
To control a circuit's bandwidth usage, each node keeps track of
|
|
how many data cells it is allowed to send to the next hop in the
|
|
circuit. This 'window' value is initially set to 1000 data cells
|
|
in each direction (cells that are not data cells do not affect
|
|
the window). Each edge node on a circuit sends a SENDME cell
|
|
(with length=100) every time it has received 100 data cells on the
|
|
circuit. When a node receives a SENDME cell for a circuit, it increases
|
|
the circuit's window in the corresponding direction (that is, for
|
|
sending data cells back in the direction from which the sendme arrived)
|
|
by the value of the cell's length field. If it's not an edge node,
|
|
it passes an equivalent SENDME cell to the next node in the circuit.
|
|
|
|
If the window value reaches 0 at the edge of a circuit, the OR stops
|
|
reading from the edge connections. (It may finish processing what
|
|
it's already read, and queue those cells for when a SENDME cell
|
|
arrives.) Otherwise (when not at the edge of a circuit), if the
|
|
window value is 0 and a data cell arrives, the node must tear down
|
|
the circuit.
|
|
|
|
6.4. Topic flow control
|
|
|
|
Edge nodes use TOPIC_SENDME data cells to implement end-to-end flow
|
|
control for individual connections across circuits. As with circuit
|
|
flow control, edge nodes begin with a window of cells (500) per
|
|
topic, and increment the window by a fixed value (50) upon receiving
|
|
a TOPIC_SENDME data cell. Edge nodes initiate TOPIC_SENDME data
|
|
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.
|
|
|
|
Line format : address ORPort OPPort APPort DirPort bandwidth(bytes/s)
|
|
followed by the router's public key.
|
|
ORport is where the router listens for other routers (speaking cells)
|
|
OPPort is where the router listens for onion proxies (speaking cells)
|
|
APPort is where the router listens for applications (speaking socks)
|
|
DirPort is where the router listens for directory download requests
|
|
|
|
Example:
|
|
moria.mit.edu 9001 9011 9021 9031 100000
|
|
-----BEGIN RSA PUBLIC KEY-----
|
|
MIGJAoGBAMBBuk1sYxEg5jLAJy86U3GGJ7EGMSV7yoA6mmcsEVU3pwTUrpbpCmwS
|
|
7BvovoY3z4zk63NZVBErgKQUDkn3pp8n83xZgEf4GI27gdWIIwaBjEimuJlEY+7K
|
|
nZ7kVMRoiXCbjL6VAtNa4Zy1Af/GOm0iCIDpholeujQ95xew7rQnAgMA//8=
|
|
-----END RSA PUBLIC KEY-----
|
|
|